초록 ▼

Active cooling technologies such as thermoelectrics can be used to introduce thermal "gain" into a cooling system and, when employed in combination with forced flow cooling loops, can provide an attractive solution for cooling high heat flux density devices and/or components. In such configurations,

Active cooling technologies such as thermoelectrics can be used to introduce thermal "gain" into a cooling system and, when employed in combination with forced flow cooling loops, can provide an attractive solution for cooling high heat flux density devices and/or components. In such configurations, it can be advantageous to discontinuously flow thermal transfer fluid into thermal contact with the hot or cold side of a thermoelectric module (TEM), allow it to dwell while heat is transferred from or to the TEM, and resume the flow. In configurations in which the TEM operation is itself discontinuous, various relationships between thermal transfer fluid flow and TEM operation can be advantageously employed to temporally integrate thermoelectric action.

대표청구항 ▼

What is claimed is: 1. A method of operating a thermoelectric system for thermal control of a target, the method comprising: flowing a first volume of thermal transfer fluid into a portion of a first fluid pathway, the first portion in thermal communication with a first side of a thermoelectric mod

What is claimed is: 1. A method of operating a thermoelectric system for thermal control of a target, the method comprising: flowing a first volume of thermal transfer fluid into a portion of a first fluid pathway, the first portion in thermal communication with a first side of a thermoelectric module; allowing at least a some of the first volume to dwell in the first fluid pathway portion; flowing a second volume of thermal transfer fluid into the first fluid pathway portion, while at the same time, flowing at least some of the first volume out toward the target; and repeating, for the second and subsequent volumes of the thermal transfer fluid, the allowing to dwell and the flowing toward the target. 2. The apparatus of claim 1, wherein duration of the dwell is selected allow heat transfer between the first side of the thermoelectric module and the thermal transfer fluid while limiting the temperature differential between the first and a second side of the thermoelectric module. 3. The method of claim 1, further comprising: discontinuously operating at least one electromagnetic (EM) pump to flow the thermal transfer fluid. 4. The method of claim 1, wherein duration of each dwell is pre-selected. 5. The method of claim 1, wherein duration of any given dwell is adaptive, at least in part, to an operating characteristic of the thermoelectric system. 6. The method of claim 1, wherein the thermoelectric module operates during at least some time during which the thermal transfer fluid dwells in the first fluid pathway portion. 7. The method of claim 1, wherein the thermoelectric module operates during at least some time during which the thermal transfer fluid flows in the first fluid pathway portion. 8. The method of claim 1, wherein the thermoelectric module operates substantially continuously. 9. The method of claim 1, wherein operation of the thermoelectric module and the repeating exhibit a phase relationship. 10. The method of claim 1, further comprising flowing a thermal transfer fluid in a second fluid pathway portion in thermal communication with the second side of the thermoelectric module. 11. The method of claim 10, wherein the flow in the second fluid pathway portion is one of: continuous; substantially temporally aligned with the flow in the first fluid pathway portion; substantially uncorrelated with the flow in the first fluid pathway portion; and discontinuous. 12. The method of claim 10, the method further comprising: allowing at least a portion of a third volume of thermal transfer fluid to dwell in the second fluid pathway portion; flowing a fourth volume of thermal transfer fluid into the second fluid pathway portion, while at the same time flowing at least a portion of the third volume of thermal transfer fluid out toward a heat exchanger; and repeating, for the fourth and subsequent volumes of the thermal transfer fluid, the allowing to dwell and the flowing toward the heat exchanger. 13. A method of operating a thermoelectric system, the method comprising: discontinuously motivating flow of a first thermal transfer fluid through a first fluid pathway portion in thermal communication with a first side of a thermoelectric module; operating the thermoelectric module such that a temperature differential exists between the first and a second side of the thermoelectric module; and transferring heat between the first side of the thermoelectric module and a first volume of thermal transfer fluid in thermal communication therewith. 14. The method of claim 13, wherein the discontinuous motivation of flow is by discontinuous operation of at least one magnetofluiddynamic (MFD) pump. 15. The method of claim 14, wherein operation of the pump is periodic. 16. The method of claim 14, wherein temporal behavior of the pump is at least partially responsive to an operating characteristic of the thermoelectric system. 17. The method of claim 16, wherein the operating characteristic of the thermoelectric system includes one or more of: a temperature differential between the first and second sides of the thermoelectric module; and a temperature of thermal transfer fluid. 18. The method of claim 14, wherein the operation of the thermoelectric module is itself one of: continuous; substantially temporally aligned with operation of the pump; substantially uncorrelated with operation of the pump; and discontinuous. 19. The method of claim 14, wherein the operation of the thermoelectric module and the operation of the pump are substantially non-overlapping. 20. The method of claim 14, wherein the operation of the thermoelectric module and the operation of the pump are arrested during an overlapping interval. 21. The method of claim 13, further comprising: motivating flow of a second thermal transfer fluid through a second fluid pathway portion in thermal communication with a second side of the thermoelectric module. 22. The method of claim 21, wherein thermal transfer fluid flow through the second fluid pathway portion is itself: continuous; substantially temporally aligned with flow through the first fluid pathway portion; substantially uncorrelated with flow through the first fluid pathway portion; and discontinuous. 23. The method of claim 21, wherein the first and second fluid pathway portions constitute distinct first and second closed fluid loops. 24. The method of claim 21, wherein the second closed fluid loop is partially overlapped with the first closed fluid loop; and wherein the first and second thermal transfer fluids are a same fluid. 25. The method of claim 21, wherein the first and second fluid pathway portions constitute respective portions of a single closed fluid loop; and wherein the first and second thermal transfer fluids are a same fluid. 26. A thermoelectric system comprising: at least one thermoelectric module that exhibits, during operation, a thermal differential between a first and second side thereof; a first fluid pathway including a first portion in thermal communication with a first side of the thermoelectric module; and a pump operable to discontinuously motivate flow of thermal transfer fluid through the first fluid pathway, wherein the discontinuous motivation flows a first volume of thermal transfer fluid into the first fluid pathway portion and flows a corresponding second volume of the thermal transfer fluid out of the first fluid pathway portion. 27. The thermoelectric system of claim 26, wherein the operation of the thermoelectric module is continuous. 28. The thermoelectric system of claim 26, wherein the operation of the thermoelectric module is discontinuous. 29. The thermoelectric system of claim 26, further comprising: a second fluid pathway including a second portion in thermal communication with a second side of the thermoelectric module. 30. The thermoelectric system of claim 26, further comprising: the thermal transfer fluid disposed within the first fluid pathway. 31. The thermoelectric system of claim 30, wherein the thermal transfer fluid includes a liquid metal. 32. The thermoelectric system of claim 30, wherein the thermal transfer fluid includes an electrically conductive fluid or slurry. 33. The thermoelectric system of claim 30, wherein the thermal transfer fluid includes a mixture of immiscible fluids. 34. The thermoelectric system of claim 29, further comprising: two distinct closed fluid loops for transfer of the thermal transfer fluid away from, and back to, the thermoelectric module, the first closed fluid loop including the first fluid pathway, and the second closed fluid loop including the second fluid pathway. 35. The thermoelectric system of claim 29, further comprising: a single closed loop in thermal communication with both the first and second sides of the thermoelectric module, the single closed fluid loop including both the first and the second fluid pathways; and wherein the pump is a single electromagnetic pump disposed within the single closed loop to motivate flow of the thermal transfer fluid through both the first and second fluid pathways. 36. The thermoelectric system of claim 29, further comprising: two at least partially overlapped closed fluid loops for transfer of the thermal transfer fluid away from, and back to, the thermoelectric module, the first closed fluid loop including the first fluid pathway, and the second closed fluid loop including the second fluid pathway, wherein thermal transfer fluid from the first and second closed fluid loops is commingled at at least one point in the overlapped closed fluid loops; and at least one electromagnetic pump disposed in an overlapped portion of the overlapped closed fluid loops. 37. The thermoelectric system of claim 29, at least one additional thermoelectric module, each thermoelectric module constituting a stage of a thermoelectric array, wherein the flow topology traverses N-stages of the thermoelectric array, and wherein the flow topology is structured so that, at any particular one of the thermoelectric modules, impinging hot-side and cold-side flows respectively traverse x and N-1-x stages {x: 0≦x