초록 ▼

A heat management apparatus for disposition in a medical imaging system is disclosed. The apparatus includes a thermally conductive detector module, sensor components disposed upon the detector module, and signal processing electronics in thermal communication with the detector module, the signal pr

A heat management apparatus for disposition in a medical imaging system is disclosed. The apparatus includes a thermally conductive detector module, sensor components disposed upon the detector module, and signal processing electronics in thermal communication with the detector module, the signal processing electronics disposed proximate the sensor components. A main heat conductor is in thermal communication with a first defined portion of a length of the detector module, and a local heat conductor is in thermal communication with a second defined portion of the length of the detector module.

대표청구항 ▼

What is claimed is: 1. A heat management apparatus configured for disposition in a medical imaging system, the apparatus comprising: a thermally conductive detector module having a thermally conductive rail; sensor components disposed upon the detector module; signal processing electronics disposed

What is claimed is: 1. A heat management apparatus configured for disposition in a medical imaging system, the apparatus comprising: a thermally conductive detector module having a thermally conductive rail; sensor components disposed upon the detector module; signal processing electronics disposed upon the detector module proximate the sensor components, the signal processing electronics in thermal communication with the rail; a main heat conductor in thermal communication with a first defined portion of a length of the rail; and a local heat conductor in thermal communication with a second defined portion of the length of the rail; wherein the second defined portion is a subset of the first defined portion, and the first defined portion is greater in length that the second defined portion; wherein the main heat conductor is disposed to conduct heat away from the first defined portion and the second defined portion, and the local heat conductor is disposed to conduct heat away from the second defined portion but not the first defined portion, thereby resulting in the second defined portion having a greater number of outgoing heat flow paths than does that portion of the first defined portion that does not include the second defined portion, thereby controlling the temperature gradient along the length of the rail. 2. The apparatus of claim 1, wherein: the detector module comprises a computed tomography detector module; the sensor components comprise a scintillator and a diode; and the signal processing electronics comprise Analog to Digital conversion circuits and digital signal processing circuits. 3. The apparatus of claim 1, wherein: the main heat conductor and the local heat conductor comprise heat transfer pipes. 4. The apparatus of claim 1, wherein: a magnitude of a temperature gradient within the detector module is increased in response to removal of heat from the first defined portion by the main heat conductor; and the magnitude of the temperature gradient within the detector module is reduced in response to removal of heat from the second defined portion by the local heat conductor. 5. The apparatus of claim 1, wherein: the first defined portion comprises an entire length of the detector module. 6. The apparatus of claim 1, further comprising: a heat exchanger in thermal communication with at least one of the main heat conductor and the local heat conductor; wherein the heat exchanger is configured to transfer heat from at least one of the main heat conductor and the local heat conductor to a cooling medium. 7. The apparatus of claim 6, further comprising: a flow enhancer to direct the cooling medium to the heat exchanger, a set of temperature sensors disposed proximate the detector module, the set of temperature sensors responsive to a temperature of the detector module; and a processor in signal communication with the set of temperature sensors and the flow enhancer, the processor responsive to a signal representative of temperature to make available to the flow enhancer a control signal; wherein the control signal shall cause a reduction in a magnitude of a temperature gradient within the detector module. 8. The apparatus of claim 7, wherein the heat exchanger is a first heat exchanger and the flow enhancer is a first flow enhancer, the apparatus further comprising: a second heat exchanger; wherein the first heat exchanger and the second heat exchanger are disposed at opposite ends of the length of the detector module; a second flow enhancer in signal communication with the processor to direct the cooling medium to the second heat exchanger; wherein the processor is responsive to motion of the detector module to control the first flow enhancer and the second flow enhancer to reduce the magnitude of the temperature gradient within the detector module. 9. The apparatus of claim 8, wherein: the first flow enhancer and the second flow enhancer are fans; and the processor is responsive to motion of the detector module to control the speed of the first fan and the speed of the second fan to reduce the magnitude of temperature gradient within the detector module. 10. The apparatus of claim 1, wherein the detector module comprises: a substrate upon which the sensor components and the signal processing electronics are disposed; and a rail in thermal communication with the substrate; wherein the main heat conductor and the local heat conductor are in thermal communication with the rail. 11. A medical imaging system comprising: a heat management apparatus comprising: a thermally conductive detector module having a thermally conductive rail; sensor components disposed upon the detector module; signal processing electronics disposed upon the detector module proximate the sensor components, the signal processing electronics in thermal communication with the rail; a main heat conductor in thermal communication with a first defined portion of a length of the rail; and a local heat conductor in thermal communication with a second defined portion of the length of the rail; wherein the second defined portion is a subset of the first defined portion, and the first defined portion is greater in length that the second defined portion; wherein the main heat conductor is disposed to conduct heat away from the first defined portion and the second defined portion, and the local heat conductor is disposed to conduct heat away from the second defined portion but not the first defined portion, thereby resulting in the second defined portion having a greater number of outgoing heat flow paths than does that portion of the first defined portion that does not include the second defined portion, thereby controlling the temperature gradient along the length of the rail. 12. The system of claim 11, wherein: the medical imaging system comprises a computed tomography medical imaging system; the detector module comprises a computed tomography detector module; the sensor components comprise a scintillator and a diode; and the signal processing electronics comprise Analog to Digital conversion circuits and digital signal processing circuits. 13. The system of claim 11, wherein: a magnitude of a temperature gradient within the detector module is increased in response to removal of heat from the first defined portion by the main heat conductor; and the magnitude of the temperature gradient within the detector module is reduced in response to removal of heat from the second defined portion by the local heat conductor. 14. The system of claim 11, wherein: the first defined portion comprises an entire length of the detector module. 15. The system of claim 11, further comprising: a heat exchanger in thermal communication with at least one of the main heat conductor and the local heat conductor; wherein the heat exchanger is configured to transfer heat from at least one of the main heat conductor and the local heat conductor to a cooling medium. 16. The system of claim 15, further comprising: a flow enhancer configured to direct the cooling medium to the heat exchanger; and a set of temperature sensors disposed proximate the detector module, the set of temperature sensors responsive to a temperature of the detector module; and a processor in signal communication with the set of temperature sensors and the flow enhancer, the processor responsive to a signal representative of temperature to make available to the flow enhancer a control signal; wherein the control signal shall cause a reduction in a magnitude of a temperature gradient within the detector module. 17. The system of claim 16, wherein the heat exchanger is a first heat exchanger and the flow enhancer is a first flow enhancer, the apparatus further comprising: a second heat exchanger; wherein the first heat exchanger and the second heat exchanger are disposed at opposite ends of the length of the detector module; and a second flow enhancer in signal communication with the processor to direct the cooling medium to the second heat exchanger; wherein the processor is responsive to motion of the detector module to control the first flow enhancer and the second flow enhancer to reduce the magnitude of the temperature gradient within the detector module. 18. The system of claim 17, wherein: the first flow enhancer and the second flow enhancer are fans; and the processor is responsive to motion of the detector module to control the speed of the first fan and the speed of the second fan to reduce the magnitude of temperature gradient within the detector module. 19. The apparatus of claim 1, wherein: the first defined portion includes two opposing outboard regions and an interdisposed central region; the second defined portion includes the central region but not the two outboard regions; the main heat conductor is disposed to conduct heat away from the central region and the two opposing outboard regions, and the local heat conductor is disposed to conduct heat away from the central region but not the two outboard regions, thereby resulting in the central region having a greater number of outgoing heat flow paths than do the two outboard regions for controlling the temperature gradient along the length of the rail. 20. The medical imaging system of claim 11, wherein: the first defined portion includes two opposing outboard regions and an interdisposed central region; the second defined portion includes the central region but not the two outboard regions; the main heat conductor is disposed to conduct heat away from the central region and the two opposing outboard regions, and the local heat conductor is disposed to conduct heat away from the central region but not the two outboard regions, thereby resulting in the central region having a greater number of outgoing heat flow paths than do the two outboard regions for controlling the temperature gradient along the length of the rail.