THOMSON J (GB)
| EP0006278A1 | 1980-01-09 | |||
| US3921656A | 1975-11-25 | |||
| US4071268A | 1978-01-31 | |||
| US2406662A | 1946-08-27 | |||
| DE177719C | ||||
| GB2051993A | 1981-01-21 | |||
| US3921656A | 1975-11-25 | |||
| US4071268A | 1978-01-31 | |||
| EP0006278A1 | 1980-01-09 |
| 1. | A breakaway coupling for joining together two pipes the coupling having at least two separable parts, through which a conduit extends along which fluid is to be conveyed, one part being adapted for connection to one pipe and the other part being adapted for connection to the other pipe, the two separable parts being secured together by frangible means, the parts defining therebetween a fluid chamber in fluid pressure communication with the conduit, the chamber serving to subject the parts to a fluid pressure force for urging the parts together. |
| 2. | A breakaway coupling according to Claim 1 wherein a first of the' coupling parts has a sleeve which extends about the second part to define an annular space there between, a pair of spaced annular pistons being received in said annular space to define therefore said fluid chamber, the pistons being connected to said parts so that fluid pressure in said fluid chamber urges said parts together. |
| 3. | Abreakaway coupling according to Claim 2 wherein at least one of said pistons is detachably secured to both parts so that on fracture of said frangible means said one piston is separable from both parts. |
| 4. | A breakaway coupling according to Claim 3 wherein said one piston is secured to one of said parts by said frangible means and is movable in unison with said other parts until said parts have axially moved relative to one another by a predetermined distance. |
| 5. | A breakaway coupling according to Claim 4 wherein said one piston is secured to said one part by one or more frangible bolts and is secured to said other part by latch means which on a relative axial movement of said parts are retractable to permit axial separation of said one piston and said other part. |
| 6. | A breakaway coupling according to. Claim 5 wherein the latch means includes one or more balls partially located in said one piston and said other part and are maintained there by said frangible bolts which on fracture 5 enable said ball or balls to retract to enable separation of said one piston and said other part. |
| 7. | A breakaway coupling a'ccording to Claim 5 wherein the latch means includes one or ore balls partially located in said one piston and said other part and are maintained there by plungers received in radial bores formed in said one piston and which abut against said one part, said one piston being secured to said one part by frangible means which one fracture enable said one piston "'■ and said other part to move in unison to a position whereat the plungers retract and enable separation of said one piston and said other part. |
| 8. | A breakaway coupling according to any of Claims 2 to 7 wherein the crosssectional' area of said pistons • is substantially the same as the crosssection area of said conduit. |
| 9. | A breakaway coupling according to any preceding .Claim wherein one of the parts includes valve means for closing said conduit on separation of said parts. |
| 10. | A breakaway coupling according to Claim 9 wherein the valve means includes a plurality of petal elements each of which is pivotally .mounted for movement between a retracted position and a fully extended position, the petal elements in their extended position collectively defining a cone. ~" " " " ιι. |
| 11. | A breakaway coupling according' to any preceding claim wherein said fluid chamber communicates with said conduit via bores formed in said first part, each bore being closed by a diaphragm which prevents fluid commun¬ ication but permits fluid pressure to be transmitted from said conduit to said fluid chamber. |
| 12. | A breakaway coupling substantially as described and as illustrated in the accompanying drawings. |
BREAKA AY COUPLING
The present invention relates to " a breakaway pipe coupling.
It is desirable in pipe lines, conveying fluids such as oil or gases to ensure that the pipe line breaks at predetermined locations; in the event of the pipe line being stretched, for instance as may happen at sea when an oil tanker is loading/unloading at a quayside.
For this purpose it has been proposed to provide frangible bolts for connecting the connecting flanges of lengths of piping so that when the piping is stretched the bolts break in preference to the body of the pipes .
Although such a construction works, theie is one major drawback, namely, if there is an internal surge of pressure within the fluid being conveyed, for instance on the rapid shutting off of flow, the resultant pressure wave may be sufficiently strong to cause shearing of the bolts.
It is therefore a general object of the -present invention to provide- a breakaway pipe coupling which functions to separate only when the pipeline is stretched.
According to one aspect of the present invention there is provided a breakaway coupling for pining together two pipes the coupling having at least two separable parts , through which a conduit extends along which fluid is to be conveyed, one part being adapted for connection to one pipe and the other part being adapted for ' connection to the other pipe, the two separable parts being secured together by frangible means, the parts defining there- between a fluid chamber in fluid pressure communication
' with the conduit, the chamber serving to subject the parts to a fluid pressure force for urging the parts .together.
Preferably the fluid pressure force for urging the parts together is at least as great as the fluid pressure force within the conduit urging the parts apart.
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Reference is now made to the accompanying drawings, in which :-
Figure 1 is a part axial section through a first embodiment according to the present invention, Figure 2 is an axial section through a second embodiment according to the present invention.
Figure 3 is a longitudinal section of a third embodiment according to the present invention.
Figure 4 is an end view of the embodiment shown in Figure 3,
Figure 5 is a part sectional view of the embodiment shown in Figure 3.
Referring initially to Figure 1 there is shown a breakaway pipe coupling 10 including two separable halves 11 and 12 respectively. Both halves 11,12 have annular end flanges 11a, 12a respectively for bolting to end flanges of pipes (not shown) which are to be coupled together by the coupling 10. • .
Coupling half 12 has a sleeve 15 which has a first portion 15a_ wh-ich, receives the end portion lib of coupling half 11 and a second portion 15b which is radially spaced from the outside face of coupling half 11 to define an annular space 16. The end portion lib is of reduced diameter to define a shoulder lie against which an annular piston in the form of a ring 17 abuts.
The ring 17 is prevented from axial movement relative to coupling half 11 by a circlip 18.
A second annular piston in the form of ring 20 is received in the annular space 16 and is restrained from axial movement within sleeve portion 15b by virtue of a series of balls 22 (only one of which is shown) spaced circu ferentially about the ring 20. Each ball 22 is received in a radially extending bore 23 and projects therefrom into an annular groove 21 formed in sleeve
OMPI
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portion 15b.
Each- ball 22 is prevented from moving radially in¬ wards by virtue of a threaded stud 24 which is threadedly received in ring 20 and projects axially therefrom to extend through a peripheral flange 26 formed on coupling half 11. A nut 27 is received on each stud so that the coupling halves 11, 12 are secured to one another via each stud and ring 20. Each stud is provided with a waisted portion 24a which defines a frangible portion. Ring 20 and ring 17 are spaced from one another so as to define an annular fluid chamber 28 and radially extending bores 30 are provided circumferentially around coupling half 11 f>r providing pressure communication between annular chamber 28 and fluid conduit 31. Bores 30 may. be closed by a diaphragm 60, for instance as illustrated in Figure 5 so that chamber 28 is isolated from fluid flowing along conduit 31 in order to prevent debris carried by the fluid flowing along conduit 31 from settling out in chamber 28.. . Accordingly, chamber 28 may- be filled with a fluid which is different to that flowing along conduit 31. The diaphragm 60 may therefore be of any suitable construction which enables fluid pressure to be transmitted between conduit 31 and and chamber 28. The diaphragm shown in Figure 5 includes an annular ring 61 across which extends a relatively thin membrane 62. The ring 61 and membrane 62 may be made integrally from a suitable material such as a plastics material or a metal.
Fluid pressure acting on opposed faces 20a_ and 17a_ tends to urge the coupling halves together whilst fluid pressure acting within the conduit 31 tends to urge the coupling halves apart. The area of opposed faces 20a_, 17a_ is chosen to be at least as large as the cross- sectional area of the conduit 31 so the -resultant fluid force acting to axially move the coupling halves is
-4- . ■ " substantially zero. However it will be appreciated that these areas may be varied so as to give -a resultant forc which either urges the coupling halves apart or urges th together. Ring 20 and ring 17 are provided with seals 36, 37 respectively so as to prevent fluid leakage from annular chamber 28. A seal 38 is provided between end portion 1 and sleeve portion 15a in order to prevent fluid leakage from conduit 31. Venting bores 40 are provided in sleeve portion 15 for venting the annular space 42. These vents prevent t creation of a vacuum on separation of the coupling halve and alsoprevent build up of fluid pressure in the event o " failure of seal 38. In use when the two coupling halves are urged axia apart by a physical pull, the studs 24 are placed under stress. The frangible portion of the studs are designed to shear at a predetermined load -and upon shearing each stud is axially withdrawn from ring 20 and ring 17 is moved into contact with ring 20. Due to the withdrawal of studs 24 the balls 22 are permitted to enter bores 23 and so leave groove 21 as the ring 17 urges ring 20 axia out of sleeve portion 15b. Thus the coupling halves 11, 12 are completely separated. In Figure 2, a second embodiment is illustrated an parts* similar to those in the first embodiment are designated by the same reference numerals.
In the second embodiment, the balls 22 seated in individual recesses 22a_ and are held in position within the bores 23 by means of a plunger 50. Each fluid bore ' 30 is enlarged and positioned so that on breaking of frangible bolts 24 the bores 30 align with plungers 50 which are urged through bores 30 by each ball leaving its recess 22a_.
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A third embodiment is shown in Figures 3 and 4 which shows a breakaway coupling 80 constructed as described above with reference to Figure 1 (and which may be modified in accordance with Figure 2) " and additionally includes a valve means 81 which on separation of parts 11 and 12 automati- - cally closes the conduit 31 in order to prevent excessive spillage of fluid from the conduit 31.
The valve means 81 includes a plurality of petal elements 82 each of which is pivotally mounted in the coupling part 12 for movement between a fully retracted position as seen on the right hand side of Figure 3 to a fully extended position as shown on the left hand side of Figure 3. *' " -- ' - . " -. "
, In tHeir fully extended position, all the petal ele- ments abut one another to form a cone shape facing the' direction of flow of fluid along conduit ' 31 so that' fluid pressure in conduit 31 urges the petal elements into abutment. . , .---. . -- . .. ; . _
Each petal element 81 is provided with an actuation arm 82*which is acted upon by a pair of opposed pistons 84, 85 respectively which are housed in a bore 86 formed in coupling part 12. As seen in Figure 3, piston 84 is biased by a spring 87 to move the actuation arm 82«to move its petal element toward its extended position. Piston 84 therefore provides the initial motive force for moving' the petal element towards its fully extended position and there¬ after the pressure of fluid within conduit 31 provides the motive force. The piston chamber 90 in which piston 85 moves is filled with a fluid which is permitted to escape from chamber 90 at a controlled rate on separation of the coupling parts. The pistons 85 thus control the rate at which petal elements 81 move to their fully extended positions. It is presently preferred to have eight petal elements 81 and to control their ratesof movement such that
four alternate petal elements 81 reach -their fully extended position rapidly as shown in Figure 4 so as to form a bridge against which the remaining petals may abut on reaching their fully extended position. In order to ensure that the full extended position of first four petal elements is correct in order that their terminal ends mutually but, ihe piston 85 £>r each petal element is arranged to act as a stop for movement of its associated petal. For a fuller description of the valve means and its operation reference should be made to our European Application No. 79 300153. -
An internal sleeve 92 is provided which extends from the coupling part 11 and which axially withdraws from part 12 on separation of parts 11 and 12. ' The sleeve 92 is provided with aperture 98 for permitting fluid pressure communication between conduit 31 and the bores30.
Seals 94, 95 are provided between sleeve 92 and" parts 11 and 12 * so as to provide a sealed annular chamber 96 in which the valve means is housed. Chamber 96 is filled with a suitable fluid, such as a lubricating oil, to reduce the likelihood of the petal elements failing to move to their extended position after separation of parts 11 and 12. - . . . . . -_ ■ . . -