Heatsink allowing in-situ maintenance in a stackable module
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H05K-007/20
F28F-007/00
H05K-005/00
출원번호
US-0788925
(2010-05-27)
등록번호
US-8279597
(2012-10-02)
발명자
/ 주소
El-Essawy, Wael R.
Elnozahy, Elmootazbellah N.
Iyengar, Madhusudan K.
Keller, Jr., Thomas W.
Rubio, Juan C.
출원인 / 주소
International Business Machines Corporation
대리인 / 주소
Lammes, Francis
인용정보
피인용 횟수 :
13인용 특허 :
56
초록▼
A modular processing module allowing in-situ maintenance is provided. The modular processing module comprises a set of processing module sides. Each processing module side comprises a circuit board, a plurality of connectors, and a plurality of processing nodes. Each processing module side couples t
A modular processing module allowing in-situ maintenance is provided. The modular processing module comprises a set of processing module sides. Each processing module side comprises a circuit board, a plurality of connectors, and a plurality of processing nodes. Each processing module side couples to another processing module side using at least one connector in the plurality of connectors such that, when all of the set of processing module sides are coupled together, the modular processing module is formed. The modular processing module comprises an exterior connection to a power source and a communication system and at least one heatsink that couples to at least a portion of the plurality of processing nodes on one of the processing module sides and is designed such that, when a set of heatsinks in the modular processing module are installed, an empty space is left in a center of the modular processing module.
대표청구항▼
1. A modular processing module allowing in-situ maintenance comprising: a set of processing module sides, wherein each processing module side comprises:a circuit board;a plurality of connectors coupled to the circuit board; anda plurality of processing nodes coupled, to the circuit board, wherein ea
1. A modular processing module allowing in-situ maintenance comprising: a set of processing module sides, wherein each processing module side comprises:a circuit board;a plurality of connectors coupled to the circuit board; anda plurality of processing nodes coupled, to the circuit board, wherein each processing module side in the set of processing module sides couples to another processing module side using at least one connector in the plurality of connectors such that when all of the set of processing module sides are coupled together the modular processing module is formed; and wherein the modular processing module comprises: an exterior connection to a power source and a communication system; andat least one heatsink that couples to at least a portion of the plurality of processing nodes on one of the processing module sides, wherein the at least one heatsink is designed such that, when a set of heatsinks in the modular processing module are installed, an empty space is left in a center of the modular processing module, wherein the empty space in the center of the processing module is filled with a core that fills an air gap left by the set of heatsinks in the modular processing module, wherein the core is comprised of a plurality of core sections, wherein the plurality of core sections are coupled together using retention mechanisms, and wherein upon the insertion of an expansion rod in the center of the core, the plurality of core sections move such that the outside edge of each core section contacts one heatsink in the set of heatsinks in the modular processing module. 2. The modular processing module of claim 1, wherein the at least one heatsink has a plurality of fins on either side of a set of middle fins that are a predetermined length shorter than the set of middle fins. 3. The modular processing module of claim 1, wherein the at least one heatsink is removable from the modular processing module without decoupling the set of processing module sides used to form the modular processing module. 4. The modular processing module of claim 1, wherein the core is at least one of an impervious core or a thermally conductive pervious core. 5. The modular processing module of claim 1, wherein the circuit board is a stackable mounted board coupled to the processing module side by at least one of a mechanical mechanism or a magnetic mechanism that allows detachment of the circuit board, the plurality of processing nodes, and the at least one heat sink from the processing module side, while the processing module side is in place within a processing system. 6. A processing system comprising a column of stackable modules allowing in-situ maintenance, wherein each stackable module in the column of stackable modules comprises: a set of processing module sides, wherein each processing module side comprises:a circuit board;a plurality of connectors coupled to the circuit board; anda plurality of processing nodes coupled to the circuit board, wherein each processing module side in the set of processing module sides couples to another processing module side using at least one connector in the plurality of connectors such that when all of the set of processing module sides are coupled together a modular processing module is formed, and wherein the modular processing module comprises: an exterior connection to a power source and a communication system; andat least one heatsink that couples to at least a portion of the plurality of processing nodes on one of the processing module sides, wherein the at least one heatsink is designed such that, when a set of heatsinks in the modular processing module are installed, an empty space is left in the center of the processing module, wherein two or more of the modular processing modules are stacked to form the column of stackable modules, wherein the empty space in the center of the processing system is filled with a core that fills an air gap left by the set of heatsinks in the column of stackable modules, wherein the core is comprised of a plurality of core sections, and wherein upon the insertion of a wedge in the center of the core, the plurality of core sections move such that the outside edge of each core section contacts one heatsink in the set of heatsinks in the column of stackable modules. 7. The processing system of claim 6, wherein the at least one heatsink has a plurality of fins on either side of a set of middle fins that are a predetermined length shorter than the set of middle fins. 8. The processing system of claim 6, wherein the at least one heatsink is removable from the modular processing module without decoupling the set of processing module sides used to form the modular processing module. 9. The processing system of claim 6, wherein a removable guide pin is held in place through the center of the column of stackable modules, wherein the removable guide pin is held in place at one end of the column by a permanent mount of rigid material with a mechanism to release the removable guide pin and with the permanent mount constructed so as to minimally impede the flow of cooling air. 10. The processing system of claim 9, wherein a length of the column of stackable modules and a length of the core are approximately equal and wherein, when the core is fully inserted into the column of stackable modules, the core is guided by the removable guide pin such that exterior edges of the core do not contact any heatsink of the modular processing modules in the column of stackable modules during insertion. 11. The processing system of claim 6, wherein the core is at least one of an impervious core or a thermally conductive pervious core. 12. The processing system of claim 6, wherein the at least one core is water cooled. 13. The processing system of claim 6, wherein the circuit board is a stackable mounted board coupled to the processing module side board by at least one of a mechanical mechanism or a magnetic mechanism that allow detachment of the circuit board, the plurality of processing nodes, and the at least one heat sink from the processing module side, while the processing module side is in place within the processing system.
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