WO2009066027A1 - Method for mounting an end piece on a pipe in order to form a connector - Google Patents

Abstract

The invention relates to a method for mounting an end piece (12) on an end (14) of a flexible tubular pipe (16). For this purpose, the invention comprises the use of: a flexible tubular pipe (16) including an inner polymer tube (18), armouring (20) and an outer polymer sheath (22), said armouring including armouring wires; an end piece (12) including a mounting end (24) intended to be inserted into the end (14) of the pipe; and a cylindrical cover (28) for covering said pipe end (14). According to the invention, the armouring (20) is cut at the pipe end (14) in order to release the free ends (34) of the armouring wires and, subsequently, said free ends (34) are folded back against the outer polymer sheath (22) before the pipe end (14) is covered with the cylindrical cover (28).

Description

 Method of mounting a nozzle on a pipe to form a coupling

The present invention relates to a method of mounting a nozzle on a flexible tubular pipe end and also to a fitting comprising said tubular pipe end and the nozzle mounted according to the method.

The flexible tubular conduits concerned are better known by the name of "RTP" (for Reinforced Thermoplastic Pipes, in English) and they are used for terrestrial applications ("on shore" in English) for transporting hydrocarbons or water under pressure. They have the advantage of being faster to install and more resistant to corrosion than rigid steel pipes. Their inner diameter is relatively small, it is for example between 50 and 100 mm and the transported fluid is at a pressure generally between 50 and 200 bar and at a temperature that can reach 80 ⁰ C.

The structure of these pipes is relatively simple and inexpensive. They comprise from inside to outside an inner polymeric polymer tube, a reinforcement generally made of composite materials and an outer polymeric sheath. The inner polymer tube has a sealing function vis-à-vis the fluid transported by the pipe. It is usually made of high density polyethylene. The outer polymeric sheath, which is especially made of polyethylene, has the function of protecting the armature. The reinforcement has the function of taking up mechanical stresses, in particular those related to the pressure of the transported fluid. The reinforcement generally consists of at least one pair of cross plies of helically wound wires. The two superposed layers constituting each pair of plies are wound in opposite directions with helix angles substantially equal in absolute value, so as to balance the torsional structure. This helix angle is advantageously of the order of about 55 °, so as to take up both the axial forces of traction and radial forces related to fluid pressure. In most cases, the frame has only two superimposed layers, namely a pair of crossed plies of reinforcement wires wound at 55 °. When the diameter of the pipe and the operating pressure are high, it may be necessary and advantageous to add a second pair of crossed webs of reinforcing threads, so that the reinforcement then comprises four superimposed layers. The son of the reinforcing plies are for example made of aramid fibers, carbon, glass or polyester.

The document FR2828722 describes an example of "RTP" pipe in which the reinforcing wires are textile tapes reinforced with kevlar® fibers. WO2004 / 068016 shows another example in which the reinforcing threads consist of glass fibers.

The pipes concerned by the present invention are called unbonded type because their various constituent layers are substantially free to slide relative to each other when the pipe is driven in bending.

One of the disadvantages of these pipes is the cost of their connection. Indeed, to be connected these pipes are equipped at their end with a tip, and the costs of this tip added to the assembly costs are relatively large compared to the cost of raw pipes.

For example, it is described in document FR 2 754 585, a method of mounting a tip at the end of a flexible tubular conduit so as to make a connection. The tip comprises a connecting end and the opposite, a mounting end intended to be fitted into the end of said pipe. The coupling also includes a sleeve that caps the conduit end to crimp the tubular conduit end to said mounting end. To do this, the internal diameter of the mounting end is deformed and increased by force by implementing a technique called degeonnage or olivage, said technique consisting in introducing and forcibly moving a dudgeon ("tube expander "in English) within and along said mounting end, said dudgeon having an outer diameter greater than the original inner diameter of said mounting end. This operation has the effect of compressing the walls of the end of the pipe inside the sleeve. Then, in order to complete this assembly, the external diameter of the sleeve is deformed and reduced by force by implementing a drawing technique ("drawing" in English). This results in a tightening or crimping of the end of the pipe between the end of the mounting end of the nozzle and the other sleeve, said crimping ensuring the functions of mechanical joining and sealing. This solution has the disadvantage of requiring a relatively large and expensive specialized tooling to perform the swaging and drawing operations. In addition, it is necessary to provide a pipe end length held tight between the sleeve and the tip, relatively large so that, in extreme conditions the tip does not separate from the end of the pipe. As a result, the cost of the materials used to make the end piece is all the greater.

Also, a problem that arises and that aims to solve the present invention is to imagine a method of mounting a nozzle on a pipe in order to achieve a connection that is not only advantageous cost but also that can withstand in extreme conditions of use.

For this purpose, and according to a first aspect, the present invention proposes a method of mounting a tip on a flexible tubular pipe end, the method being of the type in which: a flexible tubular pipe comprising an internal polymeric tube is provided, an armature around said inner polymeric tube and an outer polymeric sheath around said armature, said armature having armor wires wrapped around said inner polymeric tube; providing a tip comprising a connecting end and a mounting end to be fitted into the end of said pipe; and, we provide a cylindrical hood adapted to come capping said conduit end to crimp said tubular conduit end to said mounting end; according to the invention, said armature is peeled off at said pipe end to release free ends of reinforcing wires; and then flipping said free ends of reinforcing wires against said outer polymeric sheath before capping said pipe end with said hood, so as to maintain said free ends of reinforcing wires between said outer polymeric sheath and said cover.

Thus, a feature of the invention lies in the method of preparation of the tubular pipe end which is free at least partially of the free ends of reinforcement son by bar turning, so as to then fold these free ends of son reinforcement at 180 ° against the outer polymeric sheath. In this way, these free ends of reinforcing wires will be wedged between the outer polymeric sheath and the cap that caps the pipe end. Therefore, will be sandwiched between the outer wall of the mounting end of the ferrule and the inner wall of the cylindrical hood, respectively, the inner polymeric tube, the armature, the outer polymeric sheath and the free ends of wires. reinforcement folded. Thus, the outer polymeric sheath and the armature in particular, which according to the prior art were not bonded together and whose relative sliding during the movements of the pipe was a cause of separation of the tip, are, thanks to the method object of the invention, held in a fixed position relative to each other at the end of the pipe through the free ends of reinforcement son folded back 180 ° against the outer polymeric sheath. Indeed, the free ends of reinforcement son open from inside the outer polymeric sheath, then they are bent against the free edge of this sheath and then applied against the outer polymeric sheath. Folded in this way, the free ends of these reinforcing wires are totally integral with the outer polymeric sheath when the pipe end is crimped between the cylindrical hood and the mounting end. of the mouthpiece. Thus, thanks to the mounting method according to the invention, the length of the mounting end of the tip and symmetrically that of the cylindrical cover, can be significantly reduced. Indeed, the axial end length of crimped tubular conduit can then be less than substantially 2.7 times the internal diameter of the pipe, for example 2.5 times, whereas according to the methods of the prior art, this length is set is greater than 2.7 and rather close to 3 to obtain the same tear resistance of the tip.

Advantageously, said free ends of reinforcement wires are folded over an axial length of said pipe end between 0.3 times and 1.5 times the internal diameter D of said flexible tubular pipe. For this, it is intended to cut the armature to release free ends of armature son of a length substantially greater than the axial end pipe length on which are folded these free ends of son, because not only a portion of son is applied against the edge of the outer sheath of polymeric outer sheath but also, these reinforcing son are inclined relative to the axis of the pipe and therefore they are applied substantially helically against the outer polymeric sheath . Thus, thanks to this free end length of reinforcing wire, the armature precisely, is integral with the outer polymeric sheath at the end of the pipe.

In addition, a cylindrical cap and a nozzle of suitable dimensions are advantageously provided for crimping said tubular pipe end to an axial length less than 2.5 times internal diameter D of said flexible tubular pipe. Thus, the tip and the cylindrical cover require for their realization, a smaller amount of material than the devices of the prior art or the crimped pipe end length is greater than 2.5 times the internal diameter of the pipe. .

According to an embodiment of the invention which is particularly advantageous, a flexible tubular pipe comprising a reinforcement consisting of two superposed layers of reinforcement threads and applied to one another is provided, an inner layer bearing on said tube internal polymeric and an outer layer against which supports said outer polymeric sheath. These two layers of reinforcing threads allow the flexible pipe to withstand the internal pressure better. Indeed, these two layers allow the pipe to better take the radial and axial forces that it then undergoes.

Therefore, advantageously décollette said armature so as to release first free ends of inner layer of reinforcing wire and, in withdrawal of the first free ends, second free ends of outer layer of reinforcing wire. Thus, as will be explained in the detailed description, the end of the pipe is provided with a length of reinforcing wire with an inner layer greater than the length of the reinforcing wires of the outer layer so as to be able to fold these first free ends facing the inner layer after folding second free ends against the outer polymeric sheath. Preferably, a thickness compensating ring is mounted around said inner layer in the extension of said outer polymeric sheath before folding said first free ends on said catch ring and, after having folded said second free ends against said outer polymeric sheath. In this way, the folded free ends of the two armor layers, extended in the extension of one another, define a single circular director cylinder centered on the pipe end. In other words, these free ends of reinforcing wires extend at a substantially equal distance from the inner polymeric tube or from the axis of the pipe.

Advantageously, said catch ring is formed with an annular portion of outer polymeric sheath and an excess thickness equivalent to the thickness of said outer layer of reinforcing threads. For example, a low compressible adhesive material is applied under the annular sheath portion to form the extra thickness.

In another aspect, the present invention relates to a flexible tubular conduit connector comprising an end-mounted tip a flexible tubular conduit, said flexible tubular conduit comprising an inner polymeric tube, an armature around said inner polymeric tube and an outer polymeric sheath around said armature, said armature having armor wires wrapped around said inner polymeric tube, said armature nozzle comprising a connecting end and a mounting end to be fitted into the end of said pipe, said coupling comprising a cylindrical cap adapted to cap said pipe end for crimping said tubular pipe end on said mounting end; according to the invention, and as will be described hereinafter, said reinforcing wires have free ends which extend outside said outer polymeric sheath; and said free ends of reinforcing wires are folded against said outer polymeric sheath, so as to be held in engagement between said outer polymeric sheath and said cover. Other features and advantages of the invention will become apparent on reading the following description of particular embodiments of the invention, given by way of indication but not limitation, with reference to the accompanying drawings in which:

- Figure 1 is a partial schematic view in axial section of a flexible pipe coupling according to the invention according to a first embodiment;

Figure 2 is a detail view of the connector illustrated in Figure 1;

- Figure 3 is a detail view of a connection according to a second embodiment; and FIG. 4 is a partial diagrammatic view in axial section of a coupling including the detail illustrated in FIG. 3.

Figure 1 shows a connector 10 comprising a nozzle 12 mounted at one end 14 of flexible tubular conduit 16. This flexible tubular conduit 16 comprises an inner polymeric tube 18 around which is wound a reinforcing layer 20 of reinforcing wire, this the same reinforcing layer 20 being covered with an outer polymeric sheath 22 of protection. The reinforcing wires are for example made of aramid, and for example Kevlar®. The tip 12 has a mounting end 24, also called arch, and opposite a connecting end 26 terminated by a fastening flange. The mounting end 24 is engaged in the inner polymeric tube 18, over a total length L of about 2.5 times the internal diameter D of the pipe or nozzle. In addition, the connector 10 comprises a cylindrical cover 28, a front end 29 is integral with the connecting end 26 of the nozzle 12 and which extends concentrically around the mounting end 24. The end 14 of tubular pipe is crimped between the cylindrical cap 28 and the mounting end 24. In this way, the tip 1 _. 2 is secured to the end 14 of flexible tubular conduit 16.

Furthermore, the inner polymeric tube 18 has a free inner edge 30 while the outer polymeric sheath 22 has it, a free outer edge 32; the two free edges 30, 32 then extending edge to edge, while the frame 20 has free ends 34 of reinforcing threads which extend beyond the in-between free edge 30, 32 and which are folded against the outer polymeric sheath 22 over an axial length L1, from the free outer edge 32, close to two-thirds of the internal diameter D of the pipe. In general, the length L1 is advantageously between 0.3 and 1.5 times the diameter D.

2, the inner polymeric tube 18 and its free inner edge 30 and the outer polymeric sheath 22 and its free outer edge 32, while the free ends 34 of the reinforcing yarns of the outer layer 32 are found in more detail in FIG. 20, are folded at 180 ° with respect to the axis A of the pipe against the outer polymeric sheath 22.

To do this, the end 14 of flexible tubular conduit 16 is prepared by décolletant the reinforcing layer 20 over a length substantially greater than the axial length L1 of outer polymeric sheath 22 against which it is intended to fold the free ends of son d frame. This armature layer 20 is not only low-cut by cutting an annular portion of outer polymeric sheath 22 but also by removing an annular portion of the inner polymeric tube 18 so that on the one hand the free edges 30, 32 of the inner polymeric tube 18 and the outer polymeric sheath 22 are substantially aligned, and that on the other hand the free ends of reinforcing son extend from the between-two free edges 30, 32 over a length substantially greater than L1. Of course, it will be ensured during this bar turning not to notch these free ends of reinforcement son.

Then, the free ends 34 of reinforcement son 20 are folded on the outer wall of the outer sheath 22 being supported against the wafer. These free ends 34 of reinforcing wires 20 can be temporarily held thus against the outer wall, during the mounting of the end piece 12, by means of an adhesive tape wound around the outer polymeric sheath 22 of the end 14 of pipe 16. Then, the mounting end 24 of the nozzle 12 is fitted inside the inner polymeric tube 18 of the pipe end 16, over a length L as shown in FIG. the end 14 in which is fitted the tip 12, is covered with the cylindrical cover 28, the front end 29 is fixed on the connecting end 26. Advantageously, the length L is between 2 times and 2.5 times the internal diameter D of the pipe 16.

Finally, it is only after that, the mounting end 24 is plastically deformed and widened radially using a mandrel according to the technique of expansion or olivage, in order to crimp the end 14 of pipe 16 in an annular space 38 between the cylindrical hood 28 and the mounting end 24 of the nozzle 12. The fitting then has a shape as shown in Figure 1, where the mounting end 24 initially projecting inside the pipe 16 is now deformed so that its diameter D is substantially equal to that of the pipe 16.

Consequently, a free portion 40 of the end 14 of line 16, consisting successively of the internal polymeric tube 18, the armature layer 20, the outer polymeric sheath 22 and the free ends 34 of the reinforcing wires 20, is compressed in the annular space 38 above.

In order to ensure the external sealing of the connector 10, the inner wall of the cylindrical cover 28 is provided with teeth not shown which engage in the outer polymeric sheath 16. In parallel, and to ensure the internal seal of the connector 10 the outer wall of the mounting end 24 is also provided with unrepresented teeth which engage in the inner polymeric tube 18. Furthermore, the inner wall of the cylindrical hood 28 is provided with anchor teeth 42 at the free ends 34 of the reinforcing wires 20 to engage in these free ends 34. Thus, thanks to the compression exerted by the mounting end 24 and the cylindrical cover 28 in the free portion 40 of the end 14 of pipe 16, and also thanks to the anchoring teeth 42, the friction forces, in particular between the reinforcing layer 20 and the outer polymeric sheath 22, are extremely important so that the tip 12 is extremely resistant to tearing. It will be noted that the free ends 34 of the reinforcing yarns 20 thus folded to form hooks, produce a capstan effect when tensile forces are exerted on the pipe 16. This capstan effect contributes to increasing the tearing resistance.

Thus, one can overcome a nozzle 12 whose length of the mounting end 24 is important, precisely to increase the frictional forces. According to another embodiment, partially illustrated on the

3, a flexible tubular pipe 50 comprises an inner polymeric tube 52, an outer polymeric sheath 54 and, in between, a double armature layer 56 consisting of an inner layer 58 of reinforcing wires and an outer layer 60 of reinforcing wire. This double armature layer 56, aims to enhance the radial and axial resistance of the flexible tubular conduit when subjected to significant pressures or voltages. Also, the preparation of an end 62 of line 50 is substantially more delicate. Firstly, the armature layer 56 is décolletée so as to release first free ends 64 of inner layer reinforcement yarns 58 and second free ends 66 of outer layer reinforcement yarns 60. This machining is performed by severing and removing on the one hand an annular portion of the inner polymeric tube 18, and on the other hand an annular portion of outer polymeric sheath 22, the outer sheath length removed being greater than the inner tube length removed, such that after cutting the free edge 70 of the outer sheath 54 is set back from the free edge 68 of the inner tube 52, and that these two free edges 70, 68 are separated by an axial distance substantially equal to a predefined length L2 . In addition, after free cutting, the free ends of the armature son which then extend axially beyond the free inner edge 68 of the inner tube 52, are set to length so that on the one hand, the first free ends 64 of reinforcing wires extend beyond the free inner edge 68 and extend beyond it by an axial length substantially equal to L 2, and that secondly the free ends 66 extend beyond the outer edge free 70 of the outer sheath 54 and exceed it by an axial length substantially equal to a length L3 predefined. The lengths L2 and L3 determine the respective flap lengths of the first and second free ends of reinforcing wires. In practice, the ratio between the two lengths L2 and L3 is advantageously between 0.5 and 2. Preferably, the two lengths are substantially equal. In addition, each of the two lengths L2 and L3 is advantageously between 0.3 and 1.5 times the internal diameter D of the pipe. In addition, the sum L2 + L3 is advantageously less than 2.5 times the internal diameter D of the pipe. In this way, the second free ends 66 of reinforcing wires are then folded against the outer polymeric sheath 54 over a length L3, in a manner substantially identical to the mode of implementation. Previous work illustrated in Figure 2. However, with respect to the first free ends 64 of reinforcing son, they are folded on a catch ring 72 consists of an annular portion 74 of outer polymeric sheath 54, itself mounted on an excess of adhesive tape 76 whose thickness is close to that of the outer layer of armature 60. The width of this catch ring 72 is substantially equivalent to the flap length L2. Thus, thanks to the catch ring 72, the free ends 64, 66 define a single cylinder C circular director. In this way, and as will be explained below with reference to FIG. 4, the pressure exerted by the internal wall of a cylindrical hood will be equivalent on the two free ends 64, 66.

We find in Figure 4, elements identical to those shown in Figure 1, too, they will be identified by an identical reference assigned a prime sign: "'". There is thus a tip 12 'having a mounting end 24', and the opposite, a connecting end 26 '. The mounting end 24 'is engaged in the inner polymeric tube 52, over a total length of about 2.5 times the inner diameter D' of the pipe or tip. The tip 12 'is capped with a cylindrical cap 28' whose front end 29 'is integral with the connecting end 26' and which extends concentrically around the mounting end 24 '.

Furthermore, a recess 78 with a thickness substantially smaller than the thickness of the reinforcing layer is provided in the inner wall of the cylindrical cover 28 ', so that the radial forces exerted by the inner wall of the hood cylindrical 28 apply with the same pressure against the free ends 64, 66 of the reinforcing threads 58,

60 and against the outer surface of the outer polymeric sheath 54.

As shown in FIG. 4, the mounting end 24 'of the nozzle 12' is then deformed and enlarged by expansion or greasing in the same way as in the previous embodiment, in order to crimp the end 62 of the pipe 50 between the cylindrical hood 28 'and the end mounting 24 '. In this way, the tip 12 'is integral with the end 62 of flexible tubular conduit 50.

The mechanical properties and compression forces exerted on the various layers and sheaths of the pipe according to this second embodiment are similar to those resulting from the assembly according to the first embodiment illustrated in FIGS. 1 and 2.

This results in improved tear resistance characteristics of the tip 12 'and this, for a pipe equipped with two reinforcing layers, which reduces the size of the end caps and therefore their cost of implementation .

Claims

A method of mounting a tip (12, 12 ') on one end (14, 62) of flexible tubular conduit (16, 50), the method being of the type in which:

a flexible tubular conduit (16, 50) is provided comprising an inner polymeric tube (18, 52), an armature (20, 56) around said inner polymeric tube and an outer polymeric sleeve (22, 54) around said armature, said frame having reinforcing wires wrapped around said inner polymeric tube;

- providing a tip (12, 12 ') comprising a connecting end (26, 26') and a mounting end (24, 24 ') to be fitted into the end (14, 62) of said pipe; and,

providing a cylindrical hood (28, 28 ') adapted to cap said pipe end (14, 62) for crimping said tubular pipe end on said mounting end (24, 24'); characterized in that it further comprises the following steps:

said armature (20, 56) is cut off at said pipe end (14, 62) to release free ends (34, 64, 66) of reinforcing wires, said outer polymeric sheath (22) having a free outer edge; (32);

said free ends (34, 64, 66) of reinforcing wires are bent against said free outer edge (32) of said outer polymeric sheath (22); and, said free ends (34, 64, 66) of reinforcing threads are folded against said outer polymeric sheath (22, 54) before capping said pipe end (14, 62) with said cylindrical hood (28, 28). '), so as to maintain said free ends (34, 64, 66) of reinforcing wires between said outer polymeric sheath (22, 54) and said cylindrical hood (28, 28').

2. Mounting method according to claim 1, characterized in that flap said free ends (34, 64, 66) of reinforcement son on an axial length (1-1, L2, L3) of said pipe end of between 0.3 times and 1.5 times the inner diameter D of said flexible tubular pipe (16, 50).

3. A method of assembly according to claim 1 or 2, characterized in that provides a cylindrical cover (28, 28 ') and a tip (12, 12') of dimensions adapted to crimp said end (14, 62) of tubular pipe over an axial length less than 2.5 times the internal diameter D of said flexible tubular pipe (16, 50).

4. A method of assembly according to any one of claims 1 to 3, characterized in that provides a flexible tubular conduit comprising a frame (56) consisting of two superposed layers (58, 60) of reinforcing wire, a an inner layer (58) bearing on said inner polymeric tube (52) and an outer layer (60) against which said outer polymeric sheath (54) bears.

5. A method of assembly according to claim 4, characterized in that said armature (56) décollette so as to release first free ends (64) of inner layer reinforcement son (58) and second free ends ( 66) of outer layer reinforcement yarns (60).

6. Mounting method according to claim 5, characterized in that mounting a thickening ring (72) around said inner layer (58) in Me extension of said outer polymeric sheath (54) to fold down said first free ends (64) on said catch ring (72) after folding said second free ends (66) against said outer polymeric sheath (54).

7. Mounting method according to claim 6, characterized in that said catch ring (72) is formed with an outer polymeric sheath portion and an excess thickness (76) equivalent to the thickness of said outer layer (60) of reinforcement wires.

8. Fitting (10) flexible tubular conduit comprising a tip (12, 12 ') mounted at the end (14, 62) of a flexible tubular conduit (16, 50), said flexible tubular conduit comprising an inner polymeric tube (18, 52), an armature (20, 56) around said tube an inner polymeric sheath and an outer polymeric sheath (22,54) around said armature, said armature having armor wires wrapped around said inner polymeric tube, said ferrule including a connecting end (26,26 ') and a mounting end (24, 24 ') intended to be fitted into the end of said pipe, said coupling (10) further comprising a cylindrical hood (28, 28') adapted to cap said end (14, 62) of pipe for crimping said tubular pipe end on said mounting end; characterized in that said reinforcing wires have free ends (34, 64, 66) which extend outside said outer polymeric sheath (22, 54); and in that said free ends (34, 64, 66) of reinforcing wires are folded against said outer polymeric sheath (22, 54), so as to be held in engagement between said outer polymeric sheath and said cylindrical hood (28, 54). , 28 ').