COUPLING FOR FORMING A SEALED JOINT BETWEEN FIRST AND SECOND TUBULAR MEMBERS

Abstract

The invention concerns a coupling for use in forming a sealed joint between first and second tubular members. The coupling provides a through-passage defined by an inner coupling face and having a first open end for insertion of the first tubular member into a first region of the through-passage and a second open end for insertion of the second tubular member into a second region of the through-passage. A first inwardly directed engagement recess is provided in the inner coupling face in the first region of the through-passage and a second inwardly directed engagement recess is provided in the inner coupling face in the second region of the passage. In the assembled joint, the first inwardly directed engagement recess aligns with a first outwardly directed engagement recess of the first tubular member to form a first channel for receipt of a first retainer to secure the first tubular member in the coupling. The second inwardly directed recess aligns with a second outwardly directed engagement recess of the second tubular member to form a second channel for receipt of a second retainer to secure the second tubular member in the coupling. The first region of the through-passage has a larger diameter than the second region of the through-passage.

Claims

1. A coupling (10) for use in forming a sealed joint between first (36) and second (34) tubular members, the coupling (10) providing a through-passage (16) defined by an inner coupling face (24) and having: a first open end (12) for insertion of the first tubular member (36) into a first region (18) of the through-passage (16) the first open end (12) having a first inwardly directed engagement recess (26), which is provided in the inner coupling face (24) in the first region (18) of the through-passage (16), the first inwardly directed engagement recess (26) being alignable, in use, with a first outwardly directed engagement recess (40) of the first tubular member (36) to form a first channel for receipt of a first retainer (52) to secure the first tubular member (36) in the coupling (10); and a second open end (14) for insertion of the second tubular member (34) into a second region (20) of the through-passage, the second open end (14) having a second inwardly directed engagement recess (32), which is provided in the inner coupling face (24) in the second region (20) of the through-passage (16), the second inwardly directed recess (32) being alignable, in use, with a second outwardly directed engagement recess (42) of the second tubular member (34) to form a second channel for receipt of a second retainer (62) to secure the second tubular member (34) in the coupling (10), the coupling being characterised by: the first region (18) of the through-passage (16) having a larger diameter than the second region (20) of the through-passage (16).

2. The coupling (10) of claim 1 in which the inner coupling face (24) comprises a first seal recess (28) in the first region (18) of the through-passage (16).

3. The coupling (10) of claim 2 in which the first inwardly directed engagement recess (26) is located between the first open end (12) and the first seal recess (28).

4. The coupling (10) of claim 2, wherein the first seal recess (28) is a circumferential recess and the coupling (10) further comprises a first seal (30) received in the first seal recess (28) and arranged to seal against an outer face of the first tubular member (36), in use.

5. The coupling (10) of claim 4, wherein the first seal (30) has an internal diameter, which is larger than an external diameter of the second tubular member (34).

6. The coupling (10) of claim 5, wherein the larger internal diameter of the first seal (30) being larger than the external diameter of the second tubular member (34) permits the coupling (10) to be axially displaced relative to the first (36) and/or second (34) tubular members with a clearance between the first seal (30) and the second outwardly directed engagement recess (42) of the second tubular member (34).

7. The coupling (10) of claim 6, wherein during said relative axial displacement, the first seal (30) is not caused to roll out of its recess (28) by interference between the second tubular member (34) and the first seal (30).

8. The coupling (10) of claim 6, wherein during said relative axial displacement, the first seal (30) is not caused to roll out of its recess (28) by interference between the second outwardly directed engagement recess (42) of the second tubular member (34) and the first seal (30).

9. The coupling (10) of any preceding claim further comprising a first insertion channel (56) leading from an outer surface of the coupling (10) to the first inwardly directed engagement recess (26), to enable the first retainer (52) to be inserted into the first channel in use, and a second insertion channel (64) leading from an outer surface of the coupling (10) to the second inwardly directed engagement recess (32), to enable the second retainer (62) to be inserted into the second channel, in use.

10. A joint comprising a coupling (10) as claimed in any preceding claim, a first tubular member (36) received in the first region (18) of the coupling (10) and a second tubular member (34) received in the second region (20) of the coupling (10), wherein the first tubular member (36) has a larger outer diameter than the second tubular member (34).

11. The joint of claim 10, wherein the second tubular member (34) has an outwardly directed seal recess (44) carrying a second seal (46) which is arranged to seal against the inner coupling face (24).

12. The joint of claim 11, wherein the second inwardly directed engagement recess (32) is located between the outwardly directed seal recess (44) and the second end (14) of the coupling (10).

13. The joint of claim 11, wherein the second seal (46) has an outer diameter, which is smaller than an internal diameter of the first region (18).

14. The joint of claim 13, wherein the outer diameter of the second seal (46) being smaller than the internal diameter of the first region (18) permits the coupling (10) to be axially displaced relative to the first (36) and/or second (34) tubular members with a clearance between the second seal (46) and the first inwardly directed engagement recess (26) of the coupling (10).

15. The joint of claim 14, wherein during said relative axial displacement, the second seal (46) is not caused to roll out of its recess (44) by interference between the coupling (10) and the second seal (46).

16. The joint of claim 14, wherein during said relative axial displacement, the second seal (46) is not caused to roll out of its recess (44) by interference between the first inwardly directed engagement recess (26) of the coupling (10) and the second seal (46).

17. The joint of claim 10, wherein one of the first (36) and second (34) tubular members is a spigot attached to an accessory.

18. The joint of claim 10, wherein the first inwardly directed engagement recess (32) of the coupling (10) aligns with the first outwardly directed recess of the first tubular member (36) to form the first channel, and the first retainer (52) is received in the first channel to secure the first tubular member (36) in the coupling (10), and in which the second inwardly directed recess of the coupling (10) aligns with the second outwardly directed recess of the second tubular member (34) to form the second channel, and the second retainer (62) is received in the second channel to secure the second tubular member (34) in the coupling (10).

19. A method of disassembling a joint as claimed in claim 18, comprising withdrawing the first retainer (52), withdrawing the second retainer (62), sliding the coupling (10) toward the second tubular member (34) causing the coupling (10) to disengage from the first tubular member (36), and moving one of the first (36) and second (34) tubular members laterally relative to the other.

Description

[0030] Other aspects of the invention may provide coupling substantially as herein described with reference to, and as illustrated in, the accompanying drawings and/or a joint substantially as herein described with reference to, and as illustrated in the accompanying drawings.

[0031] Specific embodiments of the present invention will now be described, by way of example only, with reference to the accompanying drawings, in which:

[0032] FIG. 1 is a section in an axial plane through a coupling embodying the present invention;

[0033] FIG. 2 is a section through the same coupling in a radial plane;

[0034] FIG. 3 is a section in an axial plane through a disassembled pipe joint embodying the present invention, pipe components of the joint being misaligned from one another;

[0035] FIG. 4 is similar to FIG. 3 but shows the pipe components in alignment before the coupling is slid into place to form the joint;

[0036] FIG. 5 is similar to FIG. 4 but shows the coupling after it is slid into place to form the joint;

[0037] FIG. 6 is a section through the joint depicted in FIG. 5, in a radial plane; and

[0038] FIG. 7 is similar to FIG. 5 but additionally depicts an accessory.

[0039] The embodiment of the invention depicted in FIGS. 1 to 7 comprises a coupling 10 (depicted most clearly in FIGS. 1 and 2) which is a generally cylindrical tubular component. It may comprise metal. For underwater applications, it preferably comprises a corrosion resistant material. Stainless steel is suitable. The coupling 10 has a first open end 12 and a second open end 14, and extending between the ends is a through-going passage 16. The passage is of circular cross section and comprises a first region 18 including the first open end 12 and a second region 20 including the second open end 14. The first region 18 of the passage is of larger diameter than its second region 20. In the illustrated embodiment, the difference in diameters is small. A shallow shoulder 22 provides a transition from the first, larger diameter, region 18 to the second, smaller diameter region 20. This transition could take other forms. The passage 16 has a cylindrical inner coupling face 24.

[0040] Formed in the inner coupling face 24, and within the first region 18, are (a) a first inwardly directed engagement recess 26 and (b) a first seal recess 28 which is inwardly directed. The first seal recess 28 receives a first seal 30. In the present embodiment, this is formed as an O ring seal of generally conventional type, comprising elastomeric material. Also formed in the inner coupling face 24, in the second region 20, is a second inwardly directed engagement recess 32.

[0041] In the present embodiment the recesses 26, 28, 32 are all annular and each extend along a circumference of the cylindrical coupling 10. The first seal recess 28 is in this example flat bottomed with sides lying in a radial plane, suitably to cooperate with the first seal 30 to form a fluid seal. The first and second inwardly directed engagement recesses 26, 32 have in this example a curved, concave cross-section. More specifically their shape is semi-circular. However, the form of any or all of the recesses may be different in other embodiments of the invention.

[0042] To appreciate how the coupling 10 functions, consider FIGS. 3 to 6. In this example the coupling 10 is being used to form a sealed, fluid-conducting joint between first and second tubular members in the form of a pipe 34, and a spigot 36 formed upon an accessory. The accessory is to be incorporated into a pipeline. Purely by way of example it may be a valve, pressure gauge or T connector. The spigot 36 is cylindrical and tubular and has a machined outer face 38 which is a close sliding fit in the first region 18 of the coupling 10. In the outer face 38 of the spigot 36 is a first outwardly directed engagement recess 40.

[0043] The pipe 34 is of smaller external diameter than the spigot 36. The pipe 34 is a close sliding fit in the second region 18 of the coupling.

[0044] An end portion of the pipe 34 comprises recesses used in forming the pipe joint. Specifically, it has (a) a second outwardly directed engagement recess 42 and (b) a second seal recess 44, which is also outwardly directed. The second seal recess is seen in FIGS. 3-5 to receive a second seal 46 which is formed as an O ring seal of generally conventional type, comprising elastomeric material. The second seal 46 is of somewhat larger diameter than the first seal 30. Specifically, the first seal 30 is able to pass through the second seal 46 without one fouling on the other. In the present embodiment the first seal 30 has an inner diameter which is larger than the external diameter of the second seal 46.

[0045] In the configuration depicted in FIG. 3, the joint is disengaged. The coupling 10 has been slid fully onto the pipe 34 so that the coupling 10 does not project beyond the end of the pipe 34. This makes it easy to bring ends of the pipe 34 and the spigot 36 into alignment by moving them laterally (along the direction of arrow 48 in FIG. 3) even though there is little axial clearance between them, to achieve the configuration seen in FIG. 4 in which the spigot and pipe are aligned, with their axes generally coincident and parallel.

[0046] The internal diameter of the first region 18 of the coupling 10 is somewhat larger than the external diameter of the pipe 34. Clearance between them is indicated by arrow 50 in FIG. 3. As a result, the coupling 10 is able to slide along the pipe 34 without fouling. In particular, the first seal 30 is able to move past both the second seal 46 and the second outwardly directed engagement recess 42 without being snagged or damaged. Likewise, the first inwardly directed engagement recess 26 can if necessary move past the second seal 46 without that seal being snagged or damaged.

[0047] When the spigot 36 and the pipe 34 have been aligned, as in FIG. 4, the coupling 10 can be advanced (to the left in FIG. 4) to achieve the connected configuration depicted in FIG. 5. Here, the spigot 36 is received in the first portion 18 of the coupling. The first outwardly directed engagement recess 40 formed on the spigot is aligned with the first inwardly directed engagement recess 26, in the sense that they lie at a common axial position, one within the other, so that together they form a first annular channel 51. In FIG. 5 a first retainer 52 has been inserted into this channel. Looking at FIG. 2, it can be seen that the otherwise cylindrical coupling 10 has an ear portion 54, and that a first insertion channel 56 with an open end 58 leads through the ear portion 54, along a tangent, to the first inwardly directed engagement recess 26 in the coupling. Hence when the engagement recesses are suitably aligned, as in FIG. 5, the retainer 52 can be inserted through the channel 56 into the first annular channel 51 between the spigot 36 and the coupling 10, to lock the spigot axially with respect to the coupling 10. The first retainer 52 is not seen in FIG. 2 but can take the form of an elongate, cylindrical member. It has sufficient flexibility to curve around the circumference of the joint. It may be provided with means for securing it in place in the joint. It may be provided with a pulling featuree.g. a handleto enable it to be pulled out of the joint to enable its disassembly. It may be a circular rod or a helical spring, and may comprise elastomer or suitably flexible metal.

[0048] Looking again at FIG. 5 it can be seen that the first seal 30 acts radially against the outer face 38 of the spigot 36. The seal is somewhat compressed and as a result is able to resist fluid egress between the coupling 10 and the spigot 36. Note that during assembly and disassembly of the joint, the first seal runs only over the spigot's face 38, which can be formed with a smooth finish (e.g. by machining) to avoid snagging of the seal or damage to it.

[0049] Looking now at the engagement between the coupling 10 and the pipe 34, it can be seen in FIG. 5 that the end portion of the pipe 34 is received in the second portion 20 of the coupling 10. The second outwardly directed engagement recess 42 formed upon the pipe 34 is in alignment with the second inwardly directed engagement recess 32 formed upon the coupling 10, to form a second annular channel 60. A second retainer 62 is received in and extends through the second annular channel 60 to lock the pipe 34 axially with respect to the coupling 10. The coupling 10 has a second insertion channel 64 similar to the first insertion channel 56 but aligned with the second inwardly directed engagement recess 32, to enable insertion of the second retainer 62 into the second annular channel 60. FIG. 6 shows the second retainer 62 partially inserted in the second annular channel 60, and also shows a handle 63 which can be used to pull the retainer 62 to withdraw it.

[0050] Looking again at FIG. 5 it can be seen that the second seal 46 acts radially against the inner coupling face 24 of the coupling 10 to resist egress of fluid between the coupling 10 and the pipe 34.

[0051] In FIG. 7 it can be seen that the accessory on which the spigot 36 is formed takes the formin this arbitrary exampleof a valve 70 having a valve lever 72. The accessory could of course have two (or more) spigots to form multiple joints of the above described type.

[0052] Disassembly of the joint is straightforward. The first and second retainers 52, 62 are pulled out of their respective channels. The coupling 10 can then be slid back to the position shown in FIG. 3 to disengage it from the spigot 36, after which for example the accessory 70 can be removed for inspection, replacement etc. This is easily done even where it is not possible to axially separate the accessory from the pipe 34, due to the sliding action of the coupling 10.

[0053] Note that in order to slide the coupling 10 back from its engaged position (FIG. 5) to the disengaged position of FIG. 3, it is not necessary to move the first seal 30 past the first outwardly directed engagement recess 40 formed on the spigot because that recess 40 (and correspondingly the first inwardly directed engagement recess 26 on the coupling 10) lies between the first seal recess 28 and the first open end 12 of the coupling 10. Hence there is no risk of the first seal 30 snagging on the first outwardly directed engagement recess 40. The first seal 30 does move past the second seal 46 and the second outwardly directed engagement recess 42 as the coupling 10 is slid back, but it does not foul those parts due to the enlarged internal diameter of the first region 18 of the coupling 10, and the consequent clearance 50. The internal diameter of the first seal 30 is, in the present embodiment, slightly larger than the internal diameter of the second region 20 of the coupling, and slightly larger than the external diameter of the pipe 34. Hence the first seal 30 can easily move along the pipe 34 without snagging on it. The second seal 46, being received by the pipe 34 and not by the coupling 10, does not move as the coupling 10 is slid back. Because the second inwardly directed engagement recess 32 lies closer to the second open end 14 of the coupling 10 than the seal 46, it is incapable of fouling the seal 46. The result is that the coupling 10 can be slid back and forth to engage/disengage the joint without fouling of either of the seals 30, 46.

[0054] The present embodiment is presented by way of example and not limitation. Numerous variants are possible without departing from the scope of the invention as defined by the appended claims.