• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    Forming machine with - a fixed first platen (2), - a first platen (2) movable second platen (3), - at least one tubular snorkel (5), wherein the at least one snorkel (5) fixed to the second platen (3 ), - an injection unit (6) for plastifying and injecting a molding compound (7), wherein at least one stop (8) is provided, which is formed so that the injection unit (6) in the open state of the closing unit (9) against the at least one stop (8) can be clamped and that the injection unit (6) is released from the at least one stop (8) by force of the at least one snorkel (5) on the injection unit (6) in a closed state of the closing unit (9) , (
    公开号:AT520325A4
    申请号:T50189/2018
    申请日:2018-03-07
    公开日:2019-03-15
    发明作者:Eppich Stephan
    申请人:Engel Austria Gmbh;
    IPC主号:
    专利说明:

    The present invention relates to a molding machine having the features of the preamble of claim 1 and a method of operating a molding machine.
    By molding machines can be understood injection molding machines, transfer molding, pressing and the like.
    From the prior art, it is known in forming machines with a first fixed platen and a second mold platen movable to a mold clamping plate to supply a molding compound via the second movable mold platen a mold, wherein the mold between the first and the second platen is attached.
    In general, the injection unit for plasticizing and injecting a molding compound is provided on a side facing away from the second platen of the first platen. However, if injection from the second platen is desired (for example, because the second platen is a center plate), a tubular snorkel is used to direct the plasticized molding compound to be injected from the injection unit to the second platen. This tubular snorkel is usually firmly attached to the second platen.
    Such systems known from the prior art, in which a molding compound is supplied via a movable platen, are used in so-called stack molds or else tools with a plurality of parting planes. A stack mold usually consists of a plurality of tool parts, namely: a mold part which is fixed to the fixed, first mold clamping plate of a forming machine, a mold part which is mounted on a movable further mold platen, and one or more mold platens attached to a movable mold second platen are attached, wherein the second platen is usually disposed between the first and the further platen and is often referred to as the center plate.
    In order to direct the plastified, injected molding compound to a center plate - referred to below as a second platen - in such a floor tools, a tubular snorkel is used, which is attached to the second platen. This snorkel directs the plasticized molding compound to be injected from an injection unit to the center plate, which center plate conveys the molding compound to the molding tool parts which are fixed to the center plate.
    Such a stack tool (also called a tool with several parting planes) is known, for example, from DE 10 2005 047995 B4, this document describing a method for performing a stamping process with a stack mold.
    In order to better fill thin-walled moldings with improved orientation and residual stress properties of the moldings and / or to achieve complicated injection and Nachdrucksvorgänge in the production of thick-walled moldings and / or produce largely freed from residual stresses moldings, it may be necessary with a stack tool to perform so-called injection-compression, often referred to in this context only as embossing. Embossing is known in various embodiments from the prior art and therefore need not be described in detail here. When injection molding with stack molds, it is important that, for example, a nozzle of the injection unit is pressed against the snorkel to supply a plasticized molding compound to the snorkel, even though the snorkel still moves in the direction of the injection unit during the embossing movement. The contact pressure on the snorkel should be as constant as possible during the embossing process. If the snorkel is loaded too much, it could be damaged or the second platen (on which the snorkel is placed) could be damaged
    Floor tool could experience a position deviation. To solve this problem, various possibilities are known from the prior art.
    A first known from the prior art embodiment provides that the injection unit is biased on the snorkel before performing the embossing stroke by a spring element. During the embossing stroke, the snorkel is now moved further in the direction of the injection unit, whereby the injection unit is pushed away from the stationary first platen by the snorkel, this relative movement between the injection unit and fixed first platen is compensated by the spring element by the spring element is further tensioned. By this further tensioning of the spring element, the injection unit is still held on the snorkel. When opening the closing unit, the snorkel is now moved away from the injection unit, whereby the spring element is relaxed. The disadvantage of this is that at each molding cycle of the molding machine said spring element is completely relieved, which has a negative impact on the life of the spring element.
    Another disadvantage of the complete relaxation of the spring element is that when closing the tool, the tool is usually initially closed with a high closing speed and shortly before placing the individual mold parts, this closing movement is continuously reduced until the mold parts sit on each other or only with the intended Embossing gap are positioned to each other. Now, when the snorkel is moved to the injection unit at a higher drive speed, a shock occurs continuously with each closing of the forming machine, which also has a negative effect on the life of the components and possibly leads to a deformation of these. To avoid this, the speed of the second platen together with the snorkel had to be reduced earlier, which would extend the cycle time.
    A further embodiment variant is shown by DE 10 2015 112508 A1. This describes the provision of a telescopic portion of the snorkel or nozzle of an injection unit. Thus, this telescopic region of the snorkel or the nozzle can be biased by a spring element against the respective counterpart. When the embossing stroke is carried out, the telescoping area can be shifted into one another or the spring element can be tensioned further in order to carry out the compensation of the embossing stroke. By such a configuration, it is possible to provide the injection unit fixed to the machine frame of the molding machine, in other words to fix the injection unit with a fixed distance to the fixed first platen. The disadvantage of this, however, is that the nozzle or the snorkel is filled with molding compound while they compensate for the embossing stroke. This means that the telescoping portion is moved into each other by the embossing stroke and thus the volume of the tubular telescoping portion is reduced, whereby the molding material therein is either ejected (which is not possible in use, since the cavity formed by the mold parts already are completely filled and a return flow into the injection unit is not possible) or the molding compound is subjected to an additional pressure. This substantial increase in the pressure of the molding compound again puts the designers in front of the task of sealing the components with regard to an unwanted escape of the molding compound, which is not trivially solvable with regard to the high pressure that arises.
    Based on this prior art, the present invention seeks to provide a molding machine and / or a method for operating a molding machine, which have a simplified and / or less complicated design and / or allow.
    This object is achieved by a shaping machine having the features of claim 1 and a method of operating a shaping machine having the features of claim 15. Advantageous embodiments are defined in the dependent claims.
    According to the invention, at least one stop is provided, which is configured so that the injection unit is clamped in the open state of the closing unit against the at least one stop and that the injection unit in a closed state of the closing unit by the action of the at least one snorkel on the injection unit of the at least one Stop is released.
    A closed state of the closing unit is understood to mean a state in which injection of a molding compound into a mold fastened between the first and second mold platens is or may be made. In a closed state, the mold parts of the mold are adjacent to each other or have only a small gap to each other, so that when molding molding material in the cavity formed by the mold parts no molding compound can escape from the cavity through the gap. In a subsequent embossing process, an embossing gap between the mold parts during injection of the molding compound is maintained in a known manner, which is reduced or closed after injection of the molding compound. An open state of the forming machine is understood to mean a state in which the first and second platens have been at least distanced from each other so that sufficient space has been created therebetween, more specifically, between the mold parts attached thereto so that a finished product can be removed or enough space is formed to perform any work between the platen.
    By such an inventive embodiment is provided that there is always a bias of the injection unit. In an open state of the closing unit, this bias is applied to the at least one stop and in a closed state of the closing unit, this bias is given to the snorkel. As a result, the stress of the injection unit is never completely released, whereby the biasing elements are never fully relaxed during a molding cycle of the molding machine, which in turn significantly increases the life of these wearing parts.
    Furthermore, it can be provided that the stop is designed so that the snorkel during a closing movement of the closing unit of the molding machine, the injection unit from at least one stop with a low feed movement (speed) freistellt, which low feed movement of the tubular snorkel, which firmly on the second platen is attached only shortly before placing the mold parts or shortly before reaching the intended embossing gap occurs.
    It can preferably be provided that a further platen movable in relation to the first or the second platen is provided. Particularly preferably, it is provided that the second platen is disposed between the first platen and the further platen. In such an embodiment, the movable second platen is often referred to as a center plate. It is quite possible to provide even more movable platen molds and thus to expand such a tool (also called a floor mold) as desired.
    Advantageously, it can be provided that the injection unit is biased by application of force by means of at least one spring element. In this case, the at least one spring element can be designed, for example, as a mechanical and / or hydraulic spring element. Exemplary embodiments for such a spring element would therefore be either a mechanical spiral or leaf spring or a hydraulic pressure accumulator.
    It can be provided that the at least one stop is formed on the first platen. It is quite conceivable that the at least one stop is rod-shaped on a side remote from the second platen side of the first platen. In a correspondingly embodied exemplary embodiment variant, it can be provided that the at least one stop is made in several parts - preferably in two parts -, wherein a length of the at least one stop by a relative movement of the plurality of parts is mutually variable. For example, it is possible for the multiple parts to be fastened together by a screw connection, relative rotation of one of the several parts leading to an extension or shortening of the stop. These measures, either individually or in total, give a particularly simple possibility for a construction.
    Preferably, it may be provided that the injection unit is movable relative to the first platen by means of a drive unit - preferably a spindle drive. However, other drive units, which are known from the prior art, quite conceivable, such as linear motors or fluid mechanical drives. It can be provided that by means of the drive unit of the injection unit, the at least one spring element can be acted upon by a force.
    The injection unit may preferably be realized by an axially and rotatably movable plasticizing screw, wherein the plasticizing screw is arranged in a plasticizing cylinder. In a preferred embodiment, it may be provided that the injection unit in the open state of the closing unit is directly or indirectly clamped with the plasticizing against the at least one stop. However, other embodiments are quite conceivable, such as an axially movable injection and plasticizing.
    It can preferably be provided that the injection unit has at least one injection nozzle, wherein the at least one injection nozzle is clamped against the at least one snorkel.
    It can also be provided that the at least one snorkel protrudes into an opening of the first platen. However, it is also quite conceivable that the plasticizing protrudes through an opening of the first platen or the snorkel and the plasticizing in an opening of the first
    Contact platen. An arrangement parallel to the machine axis and / or outside of the shaping machine is conceivable in principle.
    Protection is also desired for a method for operating a molding machine, wherein - an injection unit is clamped in an open state of the closing unit against at least one stop, - the closing unit is closed by moving a second platen in the direction of the first platen, - the injection unit when closing the closing unit is lifted from the at least one stop by the action of force of at least one tubular snorkel arranged on the second platen on the injection unit.
    Preferably, it may be provided that when closing the closing unit at least one arranged on the second platen tubular snorkel is inserted into an opening of the first platen.
    It may preferably be provided that, when the closing unit is opened, the second platen is moved together with the at least one snorkel in a direction away from the first platen, whereby the biased injection unit lifted from the at least one stop is moved in the direction of the first platen until the injection unit contacted the at least one stop.
    It can be provided that in a molding cycle of the molding machine, starting from an open state of the closing unit, - the second platen is closed in the direction of the first platen by means of the clamping unit and - molding compound with closed closing unit by means of the injection unit on the arranged on the second platen at least one
    Snorkel a arranged on the first and on the second platen mold is passed.
    It is quite possible that by means of at least one snorkel molding compound is passed directly to a mold or is forwarded by means of a hot runner system.
    Preferably, it can also be provided that by means of the closing unit before supplying plasticized molding material, a mold part arranged on the second mold clamping plate is positioned with an embossing gap to a mold part arranged on the first mold mounting plate. Particularly preferably, it can be provided that a width of the embossing gap between 1.6 mm and 0.2 mm, preferably between 1.2 mm and 0.6 mm and more preferably between 0.9 mm and 0.7 mm is selected ,
    In a further embodiment, it may be provided that the second platen is moved by supplying the supply of plasticized molding compound in the direction of the first platen, preferably until the arranged on the second platen mold part rests against a arranged on the first platen mold part. Such a process is known, inter alia, as embossing or injection-compression molding.
    In a preferred embodiment of a method according to the invention, it may be provided that at least one stop arranged on a side of the first platen facing away from the second platen is adjusted, comprising the following method steps: closing the closing unit until it contacts a second platen Formwerkzeugteiles on a arranged on the first platen mold part, preferably under application of a closing force, - setting a gap between the at least one stop and the injection unit when concerns the mold parts by the length of the at least one stop is changed, - opening the closing unit.
    Particularly preferably, it may be provided that the gap is up to 0.4 mm, preferably between 0.1 mm and 0.3 mm, more preferably 0.2 mm - preferably plus an intended embossing gap - is.
    Further details and advantages of the present invention will be explained in more detail below with reference to the description of the figures with reference to the embodiments illustrated in the figures. Showing:
    Fig. 1 shows a first embodiment of an inventive
    Forming machine
    2a-2c adjusting a stop of the embodiment of FIG. 1, Fig. 3a-3d a molding cycle of the embodiment of Fig. 1,
    Fig. 4 shows a second embodiment of an inventive
    Shaping machine and
    5a-5c, the adjustment of a stop of the embodiment of FIG. 4th
    1 shows a first exemplary embodiment of a shaping machine 1 according to the invention. This shaping machine 1 has a closing unit 9 (which can be driven by means of a drive, not shown) and an injection unit 6. The fixed first clamping plate 2 is connected to the machine frame (likewise here For reasons of clarity not shown) firmly connected. On the fixed first platen 2, a mold part 15 is fixed, the counterpart - the mold part 16 - is attached to a movable second platen 3. Furthermore, a further mold part 19 is fastened to the second mold clamping plate 3, the counterpart of which - the mold part 20 - is fastened to a further mold mounting plate 4. At the second platen 3, a snorkel 5 is provided, which is firmly connected to the second platen 3. About this snorkel 5, a plasticized molding compound 7 coming from an injection unit 6 of the second platen 3 can be supplied later, which can forward the plasticized molding compound 7 to the mold parts 16, 19 via inner lines.
    The snorkel 5 protrudes with its free end into an opening 14 of the first platen 2. On the side remote from the mold part 15 side of the first platen 2, two stops 8 are provided in this embodiment.
    In this exemplary embodiment, the injection unit 6 has a drive unit 11, which is designed as a spindle drive. This spindle drive is attached via the spring element 10 with the first platen 2. Furthermore, the injection unit 6 has a plasticizing cylinder 12, which can be brought into contact with the snorkel 5 by means of an injection nozzle 13.
    FIGS. 2 a to 2 c show an adjustment of a stop of the exemplary embodiment from FIG. 1. First, in a first method step (shown by FIG. 2 a), the closing unit 9 is attached to a forming tool 16 arranged on the second platen 3 the first platen 2 arranged mold 15 and up to a concern of arranged on the other platen 4 mold part 20 is closed on a arranged on the second platen 3 mold part 19, as shown in Fig. 2a. In addition, a closing force can be built up, as may be present, for example, at the end of a stamping process. It is easy to see by the mold parts 20, 19 and the mold parts 16, 15 abut each other. However, the injection unit 6 is still in a non-contact state with the first platen 2, wherein the spring element 10 is released and without bias.
    In a second method step (see Fig. 2b), the injection unit 6 is now moved by means of its drive unit 11 in the direction of the first platen 2 until the injection unit 6 rests with its injection nozzle 13 on the snorkel 5 and the spring element 10 is stretched to a predetermined value. Subsequently, the stops 8 are aligned with a gap 18 to the injection unit 6. The stops 8 are variable in this embodiment in their length by being formed in two parts. Thus, these two-part stops 8 are screwed together to adjust the length of the stops 8. The gap 18 is selected in this embodiment with 1 mm, wherein the gap 18 composed of a security value of 0.2 mm plus an intended embossing gap 17 of 0.8 mm for a subsequent embossing cycle.
    In a third method step (see FIG. 2 c), the closing unit 9 is again opened, whereby now the injection unit 6 rests against the pre-adjusted stops 8. Since the opening of the closing unit 9, the snorkel 5 was moved away from the injection nozzle 13 and thus the injection unit 6 is no longer lifted by the snorkel 5 of the attacks 8. The snorkel 5 has been moved away from the injection unit 6 through the opening 14 of the first platen 2 by the opening movement of the closing unit 9, since it is firmly connected to the second platen 3. With the opening of the closing unit 9, the adjustment process of the first embodiment of a molding machine 1 according to the present invention ends, and the molding cycle of the molding machine 1 can start, which is shown by Figs. 3a to 3d.
    In a first step (as shown in FIG. 3 a), the closing unit 9 of the shaping machine 1 is closed until the mold parts 19, 20 and the mold parts 15, 16 are spaced apart from one another only by an embossing gap 17. In this concrete embodiment, an embossing gap with a size of 0.8 mm is provided. By closing the closing unit 9, the snorkel 5 is moved by the second platen 3 to the injection nozzle 13 of the injection unit 6 and the injection unit 6 released by the force of the snorkel 5 on the injection nozzle 13 of the attacks 8.
    A blow to the injection unit 6 is avoided because the stops 8 position the injection unit 6 so that the meeting of the injection nozzle 13 and the snorkel 5 occurs only when the speed of the second platen 3 is already significantly reduced.
    In a next step (as shown in Fig. 3b) is now injected through the injection unit 6 plasticized molding compound 7, wherein the plasticized by the plasticizing plastic molding compound 7 7 is injected through the injection nozzle 13 into the snorkel 5, which snorkel 5, the molding compound 7 to the second platen 3 forwards. It is a hot runner system (not shown) is provided, which passes the molding compound 7 coming from the snorkel 5 further to the mold parts 16, 19. By the mold parts 16, 19, the molding compound 7 is now passed into the cavities formed between the mold parts 19, 20 and the mold parts 15, 16.
    In a next process step of the molding cycle of the molding machine 1 (represented by FIG. 3c), the closing gap 9 closes the embossing gap 17 between the mold parts 19, 20 and the embossing gap 17 between the mold parts 15, 16. This relative movement (the closing of the embossing gap 17 between the mold parts 15, 16) is compensated by the spring element 10, whereby the injection nozzle 13 continues to be pressed against the snorkel 5. However, the distance between the stops 8 and the injection unit 6 increases from the previously selected safety distance of 0.2 mm (seen in Fig. 3a, 3b) to a gap of 1 mm, which is due to the closing of the embossing gap 17 of 0 , 8 mm and the safety distance of 0.2 mm. When closing the embossing gap 17 of the closing unit 9 while the volume between mold parts 19, 16 and injection unit 6 remains unchanged.
    In a final step of the molding cycle, the closing unit 9 is now opened again in order to be able to remove the produced parts from the molds 15, 20. This opened state of the closing unit 9 can be seen in Fig. 3d. Subsequently, the molding cycle can start again from the front (FIG. 3a).
    Fig. 4 shows a second embodiment of a forming machine 1 according to the invention. The structure of the forming machine 1 is substantially identical to that of the first embodiment of Fig. 1 with the exception of the arrangement of the stops 8. In this embodiment, no stops 8 at one of the mold 15 facing away from the first platen 2, but it is a stop 8 on the spindle of the drive unit 11 of the injection unit 6 is provided. How exactly this stop can be carried out will now be explained below with reference to FIGS. 5 a to 5 c, FIGS. 5 a to 5 c illustrating the adjustment of the stop 8 of this exemplary embodiment shown in FIG. 4.
    For this purpose, firstly the closing unit 9 is completely closed until a mold part 16 arranged on the second platen 3 touches a mold part 15 arranged on the first platen 2 and a mold part 20 arranged on the further platen 4 is applied to the second platen 3 arranged mold part 19, as shown by the Fig. 5a.
    In a second method step for adjusting the abutment 8 (shown in FIG. 5b), a gap 18 between the abutment 8 and the injection unit 6 is then adjusted to each other when the mold parts 15, 16 are in contact, by changing the length of the at least one abutment 8. Specifically, a gap 18 of 1.0 mm is set here, which is composed of a safety distance of 0.2 mm and an embossing gap 17 of 0.8 mm.
    In a last method step (to be seen in FIG. 5 c) for adjusting the stop 8 of the shaping machine 1, the closing unit 9 is opened again, wherein now the closing unit 6 is biased against the stop 8 by the spring elements 10.
    The actual shaping cycle can be carried out analogously to FIGS. 3a to 3d.
    LIST OF REFERENCES: 1 forming machine 2 first mold clamping plate 3 second mold mounting plate 4 further mold mounting plate 5 snorkel 6 injection unit 7 molding compound 8 stop 9 closing unit 10 spring element 11 drive unit 12 plasticizing cylinder 13 injection nozzle 14 opening 15 mold part 16 mold part 17 embossing gap 18 gap 19 mold part 20 mold part
    Innsbruck, March 6, 2018
    权利要求:
    Claims (23)
    [1]
    1. shaping machine with - a fixed first platen (2), - a first platen (2) movable second platen (3), - at least one tubular snorkel (5), wherein the at least one snorkel (5) fixed to the second platen (3) is attached, - an injection unit (6) for plastifying and injecting a molding compound (7), characterized in that at least one stop (8) is provided, which is formed so that the injection unit (6) in the open state of Closing unit (9) against the at least one stop (8) is clamped and that the injection unit (6) in a closed state of the closing unit (9) by the action of the at least one snorkel (5) on the injection unit (6) of the at least one stop (8) is exempted.
    [2]
    2. Forming machine according to the preceding claim, characterized in that a for the first platen (2) and / or the second platen (3) movable further platen (4) is provided.
    [3]
    3. Forming machine according to the preceding claim, characterized in that the second platen (3) between the first platen (2) and the further platen (4) is arranged.
    [4]
    4. Forming machine according to one of the preceding claims, characterized in that the injection unit (6) is biased by the application of force by means of at least one spring element (10).
    [5]
    5. Forming machine according to the preceding claim, characterized in that the at least one spring element (10) is designed as a mechanical and / or hydraulic spring element.
    [6]
    6. Forming machine one of the preceding claims, characterized in that the at least one stop (8) on the first platen (2) is formed.
    [7]
    7. Forming machine according to one of the preceding claims, characterized in that the at least one stop (8) is rod-shaped on a side remote from the second platen (3) side of the first platen (2).
    [8]
    8. Forming machine according to one of the preceding claims, characterized in that the at least one stop (8) in several parts - preferably in two parts - is formed, wherein a length of the at least one stop (8) by a relative movement of the plurality of parts is mutually variable.
    [9]
    9. Forming machine according to one of the preceding claims, characterized in that the injection unit (6) by means of a drive unit (11) - preferably a spindle drive - relative to the first platen (2) is movable.
    [10]
    10. Forming machine according to claim 4 and 9, characterized in that the at least one spring element (10) by means of the drive unit (11) of the injection unit (6) can be acted upon by a force.
    [11]
    11. Forming machine according to one of the preceding claims, characterized in that the injection unit (6) is carried out by an axially and rotatably movable plasticizing screw, wherein the plasticizing screw is arranged in a plasticizing cylinder (12).
    [12]
    12. Forming machine according to the preceding claim, characterized in that the injection unit (6) in the open state of the closing unit (9) directly or indirectly with the plasticizing cylinder (12) against the at least one stop (8) is clamped.
    [13]
    13. Forming machine according to one of the preceding claims, characterized in that the injection unit (6) has at least one injection nozzle (13), wherein the at least one injection nozzle (13) against the at least one snorkel (5) is clamped.
    [14]
    14. Forming machine according to one of the preceding claims, characterized in that the at least one snorkel (5) projects into an opening (14) of the first platen (2).
    [15]
    15. A method for operating a shaping machine, wherein - an injection unit (6) in an open state of the clamping unit (9) is clamped against at least one stop (8), - the clamping unit (9) by moving a second platen (3) in the direction the first platen (2) is closed, - the injection unit (6) upon closing of the closing unit (9) by force of at least one tubular snorkel (5) arranged on the second platen (3) on the injection unit (6) of the at least one Stop (8) is lifted.
    [16]
    16. The method according to claim 15, wherein when closing the closing unit (9) at least one of the second platen (3) arranged tubular snorkel (5) in an opening (14) of the first platen (2) is inserted.
    [17]
    17. The method according to claim 15 or 16, wherein at an opening of the closing unit (9), the second platen (3) together with the at least one snorkel (5) in a direction away from the first platen (2) direction is moved, whereby the prestressed , From the at least one stop (8) lifted, injection unit (6) in the direction of the first platen (2) is moved until the injection unit (6) contacts the at least one stop (8).
    [18]
    18. The method according to any one of claims 15 to 17, wherein in a molding cycle of the forming machine (1) starting from an open state of the closing unit (9) - the second platen (3) in the direction of the first platen (2) by means of the clamping unit (9 ) is closed and - molding compound (7) with closed closing unit (9) by means of the injection unit (6) via the arranged on the second platen (3) at least one snorkel (5) on one of the first platen (2) and on the second Mold clamping plate (3) arranged mold (15, 16) is passed.
    [19]
    19. The method according to claim 18, wherein by means of the closing unit, prior to the supply of plasticized molding compound, arranged on the second platen mold part is positioned with an embossing gap to a arranged on the first platen mold part.
    [20]
    20. The method according to claim 19, wherein a width of the embossing gap (17) between 1.6 mm and 0.2 mm, preferably between 1.2 mm and 0.6 mm and more preferably between 0.9 mm and 0.7 mm , is elected.
    [21]
    21. The method of claim 19 or 20, wherein after the supply of plasticized molding compound (7) by the closing unit (9), the second platen (3) in the direction of the first platen (2) is moved, preferably until the second platen (3 ) arranged mold part (16) on a on the first platen (2) arranged mold part (15) rests.
    [22]
    22. The method according to any one of claims 15 to 21, wherein in advance at least one on one of the second platen (3) pioneering side of the first platen (2) arranged stop (8) is set, comprising the following steps: - closing the closing unit (6 ) to a concern of the second mold mounting plate (3) arranged mold part (16) on one of the first mold mounting plate (2) arranged mold part (15), preferably under application of a closing force, - setting a gap (18) between the at least one Stop (8) and the injection unit (6), in the case of concern of the mold parts (15, 16) by the length of the at least one stop (8) is changed, - opening the closing unit (6).
    [23]
    23. The method according to claim 22, wherein the gap (18) up to 0.4 mm, preferably between 0.1 mm and 0.3 mm, more preferably 0.2 mm, preferably plus an intended embossing gap (17) - is , Innsbruck, March 6, 2018
    类似技术:
    公开号 | 公开日 | 专利标题
    AT395693B|1993-02-25|Transfer moulding installation
    EP1712341B1|2008-07-23|Injection nozzle with two outlet orifices
    DE2836692A1|1979-03-08|METHOD AND DEVICE FOR REDUCING THE RISK OF DAMAGE CAUSED BY EXTRUSIONS AT THE PARTIAL JOINTS OF INJECTION MOLDS
    DE1142058B|1963-01-03|Process for processing thermoplastics in an injection molding machine
    EP1494844B1|2005-09-14|Hydraulic device for back and forth displacement of a machine piece and a closing unit on an injection moulding machine fitted with such a hydraulic device
    DE102019105681A1|2019-09-12|Shaping machine and method of operating a molding machine
    DE2113414A1|1971-10-14|Closing, locking and preloading device for casting molds
    DE2060346A1|1971-06-09|Method and device for producing injection moldings
    DE102004047347A1|2006-02-16|Injection molding machine and method for injection molding
    EP0074473B1|1986-06-04|Method of and apparatus for manufacturing moulded plastics pieces or articles
    DE202016104165U1|2016-11-14|Injection molding machine with stack mold for injection-molding applications
    EP1986839B1|2014-04-02|Process for production of thin-walled plastics mouldings
    DE2419869A1|1975-01-23|METHOD OF FORMING ARTICLES AND DEVICE FOR CARRYING OUT THE METHOD
    DE112015004878T5|2017-07-13|Opening / closing device and pouring device
    DE1704213A1|1971-02-25|Casting machine
    EP0576837B1|1995-12-13|Injection mouding machine with stack mould
    DE112016000837T5|2017-11-23|Form-clamping device, forming device and Urformverfahren
    DE102004051324B4|2016-07-28|Process for injection-compression of thermoplastic material
    DE1583710A1|1970-08-20|Device for operating an injection molding device
    DE1168062B|1964-04-16|Method for operating a nozzle closing device for injection molding machines for processing thermoplastic materials and nozzle closing device for carrying out the process
    DE102021115687A1|2021-12-30|Injection unit for a molding machine and method for injection
    DE1230554B|1966-12-15|Injection molding machine for processing thermoplastics
    DE10009827C2|2003-01-02|Device for producing objects from thermoplastic material
    DE2520718A1|1975-11-27|CASTING OR FORMING CONTROL DEVICE
    DE2558826A1|1977-07-14|Ceramic injection moulding machine - keeps mould halves slightly apart during injection before moving together
    同族专利:
    公开号 | 公开日
    US20190275718A1|2019-09-12|
    DE102019105681A1|2019-09-12|
    US11141895B2|2021-10-12|
    DE102019105681B4|2021-09-30|
    AT520325B1|2019-03-15|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    DE4219924A1|1992-06-17|1993-12-23|Richard Herbst|Injection molding machine with stack mold|
    JPH08118403A|1994-10-24|1996-05-14|Sumitomo Heavy Ind Ltd|Injection molding machine for stacking mold|
    JP2015044392A|2013-08-29|2015-03-12|株式会社日本製鋼所|Operation method of injection molding machine to witch stack mold is attached|
    DE102015112508A1|2015-07-30|2017-02-02|Netstal-Maschinen Ag|Injection molding machine with stack mold for injection-molding applications|
    WO1995008428A1|1993-09-24|1995-03-30|Engel Maschinenbau Gesellschaft Mbh|Double closing unit for an injection moulding machine|
    DE10110611C2|2001-03-06|2003-11-27|Lehmann Gmbh & Co Kg|Device for injection molding molded articles made of plastic|
    AT8048U1|2004-10-13|2006-01-15|Engel Austria Gmbh|METHOD FOR OPERATING AN INJECTION MOLDING MACHINE|
    US7252501B2|2005-02-16|2007-08-07|D-M-E Company|Nozzle and apparatus for injection molding|
    US20080265465A1|2007-04-24|2008-10-30|Husky Injection Molding Systems Ltd.|Apparatus for Injection Compression Molding and Method of Molding Articles|
    JP2013082158A|2011-10-12|2013-05-09|Kojima Press Industry Co Ltd|Compression method of injection compression molding machine|
    FR3019773B1|2014-04-15|2017-02-10|Plastisud|TANDEM MOLD FOR THE PRODUCTION OF SYNTHETIC INJECTED PARTS|
    CA3067127A1|2017-06-28|2019-01-03|Diseno Y Desarrollo De Matriceria, S.L.|Plastic injection molding machine and molding method|JP6891212B2|2019-04-15|2021-06-18|日精樹脂工業株式会社|Injection device|
    CN111844640A|2020-07-17|2020-10-30|陈景伟|Screw type injection mold|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    ATA50189/2018A|AT520325B1|2018-03-07|2018-03-07|forming machine|ATA50189/2018A| AT520325B1|2018-03-07|2018-03-07|forming machine|
    US16/292,899| US11141895B2|2018-03-07|2019-03-05|Shaping machine and method of operating a shaping machine|
    DE102019105681.0A| DE102019105681B4|2018-03-07|2019-03-06|Molding machine and method of operating a molding machine|
    [返回顶部]