injection molding methods and apparatus

专利摘要:
SELECTION METHODS AND APPARATUS WITH INJECTION MOLDING. These are selection members, selection sets, methods for manufacturing selection members and sets and methods for selection materials that are provided for vibrating selection machines that incorporate the use of injection molded materials. The use of injection molded screen elements provides, inter alia: variant selection surface configurations; manufacture of a set of screens that are fast and relatively simple; and a combination of exceptional mechanical and electrical screen assembly properties, which include stiffness, chemical and wear resistance. The embodiments of the present invention use a thermoplastic injection molded material.
公开号:BR112016025640B1
申请号:R112016025640-9
申请日:2015-05-01
公开日:2021-03-02
发明作者:Keith F. Wojciechowski
申请人:Derrick Corporation；
IPC主号:

专利说明:

CROSS REFERENCE TO RELATED REQUESTS
[001] This application is a continuation in part of Patent Application number US 13 / 800,826, filed on March 13, 2013, whose application claims the benefit of Provisional Patent Application number 61 / 652,039, filed on May 25 of 2012, serial number US 61 / 714,882, filed on October 17, 2012. FIELD
[002] The present disclosure refers, in general, to the selection of material. More particularly, the present disclosure relates to selection members, selection sets, methods for making selection members and sets and methods for selection materials. BACKGROUND
[003] The selection of material includes the use of vibrating selection machines. Vibrating sorting machines provide the ability to excite an installed screen, so that the materials placed on the screen can be separated to a desired level. Very large materials are separated from very small materials. Over time, the screens wear out and require replacement. As such, the screens are designed to be replaceable.
[004] The replacement screen sets need to be securely attached to a vibrating sorting machine and are subjected to great vibratory forces. Replacement screens can be attached to a vibrating sorting machine by means of tension members, compression members or clamping members.
[005] Replacement screen sets are typically made of metal or a thermostable polymer. The material and configuration of the replacement screens are specific to a selection application. For example, due to their relative durability and ability to select finely, metal screens are often used for wet applications in the oil and gas industry. Traditional thermostable polymer screens (eg, molded polyurethane screens), however, are not as durable and are unlikely to withstand the harsh conditions of such wet applications and are often used in dry applications, such as wet applications. mining industry.
[006] The manufacture of thermostable polymer screens is relatively complicated, time-consuming and prone to errors. Typical thermostable polymer screens that are used with vibrating sorting machines are manufactured by combining separate liquids (for example, polyester, polyether and a dressing) that react chemically and then allow the mixture to be cured by a time period in a mold. When making screens with thin passages, for example, approximately 43 microns to approximately 100 microns, this process can be extremely difficult and time-consuming. Certainly, to create thin passages on a screen, the channels in the molds, through which the liquid travels, have to be very small (for example, in the order of 43 microns) and, quite often, the liquid does not reach all the cavities in the mold. As a result, complicated procedures are often implemented, which requires a lot of attention to pressures and temperatures. Since a relatively large single screen (for example, sixty-one centimeters (two feet) by ninety-two centimeters (three feet) or larger) is made in a mold, a flaw (for example, a hole, that is, a where the liquid does not reach) will ruin the entire screen. Thermostable polymer screens are typically manufactured by molding an entire screen array structure, such as a large selection piece, and the screen array can have passages ranging from approximately 43 microns to approximately 4,000 microns in size. The selection surface of conventional thermostable polymer screens usually has a uniform flattened configuration.
[007] Thermostable polymer screens are relatively flexible and are often attached to a vibrating sorting machine using tension members that pull the side edges of the thermostable polymer screen away from each other and hold a lower surface of the thermostable polymer screen against a surface of a vibrating sorting machine. To prevent deformation when tensioned, thermostable polymer assemblies can be molded with aramid fibers that extend in the direction of tension (see, for example, U.S. Patent No. 4,819,809). If a compressive force were applied to the side edges of typical thermostable polymer screens, it would bend or curl, thereby making the selection surface relatively ineffective.
[008] Unlike thermostable polymer screens, metal screens are rigid and can be compressed or tensioned in a vibrating sorting machine. Metal screen assemblies are often manufactured from multiple metal components. The fabrication of wire mesh sets typically includes: making a selection material, often three layers of a braided wire mesh; manufacture a metal backing plate with opening; and connect the selection material to the opening metal backing plate. The layers of wire mesh can be finely braided, with passages in the range of approximately 30 microns to approximately 4,000 microns. The entire selection surface of conventional metal assemblies is usually a relatively uniform flattened configuration or a relatively uniform fluted configuration.
[009] They are critical for the performance of selection of screen sets (sets of thermostable polymers and sets of metal type), for vibrating selection machines, the size of the passages in the selection surface, structural stability and the durability of the surface selection, the structural stability of the entire unit, the chemical properties of the unit components and the ability of the unit to perform at various temperatures and environments. The disadvantages of conventional metal assemblies include the lack of structural stability and durability of the selection surface formed by the layers of braided wire mesh, obstruction (buffering of selection passages by particles) of the selection surface, weight of the general structure, time and costs associated with the manufacture or purchase of each component member and the costs and assembly time. Due to the fact that wire mesh is often outsourced by wire mesh manufacturers and is often purchased from users or wholesalers, quality control can be extremely difficult and there are often problems with wire mesh. Faulty wire mesh can result in screen performance problems, and testing and constant monitoring are required.
[010] One of the biggest problems with conventional metal assemblies is obstruction. A new metal screen may initially have a relatively large open selection area, but over time, since the screen is exposed to particles, the selection passages are covered (that is, clogged), and the area of open selection, in addition to the effectiveness of the screen itself, is reduced relatively quickly. For example, a set of 140 mesh screens (which has three layers of fabric) can have an initial open selection area of 20 to 24%. Since the screen is used, however, the open selection area can be reduced by 50% or more.
[011] Conventional wire mesh sets also lose large amounts of open selection area due to their construction, which includes adhesives, backing plates, plastic sheets that connect the wire mesh layers together, etc.
[012] Another major problem with conventional metal assemblies is the screen life. Conventional metal assemblies do not typically fail due to the fact that they become used, but, on the contrary, fail due to fatigue. That is, the wires of the braided wire mesh, in fact, often break due to the upward and downward movement to which they are subjected during vibratory loading.
[013] The disadvantages for conventional thermostable polymer screens also include the lack of structural stability and durability. Additional disadvantages include the inability to withstand compression-type loads and the inability to withstand high temperatures (for example, typically a thermostable polymer type screen will begin to fail or suffer performance problems at temperatures above 54 ° C (130 ° F) ), especially screens with thin passages, for example, approximately 43 microns to approximately 100 microns). Additionally, as discussed above, manufacturing is complicated, time-consuming and prone to errors. In addition, the molds used to manufacture thermostable polymer screens are expensive and any failure or the slightest damage to them will spoil the entire mold and will require replacement, which can result in costly downtime in the manufacturing process.
[014] Another disadvantage for both thermostable polymer and conventional metal screens is the limitation of screen surface configurations that are available. The existing selection surfaces are manufactured with relatively uniform passage sizes along them and a relatively uniform surface configuration along them, if the selection surface is flat or undulating.
[015] Conventional polymer screens referred to in Provisional Application No. 61 / 652,039 (also referred to as traditional polymer screens, existing polymer screens, typical polymer screens or simply polymer screens) refer to polymer screens conventional thermostable polymers described in Provisional Patent Application No. US 61 / 714,882 and the conventional thermostable polymer screens described in this document (also referred to in this document and in Provisional Patent Application No. US 61 / 714,882 as thermostable polymer screens traditional thermostable polymer screens, typical thermostable polymer screens or simply thermostable screens). Consequently, the conventional polymer-type fabrics referenced in Provisional Application No. US 61 / 652,039 are the same conventional thermostable polymer fabrics referred to in this document and in Provisional Patent Application No. US 61 / 714,882, and can be manufactured with passages of extremely small selections (as described in this document and in Provisional Patent Application No. US 61 / 714,882), but have all the disadvantages (as described in this document and in Provisional Patent Application No. US 61 / 714,882) in relation to conventional thermostable polymer screens, which include the lack of structural stability and durability, the inability to withstand compression loads, the inability to withstand high temperatures and time-consuming and complicated error-prone manufacturing methods.
[016] There is a need for improved and versatile selection members, selection sets, methods for manufacturing selection members and sets and methods for selection materials for vibrating selection machines that incorporate the use of injection molded materials (for example , thermoplastics) that have improved chemical and mechanical properties. SUMMARY
[017] The present disclosure is an improvement over existing methods and screen sets for selecting and manufacturing its parts and screen sets. The present invention provides extremely improved and versatile selection members, selection sets, methods for manufacturing selection members and sets and methods for selection materials for vibrating selection machines that incorporate the use of injection molded materials that have improved properties, that include chemical and mechanical properties. In certain embodiments of the present invention, a thermoplastic is used as the injection molded material. The present invention is not limited to injection molded thermoplastic materials and, in the embodiments of the present invention, other materials can be used, which have similar chemical and / or mechanical properties. In the embodiments of the present invention, the multiple injection molded web elements are securely attached to the subgrade structures. The subgrades are attached together to form the screen set structure, which has a selection surface that includes multiple screen elements. The use of injection molded screen elements with the various modalities described in this document provides, inter alia: variant selection surface configurations; manufacture of a set of screens that are fast and relatively simple; and a combination of exceptional electrical, chemical and mechanical screen properties, including stiffness, chemical and wear resistance.
[018] The modalities of the present invention include sets of screens that are configured to have relatively large open selection areas, while having small, structurally stable selection passages for fine vibrating selection applications. In the embodiments of the present invention, the selection passes are very small (for example, as small as approximately 43 microns) and the screen elements are large enough (for example, twenty-five millimeters (one inch) by twenty-five millimeters (one inch), twenty-five millimeters (one inch) by fifty-one millimeters (two inches), fifty-one millimeters (two inches) by seventy-six millimeters (three inches), etc.) to make the assembly of a complete canvas set selection surface (for example, sixty-one centimeters (two feet) by ninety-two centimeters (three feet), ninety-two centimeters (three feet) percent and twenty-two centimeters (four feet) , etc.). The manufacture of small selection passages for fine selection applications requires very small structural injection molding members that actually form the selection passages. These structural members are injection molded to be integrally formed with the screen element structure. Importantly, the structural members are small enough (for example, in certain applications, they can be in the order of approximately 43 microns in the selection surface width) to provide an effective general open selection area and form part of the structure. full-screen element, which is large enough (for example, fifty-one millimeters (two inches) by seventy-six millimeters (three inches)), to make it practical to assemble a relatively large complete selection surface (for example, sixty-one centimeters (two feet) by ninety-two centimeters (three feet)) from it.
[019] In one embodiment of the present invention, a thermoplastic material is injection molded to form selection elements. Previous thermoplastics were not used in the manufacture of vibrating screens with thin passages (for example, approximately 43 microns to approximately 1,000 microns), due to the fact that it would be extremely difficult, if not impossible, to mold a thermoplastic injection into a unique, relatively large vibrating selection structure that has fine passages, and obtaining the open selection area necessary for competitive performance in vibrating selection applications.
[020] According to one embodiment of the present disclosure, it is proposed that a set of screens: be structurally stable and can be subjected to various loading conditions, which include compression, tensioning and tightening; can withstand large vibratory forces; include multiple injection-molded screen elements that, due to their relatively small size, can be manufactured with extremely small passage sizes (which have dimensions as small as approximately 43 microns); eliminate the need for wire mesh; be light weight; be recyclable; be simple and easy to assemble; can be manufactured in multiple different configurations, which includes having various screen pass sizes across the screen, and having various selection surface configurations, for example, various combinations of wavy and flat sections; and can be manufactured with nanomaterials and materials for specific application. In addition, each set of screens can be customized for a specific application and can be simply and easily manufactured with various combinations and passage sizes that depend on the specifications provided by an end user. The modalities of the present disclosure can be applied to various applications, which include dry and wet applications and can be applied across various industries. The present invention is not limited to the oil and gas industry and the mining industry, it can be used in any industry that requires the separation of materials with the use of vibrating selection machines, which include pulp and paper, chemical, pharmaceutical products and others.
[021] In an exemplary embodiment of the present invention, it is proposed that a set of screens substantially improve the selection of materials with the use of a thermoplastic injection molded screen element. The multiple injection molded screen elements with thermoplastic polymers are securely attached to the subgrade structures. The subgrades are attached together to form the screen set structure, which has a selection surface that includes multiple screen elements. Each screen element and subgrade can have different configurations and formats. Injection molding screen elements with thermoplastics allow precise fabrication of selection passages, which can be as small as approximately 43 microns in size. The grid frame can be substantially rigid and can provide durability against damage or deformation under the substantial vibratory load boundaries to which it is subjected when attached to a vibrating sorting machine. In addition, the subgrades, when assembled to form the complete screen set, are strong enough, not only to withstand vibratory loading, but also to the forces required to attach the screen set to the vibrating selection machine, which includes compression loads large loads, tension loads and / or tightening loads. In addition, the passages in the subgrades structurally support the screen elements and transfer the vibrations of the vibrating selection machine to the elements that form the selection passages, thus improving the selection performance. The screen elements, the subgrades and / or any other component of the screen set may include nanomaterials and / or glass fibers that, in addition to other benefits, provide durability and strength.
[022] According to an exemplary embodiment of the present disclosure, a set of screens is provided with a screen element that includes a screen element selection surface with a series of selection passes and a subgrade that includes multiple elongated structural members that form a grid frame that has grid passages. The screen element covers at least one of the grid passages and is attached to an upper surface of the subgrade. The multiple independent subgrades are attached together to form the screen set, and the screen set has a continuous screen set selection surface that has multiple screen element selection surfaces. The screen element includes substantially parallel end portions and substantially parallel side edge portions, substantially perpendicular to the end portions. The screen element additionally includes a first screen element support member and a second screen element support member orthogonal to the first screen element support member. The first web element support member extends between the end portions and is approximately parallel to the side edge portions. The second web element support member extends between the side edge portions and is approximately parallel to the end portions. The web element includes a first series of reinforcement members substantially parallel to the side edge portions and a second series of reinforcement members substantially parallel to the end portions. The screen element selection surface includes screen surface elements that form the selection passes. The end portions, the side edge portions, the first and second support members and the first and second series of reinforcement members structurally stabilize the screen surface elements and the selection passages. The screen element is formed as a single piece molded by thermoplastic injection.
[023] Selection passes can be rectangular, square, circular and oval or any other shape. The screen surface elements can extend parallel to the end portions and form the selection passages. The screen surface elements can also extend perpendicularly to the end portions and form the screen passages. Different combinations of rectangular, square, circular and oval selection passages (or other shapes) can be incorporated together and, depending on the shape used, can extend parallel and / or perpendicular to the end portions.
[024] The screen surface elements may extend parallel to the end portions and may be elongated members that form the selection passages. Selection passages can be elongated slits that are approximately 43 microns to approximately 4,000 microns apart between the inner surfaces of adjacent screen surface elements. In certain embodiments, the screen passages can have a distance of approximately 70 microns to approximately 180 microns between the inner surfaces of adjacent screen surface elements. In other embodiments, the selection passages may have a distance of approximately 43 microns to approximately 106 microns between the internal surfaces of adjacent screen surface elements. In the embodiments of the present invention, the selection passages can have a width and a length, the width can be about 0.043 mm to about 4 mm and the length can be about 0.086 mm to about 43 mm. In certain embodiments, the width-to-length ratio can be approximately 1: 2 to approximately 1: 1,000.
[025] Multiple subgrades of varying sizes can be combined to form a support structure for a set of screens for screen elements. Alternatively, a single subgrade can be injection molded with thermoplastic or otherwise constructed to form the entire support structure for a set of screens for multiple individual screen elements.
[026] In modalities that use multiple subgrades, a first subgrade can include a first base member that has a first fastener that fits with a second fastener from a second base member from a second subgrade, where the first and second fasteners hold the first and second subgrades together. The first fastener can be a clamp and the second fastener can be a clamp opening, where the clamp snaps into the clamp opening and securely attaches to the first and second subgrades together.
[027] The first and second screen element support members and the screen element end portions may include a screen element attachment arrangement configured to fit with a subgrade attachment arrangement. The subgrade attachment arrangement may include elongated attachment members and the screen element attachment arrangement may include attachment openings that fit with the elongated attachment members that securely attach the screen element to the subgrade. A portion of the elongated attachment members can be configured to extend through the screen element attachment openings and slightly above the screen element selection surface. Attachment openings can include a tapered hole or they can simply include an opening without any taper. The portion of the elongated attachment members above the selection element selection surface can be melted and can fill the tapered hole, securing the screen element to the subgrade. Alternatively, the portion of the elongated attachment members that extends through the opening in the selection element selection surface can be melted so that it forms a bead on the selection element selection surface and fixes the screen element to the subgrade.
[028] The structural elongated members may include, in substantially parallel fashion, subgrade end members and, in substantially parallel fashion, subgrade side members substantially perpendicular to the subgrade end members. Structural elongated members may additionally include a first subgrade support member and a second subgrade support member orthogonal to the first subgrade support member. The first subgrade support member can extend between the subgrade end members and can be approximately parallel to the subgrade side members. The second subgrade support member can extend between the subgrade side members and can be approximately parallel to the subgrade end members, and substantially perpendicular to the subgrade edge members.
[029] The grid frame may include a first and a second grid frame that form a first and a second grid passage. Screen elements can include a first and a second screen element. The subgrade can have a peak portion and a base portion. The first and second grid frames may include the first and second angled surfaces that peak at the peak portion and extend downward from the peak portion to the base portion. The first and second screen elements can cover the first and second angled surfaces, respectively.
[030] In accordance with an exemplary embodiment of the present invention, a set of screens is provided with a screen element that includes a screen element selection surface with a series of selection passages and a subgrade that includes multiple elongated structural members that form a grid frame that has grid passages. The screen element covers at least one grid passage and is attached to an upper surface of the subgrade. The multiple subgrades are fastened together to form the screen set, and the screen set has a continuous screen set selection surface comprised of multiple screen element selection surfaces. The screen element is a single piece molded by a thermoplastic injection.
[031] The screen element may include substantially parallel end portions and substantially parallel side edge portions, substantially perpendicular to the end portions. The screen element may additionally include a first screen element support member and a second screen element support member orthogonal to the first screen element support member. The first web element support member can extend between the end portions and can be approximately parallel to the side edge portions. The second web element support member can extend between the side edge portions and can be approximately parallel to the end portions. The web element may include a first series of reinforcement members substantially parallel to the side edge portions and a second series of reinforcement members substantially parallel to the end portions. The screen element may include elongated screen surface elements that extend parallel to the end portions and that form the selection passages. The end portions, the side edge portions, the first and the second support members, the first and the second series of reinforcement members can structurally stabilize the screen surface elements and the selection passages.
[032] The first and second series of reinforcement members may be less than one thickness of the end portions, side edge portions and the first and second web element support members. The end portions and side edge portions and the first and second support members of the screen element can form four rectangular areas. The first series of reinforcement members and the second series of reinforcement members can form multiple rectangular support grids within each of the four rectangular areas. Selection passes can be approximately 43 microns to approximately 4,000 microns wide between the internal surfaces of each of the screen surface elements. In certain embodiments, the selection passages can have a width of approximately 70 microns to approximately 180 microns between the internal surfaces of each of the screen surface elements. In other embodiments, the selection passages can have a width of approximately 43 microns to approximately 106 microns between the internal surfaces of each of the screen surface elements. In the embodiments of the present invention, the selection passages can have a width of about 0.043 mm to about 4 mm and a length of about 0.086 mm to about 43 mm. In certain embodiments, the width-to-length ratio can be approximately 1: 2 to approximately 1: 1,000.
[033] The screen elements can be flexible.
[034] The subgrade end members, the subgrade side members and the first and second subgrade support members can form eight rectangular grid passages. A first screen element can cover four of the grid passages and a second screen element can cover the other four passages.
[035] A central portion of the selection element selection surface can flex slightly when subjected to a load. The subgrade can be substantially rigid. The subgrade can also be a single piece molded by a thermoplastic injection. At least one of the subgrade end members and the subgrade side members can include fasteners configured to fit with fasteners on other subgrades, where fasteners can be clamps and clamp openings that snap together and tie , securely, the subgrades together.
[036] The subgrade may include: substantially parallel triangular end pieces, triangular intermediate parts substantially parallel to the triangular end pieces, a first and a second central support substantially perpendicular to the triangular end pieces and which extend between the triangular end pieces , a first and a second base support substantially perpendicular to the triangular end pieces and extending between the triangular end pieces and a central ridge substantially perpendicular to the triangular end pieces and extending between the triangular end pieces. A first edge of the triangular end pieces, the triangular intermediate parts and the first central support, the first base support and the central ridge can form a first upper surface of the subgrade that has a first series of grid passages. A second edge of the triangular end pieces, the triangular intermediate parts and the second central support, the second base support and the central ridge can form a second upper surface of the subgrade that has a second series of grid passages. The first upper surface can slope downwards from the central ridge to the first base support, and the second upper surface can slope downwards from the central ridge to the second base support. A first and a second screen element can cover the first and second series of grid passages, respectively. The first edges of the triangular end pieces, the triangular intermediate parts, the first central support, the first base support and the central ridge can include a first subgrade attachment arrangement configured to fit securely with a first arrangement screen element attachments of the first screen element. The second edges of the triangular end pieces, the triangular intermediate pieces, the second central support, the second base support and the central ridge can include a second subgrade attachment arrangement configured to securely fit with a second arrangement attaching the screen element of the second screen element. The first and second subgrade attachment arrangements may include the elongated attachment members, and the first and second screen element attachment arrangements may include the attachment openings that fit with the elongated attachment members, thereby tying it. safely, the first and second screen elements to the first and second subgrades, respectively. A portion of the elongated attachment members may extend through the screen element attachment openings and slightly above a first and a second screen element selection surface.
[037] The first and second screen elements may each include substantially parallel end portions and substantially parallel side edge portions, substantially perpendicular to the end portions. The first and second screen elements can each include a first screen element support member and a second screen element support orthogonal to the first screen element support member, wherein the first screen member screen element support extends between the end portions and is approximately parallel to the side edge portions, wherein the second screen element support member extends between the side edge portions and can be approximately parallel to the end portions . The first and second web elements can each include a first series of reinforcement members substantially parallel to the side edge portions and a second series of reinforcement members substantially parallel to the end portions. The first and second screen elements may each include elongated screen surface elements that extend parallel to the end portions and that form the selection passages. The end portions, the side edge portions, the first and the second support members, the first and the second series of reinforcement members can structurally stabilize the screen surface elements and the selection passages.
[038] One of the first and second base supports can include fasteners that hold the multiple subgrades together, where the fasteners can be clamps and clamp openings that snap into place and securely tie the subgrades together.
[039] The set of screens can include a first, a second, a third and a fourth screen element. The first series of grid passages can be eight passages formed by the first edge of the triangular end pieces, the triangular intermediate parts and the first central support, the first base support and the central ridge. The second series of rail passages can be eight passages formed by the second edge of the triangular end pieces, the intermediate triangular pieces, the second central support, the second base support and the central ridge. The first screen element can cover four of the grid passages of the first series of grid passages, and the second screen element can cover the other four passages of the first series of grid passages. The third screen element can cover four of the grid passages of the second series of grid passages, and the fourth screen element can cover the other four passages of the second series of grid passages. A central portion between the first, second, third and fourth selection element selection surfaces can flex slightly when subjected to a load. The subgrade can be substantially rigid and can be a single piece molded by a thermoplastic injection.
[040] In accordance with an exemplary embodiment of the present disclosure, a set of screens is provided with a screen element that includes a screen element selection surface with selection passages and a subgrade that includes a grid frame with passages from grid. The screen element covers the grid passages and is attached to a subgrade surface. The multiple subgrades are fastened together to form the screen set, and the screen set has a continuous screen set selection surface that includes multiple screen element selection surfaces. The screen element is a thermoplastic injection molded part.
[041] The screen set may also include a first thermoplastic injection molded screen element and a second thermoplastic injection molded screen element, and the grid frame may include a first and a second grid frame that form a first pass grid and a second grid pass. The subgrade can include a ridge portion and a base portion, where the first and second grid frames include the first and second angled surfaces that peak at the peak portion and extend downward from the peak to the base portion. The first and second screen elements can cover the first and second angled surfaces, respectively. The first and second angled surfaces may include a subgrade attachment arrangement configured to securely fit with a screen element attachment arrangement. The subgrade attachment arrangement may include the elongated attachment members, and the screen element attachment arrangement may include openings that fit with the elongated attachment members, thereby securely attaching the screen elements to the subgrade. .
[042] The subgrade can be substantially rigid and can be a single piece molded by thermoplastic injection. A section of the base portion can include a first and a second fastener that attach the subgrade to a third and a fourth fastener from another subgrade. The first and third fasteners can be staples and the second and fourth fasteners can be staple openings. The clamps can snap into clamp openings and securely tie the subgrade and the other subgrade together.
[043] Subgrades can form a concave structure and the continuous screen set selection surface can be concave. Subgrades can form a flattened structure and the continuous screen set selection surface can be flattened. Subgrades can form a convex structure and the continuous screen set selection surface can be convex.
[044] The screen set can be configured to form a predetermined concave shape, when subjected to a compression force by a compression set of a vibrating sorting machine against at least one side member of the vibrating screen set, when placed in the vibrating selection machine. The predetermined concave shape can be determined according to a shape of a surface of the vibrating sorting machine. The screen assembly may have a locking surface that fits the screen assembly to a surface of the vibrating sorting machine, where a locking surface may be rubber, metal (e.g., steel, aluminum, etc.), a material composite, a plastic material or any other suitable material. The screen assembly may include a locking surface configured to interface with a locking surface of a vibrating selection machine, so that the screen assembly is guided to a fixed position on the vibrating selection machine. The interlocking surface can be formed into a portion of at least one subgrade. The interlocking surface screen assembly may be a notch formed in one corner of the screen assembly or a notch formed approximately in the middle of a side edge of the screen assembly. The screen set may have an arcuate surface configured to fit with a concave surface of the vibrating sorting machine. The set of screens may have a substantially rigid structure that does not flex substantially when attached to the vibrating selection machine. The screen assembly may include a screen assembly interlocking surface configured to form a predetermined concave shape when subjected to a compressive force by a member of a vibrating sorting machine. The set of interlocking surface screens can be modeled so that they interface with an interlocking surface of the vibrating selection machine, so that the screen set can be guided to a predetermined location on the vibrating selection machine. The screen set may include a load bar attached to an edge surface of the screen set subgrade, the load bar may be configured to distribute a load across a screen set surface. The screen set can be configured to form a predetermined concave shape, when subjected to a compression force by a compression member of a vibrating sorting machine against the load bar of the vibrating screen set. The set of screens can have a concave shape and can be configured to flex and form a predetermined concave shape, when subjected to a compressive force by a member of a vibrating selection machine.
[045] A first set of subgrades can be formed in the central support frame assemblies that have a first fastener arrangement. A second set of subgrades can be formed in a first set of end support frame having a second fastener frame. A third set of subgrades can be formed into a second set of end support frame having a third fastener frame. The first, second and third fastener frames can attach the first and second end support frames to the central support assemblies. A side edge surface of the first end support frame assembly can form a first end of the screen assembly. A side edge surface of the second end support frame arrangement can form a second end of the screen assembly. An end surface of each of the first and second end support frame assemblies and central support frame assemblies can cumulatively form a first and second side surface of the complete web assembly. The first and second side surfaces of the screen set can be substantially parallel and the first and second end surfaces of the screen set can be substantially parallel and substantially perpendicular to the side surfaces of the screen set. The side surfaces of the screen assembly may include the fasteners configured to engage at least one of a bonding bar and a load distribution bar. Subgrades can include side surfaces, so that when the individual subgrades are fastened together to form the first and second end support frame sets and the central support frame set, the first and the second support frame sets end support and the central support frame assembly each form a concave shape. Subgrades can include shaped side surfaces so that when the individual subgrades are attached together to form the first and second end support frame sets and the central support frame set, the first and second end support and the central support frame assembly each form a convex shape.
[046] The screen elements can be affixed to the subgrades by at least one of a mechanical arrangement, an adhesive, thermal staking and ultrasonic welding.
[047] According to an exemplary embodiment of the present disclosure, a screen element is provided with: a screen element selection surface with screen surface elements that form a series of selection passages; a pair of substantially parallel end portions; a pair of substantially parallel side edge portions, substantially perpendicular to the end portions; a first member of the screen element support; a second web element support member orthogonal to the first web element support member, wherein the first web element support member extends between the end portions and is approximately parallel to the side edge portions, where the second web element supporting member extends between the side edge portions and is approximately parallel to the end portions and substantially perpendicular to the side edge portions; a first series of reinforcement members substantially parallel to the lateral edge portions; and a second series of reinforcement members substantially parallel to the end portions. The screen surface elements extend parallel to the end portions. The end portions, the side edge portions, the first and the second support members, the first and the second series of reinforcement members structurally stabilize the screen surface elements and the selection passages, and the screen element is a single piece molded by thermoplastic injection.
[048] According to an exemplary embodiment of the present disclosure, a screen element is provided with a screen element selection surface with screen surface elements that form a series of selection passages; a pair of substantially parallel end portions; and a pair of substantially parallel side edge portions, substantially perpendicular to the end portions. The screen element is a thermoplastic injection molded part.
[049] The screen element can also have a first screen element support member; a second web element support member orthogonal to the first web element support member, wherein the first web element support member extends between the end portions and is approximately parallel to the side edge portions, where the second web element support member extends between the lateral edge portions and is approximately parallel to the end portions; a first series of reinforcement members substantially parallel to the lateral edge portions; and a second series of reinforcement members substantially parallel to the end portions. The screen surface elements can extend parallel to the end portions. In certain embodiments, the screen surface elements can also be configured to extend perpendicularly to the end portions. The end portions, the side edge portions, the first and the second support members, the first and the second series of reinforcement members can structurally stabilize the screen surface elements and the selection passages.
[050] The screen element can also have a screen element attachment arrangement molded integrally with the screen element and configured to fit with a subgrade attachment arrangement. The multiple subgrades can form a set of screens, and the set of screens can have a continuous screen set selection surface that includes multiple screen element selection surfaces.
[051] According to an exemplary embodiment of the present disclosure, a method for manufacturing a set of screens for selection materials is provided, which includes: determining the screen set performance specifications for the screen set; determining a check pass requirement for a screen element based on the screen set performance specifications, where the screen element includes a screen element selection surface that has check passes; determine a display configuration based on the display set performance specifications, where the display configuration includes having the display elements arranged in at least one of the flattened configuration and an unflattered configuration; injection molding the screen elements with a thermoplastic material; manufacture a subgrade configured to support the screen elements, where the subgrade has a grid frame with grid passages where at least one screen element covers at least one grid pass and is attached to an upper surface of the subgrade, in that the top surface of each subgrade includes at least one of the flattened surface and the non-flattened surface that receives the screen elements; tie the screen elements to the subgrades; tying the multiple subgrade sets together to form edge screen frames and central screen frames; attaching the end screen frames to the central screen frames to form a screen frame structure; attaching a first binder bar to a first end of the screen frame structure; and attaching a second binder bar to a second end of the screen frame structure to form the screen array, wherein the screen array has a continuous screen array selection surface comprised of multiple screen element selection surfaces.
[052] Screen set performance specifications can include at least one of the dimensions, material requirements, open selection area, cut-off point and capacity requirements for a selection application. A handle can be attached to the bonding bar. An identification can be attached to the bonding bar, where the identification can include a description of the performance of the set of screens. At least one of the screen element and the subgrade can be a single piece molded by thermoplastic injection. The thermoplastic material can include a nanomaterial. The subgrade can include at least one base member that has fasteners that fit with fasteners from other base members from other subgrades and fasten the subgrades together. The fasteners can be clamps and clamp openings that snap into place and securely tie the subgrades together.
[053] According to an exemplary embodiment of the present disclosure, a method for manufacturing a set of screens for selection materials is provided by means of injection molding a screen element with a thermoplastic material, wherein the screen element includes a screen element selection surface that has selection passes; fabricating a subgrade that supports the screen element, in which the subgrade has a grid frame with grid passages, in which the screen element comprises at least one grid passage; attaching the screen element to an upper surface of the subgrade; and tying multiple sets of subgrade together to form the screen set, where the screen set has a continuous screen set selection surface made of multiple screen element selection surfaces. The method may also include attaching a first binder bar to a first end of the screen set and attaching a second binder bar to a second end of the screen set. The first and second bonding bars can join the subgrades together. The binder bar can be configured to distribute a load across the first and second ends of the screen set. The thermoplastic material can include a nanomaterial.
[054] According to an exemplary embodiment of the present disclosure, a method for selecting the material is provided by attaching a set of screens to a vibrating selection machine, in which the set of screens includes a screen element that has a series of selection passages that form a screen element selection surface and a subgrade that includes multiple elongated structural members that form a grid frame that has grid passages. The screen elements cover the grid passages and are attached to an upper surface of the subgrade. The multiple subgrades are attached together to form the set of screens. The screen set has a continuous screen set selection surface comprised of multiple screen element selection surfaces. The screen element is a single piece molded by a thermoplastic injection. The material is selected using the set of screens.
[055] According to an exemplary embodiment of the present disclosure, a method for selecting a material is provided, which includes attaching a set of screens to a vibrating sorting machine and forming a top selection surface of the set of screens in a concave shape . The screen set includes a screen element that has a series of selection passages that form a screen element selection surface and a subgrade that includes multiple elongated structural members that form a grid frame that has grid passages. The screen elements cover the grid passages and are attached to an upper surface of the subgrade. The multiple subgrades are fastened together to form the screen set, and the screen set has a continuous screen set selection surface comprised of multiple screen element selection surfaces. The screen element is a single piece molded by a thermoplastic injection. The material is selected using the set of screens.
[056] In accordance with an exemplary embodiment of the present disclosure, a set of screens is provided, which includes: a screen element that has a first adhesion arrangement; and a subgrade unit that has a second membership arrangement. The first adhesion arrangement and the second adhesion arrangement may be different materials. At least one of the first adhesion arrangement and the second adhesion arrangement is excitable, so that the screen element and the subgrade can be attached together. The screen element is a single piece molded by a thermoplastic injection.
[057] The first adhesion arrangement can be a plurality of cavity pockets on a lower surface of the mesh element and the second adhesion arrangement can be a plurality of melting bars on an upper surface of the subgrade. The screen element is micro-molded and has selection passages between approximately 40 microns and approximately 1,000 microns. The cavity pockets can be elongated pockets. The melting bars may be slightly higher than the depth of the cavity pockets. The depth of the cavity pockets can be approximately 1.27 millimeters (0.05 inches) and the height of the melt bars is approximately 1.42 millimeters (0.056 inches). The melting bars may be slightly less than the width of the cavity pockets.
[058] The screen element may include thermoplastic polyurethane. The subgrade can include nylon. The set of screens can include subgrades and additional screen elements fastened together, where the multiple subgrades are fastened together. The screen element may have a plurality of selection passages which are elongated slits of a width and length, wherein the width of the selection passages is approximately 43 microns to approximately 1,000 microns between the inner surfaces of each screen surface element. . The screen element can be attached to the subgrade by means of laser welding. A weld between the screen element and the subgrade can include a mixture of materials from the screen element and the subgrade.
[059] In accordance with an exemplary embodiment of the present disclosure, a set of screens is provided, which includes: a screen element that includes a screen element selection surface that has a series of selection passes; and a subgrade that includes multiple elongated structural members that form a grid frame that has grid passages. The screen element covers at least one of the grid passages and is attached to an upper surface of the subgrade. The multiple independent subgrades are attached together to form the screen set, and the screen set has a continuous screen set selection surface that has multiple screen element selection surfaces. The screen element includes substantially parallel end portions and substantially parallel side edge portions, substantially perpendicular to the end portions. The screen element additionally includes a first screen element support member and a second screen element support member orthogonal to the first screen element support member, wherein the first screen element support member extends between the end portions and is approximately parallel to the side edge portions, wherein the second web element support member extends between the side edge portions and is approximately parallel to the end portions. The web element includes a first series of reinforcement members substantially parallel to the side edge portions, a second series of reinforcement members substantially parallel to the end portions. The screen element selection surface includes screen surface elements that form the selection passes. The end portions, the side edge portions, the first and the second support members, the first and the second series of reinforcement members structurally stabilize the screen surface elements and the selection passages. The screen element is a single piece molded by a thermoplastic injection. The screen element includes a plurality of pocket cavities on a bottom surface of the screen element. The subgrade includes a plurality of melting bars on the upper surface of the subgrade. The plurality of melting bars are configured to fit with the plurality of pocket cavities.
[060] The selection passages can be elongated slits with a width and length, where the width of the selection passages is approximately 43 microns to approximately 1,000 microns between the inner surfaces of each screen surface element. The plurality of melting bars may be slightly higher in height than the depth of the plurality of pocket cavities. The height of the plurality of melt bars can be approximately 1.42 millimeters (0.056 inches). The depth of the plurality of pocket cavities can be approximately 1.27 millimeters (inches). Each of the plurality of pocket cavities may be slightly wider than the width of each of the plurality of melting bars. The plurality of melting bars can be configured so that, when melted, a portion of the plurality of melting bars will fill the width of the plurality of pocket cavities. The material of the screen element can be merged with the material of the subgrade. The screen element can be configured to allow a laser to pass through the screen element and contact the plurality of melting bars. The laser can fuse a portion of the plurality of melting bars, fusing the screen element to the subgrade.
[061] The subgrade can be a single piece molded by a thermoplastic injection. The screen element may include a thermoplastic polyurethane material. The thermoplastic polyurethane can be at least one of a thermoplastic polyurethane based on polyether and a thermoplastic polyurethane based on polyester. The subgrade can include a nylon material. Melting bars can include at least one of a graphite and carbon material. The subgrade can include a screen element locator arrangement configured to locate a screen element on the subgrade. The web element may include a plurality of tapered recessed holes in an upper surface of the web element, along the side edge portions and end portions between the locator passages of the locator arrangement. Fusion bars and pocket cavities can be different materials.
[062] The grid frame may include a first and a second grid frame that form a first and a second grid passage, wherein the screen elements include a first and a second screen element. The subgrade can include a ridge portion and a base portion, the first and second grid frames include the first and second angled surfaces that peak at the ridge portion and extend below the peak portion, up to the base portion, wherein the first and second screen elements comprise the first and second angular surfaces, respectively. The set of screens may include a secondary support frame that covers at least a portion of each grid passage.
[063] In accordance with an exemplary embodiment of the present invention, a set of screens is provided, which includes: a screen element that includes a screen element selection surface that has a series of selection passages and a plurality of cavities pocket on a lower surface of the screen element; and a subgrade that includes multiple elongated structural members that form a grid frame that has grid passages and a plurality of melting bars on an upper surface of the subgrade. The screen element comprises at least one grid passage and is attached to the upper surface of the subgrade by melting the plurality of melting bars to the plurality of pocket cavities. The multiple subgrades are fastened together to form the screen set, and the screen set has a continuous screen set selection surface comprised of multiple screen element selection surfaces. The screen element is a single piece molded by a thermoplastic injection. The screen element is configured to allow a laser to pass through the screen element and contact the plurality of melting bars.
[064] The selection passages can be elongated slits with a width and length, where the width of the selection passages is approximately 43 microns to approximately 1,000 microns between the inner surfaces of each screen surface element. The selection passages can be elongated slits of a width and length, where the width of the selection passages is approximately 70 microns to approximately 180 microns between the inner surfaces of each screen surface element. The selection passages are elongated slits v with a width and length, where the width of the selection passages is approximately 43 microns to approximately 106 microns between the inner surfaces of each screen surface element. The selection passages can be elongated slits with a width and a length, where the width is about 0.044 mm to about 4 mm and the length is about 0.088 mm to about 60 mm.
[065] The subgrade may include substantially parallel triangular end pieces, triangular intermediate parts substantially parallel to the triangular end pieces, a first and a second central support substantially perpendicular to the triangular end pieces and extending between the triangular end pieces, a first and second base support substantially perpendicular to the triangular end pieces and extending between the triangular end pieces and a central ridge substantially perpendicular to the triangular end pieces and extending between the triangular end pieces, a first edge of the triangular end pieces, the triangular intermediate parts, the first central support, the first base support and the central ridge form a first upper surface of the subgrade that has a first series of grid passages and a second edge of the parts triangular end s, the triangular intermediate parts, the second central support, the second base support and the central ridge form a second upper surface of the subgrade that has a second series of grid passages, the first upper surface that slopes from the ridge center to the first base support, where the second upper surface slopes from the central ridge to the second base support. A first and a second screen element can cover the first and second series of grid passages, respectively.
[066] In exemplary embodiments of the present invention, a method of fabricating a set of screens is provided, which includes: laser welding a screen element of a first material in a subgrade of a second material; and tie multiple subgrades together to form the set of screens. The first material and the second material are different materials. The first material and the second material are fused together at laser welding sites.
[067] The set of screens may have a first adhesion arrangement on a lower surface of the screen element and the subgrade has a second adhesion arrangement on an upper surface of the subgrade. The first adhesion arrangement can be a plurality of pocket cavities, and the second adhesion arrangement is a plurality of melting bars. The plurality of pocket cavities can be configured to fit with the plurality of melting bars.
[068] The method of fabricating a set of screens may include locating the screen element on the subgrade through location openings on the screen element and location extensions on an upper surface of the subgrade. The method of fabricating a set of screens may include passing a laser through the screen element, so that it comes into contact with the plurality of melting bars. The method of fabricating a set of screens may include melting a portion of the plurality of melting bars with the laser. The method of fabricating a set of screens may include melting a portion of the first material with one of the heat produced by the laser and transferring heat from the melted portions of the plurality of melting bars. The method of fabricating a set of screens may include removing the laser, so that the melted portion of the first material and the melted portion of the melting bars mix and return to a solid state.
[069] The exemplary modalities of the present disclosure are described in more detail below, with reference to the attached Figures. BRIEF DESCRIPTION OF THE DRAWINGS
[070] Figure 1 is an isometric view of a set of screens, according to an exemplary embodiment of the present invention.
[071] Figure 1A is an enlarged view of a divided portion of the set of screens shown in Figure 1.
[072] Figure 1B is a lower isometric view of the set of screens shown in Figure 1.
[073] Figure 2 is an isometric top view of a screen element, according to an exemplary embodiment of the present invention.
[074] Figure 2A is a top view of the screen element shown in Figure 2.
[075] Figure 2B is a lower isometric view of the screen element shown in Figure 2.
[076] Figure 2C is a bottom view of the screen element shown in Figure 2.
[077] Figure 2D is an enlarged top view of a divided portion of the screen element shown in Figure 2.
[078] Figure 3 is a top isometric view of an end subgrade, according to an exemplary embodiment of the present invention.
[079] Figure 3A is a lower isometric view of the end subgrade shown in Figure 3.
[080] Figure 4 is a top isometric view of a central subgrade, according to an exemplary embodiment of the present invention.
[081] Figure 4A is a lower isometric view of the central subgrade shown in Figure 4.
[082] Figure 5 is a top isometric view of a binder bar, according to an exemplary embodiment of the present invention.
[083] Figure 5A is a lower isometric view of the binder bar shown in Figure 5.
[084] Figure 6 is an isometric view of a screen subset, according to an exemplary embodiment of the present invention.
[085] Figure 6A is an exploded view of the subset shown in Figure 6.
[086] Figure 7 is a top view of the set of screens shown in Figure 1.
[087] Figure 7A is an enlarged cross section of Section A-A of the set of screens shown in Figure 7.
[088] Figure 8 is a top isometric view of a set of screens partially covered with screen elements, according to an exemplary embodiment of the present invention.
[089] Figure 9 is an exploded isometric view of the set of screens shown in Figure 1.
[090] Figure 10 is an exploded isometric view of an end subgrade showing the screen elements, prior to attachment to the end subgrade, according to an exemplary embodiment of the present invention.
[091] Figure 10A is an isometric view of the end subgrade shown in Figure 10 that has the screen elements attached to it.
[092] Figure 10B is a top view of the end subgrade shown in Figure 10A.
[093] Figure 10C is a cross section of Section B-B of the end subgrade shown in Figure 10A.
[094] Figure 11 is an exploded isometric view of a central subgrade showing the screen elements, prior to attachment to the central subgrade, according to an exemplary embodiment of the present invention.
[095] Figure 11A is an isometric view of the central subgrade shown in Figure 11 that has the screen elements attached to it.
[096] Figure 12 is an isometric view of a vibrating selection machine that has sets of screens with concave selection surfaces installed on them, according to an exemplary embodiment of the present invention.
[097] Figure 12A is an enlarged isometric view of the discharge end of the vibrating selection machine shown in Figure 12.
[098] Figure 12B is a front view of the vibrating selection machine shown in Figure 12.
[099] Figure 13 is an isometric view of a vibrating selection machine with a single selection surface that has sets of screens with concave selection surfaces installed on them, according to an exemplary embodiment of the present invention.
[0100] Figure 13A is a front view of the vibrating selection machine shown in Figure 13.
[0101] Figure 14 is a front view of a vibrating sorting machine that has two separate concave sorting surfaces with sets of preformed screens installed on the vibrating sorting machine, according to an exemplary embodiment of the present invention.
[0102] Figure 15 is a front view of a vibrating sorting machine that has a single sorting surface with a set of pre-formed screens installed on the vibrating sorting machine, according to an exemplary embodiment of the present invention.
[0103] Figure 16 is an isometric view of a subset of the end support frame, according to an exemplary embodiment of the present invention.
[0104] Figure 16A is an exploded isometric view of the end support frame subset shown in Figure 16.
[0105] Figure 17 is an isometric view of a subset of central support frame, according to an exemplary embodiment of the present invention.
[0106] Figure 17A is an exploded isometric view of the central support frame subset shown in Figure 17.
[0107] Figure 18 is an exploded isometric view of a set of screens, according to an exemplary embodiment of the present invention.
[0108] Figure 19 is a top isometric view of a set of flattened screens, according to an exemplary embodiment of the present invention.
[0109] Figure 20 is a top isometric view of a set of convex screens, according to an exemplary embodiment of the present invention.
[0110] Figure 21 is an isometric view of a set of screens that have pyramid-shaped subgrades, according to an exemplary embodiment of the present invention.
[0111] Figure 21A is an enlarged view of section D of the set of screens shown in Figure 21.
[0112] Figure 22 is a top isometric view of a pyramid-shaped end subgrade, according to an exemplary embodiment of the present invention.
[0113] Figure 22A is a lower isometric view of the pyramid-shaped end subgrade shown in Figure 22.
[0114] Figure 23 is a top isometric view of a central pyramid-shaped subgrade, according to an exemplary embodiment of the present invention.
[0115] Figure 23A is a lower isometric view of the central pyramid-shaped subgrade shown in Figure 23.
[0116] Figure 24 is an isometric view of a pyramid shaped subset, according to an exemplary embodiment of the present invention.
[0117] Figure 24A is an exploded isometric view of the pyramid shaped subset shown in Figure 24.
[0118] Figure 24B is an exploded isometric view of a pyramid-shaped edge subgrade showing the screen elements, prior to attachment to the pyramid-shaped edge subgrade.
[0119] Figure 24C is an isometric view of the pyramid-shaped end subgrade shown in Figure 24B that has the screen elements attached to it.
[0120] Figure 24D is an exploded isometric view of a central pyramid-shaped subgrade showing screen elements, prior to attachment to the central pyramid-shaped subgrade, according to an exemplary embodiment of the present invention.
[0121] Figure 24E is an isometric view of the central pyramid-shaped subgrade shown in Figure 24D that has the screen elements attached to it.
[0122] Figure 25 is a top view of a set of screens that have subgrades in pyramid shape, according to an exemplary embodiment of the present invention.
[0123] Figure 25A is a cross-sectional view of Section C-C of the set of screens shown in Figure 25.
[0124] Figure 25B is an enlarged view of Section C-C shown in Figure 25A.
[0125] Figure 26 is an exploded isometric view of a set of screens that have flat and pyramidal shaped subsets, according to an exemplary embodiment of the present invention.
[0126] Figure 27 is an isometric view of a vibrating selection machine with two selection surfaces that have sets with concave selection surfaces installed on them, where the sets of screens include flat and pyramid shaped subsets, according to a exemplary embodiment of the present invention.
[0127] Figure 28 is a top isometric view of a set of screens that have flattened and pyramid-shaped subgrades without screen elements, according to an exemplary embodiment of the present invention.
[0128] Figure 29 is a top isometric view of the set of screens shown in Figure 28, in which the subgrades are partially covered with screen elements.
[0129] Figure 30 is a front view of a vibrating sorting machine with two sorting surfaces that have sets with concave sorting surfaces installed on them, in which the sets of screens include flattened and pyramid shaped subgrades, according to a exemplary embodiment of the present invention.
[0130] Figure 31 is a front view of a vibrating selection machine with a single screen surface that has a set with a concave selection surface installed on it, in which the set of screens includes flattened and pyramid shaped subgrades, of according to an exemplary embodiment of the present invention.
[0131] Figure 32 is a front view of a vibrating sorting machine with two sorting surfaces that have sets of preformed screens with flattened selection surfaces installed on them, where the sets of screens include flattened and pyramid shaped subgrades. , according to an exemplary embodiment of the present invention.
[0132] Figure 33 is a front view of a vibrating sorting machine with a single sorting surface that has a set of pre-formed screens with a flattened selection surface installed on it, where the set of screens includes flattened subgrades and in pyramid format, according to an exemplary embodiment of the present invention.
[0133] Figure 34 is an isometric view of the end subgrade shown in Figure 3 that has a single mesh element partially attached to it, according to an exemplary embodiment of the present invention.
[0134] Figure 35 is an enlarged view of Section E divided from the end subgrade shown in Figure 34.
[0135] Figure 36 is an isometric view of a set of screens that have pyramid-shaped subgrades in a portion of the set of screens, according to an exemplary embodiment of the present invention.
[0136] Figure 37 is a flowchart of fabrication of a set of screens, according to an exemplary embodiment of the present invention.
[0137] Figure 38 is a flowchart of fabrication of a set of screens, according to an exemplary embodiment of the present invention.
[0138] Figure 39 is an isometric view of a vibrating selection machine that has a single set of screens with a flattened selection surface installed on it, with a portion of the cutout of the vibrating machine showing the set of screens, according to a exemplary embodiment of the present invention.
[0139] Figure 40 is an isometric top view of an individual screen element, according to an exemplary embodiment of the present invention.
[0140] Figure 40A is an isometric top view of a pyramid of screen element, according to an exemplary embodiment of the present invention.
[0141] Figure 40B is an isometric top view of four of the screen element pyramids shown in Figure 40A.
[0142] Figure 40C is an isometric top view of an inverted canvas element pyramid, according to an exemplary embodiment of the present invention.
[0143] Figure 40D is a front view of the screen element shown in Figure 40C.
[0144] Figure 40E is an isometric top view of a fabric element structure, according to an exemplary embodiment of the present invention.
[0145] Figure 40F is a front view of the screen element structure shown in Figure 40E.
[0146] Figures 41 to 43 are front cross-sectional views of screen elements, according to exemplary embodiments of the present invention.
[0147] Figure 44 is an isometric top view of a pre-selection structure with sets of pre-screens, according to an exemplary embodiment of the present invention.
[0148] Figure 44A is an isometric top view of the set of pre-screens shown in Figure 44, according to an exemplary embodiment of the present invention.
[0149] Figure 45 is a top view of a screen element above a portion of a subgrade, according to an exemplary embodiment of the present invention.
[0150] Figure 45A is an exploded side view of the cross section A-A showing the screen element above the subgrade portion of Figure 45.
[0151] Figure 45B is a cross-sectional side view A-A of the screen element and the portion of the subgrade of Figure 45, before attaching the screen element to the subgrade, according to an exemplary embodiment of the present invention.
[0152] Figure 45C is an enlarged view of section A of Figure 45B.
[0153] Figure 45D is a cross-sectional side view A-A of the screen element and the portion of the subgrade of Figure 45, after attaching the screen element to the subgrade, according to an exemplary embodiment of the present invention.
[0154] Figure 45E is an enlarged view of section B of Figure 45D.
[0155] Figure 46 is seen in lateral cross section of a portion of a screen element and a portion of a subgrade, according to an exemplary embodiment of the present invention.
[0156] Figure 47 is a top isometric view of a portion of a set of screens, according to an exemplary embodiment of the present invention.
[0157] Figure 48 is an isometric top view of a fabric element, according to an exemplary embodiment of the present invention.
[0158] Figure 48A is a top view of the screen element shown in Figure 48.
[0159] Figure 48B is a lower isometric view of the screen element shown in Figure 48.
[0160] Figure 48C is a bottom view of the screen element shown in Figure 48.
[0161] Figure 49 is a top isometric view of an end subgrade, according to an exemplary embodiment of the present invention.
[0162] Figure 49A is a lower isometric view of the end subgrade shown in Figure 49.
[0163] Figure 50 is a top isometric view of a central subgrade, according to an exemplary embodiment of the present invention.
[0164] Figure 50A is a lower isometric view of the central subgrade shown in Figure 50.
[0165] Figure 51 is an exploded isometric view of an end subgrade showing the screen elements, prior to attachment to the end subgrade, according to an exemplary embodiment of the present invention.
[0166] Figure 51A is an isometric view of the end subgrade shown in Figure 51 that has the screen elements attached to it.
[0167] Figure 52 is an exploded isometric view of a central subgrade showing the screen elements, prior to attachment to the central subgrade, according to an exemplary embodiment of the present invention.
[0168] Figure 52A is an isometric view of the central subgrade shown in Figure 52 that has the screen elements attached to it.
[0169] Figure 53 is a top isometric view of a pyramid-shaped end subgrade, according to an exemplary embodiment of the present invention.
[0170] Figure 53A is a lower isometric view of the pyramid-shaped end subgrade shown in Figure 53.
[0171] Figure 54 is a top isometric view of a central pyramid-shaped subgrade, according to an exemplary embodiment of the present invention.
[0172] Figure 54A is a lower isometric view of the central pyramid-shaped subgrade shown in Figure 54.
[0173] Figure 55 is an exploded isometric view of a pyramid-shaped end subgrade showing screen elements, prior to attachment to the pyramid-shaped end subgrade, in accordance with an exemplary embodiment of the present invention.
[0174] Figure 55A is an isometric view of the pyramid-shaped end subgrade shown in Figure 55, which has the screen elements attached to it.
[0175] Figure 56 is an exploded isometric view of a central pyramid-shaped subgrade showing the screen elements, prior to attachment to the central pyramid-shaped subgrade, according to an exemplary embodiment of the present invention.
[0176] Figure 56A is an isometric view of the central pyramidal subgrade shown in Figure 56, which has the screen elements attached to it.
[0177] Figure 57 is an isometric view of the end subgrade shown in Figure 50 that has a single mesh element partially attached to it, according to an exemplary embodiment of the present invention.
[0178] Figure 57A is an enlarged view of section A of the end subgrade shown in Figure 57. DETAILED DESCRIPTION
[0179] Similar reference characters denote similar parts in various drawings.
[0180] The modalities of the present invention provide a set of screens that includes injection molded screen elements that fit into a subgrade. The multiple subgrades are securely attached to each other to form the set of vibrating screens, which have a continuous selection surface and are configured for use on a vibrating selection machine. The entire screen assembly structure is configured to withstand the stringent loading conditions encountered when assembled and is operated on a vibrating sorting machine. Injection-molded screen elements provide many advantages in the fabrication of screen sets and vibrating selection applications. In certain embodiments of the present invention, the web elements are injection molded using a thermoplastic material. In certain embodiments of the present invention, the screen elements may have a first adhesion arrangement configured to fit with a second adhesion arrangement on a subgrade. The first and second bonding arrangements can include different materials and can be configured so that the screen elements can be fused to the subgrade by means of laser welding. The first adhesion arrangement can be a plurality of pocket cavities and the second adhesion arrangement can be a plurality of melting bars, which can be configured to melt when subjected to a laser. The screen elements can include a thermoplastic polyurethane, which can be based on polyester or based on polyether. The embodiments of the present invention include the screen elements attached to the subgrates by means of a hardened mixture of separate materials. The embodiments of the present invention include methods of fabricating a set of screens by fusing screen elements to the subgrades, by laser welding and attaching multiple subgrades together to form the screen set.
[0181] The embodiments of the present invention provide injection molded screen elements that are of a practical configuration and size for the manufacture of vibrating screen assemblies and for use in vibrating screening applications. Several important considerations have been taken into account when configuring individual screen elements. It is proposed that the screen elements: are of an ideal size (large enough for the efficient assembly of a complete structure of a set of screens, yet small enough to mold by injection (micro-molding, in certain modalities) extremely small structures that form the selection passages, while preventing freezing (ie, hardening of material in a mold, before completely filling the mold)); have an ideal open selection area (the structures that form the passages and that support the passages are of a minimum size to increase the general open area used to select, while maintaining, in certain modalities, very small selection passages necessary to properly separate the materials, in a specified pattern); have durability and resistance, can operate in a variety of temperature ranges; are chemically resistant; are structurally stable; are highly versatile in the fabric set fabrication processes; and are configurable in configurable configurations for specific applications.
[0182] The modalities of the present invention provide mesh elements that are manufactured using extremely precise injection molding. The larger the screen element, the easier it is to assemble a complete vibrating selection set. Simply put, the smaller pieces must be put together there. However, the larger the screen element, the more difficult it is to injection mold extremely small structures, that is, the structures that form the selection passages. It is important to minimize the size of the structures that make up the selection passes, in order to maximize the number of selection passes on an individual screen element and thereby improve the open selection area for the selection element and thus the general set of screens. In certain embodiments, it is proposed that the screen elements be large enough (for example, twenty-five millimeters (one inch) by twenty-five millimeters (one inch), twenty-five millimeters (one inch) by fifty-one millimeters (two inches), fifty-one millimeters (two inches) by seventy-six millimeters (three inches), etc.) to make it practical to assemble a complete screen set selection surface (for example, sixty-one centimeters (two feet) by ninety-two centimeters (three feet), ninety-two centimeters (three feet) percent and twenty-two centimeters (four feet), etc.). The relatively “small” size (for example, twenty-five millimeters (one inch) by twenty-five millimeters (one inch), twenty-five millimeters (one inch) by fifty-one millimeters (two inches), fifty-one one millimeter (two inches) by seventy-six millimeters (three inches), etc.) is very large when micro-molding extremely small structural members (for example, structural members as small as 43 microns). The larger the size of the general screen element and the smaller the size of the individual structural members that form the selection passages, the more error-prone is the injection molding process, such as freezing. Thus, the size of the screen elements needs to be practical for the fabrication of the screen set, while at the same time small enough to eliminate problems, such as freezing, when micro-molding the extremely small structures. Selection element sizes may vary, based on the material that is injection molded, the size of the required selection passages and the desired general open selection area.
[0183] The open selection area is a critical feature of sets of vibrating screens. The average usable open selection area (ie the actual open area after taking into account the structural steel of the support members and the bonding materials) for the 100 mesh to 200 mesh traditional wire mesh sets can be in the range 16%. The specific embodiments of the present invention (for example, selection sets with constructions described in this document and which have 100 mesh to 200 mesh screens) provide sets of screens in the same range that have similar real open selection areas. Traditional screens, however, clog very quickly in the field which results in the actual pass selection area, which is reduced very quickly. It is not uncommon for traditional metal screens to become clogged within the first 24 hours of use and have the actual open selection area reduced by 50%. Traditional wire sets also often fail, as a result of wires that are subjected to the vibratory forces that position the wire's bending loads. Injection-molded screen sets, in accordance with the modalities of the present invention, in contrast, do not undergo extensive obstruction (thereby maintaining a relatively constant real open selection area) and rarely fail, due to structural stability and the configuration of the set of screens, which includes the screen elements and the subgrade structures. In fact, the screen assemblies, according to the modalities of the present invention, have an extremely long useful life and can last for long periods of time, under heavy load. The screen sets, according to the present invention, have been tested for months, under strict conditions, without failure or obstruction, while the traditional wire sets have been tested under the same conditions and have clogged and failed within days. As more fully discussed in this document, traditional thermostable type assemblies could not be used in such applications.
[0184] In the embodiments of the present invention, a thermoplastic is used to injection mold the web elements. In contrast to polymers of the thermostable type, which often include liquid materials that react chemically and cure at low temperature, the use of thermoplastics is often simpler and can be provided, for example, by melting a homogeneous material (often in the form of solid pellets) and then by injection molding of the melted material. The physical properties of thermoplastics are not only ideal for vibrating selection applications, but the use of thermoplastic liquids provides easier manufacturing processes, especially when micro-molding the parts, as described in this document. The use of thermoplastic materials in the present invention provides excellent flexion and resistance to curvature fatigue and is ideal for parts subjected to intermittent heavy loading or constant heavy loading, as found in vibrating screens used in vibrating sorting machines. Due to the fact that vibrating sorting machines undergo movement, the low friction coefficient of injection molded thermoplastic materials provides optimal wear characteristics. Certainly, the wear resistance of certain thermoplastics is superior to many metals. In addition, the use of thermoplastics, as described in this document, provides an ideal material, as it produces “pressure adjustments,” due to its elongation and stiffness characteristics. The use of thermoplastics, in the embodiments of the present invention, also provides resistance to stress cracking, aging and extreme weather conditions. The thermal bending temperature of thermoplastics is in the range of 93 ° C (200 ° F). With the addition of glass fibers, it will increase to approximately 121 ° C (250 ° F) to approximately 149 ° C (300 ° F) or greater and increase the stiffness, as measured by the Flexural Module, from approximately 2,757.9 MPa (400,000 PSI) to more than approximately 6,894.7 MPa (1,000,000 PSI). All of these properties are ideal for the environment found, when using vibrating screens on vibrating selection machines, under the demand conditions found in the field.
[0185] The modalities of the present invention can incorporate various materials in subgrade units and / or in the screen elements, which depends on the desired properties of the modalities. Thermoplastic polyurethane (TPU) can be incorporated into the modalities of the present invention (for example, fabric elements), providing elasticity, transparency and resistance to oil, grease and abrasion. TPU also has high shear strength. These TPU properties are beneficial when applied to the modalities of the present invention, which are subjected to high vibrating forces, abrasive materials and high load demands. Different types of TPU can be incorporated into the modes, depending on the material that is selected. For example, polyester-based TPU can be incorporated into the screen sets used for oil and / or gas selection, due to the fact that esters provide abrasion resistance, oil resistance, mechanical integrity, resistance to chemicals and superior adhesion resistance. Polyether-based TPUs can be incorporated into mining applications, where resistance to hydrolysis (a property of ether-based TPUs) is important. Paraphenylene diisocyanate (PPDI) can be incorporated into the embodiments of the present invention. PPDI can provide high performance properties in a variety of screening applications. The materials for the embodiments of the present invention can be selected or determined based on a variety of factors, which include the performance properties of each material and the costs associated with using the materials.
[0186] In the embodiments of the present invention, the materials for a screen element can be selected to have high temperature tolerance, chemical resistance, hydrolytic resistance and / or abrasion resistance. The screen elements can incorporate materials, such as TPU, providing the screen elements with a transparent appearance. Transparent screen elements can allow efficient laser transmission through the screen elements for laser welding purposes. The subgrade materials can be different from the screen element material. In the embodiments of the present invention, the subgrades may be nylon. Subgrades can incorporate carbon or graphite. The different materials between the screen elements and the subgrades can be attached to each other by means of laser welding, which can provide much stronger adhesion between the screen elements and the subgrades than alternative attachment methods. The stronger attachment of the screen element to the subgrade provides improved performance of the screen sets when subjected to the high vibrating forces of vibrating sorting machines and the abrasive forces that occur on the surfaces of the screen elements during material selection.
[0187] Figure 1 illustrates a set of screens 10 for use with vibrating selection machines. The set of screens 10 is shown with multiple screen elements 16 (See, for example, Figures 2 and 2A to 2D) mounted on the subgrade structures. Subgrade structures include multiple independent end subgrade units 14 (See, for example, Figure 3) and multiple independent central subgrade units 18 (See, for example, Figure 4) that are fastened together to form a grid frame which has grid passages 50. Each screen element 16 covers four grid passages 50. Although screen element 16 is shown as a unit that covers four grid passages, the screen elements can be supplied in larger size units or smaller. For example, a screen element may be provided, which is approximately one quarter of the screen element size 16, so that it would cover a single grid passage 50. Alternatively, a screen element may be provided, which is approximately two times the screen element size 16, so that it would cover all eight passages of subgrade grid 14 or 18. Subgrades can also be supplied in different sizes. For example, subgrade units can be provided, which have two grid passes per unit, or a large subgrade can be provided for the overall structure, that is, a single subgrade structure for the entire set of screens. In Figure 1, the multiple independent subgrades 14 and 18 are attached together to form the screen set 10. The screen set 10 has a continuous screen set selection surface 11 that includes multiple screen element selection surfaces 13. Each screen element 16 is a single piece molded by thermoplastic injection.
[0188] Figure 1A is an enlarged view of a portion of the screen set 10 that has multiple end subgrades 14 and central subgrades 18. As discussed below, end subgrades 14 and central subgrades 18 can be fastened together to form the set of screens. The screen elements 16 are shown attached to the end subgrades 14 and the central subgrades 18. The size of the screen set can be changed by attaching more or less subgrades together to form the screen set. When installed on a vibrating sorting machine, the material can be fed to the screen set 10. See, for example, Figures 12, 12A, 12B, 13, 13A, 14 and 15. The material is smaller than the screen passes. of the screen element 16 passes through the passages in the selection element 16 and through the grid passages 50, thereby separating the material from that which is too large to pass through the screen passages of the screen elements 16.
[0189] Figure 1B shows a bottom view of the screen set 10, so that the grid passages 50 can be seen below the screen elements. Binder bars 12 are attached to the sides of the grid frame. The binder bars 12 can be attached to lock the subassemblies together, creating the grid frame. Binder bars 12 can include fasteners that attach to fasteners on side members 38 of subgrade units (14 and 18) or to fasteners on base member 64 of pyramidal subgrade units (58 and 60). Binder bars 12 can be provided to increase the stability of the grid frame and can distribute the compression loads if the set of screens is mounted on a vibrating sorting machine, using compression, for example, using sets of compression, as described in US Patent No. 7,578,394 and in US Patent Application No. 12 / 460,200. It is proposed that the binder bars may also include U-shaped members or tongue receiving openings, for subassembly or tensioning overassembly on a vibrating selection machine, for example, refer to the assembly structures described in US Patent No. 5,332. 101 and No. 6,669,027. The screen elements and the subgrades are securely tied together, as described in this document, so that, even under tension, the selection surface of the screen set and screen set maintains its structural integrity.
[0190] The set of screens shown in Figure 1 is slightly concave, that is, the upper and lower surfaces of the set of screens have a slight curvature. Subgrades 14 and 18 are manufactured so that when they are assembled together, this predetermined curvature is achieved. Alternatively, a set of screens can be flattened or convex (see, for example, Figures 19 and 20). As shown in Figures 12, 12A, 13 and 13A, the screen set 10 can be installed on a vibrating sorting machine that has one or more sorting surfaces. In one embodiment, the set of screens 10 can be installed on a vibrating selection machine by positioning the set of screens 10 on the vibrating selection machine, so that the binder bars come into contact with the end or side members of the vibrating selection machine. The compressive force is then applied to the binder bar 12. The binder bars 12 distribute the load of the compressive force to the set of screens. The set of screens 10 can be configured so that it flexes and deforms in a predetermined concave shape, when the compression force is applied to the binder bar 12. The amount of deformation and the range of concavity may vary, according to the use , the compression applied with force and the shape of the bed support of the vibrating selection machine. Compressing the set of screens 10 in a concave format, when installed in a vibrating sorting machine, provides many benefits, for example, installation and removal, capture and centralization of materials to be selected in a simple and easy way, etc. In addition, the benefits are listed in U.S. Patent No. 7,578,394. The centralization of material flows in the screen set 10 prevents the material from leaving the selection surface and potentially contaminating previously segregated materials and / or creating maintenance concerns. For larger volumes of material flow, the screen set 10 can be positioned at a higher compression, thereby increasing the amount of arc in the screen set 10. The larger amount of arc in the screen set 10 allows for retention capacity. greater material through the screen set 10 and preventing excessive material spillage outside the edges of the screen set 10. The screen set 10 can also be configured to deform in a convex shape, under compression or to remain substantially flat under compression or squeeze. Incorporating binder bars 12 into the screen set 10 allows a compression load from a vibrating sorting machine to be distributed through the screen set 10. The screen set 10 may include guide notches on the binder bars 12 to assist to guide the set of screens 10 into place, when installed on a vibrating selection machine that has guides. Alternatively, the set of screens can be installed on a vibrating selection machine, without bonding bars 12. In the alternative mode, the guide notches can be included in the subgrade units. U.S. Patent Application No. 12 / 460,200 is hereby incorporated by reference and any embodiments disclosed therein may be incorporated into the embodiments of the present invention described herein.
[0191] Figure 2 shows a screen element 16 having substantially parallel screen element end portions 20 and substantially parallel screen element side portions 22 which are substantially perpendicular to the screen element end portions 20. The surface Screen element selection panel 13 includes surface elements 84 that extend parallel to the screen element end portions 20 and that form selection passes 86. See Figure 2D. The surface elements 84 have a thickness T, which can vary, depending on the selection application and the configuration of the selection passages 86. T can be, for example, approximately 43 microns to approximately 100 microns, depending on the desired open selection area and the width W of selection passages 86. Selection passages 86 are elongated slots having a length L and a width W, which can be varied for a chosen configuration. The width can be a distance of approximately 43 microns to approximately 2,000 microns between the inner surfaces of each screen surface element 84. Selection passages are not required to be rectangular, but can be injection molded with thermoplastic in any suitable format for a particular selection application, which includes approximately square, circular and / or oval. For increased stability, the web surface elements 84 can include integral fiber materials that can extend substantially parallel to the end portions 20. The fiber can be an aramid fiber (or its individual filaments), a fiber of naturally occurring or other material that has a relatively high tensile strength. U.S. Patent No. 4,819,809 and U.S. Patent Application No. 12 / 763,046 are hereby incorporated by reference and, as appropriate, the embodiments disclosed therein may be incorporated into the sets of fabrics disclosed herein.
[0192] The screen element 16 can include attachment openings 24 configured so that the elongated attachment members 44 of a subgrade can pass through the attachment openings 24. Attachment openings 24 can include a tapered hole that can be filled when a portion of the elongated attachment member 44 above the selection element selection surface is melted, securing the canvas element 16 to the subgrade. Alternatively, the attachment openings 24 can be configured without a tapered bore that allows the formation of a bead on the selection element selection surface, when a portion of an elongated attachment member 44 above a selection element selection surface melted, fixing the screen element to the subgrade. The screen element 16 can be a single piece molded by thermoplastic injection. The screen element 16 can also be multiple thermoplastic injection molded parts, each of which is configured to cover one or more grid passages. The use of small thermoplastic injection molded fabric elements 16, which are attached to a grid frame, as described in this document, provides substantial advantages over previous fabric sets. Thermoplastic injection molding screen elements 16 allow selection passages 86 to have widths W as small as approximately 43 microns. This allows for accurate and effective selection. The arrangement of the screen elements 16 in subgrades, which can also be injection molded with thermoplastic, allows for easy construction of complete screen sets with very fine selection passages. The arrangement of screen elements 16 in subgrades also allows for substantial variations in the overall size and / or configuration of the screen set 10, which can be varied by including more or less subgrades or subgrades that have different shapes. In addition, a set of screens can be constructed with a variety of selection pass sizes or a gradient of selection pass sizes simply by incorporating screen elements 16 with different sized selection passages in subgrades and through of joining the subgrades in the desired configuration.
[0193] Figure 2B and Figure 2C show a bottom of the web element 16 that has a first web element support member 28 that extends between the end portions 20 and which is substantially perpendicular to the end portions 20. Figure 2B also shows a second web element support member 30 orthogonal to the first web element support member 28 which extends between the side edge portions 22, which is approximately parallel to the end portions 20 and substantially perpendicular to the side portions 22. The web element may additionally include a first series of reinforcement members 32 substantially parallel to the side edge portions 22 and a second series of reinforcement members 34 substantially parallel to the end portions 20. The end portions 20, the side edge portions 22, the first web element support member 28, the second web element support member 3 0, the first series of reinforcement members 32 and the second series of reinforcement members 34 structurally stabilize the web surface elements 84 and selection passages 86 during different loads, which includes the distribution of a compressive force and / or vibratory loading conditions.
[0194] Figure 3 and Figure 3A illustrate an end subgrade unit 14. The end subgrade unit 14 includes parallel subgrade end members 36 and parallel subgrade side members 38, substantially perpendicular to the subgrade end members 36. The end subgrade unit 14 has fasteners along a subgrade end member 36 and along the side subgrade members 38. The fasteners can be clamps 42 and clamp openings 40, so that multiple subgrade units 14 can be securely tied together. The subgrade units can be fastened together along their respective side members 38 through the passage of the clamp 42 to the clamp opening 40, until the extended members of the clamp 42 extend beyond the clamp opening 40 and the side member subgrade 38. Since the clamp 42 is driven into the clamp opening 40, the extended clamp members will be forced together, until a stapling portion of each extended member is beyond the subgrade side member 38, allowing the portions stapling members engage with an inner portion of the subgrade side member 38. When the staple portions are engaged with the staple opening, the subgrade side members of two independent subgrades will be side by side and secured together. The subgrades can be separated by applying force to the extended staple members, so that the extended members move together, allowing the stapling portions to pass outside the staple opening. Alternatively, clamps 42 and clamp openings 40 can be used to secure the subgrade end member 36 to a subgrade end member of another subgrade, such as a central subgrade (Figure 4). The end subgrade can have a subgrade end member 36 that does not have any fasteners. Although the fasteners shown in the drawings are staples and staple openings, alternative fasteners and alternative forms of staples and openings can be used, which include other mechanical arrangements, adhesives, etc.
[0195] The construction of the grid frame, from subgrades, which can be substantially rigid, creates a strong and durable grid frame and screen set 10. Screen set 10 is constructed so that it can withstand heavy loading without damage to the selection surface and the support structure. For example, the pyramid-shaped grid frames shown in Figures 22 and 23 provide a very strong pyramid-based frame that supports individual screen elements with very fine selection capability, which has selection passes as small as 43 microns. Unlike the pyramidal screen set modality of the present invention described in this document, existing pyramid or striated wire mesh screen sets are highly susceptible to damage and / or deformation under heavy loading. Thus, unlike today's screens, the present invention provides sets of screens that have very small and very accurate selection passages, while simultaneously providing substantial structural stability and resistance to damage, thereby maintaining the selection accurately under a variety of boundaries of cargo. The construction of the grid frame from sub-grids also allows for substantial variation in the size, shape and / or configuration of the set of screens, simply by changing the number and / or type of sub-grids used to build the grid frame.
[0196] The end subgrade unit 14 includes a first subgrade support member 46 that extends parallel to the subgrade side members 38 and a second subgrade support member 48 orthogonal to the first subgrade support member 46 and perpendicular to the subgrade side members 38. The elongated attachment members 44 can be configured so that they fit with the screen element attachment openings 24. The screen element 16 can be attached to the subgrade 14 by connecting the members of elongated attachment 44 with the web element attachment openings 24. An elongated attachment member portion 44 may extend slightly above the web element selection surface when the web element 16 is attached to the end subgrade 14. The web element attachment openings 24 may include a tapered bore, so that a portion of the elongated attachment members 44 extends above the surface Screen element selection surface can be melted and fill the tapered hole. Alternatively, the web element attachment openings 24 may be without a tapered hole, and the portion of the elongated attachment members that extends above the selection surface of the selection element 16 can be configured to form a bead on the selection surface. , when melted. See Figures 34 and 35. Once attached, the screen element 16 will cover at least one grid passage 50. The materials that pass through the selection passages 86 will pass through the grid passage 50. The disposition of members of elongated attachments 44 and the corresponding arrangement of screen element attachment openings 24 provide a guide for attaching screen elements 16 to subgrades, simplifying the assembly of subgrades. The elongated attachment members 44 pass through the screen element attachment openings 24, guiding the screen element in the correct positioning on the subgrade surface. Attachment by means of elongated attachment members 44 and the screen element attachment openings 24 additionally provides secure attachment to the subgrade and reinforces the selection surface of the screen set 10.
[0197] Figure 4 shows a central subgrade 18. As shown in Figure 1 and Figure 1A, the central subgrade 18 can be incorporated into a set of screens. The central subgrade 18 has clamps 42 and clamp openings 40 on both subgrade end members 36. The end subgrade 14 has clamps 42 and clamp openings 40 on only one of the subgrade end members 36. The central subgrades 18 they can be attached to the other subgrades in each of their subgrade end members and subgrade side members.
[0198] Figure 5 shows a top view of the binder bar 12. Figure 5A shows a bottom view of the binder bar 12. The binder bars 12 include staples 42 and staple openings 40, so that the binder bar 12 can be stapled to one side of a set of screen panels (see Figure 9). Like the subgrades, the fasteners on the binder bar 12 are shown as staples and staple openings, but other fasteners can be used to engage the subgrid fasteners. The handles can be attached to the bonding bars 12 (see, for example, Figure 7), which can simplify the transport and installation of a set of screens. The tags and / or labels can also be attached to the bonding bars. As discussed above, the binder bars 12 can increase the stability of the grid frame and can distribute the compression loads of a vibrating sorting machine, if the set of screens is positioned under compression, as shown in US Patent No. 7,578,394 and in US Patent Application No. 12 / 460,200.
[0199] Selection members, selection sets and their parts, which include fasteners / connection members, as described in this document, may include the nanomaterial dispersed in them for improved strength, durability and other benefits associated with the use of a particular nanomaterial or a combination of different nanomaterials. Any suitable nanomaterial can be used, which includes, but is not limited to, nanotubes, nanofibers and / or elastomeric nanocomposites. The nanomaterial can be dispersed in the selection members and selection sets and their parts in varying percentages, depending on the desired properties of the end product. For example, specific percentages can be incorporated to increase limb strength or to make a selection surface resistant to wear. The use of a thermoplastic injection molded material that has nanomaterials dispersed in it can provide increased strength while using less material. Thus, the structural members include subgrade frame supports, and the screen element support members can become smaller and stronger and / or lighter. This is particularly beneficial when manufacturing relatively small individual components that are built into a complete set of screens. In addition, in contrast to producing individual subgrades that clamp together, a large grid structure that has nanomaterials dispersed in it can be manufactured, which is relatively light and strong. The individual screen elements, with or without nanomaterials, can then be attached to the single complete grid frame structure. The use of nanomaterials in a screen element will provide increased resistance, while reducing the weight and size of the element. This can be especially useful when the injection molding screen elements have extremely small passages, since the passages are supported by the surrounding materials / members. Another advantage of incorporating nanomaterials into the screen elements is an improved selection surface that is durable and wear-resistant. Screen surfaces tend to wear out through heavy use and exposure to abrasive materials, and the use of a thermoplastic and / or a thermoplastic that has abrasive resistant nanomaterials provides a selection surface with a long service life.
[0200] Figure 6 shows a subset 15 of a row of subgrade units. Figure 6A is an exploded view of the subset in Figure 6 showing the individual subgrades and the direction of attachment to each other. The subset includes two end subgrade units 14 and three central subgrade units 18. The end subgrade units 14 form the ends of the subset, while the central subgrade units 18 are used to join the two end subgrade units 14 through connections between clamps 42 and clamp openings 40. The subgrade units shown in Figure 6 are shown with screen elements attached 16. By fabricating the set of screens from subgrades and to the subassembly, each subgrade can be built to a chosen specification, and the set of screens can be built from multiple subgrades, in a configuration required for the selection application. The screen set can be quickly and simply assembled and will have specific selection capabilities and substantial stability under load pressures. Due to the structure configuration of the grid frame and screen elements 16, the configuration of multiple individual screen elements that form the selection surface of the screen set 10 and the fact that the screen elements 16 are injection molded with thermoplastic , the passages in screen elements 16 are relatively stable and maintain their pass sizes for optimal selection under various loading conditions, which include compression loads and concavity and tensioning flexions.
[0201] Figure 7 shows a set of screens 10 with bonding bars 12 that have handles attached to the bonding bars 12. The set of screens is made up of multiple subgrade units attached to each other. The subgrade units have screen elements 16 attached to their upper surfaces. Figure 7A is a cross section of Section A-A of Figure 7 that shows individual subgrades attached to the screen elements that form a selection surface. As reflected in Figure 7A, subgrades may have subgrade support members 48 configured so that the screen set has a slightly concave shape, when the subgrade support members 48 are attached to each other, using clamps 42 and clip openings 40. Due to the fact that the set of screens is constructed with a slightly concave shape, it can be configured to deform in a desired concavity, under the application of a compression load, without having to guide the set of screens in a concave format. Alternatively, the subgrades can be configured to create a set of slightly convex screens or a set of substantially flat screens.
[0202] Figure 8 is a top isometric view of a set of screens partially covered with screen elements 16. This Figure shows the end subgrade units 14 and the central subgrade units 18 attached to form a set of screens. The selection surface can be completed by attaching screen elements 16 to the uncovered subgrade units shown in the Figure. The screen elements 16 can be attached to the individual subgrades, prior to the construction of the grid frame, or attached to the subgrades, after the subgrades have been attached to each other in the grid frame.
[0203] Figure 9 is an exploded isometric view of the set of screens shown in Figure 1. This Figure shows eleven subsets that are attached to each other by means of clamps and clamp openings along subgrade end members of drive units. subgrade in each subset. Each subset has two end subgrade units 14 and three central subgrade units 18. Binder bars 12 are stapled to each side of the assembly. Sets of screens of different sizes can be created using different amounts of subsets or different amounts of central subgrade units in each subset. An assembled screen set has a continuous screen set selection surface made of multiple screen element selection surfaces.
[0204] Figures 10 and 10A illustrate the attachment of screen elements 16 to the end subgrade unit 14, according to an exemplary embodiment of the present invention. The web elements 16 can be aligned with the end subgrade unit 14 by means of the elongated attachment members 44 and the web element attachment openings 24, so that the elongated attachment members 44 pass through the attachment openings. screen element 24 and extend slightly beyond the screen element selection surface. The elongated attachment members 44 can be melted to fill the tapered holes of the web element attachment openings 24 or, alternatively, to form granules under the web element selection surface, securing the web element 16 to the subgrade unit 14. Attachment by means of elongated attachment members 44 and mesh element attachment openings 24 is only one embodiment of the present invention. Alternatively, the screen element 16 can be attached to the end subgrade unit 14 by means of adhesive, fasteners and fastener openings, laser welding, etc. Although shown to have two screen elements for each subgrade, the present invention includes alternative configurations of one screen element per subgrade, multiple screen elements per subgrade, one screen element per subgrade, or that has a single screen element to cover multiple subgrades. The end subgrade 14 can be substantially rigid and can be formed as a single piece molded by thermoplastic injection.
[0205] Figure 10B is a top view of the end subgrade unit shown in Figure 10A with screen elements 16 attached to the end subgrade. Figure 10C is an enlarged cross section of Section B-B of the end subgrade unit in Figure 10B. The screen element 16 is positioned on the end subgrade unit, so that the elongated attachment member 44 passes through the attachment opening and beyond a screen element selection surface. The portion of the elongated attachment member 44 that passes through the attachment opening and beyond the screen element selection surface can be melted to attach the screen element 16 to the end subgrade unit, as described above.
[0206] Figure 11 and Figure 11A illustrate the attachment of screen elements 16 to the central subgrade unit 18, according to an exemplary embodiment of the present invention. The screen elements 16 can be aligned with the central subgrade unit 18 by means of the elongated attachment members 44 and the screen element attachment openings 24, so that the elongated attachment members 44 pass through the attachment attachments of screen element 24 and extend slightly beyond the screen element selection surface. The elongated attachment members 44 can be melted to fill the tapered holes of the web element attachment openings 24 or, alternatively, to form granules under the web element selection surface, securing the web element 16 to the subgrade unit central 18. Attachment by means of elongated attachment members 44 and mesh element attachment openings 24 is only one embodiment of the present invention. Alternatively, the screen element 16 can be attached to the central subgrade unit 14 by means of adhesive, fasteners and fastener openings, etc. Although shown with two screen elements for each subgrade, the present invention includes alternative configurations of one screen element per subgrade, one screen element per subgrade, multiple screen elements per subgrade, or with a single screen element covering multiple subgrade units. The central subgrade unit 18 can be substantially rigid and can be a single piece molded by thermoplastic injection.
[0207] Figures 12 and 12A show sets of screens 10 installed on a vibrating selection machine that has two selection surfaces. The vibrating sorting machine may have compression assemblies on the side members of the vibrating sorting machine, as shown in U.S. Patent No. 7,578,394. A compressive force can be applied to a binder bar or to a lateral member of the screen set, so that the screen set flexes downwards, in a concave shape. A bottom side of the screen assembly may engage with a screen assembly interlocking surface of the vibrating selection machine, as shown in U.S. Patent No. 7,578,394 and U.S. Patent Application No. 12 / 460,200. The vibrating selection machine may include a central wall member configured to receive a binder from a side member of the screen set opposite to the side member of the screen set receiving compression. The central wall member can be angled so that a compressive force against the screen assembly flexes the screen assembly downwards. The set of screens can be installed on the vibrating selection machine, so that it is configured to receive material to select. The screen set can include guide notches configured to fit with the guides of the vibrating selection machine, so that the screen set can be guided to position itself during installation and can include the guide set settings, as shown in Patent Application No. US 12 / 460,200.
[0208] Figure 12B is a front view of the vibrating selection machine shown in Figure 12. Figure 12B shows sets of screens 10 installed on the vibrating selection machine with compression applied to flex the sets of screens down, in a format concave. Alternatively, the set of screens can be preformed in a predetermined concave shape, without compression force.
[0209] Figures 13 and 13A show screen assembly installations 10 on a vibrating sorting machine that has a single sorting surface. The vibrating sorting machine may have a compression assembly on a side member of the vibrating sorting machine. The set of screens 10 can be positioned on the vibrating selection machine, as shown. A compressive force can be applied to a binder bar or a lateral member of the screen set, so that the screen set flexes downwards, in a concave shape. A bottom side of the screen assembly may engage with a screen assembly interlocking surface of the vibrating selection machine, as shown in U.S. Patent No. 7,578,394 and U.S. Patent Application No. 12 / 460,200. The vibrating sorting machine may include an opposite side member wall of the compression set configured to receive a binder bar or a side member of the screen set. The side member wall can be angled so that a compressive force against the screen assembly flexes the screen assembly downwards. The set of screens can be installed on the vibrating selection machine, so that it is configured to receive material to select. The screen set may include guide notches configured to fit with the guides of the vibrating selection machine, so that the screen set can be guided to position itself during installation.
[0210] Figure 14 is a front view of sets of screens 52 installed on a vibrating selection machine that has two selection surfaces, according to an exemplary embodiment of the present invention. The set of screens 52 is an alternative modality in which the set of screens was pre-formed to fit the vibrating selection machine, without applying a load to the set of screens, that is, the set of screens 52 includes a lower portion 52A that is formed, so that it fits with a bed 83 of the vibrating selection machine. The lower portion 52A can be formed integrally with the screen assembly 52 or, perhaps a separate part. Screen set 52 includes similar features, such as screen set 10, which includes subgrades and screen elements, but also includes a lower portion 52A that allows it to fit into bed 83, without being compressed into a concave shape. A screen set selection surface 52 can be substantially flattened, concave or convex. The screen assembly 52 can be held in place by applying a compressive force to a lateral screen assembly member 52. A lower screen assembly portion 52 can be preformed to fit any type of surface of a vibrating selection machine.
[0211] Figure 15 is a front view of a set of screens 53 installed on a vibrating selection machine that has a single selection surface, according to an exemplary embodiment of the present invention. The screen set 53 has similar features to the screen set 52 described above, which includes a lower portion 53A that is formed so that it fits with a bed 87 of the vibrating selection machine.
[0212] Figure 16 shows a subset of end support frame and Figure 16A shows an exploded view of the subset of end support frame shown in Figure 16. The subset of end support frame shown in Figure 16 incorporates eleven end subgrade units 14. Alternative configurations that have more or less end subgrade units can be used. The end subgrade units 14 are secured to each other, via clamps 42 and clamp openings 40, along the side members of the end subgrade units 14. Figure 16A shows the attachment of individual end subgrade units , so that the end support frame subset is created. As shown, the subset of the end support frame is covered in the screen elements 16. Alternatively, the subset of the end support frame can be constructed from end subgrades, prior to attaching the screen elements, or partially to from pre-covered subgrade units and partially from non-covered subgrade units.
[0213] Figure 17 shows a central support frame set, and Figure 17A shows an exploded view of the central support frame subset shown in Figure 17. The central support frame set shown in Figure 17 incorporates eleven units of central subgrade 18. Alternative configurations that have more or less central subgrade units can be used. The central subgrade units 18 are attached to each other, by means of clamps 42 and clamp openings 40, along side members of the central subgrade units 18. Figure 17A shows the attachment of individual central subgrade units, so the subset of the central support frame is created. As shown, the subset of the central support frame is covered in the screen elements 16. Alternatively, the subset of the central support frame can be constructed from central subgrades, before attaching the screen elements or partially from units of screen. pre-covered subgrade and partially from non-covered subgrade units.
[0214] Figure 18 shows an exploded view of a screen set that has three central support frame subsets and two end support frame subsets. The support frame assemblies are attached to each other by means of the clamps 42 and clamp openings 40 in the subgrade end members. Each central subgrade unit is attached to two other subgrade units, by means of end members. The end members 36 of end subgrade units that do not have clamps 42 or clamp openings 40 form the end edges of the screen assembly. The set of screens can be made with more or less subsets of central support frames or subsets of larger or smaller frames. Binder bars can be added to the side edges of the screen set. As shown, the set of screens has screen elements installed over the subgrade units, before the set. Alternatively, the screen elements 16 can be installed after all or a portion of the assembly.
[0215] Figure 19 illustrates an alternative embodiment of the present disclosure, in which the set of screens 54 is substantially flat. The screen assembly 54 can be flexible, so that it can be deformed into a concave or convex shape or can be substantially rigid. Screen set 54 can be used with a flattened selection surface. See Figure 39. As shown, the screen set 54 has binder bars 12 attached to the side portions of the screen set 54. The screen set 54 can be configured with the various modalities of the grid structures and the screen elements described in this document.
[0216] Figure 20 illustrates an alternative embodiment of the present disclosure, in which the set of screens 56 is convex. The set of screens 56 can be flexible, so that it can be deformed into a more convex shape or can be substantially rigid. As shown, the screen assembly 56 has binder bars 12 attached to the side portions of the screen assembly. The set of screens 56 can be configured with the various modalities of the grid structures and the screen elements described in this document.
[0217] In alternative embodiments of the present disclosure, the screen set 410 is provided with screen elements 416, central subgrade units 418 and end subgrade units 414. See, for example, Figure 47. The screen element 416 it can be molded by thermoplastic injection and can include all of the screen element 16 features provided above. Screen element 416 can be incorporated into any of the screen sets disclosed in this document (for example, 10 and 52 to 54) and is interchangeable with screen element 16. Screen element 416 can include location openings 424, which can be located in a screen element center 416 and each one of the four corners of the screen element 416. See, for example, Figures 48 and 48A. More or less location openings 424 can be provided in the screen element 416 and multiple configurations can be provided. Location openings 424 can be substantially the same as attachment openings 24 and can be used to locate screen element 416 on a subgrade. Alternatively, the web element 416 can be located without locating openings 424. The web element 416 can include a plurality of tapered recessed holes 470, which can facilitate the extraction of web element 416 from a mold, where the mold can have injection pins configured to propel the screen element out of the mold. See, for example, Figures 48 and 48A.
[0218] On a bottom side of screen element 416, a first adhesion arrangement can be incorporated, which can be a plurality of extensions, cavities or a combination of extensions and cavities. The first screen element bonding arrangement 416 can be configured to fit with a second complementary bonding arrangement on an upper surface of a subgrade unit. For example, in Figures 48B and 48C, a plurality of cavity pockets 472 are provided. The plurality of cavity pockets 472 can be arranged along end portions 20 and side portions 22 between the location openings 424. Additional cavity pockets 272 can be arranged along all or a portion of the first member of member support web 28 and along all or a portion of the second web member support member 30. Although shown as elongated cavities, cavity pockets 472 can have a variety of configurations, sizes and depths. Furthermore, the first adhesion arrangement on the web element 416 can be extensions, rather than cavities. The first screen element adhesion arrangement 416 can be configured to fit with a second complementary adhesion arrangement on a subgrade unit, so that a portion of screen element 416 overlaps at least a portion of the subgrade unit, regardless whether the screen element 416 or the subgrade unit has extensions or cavities.
[0219] The end subgrade unit 414 and the central subgrade unit 418 can be incorporated into the set of screens 410. See, for example, Figures 49, 49A, 50 and 50A. End subgrade unit 414 and central subgrade unit 418 can be thermoplastic injection molded and can include all of the features of end subgrade unit 14 and central subgrade unit 18 discussed above. The end subgrade unit 414 and the central subgrade unit 418 can be used interchangeably whenever the end subgrade unit 14 and the central subgrade unit 18 are indicated. The end subgrade unit 414 and the central subgrade unit 418 can have a plurality of elongated location members 444, which can be substantially the same as attachment annexes 44. The location member arrangement 444 can correspond to the location openings 424 of screen elements 416, so that screen elements 416 can be located in the end subgrade unit 414 and in the central subgrade unit 418 for attachment.
[0220] The end subgrade unit 414 and the central subgrade unit 418 may include a second adhesion arrangement on an upper surface of each of the end subgrade unit 414 and the central subgrade unit 418, wherein the The second adhesion arrangement can be complementary to the first adhesion arrangement of screen element 416, so that the screen element can fit to a subgrade unit by engaging the first and second adhesion arrangements. In one embodiment of the present invention, the second adhesion arrangement can be a plurality of melting bars 476 arranged along an upper surface of subgrade side members 38 and subgrade end members 36. The end subgrade unit 414 and the central subgrade unit 418 may also include a plurality of melting bars 478, which may be shortened melting bars having heights less than the heights of melting bars 476, arranged along an upper surface of the first member of subgrade support 46 and second subgrade support member 48. See, for example, Figures 49 to 50A. Although shown as elongated extensions, the 476 (and 478) fusion bars can be of various shapes and sizes and can be arranged in a variety of configurations. Alternatively, the second adhesion arrangement can be cavities, pockets or the like and can be configured to receive extensions of a screen element. The second adhesion arrangement could include both the extensions and the cavities.
[0221] Each of the plurality of cavity pockets 472 is configured to receive melting bars 476 and shortened melting bars 478 arranged in subgrades (414, 418, 458 and 460). See, for example, Figures 45A to 45E and 46. As shown in Figures 45B to 45E, the melting bars 476 fit within the plurality of cavity pockets 472, when the screen element 416 is positioned on a subgrade. The cavity pockets 472 may have a width C that is slightly greater than the width D of the melting bar 476. The cavity pocket 472 may have a depth A that is slightly less than a height B of the melting bar 476. See, for example, Figure 47. The height B of the melt bar 476 can be approximately 1.42 millimeters (0.056 inches). Before melting the melting bars 476, the screen element 416 can rest on the melting bars 476, without coming into contact with the rest of a subgrade. The screen element 416 and the subgrades can be connected together by means of laser welding. The connection can be made through a chemical connection between the cavity pockets 472 and the melting bars (476 or 478) or through the melting portions of the materials of each component, so that the components harden together. In one embodiment, when the screen element 416 is located on a subgrade, the melting bar 476 (or the shortened melting bar 478) can be melted, allowing a melted portion of the melting bar 476 to fill all or a portion of width C of cavity pocket 472. In certain embodiments, approximately 0.15 millimeters (0.006 inches) of melt bar 476 can be melted and allowed to fill all or a portion of cavity pocket width 472. Melting of the fusion bar 476 can be carried out by means of laser welding, which can attach the screen element 416 to a subgrade. A 500 laser can be configured and controlled to achieve a specific 476 melting bar depth.
[0222] 476 melting bars (or shortened melting bars 478) may include carbon, graphite or other materials configured to respond to a specific laser wavelength. Melting bars can be additionally configured to match a laser to be used for laser welding. The fusion bars can have specific lengths to match a 500 laser. Although shown as elongated protuberances, other shapes and / or designs can be incorporated into the fusion bars subjected to the requirements of a chosen laser. In embodiments having sub-grid melting bars, screen elements 416 typically do not include carbon or graphite. The screen element 416 and the melting bars can be made of different materials, so that a selected laser 500 can travel along the screen element 416, without melting the screen element 416, and come into contact with the screen bars. Fusion. See, for example, Figures 45B and C. The screen element 416 can be made of a TPU or similar material that has the desired performance properties for a selection application. The screen element 416 can be substantially transparent. The subgrades (414 and 418) can be made of nylon or similar materials. The melting bars can have a higher melting point than the screen element material 416, so that when the melting bars are melted, a portion of the screen element 416 also melts, which can be done by heat transfer from the melted portion of the melting bar 476 that comes into contact with the screen element 416 in the cavity pocket 472. In this way, screen element 416 is welded on a subgrade. See, for example, Figures 51, 51A, 52 and 52A.
[0223] Laser welding is typically performed by focusing a laser beam towards a seam or area to transform the material from a solid state to a liquid state and, after removal of the laser beam, the material return to a solid state. Laser welding is a type of fusion welding and can be carried out through conduction or penetration. Conduction welding relies on the conductivity of the material that is welded to generate heat and melt the material. Laser welding of screen element 416 for a subgrade that has melting bars provides laser welding of two different materials together. Typically, this cannot be done with laser welding; however, the application of laser 500, through the screen element 416, to the melting bars, which have conductive properties to generate heat, under the application of the selected laser 500, causes the melting bars (476 or 478) to melt . Similarly, the heat produced by conduction and / or from the melted melt bar material causes a portion of the screen element to melt. The two liquid materials combine and create a strong solid attachment between the subgrade and the screen element, when the laser is removed and the combined materials return to a solid state. Through the formation of laser weld connections between the screen element and the sub-grids, the attachment between the components is very strong, which is essential for the components of the screen sets used in the vibrating sorting machines. The screen sets can be subjected to vibratory forces in excess of 8 Gs, abrasive materials and chemicals and to very high load requirements. So, the screen sets need to be very strong and durable. The embodiments of the present invention provide sets of screens made of multiple parts held together. The creation of sets of screens, from smaller subparts, allows micro-molding by injection of screen elements with very small passages, for example, which have a thickness of approximately 43 microns to approximately 100 microns. The resistance of laser welding adds general resistance to the screen sets, allowing the benefits of micro-injection molding of the screen elements, while keeping the screen sets durable. Laser welding also provides a more efficient attachment procedure than other attachment procedures, such as thermal staking. In certain modalities, laser welding can be carried out in approximately 8 to 10 seconds, in which thermal staking involving other modalities may require approximately 1.5 minutes.
[0224] The end subgrade unit 414 (or 14) and the central subgrade unit 418 (or 18) can include the secondary support frame 488 which it covers through grid passages 50. The secondary support frame 488 can cover all or just a portion of a grid passage 50. Secondary support frame 488 increases the strength and durability of end subgrade unit 414 (or 14) and central subgrade unit 418 (or 18). The secondary support frame 488 increases the overall resistance of the display set 410, allowing it to withstand vibratory forces in excess of 8 Gs.
[0225] Figures 21 and 21A show an alternative embodiment of the present disclosure that incorporates pyramid-shaped subgrade units. A set of screens is shown with bonded bars 12 attached. The set of screens incorporates the edge and central subgrade units 14 and 18 (or 414 and 418) and subgrade units in the pyramidal shape of the end and central 58 and 60 (or 458 and 460). Through the incorporation of the subgrade units in pyramidal format 58 and 60 in the set of screens, an increased selection surface can be achieved. In addition, the material that is selected can be controlled and directed. The set of screens can be concave, convex or flat. The set of screens can be flexible and can be deformed into a concave or convex shape, under the application of a compressive force. The screen set may include guide notches capable of connecting to the guide connection surfaces on a vibrating sorting machine. Different configurations of subgrade units and pyramid subgrade units can be employed, which can increase or decrease an amount of selection surface area and flow characteristics of the material being processed. Unlike mesh screens or similar technology, which can incorporate grooves or other manipulations to increase the surface area, the set of screens shown is supported by the grid frame, which can be substantially rigid and able to withstand substantial loads without damage or destruction. Under heavy material flows, traditional screen sets, with striated selection surfaces, are often flattened or damaged by the weight of the material, thereby impacting performance and reducing the selection surface area of such screen sets. The screen sets disclosed in this document are difficult to damage due to the strength of the grid frame, and the benefits of increased surface area provided by incorporating pyramid-shaped sub-grids can be maintained under substantial loads.
[0226] An end subgrade in a pyramid shape 58 is illustrated in Figure 22 and Figure 22A. The pyramid-shaped end subgrade 58 includes a first and a second grid frame that form the first and second inclined surface grid passages 74. The pyramid-shaped end subgrade 58 includes a ridge portion 66, side members of subgrade / base members 64 and the first and second angled surfaces 70 and 72, respectively, which peak at the peak portion 66 and extend down to the side member 64. The pyramidal shaped subgrades 58 and 60 have triangular end members 62 and triangular intermediate support members 76. The angles shown for the first and second angular surfaces 70 and 72 are exemplary only. Different angles can be used to increase or decrease the selection surface area. The pyramid-shaped end subgrade 58 has fasteners along side members 64 and at least one triangle end member 62. The fasteners can be staples 42 and staple openings 40, so that multiple subgrade units 58 can be stuck together. Alternatively, clamps 42 and clamp openings 40 can be used to attach the pyramid-shaped end subgrade 58 to the end subgrade 14, to the central subgrade 18 or to the central pyramid-shaped subgrade 60. The elongated attachment members 44 can be configured on the first and second inclined surfaces 70 and 72, so that they fit with the screen element attachment openings 24. The screen element 16 can be attached to the pyramid-shaped end subgrade 58 by means of plug-in elongated attachment members 44 with the screen element attachment openings 24. A portion of the elongated attachment member 44 may extend slightly above the screen element selection surface when the screen element 16 is attached to the subgrade pyramid-shaped end piece 58. The web element attachment openings 24 may include a tapered bore, so that a portion of the elongated attachment members 44 nde above the screen element selection surface can be melted and fill the tapered hole. Alternatively, the web element attachment openings 24 can be without a tapered hole, and the portion of the elongated attachment members that extends above the selection surface of the selection element 16 can be melted to form a bead on the selection surface. . Once attached, the web element 16 can span the first and second inclined grid passages 74. The materials that pass through the selection passages 86 will pass through the first and second grid passages 74.
[0227] A central subgrade in the shape of a pyramid 60 is illustrated in Figure 23 and Figure 23A. The central pyramid-shaped subgrade 60 includes a first and a second grid frame that forms a first and a second sloped-surface grid passage 74. The central pyramid-shaped subgrade 60 includes a ridge portion 66, side members of the subgrade / base members 64 and the first and second angled surfaces 70 and 72 that peak at the ridge portion 66 and extend down to the side member 64. The central pyramid-shaped subgrade 60 has triangular end members 62 and triangular intermediate members 76. The angles shown for the first and second angular surfaces 70 and 72 are exemplary only. Different angles can be used to increase or decrease the selection surface area. The central pyramid-shaped subgrade 60 has fasteners along side members 64 and both triangle end members 62. The fasteners can be clamps 42 and clip openings 40, so that multiple central pyramid-shaped subgrades 60 can be stuck together. Alternatively, clamps 42 and clamp openings 40 can be used to attach the central subgrade in a pyramid shape 60 to the end subgrade 14, to the central subgrade 18 or to the end subgrade in a pyramid shape 58. The elongated attachment members 44 can be configured on the first and second inclined surfaces 70 and 72, so that they fit with the screen element attachment openings 24. The screen element 16 can be attached to the central subgrade in a pyramid shape 60 by means of members of plug-in elongated attachments 44 with the screen element attachment openings 24. A portion of the elongated attachment member 44 may extend slightly above the screen element selection surface when the screen element 16 is attached to the central subgrade in pyramidal shape 60. The screen element attachment openings 24 may include a tapered bore, so that the portion of the elongated attachment members 44 that extends above the top The screen element selection surface can be melted and fill the tapered hole. Alternatively, the web element attachment openings 24 can be without a tapered hole, and the portion of the elongated attachment members that extends above the selection surface of the selection element 16 can be melted to form a bead on the selection surface. . Once attached, the screen element 16 will cover the sloped grid passage 74. The materials that pass through the selection passages 86 will pass through the grid passage 74. Although the flat and pyramid shaped grid structures are shown , it will be appreciated that several formatted subgrades and corresponding screen elements can be manufactured in accordance with the present disclosure.
[0228] Figure 24 shows a subset of a row of pyramid-shaped subgrade units. Figure 24A is an exploded view of the subset in Figure 24 showing the individual sub-grids in a pyramid shape and the direction of attachment. The subset includes two pyramid-shaped 58 end subgrades and three 60-pyramid-shaped central subgrades. The 58 pyramid-shaped end subgrades form ends of the subset, while the 60 pyramid-shaped central subgrades are used to join the two end subgrades. 58 via connections between clamps 42 and clamp openings 40. The pyramidal subgrades shown in Figure 24 are shown with screen elements attached 16. Alternatively, the subset can be constructed from subgrades before attaching screen elements or partially from pre-covered subgrade units in a pyramid format, and partially from subgrade units not covered in a pyramid format.
[0229] Figures 24B and 24C illustrate the attachment of screen elements 16 to the end subgrade in pyramid shape 58, according to an exemplary embodiment of the present invention. The screen elements 16 can be aligned with the pyramid-shaped end subgrade 58 by means of elongated attachment members 44 and screen element attachment openings 24, so that the elongated attachment members 44 pass through the attachment openings. screen element 24 may extend slightly beyond the screen element selection surface. The portion of elongated attachment members 44 extending beyond the screen element selection surface can be melted to fill tapered holes in the screen element attachment openings 24 or, alternatively, to form granules under the element selection surface screen, securing the screen element 16 to the subgrade in pyramid shape 58. Attachment by means of elongated attachment members 44 and screen element attachment openings 24 is just one embodiment of the present invention. Alternatively, the web element 16 can be attached to the pyramid-shaped end subgrade 58 by means of adhesive, fasteners and fastener openings, etc. Although shown to have four screen elements for each pyramid-shaped 58 edge subgrade, the present invention includes alternative configurations of two screen elements per 58 pyramid-shaped edge subgrade, multiple screen elements per 58 pyramid-shaped edge subgrade. , or with a single screen element that covers an inclined surface of multiple pyramid-shaped subgrade units. The pyramid-shaped end subgrade 58 can be substantially rigid and can be a single piece molded by thermoplastic injection.
[0230] Figures 24D and 24E illustrate the attachment of screen elements 16 to the central subgrade in pyramidal format 60, according to an exemplary embodiment of the present invention. The screen elements 16 can be aligned with the central pyramid-shaped subgrade 60 by means of elongated attachment members 44 and screen element attachment openings 24, so that the elongated attachment members 44 can pass through the attachment openings screen element 24 and may extend slightly beyond the screen element selection surface. The portion of the elongated attachment members 44 that extends beyond the screen element selection surface can be melted to fill tapered holes in the screen element attachment openings 24 or, alternatively, to form granules under the element selection surface. mesh, securing the mesh element 16 to the pyramid-shaped subgrade unit 60. Attachment by means of elongated attachment members 44 and mesh element attachment openings 24 is just one embodiment of the present invention. Alternatively, the screen element 16 can be attached to the central subgrade in a pyramid shape 60 by means of adhesive, fasteners and fastener openings, etc. Although shown to have four screen elements for each central subgrade in a pyramidal format 60, the present invention includes alternative configurations of two screen elements per central subgrade in pyramidal format 60, multiple screen elements per central subgrade in pyramidal format 60, or with a single mesh element that covers an inclined surface of multiple pyramid-shaped subgrades. The pyramid-shaped central subgrade 60 can be substantially rigid and can be a single piece molded by thermoplastic injection. Although the grid structures in flattened and pyramid format are shown, it will be noted that several formatted subgrades and corresponding screen elements can be manufactured in accordance with the present disclosure.
[0231] Figures 53 to 56A show central sub-grids in pyramid shape and end 458 and 460, respectively, according to the exemplary modalities of the present disclosure. The central subgrades in pyramid shape and end 458 and 460 can be molded by thermoplastic injection and can have all of the features of central subgrades in pyramid shape and end 58 and 60 discussed in the present document above. Like the end subgrade unit 414 and the central subgrade unit 418, the central pyramidal and end subgrades 458 and 460 can have location members 444 that correspond to location openings 424 of screen element 416, so that the screen elements 416 can be located in the central sub-grids in pyramid shape and end 458 and 460 for attachment. The central subgrades in pyramid shape and end 458 and 460 can have second bonding arrangements, such as a plurality of melting bars 476 and shortened melting bars 478. Second bonding arrangements can be configured to fit with the first arrangements complementary adhesion elements on web elements 416, such as a plurality of pocket cavities. The screen elements 416 can be laser welded to the pyramidal sub-grids. The central sub-grids in pyramid shape and end 458 and 460 may include the secondary support frame 488 which it covers through grid passages 74. The secondary support frame 488 can cover all or just a portion of a grid passage 74. A secondary support frame 488 increases the strength and durability of central pyramid-shaped and end 458 and 460 subgrades. Central pyramid-shaped and end 458 and 460 subgrades may include a flattened ridge portion 465 and may have device locators 490 on the ridge 66. See, for example, Figure 53. The flattened ridge portion 465 may allow for easier molding than the pointed or rounded modalities and may allow for easier release and / or extraction of the subgrades from the molds. The embodiments may include one or more device locators 490 that can be used for alignment and / or assembly during laser welding. The devices can engage the subgrades in 490 device locators that allow laser welding alignment. The flattened peak portion 465 can provide easier engagement of the device locators 490.
[0232] Figure 25 is a top view of a set of screens 80 that have subgrades in pyramid shape, which can be any one of subgrades 14, 18, 414 and 418. As shown, the set of screens 80 is formed from from the screen subsets attached to each other, alternating from flat subsets to pyramid-shaped subsets. Alternatively, pyramidal shaped subsets can be attached to each other, or less or more pyramidal shaped subsets can be used. Figure 25A is a cross section of Section CC of the screen set shown in Figure 25. As shown, the screen set has five rows of subgrade units in pyramid shape and six rows of flattened subgrades, with rows of subgrade units flattened between each row of the subgrades in a pyramid shape. The binder bars 12 are attached to the set of screens. Any combination of flattened subgrade rows and pyramid shaped subgrade rows can be used. Figure 25B is a larger view of the cross section shown in Figure 25A. In Figure 25B, the attachment of each subgrade to the other subgrade and / or to the bonding bar 12 is visible through clamps and clamp openings.
[0233] Figure 26 is an exploded isometric view of a set of screens that have pyramid-shaped subgrade units. This Figure shows eleven subsets that are attached to each other by means of clamps and clamp openings, along side subgrade members of subgrade units in each subset. Each flattened subset has two end subgrades (14 or 414) and three central subgrades (18 or 418). Each pyramid-shaped subset has two pyramid-shaped end subgrades (58 or 458) and three central pyramid-shaped subgrades (60 or 460). Binder bars 12 are attached at each end of the assembly. Sets of screens of different sizes can be created using different quantities of subsets or different quantities of central subgrade units. The selection surface area can be increased by incorporating more subsets in a pyramid shape or decreased by incorporating more flattened sets. An assembled screen set has a continuous screen set selection surface made of multiple screen element selection surfaces.
[0234] Figure 27 shows the installation of sets of screens 80 under a vibrating selection machine that has two selection surfaces. Figure 30 is a front view of the vibrating machine shown in Figure 27. The vibrating sorting machine can have compression assemblies on the side members of the vibrating sorting machine. The screen sets can be positioned on the vibrating selection machine, as shown. A compressive force can be applied to a lateral member of the screen set, so that the screen set flexes downward in a concave shape. A bottom side of the screen assembly may engage with a screen assembly interlocking surface of the vibrating selection machine, as shown in U.S. Patent No. 7,578,394 and U.S. Patent Application No. 12 / 460,200. The vibrating selection machine may include a central wall member configured to receive a side member of the screen set opposite to the side member of the screen set receiving compression. The central wall member can be angled so that a compressive force against the screen assembly flexes the screen assembly downwards. The set of screens can be installed on the vibrating selection machine, so that it is configured to receive material to select. The screen set may include guide notches configured to fit with the guides of the vibrating selection machine, so that the screen set can be guided to position itself during installation.
[0235] Figure 28 shows an isometric view of a set of screens that have sub-grids in a pyramid shape, in which the screen elements have not been tied. The set of screens shown in Figure 28 is slightly concave, however, the set of screens can be more concave, convex or flat. The set of screens can be made up of multiple subsets, which can be any combination of flat subsets and pyramid-shaped subsets. As shown, eleven subsets are included, however, more or less subsets can be included. The screen set is shown without screen elements 16 (or 416). Subgrades can be assembled together, before or after attaching screen elements to subgrades, or any combination of subgrades that have screen elements attached and subgrades without screen elements can be attached together. Figure 29 shows the set of screens in Figure 28 partially covered in the screen elements. Pyramid shaped subsets include 58 (or 458) pyramid-shaped end subgrades and central 60 (or 460) pyramid-shaped subgrades. The flattened subsets include flattened edge grids 14 (or 414) and central flattened subgrades 18 (or 418). Subgrade units can be attached to each other by means of clamps and clamp openings.
[0236] Figure 31 shows the installation of a set of screens 81 on a vibrating selection machine that has a single selection surface, according to an exemplary embodiment of the present invention. The set of screens 81 is similar in configuration to the set of screens 80, but includes flattened and additional pyramidal sets. The vibrating sorting machine may have a compression assembly on a side member of the vibrating sorting machine. The set of screens 81 can be positioned on the vibrating selection machine, as shown. A compressive force can be applied to a lateral member of the screen assembly 81, so that the screen assembly 81 flexes downward in a concave shape. A bottom side of the screen assembly may engage with a screen assembly interlocking surface of the vibrating selection machine, as shown in U.S. Patent No. 7,578,394 and U.S. Patent Application No. 12 / 460,200. The vibrating sorting machine may include a side member wall opposite the compression assembly configured to receive a side member of the screen assembly. The side member wall can be angled so that a compressive force against the screen assembly flexes the screen assembly downwards. The set of screens can be installed on the vibrating selection machine, so that it is configured to receive material to select. The screen set may include guide notches configured to fit with the guides of the vibrating selection machine, so that the screen set can be guided to position itself during installation.
[0237] Figure 32 is a front view of sets of screens 82 installed on a vibrating selection machine that has two selection surfaces, according to an exemplary embodiment of the present invention. The screen set 82 is an alternative mode in which the screen set has been pre-formed to fit the vibrating selection machine, without applying a load to the screen set, that is, the screen set 82 includes a lower portion 82A that is formed, so that it fits with a bed 83 of the vibrating selection machine. The lower portion 82A can be integrally formed with the screen assembly 82 or it can be a separate part. Screen set 82 includes similar features, such as screen set 80, which includes subgrades and screen elements, but also includes a lower portion 82A that allows it to fit into bed 83, without being compressed into a concave shape. A screen set selection surface 82 can be substantially flattened, concave or convex. The screen assembly 82 can be held in place by applying a compressive force to a lateral screen assembly member 82 or it can simply be held in place. A lower portion of screen assembly 82 may be preformed to fit with any type of interlocking surface of a vibrating sorting machine.
[0238] Figure 33 is a front view of a set of screens 85 installed on a vibrating selection machine that has a single selection surface, according to an exemplary embodiment of the present invention. The set of screens 85 is an alternative modality in which the set of screens was pre-formed to fit the vibrating selection machine, without applying a load to the set of screens, that is, the set of screens 85 includes a lower portion 85A that is formed, so that it fits with a bed 87 of the vibrating selection machine. The lower portion 85A can be integrally formed with the screen assembly 85 or it can be a separate part. Screen set 85 includes similar features, such as screen set 80, which includes subgrades and screen elements, but also includes a lower portion 85A that allows it to fit into bed 87, without being compressed into a concave shape. A screen set selection surface 85 can be substantially flattened, concave or convex. The screen assembly 85 can be held in place by applying a compressive force to a lateral screen assembly member 85 or it can simply be held in place. A lower portion of screen assembly 85 may be preformed to fit with any type of interlocking surface of a vibrating sorting machine.
[0239] Figure 34 is an isometric view of the end subgrade shown in Figure 3 that has a single screen element partially attached to it. Figure 35 is an enlarged view of the split section E of the end subgrade shown in Figure 34. In Figures 34 and 35, the screen element 16 is partially attached to the end subgrade 38. The screen element 16 is aligned with the subgrade 38 by means of elongated attachment members 44 and web element attachment openings 24, so that the elongated attachment members 44 pass through the web element attachment openings 24 and extend slightly beyond the element selection surface of screen. As shown along the web element end edge portion 16, the elongated attachment member portions 44 extending beyond the web element selection surface are melted to form granules under the web element selection surface. , securing the screen element 16 to the end subgrade unit 38.
[0240] Figure 36 shows a set of slightly concave screens 91 that have pyramidal shaped subgrades incorporated in a portion of set of screens 91, according to an exemplary embodiment of the present invention. A screen selection surface can be substantially flat, concave or convex. The set of screens 91 can be configured to flex to a predetermined format under a compressive force. The screen set 91, as shown in Figure 36, incorporates pyramid-shaped subgrades in the portion of the screen set installed closest to the inflow of material in the vibrating selection machine. The portion incorporating the pyramid shaped subgrades allows for increased surface area selection and targeted material flow. A portion of the screen assembly installed closest to a discharge end of the vibrating sorting machine incorporates flattened sub-grids. In the flattened portion, an area can be provided, so that the material can be allowed to dry and / or form a mass in the set of screens. Various combinations of pyramidal and flattened subgrades can be included in the set of screens, depending on the desired configuration and / or the particular selection application. In addition, vibrating sorting machines that use multiple screen sets can have individual screen sets with varying configurations designed for use together in specific applications. For example, screen set 91 can be used with other screen sets, so that it is positioned close to the discharge end of a vibrating sorting machine, so that it provides mass formation and / or drying of a material.
[0241] Figure 37 is a flow chart showing the steps to manufacture a set of screens, according to an exemplary embodiment of the present invention. As shown in Figure 37, a display manufacturer can receive display set performance specifications for the display set. The specifications can include at least one of a material requirement, an open selection area, a capacity and a cutoff point for a set of screens. The manufacturer can then determine a check pass requirement (shape and size) for a screen element, as described in this document. The manufacturer can then determine a screen configuration (for example, set size, shape and selection surface configuration, etc.). For example, the manufacturer may have the screen elements arranged in at least one of a flattened configuration and a non-flattened configuration. A flattened configuration can be constructed from central subgrades (18 or 418) and end subgrades (14 or 414). An unflattened configuration can include at least a portion of pyramid-shaped central subgrades (60 or 460) and / or pyramid-shaped end subgrades (58 or 458). The screen elements can be injection molded. Subgrade units can also be injection molded, but they are not required to be injection molded. Screen elements and subgrades can include a nanomaterial, as described in this document, dispersed inside. After both screen elements and subgrade units have been created, screen elements can be attached to the subgrade units. The screen elements and the subgrades can be tied together, using connection materials that have a nanomaterial dispersed inside. The screen elements can be attached to the subgrades using laser welding. The multiple subgrade units can be tied together, forming support frames. The central support frames are formed from central subgrades, and the end support frames are formed from end subgrades. Pyramid-shaped support frames can be created from pyramid-shaped subgrade units. The support frames can be attached so that the central support frames are on a central portion of the screen set, and the end support frames are on an end portion of the screen set. The bonding bars can be attached to the set of screens. Different selection surface areas can be made by changing the number of pyramid-shaped subgrades incorporated into the set of screens. Alternatively, the screen elements can be attached to the subgrade units after attaching multiple subgrades together or after attaching multiple support frames together. Unlike multiple independent subgrades that are tied together to form a single unit, a subgrade structure can be manufactured, which is the desired size of the screen set. The individual screen elements can then be attached to a subgrade structure.
[0242] Figure 38 is a flow chart showing the steps to manufacture a set of screens, according to an exemplary embodiment of the present invention. A thermoplastic mesh element can be injection molded. Subgrades can be manufactured so that they are configured to receive the screen elements. The screen elements can be attached to the subgrades and the multiple sets of subgrade can be attached, forming a selection surface. Alternatively, the subgrades can be attached to each other, before attaching screen elements.
[0243] In another exemplary embodiment, a method for selecting a material is provided, which includes attaching a set of screens to a vibrating selection machine and forming a top selection surface of the set of screens in a concave format, in which the set of screens includes a screen element that has a series of selection passages that form a screen element selection surface and in which a subgrade includes multiple elongated structural members that form a grid frame that has grid passages. The screen elements cover grid passages and are attached to an upper surface of the subgrade. The multiple subgrades are fastened together to form the screen set, and the screen set has a continuous screen set selection surface comprised of multiple screen element selection surfaces. The screen element is a single piece molded by a thermoplastic injection.
[0244] Figure 39 is an isometric view of a vibrating selection machine that has a single set of screens 89 with a flattened selection surface installed on it, with a portion of the cutout of the vibrating machine showing the set of screens. The set of screens 89 is a single unit that includes a subgrade structure and screen elements, as described in this document. The subgrade structure can be a single unit or it can be multiple subgrades tied together. Although the set of screens 89 is shown as a set, in general, of the flattened type, it can be convex or concave and can be configured to be deformed into a concave shape, from a compression set or the like. It can also be configured to be tensioned from above or below or it can be configured in another way for attachment to different types of vibrating sorting machines. Although the modality of the screen set shown covers the entire selection bed of the vibrating selection machine, the screen set 89 can also be configured in any desired shape or size and can cover only a portion of the selection bed.
[0245] Figure 40 is an isometric view of a screen element 99, according to an exemplary embodiment of the present invention. Screen element 99 is substantially triangular in shape. The screen element 99 is a single piece molded by thermoplastic injection and has similar features (including selection pass sizes) as screen elements 16 and 416, as described in this document. Alternatively, the screen element can be rectangular, circular, triangular, square, etc. Any format can be used for the screen element and any format can be used for the subgrade, as long as the subgrade has grid passages that correspond to the formats of the screen elements.
[0246] Figures 40A and 40B show the screen element structure 101, which can be a subgrade structure, with screen elements 99 attached to it, forming a pyramid shape. In an alternative embodiment, the complete pyramid structure of fabric element structure 101 can be molded by thermoplastic injection as a single fabric element that has a pyramid shape. In the configuration shown, the screen element structure has four triangular screen element selection surfaces. The bases of two of the triangular selection surfaces begin at the two side members of the screen element, and the bases of the other two triangular selection surfaces begin at the two end members of the screen element. All selection surfaces slope upward, at a central point above the screen member end members and the side members. The angle of the inclined selection surfaces can be varied. The screen element structure 101 (or, alternatively, the only screen element pyramids) can be attached to a subgrade structure, as described in this document.
[0247] Figures 40C and 40D show screen element structures 105 with screen elements 99 tied together and with a pyramidal shape that descends below the side members and edge members of the screen element structure 105. Alternatively, the entire pyramid can be injection molded with thermoplastic as a single pyramid-shaped screen element. In the configuration shown, the individual screen elements 99 form four triangular selection surfaces. The bases of two of the triangular selection surfaces begin at the two side members of the screen element, and the bases of the other two triangular selection surfaces begin at the two end members of the screen element. All selection surfaces slope downward, to a central point below the screen member end members and the side members. The angle of the inclined selection surfaces can be varied. The screen element structure 105 (or, alternatively, the only screen element pyramids) can be attached to a subgrade structure, as described in this document.
[0248] Figures 40E and 40F show a screen element structure 107 that has multiple pyramidal shapes that descend and rise below and above the side members and edge members of the screen element structure 107. Each pyramid includes four elements of individual screen 99, but can also be formed as a single screen element pyramid. In the configuration shown, each screen element has sixteen triangular selection surfaces that form four separate pyramidal selection surfaces. The pyramidal selection surfaces can tilt above or below the screen member end members and the side members. The screen element structure 107 (or, alternatively, the only screen element pyramids) can be attached to a subgrade structure, as described in this document. Figures 40 to 40F are only exemplary, as to the variations that can be used for the screen elements and the screen element support structures.
[0249] Figures 41 to 43 show cross-sectional profile views of exemplary modalities of thermoplastic injection molded fabric element surface structures that can be incorporated into the various modalities of the present invention discussed in the present document. The screen element is not limited to the formats and configurations identified in this document. Due to the fact that the mesh element is injection molded thermoplastic, the multiple variations can be easily manufactured and incorporated into the various exemplary modalities discussed in this document.
[0250] Figure 44 shows a pre-screen structure 200 for use with vibrating sorting machines. The pre-screen structure 200 includes a support frame 300 that is partially covered with sets of individual pre-screens 210. The pre-screen sets 210 are shown with multiple pre-screen elements 216 mounted on the pre-screen sub-grids. 218. Although sets of pre-screens 210 are shown including six sub-screens of pre-screen 218 attached together, various amounts and types of sub-screens can be attached together to form various shapes and sizes of sets of pre-screens 210. Sets of pre-screens pre-screens 210 are fixed to support a frame 300 and form a continuous pre-selection surface 213. Pre-screen structure 200 can be mounted on a primary selection surface. The pre-screen sets 210, the pre-screen elements 216 and the pre-screen subgrades 218 may include any of the features of the various modalities of screen sets, screen elements and subgrade structures described in this document and may be configured to be mounted on the pre-screen support frame 300, which can have various shapes and configurations suitable for pre-selection applications. The pre-screen structure 200, the pre-screen sets 210, the pre-screen elements 216 and the pre-screen subgrades 218 can be configured to be incorporated into the pre-selection technologies (for example, compatible with the structures assembly and screen configurations) described in US Patent Application No. 12 / 051,658.
[0251] Figure 44A shows an enlarged view of the set of pre-screens 210.
[0252] The modalities of the present invention described in this document, which include selection members and selection sets, can be configured for use with several different vibrating selection machines and parts thereof, which include machines designed for dry and wet applications. wet machines, machines that have multi-level platforms and / or multiple selection baskets and machines that have various screen attachment arrangements, such as tensioning mechanisms (over- and subassembly), compression mechanisms, clamping mechanisms, magnetic mechanisms , etc. For example, the screen sets described in the present disclosure can be configured to be mounted on the vibrating selection machines described in U.S. Patent No. 7,578,394; 5,332,101; 6,669,027; 6,431,366; and 6,820,748. Certainly, the sets of screens described in this document can include: side portions or binder bars that include U-shaped members configured to receive tension members of the overmount type, for example, as described in U.S. Patent No. 5,332,101; side portions or binder bars that include tongue receiving openings configured to receive subassembly type tensioning, for example, as described in U.S. Patent No. 6,669,027; side members or binder bars for compression loading, for example, as described in U.S. Patent No. 7,578,394; or they can be configured for attachment and loading on multi-level machines, for example, such as the machines described in U.S. Patent No. 6,431,366. Screen sets and / or selection elements can also be configured to include the features described in U.S. Patent Application No. 12 / 460,200, which include the set technologies described therein and the preformed panel technologies described therein. In addition, the sets of screens and the selection elements can be configured to be incorporated into the pre-selection technologies (for example, compatible with the assembly structures and the screen configurations) described in Patent Application No. US 12 /051.658. U.S. Patent numbers 7,578,394; 5,332,101; 4,882,054; 4,857,176; 6,669,027; 7,228,971; 6,431,366; and 6,820,748 and Patent Application numbers US 12 / 460,200 and 12 / 051,658, which, together with their applications and their related patent families, and the patents and patent applications referenced in these documents, are expressly incorporated into this document. as a reference to them.
[0253] In the description above, the exemplary modalities are described. It will, however, be evident that the various modifications and changes can be made to this document without departing from the broader spirit and scope of this document. The descriptive report and the drawings must therefore be taken into account in an illustrative, rather than a restrictive sense.

权利要求:
Claims (81)
[0001]
1. Screen assembly composed of one or more screen elements and one or more subgrade elements, characterized by the fact that it comprises: a screen element that includes a first adhesion arrangement, including a plurality of cavity pockets on a surface bottom of the screen element; and a subgrade that includes a second adhesion arrangement, including a plurality of melting bars on an upper surface of the subgrade; wherein the screen element and the subgrade are fastened together through the first and second adhesion arrangements; and in which multiple subgrades are attached together to form the screen assembly.
[0002]
2. Screen set consisting of one or more screen elements and one or more subgrade elements, according to claim 1, characterized by the fact that the screen element has screening openings between 40 μm and 1000 μm.
[0003]
3. Screen set composed of one or more screen elements and one or more subgrade elements, according to claim 1, characterized by the fact that the cavity pockets are elongated pockets.
[0004]
4. Screen set composed of one or more screen elements and one or more subgrade elements, according to claim 1, characterized by the fact that the melting bars are slightly higher in height than the depth of the cavity pockets .
[0005]
5. Screen set composed of one or more screen elements and one or more subgrade elements, according to claim 4, characterized by the fact that the depth of the cavity pockets is 1.27 mm (0.05 inches) and the height of the melting bars is 1.42 mm (0.056 inches).
[0006]
6. Screen assembly composed of one or more screen elements and one or more subgrade elements, according to claim 4, characterized by the fact that the melting bars have a width slightly smaller than the width of the cavity pockets .
[0007]
7. Screen assembly composed of one or more screen elements and one or more subgrade elements, according to claim 1, characterized by the fact that the screen element comprises thermoplastic polyurethane.
[0008]
8. Screen set consisting of one or more screen elements and one or more subgrade elements, according to claim 1, characterized by the fact that the subgrade comprises at least one component among glass, carbon and nylon.
[0009]
9. Screen set composed of one or more screen elements and one or more subgrade elements, according to claim 1, characterized by the fact that the screen element is a single piece molded by thermoplastic injection.
[0010]
10. Screen assembly composed of one or more screen elements and one or more subgrade elements, according to claim 9, characterized by the fact that the screen element has a plurality of selection passages which are elongated slits with a width and a length, where the width of the selection passes is 40 μm to 1000 μm between the internal surfaces of each surface element of the screen.
[0011]
11. Screen assembly composed of one or more screen elements and one or more subgrade elements, according to claim 1, characterized by the fact that the screen element is attached to the subgrade by means of laser welding.
[0012]
12. Screen assembly composed of one or more screen elements and one or more subgrade elements, according to claim 11, characterized in that a weld between the screen element and the subgrade comprises a mixture of elements of the element screen and subgrade.
[0013]
13. Screen set consisting of one or more screen elements and one or more subgrade elements, according to claim 1, characterized by the fact that the screen element is micro molded and has a selection gap between 40 μm and 150 μm.
[0014]
14. Screen set consisting of one or more screen elements and one or more subgrade elements, according to claim 1, characterized by the fact that the screen element contains thermoplastic polyurethane in its composition and the subgrade contains in its composition at least one of glass, nylon and carbon.
[0015]
15. Screen set composed of one or more screen elements and one or more subgrade elements, according to claim 9, characterized by the fact that the screen element has selection passages with openings between 40 μm and 1000 μm.
[0016]
16. Screen assembly composed of one or more screen elements and one or more subgrade elements, according to claim 9, characterized by the fact that the screen element has a plurality of elongated opening selection passages with a width and a length, the width of the selection openings being 40 μm to 150 μm between the internal surfaces of each element of the screen surface.
[0017]
17. Set composed of one or more screen elements and one or more subgrade elements, characterized by the fact that it comprises: a screen element; and a subgrade; wherein the screen element is a single piece molded by injection of thermoplastic and is fixed to the subgrade; and where the screen element has a selection opening between 40 μm and 150 μm.
[0018]
18. Set consisting of one or more screen elements and one or more subgrade elements, according to claim 17, characterized by the fact that the screen element and the subgrade include different materials that are laser welded together to fix the screen element in the subgrade.
[0019]
19. Assembly comprising one or more screen elements and one or more subgrade elements, according to claim 17, characterized in that the screen element includes a first fixing arrangement and the subgrade includes a second fixing arrangement , the screen element is fixed to the subgrade using the first and second fixing arrangements.
[0020]
20. Set consisting of one or more screen elements and one or more subgrade elements, according to claim 17, characterized by the fact that the multiple independent subgrades are attached together to form the screen set.
[0021]
21. Set consisting of one or more screen elements and one or more subgrade elements, according to claim 17, characterized by the fact that multiple screen elements are attached to a single subgrade to form the screen set.
[0022]
22. Set consisting of one or more screen elements and one or more subgrade elements, according to claim 19, characterized by the fact that the first adhesion arrangement and the second adhesion arrangement are different materials, in which at least one of the first adhesion arrangement and the second adhesion arrangement are excitable, so that the screen element and the subgrade are fixed together.
[0023]
23. Set composed of one or more elements of mesh and one or more elements of subgrade, according to claim 19, characterized in that the first set of adhesion includes a plurality of pocket cavities on a lower surface of the element of adhesion screen and the second adhesion set includes a plurality of melting bars on the upper surface of the subgrade.
[0024]
24. Assembly composed of one or more screen elements and one or more subgrade elements, according to claim 17, characterized by the fact that the screen element includes a thermoplastic polyurethane material.
[0025]
25. Set composed of one or more elements of canvas and one or more elements of subgrade, according to claim 17, characterized by the fact that the subgrade includes at least one material among glass, nylon and carbon.
[0026]
26. Set consisting of one or more screen elements and one or more subgrade elements, according to claim 17, characterized by the fact that the screen element has a plurality of selection passages of elongated openings with a width and a length, the width of the selection openings being 40 μm to 150 μm between the internal surfaces of each element of the screen surface.
[0027]
27. Screen assembly composed of one or more screen elements and one or more subgrade elements, according to claim 17, characterized by the fact that the screen element includes translucent portions, and the subgrade includes at least one of glass , nylon and carbon, and where the screen element is laser fused to the subgrade material.
[0028]
28. Screen set, characterized by containing: multiple sets fixed together to form the screen set, in which each set includes: a screen element that has an upper screening surface and a lower surface fixed to a subgrade; wherein the upper screening surfaces of the screen elements form a continuous screening surface of the screen assembly; and wherein the web element comprises thermoplastic polyurethane.
[0029]
29. A screen assembly according to claim 28, characterized by the fact that the screen element is a single piece molded by thermoplastic injection.
[0030]
30. A screen assembly according to claim 29, characterized by the fact that the screen element has screening openings between 40 μm and 1000 μm.
[0031]
31. A screen assembly according to claim 29, characterized by the fact that the screen element has screening openings between 40 μm and 150 μm.
[0032]
32. A screen assembly according to claim 28, characterized in that the screen element includes translucent portions and the subgrade includes at least one of glass, nylon and carbon, in which the screen element is laser welded to the subgrade.
[0033]
33. Method for selecting a material, characterized by the fact that it comprises: attaching a screen assembly to a vibrating screening machine; the screen assembly including a screen element having a series of screen openings forming a screen element screening surface; and a subgrade including several elongated structural members, forming a grid structure with grid openings; wherein the screen elements span grid openings and are attached to an upper surface of the subgrade; wherein multiple subgrades are attached together to form the selection set and the selection set has a continuous selection set screening surface composed of multiple screen element screening surfaces; wherein the sieve element is a single piece molded by a thermoplastic injection; screening of the material using the screen assembly, where the screen element includes translucent portions and the subgrade includes at least one of glass, nylon and carbon, and where the screen element is laser welded on the subgrade.
[0034]
34. Method for selecting a material according to claim 33, characterized by the fact that the screen element contains a portion of the edge, and in which the screen element has screening surface elements forming the series of openings selection.
[0035]
35. Method for selecting a material according to claim 34, characterized in that the elements of the screen surface are elongated members that form the series of selection openings, the selection openings are elongated grooves with a distance of 43 μm to 1000 μm between the internal surfaces of each element of the screen surface.
[0036]
36. Method for selecting a material according to claim 34, characterized in that the elements of the sorting surface are elongated members forming a series of selection openings, the selection passages being elongated slits forming a series of openings of selection having a distance of 70 μm to 180 μm between the internal surfaces of each element of the screen surface.
[0037]
37. Method for selecting a material according to claim 34, characterized by the fact that the elements of the screen surface are elongated members forming a series of selection openings, the selection passages being elongated slits having a distance of 43 μm to 106 μm between the internal surfaces of each element of the screen surface.
[0038]
38. Method for selecting a material according to claim 34, characterized in that the selection passages are elongated cracks with a substantially uniform width and length, wherein the substantially uniform width has a magnitude in the range of 0.044 mm to 4 mm and the length has a magnitude in a range of 0.088 mm to 60 mm.
[0039]
39. Method for selecting a material according to claim 34, characterized by the fact that the mesh element further contains: a pair of substantially parallel end portions; a pair of substantially parallel side-edge portions; wherein the pair of end portions is substantially perpendicular to the pair of side edge portions; a first screen element support element; a second screen element support member orthogonal to the first screen element support member; the first web element support member extending between the end portions and being substantially parallel to the side edge portions; the second web support element extending between the side edge portions and being substantially parallel to the end portions; a first series of reinforcement members substantially parallel to the side edge portions; a second series of reinforcement members substantially parallel to the end portions; wherein the screen surface elements are parallel to the end portions; and wherein the end portions, side edge portions, first and second support members, the first series of reinforcement members and the second series of reinforcement members structurally stabilize the screen surface elements and selection openings.
[0040]
40. Method for selecting a material according to claim 34, characterized by the fact that the sieve element further comprises a fixing arrangement of a screen element integrally molded with the screen element and configured to join with an arrangement subgrade fixing.
[0041]
41. Method for selecting a material, characterized by the fact that it comprises: attaching a screen set to a vibrating screening machine; forming a top screening surface of the screen assembly in a concave shape, wherein the screen assembly includes a screen element having a series of screening openings forming a screen element screening surface; and a subgrade including several elongated structural members forming a grid structure with grid openings, where the screen elements span grid openings and are attached to an upper surface of the subgrade, where several subgrades are attached together to form the set of screen and the screen assembly has a continuous screen mounting screening surface composed of several screen element screening surfaces, wherein the screen element is a single thermoplastic injection molded part; and in which the subgrade comprises at least one material among glass, carbon and nylon; and sorting the material using the screen assembly.
[0042]
42. Method for selecting a material according to claim 41, characterized by the fact that the selection element comprises a border portion and in which the selection element has mesh surface elements forming the series of selection openings .
[0043]
43. Method for selecting a material according to claim 44, characterized by the fact that the selection passages are elongated slits with a width and length, in which the width of the selection passages is from 43 μm to 1000 μm between the inner surfaces of each screen surface element.
[0044]
44. Method for selecting a material according to claim 42, characterized by the fact that the selection passages are elongated slits with a width and length, in which the width of the selection passages is 70 μm to 180 μm between the inner surfaces of each element of the screen surface.
[0045]
45. Method for selecting a material according to claim 42, characterized by the fact that the selection passages are elongated slits with a width and length, in which the width of the selection passages is 43 μm to 106 μm between the inner surfaces of each element of the sieve surface.
[0046]
46. Method for selecting a material according to claim 42, characterized by the fact that the selection passages are elongated slits with a width and length, in which the width of the selection passages varies in the range of 0.044 mm to 4 mm and the length varies in the range of 0.088 mm to 60 mm.
[0047]
47. Method for selecting a material according to claim 42, characterized by the fact that the mesh element further contains: a pair of substantially parallel end portions and a pair of substantially parallel side portions, wherein the pair of side portions is substantially perpendicular to the end portions; a first support element of the screen element; a second web element support member orthogonal to the first web element support member, the first web element support member extending between the end portions and being substantially parallel to the side edge portions, the second web element screen support extending between the side edge portions and being substantially parallel to the end portions; a first series of reinforcement members substantially parallel to the side edge portions; a second series of reinforcement members substantially parallel to the end portions, wherein the surface elements of the web run parallel to the end portions, wherein the end portions, side edge portions, first and second support members, the first series of reinforcement members and the second series of reinforcement members structurally stabilize the elements of the screen surface and the sieving openings.
[0048]
48. Method for selecting a material, according to claim 42, characterized by the fact that the screen element also contains a screen element fixing arrangement integrally molded with the screen element and configured to join an arrangement subgrade fixing.
[0049]
49. Method for making a screen assembly for material selection, characterized by the fact that it comprises: injection molding a screen element, the screen element including a screen element screening surface with selection openings; fabricating a subgrade that supports the screen element, the subgrade having a grid structure with grid openings, the screen element comprising at least one grid opening of the grid openings; and securing the screen element to an upper surface of the subgrade, the screen assembly having a continuous screen assembly screening surface composed of various screen element screening surfaces.
[0050]
50. Method for manufacturing a screen assembly for material selection according to claim 49, characterized in that it further comprises attaching a first binder bar to a first end of the screen assembly and attaching a second binder bar to a second end of the screen assembly, in which the first link bar and the second link bar fix the sub grids together.
[0051]
51. Method for making a material selection screen assembly according to claim 50, characterized in that the first connection bar is configured to distribute a load over the first end of the screen assembly and the second end of the assembly of the screen.
[0052]
52. Method for manufacturing a screen assembly for material selection according to claim 49, characterized in that the screen element includes surface elements of the screen that form the screening openings, the screening openings being elongated grooves having a distance of 43 μm to 1000 μm between the internal surfaces of each element of the screen surface.
[0053]
53. Method for making a screen assembly for material selection according to claim 49, characterized in that the selection element includes sorting surface elements forming series of the selection openings, the selection openings being elongated grooves having a distance of 70 μm to 180 μm between the internal surfaces of each element of the screen surface.
[0054]
54. Method for making a screen assembly for material selection according to claim 49, characterized by the fact that the screen element includes screen surface elements that form the series of selection openings, the screening opening being elongated grooves having a distance of 43 μm to 106 μm between the internal surfaces of each element of the sieve surface.
[0055]
55. Method for making a material selection screen assembly according to claim 49, characterized in that the screen element includes screen surface elements that form the screening openings, the screening openings being elongated grooves having a substantially uniform width and length, the substantially uniform width having a magnitude in the range of 0.044 mm to 4 mm and the length having a magnitude in the range of 0.088 mm to 60 mm.
[0056]
56. Method for manufacturing a screen set for material selection, according to claim 49, characterized by the fact that at least one of the screen elements and the subgrade is a single piece molded by thermoplastic injection.
[0057]
57. Method for making a screen set for material selection according to claim 49, characterized by the fact that the subgrade includes at least one base member that has first fasteners that join the second fasteners of second base members second subgrades and attach the subgrade and the second subgrades together.
[0058]
58. Method for making a material selection screen assembly according to claim 49, characterized in that the first fixing elements are clips and the second fixing elements are clip openings that snap into place and secure securely the subgrade and the second subgrades.
[0059]
59. Method for making a screen assembly for material selection according to claim 49, characterized in that the screen element includes a screen element attachment arrangement configured to join a subgrade attachment arrangement .
[0060]
60. Method for making a screen set for material selection, characterized by the fact that it comprises: injection molding of a sieve element, the sieve element including a sieve element sieve surface with sieve openings; manufacture a subgrade that supports the screen element, the subgrade having a grid structure with grid openings, the screen element covering at least one grid opening, in which at least one of the screen elements and the subgrade is a single piece molded by thermoplastic injection; and securing the screen element to an upper surface of the subgrade, the screen assembly having a continuous screen assembly screening surface composed of various screen element screening surfaces.
[0061]
61. Method for manufacturing a screen assembly for material selection, according to claim 60, characterized by the fact that it also includes the attachment of a first binder bar to a first end of the screen assembly and the attachment of a second binder bar to a second end of the screen assembly, where the first and second bonding bars join the subgrades.
[0062]
62. Method for manufacturing a screen assembly for material selection according to claim 60, characterized in that the connecting bar is configured to distribute a load over the first and second ends of the screen assembly.
[0063]
63. Method for making a screen assembly for material selection according to claim 60, characterized in that the screen element includes screen surface elements that form the sieve openings, the sieve openings being elongated grooves having a distance of 43 μm to 1000 μm between the internal surfaces of each element of the screen surface.
[0064]
64. Method for manufacturing a screen assembly for material selection according to claim 60, characterized in that the screen element includes surface elements of the screen that form the sieve openings, the sieve openings being elongated grooves , having a distance of 70 μm to 180 μm between the internal surfaces of each element of the sieve surface.
[0065]
65. Method for making a screen assembly for material selection according to claim 60, characterized in that the screen element includes screen surface elements that form the sieving openings, the sieve opening being elongated grooves having a distance of 43 μm to 106 μm between the internal surfaces of each element of the sieve surface.
[0066]
66. Method for making a screen assembly for material selection according to claim 60, characterized in that the screen element includes screen surface elements that form the sieve openings, the sieve openings being elongated grooves having a width and a length, the width being from 0.044 mm to 4 mm and the length from 0.088 mm to 60 mm.
[0067]
67. Method for making a screen set for material selection according to claim 60, characterized by the fact that the subgrade includes at least one base member with fasteners that join the fasteners of other base members from other subgrades and attach the subgrades together.
[0068]
68. Method for making a screen assembly for material selection according to claim 60, characterized by the fact that the fasteners are staples and staple openings that fit in place and firmly hold the subgrades.
[0069]
69. Screen assembly composed of one or more screen elements and one or more subgrade elements, characterized by the fact that it comprises: an injection molded screen element; and an injection molded subgrade, in which the screen element is attached to the subgrade via laser welding.
[0070]
70. Screen assembly composed of one or more screen elements and one or more subgrade elements according to claim 69, characterized in that the screen element includes substantially clear thermoplastic polyurethane.
[0071]
71. Screen assembly composed of one or more screen elements and one or more subgrade elements according to claim 69, characterized by the fact that the screen element includes a series of screen openings.
[0072]
72. Screen assembly consisting of one or more screen elements and one or more subgrade elements according to claim 69, characterized in that the screen assembly has a first adhesion arrangement on a lower surface of the screen and the subgrade has a second adhesion arrangement on an upper surface of the subgrade.
[0073]
73. Screen assembly composed of one or more screen elements and one or more subgrade elements, according to claim 69, characterized by the fact that the first adhesion arrangement is a plurality of pocket cavities and the second arrangement of pockets adhesion is a plurality of melting bars.
[0074]
74. Screen assembly composed of one or more screen elements and one or more subgrade elements according to claim 73, characterized by the fact that the plurality of pocket cavities are configured to match the plurality of melting bars .
[0075]
75. Screen assembly composed of one or more screen elements and one or more subgrade elements, according to claim 73, characterized by the fact that the melting bars incorporate at least one of a carbon and a graphite material.
[0076]
76. Screen assembly composed of one or more screen elements and one or more subgrade elements, according to claim 69, characterized by the fact that the screen element has a series of screen openings.
[0077]
77. Screen assembly composed of one or more screen elements and one or more subgrade elements according to claim 76, characterized by the fact that the sieving openings are elongated cracks with a width and a length, the width being the sieving openings of 43 μm to 300 μm between the internal surfaces of each element of the sieve surface.
[0078]
78. Screen assembly composed of one or more screen elements and one or more subgrade elements, characterized by the fact that it comprises: a screen element that is a single piece molded by thermoplastic injection; and a subgrade which is a single injection molded part containing nylon and an additional material, where the additional material includes carbon or graphite, where the screen element is attached to the subgrade via laser welding.
[0079]
79. Screen assembly composed of one or more screen elements and one or more subgrade elements, according to claim 78, characterized by the fact that the screen element has a series of screen openings.
[0080]
80. Screen assembly composed of one or more screen elements and one or more subgrade elements according to claim 79, characterized in that the sieving openings are elongated cracks with a width and a length, the width being the sieving openings of 43 μm to 300 μm between the internal surfaces of each element of the sieve surface.
[0081]
81. Sieve set consisting of one or more mesh elements and one or more subgrade elements according to claim 79, characterized in that several subgrades are attached together and a plurality of pebble elements form a sieve surface to be continued.

类似技术:

---

公开号 | 公开日 | 专利标题

---

BR112016025640B1|2021-03-02|injection molding methods and apparatus

---

BR112014029429B1|2020-07-21|screen assembly for sieving materials, and method for making a screen assembly for sieving materials

---

US10843230B2|2020-11-24|Injection molded screening apparatuses and methods

---

OA18069A|2018-04-06|Injection molded screening apparatuses and methods.

同族专利:

---

公开号 | 公开日

---

BR122020012127B1|2021-02-23|

---

US20210121919A1|2021-04-29|

---

EA201692228A1|2017-07-31|

---

AR100242A3|2016-09-21|

---

AP2016009592A0|2016-11-30|

---

CN106255556B|2020-03-13|

---

CA3109849A1|2015-11-05|

---

US10967401B2|2021-04-06|

---

AU2018256563A1|2018-11-22|

---

MX2016014309A|2017-04-27|

---

US20160310994A1|2016-10-27|

---

EP3854488A1|2021-07-28|

---

EP3137233A2|2017-03-08|

---

CA3032710C|2021-02-16|

---

EA202190023A3|2021-06-30|

---

BR122020012131B1|2021-02-23|

---

CA3032719A1|2015-11-05|

---

EA202190023A2|2021-03-31|

---

AU2018256563B2|2020-04-16|

---

AU2020204620A1|2020-07-30|

---

BR122020012134B1|2021-02-23|

---

AU2020204620B2|2021-09-23|

---

AU2015252993B2|2018-08-09|

---

US20190314861A1|2019-10-17|

---

CA3032704A1|2015-11-05|

---

AU2020227097A1|2020-09-24|

---

CA3032704C|2021-02-16|

---

US20190217338A1|2019-07-18|

---

WO2015168516A3|2015-12-30|

---

WO2015168516A2|2015-11-05|

---

US9884344B2|2018-02-06|

---

CA2947714A1|2015-11-05|

---

CN110947619A|2020-04-03|

---

CA2947714C|2019-03-19|

---

CN106255556A|2016-12-21|

---

AU2015252993A1|2016-11-17|

---

CN111468399A|2020-07-31|

---

CA3032710A1|2015-11-05|

---

US9409209B2|2016-08-09|

---

US10933444B2|2021-03-02|

---

US20140262978A1|2014-09-18|

---

CA3032719C|2021-11-16|

---

US20170312785A9|2017-11-02|

---

EP3871796A1|2021-09-01|

---

US20180185880A1|2018-07-05|

---

US10259013B2|2019-04-16|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

---

US3002623A|1959-03-27|1961-10-03|Charles E Fontaine|Screen attachment for cement mixers|

---

US3377322A|1963-12-30|1968-04-09|Du Pont|Thermoplastic polyurethane elastomers suitable for injection molding|

---

DE1209856B|1964-10-21|1966-01-27|Albert Wehner|Sieve bottom|

---

US3401800A|1965-10-04|1968-09-17|Bird Machine Co|Centrifuge bowl|

---

US3713541A|1971-05-10|1973-01-30|Bird Machine Co|Screening machine with slotted screen|

---

US4028230A|1975-04-02|1977-06-07|Jesse Rosenblum|Vibratory separator screen and method of manufacture|

---

DE2649376A1|1975-11-04|1977-05-12|Terence Charles Adams|METHOD OF MANUFACTURING A SCREEN|

---

FR2349369B2|1976-04-27|1978-08-25|Tytko Jean|

---

AT344629B|1976-05-21|1978-08-10|Steinhaus Gmbh|SIEBFELD|

---

GB1558086A|1976-11-10|1979-12-19|Spiller C M|Screening|

---

ZA774472B|1977-07-25|1979-06-27|Herrmann Screens Mfg Co Ltd|Improvements in or relating to screening apparatus|

---

US4188208A|1978-05-22|1980-02-12|Newmont Exploration Limited|Recovery of gold from carbonaceous gold-bearing ores|

---

US4222865A|1979-02-16|1980-09-16|Irathane Systems Incorporated|Trommel screen unit|

---

US4361239A|1980-02-04|1982-11-30|Kumandan Krishna R|Size grader for pod vegetables|

---

DE3008931A1|1980-03-08|1981-09-17|Hein, Lehmann AG, 4000 Düsseldorf|SYSTEM SCREEN|

---

US4452656A|1982-08-13|1984-06-05|Uop Inc.|Method and apparatus for making plastic screen panels|

---

CH657287A5|1982-09-27|1986-08-29|Escher Wyss Ag|CENTRIFUGAL SCREEN.|

---

US4526682A|1983-12-06|1985-07-02|Ferrell-Ross, Inc.|Screen assembly for separating particulate material|

---

US4675065A|1985-08-30|1987-06-23|Bar Ilan University|Method for securing a microsieve to a support member|

---

US4819809A|1985-09-09|1989-04-11|Derrick Manufacturing Corporation|Reinforced polyurethane vibratory screen|

---

DE3542635C1|1985-12-03|1987-02-19|Steinhaus Gmbh|Screen component for system screen floors|

---

US4857176A|1986-08-04|1989-08-15|Derrick Manufacturing Corporation|Reinforced molded polyurethane vibratory screen|

---

GB2203061B|1987-04-10|1991-03-27|Thule United Ltd|Filter screen assembly|

---

DE3716472C2|1987-05-16|1989-02-23|Steinhaus Gmbh, 4330 Muelheim, De|

---

US5149739A|1988-08-01|1992-09-22|The Bfgoodrich Company|Fiber-reinforced thermoplastic elastomer polyurethane compositions with either modified and/or unmodified polyolefins|

---

US4882054A|1988-08-22|1989-11-21|Derrick Manufacturing Corporation|Vibratory screening machine with tiltable screen frame and adjustable discharge weir|

---

US4932112A|1988-10-06|1990-06-12|Tim Tikkanen|Sieve plate and process for making it|

---

WO1990009285A1|1989-02-16|1990-08-23|Oki Electric Industry Co., Ltd.|Wire dot printing head|

---

US4986900A|1989-04-04|1991-01-22|A. Ahlstrom Corporation|Sectional screen cylinder|

---

DE3927202A1|1989-08-17|1991-02-21|Fiedler Heinrich Gmbh|CYLINDRICAL SIEVE BASKET|

---

US5282538A|1990-10-31|1994-02-01|Multotec Cyclones Limited|Flotation column|

---

US5213217A|1991-10-25|1993-05-25|Galton Zanley F|Screening system and method for screening particulate material|

---

GB2262456B|1991-12-20|1995-07-19|Anglo Amer Corp South Africa|Mineral processing screen separator|

---

US5332101A|1992-05-06|1994-07-26|Derrick Manufacturing Corporation|Screen aligning, tensioning and sealing structure for vibratory screening machine|

---

US5378364A|1992-09-14|1995-01-03|Baker Hughes Incorporated|Conical screen basket centrifuge|

---

US5958236A|1993-01-13|1999-09-28|Derrick Manufacturing Corporation|Undulating screen for vibratory screening machine and method of fabrication thereof|

---

EP0680385B1|1993-01-13|1999-09-15|Derrick Manufacturing Corporation|Undulating screen for vibratory screening machine and method of fabrication thereof|

---

US6565698B1|1993-04-30|2003-05-20|Varco I/P, Inc.|Method for making vibratory separator screens|

---

US20030042179A1|1998-10-30|2003-03-06|Adams Thomas C.|Vibratory separator screens|

---

US6443310B1|1993-04-30|2002-09-03|Varco I/P, Inc.|Seal screen structure|

---

US5385669A|1993-04-30|1995-01-31|Environmental Procedures, Inc.|Mining screen device and grid structure therefor|

---

US5971159A|1993-04-30|1999-10-26|Tuboscope I/P, Inc.|Screen assembly for a vibratory separator|

---

US5437374A|1993-07-23|1995-08-01|Osborn Engineering, Inc.|Adjustable orifice trommel|

---

GB9404071D0|1994-03-03|1994-04-20|United Wire Ltd|Improved sifting screen|

---

US5558042A|1994-06-01|1996-09-24|Bradley; James E.|Aquaculture filtration system employing a rotating drum filter|

---

US5472096A|1994-07-15|1995-12-05|Multotec Cyclones Limited|Spiral concentrator|

---

ZA957728B|1994-09-16|1996-04-23|Multotec Cyclones|Cast iron hydrocyclone|

---

US5575618A|1994-11-25|1996-11-19|Brandon; Ronald E.|Steam turbine steam strainer|

---

CA2178189A1|1995-06-06|1996-12-07|Nardus Terblanche|Flotation column with constant feed arrangement|

---

US5816413A|1995-09-08|1998-10-06|W.S. Tyler, Canada|Wire screen deck having replaceable modular screen panels|

---

AUPO213796A0|1996-09-05|1996-09-26|Lettela Proprietary Limited|Modular screen panel|

---

US5753820A|1996-10-25|1998-05-19|Arthur D. Little, Inc.|Fluid pressure sensing unit incorporating diaphragm deflection sensing array|

---

DE69819371T2|1997-03-01|2004-07-22|United Wire Ltd.|Support frame for a filter screen|

---

AU9613498A|1997-12-09|1999-07-01|Multotec Process Equipment Ltd|A method and apparatus for aeration of liquids or slurries|

---

DE19804493B4|1998-02-05|2008-03-27|Pall Corp.|Filter medium for solid / liquid separation|

---

US6312610B1|1998-07-13|2001-11-06|Phase Inc.|Density screening outer wall transport method for fluid separation devices|

---

US6769550B2|2002-01-16|2004-08-03|Varco I/P, Inc.|Screen assemblies for shale shakers|

---

CA2298968A1|1999-02-22|2000-08-22|Jeremy Brett Bosman|Hydrocyclone with removal of misplaced coarse fraction in overflow|

---

AUPP904499A0|1999-03-08|1999-03-25|Cmi Malco Pty Ltd|A screening apparatus|

---

US6669027B1|1999-03-19|2003-12-30|Derrick Manufacturing Corporation|Vibratory screening machine and vibratory screen and screen tensioning structure|

---

CA2269314C|1999-04-20|2006-09-19|Neville P. Nixon|Wear resistant screen, screen panel or the like|

---

US6431366B2|1999-06-16|2002-08-13|Derrick Manufacturing Corporation|Vibratory screening machine with stacked and staggered screening units|

---

US6530484B1|1999-11-18|2003-03-11|Multotec Process Equipment Ltd.|Dense medium cyclone separator|

---

AUPQ455899A0|1999-12-09|2000-01-06|Usf Johnson Screens Pty Ltd|A screening module and a screening assembly inlcuding such module|

---

US6267246B1|2000-02-14|2001-07-31|Western Wire Works, Inc.|Screening system for screening or diverting particulate material|

---

KR200191289Y1|2000-02-19|2000-08-16|주식회사대현정수|A screen for drum filter|

---

CA2361085A1|2000-11-09|2002-05-09|Multotec Process Equipment Limited|Hydro cyclone with elongate inlet|

---

CA2802168A1|2001-04-16|2002-10-24|J & L Fiber Services, Inc.|Screen cylinder and method|

---

GB0119523D0|2001-08-10|2001-10-03|Ever 1529 Ltd|Screen system|

---

CA2467091C|2001-11-13|2009-10-20|Degussa Ag|Electromagnetic field curable adhesive compositions and assemblies which are able to be dissociated|

---

WO2003066243A1|2002-02-11|2003-08-14|Multotec Manufacturing Limited|Screen deck|

---

US7484625B2|2003-03-13|2009-02-03|Varco I/P, Inc.|Shale shakers and screens with identification apparatuses|

---

US20050133465A1|2002-06-12|2005-06-23|Derrick Corporation|Vibratory screen assembly and method of manufacture|

---

CN100539615C|2003-01-06|2009-09-09|伟易达通讯设备有限公司|Integrated collapsible belt clamp|

---

US7063214B2|2003-02-04|2006-06-20|Varco I/P, Inc.|Interlocking screens for vibratory separators|

---

RU2241550C1|2003-03-31|2004-12-10|Открытое акционерное общество "Уралгипромез"|Vibratory screen|

---

US7264125B2|2003-04-23|2007-09-04|Derrick Corporation|Undulating molded plastic vibratory screen|

---

US7654395B2|2003-11-25|2010-02-02|Weatherford Australia Pty Limited|Screening module|

---

SE527470C8|2004-02-13|2006-07-25|Sandvik Intellectual Property|visibility Tires|

---

SE527499C2|2004-03-26|2006-03-21|Sandvik Intellectual Property|Adapter device and vibration screen including an adapter device|

---

TWM258183U|2004-06-01|2005-03-01|Walrus Pump Co Ltd|Submergible pump with dual filtering device|

---

US7654394B2|2004-06-14|2010-02-02|Action Equipment Company, Inc.|Flexible mat screening or conveying apparatus|

---

GB0427756D0|2004-12-18|2005-01-19|United Wire Ltd|Improvements in and relating to sifting screens|

---

CA2605711C|2005-04-20|2014-04-01|Weatherford Australia Pty Limited|A screening module|

---

AU2005201683B2|2005-04-20|2011-02-24|Flsmidth A/S|A support frame|

---

US7249677B2|2005-05-13|2007-07-31|M-I L.L.C.|Dual hardness composite screen frame|

---

ZA200607875B|2005-09-22|2008-05-28|Magnapower Proprietary Ltd|Dewatering of aqueous magnetite concentrates|

---

CN101291992B|2005-10-17|2011-06-08|普立万公司|Thermoplastic polyurethane powder compositions and uses|

---

CA2630773C|2005-11-28|2014-10-07|Multotec Manufacturing Limited|Screen panel fastener and fastening arrangement|

---

US20070151920A1|2005-12-06|2007-07-05|Kay Ronald J|System and method of micromolded filtration microstructure and devices|

---

CA2573726C|2006-01-13|2014-10-21|Johnson Screens Pty Ltd.|A screening module|

---

US20070195143A1|2006-02-17|2007-08-23|Xerox Corporation|Microfilter manufacture process|

---

US7753213B2|2006-03-30|2010-07-13|M-I Llc|Composite screen|

---

NZ601008A|2006-08-01|2013-08-30|Ludowici Australia Pty Ltd|Screen module for vibratory screening apparatus|

---

US7735656B1|2006-09-18|2010-06-15|Bassler Alfred S|Self-clearing rotary screening system|

---

US7992719B2|2006-09-29|2011-08-09|M-I L.L.C.|Composite hookstrip screen|

---

US7891497B2|2006-09-29|2011-02-22|M-I L.L.C.|Peripheral sealing system for pre-tensioned screens|

---

US8393474B2|2006-09-29|2013-03-12|United Wire Limited|Injection molded grid for saving screen frames|

---

US7909172B2|2006-09-29|2011-03-22|M-I L.L.C.|Composite screen with integral inflatable seal|

---

US7819255B2|2006-09-29|2010-10-26|M-I Llc|Screen for a vibratory separator|

---

US9149839B2|2006-09-29|2015-10-06|M-I L.L.C.|Sealing system for pre-tensioned composite screens|

---

US7942353B2|2006-10-26|2011-05-17|Allegheny Paper Shredders Corporation|Adjustable screen for material destruction apparatus|

---

AU2006243879B2|2006-11-28|2011-07-07|Flsmidth A/S|A screening module retaining assembly|

---

US9056335B2|2007-03-21|2015-06-16|Derrick Corporation|Method and apparatuses for screening|

---

CN103480568B|2007-03-21|2016-10-19|德里克公司|Pre-screening method and pre-screening device|

---

US7578394B2|2007-03-21|2009-08-25|Derrick Corporation|Method and apparatuses for screening|

---

US8443984B2|2007-03-21|2013-05-21|Derrick Corporation|Method and apparatus for screening|

---

JP2008255145A|2007-04-02|2008-10-23|Nippon Carbide Ind Co Inc|Polyurethane-based master batch|

---

BRPI0812154B1|2007-05-23|2020-02-11|Ludowici Australia Pty Ltd|VIBRATORY SCREEN PANEL|

---

TWM328904U|2007-09-13|2008-03-21|Cheng You Machinery Co Ltd|Improved structure of roller screening machine|

---

US8517179B2|2007-10-05|2013-08-27|M-I L.L.C.|Vibratory separator screen attachment|

---

TW200925535A|2007-12-06|2009-06-16|Man Zai Ind Co Ltd|Refrigerant storing device for condenser|

---

SE531876C2|2007-12-19|2009-09-01|Sandvik Intellectual Property|A vibration screen with a wear protection|

---

TWM340860U|2008-03-10|2008-09-21|Jun-Rong Chen|Mesh-adjustable cylindrical sieving device|

---

CN201185517Y|2008-04-16|2009-01-21|英华达电子有限公司|Portable electronic device with double sliding covers|

---

GB2461726A|2008-07-10|2010-01-13|United Wire Ltd|Sifting Screen|

---

GB2461725B|2008-07-10|2012-06-13|United Wire Ltd|Improved sifting screen|

---

GB0812576D0|2008-07-10|2008-08-13|United Wire Ltd|Separating screens|

---

AU2009291508B2|2008-09-11|2015-09-17|Flsmidth A/S|Screen securing device|

---

CN101716573B|2008-10-09|2014-05-07|株式会社奥普特尼克斯精密|Sieve, sieve device, solder ball and method for sieving spherical particles|

---

GB0822405D0|2008-12-09|2009-01-14|British American Tobacco Co|A package for tobacco products|

---

GB0823286D0|2008-12-20|2009-01-28|Stelex Construction Eqipment Ltd|Trommel screen|

---

GB2456377B|2008-12-23|2009-11-25|Broadbent & Sons Ltd Thomas|Improvements in and relating to screen filters|

---

US7959009B2|2008-12-23|2011-06-14|Polydeck Screen Corporation|System and apparatus for protecting a support frame used in a screening arrangement|

---

DE102009010684B4|2009-02-27|2014-10-23|Siebtechnik Gmbh|screen drum|

---

US8021547B2|2009-05-01|2011-09-20|Hukki Ari M|Screen clamp|

---

NO336396B1|2009-10-27|2015-08-10|Optipro As|An improved cell insert filter for a screening machine filter|

---

US9403192B2|2010-04-19|2016-08-02|Derrick Corporation|Polyurethane screen|

---

US9010539B2|2010-04-19|2015-04-21|Derrick Corporation|Polyurethane vibratory screen|

---

US8584866B2|2010-04-19|2013-11-19|Derrick Corporation|Polyurethane vibratory screen|

---

US9375756B2|2010-04-19|2016-06-28|Derrick Corporation|Polyurethane vibratory screen|

---

KR20150127141A|2013-03-15|2015-11-16|데릭 코포레이션|Polyurethane vibratory screen|

---

EP2571630B1|2010-05-21|2016-08-24|Tega Industries Limited|Screen panel|

---

US8633283B2|2010-06-15|2014-01-21|Basf Se|Process for producing blends made of polylactides and of thermoplastic polyurethanes |

---

CN201855172U|2010-10-20|2011-06-08|广东新宝电器股份有限公司|Egg breaker with filtering function|

---

WO2012075127A2|2010-12-01|2012-06-07|Vermeer Manufacturing Company|Grinder with adjustable screens|

---

CN103547629B|2011-04-21|2016-09-07|路博润高级材料公司|Electrostatically dissipative polycarbonate compositions|

---

DE102011119344A1|2011-10-11|2013-04-11|Focke & Co. |Pack for cigarettes and method of making same|

---

FR2981600B1|2011-10-25|2013-11-15|Rhodia Operations|PROCESS FOR THE PREPARATION OF POLYAMIDE PELLETS|

---

US20130168387A1|2011-12-29|2013-07-04|Eastman Chemical Company|Wood treatment method and apparatus employing multiple vessels and multiple wood-transporting carts|

---

CN103203322B|2012-01-13|2017-03-01|美卓矿物公司|There is membrane component in the sieve of ceramic component with holes|

---

US20130277281A1|2012-02-21|2013-10-24|Guy L. McClung, III|Nanostrong vibratory screens & separators|

---

ES2706411T3|2012-05-25|2019-03-28|Derrick Corp|Injection molding sieving apparatus and method|

---

US10576502B2|2012-05-25|2020-03-03|Derrick Corporation|Injection molded screening apparatuses and methods|

---

CN203304173U|2012-05-25|2013-11-27|德里克公司|Screening assembly and screening elements|

---

US9409209B2|2012-05-25|2016-08-09|Derrick Corporation|Injection molded screening apparatuses and methods|

---

CA2876340C|2012-06-11|2018-07-17|M-I L.L.C.|Vibratory separator screen|

---

MX2015001109A|2012-08-06|2015-04-08|Tega Ind Ltd|Trommel assembly.|

---

US8827545B2|2012-08-28|2014-09-09|Sanyasi R. Kalidindi|Apparatus for alternately sifting and blending powders in the same operation|

---

TWM447274U|2012-09-25|2013-02-21|Yu-Lin Mao|Multi-functional sieving device|

---

EA201590966A1|2012-11-20|2015-09-30|Тега Индастриз Лимитед|Latching fastening system for crashing panels|

---

GB2497873B|2013-02-05|2014-01-29|Nat Oilwell Varco Lp|Screen assembly and a method of making same|

---

TWM459903U|2013-02-06|2013-08-21|Univ Southern Taiwan Sci & Tec|Filter cartridge containing hollow fiber membrane|

---

US9089877B2|2013-03-15|2015-07-28|Michael McGrath, JR.|Backing screen panels for vibrating screen separator|

---

WO2014181356A1|2013-05-09|2014-11-13|Tega Industries Limited|Trommel assembly having a spiral assembly with decaying pitch|

---

US20140342110A1|2013-05-15|2014-11-20|Chemtura Corporation|Thermoplastic Polyurethane From Low Free Monomer Prepolymer|

---

TWM470701U|2013-07-01|2014-01-21|Tian-Fu Li|Improved filter core structure|

---

TWM468568U|2013-07-09|2013-12-21|Aai Motorsports Co|Engine-oil filter heat sink|

---

CA2933574A1|2013-12-10|2015-06-18|Eric Cady|High capacity filtering screen|

---

PE20161039A1|2014-01-14|2016-10-16|Derrick Corp|IMPROVED METALS SORPTION METHODS AND SYSTEMS USING BETWEEN-STAGE SCREENING|

---

TWM481766U|2014-02-27|2014-07-11|Deng-Zhao Jian|Improved filter core structure|

---

CA2887314A1|2014-04-08|2015-10-08|Lettela Pty Limited|A screening panel and method of fixing|

---

US9643213B2|2014-06-26|2017-05-09|M-I L.L.C.|Reverse crowned filter assembly|

---

DE102014009702B3|2014-07-02|2015-08-06|Rhewum Gmbh|Plastic screen covering for a screening machine for classifying in particular fine-grained bulk material|

---

NL2014210B1|2015-01-29|2017-01-27|Oijense Bovendijk B V|Sieve device and method for separating dry granular material.|

---

EP3317028A4|2015-06-30|2019-06-26|Aqseptence Group, Inc.|Trommel screen clamping apparatus|

---

TWM513735U|2015-07-16|2015-12-11|Savant Electronics Inc|Filter core structure and secondary filter inner tube|

---

TWM527789U|2016-04-29|2016-09-01|Air O Filter Environment Systems Inc|Double-layered air purifying filter device of oil fume and mist for cooking|

---

TWM529549U|2016-06-24|2016-10-01|Cong-Wei Chen|Filtering bucket|

---

TWM532900U|2016-09-12|2016-12-01|Jian-Hua Wang|Oil smoke air-purifying machine for teppanyaki|

---

IT201600132388A1|2016-12-29|2018-06-29|Cangini Benne Srl|SCREENING BUCKET|

---

TWM544259U|2017-01-23|2017-07-01|Victory Marketing Corp|Filtering and brewing pot for preventing lid from dropping|

---

CN110691821A|2017-04-28|2020-01-14|德里克公司|Thermoplastic composition, method, apparatus and use|

---

US11213857B2|2017-06-06|2022-01-04|Derrick Corporation|Method and apparatus for screening|

---

WO2018226878A1|2017-06-06|2018-12-13|Derrick Corporation|Method and apparatuses for screening|

---

TWM556176U|2017-10-20|2018-03-01|Air O Filter Environment Systems Inc|Oil mist collector capable of detecting clogging of filter|ES2706411T3|2012-05-25|2019-03-28|Derrick Corp|Injection molding sieving apparatus and method|

---

US10576502B2|2012-05-25|2020-03-03|Derrick Corporation|Injection molded screening apparatuses and methods|

---

US11161150B2|2012-05-25|2021-11-02|Derrick Corporation|Injection molded screening apparatuses and methods|

---

US9409209B2|2012-05-25|2016-08-09|Derrick Corporation|Injection molded screening apparatuses and methods|

---

SE539965C2|2015-06-23|2018-02-13|Veolia Water Solutions & Tech|Filter panel with a controlled liquid lift, and a drum filter for filtering liquid|

---

EP3120685B1|2015-07-23|2018-11-21|CNH Industrial Belgium nv|Sieve arrangements for a cleaning system in an agricultural harvester|

---

JP2019533573A|2016-10-14|2019-11-21|デリック・コーポレーション|Apparatus, method and system for vibrating sieve|

---

US11052427B2|2016-10-14|2021-07-06|Derrick Corporation|Apparatuses, methods, and systems for vibratory screening|

---

PE20201174Z|2019-07-02|2020-10-29|Derrick Corp|VIBRATORY SCREENING APPARATUS, METHODS AND SYSTEMS|

---

AU2020299538A1|2019-07-02|2022-02-03|Derrick Corporation|Apparatuses, methods, and systems for vibratory screening|

---

US11185801B2|2016-10-14|2021-11-30|Derrick Corporation|Apparatuses, methods, and systems for vibratory screening|

---

US10342222B2|2017-03-23|2019-07-09|Verily Life Sciences Llc|Sieving devices for pupae separation|

---

US10835925B2|2017-03-23|2020-11-17|Verily Life Sciences Llc|Sieving devices for pupae separation|

---

US10772309B2|2017-03-23|2020-09-15|Verily Life Sciences Llc|Sieving apparatuses for pupae separation|

---

CN110691821A|2017-04-28|2020-01-14|德里克公司|Thermoplastic composition, method, apparatus and use|

---

US11213857B2|2017-06-06|2022-01-04|Derrick Corporation|Method and apparatus for screening|

---

FI12523U1|2018-10-04|2019-12-13|Derrick Corp|Screen basket apparatus, screening cartridge assembly and screen assembly|

---

WO2018226878A1|2017-06-06|2018-12-13|Derrick Corporation|Method and apparatuses for screening|

---

CN109453551A|2017-09-06|2019-03-12|欧盛腾集团有限公司|Sieve bend|

---

CN108057616B|2017-12-08|2020-12-25|马鞍山起劲磁塑科技有限公司|Surface treatment method of drum screen applied to mineral separation industry|

---

EP3898200A1|2018-12-19|2021-10-27|Covestro LLC|Process for manufacturing fully recyclable mining screens|

---

USD890236S1|2019-02-07|2020-07-14|Derrick Corporation|Vibratory screening machine|

法律状态:
2020-01-14| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

---

2020-12-08| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

---

2021-03-02| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 01/05/2015, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

---

申请号 | 申请日 | 专利标题

---

US14/268,101|US9409209B2|2012-05-25|2014-05-02|Injection molded screening apparatuses and methods|

---

US14/268,101|2014-05-02|

---

PCT/US2015/028737|WO2015168516A2|2014-05-02|2015-05-01|Injection molded screening apparatuses and methods|BR122020012134-3A| BR122020012134B1|2014-05-02|2015-05-01|injection molding methods and apparatus|

---

BR122020012131-9A| BR122020012131B1|2014-05-02|2015-05-01|injection molding methods and apparatus|

---

BR122020012127-0A| BR122020012127B1|2014-05-02|2015-05-01|injection molding methods and apparatus|