NIELSEN FLEMMING FERLOV (DK)
ERIKSEN ANDRE SLOTH (DK)
NIELSEN FLEMMING FERLOV (DK)
US7149087B2 | 2006-12-12 | |||
US20060002081A1 | 2006-01-05 | |||
US20030010050A1 | 2003-01-16 | |||
US20050217828A1 | 2005-10-06 | |||
US6778394B2 | 2004-08-17 | |||
US20050103475A1 | 2005-05-19 |
CLAIMS:
1 . A hybrid liquid-air cooling system adapted to provide a liquid cooling mechanism for use with a heat source component in a personal computer system, comprising: a cold plate component adapted to receive thermal energy from a proximally located heat source of the heat source component, said cold plate component coupled to a fluid manifold linked to a liquid coolant circulation pathway of a liquid cooling system for directing a flow of cooling liquid through a fluid chamber enclosed between said cold plate component and said fluid manifold; an interchangeable attachment bracket for securing said cold plate in proximity to said heat source, whereby heat from the heat source is transferred to the flow of cooling liquid within said fluid chamber via said cold plate component; and an air cooling structure operating in conjunction with said cold plate component to provide additional cooling capacity to heat source components in proximity to said cold plate.
2. The hybrid liquid-air cooling system of Claim 1 wherein said air cooling structure includes a heat sink. 3. The hybrid liquid-air cooling system of Claim 1 wherein said air cooling structure includes a plurality of cooling fins.
4. The hybrid liquid-air cooling system of Claim 1 wherein said air cooling structure includes a cooling fan.
5. The hybrid liquid-air cooling system of Claim 1 further including a shroud or duct surrounding said cold plate component and the air cooling structure, facilitating a flow of air across a thermal gradient from hot to cold.
6. The hybrid liquid-air cooling system of Claim 1 wherein said heat source is a processing unit.
7. The hybrid liquid-air cooling system of Claim 1 wherein said fluid manifold includes at least one cooling fluid input port and at least one cooling fluid output port operatively coupled to said fluid chamber.
8. The hybrid liquid-air cooling system of Claim 5 including at least one fluid circulation diverter within said fluid chamber.
9. The hybrid liquid-air cooling system of Claim 1 wherein said cold plate includes a plurality of discrete radiator components disposed within said fluid chamber.
10. The hybrid liquid-air cooling system of Claim 1 wherein said interchangeable attachment bracket is configured to facilitate coupling and decoupling of said cold plate in proximity to said heat source without breaching said coolant circulation pathway.
1 1 . The hybrid liquid-air cooling system of Claim 1 wherein said interchangeable attachment bracket holds said cold plate in proximity to said heat source with a spring bias.
12. The hybrid liquid-air cooling system of Claim 1 wherein said air cooling structure operating in conjunction with said cold plate component includes at least one of a radiator structure, a heat pipe structure, and an air circulating fan assembly. 13. The hybrid liquid-air cooling system of Claim 1 wherein said air cooling structure is at least partially enclosed within an air-flow directing shroud structure. |
HYBRID LIQUID-AIR COOLED GRAPHICS DISPLAY ADAPTER
CROSS-REFERENCE TO RELATED APPLICATIONS
The present application is related to, and claims priority from, U.S. Provisional Patent Application Serial No. 60/893,434 filed on March 7, 2007, and which is herein incorporated by reference. BACKGROUND OF THE INVENTION
The present invention is related generally to a system for cooling component circuit boards, electronic components, and heat sources associated with electronic components, and is directed specifically to a hybrid liquid - air cooling system adapted for use in cooling integrated circuit components such as those found in a personal computer system.
Personal computer systems which are designed for desktop or under- desk use, and which are typically characterized by a main-board or motherboard housed in a chassis or case. These auxiliary components may include network adapter circuit boards, modems, specialized adapters, and graphics display adapters. These auxiliary components may receive power through the connection to the motherboard, or through additional connections directly to a system power supply contained within the chassis or case. Additional components which generate heat, such as hard drives, disk drives, media readers, etc. may further be contained within the chassis or case, and coupled to the system power supply and motherboard as needed.
During operation, the motherboard and various auxiliary components consume power and generate heat. To ensure proper functionality of the computer system, it is necessary to regulate the operating temperatures inside the environment of the chassis or case. Individual integrated circuits, especially memory modules and processors, may generate significant amounts of heat during operation, resulting in localized hot spots within the chassis environment. The term "processors", as used herein, and as understood by one of ordinary skill in the art, describes a wide range of components, which may include dedicated graphics processing units,
microprocθssors, microcontrollers, digital signal processors, and general system processors such as those manufactured and sold by Intel and AMD. Failure to maintain adequate temperature control throughout the chassis environment, and at individual integrated circuits, can significantly degrade the system performance and may eventually lead to component failure.
Traditionally, a cooling fan is often associated with the system power supply, to circulate air throughout the chassis environment, and to exchange the high temperature internal air with cooler external air. However, as personal computer systems include increasing numbers of individual components and integrated circuits, and applications become more demanding on additional processing components such as graphics display adapters, a system power supply cooling fan may be inadequate to maintain the necessary operating temperatures within the chassis environment.
Specialized liquid cooling systems are available for some components in a personal computer system. Specialized liquid cooling systems typically required a coolant circulation pathway, which routes a thermal transfer liquid between a heat exchanger such as a radiator and a heat source, such as a CPU, GPU, microprocessor or transformer. Specialized liquid cooling systems are well adapted for maintaining adequate operating temperatures for individual components. However, these specialized liquid cooling systems are not easily adapted for use with a wide variety of components or adapter boards in a personal computer system. Furthermore, once such liquid cooling systems are installed, it is difficult to replace, insert, or remove components requiring cooling from the system, as the liquid cooling system must either be drained or breached to facilitate the replacement, insertion, or removal.
Accordingly, it would be advantageous to provide a hybrid liquid-air cooling system which may be easily adapted to provide a liquid cooling mechanism for use with a wide range of components in a personal computer system, and which functions cooperatively with an air cooling system. It would be further advantageous to provide a liquid-air cooling system which may be
easily detached from an associated heat source without draining of any liquid coolant or breaching of the coolant flow pathways, enabling replacement, addition, or removal of heat source components such as upgraded processors. BRIEF SUMMARY OF THE INVENTION
Briefly stated, the present disclosure provides a hybrid liquid-air cooling system which may be easily adapted to provide a liquid cooling mechanism for use with a wide range of components in a personal computer system, and which functions cooperatively with an air cooling system. The liquid cooling mechanism includes a cold plate component adapted for use with a wide range of applications, such as different types of integrated circuits or processors, and which is removably secured in place in proximity to the heat source by an exchangeable mounting clip. The cold plate component may optionally be configured to function cooperatively with an air cooling structure consisting generally of an aluminum heat sink, cooling fins, heat pipes, and a cooling fan. A shroud or duct surrounds the cold plate component and the air cooling structure, facilitating a flow of air across a thermal gradient from hot to cold.
The foregoing features, and advantages set forth in the present disclosure as well as presently preferred embodiments will become more apparent from the reading of the following description in connection with the accompanying drawings. BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS
In the accompanying drawings which form part of the specification: Figure 1 is a perspective external view of a hybrid liquid-air cooled graphics display adapter of the present invention;
Figure 2 is a perspective view of the hybrid liquid-air cooled graphics display adapter of Figure 1 , with the external components shown in phantom;
Figure 3 is a view similar to Figure 2, but from a different orientation;
-A-
Figure 4 is a view of a cold plate component of the present invention installed on a graphics display adapter;
Figure 5 is an underside perspective view of the cold plate component of Fig. 4, installed over a graphics processor which is shown in phantom; Figure 6A is a topside perspective view of the cold plate component of
Fig. 4;
Figure 6B is a sectional view of an attachment point for the cold plate component of Figures 5 and 6A;
Figure 7 is a perspective view of an embodiment of a liquid manifold of the present invention;
Figure 8 is a perspective view of an alternate embodiment of a liquid manifold of the present invention;
Figures 9A through 9D illustrate the placement of an exchangeable mounting clip over a liquid manifold of the present invention for attachment to an adapter board;
Figure 10 is a perspective view of a liquid cooling system of the present invention operatively coupled to a coolant fluid loop and heat exchanger; and
Figure 1 1 is a perspective view of a liquid cooling system of the present invention having components coupled in a chain configuration within the coolant fluid loop.
Corresponding reference numerals indicate corresponding parts throughout the several figures of the drawings. It is to be understood that the drawings are for illustrating the concepts set forth in the present disclosure and are not to scale.
DESCRIPTION OF THE PREFERRED EMBODIMENT
The following detailed description illustrates the invention by way of example and not by way of limitation. The description enables one skilled in the art to make and use the present disclosure, and describes several embodiments, adaptations, variations, alternatives, and uses of the present
disclosure, including what is presently believed to be the best mode of carrying out the present disclosure.
While the present disclosure is described generally in connection with the use of the present invention on a graphics display adapter, those of ordinary skill in the art will readily recognize that the present invention is not limited to use on a graphics display adapter, and may easily be utilized with any of a wide variety of heat sources commonly found in a personal computer system without departing from the scope of the invention. Turning to Figure 1 - 4, a cold plate 100 of the present invention is shown secured over a video or graphic processing unit of a graphics display adapter 10. The cold plate 100 is shown configured for connection to an existing liquid cooling loop 102 via any suitable liquid pathway. Preferably the liquid cooling loop 102, which is not directly part of the present invention, provides all necessary components for circulating a flow of liquid coolant to and from the cold plate 100, thereby drawing heat away from the various heat-generating components in proximity to the cold plate 100.
Preferably, the cold plate 100 is made from a material which facilitates a transfer of heat, such as a metal like copper or aluminum, or an alloy. The cold plate 100 is of a generic design and may be operatively secured in contact with different types of heat sources such as processors, power supplies, or graphic display cards by utilizing an exchangeable mounting clip 104 associated with the selected heat source. The cold plate 100 may be mounted as a member of a larger heat conducting structure 106 best seen in Figures 1 -3. The heat conducting structure 106 may be made from any suitable material, such as aluminum or copper, and preferably contacts each hot spot or component on the graphics display card 10 on one or more sides (with exception of the video or graphics processing unit, as the cold plate 100 is cooling this) to act as a heat sink. Optionally, thermal energy may be further drawn out of the aluminum structure by air convection across cooling fins 106A, heat pipes 106B, and a fan 108. Everything is preferably enclosed
within a duct or shroud 1 10 that will ensure that the heated air is blown out of the personal computer case or otherwise routed away from the graphics display adapter.
Optionally, the cold plate 100 itself may incorporate external cooling fins to facilitate cooling by the air stream in addition to the cooling by the flow of cooling liquid from the liquid cooling loop 102. The inclusion of external cooling fins on the cold plate 100 is particularly advantageous for situations where the liquid cooling loop 102 has reached a thermal capacity, thereby enabling off loading of additional thermal input by air cooling. By separating the cold plate 100 for cooling the video or graphics processing unit from the rest of the cooling system, it is possible to design a generic cold plate 100 that can be utilized to fit over multiple styles and configurations of video and graphics processing units, meaning that the manufacturer of the graphics display adapter 10 does not have to carry a large number of different cold plate products, but can do with one generic liquid cooling solution merely exchange the aluminum parts and/or the mounting clips 104 as required for different applications. Furthermore, when a component being cooled by an associated cold plate 100 is to be removed, replaced, or added, the generic design of the cold plate 100 and exchangeable mounting clip 104 enables the cold plate 100 to be disconnected from the component without requiring any draining or breaching of the liquid coolant circulation pathways, allowing the component to be replaced, added, or removed without difficulty.
An additional benefit of utilizing a liquid-air hybrid cooling system of the present invention is that the form factors of the various other cooling components 106, such as the aluminum cooling structure, may be made smaller when compared to an all-air cooled solution, due to the fact that the air cooling components do not have to cool the highest heat outputting component, i.e. the video or graphics processing unit, which is now cooled by the liquid cooling loop 102 through contact with the cold plate 100.
This invention is basically different in the sense that it is considered as a single cooling system, but is based on a combination of different technologies. As mentioned before the cold plate 100 is configured as a generic component to cooperatively function with the air cooled components 106, which may vary according to the configuration or design of the graphics display adapter or component board 10.
As shown in Figures 7 and 8, the specific configuration of the cold plate fluid manifold 1 10A, or 1 10B, which is coupled to an upper surface of the cold plate 100 to form an enclosed chamber in the liquid cooling loop 102 to facilitate circulation of the cooling liquid throughout the coolant flow circuit between a fluid delivery 102, n and fluid return line 102 ou t, may be varied as required. For example, as shown in Figure 7, a fluid flow diverter 1 12 is disposed between the cooling liquid input 102, n and output 102 ou t ports in the cold plate fluid manifold 1 10A. When the cold plate fluid manifold 1 10A is disposed over the surface of the cold plate 100 which, in turn is in contact with the upper surface of a video or graphics processing unit, the fluid circulation chamber is formed within which cooling fluid may circulate to draw heat from the surrounding surfaces, particularly heat conveyed from the heat source by the cold plate 100. During use, cooling liquid flows into the cold plate fluid manifold 1 10A through the liquid input port 102 ιn , and must circulate around the fluid flow diverter 1 12 before existing the fluid manifold 1 1 OA through the liquid output port 102 ou t- The flow of fluid ensures a uniform cooling of the various surfaces in contact with the cold plate 100, such as a video or graphics processing unit. The fluid flow diverter 1 12 may take many forms, including a multitude of pins and/or fins, and may be formed either on the cold plate fluid manifold as at 1 10A, or on the surface of the cold plate 100 which is exposed to the fluid chamber. Alternatively, as shown in Figure 8, the fluid flow diverter 1 12 may be eliminated, and fluid allowed to flow freely within the fluid circulation chamber between the cold plate 100 and the fluid manifold as at 1 10B.
To secure the cold plate 100 in place over a video or graphics processing unit, a variety of different attachment means may be utilized. Figures 9A-9D illustrate the use of an interchangeable attachment bracket or mounting clip 104 to secure the cold plate 100, together with the coupled fluid manifold 1 10A, 1 10B in place on an adapter board. The interchangeable attachment bracket 104 is designed with a set of mounting tabs 104A and a central portion 104B having an opening 104C sized to slip-fit over the cold plate 100 and fluid manifold 1 10, as shown in Figures 9A and 9B. Once in place over the cold plate 100 and fluid manifold 1 10, the attachment bracket 104 is rotated into a co-planar configuration with the cold plate 100 and fluid manifold 1 10, as shown in Figures 9C and 9D, preferably engaging a set of opposing flanges 1 14 on the peripheral edges of the cold plate 100. The attachment bracket 104 includes a set of tabs 104A through which screws, bolts, or clips may be installed to secure the attachment bracket 104 and the cold plate 100 / fluid manifold 1 10 in place against an electronic component to be cooled.
For example, as shown in Figures 5 and 6A-6B, the cold plate 100 may be secured in place over the heat source with a spring bias retention system 1 16, wherein threaded connectors 1 18 are utilized to hold attachment springs 120 in place against the tabs 104A on the attachment bracket 104. The springs 120 provide a bias force holding the cold plate 100 against the surface of the heat sink. Those of ordinary skill in the art will recognize that the specific configuration of the tabs 104A on the attachment bracket 104 may be varied in position, size, and number, as required for specific applications, and that the attachment means may be spring biased or secured by any other suitable method of affixation. Accordingly, it will be further understood that by providing a number of different attachment brackets 104, a single cold plate design 100 may be readily used in a wide range of attachment applications without requiring custom designs.
For example, as shown in Figure 10, a single cold plate 100 and fluid manifold 1 10 may be secured in place over a heat source such as a main- board processing unit, or one or more graphics processing units in parallel or series, and coupled to coolant fluid loop 102 and heat exchanger 102Hx. Alternatively, a set of cold plates 100 may be secured in place over a main- board processing unit, a graphics processing unit, and an audio processing unit, and then each may be coupled in series to a coolant fluid loop 102 and heat exchanger 102Hx to enable cooling of multiple components in a system utilizing the cold plates 100 of the present invention. The use of an adaptable attachment bracket 104 for securing the cold plates 100 in place over a variety of components enables an end-user to utilize the cooling system of the present invention in a flexible manner to provide cooling to one or more heat sources, and to expand or contract the size of the system as necessary to accommodate the addition or removal of components. As various changes could be made in the above constructions without departing from the scope of the disclosure, it is intended that all matter contained in the above description or shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense.
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