Device and method for controlling a fluid actuator
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G05D-007/06
F15B-021/08
출원번호
US-0089301
(2013-11-25)
등록번호
US-9507350
(2016-11-29)
발명자
/ 주소
Alstrin, Kevin E.
Lauer, Peter
Robb, Bert W.
출원인 / 주소
Eatonc Corporation
대리인 / 주소
Fishman Stewart PLLC
인용정보
피인용 횟수 :
0인용 특허 :
10
초록▼
A hydraulic actuator control system for controlling the motion of a master actuator and at least one slave actuator may include an external supervisory computer for sending command signals. A hydraulic control system may be connected to the master actuator and the supervisory computer. The hydraulic
A hydraulic actuator control system for controlling the motion of a master actuator and at least one slave actuator may include an external supervisory computer for sending command signals. A hydraulic control system may be connected to the master actuator and the supervisory computer. The hydraulic control system may include a microprocessor and a master hydraulic control valve for controlling the flow of a pressurized fluid to the master actuator based on the command signals. The hydraulic actuator control system may include at least one slave actuator having at least one slave sensor connected to the microprocessor and having at least one slave control valve for controlling the flow of pressurized fluid to the slave actuator. The slave control valve and the slave sensor may be controlled by the microprocessor.
대표청구항▼
1. A hydraulic actuator control system for controlling the motion of a master actuator and a slave actuator comprising: an external supervisory computer for sending distributed command signals;a hydraulic control system connected to said master actuator and connected to, but separate from, said supe
1. A hydraulic actuator control system for controlling the motion of a master actuator and a slave actuator comprising: an external supervisory computer for sending distributed command signals;a hydraulic control system connected to said master actuator and connected to, but separate from, said supervisory computer, said hydraulic control system including a microprocessor and a master hydraulic control valve for controlling the flow of a pressurized fluid to said master actuator based on said distributed command signals; andat least one slave actuator having at least one slave sensor connected to said microprocessor and having at least one slave control valve for controlling the flow of pressurized fluid to said at least one slave actuator, where said at least one slave control valve and said at least one slave sensor are controlled by said microprocessor;wherein the external supervisory computer sends said distributed control command signals to the hydraulic control system, and said supervisory computer monitors an operational state of said microprocessor, but does not monitor said at least one slave actuator and does not manipulate said at least one slave control valve, and where said microprocessor executes a closed loop control algorithm that generates a slave control command signal in response to said distributed control command signals;wherein said microprocessor is further configured to transmit said slave control valve command signal to said at least one slave control valve, wherein said at least one slave control valve is configured to move in response to receiving said slave control valve command signal so as to allow pressurized fluid to enter said at least one slave actuator to cause said at least one slave actuator to move, thereby causing said at least one slave sensor to transmit a slave control signal indicating a changed position of said at least one slave actuator to said microprocessor, and not to said supervisory computer during operation of said supervisory computer, for use in the closed loop control algorithm executed by said microprocessor. 2. The hydraulic actuator control system of claim 1, wherein said microprocessor includes an application control algorithm that is programmable by a user. 3. The hydraulic actuator control system of claim 1, further comprising a network bus interface connected to said microprocessor and connected to said at least one slave actuator, wherein the at least one slave actuator receives commands via said network bus interface from said microprocessor. 4. The hydraulic actuator control system of claim 1, further comprising a flow controller and a pressure controller where said microprocessor selects to use either said flow controller or said pressure controller. 5. The hydraulic actuator control system of claim 1, further comprising an analog to digital converter, said analog to digital converter connected to said microprocessor and to at least one external sensor and configured to digitize signals from said at least one external sensor. 6. The hydraulic actuator control system of claim 1, further comprising a local communication bus connected to said microprocessor and to at least one of said at least one slave sensor and said at least one slave control valve, and a global communication bus connected to said microprocessor and to said supervisory controller. 7. The hydraulic actuator control system of claim 1, wherein the microprocessor is further configured to: generate a second slave control valve command signal in response to said distributed command signals received from said supervisory computer; andtransmit said second slave control valve command signal to a second slave control valve;wherein said second slave control valve is configured to move in response to receiving said second slave control valve command signal so as to allow pressurized fluid to enter a second slave actuator to cause said second slave actuator to move, thereby causing a second slave valve sensor to transmit a second slave control signal indicating a changed position to said microprocessor, and not to said supervisory computer, for use in a second closed loop control algorithm executed by said microprocessor. 8. A device for controlling the motion of a master actuator and at least one slave actuator comprising: an external supervisory computer;a controller including a programmable microprocessor and database connected to a master hydraulic control valve, said controller in communication with said master actuator and the external supervisory computer configured to send distributed command signals to said controller, wherein said master hydraulic control valve controls the flow of a pressurized fluid to said master actuator based on said distributed command signals; anda slave actuator having a slave sensor in communication with said controller and having a slave control valve for controlling the flow of pressurized fluid to said slave actuator, where said slave control valve and said slave sensor are controlled by said microprocessor;wherein said external supervisory computer monitors said controller but does not monitor said slave actuator and does not manipulate said slave control valve; andwherein said controller is configured to generate a slave control valve command signal in response to said distributed command signals received from said external supervisory computer, and transmit said slave control valve command signal to said slave control valve, wherein said slave control valve is configured to move in response to receiving said slave control valve command signal so as to allow pressurized fluid to enter said slave actuator causing said slave actuator to move, thereby causing said slave sensor to transmit a slave control signal indicating a changed position of said slave actuator to said controller, and not to said external supervisory computer during operation of said external supervisory computer, for use in a closed loop control algorithm executed by said controller. 9. The device of claim 8, wherein the microprocessor includes an application control heuristic that is programmable by a user. 10. The device of claim 8, further comprising a network bus interface connected to said microprocessor and to said slave actuator, wherein said slave actuator selectively receives commands via the network bus interface from said microprocessor. 11. The device of claim 8, wherein the controller includes a flow controller and a pressure controller where the microprocessor is configured to select either said flow controller or said pressure controller. 12. The device of claim 8, further comprising at least one external sensor in communication with an analog to digital converter, said analog to digital converter connected to said microprocessor and configured to digitize signals from said at least one external sensor. 13. The device of claim 8, wherein said external supervisory computer monitors an operation state of said controller without monitoring said slave actuator or a fluid therein. 14. A method of controlling a master actuator and a slave actuator, comprising: generating distributed command signals via an external supervisory computer;receiving said distributed command signals by a controller having a microprocessor and a database, said microprocessor programmable with control algorithms;communicating, via said controller, with a master hydraulic valve for controlling the flow of a pressurized fluid to said master actuator based on said distributed command signals;monitoring at least one slave actuator via at least one slave sensor, said at least one slave sensor coupled to at least one slave control valve for managing the flow of pressurized fluid to said at least one slave actuator, where said at least one slave control valve and said at least one slave sensor are controlled by said microprocessor; andsending, via the controller, a slave control valve command signal to said at least one slave control valve in response to said distributed command signals received from said external supervisory computer, causing said at least one slave control valve to move, thus allowing pressurized fluid to enter said at least one slave actuator and causing said at least one slave actuator to move, the movement of said at least one slave control valve causing said at least one slave sensor to transmit a slave control signal indicating a changed position of said at least one slave actuator to said controller, and not to said external supervisory computer during operation of said external supervisory computer, for use in a closed loop control algorithm executed by said controller;wherein said external supervisory computer monitors said controller but does not monitor said at least one slave actuator and does not manipulate said at least one slave control valve. 15. The method of claim 14, further comprising monitoring, via said external supervisory computer, an operational state of said controller without monitoring said at least one slave actuator or fluid therein. 16. The method of claim 14, wherein said controller communicates with at least one of said at least one slave control valve and said at least one slave sensor via a local bus interface. 17. The method of claim 14, wherein said controller communicates with said external supervisory computer via a global bus interface. 18. The method of claim 14, further comprising: generating, via the microprocessor, a second slave control valve command signal in response to the distributed command signals received from the supervisory computer; andthe controller sending said second slave control valve command signal to a second slave control valve, wherein said second slave control valve moves in response to receiving said second slave control valve command signal so as to allow pressurized fluid to enter a second slave actuator causing said second slave actuator to move, the movement of said second slave control valve causing a second slave valve sensor to transmit a second slave valve control signal indicating a changed position of said second slave actuator to said microprocessor, and not to said external supervisory computer, for use in a second closed loop control algorithm. 19. The method of claim 14, further comprising programming by a user at least a subset of the control algorithms.
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이 특허에 인용된 특허 (10)
Ronald E. Beselt CA, Control system for pneumatic actuators.
Burton K. Au ; Petr Horacek CZ; Miroslav Kes CZ; Bohumir Sladek CZ, Hydraulic controller using multiple regime specific controllers combined with fuzzy logic.
Haines Lawrence A. (Mapleton UT) Messano Edward A. (Provo UT) Beatty Kenneth L. (Spanish Fork UT) Gooch Robert E. (Provo UT) Glenn Alan H. (Salem UT) O\Hara Dennis E. (Mapleton UT), Integrated process control valve.
Catanese ; Jr. Anthony T. (724 First St. Mamaroneck NY 10543) DiMaggio Anthony (Lake Carmel NY), Method and apparatus for fail-safe control of at least one electro-mechanical or electro-hydraulic component.
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