Connection for a thermoplastic pipe, assembly and method
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F16L-013/02
B29C-065/34
F16L-011/08
F16L-047/03
B29C-065/82
B29C-065/00
출원번호
US-0679794
(2012-11-16)
등록번호
US-9322495
(2016-04-26)
발명자
/ 주소
Duncan, Mark
Conley, Jeffrey Ryan
Niu, Hao
Bouey, Samuel Glen
출원인 / 주소
SHAWCOR LTD. SHAWCOR LTÉE
대리인 / 주소
Bennett Jones LLP
인용정보
피인용 횟수 :
1인용 특허 :
80
초록▼
A pipe coupling for forming a pipe connection includes: a wall formed as a tube and including an inner surface defining an inner diameter and an outer surface; an electrical conductor supported by the wall and extending about a circumference of the coupling; and a pair of contacts exposed on the out
A pipe coupling for forming a pipe connection includes: a wall formed as a tube and including an inner surface defining an inner diameter and an outer surface; an electrical conductor supported by the wall and extending about a circumference of the coupling; and a pair of contacts exposed on the outer surface and electrically in contact with the electrical conductor for connecting an electrical power source to the electrical conductor.
대표청구항▼
1. A pipe coupling for forming a pipe connection, the pipe coupling comprising: a wall formed as a tube having open ends and an axis extending between the open ends and having a tubular laminate construction including a liner with an inner surface defining an inner diameter, a reinforcement layer ou
1. A pipe coupling for forming a pipe connection, the pipe coupling comprising: a wall formed as a tube having open ends and an axis extending between the open ends and having a tubular laminate construction including a liner with an inner surface defining an inner diameter, a reinforcement layer outwardly of the liner, the reinforcement layer including at least one axially extending ply of reinforcing fibers with reinforcing fibers extending at an angle of less than 20° off the axis and at least one hoop wound ply of fibers with reinforcing fibers extending at an angle of greater than 70° relative to the axis and an outer jacket encircling the reinforcement layer and defining an outer surface of the pipe coupling; an electrical conductor supported by the liner and extending about a circumference of the coupling; and a pair of contacts exposed on the outer surface and electrically in contact with the electrical conductor for connecting an electrical power source to the electrical conductor, wherein the at least one axially extending ply of reinforcing fibers and the hoop wound ply of reinforcing fibers each are formed from a tape with the reinforcing fibers extending along a length of the tape. 2. The pipe coupling of claim 1 having an operating pressure range of from 50 to 103 bar. 3. The pipe coupling of claim 1 wherein the liner, the reinforcement layer and the outer jacket each contain a thermoplastic. 4. The pipe coupling of claim 3 wherein the thermoplastic has at least one of the following characteristics: (i) a softening temperature greater than 100° C., (ii) a brittleness temperature less than −60° C., (iii) a melt temperature of 120 to 300° C., (iv) a tensile strength of 16 to 100 MPa, (v) an elongation to break of at least 50%, (vi) resistance to fatigue cracking when subjected to 1 million cycles at 1% strain, and (vii) a notched IZOD impact strength greater than 30 J/m. 5. The pipe coupling of claim 4 wherein the thermoplastic has all of (i) to (vii) and the liner, the reinforcement layer and the outer jacket are fused together in the wall. 6. The pipe coupling of claim 4 wherein the thermoplastic is selected from a polyimide, a polyethylene and a polypropylene. 7. The pipe coupling of claim 1 wherein the electrical conductor is embedded in the liner. 8. The pipe coupling of claim 1 wherein the hoop wound ply of reinforcing fibers has fibers extending at an angle of between 85 and 90° relative to the axis. 9. The pipe coupling of claim 1 wherein the at least one axially extending ply of reinforcing fibers includes at least one ply extending in a positive helical direction and at least one ply extending in a negative helical direction. 10. The pipe coupling of claim 1 wherein the tape includes reinforcing fibers of glass in a matrix including thermoplastic. 11. The flexible pipe connection system of claim 1 wherein the liner, the reinforcement layer and the jacket each contain a thermoplastic. 12. The flexible pipe connection system of claim 11 wherein the thermoplastic has at least one of the following characteristics: (i) a softening temperature greater than 100° C., (ii) a brittleness temperature less than −60° C., (iii) a melt temperature of 120 to 300° C., (iv) a tensile strength of 16 to 100 MPa, (v) an elongation to break of at least 50%, (vi) resistance to fatigue cracking when subjected to 1 million cycles at 1% strain, and (vii) a notched IZOD impact strength greater than 30 J/m. 13. The flexible pipe connection system of claim 12 wherein the thermoplastic has all of (i) to (vii) and the liner, the reinforcement layer and the jacket are fused together in the coupling. 14. The flexible pipe connection system of claim 12 wherein the thermoplastic is at least one of a polyamide, a polyethylene and a polypropylene. 15. The flexible pipe connection system of claim 1 wherein the liner supports the electrical conductor. 16. The flexible pipe connection system of claim 15 wherein the electrical conductor is embedded in the liner. 17. The flexible pipe connection system of claim 1 wherein the at least one ply of reinforcing fibers extends substantially axially and/or is wound circumferentially around the coupling. 18. The flexible pipe connection system of claim 1 wherein the at least one ply of reinforcing fibers results from a tape with the reinforcing fibers extending along a length of the tape. 19. The flexible pipe connection system of claim 1 wherein the tape includes reinforcing fibers of glass in a matrix including thermoplastic. 20. A flexible pipe connection system comprising: a pipe having a wall including an inner surface defining an inner diameter of the pipe, an open end through which the inner diameter is accessed, and a thermoplastic outer jacket exposed on an outer surface of the pipe adjacent the open end; and a connection for connecting to the open end of the pipe, the connection including a coupling and an insert, the coupling including an inner wall surface, an outer wall surface and a wall thickness between the inner wall surface and the outer wall surface, the wall thickness having a tubular laminate construction including a liner, a reinforcement layer outwardly of the liner, the reinforcement layer including at least one ply of reinforcing fibers and a jacket encircling the reinforcement layer, an electrical conductor supported by the wall thickness and extending about a circumference of the coupling, a pair of contacts exposed on the outer wall surface and electrically in contact with the electrical conductor for connecting an electrical power source to the electrical conductor and the insert configured as a tube separate from the coupling, the insert including an outer tubular surface and having a rigidity greater than that of the coupling, the system including the insert installed within the inner diameter to internally support the pipe and the coupling installed over the pipe with the electrical conductor overlapping the thermoplastic outer jacket and the inner wall surface fused to the thermoplastic outer jacket by thermoplastic melting of the thermoplastic outer jacket by the electrical conductor. 21. The flexible pipe connection system of claim 20 wherein the connection system provides a maximum operating internal pressure of from 50 to 103 bar. 22. The flexible pipe connection system of claim 20 wherein the insert extends into the inner diameter a distance to radially underlap the electrical conductor. 23. The flexible pipe connection system of claim 20 further comprising a second pipe extending from an end of the coupling opposite the electrical conductor. 24. The flexible pipe connection system of claim 23 wherein the second pipe is secured to the coupling with the inner wall surface fused to a thermoplastic outer jacket of the second pipe by an electrofusion process. 25. A method for connecting a first pipe to a second pipe, the first pipe and the second pipe each having a wall including an inner surface defining an inner diameter, an open end through which the inner diameter is accessed, and a thermoplastic outer jacket exposed on an outer surface of the wall adjacent the open end, the method comprising: inserting an end of the first pipe into a coupling formed as a tube having open ends and an axis extending between the open ends and having a tubular laminate construction and including a liner with an inner wall surface defining an inner diameter between the open ends configured to accommodate the first pipe and the second pipe positioned end to end, a reinforcement layer outwardly of the liner, the reinforcement layer including at least one axially extending ply of reinforcing fibers with fibers extending at an angle of less than 20° off the axis and a hoop wound ply of fibers with fibers extending at an angle of greater than 70° relative to the axis and an outer jacket encircling the reinforcement layer and defining an outer wall surface, an electrical conductor supported by the liner of the coupling and extending about a circumference of the coupling, a pair of contacts exposed on the outer wall surface and electrically in contact with the electrical conductor for connecting an electrical power source to the electrical conductor, positioning the coupling with the electrical conductor overlapping the thermoplastic outer jacket of the first pipe, placing a tubular insert within the inner diameter of the first pipe, the tubular insert separate from the coupling and including an outer tubular surface and the tubular insert being hollow and having a rigidity greater than that of the coupling, the tubular insert configured to internally support the first pipe and to fit within the inner diameter of the coupling with an annular gap between the inner surface and the outer tubular surface in which the first pipe resides, generating an electrical current through the electrical conductor to melt the thermoplastic outer jacket and to fuse the first pipe to the coupling, inserting an end of the second pipe into the annular gap between the coupling and the tubular insert and positioning the second pipe with a gap between the end of the first pipe and the end of the second pipe and with the electrical conductor overlapping the thermoplastic outer jacket of the second pipe, and generating an electrical current through the electrical conductor to melt the thermoplastic outer jacket and to fuse the second pipe to the coupling, the tubular insert having an axial length along the outer tubular surface sufficient to underlap both the electrical conductor and the gap between the ends of the first pipe and the second pipe. 26. The method of claim 25 wherein generating an electrical current to fuse the first pipe to the coupling occurs before shipping and generating an electrical current to fuse the second pipe to the coupling occurs after shipping. 27. The method of claim 25 further comprising testing the integrity of the connection including: accessing an enclosed volume between the first pipe, the insert and the coupling, the enclosed volume sealed by a first seal between the inner surface and the insert and a second seal between the outer surface and the coupling; pressurizing the enclosed volume to a test pressure; and monitoring the test pressure to observe the pressure holding integrity of the first seal and the second seal. 28. The method of claim 25 further comprising installing an external clamp about the coupling before generating the electrical current. 29. A flexible pipe connection system comprising: a pipe having a wall including an inner surface defining an inner diameter of the pipe, an open end through which the inner diameter is accessed, and a thermoplastic outer jacket exposed on an outer surface of the pipe adjacent the open end; and a connection for connecting to the open end of the pipe, the connection including a coupling and an insert, the coupling including an inner wall surface, an outer wall surface and a wall thickness between the inner wall surface and the outer wall surface, the wall thickness has having a tubular laminate construction including a liner with an inner surface defining the inner wall surface, a reinforcement layer outwardly of the liner, the reinforcement layer including at least one axially extending ply of reinforcing fibers with fibers extending at an angle of less than 20° off the axis and a hoop wound ply of reinforcing fibers with fibers extending at an angle of greater than 70° relative to the axis and an outer jacket encircling the reinforcement layer and defining the outer wall surface; and the electrical conductor is embedded in the liner, an electrical conductor supported by the wall thickness and extending about a circumference of the coupling, a pair of contacts exposed on the outer wall surface and electrically in contact with the electrical conductor for connecting an electrical power source to the electrical conductor and the insert configured as a tube separate from the coupling, the insert including an outer tubular surface and having a rigidity greater than that of the coupling, the system including the insert installed within the inner diameter to internally support the pipe and the coupling installed over the pipe with the electrical conductor overlapping the thermoplastic outer jacket and the inner wall surface fused to the thermoplastic outer jacket by thermoplastic melting of the thermoplastic outer jacket by the electrical conductor. 30. The flexible pipe connection system of claim 29 wherein the at least one axially extending ply of reinforcing fibers and the hoop wound ply of reinforcing fibers each are formed from a tape with the fibers extending along a length of the tape and a thermoplastic matrix and the plies are fused together by fusion of the thermoplastic matrix. 31. A pipe connection assembly for connecting an end of a first pipe to an end of a second pipe, the connection comprising: a coupling including a wall configured as a tube having open ends and an axis extending between the open ends and having a tubular laminate construction including a liner with an inner surface defining an inner diameter between the open ends, a reinforcement layer outwardly of the liner, the reinforcement layer including at least one axially extending ply of reinforcing fibers with fibers extending at an angle of less than 20° off the axis and a hoop wound ply of fibers with fibers extending at an angle of greater than 70° relative to the axis and an outer jacket encircling the reinforcement layer and defining an outer wall surface, an electrical conductor supported by the liner and extending about a circumference of the coupling, a pair of contacts exposed on the outer wall surface and electrically in contact with the electrical conductor for connecting an electrical power source to the electrical conductor, the coupling configured to accommodate the first pipe and the second pipe positioned end to end in the inner diameter; anda tubular insert separate from the coupling and including an outer tubular surface and the tubular insert being hollow and having a rigidity greater than that of the coupling, the tubular insert configured to fit within the inner diameter of the coupling with an annular gap between the inner surface and the outer tubular surface and to internally support the first pipe, the tubular insert having an axial length along the outer tubular surface sufficient to underlap both the electrical conductor and a gap between the ends of the first pipe and the second pipe. 32. The pipe connection assembly of claim 31 wherein the connection system provides a maximum operating internal pressure of from 50 to 103 bar. 33. The pipe connection assembly of claim 31 wherein the liner and the outer jacket each contain a thermoplastic and the at least one axially extending ply of reinforcing fibers and the hoop wound ply of reinforcing fibers each are formed from a tape with the fibers extending along a length of the tape and a matrix containing thermoplastic and the plies, the liner and the outer jacket are fused together by fusion of the thermoplastic. 34. The pipe connection assembly of claim 33 wherein the thermoplastic has: (i) a softening temperature greater than 100° C., (ii) a brittleness temperature less than −60° C., (iii) a melt temperature of 120 to 300° C., (iv) a tensile strength of 16 to 100 MPa, (v) an elongation to break of at least 50%, (vi) resistance to fatigue cracking when subjected to 1 million cycles at 1% strain, and (vii) a notched IZOD impact strength greater than 30 J/m. 35. The pipe connection assembly claim 34 wherein the thermoplastic is at least one of a polyamide, a polyethylene and a polypropylene. 36. The pipe connection assembly claim 31 wherein the hoop wound ply of reinforcing fibers has fibers extending at an angle of between 85 and 90° relative to the axis. 37. The pipe connection assembly of claim 31 wherein the electrical conductor is embedded in the liner. 38. The pipe connection assembly of claim 31 wherein the tubular insert includes annular seals on the outer tubular surface. 39. The pipe connection assembly of claim 31 wherein the tubular insert includes a bore and a first end and an opposite end opening to the bore and wherein the ends have tapered inner diameter surfaces. 40. The pipe connection assembly of claim 39 wherein the tubular insert includes an annular shoulder extending outwardly from the outer tubular surface, against which the ends of the first pipe and second pipe abut. 41. The pipe connection assembly of claim 40 wherein the tubular insert has a first end length between the first end and the annular shoulder and a second end length between the opposite end and the annular shoulder and the first end length is shorter than the second end length. 42. The pipe connection assembly of claim 31 wherein the tubular insert includes surface serrations on the outer tubular surface.
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Hill Donald C. (Pasadena CA), Apparatus and method of forming fusion welded butt joint between thermoplastic pipe sections.
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