IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0291962
(2008-11-14)
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등록번호 |
US-8210282
(2012-07-03)
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발명자
/ 주소 |
- Salzer, III, John A.
- David, Michael Louis
- Eggleston, Douglas Dewayne
- Noe, Paul Freeman
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출원인 / 주소 |
- Strata Directional Technology, LLC
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대리인 / 주소 |
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인용정보 |
피인용 횟수 :
0 인용 특허 :
8 |
초록
▼
Systems and methods for preventing slippage and rotation of components installed along a rotatable tubular shaft and/or in a tubular housing member during drilling operations are disclosed herein. The housing and/or rotatable shaft include a shoulder disposed proximate to one end. An adjustable memb
Systems and methods for preventing slippage and rotation of components installed along a rotatable tubular shaft and/or in a tubular housing member during drilling operations are disclosed herein. The housing and/or rotatable shaft include a shoulder disposed proximate to one end. An adjustable member is secured proximate to the opposite end. One or more components are installed, covering a first portion of the surface between the adjustable member and shoulder. One or more spacing members are installed to cover substantially all of the remaining surface. The adjustable member is tightened such that the adjustable member and the shoulder apply a compressive axial load to the components and spacing members, causing frictional forces between adjacent objects greater than the torque acting on the housing and/or tubular shaft, causing each component to remain stationary with respect to the surface to which it is secured.
대표청구항
▼
1. A system for preventing slippage and rotation of components installed on a rotatable tubular shaft of a drill string during drilling operations, the system comprising: a tubular shaft comprising an exterior surface, an upper end configured for attachment to a mud motor, a lower end configured for
1. A system for preventing slippage and rotation of components installed on a rotatable tubular shaft of a drill string during drilling operations, the system comprising: a tubular shaft comprising an exterior surface, an upper end configured for attachment to a mud motor, a lower end configured for attachment to a drill bit, and a shoulder disposed proximate to the lower end, wherein the tubular shaft is adapted to rotate during drilling operations;an adjustable member secured to the tubular shaft proximate to the upper end;at least one rotating component comprising a thrust bearing, a radial bearing, or combinations thereof, installed on the tubular shaft between the shoulder and the adjustable member, wherein said at least one rotating component covers a first portion of the exterior surface while leaving a second portion of the exterior surface uncovered; andat least one spacing member disposed between the shoulder and the adjustable member, wherein said at least one spacing member covers substantially all of the second portion of the exterior surface, and wherein the adjustable member is tightened such that the adjustable member and the shoulder apply a compressive axial load to said at least one rotating component and said at least one spacing member, wherein the compressive axial load creates frictional forces between said at least one rotating component and said at least one spacing member greater than a maximum torque expected to act on the tubular shaft, such that said at least one rotating component remains stationary with respect to the tubular shaft during drilling operations, and such that said at least one rotating component rotates concurrent with the rotation of the tubular shaft during drilling operations, thereby reducing wear on the tubular shaft, said at least one rotating component, said at least one spacing member, or combinations thereof. 2. The system of claim 1, wherein the adjustable member comprises a nut. 3. The system of claim 1, wherein said at least one spacing member comprises a member of the group consisting of: a split ring, a spring, a spacer, a sealing member, a spring retainer, a washer, and combinations thereof. 4. The system of claim 3, wherein the sealing member comprises at least one o-ring. 5. The system of claim 1, wherein said at least one rotating component is maintained in a stationary orientation with respect to the tubular shaft during drilling operations due solely to the compressive axial load. 6. The system of claim 1, wherein the compressive axial load is created through an axial force provided by said at least one adjustable member and a counter axial force provided by the shoulder. 7. A system for securing components along a rotatable shaft, the system comprising: a rotatable shaft having an exterior surface, a first end, a second end, and a shoulder disposed proximate to the first end, wherein the rotatable shaft is adapted to rotate;an adjustable member secured to the rotatable shaft proximate to the second end;at least one rotating component installed along the rotatable shaft between the shoulder and the adjustable member, wherein said at least one rotating component covers a first portion of the exterior surface while leaving a second portion of the exterior surface uncovered; andat least one spring disposed between the shoulder and the adjustable member, wherein said at least one spring covers substantially all of the second portion of the exterior surface,wherein the adjustable member applies an axial force toward the shoulder, and wherein the shoulder applies a counter axial force toward the adjustable member to create a compressive axial load on said at least one rotating component and said at least one spring, wherein the compressive axial load creates frictional forces between said at least one rotating component and said at least one spring greater than a maximum torque expected to act on the rotatable shaft, such that said at least one rotating component remains stationary with respect to the rotatable shaft during rotation thereof. 8. The system of claim 7, wherein the spring comprises a wave spring, a belleville spring, or combinations thereof. 9. A method for preventing slippage and rotation of components installed on a rotatable tubular shaft of a drill string during drilling operations, the method comprising the steps of: installing at least one rotating component comprising a thrust bearing, a radial bearing, or combinations thereof, on a tubular shaft comprising an exterior surface, an upper end configured for attachment to a mud motor, a lower end configured for attachment to a drill bit, and a shoulder disposed proximate to the lower end, wherein the tubular shaft is adapted to rotate during drilling operations, and wherein said at least one rotating component covers a first portion of the exterior surface of the tubular shaft while leaving a second portion of the exterior surface uncovered;installing at least one spacing member on the tubular shaft, wherein said at least one spacing member covers substantially all of the second portion of the exterior surface;installing a torquable member on the tubular shaft proximate to the upper end; andtightening the torquable member, thereby providing a compressive axial load on said at least one rotating component and said at least one spacing member, wherein the compressive axial load creates frictional forces between said at least one rotating component and said at least one spacing member greater than a maximum torque expected to act on the tubular shaft, such that said at least one rotating component remains stationary with respect to the tubular shaft during drilling operations, and such that said at least one rotating component rotates concurrent with the rotation of the tubular shaft during drilling operations, thereby reducing wear on the tubular shaft, said at least one rotating component, said at least one spacing member, or combinations thereof. 10. The method of claim 9, wherein said at least one spacing member comprises a member of the group consisting of: a split ring, a spring, a spacer, a sealing member, a spring retainer, a washer, and combinations thereof. 11. The method of claim 10, wherein the sealing member comprises at least one o-ring. 12. The method of claim 9, wherein said at least one rotating component comprises a thrust bearing comprising a lug, and wherein the step of installing said at least one rotating component comprises engaging the lug with a slot in an adjacent said at least one spacing member. 13. The method of claim 9, wherein the step of tightening the torquable member provides the compressible axial load by applying an axial force toward the shoulder, and wherein the shoulder applies a counter axial force toward the torquable member to create the compressive axial load. 14. The method of claim 9, wherein said at least one rotating component is maintained in a stationary orientation with respect to the tubular shaft during drilling operations due solely to the compressive axial load. 15. A method for preventing slippage and rotation of components installed on a rotatable tubular shaft of a drill string during drilling operations, the method comprising the steps of: installing at least one rotating component on a tubular shaft comprising an exterior surface, an upper end configured for attachment to a mud motor, a lower end configured for attachment to a drill bit, and a shoulder disposed proximate to the lower end, wherein the tubular shaft is adapted to rotate during drilling operations, and wherein said at least one rotating component covers a first portion of the exterior surface of the tubular shaft while leaving a second portion of the exterior surface uncovered;installing at least one spring on the tubular shaft, wherein said at least one spring covers substantially all of the second portion of the exterior surface;installing a torquable member on the tubular shaft proximate to the upper end; andtightening the torquable member, thereby providing a compressive axial load on said at least one rotating component and said at least one spring, wherein the compressive axial load creates frictional forces between said at least one rotating component and said at least one spring greater than a maximum torque expected to act on the tubular shaft, such that said at least one rotating component remains stationary with respect to the tubular shaft during drilling operations, and such that said at least one rotating component rotates concurrent with the rotation of the tubular shaft during drilling operations, thereby reducing wear on the tubular shaft, said at least one rotating component, said at least one spring, or combinations thereof. 16. The method of claim 15, wherein the spring comprises a wave spring, a belleville spring, or combinations thereof. 17. A system for securing components along a rotatable shaft, the system comprising: a rotatable shaft having an exterior surface, a first end, a second end, and a shoulder disposed proximate to the first end, wherein the rotatable shaft is adapted to rotate;an adjustable member secured to the rotatable shaft proximate to the second end;at least one rotating component comprising a thrust bearing, a radial bearing, or combinations thereof, installed along the rotatable shaft between the shoulder and the adjustable member, wherein said at least one rotating component covers a first portion of the exterior surface while leaving a second portion of the exterior surface uncovered; andat least one spacing member disposed between the shoulder and the adjustable member, wherein said at least one spacing member covers substantially all of the second portion of the exterior surface,wherein the adjustable member applies an axial force toward the shoulder, and wherein the shoulder applies a counter axial force toward the adjustable member to create a compressive axial load on said at least one rotating component and said at least one spacing member, wherein the compressive axial load creates frictional forces between said at least one rotating component and said at least one spacing member greater than a maximum torque expected to act on the rotatable shaft, such that said at least one rotating component remains stationary with respect to the rotatable shaft during rotation thereof. 18. The system of claim 17, wherein said at least one rotating component is maintained in a stationary orientation with respect to the tubular shaft during drilling operations due solely to the compressive axial load.
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