FR2876362A1 - Reservoir for storing e.g. liquid material, has dense reticulation of synthetic fibers applied on outer surface of cover and formed of intersection of circumferential reinforcement web and longitudinal reinforcement web - Google Patents

Abstract

The reservoir (13) has a flexible and water tight cover (1) comprising a flat base perpendicular to a central axis of the reservoir. A dense reticulation of synthetic fibers is applied on an outer surface of the cover. The reticulation is formed of an intersection of a circumferential reinforcement web (2) and a longitudinal reinforcement web (3). The web (3) is placed, in equidistant or quasi equidistant manner, parallel to the cover.

Description

The present invention relates to an assembly device for pressurizing

  flexible envelopes, especially in the context of reservoirs for storing various materials.

  When a tank is constructed of flexible material, technical textile or high strength film, current assemblies with adhesives or welds do not allow to hold significant pressure, that is to say, hardly greater than 100 millibars. The low operating pressures of these reservoirs imply that a large volume envelope which stores solid or liquid elements will necessarily have to spread over a large area. In terms of storing gaseous matter, it will take a volume almost equivalent to the quantity stored.

  The device according to the invention overcomes this disadvantage. Indeed, to allow to hold significant pressure, the envelope is reinforced with non-elastic fibers, resistant, lightweight and flexible. These fibers constitute a mesh around the envelope that will take up most of the efforts and constraints. Thus, the sealing and resistance properties are dissociated; the first being provided by the envelope and the second by the external mesh. The pressure that can be assumed by the structure thus created makes it possible to make flexible tanks higher, therefore less bulky, for storing liquids and solids, and less bulky for storing the gas.

  According to particular embodiments: The reservoir may have a symmetrical shape around a central axis.

  - The tank may have a flat base.

  - The tank can be waterproof and made of flexible materials and foldable technical textiles.

  The reservoir may have a cone-shaped or quasi-conical part and / or a spheroidal or quasi-spheroidal part, and / or a straight cylinder part, and / or a toric or quasi-toric portion, or be a conjunction of these different shapes or parts of shapes.

- The tank can be closed.

  - The tank can be opened and its open part can be attached sealingly, chemically or mechanically, to a solid construction that has the same shape, instead of the junction, the open edge of the tank.

  - The shell of the tank can be covered with a dense mesh of resistant fibers allowing it to resist the internal overpressure and to keep a fixed volume.

  - The outer dense mesh can be achieved by crossing a network of circumferential and longitudinal reinforcements.

  The circumferential reinforcements may be arranged at more or less regular intervals along the entire length of the envelope.

  - The circumferential reinforcement may consist of a fiber or a rope around the envelope and having a loop at each end.

  - The circumferential reinforcement can extend on the outer surface of the envelope by describing parts of circle, circles, or following a helical progression.

  - The terminations of the circumferential reinforcements may be loops or loose splices, or fixed by sewing or any other attachment transverse to the splice; attached with a sleeve; either by a seam binding the souls placed side by side; either by a node.

  The termination loop of a circumferential reinforcement may be connected to its own start loop in the case of a circle progression.

  - The termination loop of a circumferential reinforcement can be connected to the loop of another circumferential reinforcement in the case of a helical progression or a progression in part of a circle.

  - The connection of the ends of the circumferential reinforcements can be achieved by a fastening system or directly by loop loop assembly. - 3

  - The fastening system may consist of two longitudinal cable-type connecting cords each passing through the circumferential reinforcing loops which are aligned on a meridian of the reservoir, and can be held side by side by one or more connecting pieces.

  - A longitudinal network made of cables, straps, ropes or fibers can be deployed to hold the circumferential reinforcements equidistant or quasi-equidistant on the outer surface of the casing and to take the longitudinal forces due to pressure.

  - One or more devices can be set up on the longitudinal network to calibrate the gap between the circumferential reinforcements.

  - A pole link piece can be used to bind and fix the converging endings of the longitudinal part of the network.

  - A connecting element, a cable, a strap or a rope located on the intersection of a base and the lateral surface of the reservoir can be used to bind and fix the non-converging terminations of the longitudinal part of the network.

  - Fastening elements of the ends of the longitudinal network can be fixed to a solid construction when the tank is open and attached to said construction.

  - A material can bind the two opposite poles of the tank if the central axis of symmetry is straight.

  The accompanying drawings illustrate the invention: Figure la shows cutaway, the device of the invention when the tank describes the shape of a cone of revolution.

  Figure lb shows cutaway, the device of the invention when the reservoir is spheroidal shape.

  Figure 1c shows cutaway, the device of the invention when the tank describes the shape of a straight cylinder.

  Figure 1d shows cutaway, the device of the invention when the reservoir is of toric shape.

  Figure 2a shows schematically and in condensed, a circular deployment of circumferential reinforcements around the envelope.

  Figure 2b shows schematically and in condensed, a helical deployment of circumferential reinforcements around the envelope.

  FIG. 3 represents schematically and in part a possible fastening system for the loops of the network of circumferential reinforcements, making it possible to close said network. Figure 4 shows in part, the dense mesh of resistant fibers allowing the envelope to withstand the pressure.

  Figure 5 shows on a spheroid tank part, a polar variant of the tank and its dense mesh allowing the envelope to withstand the pressure. Figure 6 shows schematically and partially cutaway, an example of a pole piece on a portion of spheroidal reservoir, where converges the longitudinal network of the external mesh.

  Figure 7 shows schematic cutaway, the attachment of an open reservoir to a solid construction which has, instead of the junction, the same shape as the open edge of the tank.

  Figure 8 shows in schematic and condensed section, the detail of the attachment of an open tank to a solid construction.

  With reference to these drawings, the invention is a reservoir (13) comprising a tight and flexible envelope (1) made of technical textile with plastic materials and comprising a grid or an internal weave. The shape of the envelope (1) is symmetrical around a central axis; it can thus be in cone of revolution, in quasi cone of revolution, spheroid, quasi-spheroid, in right cylinder, toric or a conjunction of these different forms or parts of forms. This flexible envelope (1) assembled by adhesive, by sealed stitching or by welding determines by its shape the storage volume of the tank (13). The envelope (1) serves to contain various materials whether in gaseous, liquid or solid state. In the case where the stored materials are liquid or solid and the tank (13) is placed on the ground, the envelope (1) has at least one flat bottom perpendicular to the central axis of the tank (13). The tank (13) can be closed or open. If the reservoir (13) is open, the open part of the envelope (1) can be attached with a waterproof system (15) to a solid construction (14) of metal, concrete, plastic, etc. which has the same shape, instead of the junction, as the open edge of the tank (13). The sealed system (15) can be made chemically or mechanically according to the structure and material of the solid construction (14), for example using adhesives or using parts having seals, which press the envelope (1) against solid construction (14). If the envelope (1) is in cone of revolution, spheroid, in right cylinder or a combination of these different forms, it is possible to install a connecting material (4) in place of the central axis to bind the two opposite poles of the tank (13), and if necessary attaching this connecting material (4) to the inner face of a pole piece (5) while sealing this assembly.

  A dense mesh of synthetic fibers is applied to the outer surface of the envelope (1). This mesh is a cross of a network of circumferential reinforcements (2) and a network of longitudinal reinforcements (3).

  The circumferential reinforcements (2) describe a circular or quasi-circular turn of the envelope (1) and apply more or less regularly to the nearest contact of its outer surface. The circumferential reinforcements (2) are assembled on the envelope (1) so that the envelope (1), once pressurized by its contents, naturally and without elastic forces rests on the circumferential reinforcements (2) and their transmits the stresses due to the linear tension. The space between the circumferential reinforcements (2) is a function of the operating pressure of the reservoir (13). The greater the pressure, the more the circumferential network (2) will be dense and close together; and vice versa. A circumferential reinforcement (2) is a braided fiber or rope having a loop (9) at each of its two ends. The circumferential reinforcements (2) may surround the envelope (1) in parallel planes (FIG 2a) or in a helical progression (FIG 2b). If the circumferential reinforcements (2) extend in parallel planes (FIG 2a) and realize a complete revolution of the envelope (1), the circumferential network is closed by assembling together the loops (9) of each of the ends of the circumferential reinforcements (2). If the circumferential reinforcements (2) extend in helical planes (FIG 2b) or do not perform a complete revolution of the envelope (1), the circumferential network is closed if necessary by assembling the loops (9) of the ends of each reinforcement (2) with the loops (9) of the other circumferential reinforcements (2) which follow. In the case of a helical deployment (FIG 2b) circumferential reinforcements (2), the loops (9) which terminate the circumferential network at the top and bottom and which are not attached to another circumferential reinforcement (2) are attached to a pole piece (5), to a connecting element (6) of the longitudinal network or to the longitudinal network (3). To close, with the loops (9) of termination, the network of circumferential reinforcements (2), any connecting means such as nodes, padlocks, etc. can be used. It is also possible to pass a cable (7) in a row of loops (9) aligned on a meridian of the tank (13), to perform the same operation with the loops (9) of the meridian row opposite, and then bonding the cables (7) by passing them into small sleeve-type connecting pieces (8) installed in the gap between the circumferential reinforcing loops (2).

  The longitudinal reinforcement network (3) is composed of several connecting elements, distributed around the envelope (1) on the meridian planes in the case of a tank (13) in cone of revolution, spheroid and / or cylinder law; and on parallel planes in the case of a tank (13) ring. The longitudinal reinforcements (3) are spaced equidistantly or quasi-equidistantly around the surface of the casing (1). The longitudinal reinforcements (3) are made of flexible materials of strap type. It is also possible to (3) achieve with cables, ropes or fibers as the materials used allow the tank (13) to be flexible and foldable. The longitudinal network (3) will allow to take up the longitudinal forces due to the voltage of the reservoir (13) and it will allow to fix the spacing of the circumferential network (2). Thus, each longitudinal reinforcement (3) is provided with a device (10) to ensure the spacing of the circumferential network (2). In the case where the longitudinal reinforcement (3) is a strap, this device will be realized by fixing another strap, on the outer surface, by seams (10) spaced apart. The interval between seams (10) then makes it possible to pass the circumferential network (2) and to block its possible longitudinal movements (FIG 4). This spacing device can be made by any other fastening means for intersecting the circumferential (2) and longitudinal (3) as long as the mesh retains a flexibility making the reservoir (13) collapsible. In the case of a reservoir (13) cone of revolution, spheroid and / or straight cylinder, the longitudinal network (3) is finished. When (3) converges towards a point represented by a pole (reservoir (13) spheroid) or a vertex (tank (13) cone of revolution), the longitudinal network (3) is connected to a piece of polar link (5) rigid by fixing means (11,12) for fixing the end of each longitudinal reinforcement (3) to said pole piece (5). A means for fixing the end of a longitudinal reinforcement (3) is to provide a loop (12) which passes through a peripheral projection (11) of the pole piece (5). The pole piece (5) is disposed above a pole or a vertex of the casing (1). When the longitudinal reinforcing network (3) is not convergent and ends at a circular stop formed by the intersection of a base and the side surface of the tank (13), it is attached to a cable or rope circular (6) extending along said stop. A possible attachment means is to pass this circular cable (6) in the loops (12) of the ends of the longitudinal reinforcements (3). When the reservoir (13) is open and its open portion is sealingly attached to a solid construction (14), the longitudinal network (3) is fixed to the solid construction (14) by means of fixing means (11) attached to said portion (14). The fixing can be achieved in this case by passing the loop (12) of the end of a longitudinal reinforcement (3) in the projection of a peripheral piece (11) fixed on the solid construction (14). In the case of a tank (13) ring, the longitudinal network (3) is endless; it extends on the surface of the casing (1) forming complete circles, closed by stitching, by loops (12) bonded, or any other connecting means of its ends.

Claims (9)

- 9 CLAIMS   1) Tank characterized by: E A flexible envelope (1), waterproof, technical textile, which can have at least one flat base, having a symmetrical shape around a central axis, such as a cone of revolution, a quasi-cone of revolution, a spheroid, a quasi-spheroid, a right cylinder, a torus, a quasi-torus or a conjunction of these different forms or parts of forms, and which may contain substances in the liquid, solid or gaseous state; E a dense, resistant external mesh, in flexible fibers with little or no elasticity, covering the envelope (1), and made with a cross between a network of circumferential reinforcements (2) which makes the circular or quasi-circular turn of the envelope (1) and a longitudinal reinforcement network (3) placed equidistantly or quasi-equidistantly along the meridians or parallels of the envelope (1); Means (5, 6, 11, 12) for linking and securing the convergent and non-converging terminations of the longitudinal reinforcement network (3); a closed, partially open or open volume; And means for admitting liquid, solid or gaseous materials into the envelope (1).   2) Tank according to claim 1, characterized in that the circumferential reinforcements (2) are made with braided fibers and / or woven, they (2) have a means (9) for hanging on each end and that they (2) are distributed more or less spaced apart on the surface of the envelope (1), describing around the envelope (1) parts of circles, circles or following a helical progression.   3) Tank according to claim 1 and 2, characterized in that the circumferential reinforcements (2) have their ends connected, with or without means (7, 8, 9) intermediate connection, either between them or with the ends of other circumferential reinforcements (2), or with any other element (3, 5, 6) for fixing the position of the end in the external mesh.   4) Tank according to claim 1, characterized in that the longitudinal reinforcements (3) are made with braided fibers and / or woven, they (3) have a means (12) for hanging on each end, and that they (3) have means (10) arranged along their length to pass the network of circumferential reinforcements (2), fix its (2) movements and maintain its (2) intervals.   5) Tank according to claim 1 and 4, characterized in that the network of longitudinal reinforcements (3) has its ends attached to means (5, 6, 11), these means (5, 6, 11) each constituting an element homogeneous either because they constitute the same element (5, 6) or because they are fixed more or less directly to a common element (5, 14).   6) Tank according to claim 1, 2, 3, 4 and 5, characterized in that the tank (13) can be opened and its open part can be attached to a solid construction (14), which has the same shape instead of the junction that the open edge of the reservoir (13), attaching the casing (1) sealingly to the solid construction (14) and attaching the ends of the network of longitudinal reinforcements (3), and where appropriate the ends of the network of circumferential reinforcements (2), means (11) attached or attached to the solid construction (14).   7) Tank according to claim 1, 2, 3, 4, 5, and 6, characterized in that the means (9, 12) for attaching the ends of the circumferential reinforcements (2) and longitudinal reinforcements (3) are loops (9, 12) fixed by a knot, by a splice, by a seam, and / or by means of a rigid element for fixing the buckle.   8) Tank according to claim 1, 2, 3 and 7 characterized in that an intermediate device (7, 8, 9) connects the ends in loops (9) circumferential reinforcements (2), by passing a cable (7) in a row of loops (9) aligned on a meridian of the tank (13), performing the same operation with the loops (9) of the meridian row opposite and holding the cables (7) a dimensions using connecting pieces (8) installed in the gap between the circumferential reinforcements (2).   9) Tank according to claim 1 and 6, characterized in that the means (15) for reattaching the casing (1) in a sealed manner to a solid construction (14) uses chemical adhesives, bonding joints and / or solid parts that will press the envelope (1) on the solid construction (14).   10) tank according to claim 1 and 6, characterized in that a connecting material (4) can connect the two opposite points located at the intersection of the reservoir (13) and its central axis of symmetry, when the latter axis is right.