Sensor assembly

The invention claimed is: 1. A sensor assembly for sensing a crossing of the critical point by a working fluid in a transcritical cycle, the sensor assembly comprising: a component through which the working fluid flows, and, within a predetermined region of which the crossing of the critical point of the working fluid is desired to occur; a first conduit upstream of the component for conveying the working fluid to the component; a second conduit downstream of the component for conveying the working fluid away from the component; a first broadband acoustic sensor upstream of the component and a second broadband acoustic sensor downstream of the component, each of which are arranged to detect high-frequency sounds and low-frequency sounds caused by the crossing of the critical point; and a flow regulation device configured to regulate flow of the working fluid through the component in response to the output of one or more of the first broadband acoustic sensor and the second broadband acoustic sensor, thereby adjusting the location of the crossing of the critical point. 2. The sensor assembly of claim 1 , wherein the flow regulation device comprises a control valve and a controller for the control valve. 3. The sensor assembly of claim 2 , wherein the controller is configured to control operation of the control valve so as to regulate flow of the working fluid through the component in response to signals received from one or more of the first broadband acoustic sensor and the second broadband acoustic sensor. 4. The sensor assembly of claim 3 , wherein the controller is configured to maintain flow of the working fluid through the component in response to the high-frequency sounds being detected within the component by one or more of the first broadband acoustic sensor and the second broadband acoustic sensor. 5. The sensor assembly of claim 3 , wherein the controller is configured to increase flow of the working fluid through the component in response to the high-frequency sounds being detected upstream of the component by one or more of the first broadband acoustic sensor and the second broadband acoustic sensor. 6. The sensor assembly of claim 3 , wherein the controller is configured to decrease flow of the working fluid through the component in response to the high-frequency sounds being detected downstream of the component by one or more of the first broadband acoustic sensor and the second broadband acoustic sensor. 7. The sensor assembly of claim 1 , wherein one or more of the first broadband acoustic sensor and the second broadband acoustic sensor include one or more microphones. 8. A system configured to utilise a working fluid in a transcritical cycle passing through the critical point, wherein the system includes a sensor assembly comprising: a component through which the working fluid flows, and, within a predetermined region of which the crossing of the critical point of the working fluid is desired to occur; a first conduit upstream of the component for conveying the working fluid to the component; a second conduit downstream of the component for conveying the working fluid away from the component; a first broadband acoustic sensor upstream of the component and a second broadband acoustic sensor downstream of the component, each of which are arranged to detect high-frequency and low-frequency sounds caused by the crossing of the critical point; and a flow regulation device configured to regulate flow of the working fluid through the component in response to the output of one or more of the first broadband acoustic sensor and the second broadband acoustic sensor, thereby adjusting the location of the crossing of the critical point. 9. The sensor assembly of claim 8 , wherein the flow regulation device comprises a control valve and a controller for the control valve, which controller is configured to control operation of the control valve so as to regulate flow of the working fluid through the component in response to signals received from one or more of the first broadband acoustic sensor and the second broadband acoustic sensor. 10. The sensor assembly of claim 9 , wherein the controller is configured to: maintain flow of the working fluid through the component in response to the high-frequency sounds being detected within the component by one or more of the first broadband acoustic sensor and the second broadband acoustic sensor; increase flow of the working fluid through the component in response to the high-frequency sounds being detected upstream of the component by one or more of the first broadband acoustic sensor and the second broadband acoustic sensor; decrease flow of the working fluid through the component in response to the high-frequency sounds being detected downstream of the component by one or more of the first broadband acoustic sensor and the second broadband acoustic sensor. 11. The system of claim 8 , further comprising one or more of: a pump; a compressor; an expansion valve; a turbine; a heat exchanger. 12. The system of claim 8 , further comprising a heat exchanger arranged to reject heat from the working fluid into a heat sink. 13. The system of claim 8 , further comprising a heat exchanger arranged to bring the working fluid into a heat exchanging relationship with a hot fluid stream. 14. A method of controlling a system utilising a working fluid in a transcritical cycle passing through the critical point, the method comprising: selecting a predetermined region within a component, within which the crossing of the critical point is desired to occur; detecting high-frequency sounds and low-frequency sounds, the generation of which high-frequency sounds and low-frequency sounds being caused by the crossing of the critical point; regulating flow of the working fluid through the component in response to a location at which the high-frequency and low-frequency sounds were detected, thereby adjusting the location of the crossing of the critical point. 15. The method of claim 14 , wherein flow of the working fluid through the component is maintained in response to the high-frequency sounds being detected in the component. 16. The method of claim 14 , wherein flow of the working fluid through the component is increased in response to the high-frequency sounds being detected upstream of the component. 17. The method of claim 14 , wherein flow of the working fluid through the component is reduced in response to the high-frequency and low-frequency sounds being detected downstream of the component.