Disclosed is an X-ray detector assembly for use in a computed tomography system. The X-ray detector assembly comprises an array of detector cells coupled between two rails. A thermoelectric cooler is coupled to an end of each of the rails, and is controlled to alternatively heat or cool the detector
Disclosed is an X-ray detector assembly for use in a computed tomography system. The X-ray detector assembly comprises an array of detector cells coupled between two rails. A thermoelectric cooler is coupled to an end of each of the rails, and is controlled to alternatively heat or cool the detector array to maintain the array in a substantially isothermal and thermally stable condition. The detector assembly preferably includes both passive and active cooling devices and insulation materials for controlling the temperature of the detector assembly. An electrical heater coupled at the center of the detector array can be used in conjunction with the TEC's to control the temperature profile of the detector array, and to minimize changes in the temperature gradients.
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The invention claimed is: 1. A detector assembly for use in a computed tomography scanner, the detector assembly comprising: a detector array; a thermoelectric cooler coupled to the detector array; a temperature sensor coupled to the detector array; a heater, coupled to a center portion of the dete
The invention claimed is: 1. A detector assembly for use in a computed tomography scanner, the detector assembly comprising: a detector array; a thermoelectric cooler coupled to the detector array; a temperature sensor coupled to the detector array; a heater, coupled to a center portion of the detector array; a controller device, the controller device being electrically coupled to the temperature sensor to receive an actual temperature signal and to the thermoelectric cooler to provide an adjustable power to the thermoelectric cooler, the controller device comparing the actual temperature signal to a set point value and adjusting the power supply to the thermoelectric cooler to selectively heat or cool the detector array and driving the heater to maintain the actual temperature substantially at the set point; wherein the controller drives the thermoelectric cooler and the heater to provide a selected nonuniform temperature profile along the array. 2. The detector assembly as defined in claim 1, wherein the selected nonuniform temperature profile along the array is substantially parabolic. 3. The detector assembly as defined in claim 1, further comprising a heat sink coupled to the thermoelectric cooler. 4. The detector assembly as defined in claim 3, further comprising: a first and second rail, the first and second rails being coupled to opposing sides of the detector array; and a conductive insert coupled to at least one of the first and second rails, the conductive insert transferring heat along the rail. 5. The detector assembly as defined in claim 4, wherein the conductive insert comprises at least one of a copper, a pyrolitic graphite, or a carbon based composite material. 6. The detector assembly as defined in claim 1, further comprising a fan directed at the thermoelectric cooler. 7. The detector assembly as defined in claim 1, further comprising an insulating cover, the insulating cover being coupled to each of the bottom, sides, and ends of the detector assembly. 8. A method for maintaining a temperature profile along a detector array in a thermally stable condition during CT scanning operations, the method comprising: coupling a thermoelectric cooler to each end of the detector array; selecting an operating temperature for operating the detector array; sensing an actual temperature of the detector array at each of a center portion and a first end or second end of the detector array; providing a heater to control the temperature of the center position of the array; and comparing the selected operating temperature and the actual sensed temperature, and commanding the thermoelectric cooler to heat or cool the detector array and the heater to heat the center portion of the array based on the difference between the selected operating and sensed temperatures, wherein a selected nonuniform temperature profile along a length of the detector is maintained. 9. The method as defined in claim 8, further comprising the step of coupling a heat conductive material along the length of the detector array, the heat conductive material transferring heat along the length of the detector array. 10. The method as defined in claim 8, further comprising the step of passively dissipating heat produced by the thermoelectric cooler. 11. The method as defined in claim 8, further comprising the step of actively dissipating heat produced by the thermoelectric cooler. 12. The method as defined in claim 8, further comprising the step of insulating the detector array to prevent heat produced by an X-ray tube or cold air in a gantry from affecting the detector assembly. 13. The detector assembly as defined in claim 8, wherein the selected nonuniform temperature profile along the array is substantially parabolic. 14. A detector assembly for use in a computed tomography scanner, the detector assembly comprising: a detector array; first and second rails, the first and second rails disposed on opposing sides of the detector array, each of the first and second rails including a conductive insert for conducting heat along the length of the detector array; a thermoelectric cooler coupled to a distal end of each of the first and second rails, the thermoelectric cooler including a positive and a negative power lead for receiving a power supply; a passive heat dissipating device coupled to the thermoelectric cooler; a plurality of temperature sensors coupled at spaced intervals along the detector array; a heater directed at a center portion of the detector array; and a controller device, the controller device being electrically coupled to the thermoelectric cooler, the heater, and to the plurality of temperature sensors, wherein the controller device receives a plurality of signals indicative of a temperature of the detector array from each of the temperature sensors, compares the received signals to a corresponding plurality of set point temperatures of a selected nonuniform temperature profile along the array and supplies a drive signal to each of the thermoelectric coolers and the heater to maintain the array at the selected nonuniform temperature profile along the array. 15. The detector assembly as defined in claim 14, further comprising an active heat dissipating device, the active heat dissipating device providing an air flow to the thermoelectric cooler to dissipate heat. 16. The detector assembly as defined in claim 14, wherein the thermoelectric cooler is coupled to the detector array to provide a heating element to the array. 17. The detector assembly as defined in claim 14, wherein the thermoelectric cooler selectively provides a heating element or a cooling element to the array. 18. The detector assembly as defined in claim 14, wherein the controller actively maintains the selected nonuniform temperature profile along the array such that the array is hotter in a center portion than at opposing ends of the array. 19. The detector assembly of claim 14, wherein the selected nonuniform temperature profile along the array is substantially parabolic.
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이 특허에 인용된 특허 (19)
Hazen William A. (Hopkinton MA), Apparatus for cooling circuits.
Crawford Carl R. ; Weedon Hans J. ; Ruth Christopher C., Computed tomography scanning apparatus and method with temperature compensation for dark current offsets.
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