Emergency shutdown system for dynamic and high integrity operations
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G05B-019/042
G05B-011/01
G06F-021/30
G05B-009/02
G05B-023/02
출원번호
US-0259248
(2016-09-08)
등록번호
US-10234840
(2019-03-19)
발명자
/ 주소
Daraiseh, Abdelghani
Flanders, Patrick S.
출원인 / 주소
Saudi Arabian Oil Company
대리인 / 주소
Bracewell LLP
인용정보
피인용 횟수 :
0인용 특허 :
15
초록▼
Provided in some embodiments are systems and methods for emergency shutdown (ESD) systems. Embodiments provide for receiving, from a central logic solver (CLS) of an emergency shutdown (ESD) system for a plant via a first communication channel, a command indicative of a first state for an ESD valve,
Provided in some embodiments are systems and methods for emergency shutdown (ESD) systems. Embodiments provide for receiving, from a central logic solver (CLS) of an emergency shutdown (ESD) system for a plant via a first communication channel, a command indicative of a first state for an ESD valve, in response to receiving the command, controlling the ESD valve to operate in the first state, obtaining, from a central status monitor (CSM) of the ESD system via a second communication channel, current status information for the plant, determining a second state for the ESD valve based at least in part on the current status information obtained from the CSM, and controlling the ESD valve to operate in the second state.
대표청구항▼
1. An emergency shutdown (ESD) system for a plant, comprising: a central control system comprising: a central logic solver (CLS) comprising a first communication interface coupled to a first communication channel for communicating with each of a plurality of emergency shutdown (ESD) valves of the ES
1. An emergency shutdown (ESD) system for a plant, comprising: a central control system comprising: a central logic solver (CLS) comprising a first communication interface coupled to a first communication channel for communicating with each of a plurality of emergency shutdown (ESD) valves of the ESD system, wherein the CLS is configured to, for each of the ESD valves: determine a desired state for the ESD valve based on status information for the plant; andissue a command configured to cause the ESD valve to operate in the desired state, wherein the command is communicated to the ESD valve via the first communication interface and the first communication channel;a central status monitor (CSM) comprising a second communication interface coupled to a second communication channel for communicating with each of the ESD valves, wherein the CSM is configured to: maintain a current listing of current status information for the plant; andin response to determining that the CLS is unable to communicate with an ESD valve via the first communication channel, provide, to the ESD valve via the second communication interface and the second communication channel, at least a portion of the current status information for the plant for use in determining an appropriate state for the ESD valve; andthe ESD valves, wherein each of the ESD valves comprises: a valve mechanism configured to regulate the flow of a medium through a pipe;an actuation system configured to move the valve mechanism between different operational states;a communication interface coupled to the first and second communication channels; anda local controller configured to: in response to determining that the first communication channel is unavailable: obtain, from the CSM, current status information for the plant;determine an appropriate state for the ESD valve based at least in part on the current status information obtained from the CSM; andcontrol the actuation system to move the valve mechanism to a position corresponding to the appropriate state; andin response to receiving a command from the CLS specifying a desired state for the ESD valve, control the actuation system to move the valve mechanism to the desired state. 2. The system of claim 1, wherein the first communication channel is different from the second communication channel. 3. The system of claim 1, wherein the first communication channel comprises a wired connection between the CLS and the ESD valves, and wherein the second communication channel comprises a wireless connection between the CSM and the ESD valves. 4. The system of claim 1, wherein the first communication channel comprises a wired connection between the CLS and the ESD valves, and wherein the second communication channel comprises a wired connection between the CSM and the ESD valves. 5. The system of claim 1, wherein each of the ESD valves comprises a local power supply system configured to provide power for operating the valve mechanism. 6. The system of claim 1, further comprising: a central power supply system configured to provide operational power to each of the ESD valves,wherein each of the ESD valves comprises: a local power supply system; anda valve power interface configured to selectively route power from the central power supply system and the local power supply system for use in powering components of the ESD valve. 7. The system of claim 6, wherein the valve power interface is configured to: determine whether power for powering the components of the ESD valve is available from the central power supply system; andin response to determining that power for powering the components of the ESD valve is not available from the central power supply system, route power from the local power supply system for use in powering the components of the ESD valve. 8. The system of claim 1, further comprising: an instrument system comprising one or more instruments configured to obtain values for one or more process variables, wherein the instrument system comprises a third communication interface coupled to a third communication channel for communicating the values for one or more process variables to at least one of the plurality of emergency shutdown (ESD) valves; andwherein the local controller of each of the at least one ESD valves is configured to determine an appropriate state for the ESD valve based at least in part on the values for one or more process variables obtained from the instrument system. 9. The system of claim 1, wherein the local controller is configured to: receive an authorization code and a request to operate the valve in a given state;in response to determining that the authorization code is valid, control the actuation system to move the valve mechanism to the given state; andin response to determining that the authorization code is not valid, not control the actuation system to move the valve mechanism to the given state. 10. The system of claim 1, wherein the local controller is configured to: conduct a self-test operation;generate a report indicative of results of the self-test operation; andin response to determining that the ESD valve failed the self-test operation, generate an alert indicating that the ESD valve failed the self-test operation. 11. The system of claim 1, wherein the different operational states comprise at least a first fail-safe state and a second fail-safe state. 12. The system of claim 1, wherein the CSM is configured to determine a fail-safe state for the ESD valve based on the status information for the plant, wherein the current status information for the plant comprises the fail-safe state for the ESD valve, wherein determining an appropriate state for the ESD valve based at least in part on the current status information obtained from the CSM comprises determining the fail-safe state for the ESD valve based at least in part on the current status information obtained from the CSM, and wherein controlling the actuation system to move the valve mechanism to a position corresponding to the appropriate state comprises controlling the actuation system to move the valve mechanism to the fail-safe state. 13. A method comprising: receiving, by a local controller of an emergency shutdown (ESD) valve from a central logic solver (CLS) of an ESD system via a first communication channel, a command indicative of a first state for an ESD valve;controlling, by the local controller in response to the local controller receiving the command, the ESD valve to operate in the first state;obtaining, by the local controller from a central status monitor (CSM) of the ESD system via a second communication channel, current status information for the plant;determining, by the local controller, a second state for the ESD valve based at least in part on the current status information obtained from the CSM; andcontrolling, by the local controller, the ESD valve to operate in the second state. 14. The method of claim 13, wherein the first communication channel is different from the second communication channel. 15. The method of claim 14, wherein the first communication channel comprises a wired connection, and wherein the second communication channel comprises a wireless connection. 16. The method of claim 13, further comprising: determining whether power for powering components of the ESD valve is available from a central power supply system configured to provide operational power to the ESD valve; andin response to determining that power for powering the components of the ESD valve is not available from the central power supply system, route power from a local power supply system of the ESD valve for use in powering the components of the ESD valve. 17. The method of claim 13, wherein determining a second state for the ESD valve is based at least in part on values for one or more process variables obtained from an instrument system via a third communication channel. 18. The method of claim 13, further comprising: receiving an authorization code and a request to operate the valve in a given state; andin response to determining that the authorization code is valid, controlling the ESD valve to operate in the given state. 19. The method of claim 13, further comprising: determining, by the CLS, the desired state for the ESD valve based on status information for the plant; andissuing, by the CLS, the command indicative of a first state for an ESD valve via the first communication channel. 20. The method of claim 19, further comprising: maintaining, by the CSM, a current listing of current status information for the plant; andin response to determining that the CLS is unable to communicate with the ESD valve via the first communication channel, providing, to the ESD valve, the current status information for the plant. 21. The method of claim 13, wherein the ESD valve comprises: a valve mechanism configured to regulate the flow of a medium through a pipe; andan actuation system configured to move the valve mechanism between different operational states, andwherein controlling the ESD valve to operate in a given state comprises controlling the actuation system to move the valve mechanism to a position corresponding to the given state. 22. The method of claim 13, wherein the first state comprises a first fail-safe state and the second state comprises a second fail-safe state. 23. A non-transitory computer readable storage medium comprising program instructions executable by a computer processor to cause: receiving, by a local controller of an emergency shutdown (ESD) valve from a central logic solver (CLS) of an ESD system via a first communication channel, a command indicative of a first state for an ESD valve;controlling, by the local controller in response to the local controller receiving the command, the ESD valve to operate in the first state;obtaining, by the local controller from central status monitor (CSM) of the ESD system via a second communication channel, current status information for the plant;determining, by the local controller, a second state for the ESD valve based at least in part on the current status information obtained from the CSM; andcontrolling, by the local controller, the ESD valve to operate in the second state. 24. The medium of claim 23, wherein the first communication channel is different from the second communication channel. 25. The medium of claim 24, wherein the first communication channel comprises a wired connection, and wherein the second communication channel comprises a wireless connection. 26. The medium of claim 23, the instructions further executable by the computer processor to cause: determining whether power for powering components of the ESD valve is available from a central power supply system configured to provide operational power to the ESD valve; andin response to determining that power for powering the components of the ESD valve is not available from the central power supply system, route power from a local power supply system of the ESD valve for use in powering the components of the ESD valve. 27. The medium of claim 23, wherein determining a second state for the ESD valve is based at least in part on values for one or more process variables obtained from an instrument system via a third communication channel. 28. The medium of claim 23, the instructions further executable by the computer processor to cause: receiving an authorization code and a request to operate the valve in a given state; andin response to determining that the authorization code is valid, controlling the ESD valve to operate in the given state. 29. The medium of claim 23, the instructions further executable by the computer processor to cause: determining, by the CLS, the desired state for the ESD valve based on status information for the plant; andissuing, by the CLS, the command indicative of a first state for an ESD valve via the first communication channel. 30. The medium of claim 29, the instructions further executable by the computer processor to cause: maintaining, by the CSM, a current listing of current status information for the plant; andin response to determining that the CLS is unable to communicate with the ESD valve via the first communication channel, providing, to the ESD valve, the current status information for the plant. 31. The medium of claim 23, wherein the ESD valve comprises: a valve mechanism configured to regulate the flow of a medium through a pipe; andan actuation system configured to move the valve mechanism between different operational states, andwherein controlling the ESD valve to operate in a given state comprises controlling the actuation system to move the valve mechanism to a position corresponding to the given state.
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