Fluid pump control modes in a medical perfusion system include a Back Off Response Mode, a Flow Servo Mode, a Pressure Servo Mode, and a Master-Slave Servo Mode. In the Back Off Response Mode, pump's speed is decremented to a new speed when an excessive flow rate or pressure condition is detected. T
Fluid pump control modes in a medical perfusion system include a Back Off Response Mode, a Flow Servo Mode, a Pressure Servo Mode, and a Master-Slave Servo Mode. In the Back Off Response Mode, pump's speed is decremented to a new speed when an excessive flow rate or pressure condition is detected. The new speed is maintained until an additional decrement is required or until the Back Off Response Mode is exited. In the Flow Servo Mode, a pump's speed is controlled to maintain a fluid flow rate indicated by a user as a setpoint. In the Pressure Servo Mode, a pump's speed is controlled to maintain a pressure indicated by the user as a setpoint. In the Master-Slave Servo Mode, a slave pump receives an indication of a master pump's speed, and the slave pump speed is controlled to maintain a specified percentage of the master pump's speed.
대표청구항▼
1. A method for controlling a fluid pump in a perfusion system, comprising the following steps:(i) establishing a setpoint for an operating parameter of the pump;(ii) controlling the speed of the pump to maintain operation at said established setpoint;(iii) detecting an alarm condition;(iv) automati
1. A method for controlling a fluid pump in a perfusion system, comprising the following steps:(i) establishing a setpoint for an operating parameter of the pump;(ii) controlling the speed of the pump to maintain operation at said established setpoint;(iii) detecting an alarm condition;(iv) automatically reducing the speed of the pump in response to said alarm condition and establishing a new setpoint for said operating parameter that corresponds to the reduced speed; and(v) controlling the speed of the pump to maintain operation at said new setpoint. 2. The method of claim 1, wherein the speed of the pump is reduced in step (iv) by a predetermined percentage of the current operating speed. 3. The method of claim 2, wherein said percentage is varied in dependence upon the amount that the detected condition exceeds a predetermined level for said condition. 4. The method of claim 2, further including the step of repeating steps (iii)-(v) to iteratively reduce the setpoint by said percentage, until a detected condition reaches an acceptable level. 5. The method of claim 4, wherein the time period between successive iterations is varied in dependence upon the amount that said detected condition exceeds said acceptable level. 6. The method of claim 1, wherein the speed of the pump is reduced in step (iv) by a predetermined number of revolutions per minute. 7. The method of claim 1, wherein the speed of the pump is reduced in step (iv) to a fixed value. 8. The method of claim 1, wherein said operating parameter is fluid flow rate. 9. The method of claim 1, wherein said operating parameter is fluid pressure. 10. The method of claim 1, wherein said setpoint is manually established by a user in step (i). 11. The method of claim 1, wherein said alarm condition is based on fluid flow rate. 12. The method of claim 1, wherein said alarm condition is based on fluid pressure. 13. The method of claim 1, further including the step of generating an alert signal to indicate that the speed of the pump has been automatically reduced. 14. A perfusion system, comprising:a fluid pump;a controller that controls the speed of said pump to maintain an operating parameter of the perfusion system at a setpoint value;a sensor that detects an alarm condition in the perfusion system; andmeans responsive to the alarm condition for automatically reducing the setpoint value for said controller, to thereby cause the controller to operate the pump at a reduced speed. 15. The perfusion system of claim 14, wherein said setpoint value reducing means causes the controller to reduce the speed of the pump by a predetermined percentage of its current operating speed. 16. The perfusion system of claim 15, wherein said setpoint value reducing means iteratively reduces said setpoint value by said percentage until a detected condition reaches an acceptable level. 17. The perfusion system of claim 14, wherein said setpoint value reducing means causes the controller to reduce the speed of the pump by a predetermined number of revolutions per minute. 18. The perfusion system of claim 14, wherein said setpoint value reducing means causes the controller to reduce the speed of the pump to a fixed value. 19. The perfusion system of claim 14, wherein said operating parameter is fluid flow rate. 20. The perfusion system of claim 14, wherein said operating parameter is fluid pressure. 21. The perfusion system of claim 14, further including means for generating an alert signal to indicate that the setpoint value has been automatically reduced.
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