Disclosed is an embodiment of a module for insertion between a first shelf and a second shelf of a rack based processing system. The module includes a first thermal plate substantially parallel to a second thermal plate. An inner surface of the first thermal plate faces an inner surface of the secon
Disclosed is an embodiment of a module for insertion between a first shelf and a second shelf of a rack based processing system. The module includes a first thermal plate substantially parallel to a second thermal plate. An inner surface of the first thermal plate faces an inner surface of the second plate and an outer surface of each of the first and second thermal plates faces opposite to the respective inner surfaces. Each thermal plate is configured to thermally couple to one or more component units locatable between the inner surfaces of the first and second thermal plates.
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1. A module for insertion between a first shelf and a second shelf of a rack based processing system, the module comprising: a first thermal plate substantially parallel to a second thermal plate, an inner surface of the first thermal plate facing an inner surface of the second plate and an outer su
1. A module for insertion between a first shelf and a second shelf of a rack based processing system, the module comprising: a first thermal plate substantially parallel to a second thermal plate, an inner surface of the first thermal plate facing an inner surface of the second plate and an outer surface of each of the first and second thermal plates facing opposite to the respective inner surfaces; the first thermal plate thermally coupled to a first component unit located between the inner surfaces of the first and second thermal plates; the second thermal plate thermally coupled to a second component unit located between the inner surfaces of the first and second thermal plates; and the first component unit and the second component unit each including a component board and one or more components; wherein the module comprises one or more tensioning units directly mechanically coupled to the first and second component units and located between the first and second thermal plates, the one or more tensioning units configured to generate a bias that urges the first thermal plate away from the second thermal plate, wherein the one or more tensioning units are springs. 2. The module of claim 1, wherein the first component unit is mounted to the inner surface of the first thermal plate. 3. The module of claim 1, wherein the first component unit has a component side and a non-component side, and the inner surface of the first thermal plate is thermally coupled to the component side of the first component unit. 4. The module of claim 3, wherein the component side of the first component unit includes a heat transfer device configured to transfer heat from a first component to the first thermal plate. 5. The module of claim 1, wherein, when inserted between the first shelf and the second shelf of the rack based processing system, the module is configured to transfer heat away from the first and second thermal plates via a cooling source coupled to the first shelf and the second shelf. 6. The module of claim 1, wherein a distance between the first thermal plate and the second thermal plate is variable. 7. The module of claim 1, wherein at least one of the first and second thermal plates comprises a frame and a heat exchanger coupled to the frame. 8. The module of claim 7, wherein the frame comprises multiple insert receptacles, each of which is configured to receive a corresponding one of a plurality of heat exchanger inserts. 9. The module of claim 7, wherein the heat exchanger comprises a flat heat pipe. 10. The module of claim 7, wherein the frame is rigid and the heat exchanger is flexible. 11. The module of claim 1, including a thermal conducting filler between the first component unit and the inner surface of the first thermal plate. 12. A module for insertion between a first shelf and a second shelf of a rack based processing system, the module comprising: a first thermal plate substantially parallel to a second thermal plate, an inner surface of the first thermal plate facing an inner surface of the second plate and an outer surface of each of the first and second thermal plates facing opposite to the respective inner surfaces;each thermal plate configured to thermally couple to one or more component units locatable between the inner surfaces of the first and second thermal plates; and wherein:at least one of the first and second thermal plates comprises a frame and a heat exchanger coupled to the frame;the frame is rigid and the heat exchanger is flexible;the flexible heat exchanger is configured to bow such that the outer surface of the first and the second thermal plates are bowed outward with respect to the inner surface; andoutwardly bowed surfaces of each thermal plate when inserted between the first shelf and the second shelf of the rack based processing system provide a contact bias between the outer surface of each thermal plate and a corresponding one of the first shelf and the second shelf and provide thermal coupling between the flexible heat exchanger and at least one of the component units. 13. A conduction cooling apparatus for a rack based processing system, the apparatus comprising: a frame including a module insertion area on a first side of the rack; a plurality of shelves within the frame and coupled to a coolant source, each shelf having a first surface and a second surface and configured to permit coolant flow between the first and second surfaces, the plurality of shelves being positioned substantially parallel to each other and substantially perpendicular to a plane of the first side of the rack; a plurality of bays, each bay defined by a volume of space between adjacent ones of the plurality of shelves; and a module unit inserted into a bay of the plurality of bays, the module unit including: a first thermal plate substantially parallel to a second thermal plate, an inner surface of the first thermal plate facing an inner surface of the second plate and an outer surface of each of the first and second thermal plates facing opposite to the respective inner surfaces; each thermal plate thermally coupled to a component unit located between the inner surfaces of each thermal plate; wherein each component unit includes a component board and one or more components; the first thermal plate thermally coupled to a first shelf that defines the bay; and the second thermal plate thermally coupled to a second shelf that defines the bay, the module unit further comprising one or more tensioning units directly mechanically coupled to a respective component unit and located between the first and second thermal plates, the one or more tensioning units configured to generate a bias that urges the first thermal plate away from the second thermal plate. 14. The apparatus of claim 13, wherein a first component unit has a component side and a non-component side, and the inner surface of the first thermal plate is thermally coupled to the component side of the first component unit. 15. The apparatus of claim 13, wherein at least one of the first and second thermal plates comprises a frame and a heat exchanger coupled to the frame. 16. The apparatus of claim 15, wherein the frame is rigid and the heat exchanger is flexible. 17. A method of cooling one or more component units in a frame of a rack based processing system, the method comprising: providing coolant to a plurality of shelves coupled within the frame, wherein each shelf includes a first surface and a second surface, the coolant flowing between the first and the second surfaces; and cooling the one or more component units of a module unit inserted between a first shelf and a second shelf, wherein: each component unit includes a component board and one or more components; each module unit further includes a first plate substantially parallel to a second plate; the one or more component units are located between each parallel plate providing a thermal coupling of the one or more component units to at least one of the first shelf and the second shelf; and the first plate and the second plate are separated by a distance h and the distance h between the first plate and the second plate is configured to be adjustable. 18. The method of claim 17, including connecting the rack based processing system to a building chiller unit to provide the coolant.
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