Hydraulic re-configurable and subsea repairable control system for deepwater blow-out preventers
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
E21B-033/038
E21B-043/013
E21B-033/035
E21B-033/06
E21B-034/16
출원번호
US-0938599
(2015-11-11)
등록번호
US-9828824
(2017-11-28)
발명자
/ 주소
McAuley, Alexander Michael
Nolan, James Matthew
Kindt, David Samuel
Stewart, Zachary William
출원인 / 주소
Hydril USA Distribution, LLC
대리인 / 주소
Hogan Lovells US LLP
인용정보
피인용 횟수 :
0인용 특허 :
67
초록▼
Blowout preventer (BOP) systems and methods for providing additional redundancy and reliability are provided. A BOP system for providing additional redundancy can include a first set of components including a BOP control pod with a primary regulator and a secondary regulator, where the primary regul
Blowout preventer (BOP) systems and methods for providing additional redundancy and reliability are provided. A BOP system for providing additional redundancy can include a first set of components including a BOP control pod with a primary regulator and a secondary regulator, where the primary regulator and the secondary regulator are arranged in a parallel configuration; a hydraulic supply line in communication with the BOP control pod; a pod select valve in communication with the primary regulator and the secondary regulator; and a bypassable hydraulic regulator in communication with the pod select valve; and a second set of components, the bypassable hydraulic regulator disposed between the pod select valve and the second set of components, where a hydraulic regulator bypass line bypasses the bypassable hydraulic regulator between the pod select valve and the second set of components.
대표청구항▼
1. A blowout preventer (BOP) system for providing additional system redundancy in the case of reduced component functionality, the system comprising: a first set of components comprising: at least two BOP control pods, wherein at least one of the at least two BOP control pods comprises a primary reg
1. A blowout preventer (BOP) system for providing additional system redundancy in the case of reduced component functionality, the system comprising: a first set of components comprising: at least two BOP control pods, wherein at least one of the at least two BOP control pods comprises a primary regulator and a secondary regulator, wherein the primary regulator and the secondary regulator are arranged in a parallel configuration;a hydraulic supply line in communication with at least one of the at least two BOP control pods;a pod select valve in communication with the primary regulator and the secondary regulator; anda bypassable hydraulic regulator in communication with the pod select valve; anda second set of components, the bypassable hydraulic regulator disposed between the pod select valve and the second set of components, wherein a hydraulic regulator bypass line bypasses the bypassable hydraulic regulator between the pod select valve and the second set of components. 2. The BOP system of claim 1, further comprising: an alternative BOP control pod, the alternative BOP control pod comprising an alternative primary regulator and an alternative secondary regulator, wherein the alternative primary regulator and the alternative secondary regulator are arranged in a parallel configuration;an alternative hydraulic supply line, in communication with the alternative BOP control pod;an alternative pod select valve, in communication with the alternative primary regulator and the alternative secondary regulator of the alternative BOP control pod; andan alternative bypassable hydraulic regulator, in communication with the alternative pod select valve,wherein the alternative bypassable hydraulic regulator is disposed between the alternative pod select valve and an alternative set of the second set of components, and wherein an alternative hydraulic regulator bypass line bypasses the alternative bypassable hydraulic regulator between the alternative pod select valve and the alternative set of the second set of components. 3. The BOP system of claim 1, wherein the second set of components further comprises: a primary hydraulic manifold comprising a valve, the primary hydraulic manifold in communication with BOP stack shuttles to perform at least one function;a spare, re-assignable hydraulic manifold comprising a valve wherein the spare, re-assignable hydraulic manifold is operable to perform a function of the primary hydraulic manifold; andan isolation valve, wherein the isolation valve is operable to prevent flow from the hydraulic supply line to the primary hydraulic manifold and direct the flow from the hydraulic supply line to the spare, re-assignable hydraulic manifold. 4. The BOP system of claim 2, wherein the alternative set of the second set of components further comprises: a primary hydraulic manifold comprising a valve, the primary hydraulic manifold in communication with BOP stack shuttles to perform at least one function;a spare, re-assignable hydraulic manifold comprising a valve wherein the spare, re-assignable hydraulic manifold is operable to perform a function of the primary hydraulic manifold; andan isolation valve, wherein the isolation valve is operable to prevent flow from the alternative hydraulic supply line to the primary hydraulic manifold and direct the flow from the alternative hydraulic supply line to the spare, re-assignable hydraulic manifold. 5. The BOP system of claim 1, wherein the second set of components further comprises: a primary hydraulic manifold comprising a valve, the primary hydraulic manifold in communication with BOP stack shuttles to perform at least one function;a spare, re-assignable hydraulic manifold comprising a valve wherein the spare, re-assignable hydraulic manifold is operable to perform a function of the primary hydraulic manifold; anda flexible connection disposed between the spare, re-assignable hydraulic manifold and the BOP stack shuttles. 6. The BOP system of claim 2, wherein the alternative set of the second set of components further comprises: a primary hydraulic manifold comprising a valve, the primary hydraulic manifold being in communication with BOP stack shuttles to perform at least one function;a spare, re-assignable hydraulic manifold comprising a valve wherein the spare, re-assignable hydraulic manifold is operable to perform a function of the primary hydraulic manifold; anda flexible connection disposed between the spare, re-assignable hydraulic manifold and the BOP stack shuttles. 7. The BOP system of claim 5, wherein the flexible connection is connected between the spare, re-assignable hydraulic manifold and the BOP stack shuttles at remotely operated vehicle (ROV) stabs. 8. The BOP system of claim 5, wherein the spare, re-assignable hydraulic manifold is supplied with hydraulic fluid from an alternative source selected form the group consisting of: an accumulator and a hot-line hose. 9. The BOP system of claim 5, wherein the spare, re-assignable hydraulic manifold is hard-piped to ROV stabs through a selection valve. 10. The BOP system of claim 6, wherein the flexible connection is connected between the spare, re-assignable hydraulic manifold and the BOP stack shuttles at ROV stabs. 11. A blowout preventer (BOP) system for providing additional redundancy in the case of reduced component functionality, the system comprising: a first BOP control pod and a second BOP control pod, the first and second BOP control pods each comprising at least two redundant manual regulators in a parallel configuration;a hydraulic supply line, in communication with the first and second BOP control pods;a first bypassable hydraulic regulator in communication with the first BOP control pod and a second bypassable hydraulic regulator in communication with second BOP control pod;a primary hydraulic manifold comprising a valve, the primary hydraulic manifold in communication with BOP stack shuttles to perform at least one function;a spare, re-assignable hydraulic manifold comprising a valve wherein the spare, re-assignable hydraulic manifold is operable to perform a function of the primary hydraulic manifold; andan isolation valve, wherein the isolation valve is operable to prevent flow from the hydraulic supply line to the primary hydraulic manifold and direct the flow from the hydraulic supply line to the spare, re-assignable hydraulic manifold. 12. A method for increasing mean time between failures (MTBF) of a BOP system comprising at least two BOP control pods, the method comprising the steps of: supplying hydraulic fluid by a hydraulic supply line to components of the BOP system through a primary regulator of at least one of the at least two BOP control pods;isolating the primary regulator when the primary regulator has reduced functionality; andredirecting hydraulic fluid through a secondary regulator of the at least one of the at least two BOP control pods, wherein the primary regulator and secondary regulator are arranged in a parallel configuration within the at least one of the at least two BOP control pods. 13. The method of claim 12, further comprising the step of: supplying hydraulic fluid to a set of components of the BOP system through a hydraulic regulator bypass line when a hydraulic regulator fails. 14. The method of claim 12, further comprising the steps of: utilizing a primary hydraulic manifold comprising a valve, wherein the primary hydraulic manifold is in communication with BOP stack shuttles to perform at least one function; andincreasing redundancy in the BOP system with a spare, re-assignable hydraulic manifold comprising a valve wherein the spare, re-assignable hydraulic manifold is operable to perform a function of the primary hydraulic manifold. 15. The method of claim 12, further comprising the steps of: utilizing a primary hydraulic manifold comprising a valve, wherein the primary hydraulic manifold is in communication with BOP stack shuttles to perform at least one function;increasing redundancy in the BOP system with a spare, re-assignable hydraulic manifold comprising a valve wherein the spare, re-assignable hydraulic manifold is operable to perform a function of the primary hydraulic manifold; andconnecting a flexible connection between the spare, re-assignable hydraulic manifold and the BOP stack shuttles. 16. The method of claim 15, further comprising the step of connecting the flexible connection between the spare, re-assignable hydraulic manifold and the BOP stack shuttles at ROV stabs. 17. The method of claim 15, further comprising the step of supplying the spare, re-assignable hydraulic manifold fluid from an alternative source selected from the group consisting of: an accumulator and a hot-line hose. 18. The method of claim 15, wherein the spare, re-assignable hydraulic manifold is hard-piped to ROV stabs through a selection valve. 19. The method of claim 12, further comprising the step of reassigning functions of a primary hydraulic manifold to a spare, re-assignable hydraulic manifold. 20. The method of claim 14, further comprising the step of reassigning functions of the primary hydraulic manifold to the spare, re-assignable hydraulic manifold.
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