FR2735511A1 - MULTI-LAYERED CABLE SHEATH, MANUFACTURING METHOD THEREOF, AND MACHINE FOR CARRYING OUT SAID METHOD - Google Patents

Abstract

A cable sheath (1) with a multilayer structure comprising at least two continuous stratified plastic layers (10a, 10b) each consisting of a helical strip (11a, 11b) with respective contiguous side edges (12a, 13a; 12b, 13b) sealed together.

Description

 The present invention relates to a cable sheath, in particular a prestressing sheath or a shroud sheath, its manufacturing process and the machine for implementing said process.

Prestressing ducts, which are intended to be embedded in concrete structures and to receive the prestressing cables of these structures, must meet several requirements:
- they must meet certain waterproof characteristics,
- they must have a high resistance to abrasion and stresses
mechanical,
- they must have a minimum wall thickness to avoid being drilled
when tensioning the cables,
- they must ensure low friction when tensioning the cables,
- they must allow the transfer of the prestressing forces to the structure by
through the hardened cement slurry, injected after installation
tension, with a relief on their outer surface.

 It is known to produce prestressing sheaths in metal, in particular in steel.

A simple technique consists of winding a metal strip helically, stapling the edges of the adjacent strip after winding. This technique has the advantage of producing a sheath which may have a spiral rib on its outer surface making it possible to fix sheath fittings by simple screwing at the ends of said sheaths. However, these metal sheaths have the disadvantage of rusting easily, which can cause local deterioration and therefore loss of tightness and / or solidity. To overcome this drawback, it is possible to coat the metal strip with a protective layer, which however considerably increases the manufacturing cost.

 Another solution to overcome this drawback is to produce plastic sheaths. However, due to the minimum sheath wall thickness required (about 2 millimeters) and the shape memory of the appropriate plastics, in order to be able to use the manufacturing process of the metal sheaths mentioned above, it is necessary to heat the assembly of the plastic strip, wind it, weld the adjacent edges and cool the sheath quickly, which is long and involves a very high energy cost.

This manufacturing process is therefore too expensive and cannot be carried out in situ, that is to say on the site. It is therefore necessary to manufacture these plastic sheaths, for example by extrusion or molding, in complicated and expensive machines and to transport them to the site from the place of manufacture, which is also very expensive, in particular because of their bulky volume. On the other hand, transporting the sheaths prevents the production of large sheaths in straight lengths.

 Furthermore, these plastic sheaths generally have, as protruding relief, grooves on their outer surface. These corrugations do not make it possible to fix sheath fittings by screwing. To overcome this drawback, threaded portions are generally provided at the ends of the sheaths, these threaded portions generally being produced by molding. In addition to the increase in manufacturing costs, this implementation prevents the sizing on site of these sheaths to any desired length. Alternatively, special sleeves are provided, in the form of half-shells which are assembled after the installation of the sheaths. This implementation also causes an increase in manufacturing costs.

 There are machines for making plastic sheaths by extrusion having a spiral thread on their outer surface. These machines are however very complicated and very expensive and cannot be used in situ. The aforementioned drawbacks are therefore not eliminated.

 Another disadvantage of plastic sleeves is that it is difficult to find a plastic material which simultaneously fulfills all the above-mentioned requirements.

 The present invention aims to provide a cable sheath meeting the above requirements by eliminating the aforementioned drawbacks.

 The present invention therefore aims to provide an improved cable sheath which is waterproof and resistant, which has a minimum wall thickness, which has low friction inside, and which can effect the transfer of the prestressing forces to the concrete. . In particular, the present invention aims to provide an improved cable sheath which has a structure such that the above requirements are each optimally fulfilled.

 The present invention also aims to provide such an improved cable sheath, the manufacture of which is simple, rapid and economical.

 The present invention also aims to provide such an improved cable sheath which can be manufactured in situ at any desired length.

 The present invention also aims to provide such an improved cable sheath made essentially of plastic.

 The present invention therefore relates to a cable sheath comprising a multi-layer structure comprising at least two continuous superimposed layers of plastic material, each consisting of a strip arranged in a helix and the lateral edges of which are respectively joined with tight junctions.

 This multi-layer structure has many advantages. Thus, it is possible to easily vary the thickness of the wall of the sheath by modifying the number of layers, these may each have very small thicknesses, which largely eliminates the winding difficulties due to memory. shape of plastics. On the other hand, it is possible to incorporate layers of different materials, each layer having particular properties.

 The multi-layer structure can comprise more than two plastic layers. In particular, the invention provides a cable sheath made entirely of plastic.

 Preferably, said at least two plastic layers are welded to each other at at least one point, advantageously along a line, for example by thermal welding. This characteristic makes it possible to make irreversible connections between the layers and guarantees repeatability and homogeneity of the sheath.

 Preferably, the cable sheath has on its outer surface at least one continuous helical thread. The presence of the continuous helical or spiral thread allows the fitting of duct fittings by simple screwing. In addition, the fact that the thread extends continuously over the entire sheath makes it possible to cut the latter to any desired length. In addition, depending on the pitch of said spiral net, the rigidity of the sheath can be modified.

 According to one aspect of the invention, an insert, such as a metal wire, is arranged in the multi-layer structure of the sheath, in particular in at least one longitudinal rib of at least one strip. This insert can act to reinforce the rigidity of the sheath or possibly be a heating insert.

 A particularly suitable use of the sheath according to the invention is the use as a prestressing sheath.

 However, the sheath according to the invention can also be used as a shroud sheath. The advantageous presence of a continuous spiral net on the external surface of the sheath has in this case aerodynamic advantages with respect to the wind as well as rainwater which can flow more easily by being channeled, and the multilayer structure makes it possible to produce an outer layer having any practical or aesthetic characteristic desired.

The present invention further relates to a method of manufacturing a cable sheath, comprising the following steps: - supplying at least two strips of plastic material, - assembling in a helix, by superimposing them by means of a device assembly,
each of said strips, so that their respective lateral edges are joined
to form a sheath with a multi-layer structure comprising at least two layers in
plastic.

 Preferably, the method comprises the step of welding at least one point said at least two superimposed layers of plastic. Advantageously, this welding is carried out thermally along a continuous helical line, which provides improved sealing of the sheath.

 Preferably, the method comprises, before the step of assembling, of forming at least one longitudinal rib in each strip.

 The invention further relates to a machine for implementing the method comprising at least two reels for receiving strip rolls for supplying said at least two strips, and an assembly device for assembling the strip helically so their respective lateral edges are joined.

 According to a first variant of the invention, the assembly device comprises a fixed cylindrical mandrel, which may comprise at least one continuous spiral thread on its outer surface, on which a respective longitudinal rib of each strip formed is wound helically. beforehand by means of a corresponding rib forming module, the winding being advantageously carried out by means of driving rollers and / or pressers. This variant makes it possible to produce substantially circular cross-section sheaths.

 According to a second variant of the invention, the assembly device comprises two rotary cylindrical mandrels, around which the strips are wound in a helix, the assembly formed by said two rotary mandrels being itself rotary.

The winding is also advantageously carried out by means of driving rollers and / or pressers. This variant makes it possible to produce ducts of oblong cross section.

Other characteristics and advantages will appear during the following detailed description, given by way of nonlimiting example, with reference to the attached drawings, in which:
- Figure I is a schematic view in longitudinal section of the wall of a
sheath with a multi-layer structure according to the invention,
FIG. 2 represents a part of the assembly device according to the invention and
schematically illustrates the manner in which the multi-structure sheath
layer according to the invention is assembled,
- Figure 3 is a schematic view of a machine for implementing the
process for manufacturing a sheath with a multi-layer structure according to the invention,
said machine incorporating a first variant of the assembly device, and
- Figure 4 is a view similar to Figure 3, the machine incorporating a
second variant of the assembly device.

 With reference to FIG. 1, the sheath I according to the invention comprises a multilayer structure which can for example comprise three superposed layers 10a, 10b, 10c. Of course, the number of layers 10 which is at least two is not limited and the embodiment of the sheath comprising three layers as shown in the figures only represents an advantageous embodiment. The three-layer structure is advantageous when the sheath is used as a prestressing sheath because, to obtain the minimum wall thickness required, that is to say approximately 2 millimeters before the cables are tensioned, it is possible to in this case use layers of material having a standard thickness of about 0.7 millimeters. Obviously, if the cable sheath according to the invention is not intended to be used as a prestressing sheath, the thickness of the wall may be lower or higher, and the number of layers may therefore be different.

 According to one aspect of the invention, the sheath with a multi-layer structure comprises at least one layer of plastic material. Preferably, said sheath comprises at least two layers of superimposed plastic material, which makes it possible to bind them intimately together as will be explained later on in the description of the process for manufacturing the sheath.

 The detailed description of the invention which will be made with reference to the drawings relates more particularly to a sheath with a multi-layer structure comprising three layers 10a, 10b, 10c made of plastic, but it is clear that the sheath may comprise a layer made of a other material, such as fiberglass or metal, for example.

 In fact, a particularly advantageous characteristic of the sheath with a multi-layer structure of the present invention lies in the possibility of choosing each layer in a particular material having particular intrinsic characteristics, so that each layer of the multi-layer structure fills a special function. For example, the layer 10a located inside the sheath can be made of a material which has a low friction during the tensioning of the prestressing cables, for example Teflon or graphite high density polyethylene (HDPE). The second layer 10b, that is to say the one which is directly superimposed on said first inner layer 10a, can for example be made of a material having a relatively high rigidity. The outer layer 10c can be made of a material with characteristics of good resistance to ultraviolet rays. This proves to be advantageous in particular when the sheaths are stored on a site located in a hot country. Softening and deformation of the sheath due to the sun's rays can thus be limited. This multi-layer structure also allows the cable sheath according to the invention to be suitable for other uses than that of prestressing sheath. Thus, such a sheath can be used as a shroud sheath. In this case, the characteristics required for the inner 10a and outer 10c layers of the sheath are not necessarily the same as those of a prestressing sheath, it is then possible to choose different materials for the layers constituting said sheath. a shroud sheath, the outer layer 10c can for example be made of a colored material to meet aesthetic requirements, said colored material also having good resistance to ultraviolet rays to guarantee good color fastness.

 According to the invention, each layer 10 of the sheath is continuous, that is to say that each layer of the sheath forms a closed sleeve 10, the multi-layer structure therefore being a superposition of several of these individual sleeves 10a , 10b, 10c. As can be seen in the figures, each layer 10 of the sheath is formed from a strip or strip of material 11, which is assembled in such a way that its lateral edges 12, 13 are contiguously adjacent to form said sleeve. According to a characteristic of the invention, said lateral edges 12a, 13a; 12b, 13b; 12c, 13c of each strip It has, 1 in, 11c of plastic material, which are contiguously adjacent after their assembly, are thermally welded together to form a layer of sheath of homogeneous and waterproof plastic. Preferably, these weld zones thermal 17 of the lateral edges of each plastic strip are offset from one layer to another axially along the sheath 1. This additionally ensures perfect sealing of the multi-layer structure of the sheath, these zones 17 relative weakness of sealing of the different sheath layers not being located opposite one another.

 According to an example of application of the invention, the sheath 1 has on its outer surface at least one continuous helical or spiral thread 15. This spiral thread 15 acts in particular to fulfill the above-mentioned requirement for transferring forces to concrete, after hardening cement grout. Preferably, this continuous spiral thread 15 outside the sheath is formed by one or more longitudinal ribs 14a, 14b, 14c formed in each strip 1 a, 1 lb, 1 lc constituting said multi-layer structure. Said longitudinal ribs 14a, 14b, 14c of the different strips are preferably equidistant so as to be superposed on each other during the assembly of said sheath. Thus, in the example shown in Figure 1, each strip lia, 1 lob, lic respectively constituting the layers 10a, 10b, 10c of the sheath 1 has three longitudinal ribs of identical shape which are superimposed during the spiral assembly said strips, as will be described later with reference to the process.

In this exemplary embodiment, the sheath 1 therefore has on its outer surface three continuous helical threads 15. This characteristic is particularly advantageous when the sheath has a circular cross section, because it allows the fitting of sheath fittings by simple screwing on said threads. spiral 15, at the ends of the sheath 1.

 The width of the different strips 1 la, 1 lob, lic forming the multi-layer structure as well as the number and / or the distance between the longitudinal ribs 14a, 14b, 14c formed in each of said strips i la, l lb, 1 lc can be variable, which advantageously makes it possible to modulate the rigidity of said sheath 1.

 According to another advantageous aspect of the invention, an insert 19 is arranged in the multi-layer structure of the sheath. This insert 19, which may for example be a metal wire, can serve to further strengthen the rigidity of said sheath, but it can also act as a heating insert by passing an electric current through it. In this case, said insert 19 acts to heat the sheath in the event of an extremely low temperature, thus making it possible to inject the cement slurry even in cold weather.

This insert or metal wire is advantageously disposed in one or more of said longitudinal ribs 14a, 14b, 14c of one or more of said strips 1 la, 1 lb, 1 il. In this case, it extends over the entire length of the sheath in a spiral manner.

 As mentioned above, the sheath according to the invention can have a circular cross section, but it can also have a different cross section and in particular oblong, as visible in FIG. 4. This implementation ensures, in certain applications, a better distribution of prestressing forces, especially in thin structures.

 The invention also relates to the method of manufacturing a sheath with a multi-layer structure as described above. This method essentially comprises assembling in a spiral by superimposing said strips by means of an assembly device 20. The assembly is carried out so that the respective lateral edges of each strip are joined to form continuous sheath layers . As mentioned above, at least one of said strips 1a, 1 lb, 11c is made of plastic and according to a preferred aspect of the manufacturing process, at least two of said strips 1a, 1 lob, 1 tick are made of plastic to form minus two superimposed layers of plastic in the multi-layer structure of the sheath.

 Each strip 1 la, 1 lob, 1 lc is fed from a roller or a reel 50a, 50b, 50c and advantageously enters first into a first module 40 called rib forming module, in which at least one longitudinal rib 14a, 14b, 14c is respectively formed in said strip 1a, 1 lob, 1 il. These modules 40 are adapted to form ribs 14a, 14b, 14c which are identical in the various strips constituting the multi-layer structure and advantageously include heating means making it possible to deform the material to form said ribs 1a, 1lb, lic in each respective strips. Said strips 1 la, 1 lob, lic constituting the multilayer structure are then assembled, preferably simultaneously as visible in FIGS. 3 and 4, by means of an assembly device 20. This assembly is preferably carried out by spirally winding each of said strips so that their longitudinal ribs 1a, 1b, 1c overlap. Said strips thus form the different layers 10a, 10b, 10c of the multi-layer structure of the sheath.

 According to a first variant of the invention, said assembly device 20 comprises a fixed cylindrical mandrel 21 which in this example comprises at least one continuous helical or spiral thread 22 on its outer surface. In this case, the assembly device 20 is suitable for assembling a sheath with a multi-layer structure having a substantially circular cross section. As can be seen in FIG. 2, the mandrel 21 comprises a continuous spiral thread 22 for each longitudinal rib 14a, 14b, 14c of the different strips i la, 1 lob, 1 lc. Thus in the example shown, the strips each have three longitudinal ribs as well as the mandrel. Thus, each of said longitudinal ribs 14a, 14b, 14c of each of said strips engages on a spiral thread 22 respective of the mandrel 21, during of the assembly. This assembly is advantageously done by helically winding said strips around said mandrel 21. As visible in FIG. 3, this winding is preferably carried out by means of drive rollers 25 which are advantageously arranged in an inclined manner to follow said continuous spiral threads 22 of mandrel 21 and which are rotated by a suitable device 26. These rollers 25 act in particular to guide the strips so that their longitudinal ribs 14a, 14b, 14c engage on said spiral threads 22 of the mandrel 21. Each strip 1a, ilb, llc therefore wraps around said mandrel 21 to form a layer 10a, 10b, 10c of the multi-layer structure of the sheath 1, this winding taking place in such a way that the lateral edges 12a, 13a; 12b, 13b; 12c, 13c of each strip 1 la, 1 lob, i lc are adjacent to each other in a contiguous manner after winding around said mandrel 21.

This is visible in particular in Figure 2 in which we also see that the winding of the three strips 1 la, 1 lob, 1 lc is made so that they overlap with their side edges axially offset. Preferably, after the forming of the longitudinal ribs 14a, 14b, 14c by means of the respective forming modules 40, and before the winding by means of said assembly device 20, the method advantageously provides for having a heating module 30 for each plastic strip, intended in particular for heating its lateral edges 12a, 13a; 12b, 13b; 12c, 13c. In this way, during the winding around the mandrel 21, the adjacent heated edges of each plastic strip are thermally welded together by means of said drive rollers 25 which, in this case, also act as as pressure rollers. This characteristic makes it possible to obtain with each plastic strip a tight and homogeneous plastic layer.

 Preferably, each of said heating modules 30 is further intended to locally heat so-called melting zones 18 in each strip so that, during winding, said respective heated zones 18 of two strips, which overlap during said winding , are pressed against each other by means of said pressure rollers 25, so that said superimposed layers formed by said two strips are intimately linked in these melting zones 18. This gives irreversible connections between the different layers of the multi-layer structure which guarantees perfect homogeneity of the sheath 1.

 In certain applications where the sheath is not embedded in the concrete, the spiral ribs no longer serve to ensure the transfer of the forces to the concrete. We can then dispense with it. Note, however, that these ribs participate in obtaining good rigidity of the sheath.

 In Figure 4 is shown a second variant of the assembly device 20 described above. In this variant, the assembly device 20 does not comprise a fixed mandrel, but two rotary cylindrical mandrels 23a, 23b which may each include one or more continuous spiral threads (not shown) on their outer surface. The assembly formed by said two rotary mandrels 23a and 23b is itself rotary around an axis. Thus, the strips are wound around said two mandrels 23a, 23b to form a sheath with a multi-layer structure having an oblong cross section.

 Once the various strips have been assembled to form the sheath with a multi-layer structure, the latter advantageously passes through a cooling module 60 in order to freeze the shape of said sheath 1. Since the heating modules 30 only act locally, that is to say on the lateral edges and in particular melting zones of each strip, this cooling is not essential and in any case does not need to be particularly important.

 Then, the sheath with a multi-layer structure preferably passes through a cutting module 70 in which said sheath is cut to any desired length.

The manufacturing process described above therefore has very important advantages which are: - the sheath obtained comprises a multi-layer structure, which implies advantages
previously mentioned, namely in particular that according to the characteristics
desired, the number of layers and / or the material of the strips constituting the layers
can be changed very simply.

- the machine to implement this process is simple and space-saving and not necessary
therefore a manufacturing on site, that is to say on site, of the multi-structure sheath
layer of the invention.

- the sheath obtained with this process may include one or more continuous spiral threads
on its outer surface which allows for duct connections by simple
screwing in suitable sleeves, whatever the desired length of the sheath.

- the cutting module allows the sheath obtained to be cut to any length
desired. The fact that this process can be implemented on site allows
possibly to make sheaths of great lengths which is impossible
when the ducts must be transported from the factory to the site.

- the energy costs of said process are low due to the heating at points
localized only.

- by simply replacing the fixed mandrel of the first variant of the device
assembly by a mandrel having a slightly larger outside diameter, the
machine for implementing the method of manufacturing the sheath according to the invention
also allows to realize on site said coupling sleeves which are screwed on the
ends of said sheaths to connect them.

Claims (13)

Claims  1.- Cable sheath (1) of prestressing, characterized in that it comprises a multi-layer structure comprising at least two continuous superposed layers (10a, 10b) made of plastic material, each consisting of a strip (i la, 1 lob) arranged in a helix and the lateral edges (12a, 1 3a; 12b, 13b) are respectively contiguous with tight junctions.  2.- cable sheath according to claim 1, wherein said at least two layers (10a, 10b) of plastic are welded to each other at at least one point (18).  3.- Cable sheath according to claim 1 or 2, comprising on its outer surface at least one continuous helical thread (15).  4. Cable sheath according to any one of the preceding claims, in which an insert (19), such as a metal wire, is arranged in the multi-layer structure of the sheath, in particular in at least one helical thread ( 15).  5.- A method of manufacturing a cable sheath, characterized in that it comprises the following steps:  - provide at least two strips (1 la, 1 lb) of plastic,  - to assemble in helix, by superimposing them by means of an assembly device  (20), each of said strips (11), so that its lateral edges  respective (12, 13) are joined to form a sheath (1) with a multi-structure  layer comprising at least two plastic layers.  6. The method of claim 5, wherein the step of assembling further comprises welding at least one point (18) said at least two superimposed plastic layers of the sheath.  7.- Method according to claim 6, comprising, before assembly, the step of locally heating melting zones (18) of plastic strips, the assembling step further comprising pressing the melting zones heated (18) respective plastic strips which overlap during assembly, so that said superimposed plastic layers of the sheath are welded in these melting zones.  8.- Method according to any one of claims 5 to 7, comprising, before assembly, the step of heating the lateral edges (12, 13) of each strip (it) of plastic, the step of assembling further comprising pressing said heated side edges of each plastic strip when they are adjacent, to weld them together thermally (17) to form a layer of sheath of homogeneous and waterproof plastic.  9.- Method according to any one of claims 5 to 8, comprising, before assembly, the step of forming at least one longitudinal rib (14) in each strip (11), and the step of assembling comprises wind helically the strips (11) so that the at least one longitudinal ribs (14) of each respective strip (11) overlap to form at least one continuous helical thread (15) on the outer surface of the sheath (1).  10.- Machine for implementing the method according to any one of claims 5 to 9, characterized in that it comprises at least two reels (50) for receiving strip rolls to supply said at least two strips (lia , 1 lb), and an assembly device (20) for assembling the strips in a helix so that their respective lateral edges (12a, 1 3a; 1 2b, 13b) are contiguous.  11.- Machine according to claim 1 O, wherein the assembly device (20) comprises a fixed cylindrical mandrel (21) around which are wound helically the strips (11).  12.- Machine according to claim 11, wherein the assembly device (20) comprises two rotary cylindrical mandrels (23a, 23b) around which are wound helically the strips (11), the assembly formed by said two rotary mandrels (23a, 23b) being itself rotary.  13.- Machine according to claim 11, further comprising a rib forming module (40) for each strip, intended to form at least one longitudinal rib (14) in each strip (11), before its assembly, said cylindrical mandrel fixed (21) comprising at least one continuous helical thread (22) on its outer surface, on which is wound a longitudinal rib (14) respective of each strip (11).