• 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:
    The present invention concerns the field of trailers for the anti-explosive transport of cryogenic high pressure and low temperature by dragging in a direction of transport by a tractor truck. This type of trailers consists of a cryogenic cistern formed by a compartment where an alloy in the form of a mesh or spheres with anti-explosive properties is housed. Said cryogenic tank is attached to a chassis that supports at least two pairs of wheels in its rear half, and to anchoring means in its front half for anchoring it to a tractor truck to produce its drag and transport. The alloy in the form of mesh or spheres that is incorporated in the compartment or structure of the tank, is formed by the body of the alloy. This is formed by sheets of perforated material, these are provided by at least one arc of a plurality of polygonal openings, and at least one of those polygonal openings is irregular with respect to at least one adjacent polygonal aperture and having a surface area per unit volume of about 4,200 times the contact surface of the stored fluids that are in a container, tank, tank and that have a heat conduction capacity of at least about 0.023 Cal/cm-sec. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2708877A1
    申请号:ES201631738
    申请日:2016-12-30
    公开日:2019-04-11
    发明作者:Sierra Laura Cañada
    申请人:TechnoKontrol Global Ltd;
    IPC主号:
    专利说明:

    [0001]
    [0002] Trailer for transport anti-explosive of cryogenic fluids at high pressure and low temperature
    [0003]
    [0004] DESCRIPTION OF THE INVENTION
    [0005] The present invention concerns the field of trailers for the anti-explosive transport of cryogenics at high pressure and low temperature by means of their dragging in a direction of transport by a tractor truck. This type of trailers consists of a cryogenic cistern formed by a compartment where an alloy in the form of mesh or spheres with anti-explosive properties is housed. Said cryogenic cistern is attached to a chassis that supports at least two pairs of wheels in its rear half, and to anchoring means in its front half for its attachment to a tractor truck to produce its drag and transport.
    [0006]
    [0007] The alloy in the form of mesh or spheres that is incorporated in the compartment or structure of the cistern, is conformed by the body of the alloy. This is formed by sheets of perforated material, these are provided by at least one arc of a plurality of polygonal openings, and at least one of those polygonal openings is irregular with respect to at least one contiguous polygonal aperture and having a surface area per unit volume of about 4,200 times the contact surface of the stored fluids that are in a container, tank, tank and that have a heat conduction capacity of at least about 0.023 Cal / cm-sec.
    [0008]
    [0009] It should be noted that, preferably, the peripheral internal length of one of the openings is different from the internal peripheral length of at least one of the adjacent openings, and, moreover, the invention, preferably has a compression field no greater than to 8%.
    [0010]
    [0011] With the invention the problem of the transport of cryogenic fluids at high pressure and low temperature is solved, without there being danger of explosion.
    [0012] State of the art
    [0013] At present, trailers are known for transporting cryogenic fluids of the described type equipped with a cryogenic tank formed by an interior compartment and an outer compartment separated by an insulating chamber subjected to total or partial ford as thermal insulation. This type of tank contains liquefied gas at pressures higher than the atmospheric pressure and at temperatures below atmospheric temperature.
    [0014]
    [0015] The geometry of this type of cryogenic tanks is limited by its resistant and safety requirements, so! as per the rules of road transport.
    [0016]
    [0017] This results in a cylindrical geometry with its ends closed by spherical or rounded caps and at the same time filled with anti-explosive alloys. This geometry provides unique anti-explosive properties and also high resistance to internal pressure and an optimized transport volume for transport by road within the maximum dimensions allowed for the transport of goods.
    [0018]
    [0019] However, the fact of having the front part supported on a tractor truck determines an elevated position of said tank, which implies a high center of gravity that can be unstable and cause accidents. That is why it requires solutions that reduce the center of gravity of cryogenic tanks. With the introduction of the anti-explosive alloys inside the cylinder, another great safety advantage is obtained, which is the drastic reduction of the water hammer / movement of liquids (liquid sloshing) which allows a maximum operative safety and maximum reduction of possibility of overturn
    [0020]
    [0021] With this solution the transport capacity is not reduced. Nor is the volume of transported liquids reduced. It facilitates its construction by not requiring the incorporation of bulkheads or anti-movement barriers of metal fluids inside, and allows a maximum structural resistance to be completely structurally firm and reduces the possibility of these structures by the reduction of the hammer blow.
    [0022] The present invention concerns a trailer for transporting cryogenic fluids that at high pressure and low temperature by dragging it in a direction of transport by a tractor truck which is filled with an alloy in the form of mesh and / or spheres with anti-explosive properties, Anti-water hammer, anti-corrosive, anti-algae and anti-static.
    [0023]
    [0024] The alloy in the form of mesh or spheres that is incorporated in the compartment or structure of the tank.
    [0025]
    [0026] In particular with reference to Figures 1 and 2, a sheet of heat conducting material is used, which preferably has the physical properties previously noted, the sheet having a generally flat configuration, with a thickness ranging from 0.01 mm to about 0.1 mm, preferably from about 0.02 mm to about 0.06 mm, or from about 0.02 mm to about 0.05 mm.
    [0027]
    [0028] The body of the alloy in the form of sheet, mesh, net, spheres of the material of the invention is manufactured with a material of good conductivity in order to prevent, annul, suppress, reduce, any type of damages or attacks of harmful origin, corrosive and / or bacteriological.
    [0029]
    [0030] The heat conductivity should be at least about 0.023 Cal / cm-sec, particularly for materials having a specific density of about 2.8 g / cm3 to about 19.5 g / cm3, and preferably from about 0.023 to about 0.95 Cal / cm-seq, particularly for materials having a specific density of about 2.8 g / cm3 to about 19.5 g / cm3.
    [0031]
    [0032] The nominal heat conductivity is about 2.36 Watt / cm-degrees (Kelvin) to 273 T.K. (Kelvin degrees) for aluminum.
    [0033]
    [0034] The following materials can be used as allowed candidates or as raw materials depending on the application. Namely:
    [0035] -Plate 4.28 Watt / cm-degrees (Kelvin) to 273 T.K.
    [0036] -Oh 3,2018 Watt / cm-degrees (Kelvin) to 273 T.K.
    [0037] -Copper 4.1 Watt / cm-degrees (Kelvin) to 273 T.K.,
    [0038] -Nobium, Nb, 41,
    [0039] -Inconel 600, 625, 690, 718, 751,792, 939
    [0040] -Nimonic 90, 100, 105, 115
    [0041] -Chrome, Cr, 24
    [0042] -Moleybdeum, Mo, 42
    [0043] -Moleybdeum (MoS2)
    [0044] -Hafium, Hf, 72
    [0045] -Hafnium oxide (HfO2)
    [0046] -Vermiculite (Mg, Fe, Al) 3 (Al Si) 4 O 10 (O H2) 4 (H20)
    [0047] -Monel, 400, 401, 404, K-500, R-405
    [0048] And polymer material.
    [0049]
    [0050] For a material density, for example, 2.7 g / cm3 (Aluminum); 10.5 g / cm3 (Silver), 19.3 g / cm3 (Gold), 8.92 g / cm3 (Copper), 7.86 g / cm3 (stainless steel) or 0.9 to 1.5 g / cm3 (polymer material).
    [0051]
    [0052] It is desirable that the sheet of material be relatively, inert to the contents of the container closed or open, encapsulated, molded or in carcasses for its installation / fixation / application for the usable life of the container and / or the residence period of the containers. contained in the container.
    [0053]
    [0054] The materials must be common metals or special metals allowed, such as Niobium, inconel, monel, vermerculite, titanium, nickel, Hafium, Ninomico, aluminum, magnesium, copper, gold, silver or stainless steel, or non-metallic, such as plastic materials or pohmeros
    [0055]
    [0056] A thin sheet of material that is used in the present disclosure, as shown in Figures 3, 4 and 5, as an example, comprises a sheet of material 10 having a plurality of parallel Hneas P (Figure 3) of elongated rectangular openings (12), preferably grooves.
    [0057]
    [0058] Each rectangular opening (12) and each line P of rectangular openings (12), extends parallel to the central longitudinal axis of the sheet.
    [0059]
    [0060] Each rectangular opening (12) in a line P of rectangular openings (12) is spaced apart from the preceding rectangular opening (12), and the rectangular opening (12) that follows it through an intermediate network (14) of solid and Non-perforated sheet material.
    [0061] (12), there is a rectangular opening (12) followed by an intermediate network (14), followed by a rectangular opening (12), followed by an intermediate network (14), and thus! gradually.
    [0062]
    [0063] When forming a sheet with polygonal openings, the intermediate networks (14) of the contiguous lines of the rectangular openings are outside with respect to each other, in such a way that when proceeding transversely through the sheet following a line T perpendicular to the central axis of the sheet and passing through an intermediate network (14) of a contiguous longitudinal line P of rectangular openings (12), having to take into account the following:
    [0064] to. the transverse line (7) must pass through the rectangular opening (12) of the next longitudinal line P adjacent to the longitudinal openings (12).
    [0065] b. then, it should pass through an intermediate network (14) of the next longitudinal line P contiguous to the longitudinal openings (12).
    [0066] c. then, it must pass through the rectangular opening (12) of the next contiguous longitudinal line of longitudinal openings, etc.
    [0067]
    [0068] In this way, the rectangular openings (12) which are longitudinally understood, alternate with intermediate networks 14 transversely through the sheet (10).
    [0069]
    [0070] It is preferable that the length of each rectangular opening extending longitudinally, when passing along a transverse line T of rectangular openings (12), is different from the length of the rectangular opening (12) preceding it and of the length of the rectangular opening (12) that follows it.
    [0071]
    [0072] In other words, the length of each rectangular opening (12) extending longitudinally is preferably different from the length of the next adjacent rectangular opening (12) extending longitudinally in a transverse line T across the width of the sheet , and furthermore, with respect to each rectangular opening (12), the length of each of the four rectangular openings (12) closest to the two closest longitudinal lines P of rectangular openings (12) must preferably also be different from that of the rectangular opening (12).
    [0073]
    [0074] The lengths of the respective longitudinally extending rectangular openings (12) in a transverse line T across the width of the sheet must be random with respect to each other and, alternatively, the lengths of each respective rectangular opening (12) T crosswise through the width of the sheet or decrease in length.
    [0075]
    [0076] In an alternative embodiment, the lengths of each longitudinal opening (12) extending longitudinally progressively increases in length in a transverse line T across the width of the sheet and the lengths of each rectangular opening (12) extending longitudinally in the next transversal line T decreases progressively in length through the width of the sheet.
    [0077]
    [0078] The nominal length of the openings (12) ranges from about 10 mm to about 15 mm, desirably from about 12 mm to about 15 mm, and preferably from about 13 mm to about 15 mm.
    [0079]
    [0080] Thus, an opening of 10 mm is followed by a 10.033 mm, followed by a 10.06 mm, and the width of each rectangular opening, or slot, should be from about 0.02 mm to 0.06 mm, preferably from about 0.03 mm to about 0.05 mm and preferably from about 0.04 mm to about 0.05 mm.
    [0081]
    [0082] The spacing between the arches of openings must be varied based on the properties of the material used for the sheet.
    [0083]
    [0084] The intermediate network between openings, in turn, ranges from around 2.5 mm to around 4.5 mm, and thus an intermediate network of 3 mm should be followed by a 3.5 mm, followed by a of 4 mm.
    [0085]
    [0086] In this way, the irregularity is induced in the expanded perforated sheet and its configuration produces a resistance to settlement and compaction.
    [0087]
    [0088] A thin sheet of the material used in the invention, as illustrated in figures 6, 7, 8 and 9, becomes an expanded and perforated sheet (or with windows) of the material (20) of the invention , and is provided with a plurality of plurilateral or polygonal openings (22), as is, for example, that illustrated with hexagonal openings, and at least one of the polygonal openings is irregular with respect to at least one of the polygonal openings contiguous
    [0089] (22), for example lengths (22a), (22b), (22c), (22d), (22e), and (22f) of Figure 9, determines a peripheral internal length of a polygonal aperture (22) and the The internal peripheral length of each polygonal opening (22) when proceeding along a transverse line T of polygonal openings (22), must be different from the internal peripheral length of the polygonal opening that precedes it and the internal peripheral length of the polygonal opening (22) that follows it. (Figure 8).
    [0090]
    [0091] In other words, the peripheral internal length of each polygonal aperture (22) is different from the peripheral internal length of the next contiguous polygonal aperture (22) in a transverse line across the width of the sheet.
    [0092]
    [0093] Furthermore, with respect to each polygonal aperture (22), the internal peripheral length of each of the four polygonal apertures (22) closest to the two longitudinal edges, closest to polygonal apertures (22), should preferably also be different from the polygonal opening (22).
    [0094]
    [0095] The peripheral internal lengths of the respective polygonal openings (22) in a transverse line T across the width of the sheet must be random with respect to each other and, alternatively, the peripheral internal lengths of each respective polygonal aperture ( 22), must progressively increase in peripheral internal length in a transverse line T across the width of the sheet or decrease.
    [0096]
    [0097] In an alternative embodiment, the peripheral internal lengths of each respective polygonal aperture (22) progressively increase in length in a transverse line T across the width of the sheet and the internal peripheral lengths of each respective polygonal aperture (22) in the next transverse line T decreases progressively in length across the width of the sheet.
    [0098]
    [0099] The term "irregular", as used herein in the context of the internal peripheral length of at least one of the openings that is unequal to the internal peripheral length of at least one contiguous opening, means that the numerical value of the inequality of the internal peripheral length with respect to the other peripheral internal length is greater than the variation in peripheral internal length produced by the variation in manufacturing or the inherent variation of manufacturing.
    [0100] contiguous polygonal aperture has been described in terms of peripheral internal length of at least one of the apertures that is unequal to the internal peripheral length of at least one contiguous aperture, it is to be understood that irregularity can also be produced in other ways, such as having a different number of sides of the polygon (such as a pentagon or a heptagono with respect to the hexagon) or the length of one side of a polygonal aperture that is different from the corresponding side of an adjacent polygonal aperture (that is, greater than the variation) or manufacturing tolerance as indicated above) or the angle between two contiguous sides of a polygonal aperture is different from the corresponding angle between the two corresponding sides of a contiguous polygonal aperture, eg, the respective lengths of the side edges of the polygonal apertures. openings may not all be the same, (that is, at least one side may not have the same length as any other e the other sides, so it provides an opening that has the configuration of an irregular poHgono).
    [0101]
    [0102] In this way, when expanded, perforated sheets are placed one above the other, it is not possible to align the polygonal openings and fit one into another, seating and thereby reducing the effective thickness of the multiple sheets (20).
    [0103]
    [0104] A sheet expanded and perforated (or with windows) of the material (20) of the present invention, preferably has a field of compression or resistance to compaction (ie, permanent deformation under a compression weight) not greater than 8%. Ideally, however, there is essentially no compression field in its use.
    [0105]
    [0106] The expanded and perforated sheet of the material (20) is formed by tensioning sheets of grooved material (10) on wide wheels of different diameters placed in such a way that the outlet of the sheet of material can be regulated to an additional width between 50% and 100% of the width of the initial material sheet, so as to ensure that the resulting openings form a plurality of polygonal openings (22) as described above.
    [0107]
    [0108] The expanded and perforated sheet material (20) desirably has a surface area per unit volume from at least 4,200 times the contact surface of the liquids / vapors, polluting or non-polluting emissions, liquids, hydrocarbons contained in the closed containers of any type including pipes, tanks, cisterns particularly to inhibit, suppress, reduce, the ebullition of liquids and preferably increase 4,200 times the contact surface of the liquids / vapors and flammable gases contained in the containers polluting or non-polluting emissions.
    [0109]
    [0110] The term "contact surface" refers to the surface area of the container container that is in contact with the gaseous phase, aerosol or vaporization of hydrocarbons, gases, liquids, polluting or non-polluting emissions contained in the container, tank, chimney, gas pipelines, etc.
    [0111]
    [0112] Normally, flammable liquids (liquid, vapor, aerosol or gas) are in contact with areas of the surface of the walls of the container where the flammable fluid, combustion, hydrocarbons and the insertion of the sheets of finished material, expanded and perforated the surface area in contact with the liquid and flammable gases increases at least about 4,200 times the contact surface area, preferably at least about 4,200 times this contact surface area.
    [0113]
    [0114] In one embodiment, the expanded and perforated sheet of the material (20) which is used in the present invention, and which is illustrated in (Figure number 13) as an example, can be configured as a shape comprising a body (100) with an external shape or configuration generally spheroidal.
    [0115]
    [0116] The internal configuration of the body (100), generally spheroidal, comprises at least one strip of the sheet expanded and perforated of the material mentioned above, which is bent and / or curled and recessed to form said spheroidal shape.
    [0117]
    [0118] The generally spheroidal shape can be formed by using a section of the expanded and perforated sheet of material of a proportional size about 20% of the width of the expanded and perforated sheet of material.
    [0119]
    [0120] The external spherical perimeter of the spheroid (100) encloses a volume and the area of the surface of the material contained within that spherical perimeter, that is, within the spheroid (100), subject to the design requirements of the application, is of less than 1.5 square cm per cubic cm of said volume or wider if required. The surface area of the material must be at least 4,200 times the contact surface of liquid and gases contained in the container enclosing the flammable fluid, in particular to inhibit, suppress, reduce, liquid or polluting or non-polluting emissions.
    [0121] that is, permanent deformation under compression, not exceeding 8%.
    [0122]
    [0123] The structural strength of the final product can be modified according to the thermal treatment used in the manufacturing process of the raw material.
    [0124]
    [0125] In an alternative embodiment of this invention, the expanded and perforated sheet material (20) that is used in this invention, as illustrated in Figures 10, 11 and 12 by way of example, is provided with a corrugated transverse or sinusoidal wave (42) formed in the and the sheet of material (40) corrugated, expanded, perforated, being introduced helically in a cylindrical shape. The cylindrical shape is generally circular in cross section, and generally rectangular in longitudinal section, and in a later version of this cylindrical presentation, a sheet of flat, expanded, perforated material must be bent into the cylindrical shape. In a new form, the sheet of perforated material must be folded into the cylindrical shape, in such a way that depositions of sheets of the expanded and flattened or corrugated material are formed in the cylindrical form.
    [0126]
    [0127] Due to the ripple (42) formed in the material sheet (40), with the sheet of material (40) folded helically, the ripple (42) causes an increase in the effective diameter of the cylinder and thus increases the area of the effective surface contained within a given external spherical perimeter of the cylinder, providing a wide volume inclusion in the cylinders with low mass and high internal effective area.
    [0128]
    [0129] It is desirable that the cylinder has a compression field, or resistance to compaction, that is, permanent deformation under compression, not exceeding 8%, and, however, ideally, during use there is essentially no compression field .
    [0130]
    [0131] The non-perforated material sheet (1), from which it is split, must be provided as a continuous, non-perforated web of material sheet, and then, the rectangular openings (12), or slots, are formed in the continuous network in the configuration described above, such as can be slits, and in that case, the slotted network (10) must be transversely expanded by transversally tensioning the sheet of material (10), as above a wheel located in such a way as to regulate the exit of the sheet of material with an additional width of 50% to 100% of the width of the raw material sheet, so as to ensure that the resulting holes form a plurality of polygonal openings (22) with irregularity, such as it has been previously cited.
    [0132] expansion of the production machine, and in doing so, the result is the ability to have the walls of the finished panel model more or less erect and, therefore, increase the compressive strength of the perforated sheet of expanded material (20) completed .
    [0133]
    [0134] Optionally, the expanded and pierced net (20) may have a transverse sinusoidal sling (42) formed therein and the shape of the sling (42) is introduced or impressed into the lengths of the material sheet (20) as a series of curls or slings (42) transverse along the length of the net that look deep when the finished product is coiled.
    [0135]
    [0136] The cylindrical shapes can be made by spherical rolling of the sheets of expanded and perforated material discussed above.
    [0137]
    [0138] The spheroidal shapes (100) can be made by feeding the sheets of the material (20) to which there are provided pluralities of arcs with a plurality of parallel openings (22), of which the longitudinal center is parallel to the central longitudinal axis of the laminate, introducing said sheet into a machine having a mechanical device comprising two concave semicircular sections that work in opposition to one another, and these concave sections (the mobile unit and the one covering it, fixed opposite concave) may have a variable radius with a concave working edge.
    [0139]
    [0140] The central part of the wheel-shaped contraption with the outer part similar to the rim of a bicycle, rolls 360 ° with a working edge concave with a friction surface, and the rotation of the feeding sheet in the form of circular tubular cylinder against the rough surface of the opposing mechanical devices, the movable central unit and the fixed external one, causing the material fed in the form of a cylindrical tube to coil and exit in spheroidal form.
    [0141]
    [0142] It will be understood that the term high pressure refers to a pressure higher than the atmospheric pressure, typically several multiples of the atmospheric pressure, and that the term low temperature refers to temperatures lower than the usual atmospheric temperature, typically temperatures below the - 20 ° C, or tens or hundreds of degrees below this temperature.
    [0143]
    [0144] These conditions of pressure and temperature allow certain substances that remain in gaseous state under conditions of pressure and atmospheric temperature can be stored and Transports much more efficient.
    [0145]
    [0146] The proposed cryogenic tank comprises, in a usual way in the sector:
    [0147] • a sealed inner compartment, defined by interior walls, resistant to high pressures, said sealed inner compartment having a cylindrical section closed by its two opposite ends, spherical or rounded caps, said cylindrical section defining at its center a longitudinal cistern axis lying on the Transport direction filled with anti-explosive alloys.
    [0148]
    [0149] • a watertight outer compartment, defined by exterior walls, which houses the interior compartment inside, the interior walls of the interior compartment being spaced from the outer walls of the exterior compartment defining between said interior and exterior walls an insulating chamber, wherein the aforementioned The insulating chamber is maintained at a total or partial watt, wherein the outer walls of said outer compartment are parallel to the interior walls of the interior compartment in the majority of the cryogenic tank.
    [0150]
    [0151] The proposed trailer includes, in addition:
    [0152] S a chassis attached to the sealed outer compartment of said cryogenic tank;
    [0153] S at least two pairs of wheels facing their axes perpendicular to the direction of transports, said wheels having the same diameter and said wheels being coupled to said chassis by means of a suspension system, defining the axes of said wheels, under a uniform inflation and When the view is on a flat floor, a plane of support of the chassis,
    [0154] S means of anchoring the tank to a tractor truck, said anchoring means being located under the outer compartment of the cryogenic tank in its front half and connected to a tractor truck.
    [0155]
    [0156] As it will be obvious to the expert, between the interior and exterior compartments there will be supports and anchors that allow to support the interior compartment inside the outer compartment and separated from it, said supports and anchors being designed to avoid the creation of thermal bridges between both compartments.
    [0157] mesh and / or anti-explosive spheres will perform the functions of thermal insulation and anti-explosive that will allow maintaining the temperature of the interior compartment under cryogenic conditions during transport without requiring refrigeration equipment and without the possibility of explosion externally and / or internal even by penetration of explosive, incendiary and / or penetrating bullet in the most extreme cases.
    [0158]
    [0159] The chassis supports at least two pairs of wheels in its rear half, connected to the chassis by means of a usual suspension system of the usual type. Each pair of wheels are arranged symmetrically on opposite sides of the cryogenic tank and, under uniform pressure conditions of the tires and on a flat floor, their respective axes are coaxial. The successive pairs of wheels have identical disposition and are with their respective axes parallel to the wheel axes described, jointly defining a chassis plane that ideally will be parallel to the flat ground on which the wheels are seated.
    [0160]
    [0161] The present invention proposes that the cistern axis forms, in the direction of transport, an angle of between 2 ° and 3.5 ° with respect to said chassis support plane, so that the rear portion of the cryogenic cistern is at a lower level than the front portion of it.
    [0162]
    [0163] These characteristics allow to place the rear end of the tank in a position lower than the usual in the sector, which in turn has a decrease in the center of gravity of the tank without having to reduce its capacity and without modifying the height of the tank. the means of anchoring the truck on which the cryogenic tank is supported. The descent of the center of gravity affects in a greater stability of the cistern during its transport, and therefore a safer transport.
    [0164]
    [0165] According to an additional embodiment, said chassis includes at least two parallel and confronting structural bars between which the outer compartment of the cryogenic tank is partially housed. This allows to reduce the distance between the rear of the tank and the flat floor, partially fitting it into the chassis, thus reducing! the center of gravity of the entire trailer. In the present example, the free distance between these two structural bars is greater than 1300mm, for example, 1400mm.
    [0166]
    [0167] Said two parallel and facing structural bars are proposed to be parallel to the chassis support plane, and parallel to the cistern axis. As the position of said bars will be understood in which the tire pressure of all wheels is identical and the trailer is on a flat floor and coupled to a tractor truck. Being different conditions the wheel suspension system would modify the position of the axes of the wheels, alternating the reference of the support plane of the chassis. However, in such a case, the support plane of the chassis obtained under the conditions initially described would be maintained, even if the position of the axes of the wheels is modified.
    [0168]
    [0169] According to another proposed additional or alternative embodiment of the trailer, the chassis includes at least two facing cradle structural elements between which the outer compartment of the cryogenic tank is partially housed, each structural element in cradle including at least one upper edge parallel to the axis of the cradle. cistern, and at least one lower edge parallel to the chassis support plane. These cradle structural elements allow connecting the rest of the chassis and the wheels to the cryogenic cistern, defining the aforementioned inclination greater than 2 ° thanks to its cradle geometry.
    [0170]
    [0171] Said cradle structural elements can be a continuous element disposed on each side of the cryogenic cistern, or they can be a succession of spacers of different heights located on either side of the cryogenic cistern which, together, define said two structural elements in cradle faced.
    [0172]
    [0173] The structural elements in the cradle can be combined with the aforementioned two parallel bars facing each other.
    [0174]
    [0175] It is also proposed that, when the trailer is anchored to the tractor truck by means of said anchoring means and on said flat floor, the lowest point of the outer compartment of the cryogenic tank, at the rear of the trailer, is less than 95 cm from said trailer. flat floor, preferably less than 85 cm.
    [0176]
    [0177] Preferably the cryogenic tank will have a length equal to or greater than 18 meters, and / or a diameter equal to or greater than 240 cm.
    [0178]
    [0179] It will be understood that the references to geometrical positions, such as parallel, perpendicular, tangent, etc. they admit slight deviations with respect to the theoretical position defined by said nomenclature.
    [0180] extreme values and may require adaptations of the invention so that said extreme values are applicable, said adaptations being within the reach of a person skilled in the art.
    [0181]
    [0182] Other features of the invention will appear in the following detailed description of a realization example.
    [0183]
    [0184] Description of the drawings:
    [0185] The foregoing and other advantages and features will be more fully understood from the following detailed description of an exemplary embodiment with reference to the accompanying drawings, which should be taken by way of illustration and not limitation, in which:
    [0186]
    [0187] In view of the figures or drawings made, it can be observed:
    [0188]
    [0189] Figure number 1 .- Corresponds to a plan view of a sheet of the material used in the invention corresponding to suppression, reduction and inhibiting sheets, reducing the propagation speed of wave type in any type of fluid.
    [0190]
    [0191] Figure number 2 .- Shows a high side view taken in cross section of the object reflected in figure number 1.
    [0192]
    [0193] Figure number 3 .- Corresponds to a top plane of a perforated sheet of the invention.
    [0194]
    [0195] Figure number 4.- Shows a side elevation view of the object reflected in figure number 3.
    [0196]
    [0197] Figure number 5 .- Reflects a side view in longitudinal section of the object represented in figure number 3.
    [0198]
    [0199] Figure number 6 .- Shows a top plane of an expanded and perforated sheet of the material used in the invention.
    [0200]
    [0201] Figure number 7 .- It represents a side view elevated in cross section of the object shown in figure number 6.
    [0202] represented in figure number 7.
    [0203]
    [0204] Figure number 9 .- Again corresponds to a high side view in cross section of the object reflected in figure number 8.
    [0205]
    [0206] Figure number 10 .- Corresponds to a plan of the top view of a corrugated sheet, expanded and perforated of the material used in the invention.
    [0207]
    [0208] Figure number 11 .- Reflects a high side view taken in cross section of the object represented in figure number 10.
    [0209]
    [0210] Figure number 12 .- Corresponds to a high side view taken in cross section of the object shown in figure number 10.
    [0211]
    [0212] Figure number 13 .- Finally represents a high side view of a spheroidal shape made according to the body of the alloy. Lamina expanded and perforated of the body of the alloy.
    [0213]
    [0214] Figure number 14. It shows a side view of a tank truck in which we explain the parts and places of installation of the body of the alloy.
    [0215]
    [0216] Figure number 15 shows a side view of the proposed trailer according to a preferred embodiment provided with three pairs of wheels connected to the chassis of the trailer, the trailer being connected to a tractor truck filled with anti-explosive alloys.
    [0217]
    [0218] Figure number 16 shows the same as Fig. 15, but without showing the tractor truck;
    [0219]
    [0220] Figure 17 shows a cross section of the proposed trailer according to the same preferred embodiment shown in Figure 15, said section being made by a position coinciding with the chassis and with a pair of wheels.
    [0221] The alloy in the form of mesh or spheres that is incorporated in the compartment or structure of the cistern, is conformed by the body of the alloy. This is formed by sheets of perforated material, are expanded sheet and perforated material (20) that is used in the present invention, and which is illustrated in (Figure number 13) as an example, can be configured as a form comprising a body (100) with an external shape or configuration generally spheroidal.
    [0222]
    [0223] The internal configuration of the body (100), generally spheroidal, comprises at least one strip of the sheet expanded and perforated of the material mentioned above, which is bent and / or curled and recessed to form said spheroidal shape.
    [0224]
    [0225] The generally spheroidal shape can be formed by using a section of the expanded and perforated sheet of material of a proportional size about 20% of the width of the expanded and perforated sheet of material.
    [0226]
    [0227] The external spherical perimeter of the spheroid (100) encloses a volume and the area of the surface of the material contained within that spherical perimeter, that is, within the spheroid (100), subject to the design requirements of the application, is of less than 1.5 square cm per cubic cm of said volume or wider if required. The surface area of the material must be at least 4,200 times the contact surface of flammable fluids contained in the container / tank enclosing / supporting / containing the flammable fluid, in particular to inhibit, suppress, reduce, fluids or pollutant emissions or non-polluting.
    [0228]
    [0229] Preferably, the spheroid (100) has a field of compression or resistance to compaction, that is, permanent deformation under compression, not exceeding 8%.
    [0230]
    [0231] The structural strength of the final product can be modified according to the thermal treatment used in the manufacturing process of the raw material.
    [0232]
    [0233] In an alternative embodiment of this invention, the expanded and perforated sheet material (20) that is used in this invention, as illustrated in Figures 10, 11 and 12 by way of example, is provided with a corrugated transverse or sinusoidal wave (42) formed in the and the sheet of material (40) corrugated, expanded, perforated, being introduced helically in a cylindrical shape. The cylindrical shape is generally circular in cross section, and generally Sheet of flat material, expanded, perforated, must be folded into the cylindrical shape. In a new form, the sheet of perforated material must be folded into the cylindrical shape, in such a way that depositions of sheets of the expanded and flattened or corrugated material are formed in the cylindrical form.
    [0234]
    [0235] Due to the ripple (42) formed in the material sheet (40), with the sheet of material (40) folded helically, the ripple (42) causes an increase in the effective diameter of the cylinder and thus increases the area of the effective surface contained within a given external spherical perimeter of the cylinder, providing a wide volume inclusion in the cylinders with low mass and high internal effective area.
    [0236]
    [0237] It is desirable that the cylinder has a compression field, or resistance to compaction, that is, permanent deformation under compression, not exceeding 8%, and, however, ideally, during use there is essentially no compression field .
    [0238]
    [0239] The body of the alloy in the sheet of non-perforated material (1), from which it is split, must be provided as a continuous, non-perforated web of material sheet, and then, the rectangular openings (12), or grooves, they are formed in the continuous network in the configuration described above, such as rajas, and in that case, the grooved network (10) must be transversally expanded by transversally tensioning the sheet of material (10), as above a wheel positioned in such a way as to regulate the exit of the sheet of material with an additional width of 50% to 100% of the width of the sheet of raw material, so as to ensure that the resulting holes form a plurality of polygonal openings (22) with irregularity, as mentioned above. Also with the possibility of expanding said material by passing it through rubber wheels that increase their separation with the desired width consecution.
    [0240]
    [0241] The aforementioned, is achieved by adjusting the position and tension of the expansion wheel of the production machine, and in doing so, the result is the ability to have the walls of the finished panel model more or less erect and, therefore, increase the compression force of the perforated sheet of expanded expanded material (20).
    [0242]
    [0243] Optionally, the expanded and pierced net (20) may have a transverse sinusoidal sling (42) formed therein and the shape of the sling (42) is introduced or impressed in the length of the net that looks deep when the finished product is emboiled.
    [0244]
    [0245] The cylindrical shapes can be made by spherical rolling of the sheets of expanded and perforated material discussed above.
    [0246]
    [0247] The spheroidal shapes (100) can be made by feeding the sheets of the material (20) to which there are provided pluralities of arcs with a plurality of parallel openings (22), of which the longitudinal center is parallel to the central longitudinal axis of the laminate, introducing said sheet into a machine having a mechanical device comprising two concave semicircular sections that work in opposition to one another, and these concave sections (the mobile unit and the one covering it, fixed opposite concave) may have a variable radius with a concave working edge.
    [0248]
    [0249] The tanks that transport hydrocarbons, gases, chemical products, in metal, steel, stainless steel, aluminum, plastic fibers of any size or uses, are characterized by the fact that it comprises the following phases:
    [0250]
    [0251] - Fabrication, by means of drawing, of the two steel half-shells (1a) and (1b), one of which has a hole (1c) in which the fitting is welded.
    [0252]
    [0253] - Introduction of the diffuser element (3) inside the bottle (1) through its introduction in the form of rolls of mesh placed inside each of the half-bodies at the time prior to the realization of the joint welds same.
    [0254]
    [0255] - Application of welding points with the corresponding tooling.
    [0256]
    [0257] - Process of annealing in furnace to relieve it.
    [0258]
    [0259] Figures 15, 16 and 17 show an embodiment with nonlimiting illustrative character of a trailer with anti-explosive properties for transport of cryogenic fluids at high pressure and low temperature by dragging in a transport direction by a tractor truck as shown in Fig.15, the direction of transport being the direction of advance of the tractor truck.
    [0260] formed by a cabin and by a rear platform on which to bear part of the weight of the trailer or sema-trailer to be transported.
    [0261]
    [0262] The trailer shown in the present embodiment (Fig. 15 and 16) consists of a cryogenic tank filled with anti-explosive alloys in mesh / spheres format formed by an outer compartment 12, defined by an outer wall, which contains an interior compartment 11, defined by an inner wall, the outer and inner walls of both the outer 12 and inner 11 compartments being separated and spaced apart by spaced-apart spacing so as to reduce the thermal transmission therethrough. The space between both compartments constitutes an insulating chamber 13 filled with anti-explosive alloys. This nested construction of two compartments is shown in the section of Fig.16.
    [0263]
    [0264] The inner compartment 11 is resistant to high pressures to contain liquified liquids in the cryogenic state without the possibility of explosion. In order to achieve this resistance with a low weight, the geometry of the inner compartment 11 is optimized, which is proposed to consist of a cylindrical body of approximately 235 cm in diameter and approximately 18 meters in length defining at its center an axis of cistern E, the cylindrical body being closed at both ends by rounded caps. The result is an elongated compartment with high resistance to internal pressure.
    [0265]
    [0266] The outer compartment 12 completely envelops said inner compartment 11, reproducing its geometry, but with a larger size, its outer walls being parallel to the inner walls of the inner compartment 11 in the majority of said outer compartment 12, for example, to between 5 and 10 cm away.
    [0267]
    [0268] Under said cryogenic cistern 10, an anchoring means 40 for the articulated fixation and towing of the trailer by a tractor truck is fixed in its previous half. This type of anchoring means 40 are standardized and are those commonly used in all trailers of this type. Typically, they consist of a vertical descendant teat terminated by a projection attached to the trailer, and a pivoting platform equipped with a cradle-shaped center that culminates in a housing complementary to said projection of the vertical teton.
    [0269]
    [0270] Under the rear half of the trailer, in the transport direction, a chassis 20 is located which, in the present embodiment, consists of two parallel structural bars 21, for example, two profiles outside of the outer compartment 12, said outer compartment 12 being partially housed between said two parallel structural bars 21.
    [0271]
    [0272] The connection between each of the parallel structural bars 21 and the outer compartment 12 is produced by a cradle structural element 22, consisting of an element of increasing section in the direction of transport. Said cradle structural element 22 is welded to the outer compartment 12 at its upper end along a line parallel to the cistern axis E, and is subjected to the corresponding structural bar 21 at its lower end along its length. As the cradle structural element 22 of increasing section, the two parallel structural bars 21 are not parallel to the cistern axis E, but form an angle equal to the inclination of the cradle structural element 22. In this example the aforementioned inclination is of 2, 54 °.
    [0273]
    [0274] On the two parallel structural bars 21 the rest of the chassis 20 is fixed, where the suspension systems of three pairs of parallel wheels 30 are anchored, leaving three wheels 30 arranged on each side of the trailer, in its rear half. The six wheels 30 will be identical and, under conditions of equal pressure and on a flat floor, the trailer being supported on a tractor truck by its anchoring means 40, the axes of the wheels 30 will define a support plane of chassis P.
    [0275]
    [0276] In the present embodiment the inclination of the two structural bars 21 parallel to the cistern axis E has been calculated so that said two structural bars 21 are parallel to the support plane of the chassis P under the indicated conditions.
    [0277]
    [0278] As a result of the described characteristics, a trailer is obtained that includes a cryogenic tank 10 with its rear end lower than its front end, under transport conditions, with the lowest point of said cistern being less than 90 cm from the flat floor. This reduces the center of gravity of the trailer, offering safer transport conditions.
    [0279]
    [0280] Another embodiment not shown contemplates that the two parallel structural bars 21 are directly clad to the outer compartment 12 in a position parallel to the cistern axis E, and that under said structural bars 21 the cradle structural elements 22 are welded which will be increasing in the direction Of transport. To these structural elements of cradle 22 would be joined structural 21 would be parallel to the cistern axis E, and not to the support plane of the chassis P.
    [0281]
    [0282] In an additional embodiment not shown, it is proposed to dispense with the structural bars 21 and to use only the cradle structural elements 22 of increasing section in the transport direction.
    [0283]
    [0284] As it is evident, the trailer will include other elements to allow the safe filling and emptying of the cryogenic cistern, such as conduit systems, valves, etc., thus! as security elements for transport, such as bumpers, lights, signals, etc.
    权利要求:
    Claims (9)
    [1]
    1. Trailer for transporting anti-explosive of cryogenic fluids at high pressure and low temperature by dragging it in a direction of transport by a tractor truck, said trailer comprising:
    a cryogenic cistern (10) comprising:
    S an interior compartment (11) tight, defined by interior walls, resistant to high pressures, said inner compartment (11) sealed a cylindrical section closed by its two opposite ends by a spherical or rounded caps, defining said cylindrical section at its center a longitudinal cistern shaft (E) lying in the transport direction; Y
    S a sealed outer compartment (12), defined by exterior walls, which houses inside the interior compartment (11), the interior walls of the interior compartment (11) being spaced from the outer walls of the exterior compartment (12) defining between said inner and outer walls an insulating chamber (13), wherein said insulating chamber (13) is maintained at a total or partial watt, wherein the outer walls of said outer compartment (12) are parallel to the interior walls of the interior compartment (11) in most of the cryogenic tank (10); anchoring means (40) of the tank (10) to a tractor truck, said anchoring means (40) being located under the outer compartment (12) of the cryogenic tank (10) in its anterior half; a chassis (20) attached to the sealed outer compartment (12) of said cryogenic tank (10); and at least two pairs of wheels (30) facing their axes perpendicular to the transport direction, said wheels (30) having the same diameter and said wheels (30) being coupled to said chassis (20) by means of a suspension system, defining the axes of said wheels (30), under a uniform inflation and when the trailer is on a flat floor, and connected to a tractor truck by the anchoring means, a plane of support chassis (P); characterized in that the cistern axis (E) forms, in the transport direction, an angle of between 2 ° and 3.5 ° with respect to said chassis support plane (P), so that the rear portion of the cistern ( 10) Cryogenics is at a lower level than the front portion of it.
    [2]
    2. - Trailer according to claim 1 wherein the chassis (20) includes at least two parallel and facing structural bars (21) between which the outer compartment (12) of the cryogenic tank (10) is partially housed.
    [3]
    . - Emo that according to the new cac on on e ects of the future is for both sides and are parallel to the chassis support plane (P).
    [4]
    4. - Trailer according to claim 2 wherein said two parallel and facing structural bars (21) are parallel to the cistern axis (E).
    [5]
    5. - Trailer according to claim 1 wherein the chassis (20) includes at least two structural elements in cradle (22) faced between which is partially housed the outer compartment (12) of the cryogenic tank (10), each structural element in cradle (22) including at least one upper edge parallel to the tank axis (E), and at least one lower edge parallel to the chassis support plane (P).
    [6]
    6. - Trailer according to any one of claims 1 to 5, wherein the trailer being anchored to a tractor truck by means of said anchoring means (40) and on a flat and horizontal floor, the lowest point of the outer compartment (12) of the cryogenic cistern (10), at the rear of the trailer, is less than 100 cm from said flat floor.
    [7]
    7. - Trailer according to any one of claims 1 to 6, wherein the cryogenic cistern (10) has a length equal to or greater than 12 meters.
    [8]
    8. - Trailer according to any one of claims 1 to 7, wherein the cryogenic tank (10) has a diameter equal to or greater than 230 cm.
    [9]
    9. - Trailer according to any one of claims 1 to 8, wherein the cryogenic cistern (10) has in its structure woven fabric material comprising:
    S at least one arc of a plurality of polygonal openings,
    S at least one of these polygonal openings is irregular with respect to at least one adjacent polygonal aperture and having a surface area per unit volume of about 4,200 times the contact surface of the flammable fluids found in a container container and having a heat conduction capacity of at least about 0.023 Cal / cm-sec. S a density ranging from 2.8 g / cm3 to about 19.5 g / cm3.
    S a compression field of the sheets not more than 8%.
    S act as galvanic anode and anti-static.
    类似技术:
    公开号 | 公开日 | 专利标题
    KR101953943B1|2019-03-04|Storage tank containment system
    RU2444661C2|2012-03-10|High-pressure tank, particularly, made up of four body members
    ES1174784U|2017-01-24|Tank truck for the transport anti-hit of ariete of cryogenic fluids, liquefied gases, hydrocarbons to high pressure or low pressure. |
    US5228585A|1993-07-20|Variable capacity vehicle-mounted cryogenic storage vessels and method of making same
    US20160040829A1|2016-02-11|Storage tank containment system
    ES2708877B1|2020-01-20|TRAILER FOR ANTI-EXPLOSIVE TRANSPORTATION OF HIGH PRESSURE AND LOW TEMPERATURE CRIOGENIC FLUIDS
    ES1174617U|2017-01-23|Tank truck for the transport anti-algae of cryogenic fluids, liquefied gases, hydrocarbons at high pressure or low pressure. |
    ES1174785U|2017-01-24|Tank truck for anti-explosive transportation of cryogenic fluids, liquefied gases, hydrocarbons at high pressure or low pressure. |
    ES2695624B1|2019-12-05|CISTERNA TRUCK FOR THE ANTI-CORROSIVE TRANSPORTATION OF CRIOGENIC FLUIDS, LIQUID GASES, HYDROCARBONS AT HIGH PRESSURE OR LOW PRESSURE.
    ES2695648B1|2019-12-05|CISTERNA TRUCK FOR THE ANTI-EXPLOSIVE TRANSPORTATION OF CRIOGENIC FLUIDS, LIQUID GASES, HYDROCARBONS AT HIGH PRESSURE OR LOW PRESSURE.
    ES2695623B1|2019-12-05|CISTERNA TRUCK FOR THE ANTI-ALGAE TRANSPORT OF CRIOGENIC FLUIDS, LIQUID GASES, HYDROCARBONS AT HIGH PRESSURE OR LOW PRESSURE.
    ES2695348A2|2019-01-03|TANK TRUCK FOR THE TRANSPORT ANTI-HIT OF ARIETE OF CRYOGENIC FLUIDS, LIQUEFIED GASES, HYDROCARBONS TO HIGH PRESSURE OR LOW PRESSURE. |
    ES2395549T3|2013-02-13|Procedure for the manufacture of a plastic tank and plastic tank
    ES1174616U|2017-01-23|Trailer for anti-explosive transport of criogenic fluids at high pressure and low temperature |
    ES1195233U|2017-10-25|Tank, tank, tank that incorporates antiexplosive alloys in its interior by means of a system of filling and emptying manually, mechanized, electronic, robotic, flow, by pressure of venturi type and/or vacuum. |
    ES1181784U|2017-05-03|Tank truck for anti-thermal transport of cryogenic fluids, liquefied gases, high pressure or low pressure hydrocarbons |
    ES1188508U|2017-07-24|Tank truck for anti-vaporization transport of cryogenic fluids, liquefied gases, hydrocarbons at high pressure or low pressure. |
    EP2054126B1|2013-09-25|Explosion suppressor
    ES1187965U|2017-07-17|Wagon-traffic tank for the anti-thermal transport of cryogenic fluids, liquefied gases, hydrocarbons at high pressure or low pressure. |
    CN102940941A|2013-02-27|Nonmetal block explosion suppression sphere
    WO2018178437A1|2018-10-04|Tank or container for the transport and storage of cryogenic fluids, liquefied gases, hydrocarbons or chemical products at any pressure, which prevents explosions and spills resulting from the physical rupture or penetration of the tank for any reason
    US20190331296A1|2019-10-31|Storage tank containment system
    ES1181083U|2017-04-20|Alloy in laminar format or other formats, suppressor and reducer of all types of vaporizations and emissions. |
    WO2020141233A1|2020-07-09|Three-dimensional alloy for preventing and eradicating the creation and formation of microorganisms, bacteria, fungi, algae and corrosion in tanks of hydrocarbons, gases and drinkable liquids
    ES1189958U|2017-08-21|Bottles/cylinders for hydrocarbons filled with anti-explosive three-dimensional metal mesh. |
    同族专利:
    公开号 | 公开日
    ES2708877B1|2020-01-20|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US4674674A|1982-03-29|1987-06-23|Union Carbide Corporation|Method for fabricating fiberglass insulated mobile cryogenic tankage|
    DE8815487U1|1988-12-14|1989-07-06|Goettling, Ralph D., Dipl.-Ing., 2107 Ehestorf, De|
    EP0703115A1|1994-09-26|1996-03-27|Philippe Mangeard|Protector for tipper body|
    ES2524013A2|2013-01-19|2014-12-03|Technokontrol-Cat Global, Sl|Body of the alloys in laminar or other format, suppressors of all types of vaporizations and emissions. |
    DE102014000233A1|2014-01-09|2015-07-09|Linde Aktiengesellschaft|Trailer for liquefied gases|
    法律状态:
    2018-04-23| FA2A| Application withdrawn|Effective date: 20180417 |
    2019-04-11| BA2A| Patent application published|Ref document number: 2708877 Country of ref document: ES Kind code of ref document: A1 Effective date: 20190411 |
    2020-01-20| FG2A| Definitive protection|Ref document number: 2708877 Country of ref document: ES Kind code of ref document: B1 Effective date: 20200120 |
    优先权:
    申请号 | 申请日 | 专利标题
    ES201631738A|ES2708877B1|2016-12-30|2016-12-30|TRAILER FOR ANTI-EXPLOSIVE TRANSPORTATION OF HIGH PRESSURE AND LOW TEMPERATURE CRIOGENIC FLUIDS|ES201631738A| ES2708877B1|2016-12-30|2016-12-30|TRAILER FOR ANTI-EXPLOSIVE TRANSPORTATION OF HIGH PRESSURE AND LOW TEMPERATURE CRIOGENIC FLUIDS|
    [返回顶部]