Method and system for process control network migration
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G06F-015/16
G06F-011/16
G06F-011/20
출원번호
US-0942177
(2010-11-09)
등록번호
US-8924498
(2014-12-30)
발명자
/ 주소
McLaughlin, Paul F.
출원인 / 주소
Honeywell International Inc.
인용정보
피인용 횟수 :
1인용 특허 :
35
초록▼
A method includes disconnecting a first component from a first network. The first component is redundant to a second component and operates in a secondary or passive redundancy mode. The second component operates in a primary or active redundancy mode and is coupled to the first network. The method
A method includes disconnecting a first component from a first network. The first component is redundant to a second component and operates in a secondary or passive redundancy mode. The second component operates in a primary or active redundancy mode and is coupled to the first network. The method also includes updating at least one of hardware and software on the first component to allow the first component to communicate on a second network. The method further includes connecting the updated first component to the second network and synchronizing data between the updated first component on the second network and the second component on the first network. In addition, the method includes switching the updated first component from the secondary redundancy mode to the primary redundancy mode.
대표청구항▼
1. A method comprising: physically disconnecting a first component from a first network, the first component redundant to a second component, the first component operating in a secondary redundancy mode, the second component operating in a primary redundancy mode, the second component coupled to the
1. A method comprising: physically disconnecting a first component from a first network, the first component redundant to a second component, the first component operating in a secondary redundancy mode, the second component operating in a primary redundancy mode, the second component coupled to the first network;updating at least one of hardware and software on the first component to allow the first component to communicate on a second network, the second network utilizing a different protocol than the first network;physically connecting the updated first component to the second network;synchronizing data between the updated first component on the second network and the second component on the first network;switching the updated first component from the secondary redundancy mode to the primary redundancy mode; andswitching the second component on the first network from the primary redundancy mode to the secondary redundancy mode;wherein: the first and second components comprise controllers in a continuous distributed control system;control commands are continuously sent from or through at least one of the controllers to a process element in the continuous distributed control system during the disconnecting, updating, connecting, and synchronizing;the second component on the first network is configured to switch back to the primary redundancy mode;communications to or from the process element are sent through the second network when the updated first component is in the primary redundancy mode; andcommunications to or from the process element are sent through the first network when the second component is in the primary redundancy mode. 2. The method of claim 1, further comprising: disconnecting the second component from the first network;updating at least one of hardware and software on the second component to allow the second component to communicate on the second network;connecting the updated second component to the second network; andsynchronizing data between the updated first component on the second network and the updated second component on the second network. 3. The method of claim 1, wherein: the first network is an IEEE 802.4-based network or a ControlNet-based network; andthe second network is an IEEE 802.3-based network. 4. A method comprising: physically disconnecting a first component from a first network, the first component redundant to a second component, the first component operating in a secondary redundancy mode, the second component operating in a primary redundancy mode, the second component coupled to the first network;updating at least one of hardware and software on the first component to allow the first component to communicate on a second network, the second network utilizing a different protocol than the first network;physically connecting the the updating first component to the second network;synchronizing data between the updated first component on the second network and the second component on the first network;switching the updated first component from the secondary redundancy mode to the primary redundancy mode;disconnecting a first network interface module (NIM) node or a first server from the first network, the first NIM node or the first server redundant to a second NIM node or a second server, the first NIM node or the first server operating in the secondary redundancy mode, the second NIM node or the second server operating in the primary redundancy mode, the second NIM node or the second server coupled to the first network;updating at least one of hardware and software on the first NIM node or the first server to allow the first NIM node or the first server to communicate on the second network;connecting the updated first NIM node or the updated first server to the second network;placing the updated first NIM node or the updated first server in the primary redundancy mode while the second NIM node or the second server is also in the primary redundancy mode; andallowing an operator station to view network components on the second network through the updated first NIM node or the updated first server and network components on the first network through the second NIM node or the second server. 5. The method of claim 4, further comprising: disconnecting the second NIM node or the second server from the first network;updating at least one of hardware and software on the second NIM node or the second server to allow the second NIM node or the second server to communicate on the second network;connecting the updated second NIM node or the updated second server to the second network;synchronizing data between the updated first NIM node or the updated first server and the updated second NIM node or the updated second server; andswitching at least one of the updated NIM nodes or the updated servers from the primary redundancy mode to the secondary redundancy mode. 6. The method of claim 5, wherein disconnecting the second NIM node or the second server from the first network occurs after all network components on the first network viewable through the second NIM node or the second server have been moved to the second network. 7. A method comprising: physically disconnecting a first component from a first network, the first component redundant to a second component, the first component operating in a secondary redundancy mode, the second component operating in a primary redundancy mode, the second component coupled to the first network;replacing the first component with an updated first component, the updated first component configured to communicate on a second network, the second network utilizing a different protocol than the first network;physically connecting the updated first component to the second network;synchronizing data between the updated first component on the second network and the second component on the first network;switching the updated first component from the secondary redundancy mode to the primary redundancy mode; andswitching the second component on the first network from the primary redundancy mode to the secondary redundancy mode;wherein: the first and second components comprise controllers in a continuous distributed control system;control commands are continuously sent from or through at least one of the controllers to a process element in the continuous distributed control system during the disconnecting, updating connecting, and synchronizing;the second component on the first network is configured to switch back to the primary redundancy mode;communications to or from the process element are sent through the second network when the updated first component is in the primary mode; andcommunications to or from the process element are sent through the first network when the second component is in the primary redundancy mode. 8. The method of claim 7, further comprising: disconnecting the second component from the first network;replacing the second component with an updated second component, the updated second component configured to communicate on the second network;connecting the updated second component to the second network; andsynchronizing data between the updated first component on the second network and the updated second component on the second network. 9. The method of claim 7, wherein: the first network is an IEEE 802.4-based network or a ControlNet-based network; andthe second network is an IEEE 802.3-based network. 10. A method comprising: physically disconnecting a first component from a first network, the first component redundant to a second component, the first component operating in a secondary redundancy mode, the second component operating in a primary redundancy mode, the second component coupled to the first network;replacing the first component with an updated first component, the updated first component configured to communicate on a second network, the second network utilizing a different protocol than the first network;physically connecting the updated first component to the second network;synchronizing data between the updated first component on the second network and the second component on the first network;switching the updated first component from the secondary redundancy mode to the primary redundancy mode;disconnecting a first network interface module (NIM) node or a first server from the first network, the first NIM node or the first server redundant to a second NIM node or a second server, the first NIM node or the first server operating in the secondary redundancy mode, the second NIM node or the second server operating in the primary redundancy mode, the second NIM node or the second server coupled to the first network;replacing the first NIM node or the first server with an updated first NIM node or updated first server, the updated first NIM node or updated first server configured to communicate on the second network;connecting the updated first NIM node or the updated first server to the second network;placing the updated first NIM node or the updated first server in the primary redundancy mode while the second NIM node or the second server is also in the primary redundancy mode; andallowing an operator station to view network components on the second network through the updated first NIM node or the updated first server and network components on the first network through the second NIM node or the second server. 11. The method of claim 10, further comprising: disconnecting the second NIM node or the second server from the first network;replacing the second NIM node or the second server with an updated second NIM node or an updated second server, the updated second NIM node or the updated second server configured to communicate on the second network;connecting the updated second NIM node or the updated second server to the second network;synchronizing data between the updated first NIM node or the updated first server and the updated second NIM node or the updated second server; andswitching at least one of the updated NIM nodes or the updated servers from the primary redundancy mode to the secondary redundancy mode. 12. The method of claim 11, wherein disconnecting the second NIM node or the second server from the first network occurs after all network components on the first network viewable through the second NIM node or the second server have been moved to the second network. 13. The method of claim 1, further comprising: placing redundant network interface module (NIM) nodes or redundant servers in a dual primary mode;wherein: the NIM nodes or servers are in communication with both the first and second components on the first network while in a redundancy mode; andthe NIM nodes or servers simultaneously provide a path of communication to the first component through the second network and to the second component through the first network while in the dual primary mode. 14. A method comprising: physically disconnecting a first component from a first network, the first component redundant to a second component, the first component operating in a secondary redundancy mode, the second component operating in a primary redundancy mode, the second component coupled to the first network;updating at least one of hardware and software on the first component to allow the first component to communicate on a second network, the second network utilizing a different protocol than the first network;physically connectintg updated first component to the second network;synchronizing data between the updated first component on the second network and the second component on the first network;switching the updated first component from the secondary redundancy mode to the primary redundancy mode;placing redundant network interface module (NIM) nodes or redundant servers in a dual primary mode, wherein: the NIM nodes or servers are in communication with both the first and second components on the first network while in a redundancy mode; andthe NIM nodes or servers simultaneously provide a path of communication to the first component through the second network and to the second component through the first network while in the dual primary mode; andleaving the second component on the first network for a period of time during the simultaneously provided path from the NIM nodes or servers to determine whether an error occurs with the first component on the second network. 15. A method comprising: physically disconnecting a first component from a first network, the first component redundant to a second component, the first component operating in a secondary redundancy mode, the second component operating in a primary redundancy mode, the second component coupled to the first network;updating at least one of hardware and software on the first component to allow the first component to communicate on a second network, the second network utilizing a different protocol than the first network;physically connecting the updated first component to the second network;synchronizing data between the updated first component on the second network and the second component on the first network;switching the updated first component from the secondary redundancy mode to the primary redundancy mode; andplacing redundant network interface module (NIM) nodes or redundant servers in a dual primary mode, wherein: the NIM nodes or servers are in communication with both the first and second components on the first network while in a redundancy mode; andthe NIM nodes or servers simultaneously provide a path of communication to the first component through the second network and to the second component through the first network while in the dual primary mode; andwherein the synchronizing occurs through a communication path other than the second network and the first network. 16. The method of claim 1, wherein the synchronizing occurs through a communication path other than the second network and the first network. 17. The method of claim 4, wherein the synchronizing occurs through a communication path other than the second network and the first network. 18. The method of claim 7, wherein the synchronizing occurs through a communication path other than the second network and the first network. 19. The method of claim 10, wherein the synchronizing occurs through a communication path other than the second network and the first network. 20. The method of claim 14, wherein the synchronizing occurs through a communication path other than the second network and the first network.
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