FR2995651A1 - Sealing assembly for tubular joint between spigot end and socket end for drain, has seal including heel, where heel is adapted to extend between external radial face and wall of groove, and heel is arranged with set of easing recesses - Google Patents

Abstract

The assembly (7) has a seal (8) that is intended to be placed in an interior groove around a spigot end. A locking element (12) is fixed on the seal, where the locking element is adapted to lock the spigot end in a socket end. The seal includes a heel (40) that is fixed on a part of an external radial face. The heel is adapted to extend between the external radial face and a wall of the groove. The heel is arranged with a set of easing recesses. The heel is arranged with a free face (42). An independent claim is also included for a tubular joint.

Description

Sealing assembly for tubular joint and corresponding tubular junction. The present invention relates to a sealing assembly for a tubular connection between a plain end and an interlocking end having an internal groove forming a groove wall, the sealing assembly comprising: - a seal intended to be arranged in a the inner groove around the spigot end, and - at least one locking element fixed to the seal and adapted to lock the spigot end in the interlocking end, the locking element having a radially outer face directed towards the wall groove in an insertion position of the spigot into the interlocking end. The invention also relates to a tubular junction provided with such a sealing assembly. The invention is particularly applicable to pipelines carrying drinking water or wastewater for sanitation. These pipes are for example ductile iron. They include pipes having a typical diameter greater than or equal to 75 mm and a length of a few meters, for example about 6 meters. In the state of the art, such tubular junctions are known. The seal, generally made of elastomeric material, is intended to prevent leakage of the fluid transported outwardly during the operation of the pipe. The locking elements are adapted to prevent dislocation, including axial separation between the spigot end and the interlocking end. The locking elements must not, however, be substantially opposed to the assembly, generally manual, of these elements.

There is a radial clearance between the spigot end and the socket end to allow assembly. Because of the manufacturing tolerances, this game varies between a given minimum game and a given maximum game. However, when the radial clearance is small, the engagement of the spigot requires greater efforts than when the radial clearance is high. However it turns out that it is difficult, especially when the pipes have large diameters, for example a nominal diameter greater than or equal to 125 mm, and more particularly when the radial clearance between the spigot end and the socket end is low. , to maintain the assembly efforts at an acceptable level allowing a manual interlocking of the spigot with a bar. An object of the invention is therefore to provide a sealing assembly for tubular junction that allows to maintain the assembly forces at a level allowing a manual interlocking with a lead bar, and whatever the radial clearance, in particularly for large pipe diameters and a small radial clearance between the spigot end and the socket end. For this purpose, the subject of the invention is a sealing assembly of the type described above, in which the seal comprises at least one heel fixed on at least a fraction of the radially outer face and adapted to extending between the radially outer face and the groove wall, said heel having one or more softening recesses. According to particular embodiments, the sealing assembly may comprise one or more of the following characteristics, taken individually or in any technically possible combination: said heel of the gasket covers the whole face radially outer; said heel comprises a free surface adapted to be in contact with the groove wall and the or the recesses comprise grooves situated on the free surface; the grooves are substantially parallel to one another; the grooves are oriented such that they are substantially directed along a longitudinal axis of the tubular junction; the grooves have a circumferential width of between 0.5 and 3 mm; said heel has an unequal thickness perpendicular to the radially outer face, and the grooves have a maximum depth greater than or equal to 50%, preferably greater than or equal to 80% of the maximum thickness of the heel; and the recesses have a volume representing between 20% and 60%, preferably approximately 30%, of the gross volume of said bead without the recesses. The invention also relates to a tubular joint comprising a spigot end, an interlocking end having an inner groove forming a groove wall, and a sealing assembly, characterized in that the sealing assembly is a sealing assembly as described above, in that the seal is disposed in the inner groove around the plain end, and in that the radially outer face is directed towards the groove wall in the end insertion position. in the interlocking end. The invention will be better understood on reading the description which follows, given solely by way of example and with reference to the appended drawings, in which: FIG. 1 is a perspective view of a tubular junction according to the invention in the unassembled state; Figure 2 is a perspective view of a portion of the seal assembly shown in Figure 1; Figure 3 is a longitudinal sectional view of a portion of the seal assembly shown in Figures 1 and 2; - Figures 4 to 6 are longitudinal sectional views of a portion of the tubular junction shown in Figure 1, showing successive steps of insertion of the spigot in the low-play interlocking end; - Figure 7 is a view similar to Figure 6, after pressurization of the tubular junction; - Figure 8 is a sectional view of a portion of the sealing assembly and the interlocking end, the section being taken along the line VIII-VIII of Figure 4, in a plane perpendicular to the radially outer face; the locking member, the overmolded heel of the packer being in an uncompressed state; and - Figure 9 is a view similar to Figure 8, the section being taken along the line IX-IX of Figure 6, the overmolded heel of the seal being in a compressed state between the interlocking end and the radially outer face of the locking element. Figure 1 shows a tubular junction according to the invention, designated by the general reference 2.

The tubular junction 2 comprises a first pipe element provided with an interlocking end 4, a second pipe element provided with a spigot end 6, and a sealing assembly 7. The tubular junction 2 defines a longitudinal axis X-X. In what follows, the terms "axially", "radially" and "circumferentially" are used with reference to this longitudinal axis X-X. The interlocking end 4 and the spigot end 6 are for example made of ductile cast iron. The interlocking end 4 and the spigot 6 are advantageously coated with a protective layer, not shown. The socket end 4 (FIGS. 1 and 4 to 7) has a free end 16 facing towards the end 6 in the unassembled state. The socket end 4 further comprises an inner annular groove 18. The inner groove 18 forms a groove wall 20 inclined relative to the longitudinal axis X-X. The groove wall 20 has a frustoconical shape and narrows towards the free end 16 of the interlocking end. The groove wall 20 forms an angle α with the longitudinal axis X-X, for example between 10 ° and 55 °.

The socket end 4 has a radially inner surface 21 which extends between the free end 16 and the groove wall 20. This surface 21 is substantially cylindrical and is defined by a radius R about the longitudinal axis X-X. The spigot end 6 has a radially outer surface 22 substantially cylindrical and defined by a radius r about the longitudinal axis X-X. According to a particular embodiment, R and r are between 100 and 200 mm, for example between 130 and 170 mm. The inner surface 21 and the outer surface 22 delimit between them a radial clearance J = R-r. The r and r rays are within a range of manufacturing tolerances. According to the manufacturing tolerances of the socket end 4 and the spigot end 6, the radial clearance J is between a maximum clearance Jmax, obtained when the radius R is maximum and the radius r is minimal, and a minimum clearance Jmin, obtained when the radius R is minimal and the radius r is maximum. Most commonly however, the radial clearance J between the spigot end 6 and the interlocking end 4 is a mean clearance, located between the maximum clearance Jmax and the minimum clearance Jmin. However, for the tubular junction described in Figures 4 to 9, the clearance J between the socket end 4 and the spigot 6 is low and close to the minimum clearance Jmin, because it is in this configuration that the assembly is the more difficult. The sealing assembly 7 (FIG. 2) comprises a seal 8 extending circumferentially around the longitudinal axis XX, the anti-extrusion elements of the seal 10 fixed on the seal 8, and sealing elements. 12 as shown in Figures 4 to 7, the seal assembly 7 is inserted into the inner groove 18 of the interlocking end 4. The seal 8 is arranged axially on the side opposite the free end 16, while the locking elements 12 and the anti-extrusion elements 10 are arranged axially on the side of the free end 16. The seal 8 is for example made of rubber or elastomeric material. It comprises a base body 24 in contact with the socket end 4, and a sealing lip 26 in contact with the spigot end 6 and oriented towards the free end thereof in the nested position.

Each locking element 12 is for example made of a material having a hardness greater than that of the spigot end 6, for example steel. The locking element 12 (Figure 2) covers a radial angular range around the longitudinal axis X-X preferably between 5 ° and 15 °. In the embodiment shown, fourteen locking elements 12 are distributed around the longitudinal axis X-X, each of which covers an angular range of approximately 10 °.

The anti-extrusion elements 10 are here seven in number. Each anti-extrusion element 10 is separated from the adjacent anti-extrusion element 10 in the circumferential direction by two consecutive locking elements 12. Referring to Figures 2-7, the generating section of the locking member 12 is substantially triangular. The locking element 12 comprises a frustoconical radially outer face 28 which converges towards the outside of the interlocking end 4, a radially inner face 30, and a connecting face 32 facing towards the base body 24 of the seal 8.

The connecting face 32 extends, in the unstressed state of the liner 8, substantially radially. The connecting face 32 partially ensures the attachment of the locking element 12 to the seal 8. The locking element 12 is fixed on the seal 8, for example by overmolding the elastomer of the the seal on the connecting face 32 of the insert previously coated with a bonding agent.

In the nested position illustrated in FIG. 7, which corresponds to a radial clearance J close to the minimum clearance J ,,, between the ends 4 and 6, the radially outer face 28 is inclined at an angle 13 relative to the axis longitudinal XX substantially identical to the inclination angle a of the groove wall 20. The locking element 12 further comprises, at the junction between the inner face 30 and the connecting face 32, a tooth of main attachment 36 adapted to bite into the outer surface 22 of the spigot end 6 when it is subjected to a disengagement force. Opposite the radially outer face 28 of each locking element 12, the gasket 8 further comprises, integrally formed, a bead 40 (FIGS. 2, 3, 4, 8 and 9) for example molded on the face radially. 28. The elastomer bead 40 advantageously has a thickness that decreases progressively towards the end opposite the base body 24, this thickness thus passing for example from 2 mm facing the connecting face 32 to about 0 2 mm opposite the end of the locking element situated opposite the connecting face 32.

The heel 40 comprises a free surface 42 intended to be in contact with the groove wall 20, in particular during the assembly with weak radial clearance and during the pressurization of the pipe. The heel 40 has outer recesses 44, forming three grooves 44A, 44B and 44C substantially oriented along the longitudinal axis X-X, and therefore substantially parallel to each other. The grooves 44A, 44B and 44C extend axially over substantially the entire bead 40. The grooves 44A, 44B and 44C have a maximum radial depth representing approximately 90% of the maximum radial thickness of the bead 40. Thus, the bead 40 comprises a radial bottom formed by the grooves 44A, 44B, 44C, so that the entire radially outer face 28 is covered by the elastomer. The grooves 44A, 44B and 44C each have a circumferential width of between 0.5 and 3 mm, for example about 1.5 mm. The grooves 44A, 44B and 44C together have a volume representing between 20% and 60% of the gross volume of the heel 40, for example 30% of the gross volume of the heel. The gross volume of the heel 40 is the volume of the wrapping of the heel 40 delimited circumferentially and axially by the locking element 12 and radially by the locking element 12 and the free surface 42 of the bead considered without the recesses 44 and the unsolicited state of the heel 40. The groove 44B is substantially equidistant from the grooves 44A and 44C. As can be seen in FIG. 2, the anti-extrusion elements 10 have a triangular cross-section substantially corresponding to that of the locking element 12. However, the section of the anti-extrusion element 10 is without the tooth main attachment 36. The anti-extrusion elements 10 are attached to the seal 8 by any appropriate means. They can in particular be fixed by gluing, overmoulding, snapping, screwing or riveting. The anti-extrusion elements 10 have an arcuate shape around the longitudinal axis X-X and extend circumferentially between two adjacent locking elements 12. Thus, the anti-extrusion elements 10 prevent, in combination with the locking elements 12, the elastomer of the seal 8 being extruded outwards through the annular space delimited by the outer surface 22 of the tip uni 6 and the inner surface 21 of the interlocking end 4 during the pressurization of the pipe elements. The anti-extrusion elements 10 are preferably made of a material harder than that of the seal 8, for example a plastic such as polyamide, polyethylene or polypropylene. The assembly of the tubular junction 2 is carried out as follows.

The sealing assembly 7, manipulable in a single block, is arranged, for example by hand, in the inner groove 18. When inserting the spigot end 6 in the interlocking end 4 with radial clearance J low , in particular with minimal radial clearance, the free surface 42 of the beads 40 is substantially in contact with the groove wall 20. The heels 40 are not first crushed between the radially outer face 28 and the groove wall 20 (FIG. 8), and this until the locking elements 12 are approached by the spigot end 6 (FIG. 4).

When crossing the locking elements 12 by the spigot (Figures 5 and 6), there is a progressive crushing of the beads 40 between the radially outer face 28 and the groove wall 20. The volume of the grooves 44A, 44B and 44C is then reduced by displacement of the elastomer of the heels 40 in the outer recesses 44 (Figure 9), which allows a further approximation of the radially outer face 28 and the groove wall 20. Such a comparison would not be possible, or would be more difficult, in the absence of the recesses 44 of the heel 40, because the elastomeric material is relatively incompressible.

The crushing of the heel 40 allows the locking elements 12 to move away from the longitudinal axis XX and reduces the insertion forces of the spigot end 6, especially when the radial clearance between the spigot end and the socket end is low. or equal to the minimum game. After insertion of the spigot end 6 into the interlocking end and before the pressurization of the pipes, a configuration is obtained (FIG. 6) in which the inner face 30 is substantially parallel to the outer surface 22 of the spigot end 6, with the main attachment tooth 36 resting on the outer surface 22 but without biting therein. In this configuration, the sealing lip 26 is compressed radially outward and the heels 40 are crushed between the radially outer face 28 and the groove wall 20 (Figure 9).

When the spigot 6 recoils under the effect of a high internal pressure during the pressurization of the pipes, the locking elements 12 move axially towards the free end 16 of the interlocking end 4 and radially towards the end. internal sliding of the heel 40 on the groove wall 20. The locking elements 12, thus cause the progressive penetration of the attachment tooth 36 of the locking element 12 in the outer surface 22 of the spigot 6 and up to 'to obtain a wedge lock. This results in the locking configuration of FIG. 7. Thanks to the characteristics described above, in particular the heel 40 intended, in the locking position, to extend between the radially outer face 28 and the groove wall 20, the heel 40 having one or more recesses 44 to give the heel 40 a greater compressibility perpendicularly to the radially outer face 28, the sealing assembly 7 makes it possible to maintain the tightness and the assembly forces of the tubular junction 2 in acceptable ranges irrespective of the radial clearance J, in particular for large pipe diameters 4, 6 and low radial clearances.

Claims (9)

REVENDICATIONS1. Sealing assembly (7) for tubular joint (2) between a plain end (6) and a socket end (4) having an inner groove (18) forming a groove wall (20), the sealing assembly comprising: - a seal (8) intended to be arranged in the inner groove (18) around the plain end (6), and - at least one locking element (12) fixed on the seal (8) ) and adapted to lock the spigot end (6) in the interlocking end (4), the locking element (12) having a radially outer face (28) facing the groove wall (20) in a position of insertion of the spigot end (6) in the interlocking end (4), characterized in that the seal (8) comprises at least one bead (40) fixed on at least a fraction of the radially outer face (28) and adapted to extend between the radially outer face (28) and the groove wall (20), said heel (40) having one or a plurality of softening recesses (44). 2. Assembly (7) according to claim 1, characterized in that said bead (40) of the seal (8) covers the entire radially outer face (28). 3. Assembly (7) according to claim 1 or 2, characterized in that said heel (40) has a free surface (42) adapted to be in contact with the groove wall (20) and the recess or recesses (44). ) comprise grooves (44A, 44B, 44C) located on the free surface (42). 4. Assembly (7) according to claim 3, characterized in that the grooves (44A, 44B, 44C) are substantially parallel to each other. 5. Assembly (7) according to claim 3 or 4, characterized in that the grooves (44A, 44B, 44C) are oriented such that they are substantially directed along a longitudinal axis (XX) of the tubular junction (2). ). 6. Assembly (7) according to any one of claims 3 to 5, characterized in that the grooves (44A, 44B, 44C) have a circumferential width of between 0.5 and 3 MM. 7. Assembly (7) according to any one of claims 3 to 6, characterized in that, said heel (40) having an unequal thickness perpendicular to the radially outer face (28), the grooves (44A, 44B, 44C) have a maximum depth greater than or equal to 50%, preferably greater than or equal to 80% of the maximum thickness of the heel. 8. Assembly (7) according to any one of claims 1 to 7, characterized in that the recesses (44) have a volume representing between 20% and 60%, preferably about 30%, of the gross volume of said heel (40) considered without the recesses (44). Tubular joint (2) comprising a plain end (6), an interlocking end (4) having an inner groove (18) forming a groove wall (20), and a sealing assembly, characterized in that seal assembly is a seal assembly according to any of the preceding claims, in that the seal (8) is disposed in the inner groove (18) around the plain end (6), and the radially outer face (28) is directed towards the groove wall (20) in the insertion position of the spigot end (6) in the interlocking end (4).