Stress control cones for downhole electrical power system tubing encapsulated power cables
First Claim
1. A stress cone for use on a terminated end of a tubing encapsulated power cable (TEPC) used in surface applications of a subsurface well power system employing electric submersible pumps, the TEPC comprising a central conductor section of a first outer diameter OD1, a TEPC insulation layer coaxially surrounding the conductor and having a second outer diameter OD2, and a metal tubing sheath coaxially surrounding the TEPC insulation layer, and having an internal diameter ID1 equal to the second outer diameter OD2, a third outer diameter OD3, and a sheath width defined as the difference between the ID1 and the OD3, the terminated end of the TEPC creating a sheath termination end face, the TEPC insulation layer and conductor section extending for a desired length beyond the sheath termination end face, the conductor section extending for a desired length beyond a termination end of the TEPC insulation layer, the stress cone comprising:
- a. a housing comprising an inlet end and an outlet end oriented about a longitudinal axis, the inlet end capable of receiving the sheath terminated end face, the outlet end capable of permitting the TEPC insulation layer termination end to extend therethrough and out of the housing;
b. an internal insulation chamber located within the housing between the inlet end and the outlet end and comprising an internal metal surface oriented about the axis, the internal metal surface defining a desired shape about the axis, the TEPC insulation layer capable of extending therethrough;
c. a TEPC tubing coupler section axially aligned about the axis at the housing inlet end comprisingi. an annular section oriented about the axis of an inside diameter ID2 equal to the TEPC sheath OD3 having a coupler first end opening and a coupler second end opening of a smaller inside diameter ID3 equal to the TEPC insulation layer OD2, the coupler first end opening capable of receiving the terminated end of the TEPC sheath therethrough, the coupler second end opening leading into the internal insulation chamber and capable of receiving the TEPC insulation layer therethrough, the insulation chamber capable of receiving the desired length of TEPC insulation layer therethrough;
ii. a radially inwardly protruding metal shoulder at the coupler second end comprising a shoulder mating surface facing toward the coupler first end opening, the shoulder mating surface having a depth equal to the sheath width and capable of mating with the sheath termination end face when the terminated TEPC sheath is inserted into the annular section, the shoulder also defining the coupler second opening;
iii. a tubing coupler mechanism capable of securing the TEPC within the coupler annular section; and
d. an insulation material contained within the internal insulation chamber capable of insulating between the TEPC insulation layer OD2 and the insulation chamber internal metal surface when the TEPC is secured within the coupler annular section and the TEPC insulation layer is extending through the internal insulation chamber and out through the housing outlet.
4 Assignments
0 Petitions
Accused Products
Abstract
A stress cone for reducing electrical stresses is disclosed for use on terminated ends of tubing encapsulated power cable used in surface applications in a subsurface well power system employing electric submersible pumps (ESPs). The stress cone comprises an annular section about a longitudinal axis for receiving a terminated end of the TEPC in its first end and for abutting the terminated metal TEPC end against a metal shoulder at its second end therein, and an insulation chamber axially aligned with and connected to the annular section. The chamber comprises a metal interior surface symmetrical about the axis. The insulated TEPC core (without outer metal sheath) passes through the insulation chamber along the axis and then exits. The ID of the TEPC metal sheath and the inside metal surface of the chamber form a smooth ground plane transition surface. Insulation material surrounds the TEPC insulation layer within the insulation chamber.
37 Citations
38 Claims
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1. A stress cone for use on a terminated end of a tubing encapsulated power cable (TEPC) used in surface applications of a subsurface well power system employing electric submersible pumps, the TEPC comprising a central conductor section of a first outer diameter OD1, a TEPC insulation layer coaxially surrounding the conductor and having a second outer diameter OD2, and a metal tubing sheath coaxially surrounding the TEPC insulation layer, and having an internal diameter ID1 equal to the second outer diameter OD2, a third outer diameter OD3, and a sheath width defined as the difference between the ID1 and the OD3, the terminated end of the TEPC creating a sheath termination end face, the TEPC insulation layer and conductor section extending for a desired length beyond the sheath termination end face, the conductor section extending for a desired length beyond a termination end of the TEPC insulation layer, the stress cone comprising:
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a. a housing comprising an inlet end and an outlet end oriented about a longitudinal axis, the inlet end capable of receiving the sheath terminated end face, the outlet end capable of permitting the TEPC insulation layer termination end to extend therethrough and out of the housing; b. an internal insulation chamber located within the housing between the inlet end and the outlet end and comprising an internal metal surface oriented about the axis, the internal metal surface defining a desired shape about the axis, the TEPC insulation layer capable of extending therethrough; c. a TEPC tubing coupler section axially aligned about the axis at the housing inlet end comprising i. an annular section oriented about the axis of an inside diameter ID2 equal to the TEPC sheath OD3 having a coupler first end opening and a coupler second end opening of a smaller inside diameter ID3 equal to the TEPC insulation layer OD2, the coupler first end opening capable of receiving the terminated end of the TEPC sheath therethrough, the coupler second end opening leading into the internal insulation chamber and capable of receiving the TEPC insulation layer therethrough, the insulation chamber capable of receiving the desired length of TEPC insulation layer therethrough; ii. a radially inwardly protruding metal shoulder at the coupler second end comprising a shoulder mating surface facing toward the coupler first end opening, the shoulder mating surface having a depth equal to the sheath width and capable of mating with the sheath termination end face when the terminated TEPC sheath is inserted into the annular section, the shoulder also defining the coupler second opening; iii. a tubing coupler mechanism capable of securing the TEPC within the coupler annular section; and d. an insulation material contained within the internal insulation chamber capable of insulating between the TEPC insulation layer OD2 and the insulation chamber internal metal surface when the TEPC is secured within the coupler annular section and the TEPC insulation layer is extending through the internal insulation chamber and out through the housing outlet. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18)
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19. A stress cone for attachment over a terminated end of a tubing encapsulated power cable (TEPC) used in surface applications of a subsurface well power system employing electric submersible pumps comprising:
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a. a tubing coupler capable of receiving the terminated end of the TEPC, the TEPC comprising a central conductor wire, a TEPC insulation layer of a desired outer diameter coaxially surrounding the conductor wire, and a metal tubing sheath having a desired wall thickness and diameter coaxially surrounding the TEPC insulation layer, the TEPC termination end comprising an end portion of the TEPC wherein a portion of the sheath has been cut off leaving a sheath termination end face and leaving a section of the TEPC insulation layer extending beyond the sheath termination face, and wherein a portion of the TEPC insulation layer has been removed from the extended section of the TEPC insulation layer to expose a section of the conductor wire,
the tubing coupler comprising a coupler annular section comprising a coupler inlet end and a coupler outlet end oriented about a longitudinal axis,the coupler inlet end having an inner diameter capable of receiving the sheath terminated end face, the coupler outlet end capable of permitting the TEPC insulation layer termination end to extend therethrough, the coupler outlet end comprising a reduced inside diameter shoulder stop of inside diameter equal to the insulation layer outer diameter, the shoulder stop further comprising a shoulder mating surface facing toward the coupler inlet, the shoulder mating surface having a depth equal to the sheath wall thickness and capable of mating with the sheath termination end face when the terminated TEPC sheath is inserted into and secured to the coupler inlet end; and b. an enclosed insulation chamber capable of receiving an insulation material comprising i. an insulation chamber inlet end coterminous with the coupler outlet end, ii. an insulation chamber internal metal surface oriented symmetrically about the axis, the internal metal surface defining a desired symmetrical shape about the axis, the TEPC insulation layer capable of extending therethrough along the axis and being surrounded by the insulation material received within the insulation chamber, and iii. an insulation chamber outlet end comprising an apertured opening capable of receiving the extended section of the TEPC insulation layer therethrough. - View Dependent Claims (20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35)
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36. A high-pressure connector assembly for use on a terminated end of a tubing encapsulated power cable (TEPC) used in applications of a subsurface well power system employing electric submersible pumps, the TEPC comprising a central conductor section of a first outer diameter OD1, a TEPC insulation layer coaxially surrounding the conductor and having a second outer diameter OD2, and a metal tubing sheath coaxially surrounding the TEPC insulation layer, and having an internal diameter ID1 equal to the second outer diameter OD2, a third outer diameter OD3, and a sheath width defined as the difference between the ID1 and the OD3, the terminated end of the TEPC creating a sheath termination end face, the TEPC insulation layer and conductor section extending for a desired length beyond the sheath termination end face, the conductor section extending for a desired length beyond a termination end of the TEPC insulation layer and terminating at central conductor termination end, the high pressure connector assembly comprising:
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a. a metal housing comprising an inlet end and an outlet end oriented about a longitudinal axis; b. an annular space located about the axis within the housing between the inlet end and the outlet end defined by inner housing metal surfaces, c. a first high-pressure metal pressure fitting capable of receiving the sheath terminated end face and securing the TEPC cable into the housing inlet end in a pressure-tight seal; the first high-pressure metal pressure fitting further comprising a fitting annular section comprising a fitting inlet end and a fitting outlet end oriented about the longitudinal axis, the first fitting inlet end having an inner diameter capable of receiving the sheath terminated end face, the first fitting outlet end capable of permitting the TEPC insulation layer termination end to extend therethrough, the first fitting outlet end comprising a reduced inside diameter shoulder stop of inside diameter equal to the insulation layer outer diameter, the shoulder stop further comprising a shoulder mating surface facing toward the fitting inlet, the shoulder mating surface having a depth equal to the sheath wall thickness and capable of mating with the sheath termination end face when the terminated TEPC sheath is inserted into and secured to the first fitting inlet end; d. a second high-pressure pressure fitting located at the outlet end; e. a conductor pin mounted along the axis within the annular space and having a first end capable of being mounted in electrical conductive contact with the conductor section terminal end, and a second conductor pin end extending into the second high-pressure pressure fitting; f. a socket to socket type connector located about the axis within the annular space comprising a first socket connector end for receiving the desired length of the conductor section extending beyond the termination end of the TEPC insulation layer, and a second end for receiving the first end of the conductor pin in abutted engagement with the conductor section terminal end; g. an enclosed insulation chamber formed within the annular space capable of receiving an insulation material comprising i. an insulation chamber inlet end coterminous with the first fitting outlet end, ii. an insulation chamber internal metal surface oriented symmetrically about the axis, the internal metal surface comprising an electrical stress relief zone proximate the insulation chamber inlet end defining a desired symmetrical shape about the axis, the TEPC insulation layer capable of extending therethrough along the axis and being surrounded by the insulation material received within the insulation chamber, the socket to socket connection and conductor pin first end being surrounded by the insulation material, iii. an insulation chamber outlet end comprising an apertured opening capable of receiving the conductor pin second end therethrough and secured in sealed fashion; and h. an insulation material filling the annular space wherein the second high-pressure fitting located at the outlet end is capable of being secured, in pressure sealed fashion, to another TEPC cable. - View Dependent Claims (37, 38)
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Specification