System for reliably removing heat from a semiconductor junction
The system includes a heat sink member which is permanently attached to a semiconductor integrated circuit which is part of an integrated circuit board assembly, which in turn is part of an electronic equipment unit. A mounting member is positioned in the equipment chassis, adjacent to the integrated circuit board assembly, the mounting member having two spaced openings therein through which inwardly curved end portions of a spring clip extend. The end portions are adapted to conveniently and readily receive and release the heat sink in a low thermal resistance relationship. Hence, individual circuit boards my be removed from the equipment and replaced, without disturbing the desired thermal conductivity between the integrated circuit on the board and the equipment chassis. When the heat sink is operatively received by the end portions of the clip, heat is conducted away from the semiconductor junctions in the integrated circuit to the ambient air outside of the equipment chassis.
This invention relates generally to semiconductor integrated circuits, and more specifically concerns a system for removing heat from such circuits generated by their operation.
BACKGROUND OF THE INVENTIONIt is well known that integrated circuits (ICs) consume power, ranging from less than a few microwatts to more than several watts. This power is typically dissipated in the form of heat in the various semiconductor junctions present in the IC. If a semiconductor junction is heated beyond the limits established by the IC manufacturer, the IC may cease to function properly, may act erratically, and in some cases will be permanently damaged.
The temperature of an IC junction can be calculated as follows, relative to the ambient or air temperature outside the electronic equipment containing the IC:
Tj=Pd*Rja+Ta,
where Tj is the junction temperature in degrees centigrade (C.), Pd is the power dissipated in the IC in watts (W), Rja is the thermal resistance from the semiconductor junction to the ambient air outside the electronic equipment in degrees centigrade per watt (C/W), and Ta is the temperature of the ambient air outside the electronic equipment in degrees centigrade (C.).
Rja can be expressed more specifically as the series combination of several individual thermal resistances, for instance:
Rja=Rjc+Rcs+Rse+Rea
where Rjc, is the thermal resistance from the semiconductor junction to the integrated circuit case/board, Rcs is the thermal resistance from the integrated circuit case to a heat sink, Rse is the thermal resistance from the heat sink to the electronic equipment housing/chassis, and Rea is the thermal resistance from the electronic equipment housing/chassis to the air surrounding the equipment.
It is desirable to maintain Rja as small as possible so that Tj is maintained at a low (safe) thermal level. Although the thermal resistances may initially be small, there typically arises a problem with respect to heat dissipation when a printed circuit card is removed from the electronic equipment for repair or replacement. The removal results in the mechanical interface established during manufacture between the integrated circuit board and the heat sink, or the interface between the heat sink and the equipment chassis, being interrupted (broken).
When a new printed circuit board or a repaired board is replaced in the equipment, the newly established mechanical interface between the connected elements may result in a substantially higher total thermal resistance. In one solution, a force element, such as a threaded fastener, is used to provide the force of contact between the physical surfaces which have been previously broken. However, in many cases, the tool or tools which are necessary to tighten the threaded fastener cannot be used because of the particular equipment design and/or because of the location of the IC board in the equipment. In another attempted solution, a thermal grease or gasket is positioned between the thermal interfaces to reduce the thermal resistance of the system. However, the thermal grease or similar material is not easy to apply between the surfaces, particularly when the user attempts to reinstall a printed circuit assembly into a relatively small space in the electronic equipment.
Accordingly, it is desirable to have an IC thermal connection system which can be easily broken, such as when a printed circuit card is removed and then a new one installed while maintaining the original low thermal resistance, without the need for special tools or specialized material such as a thermal grease.
SUMMARY OF THE INVENTIONAccordingly, the present invention is a system for removing heat from a semiconductor integrated circuit in electronic equipment, comprising: a heat sink member attached to a semiconductor integrated circuit which is part of an integrated circuit board assembly; a mounting member connected to or part of a chassis portion of the electronic equipment; and an attachment element positioned on the mounting member for receiving and releasing the heat sink, wherein when the heat sink is received by the attachment element, a low thermal resistance path is established from the integrated circuit to the mounting member, permitting heat to be conveniently removed from the integrated circuit.
BRIEF DESCRIPTION OF THE DRAWINGS
Referring now to
One element in the thermal connection system of the present invention is a heat sink 20, shown in
Heat sink 20 in the embodiment shown is permanently attached to a surface 26 of integrated circuit 14. The attachment may be made by mechanical means such as clips or threaded fasteners, or by double-sided thermally conductive tape, adhesive or other similar means.
A second portion of the thermal connection system of the present invention is an attaching spring clip, shown generally at 28 in
Spring clip 28 is mounted through surface mounting member 30 (
Mounting member 30 is made from a thermally conductive material, typically aluminum, and if not part of the equipment unit chassis per se, is secured to the housing by welding, a threaded fastener, a mechanical clamp or by an interference fit.
Referring to
The arrangement between the engaged spring clip 28 and the mounting member is such that the clip 28 can move in all three axes but will not come out of the openings 46, 48 of the mounting member; it is captive but floating relative to the mounting member.
When the mounting member is operatively positioned in the electronic equipment chassis 45 (if the mounting member is in fact separate from the equipment chassis), the printed circuit assembly 10 is then moved into juxtaposition with the mounting member, such that disc 21 of the heat sink 20 moves between the clip end portions 41, 43 of the spring clip and adjacent surface 44 of the mounting member. The end corners of the spring clip are configured in such a way as to conveniently allow disc 21 of heat sink 20 to slide between the clip end portions 41, 43 and the surface 44.
As the heat sink thus engages the ends of the spring clip, the spring clip will bend and exert a force on the heat sink, pulling the heat sink against surface 44 of the mounting member, resulting in solid thermal contact between the heat sink on the printed circuit assembly and the mounting member. This results in a low thermal resistance connection between the heat sink and the mounting member.
The physical arrangement between the printed circuit assembly 10 with attached heat sink 20 and spring clip 28 held in mounting member 30 is shown in
The mounting member 30, as indicated above, is solidly mounted to the equipment unit chassis 45, and the heat sink 20 is solidly mounted to the integrated circuit 14, with both connections having low thermal resistance. The total thermal resistance, from the IC itself on the printed circuit assembly to the equipment unit chassis, thus is minimized. As indicated above, the mounting member 30 can either be a separate element, as shown in the various figures, or it can be a part of the actual equipment chassis itself.
In operation, heat flows from the integrated circuit itself, which is consuming power, to the heat sink, to the mounting member, to the equipment chassis and then to the ambient air surrounding the equipment. The semiconductor junctions are thus prevented from heating excessively.
As discussed above, the mounting member 30 containing the spring clip can be attached at different locations to the equipment chassis to provide the desired thermal connection therewith. Attaching the mounting member at different locations to the chassis permits this cooling arrangement to be used at various locations in the equipment chassis. Further, the mounting member can be either a separate element from the chassis, or can be a part of the chassis itself.
In the embodiment shown, mounting member 30 is manufactured with a treatment of surface 44 which allows the heat sink to slide easily over surface 44 until it mates with the spring clip 28, while still producing a relatively large force between the heat sink and the mounting member after mating of the elements occurs.
The surface treatment is embossing a selected area around the protruding portion of the clip. The embossed area is approximately 0.8 mm higher than the remainder of the surface member, so that the embossed area assists in minimizing the distance that the central portion of the spring clip is above the opposing surface 50 of the mounting member, i.e. a “low profile” spring clip. This helps to avoid interference of the bowed portion of the spring clip with adjacent features, such as other components of the printed circuit assembly.
Further, the embossed area of surface 44 can be treated with a lubricant, such as oil or thermal grease that will decrease thermal resistance and also decrease sliding friction, resulting in easier insertion of a circuit card assembly.
Accordingly, a system has been disclosed which provides a reliable thermal connection between a printed circuit assembly and ultimately the equipment, resulting in heat from the semiconductor junctions being removed therefrom to the ambient air outside the equipment. The system permits the breaking and the reestablishing of a thermal connection between an IC and the equipment chassis without detrimentally affecting the removal of heat from the IC junction.
Although a preferred embodiment of the invention has been disclosed for purposes of illustration, it should be understood that various changes, substitutions and modifications may be incorporated in such embodiment without departing from the spirit of the invention which is defined by the claims which follow.
Claims
1. A system for removing heat from a semiconductor integrated circuit in electronic equipment, comprising:
- a heat sink member attached to a semiconductor integrated circuit which is part of an integrated circuit board assembly; and
- a mounting member connected to or part of a chassis portion of the electronic equipment and an attachment element positioned on the mounting member for receiving and releasing the heat sink, wherein when the heat sink is received by the attachment element, a low thermal resistance path is established from the integrated circuit to the mounting member, permitting heat to be conveniently removed from the integrated circuit.
2. The system of claim 1, wherein the attachment element is a spring clip having two opposing inwardly directed end portions for holding the heat sink.
3. The system of claim 2, wherein the mounting member includes two spaced opposed openings through which the end portions of the clip extend, and wherein the spring clip has a central portion which is on the opposite side of the mounting member from the two end portions when the spring clip is operatively positioned on the mounting member.
4. The system of claim 3, wherein the heat sink comprises two flange portions joined together by an intermediate portion of less cross-sectional area than the flange portions, such that one of the flange portions can be moved into firm engagement between the end portions of the clip and the adjacent surface of the mounting member.
5. The system of claim 1, wherein the heat sink is permanently attached to the integrated circuit on the integrated circuit board assembly.
6. The system of claim 1, wherein the mounting member is insertable into the equipment chassis in a low thermal resistance relationship therewith.
7. The system of claim 1, wherein the mounting member comprises a part of the equipment chassis.
8. The system of claim 1 wherein the mounting member includes an embossed area on a surface thereof adjacent the end portions of the operatively positioned spring clip.
9. The system of claim 4, wherein the flange portions are circular and the intermediate portion is cylindrical.
10. The system of claim 4, wherein the flange portions are approximately square and are each larger than the intermediate portion, sufficient to permit the heat sink to be conveniently engaged by the end portions of the spring clips against the adjacent surface of the mounting member.
11. The system of claim 1, wherein the end portions each include corner parts which flare downwardly from the end portions.
12. The system of claim 8, wherein the embossed area includes a lubricant.
Type: Application
Filed: Jul 22, 2003
Publication Date: Jul 28, 2005
Inventor: Gerald Hein (Pullman, WA)
Application Number: 10/625,340