Distributed control system

US 6,968,905 B2
Filed: 03/18/2003
Issued: 11/29/2005
Est. Priority Date: 03/18/2003
Status: Active Grant

First Claim

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1. A method for distributed control of a coiled tubing unit comprising:

operating an input device at a control station to transmit control signals from the control station across a non-real-time network to a local control panel (LCP);

converting and transmitting the control signals from the control station across a real-time network to at least one distributed control unit (DCU);

transmitting the control signals from the at least one DCU to the at least one piece of coiled tubing unit equipment;

sensing sensor data from at least one piece of coiled tubing unit equipment and transmitting the sensor data across the real-time network from at least one DCU to the LCP;

converting and transmitting the sensor data from the LCP across a non-real-time network to at least one output device at the control station;

wherein the LCP bridges communication between the non-real-time network and the real-time network; and

wherein the at least one DCU comprises a power pack DCU, coiled tubing reel DCU, and an injector head/BOP DCU, the method further comprising;

sensing a non-real-time network signal failure; and

transmitting control signals to one or more of the power pack DCU, the coiled tubing reel DCU, and the injector head/BOP DCU when the non-real-time network signal failure is sensed.

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Abstract

A distributed control system for local or remote control of equipment. The distributed control system provides a communication bridge through a local control panel between a non-real-time network, and a real-time network, such as a controller area network. Both soft real-time and hard real-time networks are suitable, but hard real-time is preferred. Multiple distributed control units are used to control various equipment components. The distributed control system may be applied in any environment. The distributed control system may be applied to a skid-mounted coiled tubing unit.

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21 Claims

1. A method for distributed control of a coiled tubing unit comprising:
- operating an input device at a control station to transmit control signals from the control station across a non-real-time network to a local control panel (LCP);
  
  converting and transmitting the control signals from the control station across a real-time network to at least one distributed control unit (DCU);
  
  transmitting the control signals from the at least one DCU to the at least one piece of coiled tubing unit equipment;
  
  sensing sensor data from at least one piece of coiled tubing unit equipment and transmitting the sensor data across the real-time network from at least one DCU to the LCP;
  
  converting and transmitting the sensor data from the LCP across a non-real-time network to at least one output device at the control station;
  
  wherein the LCP bridges communication between the non-real-time network and the real-time network; and
  
  wherein the at least one DCU comprises a power pack DCU, coiled tubing reel DCU, and an injector head/BOP DCU, the method further comprising;
  
  sensing a non-real-time network signal failure; and
  
  transmitting control signals to one or more of the power pack DCU, the coiled tubing reel DCU, and the injector head/BOP DCU when the non-real-time network signal failure is sensed.

2. A method for distributed control of a coiled tubing unit comprising:
- operating an input device at a control station to transmit control signals from the control station across a non-real-time network to a local control panel (LCP);
  
  converting and transmitting the control signals from the control station across a real-time network to at least one distributed control unit (DCU);
  
  transmitting the control signals from the at least one DCU to the at least one piece of coiled tubing unit equipment;
  
  sensing sensor data from at least one piece of coiled tubing unit equipment and transmitting the sensor data across the real-time network from at least one DCU to the LCP;
  
  converting and transmitting the sensor data from the LCP across a non-real-time network to at least one output device at the control station;
  
  wherein the LCP bridges communication between the non-real-time network and the real-time network; and
  
  wherein the at least one DCU comprises a power pack DCU, coiled tubing reel DCU, and an injector head/BOP DCU, the method further comprising;
  
  sensing a non-real-time network signal failure; and
  
  transmitting control signals to one or more of the power pack DCU, the coiled tubing reel DCU, and the injector head/BOP DCU when the non-real-time network signal failure is sensed.

3. A method for distributed control of a coiled tubing unit comprising:
- operating an input device at a control station to transmit control signals from the control station across a non-real-time network to a local control panel (LCP);
  
  converting and transmitting the control signals from the control station across a real-time network to at least one distributed control unit (DCU);
  
  transmitting the control signals from the at least one DCU to the at least one piece of coiled tubing unit equipment;
  
  sensing sensor data from at least one piece of coiled tubing unit equipment and transmitting the sensor data across the real-time network from at least one DCU to the LCP;
  
  converting and transmitting the sensor data from the LCP across a non-real-time network to at least one output device at the control station;
  
  wherein the LCP bridges communication between the non-real-time network and the real-time network; and
  
  wherein the at least one DCU comprises a power pack DCU, a coiled tubing reel DCU, and an injector head/BOP DCU, the method further comprising;
  
  sensing a non-real-time network signal failure; and
  
  transmitting control signals to one or more of the power pack DCU, the coiled tubing reel DCU, and the injector head/BOP DCU when the sensor data signal failure is sensed.

4. A method for distributed control of a coiled tubing unit comprising:
- operating an input device at a control station to transmit control signals from the control station across a non-real-time network to a local control panel (LCP);
  
  converting and transmitting the control signals from the control station across a real-time network to at least one distributed control unit (DCU);
  
  transmitting the control signals from the at least one DCU to the at least one piece of coiled tubing unit equipment;
  
  sensing sensor data from at least one piece of coiled tubing unit equipment and transmitting the sensor data across the real-time network from at least one DCU to the LCP;
  
  converting and transmitting the sensor data from the LCP across a non-real-time network to at least one output device at the control station;
  
  wherein the LCP bridges communication between the non-real-time network and the real-time network; and
  
  wherein the coiled tubing unit comprises a power pack to supply power to other components of the coiled tubing unit, a coiled tubing reel, an injector head, a stripper, and a BOP, and wherein the at least one DCU comprises a power pack DCU, a coiled tubing reel DCU, and an injector head/BOP DCU, the method further comprising;
  
  converting and transmitting the control signals from the control station across a real-time network to one or more of the power pack DCU to control the operation of the power pack, the coiled tubing eel DCU to control operation of the injector head, the stripper, and the BOP; and
  
  sensing sensor data and transmitting the sensor data across the real-time network from one or more of the power pack DCU, the coiled tubing reel DCU, and the injector head/BOP DCU to the LCP.

5. A method for distributed control of a coiled tubing unit comprising:
- operating an input device at a control station to transmit control signals from the control station across a non-real-time network to a local control panel (LCP);
  
  converting and transmitting the control signals from the control station across a real-time network to at least one distributed control unit (DCU);
  
  transmitting the control signals from the at least one DCU to the at least one piece of coiled tubing unit equipment;
  
  sensing sensor data from at least one piece of coiled tubing unit equipment and transmitting the sensor data across the real-time network from at least one DCU to the LCP;
  
  converting and transmitting the sensor data from the LCP across a non-real-time network to at least one output device at the control station;
  
  wherein the LCP bridges communication between the non-real-time network and the real-time network; and
  
  wherein the at least one DCU comprises a power pack DCU, a coiled tubing reel DCU, and an injector head/BOP DCU, the method further comprising;
  
  transmitting and sharing the sensor data among one or more of the power pack DCU, the coiled tubing reel DCU, the injector head/BOP DCU, and the LCP; and
  
  calculating fail-safe parameters and comparing against a pre-loaded operating envelope and automatically transmitting control signals from one or more of the power pack DCU, the coiled tubing reel DCU, and the injector head/BOP DCU when the pre-loaded operating envelope is violated.

6. A method for distributed control of a coiled tubing unit comprising:
- operating an input device at a control station to transmit control signals from the control station across a non-real-time network to a local control panel (LCP);
  
  converting and transmitting the control signals from the control station across a real-time network to at least one distributed control unit (DCU);
  
  transmitting the control signals from the at least one DCU to the at least one piece of coiled tubing unit equipment;
  
  sensing sensor data from at least one piece of coiled tubing unit equipment and transmitting the sensor data across the real-time network from at least one DCU to the LCP;
  
  converting and transmitting the sensor data from the LCP across a non-real-time network to at least one output device at the control station;
  
  wherein the LCP bridges communication between the non-real-time network and the real-time network; and
  
  wherein the at least one DCU comprises a power pack DCU, a coiled tubing reel DCU, and an injector head/BOP DCU, the method further comprising;
  
  transmitting and sharing the sensor data among one or more of the power pack DCU, the coiled tubing reel DCU, the injector head/BOP DCU, and LCP; and
  
  calculating fail-safe parameters and comparing against a pre-loaded operating envelope and automatically transmitting control signals from one or more of the power pack DCU, the coiled tubing reel DCU, and the injector head/BOP DCU, to other DCU'"'"'s on the real-time network and the LCP when the pre-loaded operating envelope is violated.

7. A method for distributed control of a coiled tubing unit comprising:
- operating an input device at a control station to transmit control signals from the control station across a non-real-time network to a local control panel (LCP);
  
  converting and transmitting the control signals from the control station across a real-time network to at least one distributed control unit (DCU);
  
  transmitting the control signals from the at least one DCU to the at least one piece of coiled tubing unit equipment;
  
  sensing sensor data from at least one piece of coiled tubing unit equipment and transmitting the sensor data across the real-time network from at least one DCU to the LCP;
  
  converting and transmitting the sensor data from the LCP across a non-real-time network to at least one output device at the control station;
  
  wherein the LCP bridges communication between the non-real-time network and the real-time network; and
  
  wherein the at least one DCU comprises a power pack DCU, a coiled tubing reel DCU, and an injector head/BOP DCU, the method further comprising;
  
  storing sensor data from one or more of the power pack DCU, the coiled tubing reel DCU, the injector head/BOP DCU, and the LCP in a memory storage device; and
  
  calculating fail-safe parameters based on the stored sensor data and comparing against a pre-loaded operating envelope and automatically transmitting control signals to one or more of the power pack DCU, the coiled tubing reel DCU, and the injector head/BOP DCU when the pre-loaded operating envelope is violated.

8. A method for distributed control of a coiled tubing unit comprising:
- operating an input device at a control station to transmit control signals from the control station across a non-real-time network to a local control panel (LCP);
  
  converting and transmitting the control signals from the control station across a real-time network to at least one distributed control unit (DCU);
  
  transmitting the control signals from the at least one DCU to the at least one piece of coiled tubing unit equipment;
  
  sensing sensor data from at least one piece of coiled tubing unit equipment and transmitting the sensor data across the real-time network from at least one DCU to the LCP;
  
  converting and transmitting the sensor data from the LCP across a non-real-time network to at least one output device at the control station;
  
  wherein the LCP bridges communication between the non-real-time network and the real-time network; and
  
  wherein the at least one DCU comprises a power pack DCU, a coiled tubing reel DCU, and an injector head/BOP DCU, the method further comprising;
  
  loading and operating envelope in the LCP;
  
  transmitting and sharing the sensor data among one or more of the power pack DCU, the coiled tubing reel DCU, the injector head/BOP DCU when the operating envelope is violated.

9. A method for distributed control of a coiled tubing unit comprising:
- operating an input device at a control station to transmit control signals from the control station across a non-real-time network to a local control panel (LCP);
  
  converting and transmitting the control signals from the control station across a real-time network to at least one distributed control unit (DCU);
  
  transmitting the control signals from the at least one DCU to the at least one piece of coiled tubing unit equipment;
  
  sensing sensor data from at least one piece of coiled tubing unit equipment and transmitting the sensor data across the real-time network from at least one DCU to the LCP;
  
  converting and transmitting the sensor data from the LCP across a non-real-time network to at least one output device at the control station;
  
  wherein the LCP bridges communication between the non-real-time network and the real-time network; and
  
  wherein the at least one DCU comprises a power pack DCU, a coiled tubing reel DCU, and an injector head/BOP DCU, the method further comprising;
  
  loading an operating envelope in a memory storage device;
  
  transmitting and sharing the sensor data among one or more of the power pack DCU, the coiled tubing reel DCU, the injector head/BOP DCU, and the LCP; and
  
  transmitting control signals to one or more of the power pack DCU, the coiled tubing reel DCU, and the injector head/BOP DCU when the operating envelope is violated.

10. A system for distributed control of a coiled tubing unit, the coiled tubing unit including a power pack, a coiled tubing reel, an injector head, and a BOP, the system comprising:
- a master control station, including at least one input device and at least one output device, to operate the coiled tubing unit;
  
  a local control panel (LCP);
  
  a power pack distributed control unit (DCU) to control operation of the power pack;
  
  a coiled tubing reel DCU to control operation of the coiled tubing reel;
  
  an injector head/BOP DCU to control operation of the injector head and the BOP;
  
  a non-real-time network to send signals between the master control station and the LCP; and
  
  a real-time network to send signals between the LCP, the power pack DCU, the coiled tubing reel DCU, and the injector head/BOP DCU.
- View Dependent Claims (11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21)
- - 11. The system of claim 10, wherein the non-real-time network is an Ethernet network.
  - 12. The system of claim 10, wherein the non-real-time network is a token ring.
  - 13. The system of claim 10, wherein the real-time network is a controller area network (CAN).
  - 14. The system of claim 10, wherein the real-time network also uses a sensor network to send sensor signals from sensors to the LCP.
  - 15. The system of claim 10, wherein the master control station is positioned proximate the coiled tubing unit.
  - 16. The system of claim 15, further comprising at least one video input device positioned proximate the coiled tubing unit to send video signals to at least one electronic display located proximate the master control station.
  - 17. The system of claim 15, further comprising at least one sound input device proximate the coiled tubing unit to transmit sound signals from the coiled tubing unit to at least one sound output device proximate the master control station.
  - 18. The system of claim 10, further comprising an ancillary control station to monitor operation of the coiled tubing unit.
  - 19. The system of claim 10, wherein the master control station is located remote from the coiled tubing unit.
  - 20. The system of claim 19, further comprising at least one video input device positioned proximate the coiled tubing unit to send video signals to at least one electronic display located proximate the control station.
  - 21. The system of claim 19, further comprising at least one sound input device proximate the coiled tubing unit to transmit sound signals from the coiled tubing unit to at least one sound output device proximate the master control station.

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Current Assignee
Schlumberger Technology Corporation (Schlumberger NV)
Original Assignee
Schlumberger Technology Corporation (Schlumberger NV)
Inventors
Opel, Kent C., Lu, Weibin, Adnan, Sarmad, Zheng, Shunfeng, Rouse, Matthew D.
Primary Examiner(s)
GAY, JENNIFER HAWKINS

Application Number

US10/390,972
Publication Number

US 20040182574A1
Time in Patent Office

987 Days
Field of Search

166/250.01, 166/381, 166/384, 166/853, 166/65.1, 166/66, 166/75.4, 166/77.1, 166 772- 774, 166/113, 166/243, 166/335, 166/363, 701/2, 701/117, 378/84, 378/85, 378/114, 731/521.9, 731/525.4, 734/523.9, 710 8- 19, 710 62- 77
US Class Current

166/384
CPC Class Codes

E21B 44/00 Automatic control systems s...

G05B 15/02 electric

Distributed control system

First Claim

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Abstract

55 Citations

21 Claims

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Distributed control system

First Claim

1 Assignment

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Abstract

55 Citations

21 Claims

Specification

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