DE3028722C2 - Device for attaching a high-voltage power transistor to a heat sink - Google Patents

Description

The invention relates to a device for fastening a high-voltage power transistor to a Heat sink, in which the transistor with the interposition of an insulating film by means of a mounting flange of the transistor piercing screw fastenings held on the heat sink and the shaft of the A fastening device of this type is enclosed by at least one insulating bushing 73 32 299 is known from DE-GM 73 32 299 for a transistor

The installation and fastening of high-voltage power transistors, whose power loss is so great that an impermissibly high temperature rise can occur, must meet certain requirements so that, on the one hand, the resulting heat loss can be dissipated well on the other hand, v-nd can have a sufficiently high dielectric strength. Power transistors with Metal housings are usually screwed insulated onto a cooling plate in order to dissipate the heat loss. The insulating agent must be used in order to avoid thermal problems and to ensure that the transistor operates safely to ensure, on the one hand, have the lowest possible thermal resistance and, on the other hand, with the Attachment of high voltage power transistors withstand high test voltages. The fulfillment of this Requirements often stand in the way of a structurally simple solution.

The invention is therefore based on the object of a device for fastening a high-voltage power transistor to create a heat sink with a structurally simple, space-saving structure the transistor fastening dissipates the heat loss well and has a sufficiently high dielectric strength having.

This object is achieved in a device of the type mentioned according to the invention in that that for each screw fastening two insulating bushes which can be pushed into one another with a shaft are provided are that the one insulating sleeve is formed with a flange and below with this flange the insulating film can be used in a recess in the heat sink, and that the second insulating bushing through the The transistor's mounting flange can be plugged into the first insulating socket from the other side of the insulating film and formed with a collar that can be clamped against the mounting flange of the transistor by the screw fastening is.

In a device according to the invention, two telescopic insulating bushes are provided which are formed with a flange or a collar. The flange of the first insulating sleeve is located here under the insulating film arranged between the heat sink and the transistor in a recess in the heat sink, i.e. between the mounting flange of the transistor or the insulating film and the metal heat sink, while the collar of the second insulating sleeve between the mounting flange of the transistor and the Screw fastening is clamped. In this way there is one hand between the transistor and the heat sink and the transistor and the screw fastening, on the other hand, each have an uninterruptible insulating

stretch of certain length formed by this from the flange of the first insulating bushing and from the collar of the second insulating bushing and also formed by the insulating film and the shafts of the insulating bushes Creepage distances are possible, commercially available and previously used for low-voltage Trans'storen Use insulation material with a very low thermal resistance and at the same time a high-voltage-resistant one To ensure transistor holder, soft also for high test voltages of z. B. suitable about 2.5 kV The height of the flange of the first insulating bushing, the collar of the second insulating bushing, is determined here, of the shafts of the insulating bushes and the size of the insulating film according to the level of the test voltage dependent length of the creepage distances. A particular advantage of a device according to the invention consists in the structurally simple, space-saving structure of the transistor mounting.

The transistor fastening according to the invention is particularly advantageous for isolating high-voltage power transistors suitable in switch mode power supplies

In a device according to the invention, the height of the flange of the first insulating bushing is expedient equal to the height of the collar of the second insulating sleeve. This means that the mounting flange of the Transistor created against the heat sink or against the screw fastening creepage distances of the same length.

It is also advantageous if, in a device according to the invention, the length of the shaft is the second The insulating bushing is approximately 1.5 to 2 times the length of the shaft of the first insulating bushing. That way results To guide the shafts of the two insulating bushes into one another, a larger axial stroke, which is advantageous Way a tolerance compensation for different thicknesses of the mounting flange of the transistor and at possibly between the collar of the second insulating bushing and the mounting flange arranged solder lug allows. In addition, this ensures a sufficiently long creepage distance in the area of the shafts.

Further advantageous embodiments of the subject matter of claim 1 are in the features of the remaining subclaims.

In the following the invention is based on an embodiment shown in the drawing Device for fastening a high-voltage power transistor nn a heat sink explained in more detail.

The figure essentially shows the fastening of a transistor, while only a fraction of the transistor itself is shown. The transistor 1 has a metal housing 2 with a mounting flange 3 on the on a heat sink 4, z. B. a cooling plate to be attached underside. Between the mounting flange 3 and the heat sink 4 is a thin insulating film 5, for. B. made of plastic, provided with the lowest possible thermal resistance, on the one hand to isolate the transistor 1 from the heat sink 4 and on the other hand to enable good heat transfer from the transistor to the heat sink. The transistor 1 is fastened by means of the mounting flange 3, the heat sink 4 and the interposed insulating film 5 of penetrating screw fastenings, of which only one screw fastening 6 can be seen here. For this purpose, the heat sink 4 and the mounting flange 3 of the transistor are each provided with a mounting hole 7 and 8 and the insulating film 5 with a through hole 9, the diameter of which corresponds to the diameter of the mounting hole 8 of the mounting flange 3, mounting flanges of transistors generally have different thicknesses for tolerance reasons so that flanges of different thicknesses have to be clamped with the provided screw fastenings within certain limits. To make this clear, the mounting flange 3 of the transistor is shown thinner (lowest tolerance limit) to the left of the drawn center axis of screw fastening 6 and thicker to the right of it (uppermost tolerance limit) Positions shown The screw attachment consists of a screw 10, which is inserted from below into the mounting hole 7 of the heat sink 4 and a nut 11 with washer 12 and another washer 23. The length of the screw shaft 13 is chosen so large that the mounting flange 3 of the transistor can be tightened without difficulty even at the uppermost tolerance limit. For each screw fastening, two insulating bushes 14 and 15 are provided, which can be pushed into one another with their shaft 16 and 17 and enclose the shaft 13 of the screw 10. The insulating sleeves 14, 15 are advantageously made of a temperature-resistant material with a high dielectric constant, for. B. made of glass fiber reinforced polycarbonate, which has become known under the trade name Makroion. One insulating bushing 14 is provided with a circular, disc-shaped flange 18, which is perpendicular to the bushing axis, and is inserted with this flange into a recess 19 in the cooling body 4 below the insulating film 5. The thickness of the flange set flush with the lower end of the socket is equal to the depth of the recess 19, so that the upper side of the flange is flush with the upper side of the heat sink 4. With the shaft 18, the first insulating socket 14 penetrates in the case of the lowest tolerance limit of the mounting flange 3 here its fastening hole 8 entirely, while in the case of the uppermost tolerance limit it ends in the fastening hole. The outside diameter of the shaft 16 of the insulating bushing 14 is approximately equal to the inside diameter of the fastening bore 8, while the inside diameter of the shaft 16 is the same as the diameter of the fastening bore 7 provided in the cooling body 4. The second insulating bushing 15 is inserted with its shaft 17 through the assembly flange 3 of the transistor from the other side of the insulating film 5 into the shaft 16 of the first insulating bushing 14 and serves as a counter-bushing by being provided with a cylindrical collar 20 surrounding the shaft 17 . which is clamped by the nut 11 of the screw fastening 6 against the Mowtage flange 3 of the transistor and after screwing the insulated transistor firmly against the heat sink 4 or against the insulating film 5 in between another solder lug 21, e.g. B. to the collector connection, inserted and clamped. The height Λ 2 of the collar of the second insulating sleeve 15 is expediently equal to the height h 1 of the flange 18 of the first insulating sleeve 14, s ^ that between the mounting flange 3 and the heat sink 4 on the one hand and the mounting flange 3 and the nut 1J of the screw fastening and the mounting flange 3 and the nut 11 of the screw fastening on the other hand, as well as between the soldering eye 21 and the nut of the screw fastening of the same length, interrupt

Uninterrupted isolation paths are formed. The over the edge of the mounting flange 3 by the height Λ 1 of the flange 18 protruding insulating film 5 and the nested, overlapping shafts 16,17 of the two insulating bushes form further, expediently, uninterrupted sections of the same length as the other insulating sections Insulating distances. These creepage distances are in the illustrated embodiment, for. B. about 3.5 mm long so that the transistor mount can withstand test voltages of up to about 2.5 kV.

In addition, the collar 20 of the second insulating sleeve 15 is larger in its outer diameter than the largest Outer diameter of the screw fastening 6. The outer diameter of the shaft 17 of the second insulating sleeve 15 is equal to the inner diameter of the shaft 16 of the first insulating bushing to form a sliding fit guide 14 and the diameter of the mounting hole 7 provided in the heat sink 4. Finally, the Length 12 of the shaft 17 of the second insulating bushing 15 approximately 1.5 to 2 times the length / 1 of the shaft 16 of the first insulating bushing 14, in order to have an axial stroke of the insulating bushes that is sufficient to compensate for tolerances to ensure a sufficiently long creepage distance in this area. For this reason is also between the collar 20 and the shaft 17 of the second insulating bushing 15 an undercut 22 for the Shank 16 of the insulating sleeve 14 is provided.

1 sheet of drawings

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Claims (10)

Patent claims: 1. A device for fastening a high-voltage power transistor to a heat sink, in which the transistor is held with the interposition of an insulating film by means of a mounting flange of the transistor penetrating screw fastenings on the heat sink and the shaft of the fastening screws is enclosed by at least one insulating sleeve, characterized in that for each screw fastening (6) two insulating bushes (14, 15) which can be pushed into one another with a shaft (16, 17) are provided that one insulating bushing (14) is designed with a flange (18) and with this flange below the insulating film (5) in a recess (19) of the heat sink (4) »iinsetz- bzT , and that the second Iso'.ierbuchse (15) through the mounting flange (3) of the transistor (1) from the other side of the insulating film (5) into the first insulating bushing (14) can be plugged in and designed with a collar (20) that can be clamped against the mounting flange (3) of the transistor by the screw fastening (6) is educated. 2. Device according to claim 1, characterized in that the height (h 1) of the flange (18) of the first insulating sleeve (14) is equal to the height (h2) of the collar (20) of the second insulating sleeve (15). 3. Device according to claim 1 or 2, characterized in that the outer diameter of the Shank (17) of the second insulating bushing (15) is equal to the inner diameter of the shaft of the first insulating bushing (14) and the diameter of a mounting hole (7) provided in the heat sink (4) is. 4. Device according to one of claims 1 to 3, characterized in that the outer diameter of the shaft (16) of the first insulating bushing (14) approximately equal to the inner diameter of one in the mounting flange (3) of the transistor (1) provided mounting hole (8). 5. Device according to one of the preceding claims, characterized in that the outer diameter of the federal government (20) of the second insulating sleeve (15) is larger than the largest outer diameter the screw fastening (6). 6. Device according to one of the preceding claims, characterized in that the length (1 1) of the shaft (16) of the first insulating bushing (14) is equal to the height (h 1) of the flange (18). 7. Device according to one of the preceding claims, characterized in that the length (12) of the shaft (17) of the second insulating bushing (15) is approximately 1.5 to 2 times the length (I 1) of the shaft (16) of the first insulating bushing (14). 8. Device according to one of the preceding claims, characterized in that between the collar (20) and the shaft (17) of the second insulating bushing (15) an undercut (22) for the Shank (16) of the first insulating bushing (14) is provided. 9. Device according to one of the preceding claims, characterized in that the thickness of the flange (18) of the first insulating sleeve (14) is equal to the depth of the recess (19) in the cooling b5 body (4) is. 10. Fjinrichtung according to any one of the preceding claims, characterized in that the insulating film (5) by the height (h 1) of the flange (18) of the first insulating bushing (14) is greater than the mounting flange (3) of the transistor.