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Title:
METHOD AND APPARATUS FOR LEAK-PROOF MOUNTING OF A LIQUID COOLING DEVICE ON AN INTEGRATED CIRCUIT
Document Type and Number:
WIPO Patent Application WO/2007/095044
Kind Code:
A2
Abstract:
An electrical circuit element on an electrical element package is cooled by structure including a hollow body defining a cavity for containing cooling fluid located in heat transfer relation with the electrical circuit element, and a rotatably tightenable connection is provided between the electrical element package and the hollow body to block leakage of cooling fluid from the cavity.

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Inventors:
CLOUGH WILLIAM J (US)
Application Number:
PCT/US2007/003336
Publication Date:
August 23, 2007
Filing Date:
February 07, 2007
Export Citation:
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Assignee:
ONSCREEN TECHNOLOGIES INC (US)
CLOUGH WILLIAM J (US)
International Classes:
F28F7/00
Foreign References:
US6392313B1
US2728551A
Attorney, Agent or Firm:
ROTH, Norman, W. (Suite 707Los Angeles, CA, US)
Download PDF:
Claims:

CLAIMS

1. Apparatus for cooling of an electrical circuit element on an electrical element package, comprising in combination a) structure including a hollow body defining a cavity for containing cooling fluid located in heat transfer relation with said element, b) a rotatably tightenable connection between said package and said hollow body, and acting to block leakage of cooling fluid from said cavity.

2. The combination of claim 1 wherein said connection including interengaged first and second screw threads respectively on said package and on said hollow body.

3. The combination of claim 2 wherein said connection includes an annular part projecting from said package and extending about said element, said first screw thread located on said part, and said second screw thread located on said hollow body.

4. The combination of claim 3 wherein said hollow body defines an opening via which said element is exposed to fluid in said cavity.

5. The combination of claim 3 including an annular retainer integrally carried by said hollow body, and which extends re-entrantly into said cavity, said second screw thread located on said retainer.

6. The combination of claim 5 wherein the screw threads extend about an axis of an opening via which said element is exposed to fluid in the cavity, said first screw thread facing in one of the following directions: i) toward said axis ii) away from said axis.

7. The combination of claim 1 wherein said element is an integrated circuit.

8. The combination of claim 5 including interengageable sealing shoulders on said part and said retainer.

9. The combination of claim 7 wherein said part and retainer have a central axis, which intersects said integrated circuit.

10. The combination of claim 2 wherein the screw threads extend about a cavity receiving said element and into which cooling fluid extend from a larger body of cooling fluid, said larger body of cooling fluid extending annularly about said screw threads.

Description:

METHOD AND APPARATUS FOR LEAK-PROOF MOUNTEVG OF A LIQUID COOLING DEVICE ON AN INTEGRATED CIRCUIT

BACKGROUND OF THE INVENTION

Field of the Invention

Contemporary computer systems are facing increasing difficulties with respect to thermal management. With the migration towards smaller processing geometry, higher clock speeds can be realized; at the same time, the transistor count has grown exponentially. However, increasing clock speed and higher transistor counts translate into higher power consumption and, by extension, higher thermal dissipation.

In past years, performance-increasing design improvements have centered primarily on the central processing unit (CPU). As a side effect, also the thermal management efforts were primarily driven by the manufacturers of CPUs. By comparison, other system components received relatively little attention. CPUs have one major drawback; they are extremely versatile but at the same time, because they have to handle so many different tasks, they perform relatively badly in specialized applications.

One case in point is the digestion of 3D graphics data. In short, any pixel output to the screen is essentially the product of 6 consecutive steps:

1. Application Tasks (the movement of objects according to tasks, movement of camera, aim of camera)

2. Scene Level Calculations (selection of detail level, object level culling, creating object mesh) 3. Transform

4. Lighting

5. Triangle Setup and Clipping

6. Rendering

Until the end of 1999, Application Tasks, Scene Level Calculations,

Transform and Lighting were performed by the CPU, however, the performance levels achieved could not keep up with the demands of the software. Starting in 1999, simple video processors started to evolve into graphics processing units that initially took over the tasks of transform and lighting but soon evolved further into visual processing units. The terms graphics processing units (GPUs) and visual processing units (VPUs) are only vaguely defined but both have in common that the integrated circuit used is capable of processing vertices and textures in more complex ways than just taking geometry data and texturing the resulting triangles.

On the contrary, modern GPUs/VPUs are capable of parallel execution of highly sophisticated programs called shaders that turn relatively simple geometry models into independent entities or else assign color-changing routines to the individual triangles on a per pixel basis. It is understood that any of these geometry and pixel permutations require logic operations, and each logic operation requires clock cycles, and therefore energy.

By extension, this implies that increasingly complex graphics require increasing amounts of electrical power that is dissipated as heat.

One particular obstacle in the management of thermal dissipation on the level of GPUs is the form factor definition of current computer systems. The currently prevailing ATX (Advance Technology Extended) specifications have strict definitions of the space allotted for CPU cooling and they also define the distance between expansion slots on the motherboard. For low and midrange graphics cards, the available space suffices, however, as soon as one moves towards the high-end graphics sector, it is evident that a single slot cooling solution no longer suffices.

A short comparison of the power consumption of CPUs and GPUs shows that the power consumption of both groups has reached parity:

CPU Power Consumption Under Full Load*

* http.7/www. lostcircuits.com/cpu/amd fx60/6.shtml

Graphics Card Power Consumption Under Full Load*

** http://www.xbitlabs.com/articles/video/display/gpu-consumpti on2006.html

Future graphics cards will have even higher power consumption, expected values for the end of 2006 are around 180 W power consumption whereas it is expected that the power consumption of CPUs may stay at the present level ' or even decrease.

Description of Related Art

The increased power consumption of GPUs along with the restrictions of the available cooling space requires the consideration of alternative cooling solutions. Of particular interest are solutions that actively move heat away from the source to a remote radiator that is not within the same thermal zone as the heat source. For example, currently used solutions use fans that blow hot air out of the case through ventilation slots in the mounting brackets using air pipes or tunnels. Other solutions use heatpipes. In advanced cases, water and thermoelectric cooling solutions are used. Even more important than the transport of heat out of the case is the method of heat transfer between the heat source and the heat sink. Conventional heat transfer relies on transfer of heat from one surface to another using a thermal interface material (TIM). In general, this approach works, however, the actual removal of heat is limited by the thermal transfer rate of the heatsink, which is a matter of the thermal coefficient and the thickness of the material. Regardless of how advanced the design may be, this method of heat transfer relies on diffusion of heat through a solid body of material and is, therefore, slow.

A different approach uses fluids to transport the heat away from the source. Conventional waterblocks still rely on the same principle as that underlying air-cooling- based heatspreaders, that is, there is a passive heat diffusion from the IC to a thermal interface material and then to the heatspreader. In the latter, the heat still needs to diffuse from through a solid wall until it reaches the waterchannels.

A different method of removing heat from a source is to bring the coolant into direct contact with the heat source, in this case the IC. In this case, the laminar flow over the surface that needs to be cooled is the limiting factor for the heat transfer. There are different ways of how the flow and the heat exchange can be optimized, the most efficient method uses a microcapillary system. A reasonable approximation of this approach can be achieved through the use of a micro-mesh that introduces turbulences in

the flow as disclosed in U.S. Patent Application Serial No. 11/314,433 and/or 10/625,185.

A problem with retrofitting a cooling system as that described above is the inherent risk for spills and leaks. Spills can cause shorting of electrical contacts, likewise, leaks can cause overheating problems because of the resulting lack of fluid. Conventional mounting techniques use elastic o-rings but in a "mission-critical application, this solution does not suffice.

It is therefore understood that the implementation of a cooling solution such as the one disclosed above* requires a better mounting and sealing mechanism than those currently available. * Serial Nos. 11/314,433 and/or 10/625,185 incorporated herein by reference.

SUMMARY OF THE INVENTION

The present invention discloses a leak-proof mounting mechanism for a fluid cooling system where the fluid coolant is in direct contact with the IC surface or a factory- mounted heat slug such as used by most CPU manufacturers. The invention can be used to mount a cooling device with a bottom opening onto any IC. The preferred embodiment of the invention is the use of the mounting mechanism with either CPUs or GPUs/VPUs but those skilled in the art will understand that the invention can be applied in a broader sense. The simplest and most effective way of establishing a seal for the coolant is the use of a threaded seal, similar to the approach used in gas tanks. The invention requires the permanent mounting of one threaded part on the package of the IC and the other one mounted on the cooler. A compressible seal between the two parts, like those commercially available and made of Teflon or other durable materials, will provide the necessary friction between the parts to make the seal spill proof.

Alternatively, the seal can be mounted on the PCB of the device, surrounding the IC that needs to be cooled.

Further mechanical support of the cooling unit will warrant that there is no mechanical deformation of the assembly that could result in spills.

In short, the advantages of the current invention can be summarized as follows: a) it provides a spill-proof seal. b) it is mechanically stable and easy to implement on any surface using permanent mounting techniques. c) a threaded female mount with in combination with a male threaded insert allows the custom configuration and flow optimization of the cooling orifice without having to worry about seals in the immediate vicinity of the actual opening.

DRAWING DESCRIPTION Fig. 1 shows top and side views of a printed circuit board with an integrated circuit mounted. The package of the IC is larger than the die itself. On the package is an annular, threaded mount for the cooling device to be screwed in.

Fig. 2 shows the circuit board of Fig. 1 with a cooling device mounted over the IC. Fig. 3 is an enlarged view, taken in section, to show details of one form of the invention. An electrical element 11 as for example an integrated circuit device, is located at the upper side of electrical element package 10. Element 11 may be considered as part of the package, which is carried, as via bonding balls 12, or connectors, on a printed circuit board 13, to be in electrical communication with circuitry on the board.

AJso shown is structure including a hollow body 14 defining a cavity 15 for containing cooling fluid 16. That fluid will be understood as located in heat transfer relation with element 11. As shown, element 11 is in surface contact with the fluid 16.

A rotatably tightenable connection 17 is provided between the package 10 and the hollow body 14, to act as a means or part thereof for blocking leakage of cooling fluid from the cavity 15. Connection 17 includes first and second interengaged screw threads 20 and 21 respectively on the package 10 and on the hollow body 14. See for example first thread 20 carried on the package 10, and second thread 21 carried on body 14. The example in Fig. 3 shows an annular part 22 on and projecting upwardly from the package upper surface 10a to provide first thread 20 facing radially inwardly toward thread axis 23; and annular retainer 24 integral with body 14, to carry second thread 21 facing radially outwardly from the axis 23 common to both threads. Retainer 24 extends re- entrantly into the cavity 15, and forms an annular downwardly opening recess 25 receiving part 22. This enables the lower side 14a of body 14 to extend close to the upper side 10b of package 10, providing a very compact overall assembly. Also, the sides 14a and 10b. may come into contact, upon rotary tightening of the connection, providing a surface to surface annular seal enhancing the leakage blocking relationship. The interengagement of the threads, as described, also provides substantial, or complete, coolant fluid leakage blockage, and the threads may consist of seal material as referred to above.

Fig. 4 corresponds to Fig. 3, except that the thread 220 on annular part 222 faces radially outwardly; thread 221 on re-entrant annular retainer 224 faces radially inwardly. Cavity 15 extends annularly about the re-entrant retainer to enhance coolant fluid volume receiving heat from element 11. Shoulders 222a on 222 and 224a on 224 may interengage to provide fluid sealing.

A pump 24 is typically provided to circulate fluid 16 from and back to cavity 15. Also, a heat transfer device 32 may be provided to remove heat from the circulated fluid.