A seal monitoring and control system for a gas lubricated non-contacting seal includes various sensors providing signals to a programmable logic control system. The control system is disposed to determine a presence of an anomalous operating condition of the seal, for example, based on phase, relati
A seal monitoring and control system for a gas lubricated non-contacting seal includes various sensors providing signals to a programmable logic control system. The control system is disposed to determine a presence of an anomalous operating condition of the seal, for example, based on phase, relative position of rotor to stator or other signals in combination provided by the various sensors to provide an output signal, which in one embodiment performs at least one mitigating process to correct the anomalous operating condition by adjusting at least one operating parameter of the seal.
대표청구항▼
1. A seal monitoring system for a gas lubricated non-contacting seal disposed in sealing relationship between a rotatable shaft and a housing of a compressor, said seal having a surrounding seal chamber, said system comprising: a phase sensor disposed to provide a phase signal indicative of non-gase
1. A seal monitoring system for a gas lubricated non-contacting seal disposed in sealing relationship between a rotatable shaft and a housing of a compressor, said seal having a surrounding seal chamber, said system comprising: a phase sensor disposed to provide a phase signal indicative of non-gaseous matter adjacent to said gas lubricated non-contacting seal; anda programmable logic control system disposed to receive said phase signal, wherein said programmable logic control system is further disposed to determine an operating condition of said gas lubricated non-contacting seal based on said phase signal and prove an output signal in response to said operating condition;wherein the programmable logic controller is further disposed to determine a presence of an anomalous operating condition based on said operating condition, and perform at least one mitigating process to correct said anomalous operating condition by adjusting at least one operating parameter of said gas lubricated non-contacting seal;a process gas treatment module arranged to provide a flow of process gas to said gas lubricated non-contacting seal via a process gas inlet passage formed in the housing of the compressor, said process gas treatment module including:a process gas conduit adapted to provide said flow of process gas from an upstream end to a downstream end thereof;at least one coalescing filter fluidly intersecting said process gas conduit;a differential pressure sensor disposed across said at least one coalescing filter along said process gas conduit and providing a process gas differential pressure signal;a process gas phase sensor disposed to provide a process gas phase signal indicative of non-gaseous matter in said process gas conduit downstream of said at least one coalescing filter;a process gas temperature sensor disposed to provide a process gas temperature signal;a process gas flow sensor disposed to provide a process gas flow signal indicative of a flow rate of said flow of process gas downstream of said at least one coalescing filter;wherein said programmable logic control system is further disposed to perform said at least one mitigating process based on at least one of said process gas differential pressure signal, process gas phase signal, process gas temperature signal, and process gas flow signal. 2. The seal monitoring system of claim 1, wherein said process gas treatment module further comprises: a heater/cooler device disposed along said process gas conduit and disposed to adjust a process gas temperature in response to a temperature change command signal provided by said programmable logic control system; anda flow control device disposed along said process gas conduit and disposed to adjust a rate of flow of said flow of process gas in response to a flow control signal provided by said programmable logic control system;wherein at least one of said temperature change command signal and said flow control signal is provided as part of said at least one mitigating process of said programmable logic control system. 3. A seal monitoring system for a gas lubricated non-contacting seal comprising a first gas lubricated non-contacting seal disposed in sealing relationship between a rotatable shaft and a housing of a compressor, and a second gas lubricated non-contacting seal disposed in tandem arrangement relative to said first gas lubricated non-contacting seal between said rotatable shaft and said housing of said compressor; said system comprising: a first phase sensor disposed to provide a first phase signal indicative of non-gaseous matter adjacent to said first gas lubricated non-contacting seal;a first temperature sensor disposed to provide a first temperature signal of a temperature of a component of said first gas lubricated non-contacting seal;a first gap sensor disposed to provide a first gap signal indicative of a distance between a primary ring and a mating ring of said first gas lubricated non-contacting seal;a programmable logic control system disposed to receive said first phase signal, said first temperature signal and first gap signal wherein said programmable logic control system is further disposed to determine an operating condition of said first gas lubricated non-contacting seal based on any one of said signals and provide an output signal in response to said operating condition; andwherein said second gas lubricated non-contacting seal is associated with: a second temperature sensor disposed to provide a second temperature signal indicative of a temperature of an additional component of said second gas lubricated non-contacting seal,a second gap sensor disposed to provide a second gap signal indicative of a distance between a second primary ring and a second mating ring of said second gas lubricated non-contacting seal, andan additional phase sensor disposed to provide an additional phase signal indicative of non-gaseous matter adjacent to said second gas lubricated non-contacting seal;wherein said programmable logic control system is further disposed to receive said second temperature, second gap and additional phase signals, andwherein said programmable logic control system is further disposed to determine an operating condition of said second gas-lubricated non-contacting seal based on any one of said second signals and provide an output signal is response to said operating condition. 4. The seal monitoring system of claim 3, further comprising a secondary gas supply system adapted to provide a flow of separation gas to said second gas lubricated non-contacting seal and including: a separation gas control valve disposed to adjust a flow rate of said flow of separation gas in response to a separation gas valve control signal provided by said programmable logic control system;a separation gas flow sensor disposed to provide a separation gas flow signal to said programmable logic control system;a separation gas phase sensor disposed to provide a separation gas phase signal to said programmable logic control system; anda separation gas inlet pressure sensor disposed to provide a separation gas inlet pressure signal to said programmable logic control system;wherein said determination of said operating condition is further based on at least one of said separation gas flow signal, separation gas phase signal, and inlet pressure signals, andwherein said at least one mitigating process further includes providing an adjusted separation gas valve control signal. 5. A supply system for providing a flow of treated gas to a gas lubricated non-contacting seal disposed within a compressor, comprising: a control system;a first plurality of sensors disposed to measure seal operating parameters and provide a first plurality of signals indicative of said seal operating parameters to said control system;a second plurality of sensors disposed to measure supply system operating parameters and provide a second plurality of signals indicative of said supply system operating parameters relative to said flow of treated gas to said control system;a third plurality of sensors disposed to measure compressor operating parameters and provide a third plurality of signals indicative of said compressor operating parameters to said control system;wherein said control system is disposed to: determine an operating condition of said gas lubricated non-contacting seal based on said first, second, and third pluralities of signals; and provide an output in response to said operating condition. 6. The supply system of claim 5, wherein said control system is further disposed to determine said operating condition as being an anomalous operating condition, and to automatically perform at least one mitigating process to correct said anomalous operating condition by adjusting at least one physical property parameter of said flow of treated gas. 7. The supply system of claim 6, wherein said anomalous operating condition includes at least one of overheating of said gas lubricated non-contacting seal, and a presence of a liquid state of matter in said flow of treated gas. 8. The supply system of claim 6, wherein said at least one mitigating process includes selectively increasing a rate of said flow of treated gas incrementally while said anomalous operating condition is present and until a flow limit is reached. 9. The supply system of claim 6, wherein said at least one mitigating process includes selectively increasing a temperature of said flow of treated gas incrementally while said anomalous operating condition is present and until a temperature limit is reached. 10. The supply system of claim 5, wherein said first plurality of sensors includes at least one of a phase sensor disposed to provide a phase signal indicative of a presence of non-gaseous matter adjacent to said gas lubricated non-contacting seal, a temperature sensor disposed to provide a signal indicative of a temperature of a component of said gas lubricated non-contacting seal, a gap sensor disposed to provide a gap signal indicative of a distance between a primary ring and a mating ring of said gas lubricated non-contacting seal, and a position sensor disposed to provide an axial distance signal indicative of an axial distance between rotatable and stationary components of said compressor. 11. The supply system of claim 5, wherein said second plurality of sensors is associated with at least one of a gas treatment module and a gas control panel and includes at least one of a pressure sensor disposed to provide a pressure signal indicative of a pressure of said flow of treated gas, a temperature sensor disposed to provide a temperature signal indicative of a temperature of said flow of treated gas, a differential pressure sensor disposed to provide a differential pressure signal indicative of a state of a filter disposed to filter said flow of treated gas, a phase sensor disposed to provide a signal indicative of a presence of non-gaseous matter in said flow of treated gas, and a flow sensor disposed to provide a signal indicative of a rate of flow of said flow of treated gas. 12. The supply system of claim 5, wherein said third plurality of sensors includes at least one of a speed sensor disposed to provide a rate of rotation signal indicative of a speed of the compressor, a suction pressure sensor disposed to measure a process gas pressure at a suction side of the compressor, a discharge pressure sensor disposed to provide a process gas pressure at a discharge side of the compressor, a suction side vibration sensor disposed to measure a vibration at a suction flange of the compressor, and a discharge side vibration sensor disposed to measure a vibration at a discharge flange of the compressor. 13. The supply system of claim 5, wherein the control system is further disposed to: determine a static condition of said gas lubricated non-contacting seal based on said first and second pluralities of signals prior to operation of said compressor;lock startup of said compressor when said static condition is an anomalous stating condition; andprovide an output signal in response to said static condition. 14. The supply system of claim 13, wherein determination of said static condition is based on a comparison of an axial distance measured between rotatable and stationary components of said compressor with a threshold value. 15. The supply system of claim 13, wherein determination of said static condition is based on a gap signal provided by a gap sensor disposed to measure a distance between a primary ring and a mating ring of the gas lubricated non-contacting seal. 16. The supply system of claim 5, wherein said control system is further disposed to provide a visual representation of said operating condition. 17. A seal monitoring system for a gas lubricated non-contacting seal disposed in sealing relationship between a rotatable shaft and a housing of a compressor, comprising: a position sensor disposed to provide a position signal indicative of a relative axial position of rotatable components and stationary components of the gas lubricated non-contacting seal;a programmable logic control system disposed to receive said position signal, wherein said programmable logic control system is further disposed to determine an operating condition of said gas lubricated non-contacting seal based on said position signal and provide an output signal in response to said operating condition;a second gas lubricated non-contacting seal disposed in tandem arrangement relative to said gas lubricated non-contacting seal between said rotatable shaft and said housing of said compressor;wherein said second gas lubricated non-contacting seal is associated with: a temperature sensor disposed to provide a temperature signal indicative of a temperature of an additional component of said second gas lubricated non-contacting seal,a gap sensor disposed to provide a gap signal indicative of a distance between a second primary ring and a second mating ring of said second gas lubricated non-contacting seal, anda phase sensor disposed to provide a phase signal indicative of nongaseous matter adjacent to said second gas lubricated non-contacting seal;wherein said programmable logic control system is further disposed to receive said temperature, gap, and phase signals, andwherein said programmable logic control system is further disposed to determine said operating condition based on at least one of said temperature, gap, and phase signals. 18. A seal monitoring system for a gas lubricated non-contacting seal disposed in sealing relationship between a rotatable shaft and a housing of a compressor, said seal having a surrounding seal chamber, said system comprising: a phase sensor disposed to provide a phase signal indicative of non-gaseous matter in said seal chamber adjacent to said gas lubricated non-contacting seal; anda programmable logic control system disposed to receive said phase signal, wherein said programmable logic control system is further disposed to determine an operating condition of said gas lubricated non-contacting seal, based on said phase signal and provide an output signal in response to said operating condition;wherein said compressor further include a separation seal between said housing and rotatable shaft, and said phase sensor is disposed between said gas lubricating non-contacting seal and said separation seal. 19. The seal monitoring system of claim 18, wherein said phase sensor is an optical sensor that detects the presence of a solid or liquid aerosol solution in a gas stream based on properties of a light beam emitted and received by said sensor.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (17)
Miller Alan L. (Chicago IL) Kozlowski James L. (Whiting IN), Adaptive control system for mechanical seal assembly.
Gerard Donald R. (Bowling Green KY) Hook William J. (Bowling Green KY) Pennington Charles A. (Bowling Green KY) Richardson ; II Robert J. (Bowling Green KY), Automated apparatus and vapor/immersion cleaning method for soiled parts.
Salant Richard F. (Arlington Hts. IL) Key William E. (Schaumburg IL) Kay Peter L. (Arlington Hts. IL), Mechanical seal with automatic gap convergence control.
Beggs James M. Administrator of the National Aeronautics and Space Administration ; with respect to an invention of ( Rockville MD) Gasser Max G. (Rockville MD) Sherman Allan (Lanham MD) Studer Phili, Stirling cycle cryogenic cooler.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.