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Thermal bond system |
| H1699 |
Thermal bond system
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| Patent Drawings: | |
| Inventor: |
Vavrick |
| Date Issued: |
December 2, 1997 |
| Application: |
08/551,214 |
| Filed: |
October 31, 1995 |
| Inventors: |
Vavrick; Daniel J. (Beltsville, MD)
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| Assignee: |
The United States of America as represented by the Secretary of the Navy (Washington, DC) |
| Primary Examiner: |
Jordan; Charles J. |
| Assistant Examiner: |
Chelliah; Meena |
| Attorney Or Agent: |
Bechtel, Esq.; James B. |
| U.S. Class: |
156/276; 257/E23.112 |
| Field Of Search: |
156/276; 437/902; 257/178; 257/706 |
| International Class: |
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| U.S Patent Documents: |
3694699; 4842911; 4888247; 5088007; 5200365; 5224017; 5224030; 5285108 |
| Foreign Patent Documents: |
61-4255; 382145; 2196472 |
| Other References: |
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| Abstract: |
A thermal bond system is provided for bonding a first component that prods heat to a second component that dissipates heat. Carbon or other thermally conductive fiber tows are woven together to define a fabric mesh having first and second opposing woven surfaces. An adhesive bond that is flowable prior to drying is used to wet and cover the first and second opposing surfaces. The adhesive bond extends into interstices formed between adjacent fiber tows. |
| Claim: |
What is claimed as new and desired to be secured by Letters Patent of the United States is:
1. A thermal bond system for bonding a first component that produces heat to a second component thatdissipates heat, comprising:
a woven fabric composed solely of carbon; and
an adhesive bond wetting said woven carbon fabric, wherein said woven carbon fiber fabric so wetted is interposed between said first component and said second component.
2. A thermal bond system as in claim 1 wherein said woven carbon fabric has its weave type selected from the group consisting of a plain weave, a basket weave, a twill weave, a crowfoot weave, a satin weave and a leno weave.
3. A thermal bond system as in claim 1 wherein said first component includes a bonding area, and wherein said woven carbon fabric is sized commensurate with said bonding area.
4. A thermal bond system as in claim 1 wherein said woven carbon fabric is made from tightly woven carbon fiber tows.
5. A thermal bond system as in claim 1 wherein said adhesive bond is selected from the group consisting of silicone and urethane.
6. A thermal bond system for bonding a first component that produces heat to a second component that dissipates heat, comprising:
tows woven together and composed solely of carbon fiber to define a fabric mesh having first and second opposing woven surfaces, wherein interstices are formed between adjacent ones of said carbon fiber tows; and
an adhesive bond that is flowable prior to drying, said adhesive bond covering said first opposing surface and said second opposing surface, said adhesive bond further extending into said interstices.
7. A thermal bond system as in claim 6 wherein said fabric mesh has its weave type selected from the group consisting of a plain weave, a basket weave, a twill weave, a crowfoot weave, a satin weave and a leno weave.
8. A thermal bond system as in claim 6 wherein said first component includes a bonding area, and wherein said fabric mesh is sized commensurate with said bonding area.
9. A thermal bond system as in claim 6 wherein said carbon fiber tows are woven tightly to minimize the size of said interstices.
10. A thermal bond system as in claim 6 wherein said adhesive bond is selected from the group consisting of silicone and urethane.
11. A thermal bond system for bonding a first component that produces heat to a second component that dissipates heat, comprising:
a woven fabric that includes heat-conducting fibers running in both the warp and fill directions of said woven fabric, said fibers crossing each other so a to provide heat transfer in all directions, said woven fabric defining first and secondopposing woven surfaces; and
an adhesive bond that is flowable prior to drying, said adhesive bond covering said first opposing surface and said second opposing surface.
12. A thermal bond system as in claim 11 wherein said woven fabric has its weave type selected from the group consisting of a plain weave, a basket weave, a twill weave, a crowfoot weave, a satin weave and a leno weave.
13. A thermal bond system as in claim 11 wherein said first component includes a bonding area, and wherein said woven fabric is sized commensurate with said bonding area.
14. A thermal bond system as in claim 11 wherein said adhesive is selected from the group consisting of silicone and urethane.
15. A thermal bond system as in claim 11 wherein said heat-conducting fibers are made from materials selected from the group consisting of carbon, copper, gold, silver and aluminum.
16. A thermal bond system as in claim 11 wherein said heat-conducting fibers are carbon fiber tows. |
| Description: |
FIELD OF THE INVENTION
The invention relates generally to bonding systems, and more particularly to a thermal bond system for bonding a heat-producing component to a heat-dissipating component in order to efficiently transfer heat between components and to allow forthe possible breaking of the bond without the use of extreme temperature and/or force.
BACKGROUND OF THE INVENTION
Thermally conductive bonds are typically used when a heat-producing electronic component is to be bonded to a heat-dissipating component, i.e., a heat sink or thermal doubler. For best conductivity, the bond is a solid or continuous thermalconductor such as solder. Unfortunately, solder banding metals must be re-heated to a relatively high temperature in order to remove the attached component. The high heat required can damage or destroy the electronic component being removed. Thus,solder may not be a suitable thermal bond when it may be necessary to detach the bonded electronic components.
There are alternatives to the solder bond which have a relatively high thermal conductivity and which bond both metals and non-metals. These include thermoplastic resin or epoxy bond materials that have had thermally conductive particles orwhiskers mixed therein. Because these bond materials are low in thermal conductivity, the thermally conductive particles or whiskers need to be mixed in a sufficient percentage to enhance the thermal properties thereof. Such thermally enhanced bondsare well known in the art. However, thermoplastic resin material can require high application and/or removal temperatures. Epoxy bond materials often become relatively strong upon curing thereby making the removal of an attached component difficult orimpossible without the addition of relatively high heat or large forces.
SUMMARY OF THE INVENTION
Accordingly, it is an object of the present invention to provide a thermal bond system for forming an efficient heat-transferring bond between a first heat-producing component and a second heat dissipating component.
Another object of the present invention is to provide a thermal bond for bonding two components such that the bond can be broken without damaging either of the two components.
Still another object of the present invention is to provide a thermal bond system that is thin.
Other objects and advantages of the present invention will become more obvious hereinafter in the specification and drawings.
In accordance with the present invention, a thermal bond system is provided for bonding a first component that produces heat to a second component that dissipates heat. Carbon or other thermally conductive fibers or fiber tows are woven togetherto define a fabric mesh having first and second opposing woven surfaces. As a result, interstices are formed between adjacent fibers or fiber tows. An adhesive bond that has low enough viscosity to flow between the fibers or fiber tows is used to wetand cover the first and second opposing surfaces. The adhesive bond extends into the interstices. The flow of heat from the first to the second component follows a path primarily defined by the woven fibers or fiber tows. Since the adhesive bond onlyexists as a thin-layer (e.g., on the order of a few tenths of a mil) where the carbon or other thermally conductive fibers or fiber tows are closest to the first and second components, the non-conductive nature of the adhesive bond has a minimal effecton the system's overall thermal conductive properties. The interstices between the fibers or fiber tows form pockets that contain the adhesive bond. This increases the contact surface area so that the adhesive bond can form a good bond between thefirst and second component and the fibers or fiber tows.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is an exploded perspective view of the thermal bond system of the present invention interposed between two components; and
FIG. 2 is a cross-sectional view of the thermal bond system of the present invention using a satin weave fabric of thermally conductive fiber tows.
DETAILED DESCRIPTION OF THE INVENTION
Referring now to the drawings, and more particularly to FIG. 1, the thermal bond system of the present invention is shown in an exploded view between two components to be bonded together thereby. More specifically, thermal bond system 10 will bedescribed for its use in bonding heat-producing component 100 to heat-dissipating component 200 such as a thermal doubler or heat sink as it will be referred to hereinafter. Heat-producing component 100 is typically an electronic component thatgenerates heat during operation thereof that is preferably dissipated by heat sink 200. Such heat-producing components and heat sinks can come in a variety of shapes and sizes as well known in the art. Thus, the specifics of these elements will not bediscussed further herein.
Thermal bond system 10 consists of adhesive 12 and a layer of thermally conductive fabric 14. Thermally conductive fabric 14 is a fabric mesh of warp fiber tows 16 and fill fiber tows 18 with interstices 20 formed therebetween. Depending on thefiber volume or tightness of the weave of thermally conductive fabric 14, interstices 20 can extend only partially into fabric 14 in the case of a tight weave or all the way through fabric 14 in the case of a looser weave. For the best thermalconductivity, thermally conductive fabric 14 is woven tightly. The types of weave used can include, but are not limited to, a plain weave (FIG. 1), a basket weave, a twill weave, a crowfoot weave, a satin weave (FIG. 2), and a leno weave. Descriptionsof the various weave types can be found in "Composite Basics", by Andrew C. Marshall, Marshall Consulting, Walnut Creek, Calif., 1993, the relevant portions of which are found in Chapter 2. In terms of thermal conductivity, it is important for thethermally conducting fiber tows of fabric 14 to cross in some fashion in order to provide for heat transfer in all directions as will be explained further below. The area occupied by thermally conductive fabric 14 should generally be commensurate withthe area of component 100 reserved for bonding.
At least a portion, and typically a majority or all, of the fiber tows used for warp fiber tows 16 and fill fiber tows 18 must be made from a thermally conductive material. The choice of material for the thermally conductive ones of tows 16 and18 includes such thermally conductive material as carbon, copper, gold, silver and aluminum. For the best performance in terms of thermal conductivity, fiber tows 16 and 18 are all made from high conductivity carbon fibers such as the K-1100 carbonfiber manufactured by Amoco Performance Products, Inc., Alpharetta, Ga. Since it is desirable to minimize the overall thickness of thermal bonding system 10, high conductivity carbon fibers represent a good choice owing to their commercial availabilityin 2 K tows of individual fibers with diameters of 10 microns. The flexibility of the carbon fibers is critical to allow for a variety of weave configurations. It has been found that carbon fiber tows that have not been heat treated prior to beingwoven offer a greater amount of flexibility during weaving.
Adhesive 12 is any suitable bonding adhesive satisfying the requirements of the bonding application. For example, when the bonding application requires that component 100 be easily removed from heat sink 200, adhesive 12 should have a relativelysmall peel strength (e.g., on the order of one pound per inch width for electronic components or packages) or have a low softening temperature to allow for the removal of component 100 without the application of high, component-damaging heat. For suchapplications, adhesive 12 is a silicone, urethane or other low temperature plastic that exhibits a flowing viscosity prior to drying and that is flexible once dried. However, a more permanent bonding adhesive can be used in the present invention whencomponent removal is of no concern. In all cases, the viscosity of adhesive 12 prior to drying should be low enough to fill interstices 20 between warp fiber tows 16 and fill fiber tows 18 of thermally conductive fabric 14, and to allow excess adhesive12 to be pressed out or smoothed out as component 100 is seated on heat sink 200 with thermal bond system 10 interposed therebetween.
Referring now to FIG. 2, a cross-sectional view is shown of component 100 bonded to heat sink 200 using the thermal bonding system of the present invention. By way of additional illustrative example, thermally conductive fabric 14 is formed as afive-harness satin weave in which warp fiber tow 16 goes under every four fill fiber tows 18. Upon wetting fabric 14 with adhesive 12, interstices 20 are filled with adhesive 12. In addition, adhesive 12 will form at least a thin layer all along theopposing woven surfaces presented by fabric 14. The predominant flow of heat from component 100 to heat sink 200 follows the path identified by arrow 300. As is readily apparent, a similar heat flow path exists in fill fiber tows 18. Since adhesive 12only exists as a thin-layer (e.g., on the order of a few tenths of a mil) where fiber tows 16 and 18 are closest to component 100 and heat sink 200, the low-conductive nature of adhesive 12 has a minimal effect on the system's overall thermal conductiveproperties. At the same time, interstices 20 form pockets where adhesive 12 contacts a relatively large surface area.
The advantages of the present invention are numerous. The use of a layer of woven, high thermal conductivity fibers provides for good heat transfer in all directions. The thermally conductive fibers in the fabric define a plurality of heatconductive paths from the heat-producing component to the heat sink so that heat can travel along the path of least resistance for efficient cooling.
Although the invention has been described relative to a specific embodiment thereof, there are numerous variations and modifications that will be readily apparent to those skilled in the art in light of the above teachings. It is therefore to beunderstood that, within the scope of the appended claims, the invention may be practiced other than as specifically described.
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