• 专利附录
  • 专利说明
  • 权利要求
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    • 专利摘要:
    Portable tubular frame and fixed tubular frame derived from it. The present invention relates to a portable tubular structure comprising at least the following concentric layers: - an inner layer, made up of at least one sheet, being the free surface of the inner layer, which is the innermost surface, capable of forming a gap when the structure is in the extended position - an intermediate layer, to which the inner layer is attached, said intermediate layer is a bag capable of accommodating a filling material, - an outer layer, joined to the intermediate layer, said outer layer is formed by at least one sheet of the same material as the sheet of the inner layer, to a fixed structure derived from it and its use in hyperloop technology, for the construction of means of transport, such as trains. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2808729A1
    申请号:ES202031298
    申请日:2020-12-23
    公开日:2021-03-01
    发明作者:Ibanez José Ramón Albiol;Senach José Luis Bonet;Prada Miguel Angel Fernandez;Sosa Pedro Miguel;Martin Daniel Orient;Perez David Pistoni;Balaguer Juan Vicen;Lopez Fernando José Cos-Gayon;Barrachina Jaime Lozano
    申请人:Universidad Politecnica de Valencia;Zeleros Global SL;
    IPC主号:
    专利说明:

    [0002] PORTABLE TUBULAR STRUCTURE AND FIXED TUBULAR STRUCTURE
    [0004] TECHNICAL SECTOR
    [0005] The present invention is part of the technology called "hyperloop" for the industry of tunnels for transport, for example, passenger or freight trains, or for the industry, for example, for the shafts of wind turbines or any type of shaft or post in general.
    [0007] STATE OF THE ART
    [0008] In the construction industry, the current infrastructures of the "hyperloop" transport concept are based on steel pipes, which are difficult to handle and transport. Their costly production in iron and steel processes and in large-scale pipe manufacturing facilities diameter, gave rise to the need to reduce costs in its construction, transport and its implementation.
    [0010] Currently, this type of infrastructure of this size is unthinkable to transport them in one piece and assembly on site is very expensive.
    [0012] Document NL8102255A discloses a structure formed by a metal tube inside which an inflatable bag has been arranged and on it a reinforcing material. All of this can also be covered with an external sleeve. The manufacturing method comprises covering the inner wall of the mentioned tube (thin-walled, which can be made of aluminum) with at least one layer of uncured reinforced plastic (for example, carbon fiber, in which preferably the fibers are arranged in the longitudinal direction with respect to the tube). This layer of uncured plastic is placed around an inflatable bag (for example, made of silicone rubber) and then the bag with the plastic is simultaneously introduced into the outer tube. The bag is pressurized by gas and held under pressure during the curing of the plastic. The process saves labor and results in a more accurate product, allowing the fibers to be oriented in the longitudinal direction to maximize tensile strength, flexural strength and resistance to radial load. The product combines high strength and impact resistance with low weight.
    [0013] The structure of the present invention, which comprises at least two concentric layers, each of which has at least one sheet of composite material, and which are connected by an intermediate layer ("sandwich" type structure) is different from that described in NL8102255A, and as a result of these differences, has advantages such as being much less bulky, making transport much easier. The portable tubular structure of the present invention allows transport much more efficiently, since the inflation of the It is not carried out before disposal at the final site for use.
    [0014] The present invention also has advantages derived from the type and arrangement of layers that provide greater rigidity and resistance to the assembly.
    [0016] It also differs in the manufacturing method: in the case of NL8102255A, the inflatable bag is inflated and a fiber warp is woven over it. In the present invention, inflation and then laying of material on the resulting product is not carried out. It is only inflated in the present invention to obtain the assembled structure in its final location, formed by a mixture of already woven materials.
    [0018] Document WO2004105457A2 describes a sliding bearing consisting of FRP ( fiberreinforcedpolymer ) sheets: pre-impregnated carbon fibers at different angles and phenolic resin as curing agent. These materials make up the internal composite lining of the bearing. The materials of this coating are initially placed on the external surface of a mandrel, and then introduced into a metal casing. The mandrel is then removed and the liner and metal casing are wrapped with a vacuum bag; a vacuum is applied so that the coating is in close contact with the inner surface of the metal casing; and then the metal shell with the prepreg compound is placed in an autoclave until the prepreg compound is cured, and finally the vacuum bag is removed.
    [0020] The product disclosed in this document is different from that of the present invention, since according to the present invention it is a sandwich-type structure with two sub concentric structures or layers, nor is it manufactured in the same way. Nor is it intended for the same purpose.
    [0022] These tubular structures of hyperloop technology are currently built by various methods: manual molding ( hand lay up), pultrusion, infusion, etc., always along the entire length of the piece (their facilities are expensive) and they are difficult to transport (they use large vehicles , with difficult access to various areas).
    [0024] In view of the state of the art, there are still needs and problems pending to be solved in the technology related to hyperloop transport, which are objectives of the present invention:
    [0026] 1. Eliminate expensive fixed installations (such as pultruders), achieving that the assembly of a fixed tubular structure can be carried out in workshops with reduced installations and that a deflated portable structure can be transported to remote places and installed "in situ".
    [0027] 2. Reduce the use of metallic materials, reducing the carbon footprint and the exploitation of mines, less use of coal and reducing the cost of electrical energy systems to refine steel.
    [0028] 3. Facilitate the transport of the structure through its modulation, so that light transport vehicles can be used with easy access to any area.
    [0029] 4. Facilitate construction and installation.
    [0030] 5. Build a lightweight structural system with low-weight composite materials. 6. Achieve durability and longevity of the infrastructure, with little maintenance.
    [0032] The advantages of the invention are:
    [0033] - the most important advantage of the invention is that a portable structure is manufactured that is inflated once on site,
    [0034] - Easy assembly on site, as heavy machinery is not necessary for its transport or assembly. The assembly in situ is 3 times faster than in known infrastructures, the saving is important for such high structural requirements, as they are large structures to house a means of transport inside them, such as a train and even with diameters and "oversize" lengths,
    [0035] - fuel consumption is 3 times less per transport than for infrastructures known up to now,
    [0036] - uses non-traditional prefabricated materials,
    [0037] - a structure according to the invention (even "oversize") can be moved at low cost, multiplying by 10 the units of pipe that can be transported in a single truck with respect to known infrastructures. Light vehicles with high maneuverability can be used, with which the inconvenience during transport with the rest of road traffic does not exist and it can circulate at any time without special permits.
    [0039] The objectives of the invention are achieved through the use of portable tubular structures that are converted into fixed tubular structures according to the claims of this application.
    [0041] The manufacture of this portable tubular structure, with the shape described below, previously manufactured in the workshop, allows rapid execution, storage in confined spaces and transport to the assembly site quickly, reducing fuel consumption and facilitating access to places with difficult access by their roads.
    [0043] Once on site, a fixed tubular structure can be assembled in a similar way to how, for example, a hot air balloon is assembled (blowing air under pressure or injecting material into the intermediate layer).
    [0045] DESCRIPTION OF THE INVENTION
    [0047] The expression "tubular structure" in the present specification refers to an elongated structure that can have a cylindrical section, or of any type, for example, circular, oval, elliptical, square, rectangular section, and even I-shaped types, H, U, W, L, Z, X, V, S, T, Y, and that it has a central gap along its entire length.
    [0048] The term "cementitious material" or "cementitious matrix" refers to any material that contains cement in any proportion, such as cement, concrete, micro-concrete, mortar or micro-mortar.
    [0050] The present invention relates first of all to a portable tubular structure comprising at least the following concentric layers:
    [0051] - an inner layer, made up of at least one sheet
    [0052] whose free surface, which is the innermost surface, is capable of forming a hole when the structure is in the extended position
    [0053] - an intermediate layer, to which the inner layer is attached, said intermediate layer is a bag capable of accommodating a filling material,
    [0054] - an outer layer, joined to the intermediate layer, such that said outer layer is formed by at least one sheet of the same material as the sheet of the inner layer.
    [0056] The term "extended" means unfolded - since it can be folded - or unwound - unfolded that it can be rolled up.
    [0058] The present invention relates more specifically to a portable tubular structure comprising at least the following concentric layers:
    [0059] - an inner layer, formed by at least one sheet selected from carbon fiber sheets, glass fiber sheets, plastic fiber sheets, basalt fiber sheets, aramid sheets, polyamide fiber sheets, such as Kevlar, metal sheets, and combinations of such sheets
    [0060] whose free surface, which is the innermost surface, is capable of forming a hole when the structure is in the extended position
    [0061] - an intermediate layer, to which the inner layer is attached, said intermediate layer is a bag capable of accommodating a filling material,
    [0062] - an outer layer, joined to the intermediate layer, such that said outer layer is formed by at least one sheet selected from among sheets of carbon fibers, sheets of fiberglass, sheets of plastic fibers, sheets of basalt fibers, sheets of aramid, sheets of polyamide fibers, such as Kevlar, metal sheets, and combinations of such sheets.
    [0063] The free surface of the inner layer is the surface of the inner layer opposite to the surface through which it is attached to the intermediate layer, and which - therefore - is not in contact with another surface of the portable structure when it it is in an extended position, (ie, unfolded or unrolled), and is capable of forming a gap that forms a fixed tubular structure when the portable structure is disposed in its final location.
    [0065] According to particular embodiments, the portable tubular structure further comprises an outer plastic sheet in contact with the outer layer and an inner plastic sheet in contact with the free surface, or innermost face, of the inner layer, such that both outer and lower plastic sheets they form an envelope that encloses the external and internal layers of the portable structure, but maintaining the ability to form a gap that shapes a fixed tubular structure. The outer and inner plastic sheets can be of any plastic material, such as polyethylene.
    [0067] According to additional particular embodiments of the portable tubular structure, the outer layer and the inner layer are made up of different numbers of sheets.
    [0068] According to additional particular embodiments of the portable tubular structure, the outer layer and the inner layer are formed by the same number of sheets.
    [0069] According to additional particular embodiments, the outer layer and the inner layer are formed by the same number of sheets, these sheets being of identical composition in both layers, but being arranged in the inner layer in the reverse order to that found in the outer layer. By way of example, a portable tubular structure with five sheets in the outer layer of different composition and numbered from the outside in as 1,2, 3, 4 and 5, will have, according to this embodiment, an inner layer with five sheets of the same composition as those of the outer layer and arranged from outside to inside in the order 5, 4, 3, 2 and 1.
    [0071] According to additional particular embodiments of the portable tubular structure, the outermost sheet and the innermost sheet of the structure are made of carbon fiber.
    [0072] According to a preferred embodiment of the portable tubular structure, the outer layer is formed - from the outside inwards - by at least two sheets: a carbon fiber sheet and a glass fiber sheet, while the inner layer is formed - from the surface furthest from the center of the structure towards the inside - by sheets identical to those of the outer layer, placed in reverse order. That is, according to this embodiment, the inner layer is formed - from the surface furthest from the center of the structure towards the inside - of at least one glass fiber sheet and one carbon fiber sheet.
    [0074] In a particularly preferred embodiment, the outer layer is made up of two sheets: an outer one made of carbon fiber, and an inner one, glued to it, made of fiberglass, and the inner layer is made up of two sheets identical to those of the outer layer. so that the carbon fiber sheet is the innermost of them.
    [0076] The sheets that make up the outer and inner layers must be very thin to be able to fold them well or roll them at the time of transport. For example, they can be between 0.03mm and 2mm, preferably between 0.03mm and 1mm. In a particular embodiment, the layers are 0.05 mm thick, such as 0.05 mm thick steel.
    [0078] The sheets that make up each of the inner and outer layers comprise fibers of any weight and warp. These fibers can be arranged in a single direction with respect to the longitudinal axis of the structure, or they can be arranged in two directions (bidirectional) or in different directions with respect to said axis.
    [0080] The orientation of the fibers relative to each other, in a sheet, can vary so that the inclination of the fibers with respect to the longitudinal axis of the tubular structure can be between 0 ° and 360 °.
    [0082] For example, the sheets can be made up of fibers that are arranged in more than one direction relative to the longitudinal axis of the portable tubular structure, oriented in a way selected from:
    [0083] - an orientation selected between 45 ° and 90 ° with respect to the longitudinal axis of the portable tubular structure,
    [0084] - in transverse directions, with respect to the longitudinal axis of the portable tubular structure and
    [0085] - randomly oriented with respect to the longitudinal axis of the portable tubular structure.
    [0087] The selection of sheets with a single orientation or more than one orientation, and the type of orientation, depends on the stresses to which the external and internal layers are expected to be subjected, and, therefore, the fixed tubular structure of the invention derived from the portable tubular structure. The orientation of the fibers in the sheets allows obtaining various mechanical properties, such as resistance to compression, shear, tear and resistance to traction in different directions, among others.
    [0089] The thickness of the outer, inner and intermediate layers depends on the application for which the fixed tubular structure derived from the portable structure is intended. For example, in the case that the interior of the fixed tubular structure is intended to house a means of transport, such as a train, this thickness depends on the number of wagons, train speed, anticipated accelerations, the distance between supports (called light in tech jargon), among other factors. The thickness of the entire portable tubular structure can be between 10 and 25 mm. As an example, according to the state of the art, for a 1.5 m diameter tube, 12 m spans, for a 2TN (2 ton) weight test vehicle (and 5G test acceleration) the thickness is around 15 -20 mm thick in steel. With the present invention, the total thickness - of the three layers together - can be in this same range, but with 1/3 the weight of a structure of the state of the art.
    [0091] The intermediate layer is composed of a bag of any flexible material capable of accommodating a filling material. This flexible material that makes up the bag is preferably a plastic material, more preferably a plastic polymeric material.
    [0092] According to particular embodiments, the bag made of plastic material can be, for example, polyethylene, such as high-density polyethylene (HDPE) or low-density (LDPE).
    [0093] The middle layer bag has closure systems, which can be valves, such as non-return valves, or car tire type closure systems, so that the bag can be or is hermetically closed. These valves or closure devices are preferably arranged in the bag prior to the attachment of the bag to the outer and inner layers of the portable tubular structure.
    [0095] Adhered to said bag of the intermediate layer - each on one side of the bag - the inner layer and the outer layer.
    [0097] The function of the bag of the intermediate layer is to house the filling material, such as an expansive material, for example, a foam or a gas, (as examples of gases, air or argon can be mentioned). Among the expansive material we can mention a material that fresh without hardening is expansive, such as expansive concrete, or polyurethane foam. The filling material will help shape the fixed tubular structure in its final location.
    [0099] The terms "expansive" and "expandable" are used synonymously herein.
    [0101] The present invention also relates to a fixed tubular structure comprising the concentric layers of the portable structure defined above, in which:
    [0102] - in the inner layer, attached to the intermediate layer, the fibers of the sheet (and therefore the sheet), or sheets, are bound by a matrix,
    [0103] and whose free surface forms the central, longitudinal interior hollow of the fixed tubular structure,
    [0104] - the intermediate layer comprises a filling material inside the bag,
    [0105] - in the outer layer, attached to the intermediate layer on the opposite side to which the intermediate and inner layer are attached, the fibers of the sheet or sheets (and therefore the sheet (s)), they are bound together by a matrix.
    [0107] The matrix that binds the sheets of the outer and inner layers can be selected from a polymeric matrix and a cementitious matrix. The polymeric matrix can be a matrix selected from a resin and a geopolymer.
    [0108] The matrix that binds the sheets can be the same in the outer and inner layer, or it can be a different matrix in one layer with respect to the other.
    [0110] "Free surface" of the inner layer refers to the innermost surface, and that in the finished fixed structure (when the inner bag used in the manufacturing process, described below has already been removed), it is not in contact with other sheets or materials.
    [0112] According to particular embodiments, the fixed tubular structure comprises - as the corresponding embodiment in the portable structure - in addition, an outer plastic sheet in contact with the outer layer and an inner plastic sheet in contact with the free surface, or innermost face, of the inner layer, such that both outer and lower sheets form an envelope that encloses the outer layer and the inner layer of the fixed structure. The outer and inner plastic sheets can be of any plastic material, such as polyethylene.
    [0114] According to a particular embodiment of the fixed tubular structure: the sheets that form the inner and outer layers are composed of materials called FRP.
    [0115] On FRP materials:
    [0116] - the fibers can be made of any material, in particular the aforementioned materials: carbon fibers, fiberglass, plastic fibers, basalt fibers, aramid fibers, polyamide fibers,
    [0117] - and the matrix that binds the fibers is a polymeric or cementitious matrix.
    [0119] The term "FRP" refers to "reinforced polymeric fibers" or "fiber reinforced polymers". They are composite materials, which comprise a polymeric or cementitious matrix, reinforced with fibers. The union of the fibers and the matrix make them a FRP sheet.
    [0120] The fibers contained in the materials called FRP can be any type of fiber, and in particular, from materials selected from fiberglass, aramid, carbon fibers, plastic fibers, basalt fibers, polyamide fibers, such as Kevlar.
    [0121] The material preferably between FRP is FRP containing carbon fiber (CFRP (Carbon Fiber Reinforced Polymer (polymer reinforced with carbon fiber)), and the FRP containing glass fibers (GFRP) (Glass fiber reinforced polymer (polymer fiberglass reinforced)),
    [0123] The matrix in the case of using FRP materials can comprise:
    [0124] - resins, such as polyester resins, polyamide, vinyl ester resins, acrylic resins, epoxy resins, phenolic resins, urethane resin,
    [0125] - cementitious materials
    [0126] - geopolymers (polymers found in the earth's crust, such as aluminosilicates)
    [0127] and combinations of them.
    [0129] The expression "combinations of them" means that you can have one type of matrix material in the outer layer and another type of matrix in the inner layer, but the different types of matrix materials are not mixed in the same layer.
    [0131] By way of example, FRP can be fiber meshes impregnated with resins, so that when the resin that binds them hardens, a very resistant mesh is generated.
    [0133] FRP materials, such as CFRP or GFRP, have the function of supporting the stresses generated by the distance between the supports, as well as the function of strapping, among others (wind, train actions, among others).
    [0135] According to a further particular embodiment of the fixed tubular structure: the sheets that form the inner and outer layers are composed of MLF.
    [0137] The materials called MLF are composite materials that comprise the same type of fibers as in the case of FRP, in which the matrix that binds the fibers is a polymeric or cementitious matrix, and to which some film or sheet of fiber has been added. metallic nature. That is, FML materials comprise the same materials as FRP in the fibers of the sheets and also comprise one or more sheets metallic, such as steel, galvanized, or aluminum (all its variants, such as those that can be achieved according to the manufacturing process, or that may have some additional chemical element, or that are achieved depending on the type of cooling or modified metals obtained by chemical, mechanical, thermal and thermochemical processes). MLF are laminates of thin layers of metal joined by sheets similar to those of an FRP material - as defined above Among the best known MLFs we can mention some that contain aluminum, such as:
    [0138] ARALL (aramid fiber reinforced aluminum laminate)
    [0139] GLARE (glass fiber reinforced aluminum laminate)
    [0140] CARALL (carbon fiber reinforced aluminum laminate).
    [0142] The MLF materials can be those known in the state of the art or they can be micro-perforated MLF.
    [0144] Microperforated MLFs are MLF materials as defined above, in which the metal sheets are microperforated.
    [0146] In microperforated MLF materials, microperforations can represent between 5 and 95% of the metal sheet (s). The higher the percentage of perforations, the easier it is for the matrix material that binds the fibers, and therefore the sheets, to pass through.
    [0148] There is an alternative of the fixed tubular structure according to which the metal sheet or sheets of the FML materials are not micro-perforated: it is the case in which these metal sheets are placed adjacent to the bag of flexible material the intermediate layer.
    [0150] Micro-perforated MLF materials are preferably used in the present invention, so that the matrix that binds the sheets can pass through said metal sheets.
    [0151] FRP or FML materials reinforced, for example, with fiberglass are responsible for supporting the structure as a whole, preventing it from deforming and allowing it to withstand sub-pressures inside.
    [0153] The polymeric matrix of FML materials can comprise the same materials as in the case of FRP materials. Preferably, in MLF materials the matrix is a polymeric matrix of resins:
    [0154] You can have, for example, a resin matrix in the outer layer and a cementitious matrix in the inner layer.
    [0156] According to particular embodiments, the fixed tubular structure comprises at least the following concentric layers:
    [0157] - an inner layer formed by at least one sheet of a material selected from: FRP and FML, and whose free surface forms the central, longitudinal interior hollow of the tubular structure,
    [0158] - an intermediate layer, to which the inner layer and the outer layer are attached by opposite sides of the intermediate layer, said intermediate layer is formed by a bag of flexible material, comprising a filling material,
    [0159] - an outer layer, joined to the intermediate layer, said outer layer is formed by at least one sheet of a material selected from: FRP and FML.
    [0161] According to particular embodiments of the fixed tubular structure, the outer layer and the inner layer are made up of the same number of sheets, these sheets being of identical composition in both layers, but being arranged in the inner layer in the reverse order to that found in the outer layer.
    [0163] According to additional particular embodiments of the fixed tubular structure, the outermost sheet of the structure and the innermost sheet of the structure are made of FRP comprising carbon fiber.
    [0165] According to additional particular embodiments of the fixed tubular structure, the innermost sheet of the outer layer and the outermost sheet of the inner layer of the structure are made of FRP comprising glass fiber.
    [0166] According to a preferred embodiment, the outer layer is formed - from the outside inwards - of at least one FRP sheet with carbon fiber and one sheet of FRP with fiberglass, while the inner layer is formed - from the surface farthest from the center of the structure towards the inside - by sheets identical to those of the outer layer, placed in reverse order. That is, according to this embodiment, the inner layer is formed - from the surface furthest from the center of the structure towards the inside of, - at least-, one sheet of FRP with fiberglass and one sheet of FRP with carbon fiber. .
    [0168] In one embodiment of the fixed tubular structure, the outer layer is formed by one or more sheets of FRP, or by sheets of FML, or combinations of FRP and FML sheets, while the inner layer is formed, from the surface furthest from the center of the structure towards the inside, by sheets identical to those of the outer layer, placed in reverse order.
    [0170] In a preferred embodiment of the fixed tubular structure, the outer layer is made up of two sheets: an outer layer of FRP with carbon fiber, and an inner layer made of FRP with glass fiber, and the inner layer is made up of two sheets. identical to those of the outer layer, so that in the inner layer, the FRP sheet with carbon fiber is the innermost of them.
    [0172] In a further preferred embodiment,
    [0173] the outer layer is made up of:
    [0174] - two sheets: one exterior with carbon fiber, and one interior made of metal and that makes up the FML material,
    [0175] - or it is made up of two sheets: an outer one with fiberglass, and an inner one of metal and that makes up the FML material
    [0176] and in each case, the inner layer is made up of two sheets identical to those of the outer layer arranged in reverse order
    [0177] For example, the fixed tubular structure can have an outer layer, comprising from outside to inside: FML + FRP or FRP FML. In the same layer there may be a combination of MLF and FRP.
    [0179] Some examples of the composition of the fixed (finished) tubular structure are lattices of sheets (the sheets can be parallel to each other, or they can be crisscrossed) of the following materials, named in all cases from the outside to the inside:
    [0180] - CFRP + GFRP + LDPE + PUexpanded + LDPE + GFRP + CFRP is the model of the section presented in fig. 1, named from outside to inside,
    [0181] - GFRP + CFRP + LDPE + PUexpanded + LDPE + GFRP + CFRP
    [0182] - GFRP + CFRP + LDPE + PUexpanded + LDPE + CFRP + GFRP
    [0183] - CFRP + STEEL + GFRP + LDPE + PUexpanded + LDPE + GFRP + STEEL + CFRP where:
    [0184] LDEP stands for Low Density Polyethylene
    [0185] PU stands for polyurethane (polyurethane).
    [0187] Other alternative examples of a fixed tubular structure are:
    [0188] -that the outer layer has the composition CFRP + Al + GFRP + Al, as preferred, or - that the outer layer has the composition: CRFP + GFRP + Al or CFRP + Al + GFRP
    [0190] The sheets of fibers that make up the inner and outer layers in the fixed tubular structure, for example, the sheets of FRP and / or FML, can be formed by fibers that are arranged in the same direction or in more than one direction relative to the longitudinal axis of the fixed tubular structure. For example, the fibers can be oriented in different directions, analogously and as indicated for the fibers in the sheets of the portable tubular structure.
    [0192] The thickness of the outer, inner and intermediate layers depends on the application for which the fixed tubular structure is intended.
    [0193] Each of the fiber sheets that make up the inner and outer layers can be between 0.5 mm and 3 mm (for example, FRP and FML in the fixed tubular structure), preferably between 0.5 and 2.8 mm .
    [0195] It is necessary to apply a binder material to the fibers of the outer and inner layers for their hardening and to achieve the rigidity of all their layers. With this material, which is the matrix, polymeric or cementitious, the durability of the structure is achieved. Depending on the type of material - matrix - desired hardening and / or curing and / or rigidity effects are obtained.
    [0197] The binder matrix can be applied manually or automated. It can be applied, for example, by spraying or injection-vacuum.
    [0199] The intermediate layer is composed of a bag made of flexible material, such as plastic, which contains inside a filling material, preferably a plastic polymer. This intermediate layer will help shape the fixed tubular structure.
    [0201] The bag of the intermediate layer is sealed (previously, in the manufacture of the portable structure) and is filled when the portable tubular structure is in its final location for obtaining the fixed tubular structure. Adhered to said bag - each on one side of the bag - the inner layer and the outer layer.
    [0203] The outer and inner layers are attached, preferably glued, to the bag made of flexible material, preferably polymeric. They stick to it, for example, with flexible elastic glue.
    [0205] The filling of the intermediate layer is of an expandable material such as a material selected from a foam, a polymeric expanded material, such as polyurethane (PU), a gas (such as air or argon), and a cementitious material.
    [0207] The filling material has the function of filling the entire interior of the bag with the intermediate layer (which will be hermetically closed once filled) and that once it is arranged in the bag provides rigidity and the shape that the tubular structure needs. fixed, providing it with sufficient resistance to maintain its shape and with a fairly low weight (compared to known structures).
    [0209] The fixed tubular structure may further comprise a liner formed by one or more protective layers and optionally additionally decorative layers. The coating may comprise, by way of example, paints and limes.
    [0211] The coating is applied on the inner surface (inner face of the inner layer), outer surface (outer layer of the outer layer) or both, of the fixed tubular structure.
    [0213] The paints or limes can be applied for different purposes such as protecting from fire, therefore, fire retardant paints can be applied. Thermal paints, anti-corrosion paints, against UV solar rays, solar radiation absorbing paints that reduce the temperature of the structure, among others, can be applied. Decorative paints can also be applied to color the fixed tubular frame.
    [0215] Regarding the mechanical behavior of the fixed tubular structure, the stresses to which it is subjected in a section, the stresses of a compression, traction, shear, torsion beam and point loads both in supports and along the tubular structure are absorbed by the combination by the sheets (such as FRP, FML) that make up the outer and inner layers, as well as by the intermediate layer.
    [0217] According to a preferred embodiment, the fixed tubular structure comprises:
    [0218] - inner layer: it comprises a network of meshes or sheets of FRP and / or FML that comprise carbon fiber in the innermost part and that comprise fiberglass in the outer part, in different orientations with respect to the longitudinal axis of the structure, such that the FRP and / or FML sheet comprising the outermost glass fibers (of larger dimensions, diameter in the case of circular section structures) within the inner layer is glued to a plastic polymeric bag, as can be seen in Figure 1,
    [0219] - Intermediate layer: formed by a plastic bag to which the outermost FRP and / or FML sheet comprising fiberglass, of the inner layer, and the innermost FRP and / or FML sheet comprising fiber glass, from the outer layer, such that this bag is filled with expansive polyurethane foam,
    [0220] - external layer: it comprises a network of meshes or sheets of FRP and / or FML that comprise carbon fiber in the outermost part and that comprise glass fiber in the inner part, in different orientations with respect to the longitudinal axis of the structure, such that the FRP and / or MLF sheet comprising the innermost glass fibers (of a smaller diameter, in the case of circular section structures) within the outer layer is glued to the plastic polymeric bag, as seen in Figure 1.
    [0222] The invention has as a further object a method of manufacturing the portable tubular structure and the fixed tubular structure defined above.
    [0224] The manufacturing process of the portable tubular structure comprises:
    [0225] - arrange the sheets of the outer layers,
    [0226] - arrange a double sheet that will make up the bag of the intermediate layer
    [0227] - arrange the sheets of the inner layer
    [0228] - Make the union of the sheets of the outer layer and on the other hand make the union of the sheets of the inner layer
    [0229] - join the previous layers and
    [0230] - have at least one valve in the double sheet of flexible material for the introduction of filling material,
    [0231] the stages being able to be carried out in an order other than the order in which they are mentioned, and in particular, the last two stages can be carried out in the reverse order.
    [0233] According to a first particular embodiment, the manufacturing process of the portable tubular structure comprises:
    [0234] - arrange the sheets of the outer and inner layers
    [0235] - Make the union of the sheets of the outer layer and on the other hand make the union of the sheets of the inner layer
    [0236] - join a double sheet of flexible material for the formation of a bag (sealing) capable of accommodating filling material, to the two inner and outer layers, one on each side of the double sheet, obtaining the bag that forms the intermediate layer
    [0237] - have at least one valve in the double sheet of flexible material for the introduction of filling material,
    [0238] the stages being able to be carried out in an order other than the order in which they are mentioned, and in particular, the last two stages can be carried out in the reverse order.
    [0240] The sheets of each of the outer and inner layers used in the first stage are preferably joined together, by interlocking.
    [0242] The outer and inner layers are attached to the sheets that make up the bag of the intermediate layer by gluing. The respective sheet of the outer and inner layer, which is closer to the bag of flexible material, than the intermediate layer, can be glued by heat sealing or with flexible plastic glue to the plastic bag, by ultrasonic wave or by induction. The adhesive with flexible plastic glue to the bag of the intermediate layer is carried out in a percentage of the surface comprised between 10 and 90% of each layer. In this way it is possible to roll or fold the portable tubular structure to facilitate the transport of the portable tubular structure to the construction site - final site-
    [0244] Optionally, the operation of gluing the two sets of interwoven sheets to the bag of flexible material can be carried out before the stage of placing valves for filling the bag, such as plastic, which forms the intermediate layer, but preferably it is carried out after the placement of the valves for filling the bag of flexible material.
    [0246] The sealing of this bag of the intermediate layer can be carried out by heat sealing, by ultrasonic vibration or by induction, preferably it is sealed by heat sealing. The bag has at least one valve that can be previously arranged, or that is arranged once the sheets have been sealed and the bag shaped. Valve or valves They serve to introduce the filling material, and control the exit of the excess of said material that may have been introduced.
    [0247] The sealing of the polymeric bag is not done manually, it is done with non-return valves or car tire systems.
    [0249] Induction sealing, or lid sealing, is a non-contact method of heating a metal disk to hermetically seal the tops of plastic and glass containers. This sealing process takes place after the container has been filled with its contents and the lid has been placed in position. The name comes from the fact that the method uses the principle of electromagnetic induction to generate heat and fix the seal material.
    [0251] According to a more particular embodiment, the method for manufacturing the portable tubular structure comprises:
    [0252] - make an interlock of at least two meshes or sheets, one of carbon fiber and the other of glass fiber, for the inner layer and at least two other sheets of the same materials - with an inverse distribution with respect to the inner layer - to the outer layer (see Figure 1),
    [0253] - glue the two sets of interlocked sheets to one side and the other side of the double sheet bag that will make up the intermediate layer bag, for example, using a glue for flexible plastics
    [0254] - placing at least one valve for filling with a filling material in a double sheet that will form the bag of flexible material that in turn forms the intermediate layer
    [0255] - sealing the bag of flexible material of the intermediate layer, in the form of a tube with a heat sealer, leaving the opening of the valve or valves, which serves to introduce an expansive material, such as foam and control the exit of the excess material introduced .
    [0257] The portable tubular structure is ready to be folded or rolled and transported to the location of the fixed tubular structure.
    [0258] The operation of gluing the two sets of interwoven sheets to one side and the opposite of the bag of flexible material that makes up the intermediate layer, by means of a glue for flexible plastics, can alternatively be done as follows:
    [0259] - Interlocking of sheets obtaining the outer layer
    [0260] - Bonding of the outer layer to the sheet that makes up the bag of flexible material or to the previously shaped bag.
    [0261] - Interlocking of sheets obtaining the inner layer
    [0262] - Glued the inner layer to the bag of flexible material.
    [0264] According to a second alternative embodiment, the manufacturing method of the portable tubular structure comprises:
    [0265] - arrange the sheets of the outer layers extended,
    [0266] - arrange on them the double sheet of flexible material that will make up the bag of the intermediate layer
    [0267] - arrange on the front double sheet, the sheets of the inner layer
    [0268] - make the union of all the previous sheets at their ends
    [0269] - have at least one valve in the double sheet of flexible material for the introduction of filling material,
    [0270] the last two stages can be carried out in reverse order.
    [0272] According to an alternative embodiment, the manufacturing method of the portable tubular structure comprises:
    [0273] - lay out an extended plastic sheet
    [0274] - arrange on it the sheets of the outer layers
    [0275] - arrange on them the double sheet that will make up the bag of the intermediate layer - arrange on the previous double sheet, the sheets of the inner layer
    [0276] - arrange on the sheets of the inner layer a second plastic sheet
    [0277] - make the union of all the previous sheets at their ends
    [0278] - have at least one valve in the double sheet of flexible material for the introduction of filling material,
    [0279] having valves in the outer and inner layers to be able to carry out an infusion-vacuum process at the final location.
    [0280] The manufacturing process of the fixed tubular structure comprises:
    [0281] - arrange the portable tubular structure, previously manufactured, at the location of the fixed tubular structure
    [0282] - insert an internal bag into the internal hole of the structure
    [0283] - fill the inner bag by inflation or injection
    [0284] - fill the middle layer bag with the filling material,
    [0285] - remove the inner bag
    [0286] - apply the material that binds the sheets of the outer and inner layers of the tubular structure from the previous stage, obtaining the fixed tubular structure.
    [0288] The union of the external and internal layers between them can be carried out in two ways: by connectors, or through the intermediate layer, by contact with it, in which case they are not joined directly between them.
    [0290] According to a particular embodiment, the inner layer and the outer layer are joined together by connectors arranged between them. This operation is carried out on site, that is, "in situ", at the final site. These connectors are rigid elements, for example made of metal (such as aluminum, steel) or FRP. The connectors are elements of connection that can have a section between 5 and 9000 mm2 and its length can be, at most, the total thickness of the tubular structure. As can be seen in figure 1, they are placed radially and separated at an angle of between 25 ° and 35 °, for example, approximately 30 ° to the section This alternative is a preferred embodiment of the invention.
    [0292] Throughout the tubular structure the connector sections are spaced 30-50 cm apart.
    [0294] According to a further particular embodiment, the inner layer and the outer layer are joined together, along their contour (this is only during commissioning, in situ), for example, and preferably, by means of the matrix that binds the sheets preferably by means of a resin. This option is only carried out at the final location of the fixed tubular structure, that is, it is not used to obtain the tubular structure. laptop. In this case of gluing the external and internal layers together in the portable structure, a maximum of 40% of the surface of the layers will be glued using a flexible plastic glue, because if this percentage is higher, the material that binds the fibers of the sheets into the layers of the tubular structure.
    [0296] In the preferred case of using connectors to join the outer and inner layers, said connectors are placed by drilling the layers, after removing the inner bag from the structure, and before applying the resin or cementitious matrix to the layers to harden the layers. sheets.
    [0298] Optionally, the fixed tubular structure obtained can be treated with materials for painting, liming, decorating, among others.
    [0300] According to a particular embodiment, the method for manufacturing the fixed tubular structure comprises:
    [0302] 1 - make an interlock of at least two meshes or sheets, one of carbon fiber and the other of glass fiber, for the inner layer and at least two other sheets of the same materials - with an inverse distribution with respect to the inner layer - for the outer layer (see Figure 1) -2. Glued the two sets of interwoven sheets - one on each side - to a double sheet that will form the bag - which once heat-sealed forms the intermediate layer -, using a glue for flexible plastics.
    [0303] 3. Placement of valves to fill the plastic bag that makes up the intermediate layer.
    [0304] 4. Sealing of the plastic bag of the intermediate layer, in the form of a tube with a heat sealer (leaving the opening of the valve or valves, which is used to introduce a foam and control the exit of the excess foam introduced).
    [0305] 5. Arrangement and inflation of an inner bag in the hollow that forms the inner layer; Once the inner bag is inflated inside the tube, the intermediate layer 6 is filled. After several hours, preferably 24 hours, the "balloon" or inner bag is deflated for subsequent extraction.
    [0306] 7. To harden the sheets of the outer and inner layers, it is injected or sprayed with the materials that bind the sheets and the fibers of the sheets, such as the resins already mentioned.
    [0307] At the same time they are protected from the elements.
    [0309] The inflation of the inner bag can be done by means of a compressed air compressor.
    [0311] The polymeric matrix (made of resin or geopolymers) or cementitious material is applied "in situ" on the sheets of the external and internal layers, thus obtaining the FRP or FML materials. The matrix material is introduced between the fibers , occupying the space available in the gaps and binding them. According to the language used by experts, the matrix material "wets" the fibers of the sheets.
    [0313] The tubular structure is capable of being inflated "in situ", acquiring its final shape through inflation at the final location.
    [0315] The materials that bind the sheets of the outer and inner layers have the function of acting as hardening, reinforcing or "core reinforcement" materials to give rigidity to the previously made tubular structure.
    [0317] According to an alternative embodiment, the manufacturing method of the fixed tubular structure comprises
    [0318] - arranging the portable tubular structure, previously manufactured, which comprises in this case, a plastic wrap, at the location of the fixed tubular structure - inserting an internal bag into the interior hollow of the structure
    [0319] - fill the inner bag by inflation or injection
    [0320] - fill the middle layer bag with the filling material
    [0321] - remove the inner bag
    [0322] - apply the material that binds the sheets of the external and internal layers of the tubular structure of the previous stage, by means of an infusion-vacuum process, obtaining the fixed tubular structure.
    [0323] The infusion-vacuum process, which takes place after the filling stage of the intermediate layer, comprises:
    [0324] - having at least one valve in the outer layer and at least one valve in the inner layer of the structure through which the vacuum is drawn
    [0325] - having at least one valve in the outer layer and at least one valve in the inner layer of the structure through which the matrix material that binds the fibers is injected.
    [0326] - making a vacuum through the vacuum valves, while injecting the matrix material that binds the fibers through the material injection valves.
    [0328] The infusion-vacuum process for the application of the matrix material has the advantages that no previous molds are needed in the workshop, since the intermediate layer after swelling acts as a mold "in situ".
    [0330] In the process of the present invention, no autoclaves are needed, the hardening of the materials is carried out at room temperature.
    [0332] Finally, the mentioned paints or limes can be applied for protective and / or decorative purposes.
    [0334] The invention is applicable to current infrastructures of the "hyperloop" concept or to wind tower shafts.
    [0336] BRIEF DESCRIPTION OF THE FIGURES
    [0338] Figure 1: Infographic of the section of a particular embodiment of the tubular structure of the invention, in which:
    [0339] 1: FRP / FML sheets with carbon fiber
    [0340] 2: FRP / FML sheets with fiberglass
    [0341] 3: plastic bag
    [0342] 4: polyurethane foam
    [0343] IN: inner layer
    [0344] I: intermediate layer
    [0345] E: outer layer
    [0346] 5: connectors
    [0347] The connectors are appreciated, which are positioned radially and spaced at an angle of approximately 30 °. Along the fixed hybrid tubular structure the connectors maintain a separation that can be between 10 and 50 cm, preferably 30 and 50 cm. Figure 2: Photograph of the circular section of a particular embodiment of the structure of the invention.
    [0348] Figure 3: a particular embodiment of the tubular structure before inflation of the polymeric bag. In the figure you can see two bags: the one on the left of the figure is the bag arranged in the hole formed by the inner layer, and the other bag is the plastic bag that makes up the intermediate layer of the structure. In this figure you can see the orientation of the sheets is longitudinal.
    [0349] Figure 4: a particular embodiment of the tubular structure in which the inner bag is inflated, but the intermediate layer bag has not yet been filled.
    权利要求:
    Claims (39)
    [1]
    1. A portable tubular structure comprising at least the following concentric layers:
    - an inner layer, made up of at least one sheet,
    being the free surface of the inner layer, which is the innermost surface, capable of forming a gap when the structure is in the extended position
    - an intermediate layer, to which the inner layer is attached, said intermediate layer is a bag capable of accommodating a filling material,
    - an outer layer, joined to the intermediate layer, said outer layer is formed by at least one sheet of the same material as the sheet of the inner layer.
    [2]
    2. Portable tubular structure according to claim 1, further comprising an outer plastic sheet in contact with the outer layer and an inner plastic sheet in contact with the free surface, or innermost face, of the inner layer, such that both outer sheets and bottom form an envelope that encloses the outer layer and the inner layer of the wearable structure.
    [3]
    3. Portable tubular structure according to claim 1 or 2, comprising at least the following concentric layers:
    - an inner layer, formed by at least one sheet selected from carbon fiber sheets, glass fiber sheets, plastic fiber sheets, basalt fiber sheets, aramid sheets, polyamide fiber sheets, metal sheets, and combinations of said sheets
    whose free surface, which is the innermost surface, is capable of forming a hole when the structure is in the extended position
    - an intermediate layer, to which the inner layer is attached, said intermediate layer is a bag capable of accommodating a filling material,
    - an outer layer, joined to the intermediate layer, such that said outer layer is formed by at least one sheet selected from among sheets of carbon fibers, sheets of fiberglass, sheets of plastic fibers, sheets of basalt fibers, sheets of aramid, sheets of polyamide fibers, metal sheets and combinations of said sheets.
    [4]
    Portable tubular structure according to one of Claims 1 to 3, in which the outer layer and the inner layer are formed by the same number of sheets or by different numbers of sheets.
    [5]
    Portable tubular structure according to one of claims 1 to 4, in which the outer layer and the inner layer are formed by the same number of sheets, these sheets being of identical composition in both layers, but being arranged in the inner layer in reverse order to that found in the outer layer.
    [6]
    6. Portable tubular structure according to one of claims 1 to 5, in which the outermost sheet and the innermost sheet of the structure are made of carbon fiber.
    [7]
    Portable tubular structure according to one of claims 1 to 5, in which the outermost sheet and the innermost sheet of the structure are made of carbon fiber bonded to a fiberglass sheet.
    [8]
    Portable tubular structure according to one of claims 1 to 5, in which the outer layer is formed - from the outside inwards - by at least two sheets: a carbon fiber sheet and a glass fiber sheet, while the inner layer is formed - from the surface furthest from the center of the structure inwards by sheets identical to those of the outer layer, placed in reverse order.
    [9]
    Fixed tubular structure comprising the concentric layers of the portable structure defined above in one of claims 1 to 8, in which:
    - in the inner layer, joined to the intermediate layer, the fibers of the sheet or sheets are bound by a matrix,
    and whose free surface forms the central, longitudinal interior hollow of the fixed tubular structure,
    - the intermediate layer comprises a filling material inside the bag,
    - in the outer layer, attached to the intermediate layer on the opposite side to which the intermediate and inner layers are attached, the fibers of the sheet or sheets are bound by a matrix.
    [10]
    10. Fixed tubular structure according to claim 9, in which the matrix that binds the sheets of the outer and inner layers is selected from a polymeric matrix and a cementitious matrix.
    [11]
    Fixed tubular structure according to claim 9 or 10, further comprising an outer plastic sheet in contact with the outer layer and an inner plastic sheet in contact with the free surface, or innermost face, of the inner layer, such that both outer and lower sheets form an envelope that encloses the outer layer and the inner layer of the fixed structure.
    [12]
    Fixed tubular structure according to one of Claims 9 to 11, in which the inner and outer layers are composed of FRP, MLF or combinations thereof.
    [13]
    Fixed tubular structure according to one of claims 9 to 12, in which the materials that make up the sheets are selected from carbon fibers, fiberglass, plastic fibers, basalt fibers, aramid fibers, polyamide fibers, and metals.
    [14]
    Fixed tubular structure according to one of claims 9 to 13, in which the inner and outer layers are composed of FRP comprising carbon fiber and FRP comprising glass fiber.
    [15]
    Fixed tubular structure according to one of claims 9 to 14, in which the outer and inner layers are made of FRP and the polymeric matrix comprises materials selected from:
    - resins, preferably polyester resins, polyamide, vinyl ester resins, acrylic resins, epoxy resins, phenolic resins, urethane resin,
    - cementitious materials and
    - geopolymers,
    and combinations of them
    [16]
    16. Fixed tubular structure according to one of claims 9 to 15, in which the outer and inner layers are made of MLF and the polymeric matrix comprises materials selected from:
    - resins, preferably polyester resins, polyamide, vinyl ester resins, acrylic resins, epoxy resins, phenolic resins, urethane resin and
    - geopolymers
    and combinations of them.
    [17]
    Fixed tubular structure according to one of claims 9 to 16 comprising at least the following concentric layers:
    - an inner layer formed by at least one sheet of a material selected from: FRP and FML, and whose free surface forms the central, longitudinal interior hollow of the tubular structure,
    - an intermediate layer, to which the inner layer and the outer layer are attached by opposite sides of the intermediate layer, said intermediate layer is formed by a bag of flexible material, comprising a filling material,
    - an outer layer, joined to the intermediate layer, said outer layer is formed by at least one sheet of a material selected from: FRP and FML.
    [18]
    Fixed tubular structure according to one of Claims 9 to 17, in which the outer layer and the inner layer are formed by the same number of sheets, these sheets being of identical composition in both layers, but being arranged in the inner layer in reverse order to that found in the outer layer.
    [19]
    Fixed tubular structure according to one of claims 9 to 18, in which the outermost sheet of the structure and the innermost sheet of the structure are made of FRP comprising carbon fiber.
    [20]
    Fixed tubular structure according to one of claims 9 to 18, in which the innermost sheet of the outer layer and the outermost sheet of the inner layer of the structure are made of FRP comprising glass fiber.
    [21]
    21. Fixed tubular structure according to one of claims 9 to 18, in which the outer layer is formed by a sheet of FRP with carbon fiber and a sheet of FRP with fiberglass, while the inner layer is formed, from the surface furthest from the center of the structure towards the inside, by sheets identical to those of the outer layer, placed in reverse order.
    [22]
    22. Fixed tubular structure according to one of claims 9 to 18, in which the outer layer is made up of two sheets: an outer layer of FML with carbon fiber, and an inner one, joined to it, of FML with fiberglass, and the The inner layer is made up of two sheets identical to those of the outer layer, so that in the inner layer, the FML sheet with carbon fiber is the innermost of them.
    [23]
    23. Fixed tubular structure according to one of claims 9 to 18, in which the outer layer is formed by one or more sheets of FRP and FML, while the inner layer is formed, from the surface farthest from the center of the structure towards the inside, by sheets identical to those of the outer layer, placed in reverse order.
    [24]
    24. Fixed tubular structure according to one of claims 9 to 23, wherein the fiber sheets that make up the inner and outer layers in the fixed tubular structure are formed by fibers that are arranged in the same direction or in more than one direction with respect to the longitudinal axis of the fixed tubular structure.
    [25]
    25. Fixed tubular structure according to one of claims 9 to 24, wherein each of the fiber sheets that make up the inner and outer layers have a thickness between 0.5 mm and 3 mm.
    [26]
    26. Fixed tubular structure according to one of claims 9 to 25, wherein the bag of the intermediate layer is filled with an expandable material, preferably a foam, gas or a cementitious material.
    [27]
    27. Fixed tubular structure according to one of claims 9 to 26, further comprising a coating formed by one or more protective or decorative layers or both.
    [28]
    28. Fixed tubular structure according to one of claims 9 to 27, comprising micro-perforated FML materials.
    [29]
    29. A method for manufacturing a portable tubular structure defined in one of claims 1 to 8, comprising:
    - arrange the sheets of the outer layers,
    - arrange a double sheet that will make up the bag of the intermediate layer
    - arrange the sheets of the inner layer
    - Make the union of the sheets of the outer layer and on the other hand make the union of the sheets of the inner layer
    - join the previous layers and
    - have at least one valve in the double sheet of flexible material for the introduction of filling material,
    the stages being able to be carried out in an order other than the order in which they are mentioned, and in particular, the last two stages can be carried out in the reverse order.
    [30]
    30. A method according to claim 29 comprising:
    - arrange the sheets of the outer layers extended,
    - arrange on them the double sheet of flexible material that will make up the bag of the intermediate layer
    - arrange on the front double sheet, the sheets of the inner layer
    - make the union of all the previous sheets at their ends
    - having at least one valve in the double sheet of flexible material for the introduction of filling material.
    [31]
    31. A method according to claim 29 or 30 comprising:
    - lay out an extended plastic sheet
    - arrange on it the sheets of the outer layers
    - arrange on them the double sheet that will make up the bag of the intermediate layer - arrange on the previous double sheet, the sheets of the inner layer
    - arrange on the sheets of the inner layer a second plastic sheet
    - make the union of all the previous sheets at their ends
    - have at least one valve in the double sheet of flexible material for the introduction of filling material,
    having valves in the outer and inner layers to be able to carry out an infusion-vacuum process at the final location.
    [32]
    32. A method according to one of claims 29 to 31, wherein the sheets of each of the outer and inner layers are joined together by interlocking.
    [33]
    33. A method according to one of claims 29 to 32, in which the outer and inner layers are attached to the bag forming the intermediate layer by gluing.
    [34]
    34. A method according to claims 29 to 33, comprising:
    - make an interlock of at least two meshes or sheets, one of carbon fiber and the other of glass fiber, for the inner layer and at least two other sheets of the same materials - with an inverse distribution with respect to the inner layer - to the outer layer - glue the two sets of interlocked sheets to one side and the opposite side of the double sheet bag that will make up the middle layer bag,
    - placing at least one valve for filling in a double sheet that will make up the bag of flexible material that in turn makes up the intermediate layer
    - Sealing of a bag of flexible material of the intermediate layer, in the form of a tube, leaving the opening of the valve or valves, which serves to introduce an expansive material and control the exit of the excess material introduced.
    [35]
    35. A method according to one of claims 29 to 34, further comprising:
    - arrange the portable tubular structure, previously manufactured, at the location of the fixed hybrid tubular structure
    - insert an internal bag into the interior hole of the portable structure
    - fill the inner bag by inflation or injection
    - fill the intermediate polymeric bag with the filling material,
    - remove the inner bag
    - apply the material that binds the sheets of the external and internal layers of the tubular structure of the previous stage, obtaining the fixed tubular structure defined in claim 9.
    [36]
    36. A method according to claim 35, comprising
    - arranging the portable tubular structure, previously manufactured, comprising a plastic wrap, at the location of the fixed tubular structure
    - insert an internal bag into the internal hole of the structure
    - fill the inner bag by inflation or injection
    - fill the middle layer bag with the filling material
    - remove the inner bag
    - apply the material that binds the sheets of the external and internal layers of the tubular structure of the previous stage, by means of an infusion-vacuum process, obtaining the fixed tubular structure.
    [37]
    37. A method according to claim 36, wherein the vacuum-infusion process, which is carried out after the intermediate layer filling step, comprises:
    - having at least one valve in the outer layer and at least one valve in the inner layer of the structure through which the vacuum is drawn
    - having at least one valve in the outer layer and at least one valve in the inner layer of the structure through which the matrix material that binds the fibers is injected.
    - making a vacuum through the vacuum valves, while injecting the matrix material that binds the fibers through the material injection valves.
    [38]
    38. A method according to one of claims 35 to 37, wherein:
    the union of the outer and inner layers is carried out by connectors arranged between them, so that the connectors are placed by drilling the layers, after remove the inner bag from the structure, and before applying the material that binds the sheets of the outer and inner layers.
    [39]
    39. A method according to one of claims 35 to 37, in which the bonding of the outer and inner layers to the intermediate layer is carried out by joining their contour by means of a flexible plastic glue, in a maximum of 40% of the surface of the layers.
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    同族专利:
    公开号 | 公开日
    ES2808729B2|2021-07-07|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    NL8102255A|1981-05-08|1982-12-01|Nijverdal Ten Cate Textiel|Thin walled tube strengthened by fibre reinforced plastic - has inner layer heat set while pressurised from inside via inflatable bag|
    WO2004105457A2|2003-05-16|2004-12-09|Korea Advanced Institute Of Science And Technology|Hybrid composite journal bearing and manufacturing method thereof|
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