EP1364564A2

EP1364564A2 - Cooling device, method for the production thereof, and device for carrying out this method

Info

Publication number: EP1364564A2
Application number: EP01989436A
Authority: EP
Inventors: Werner J. Graf; Erich Buck
Original assignee: Corus Aluminium Profiltechnik GmbH
Current assignee: ST Extruded Products Germany GmbH
Priority date: 2000-11-14
Filing date: 2001-11-02
Publication date: 2003-11-26
Also published as: WO2002041677A3; DE10056387B4; WO2002041677A2; DE10056387A1

Abstract

The invention relates to a cooling device for, in particular, electronic components. Said cooling device comprises a base plate and cooling fins that are anchored inside channels of said base plate. The invention provides that in each case, only one lateral wall (2b) of each channel (2) can be permanently deformed or is permanently deformed, whereas the shape of the other lateral wall (2a) of the respective channel (2) remains essentially unchanged and guarantees the defined position of the cooling fins (3).

Description

Cooling device and method for its production and device for carrying out the method

The invention relates to a cooling device of the type mentioned in the preamble of claim 1, with which in particular electronic and electrical components are cooled, and to a method and a device for the production thereof.

Such cooling devices have a base plate, which are connected on one side in particular to the electrical or electronic components to be cooled and also other components in a thermally highly conductive manner, while in particular on the other surface of the base plate there are a number of longitudinal grooves or in the longitudinal direction Grooves. Cooling fins are embedded in the grooves at the foot ends, forming thermally highly conductive contact surfaces. As a result, the heat generated in the components is passed on to the cooling fins via the base plate and from there to the atmosphere for cooling due to the large total surface area of the cooling fins. The cooling fins are in particular plate-like or as thin plates or lamellae. It is known (DE - 25 02 472 C2) to provide the cooling fins on their longitudinal sides with transverse ribs and to press them with the foot ends into the grooves of the base plate in such a way that the cooling fins there are not only good mechanical anchoring but also a large one Find heat transfer contact area. The cooling fins protrude from the base plate in the normal direction, so that the transverse grooves also run in this normal direction. It is also known to provide the grooves in the base plate with grooves which extend in the longitudinal direction, as a result of which better resistance against the removal of cooling fins from the grooves of the base plate would be ensured.

In addition, it is known (DE - 35 18 310 C2) to provide the cooling fins on the side surfaces of the foot end with longitudinal grooves and to implement the good mechanical anchoring to the base plate in the following way: After the cooling fins have been inserted into the grooves, there is a gap between all of them A cooling tool in the form of an embossing die is inserted into each of the adjacent cooling fins. The embossing surface of the embossing dies, which has a pointed cross section, penetrates between the actual holding grooves for the cooling fins and spreads the base plate material located between the fins so that it reduces the cross section of the grooves holding the cooling fins.

In addition, it is also known (EP - 0 696 160 A2, EP 0 759 636 A2 and EP 0 902 469 A2) to use cooling ribs which are U-shaped or meandering in cross-section, each with foot ends of the "U-profiles" in grooves, without Deform base plate material in the groove area. The U-shaped cooling fins are either dovetail-shaped in cross section Grooves clamped or a wire-shaped piece of material is pressed between adjacent webs of the foot part of the U-shaped cooling fins, so that the material of this foot part of the U-shaped cooling fins is permanently deformed outwards and abuts against the side walls of the groove.

The invention is based on the object of improving a cooling device of the type mentioned at the outset with simple means such that, in particular, plate-shaped or plate-shaped cooling fins find a secure hold while ensuring the intended position, in particular in the normal direction to the surface of the base plate, and high extraction values can be achieved. The cooling fins should not only be mechanically firmly connected to the base plate quickly and with little production and assembly effort. This should result in good heat transfer from the base plate to the cooling fins.

The invention is characterized in patent claim 1 with regard to the cooling device, in patent claim 11 with regard to the manufacturing process thereof and in patent claim 16 with regard to a preferred device for manufacturing. Further improvements of the invention are claimed in subclaims and particularly preferred embodiments of the invention are explained in the following description of the figures with reference to the drawings.

According to the invention - in contrast to the prior art according to DE 35 18 310 C2 - not both the side walls of a groove delimiting material parts of the base plate are permanently deformed, but it is ensured that one side wall of each groove when inserting and fastening the The cooling fin in question remains undeformed and determines the mounting position of the cooling fin in question, while only material parts of the other side wall of the groove in question are so permanently deformed, in particular in the direction of the foot part of the cooling fin used, that the cooling fin is firmly anchored there and at the same time the largest possible contact area for forms a favorable heat transfer resistance.

When using this measure in the production according to the method claimed in claim 10, the deformation tool does not have to be inserted into every space, but only into every second space between adjacent grooves and used for permanent deformation of base plate material.

In other words, the surface of the base plate, in which the grooves are located, alternates between a surface which is undeformed and in particular flat when the cooling fins are mounted, and a permanently deformed and in particular concave surface which is pressed inward into the base plate. It has been shown that the invention achieves the above object despite the simplified installation option and therefore faster production. There is another advantage that helps to improve the cooling effect of the cooling device: The distance between the cooling fins in the area of the non-permanently deformed surfaces can be chosen to be smaller, since on the one hand no deformation tool attacks there and on the other hand the non-deformed side walls of the grooves adjust the alignment and define the position of the adjacent cooling fins better, so that the risk of adjacent cooling fins and one another poorer "ventilation" of the gaps between the cooling fins lying against one another is avoided.

It is advisable if the grooves in the still undeformed state of the side walls have a substantially asymmetrical cross-section which opens from the bottom of the groove towards the adjacent surfaces of the base plate at an opening angle β to the normal to the surface of the base plate in question. To a certain extent, this is a reversal of dovetail-shaped profiles with the special feature that each groove forms an angle of 90 ° at a transition point between the groove base and a side wall. The width of the groove base should correspond to the nominal dimension of the foot end of the cooling fin in question.

It is recommended to use cooling fins made of aluminum sheet.

The base plate should also consist of aluminum and is preferably made by extrusion; the grooves are also extruded.

The opening angle ß should be between 2 and 20 °.

In addition, it can be recommended if a distance A is formed in the normal direction between the connecting surface between adjacent grooves in the region of the deformed or to be deformed side walls on the one hand and the surfaces between adjacent undeformed side walls of neighboring grooves. In other words, the connection surface is set back into the base plate in relation to the undeformed surfaces. As a result, the cavity between adjacent beard cooling fins and the permanently deformed base plate part are enlarged and an even better heat transfer from the cooling fins to the surroundings is achieved.

Furthermore, it is advisable to provide the connecting surface between deformed or deforming adjacent side walls with a likewise, in particular, groove-shaped depression which extends parallel to the longitudinal direction of the groove. This ensures that the deformation tool is attacked in a defined line in the longitudinal direction. Even more effective is the use of an embossing stamp, with which a series of, in particular, pyramid-shaped impressions or impressions can be produced in the base material between and parallel to the grooves.

In order to improve the anchoring, ie mechanical fastening of the cooling fins in the grooves, it is expedient to provide the permanently deformable or deformable side walls, in particular at the transition point to the connecting surface between such adjacent side walls, with a projection or profile web which is in particular rounded in cross section, which is embossed when the relevant base plate material is deformed in the direction of the other undeformed side wall onto the adjacent cooling fin surface or in particular into a longitudinal groove extending in the longitudinal direction in the foot region of the cooling fin. The longitudinal groove should be at a distance from the front end of the cooling rib, with which it preferably lies on the groove base. This results in a real "clinging" between the cooling fin and the base plate. In order to make permanent deformation even easier, it is recommended that the cross-section of the base plate between adjacent deformed or to be deformed end walls of adjacent grooves be constricted at a distance from the relevant connecting surface of these side walls to form weakening grooves. As a result, rib-shaped, web-like or tab-shaped material parts of the base plate are formed between the relevant side wall and connecting surface, so that the deformation tool has to do less deformation work when these web-shaped parts are pressed outwards.

The use of particularly stamp-shaped stamping dies, which should in particular have a pointed embossing cross-section on their deforming end faces, is recommended as deformation tools.

The use of embossing rollers as a forming tool offers particular advantages. These embossing rollers are designed as thin disks and expediently provided with a convex embossing cross section on the outer circumference.

Embossing stamps or embossing rollers can be integrated into a common embossing or shaping tool to form several comb segment-like types. In this case, an embossing die or an embossing roller engages in the space between adjacent cooling fins in the base plate surface, while the respectively adjacent interstices of embossing rollers or embossing dies remain free, in contrast to the prior art. This design also differs from the likewise known metal profile production method according to EP 0 868 237 B1, in the case of the base plate material for both Sides of a profile leg part to be anchored in this are permanently deformed.

Exemplary embodiments of the invention are explained in more detail below with reference to the drawings, in which:

Figure 1 is a front view of a cooling device according to the invention in a schematic representation of the spaces between adjacent cooling fins;

Figure 2 with the enlarged Figure 2a, an embodiment of the invention at the beginning of the permanent deformation process;

Figures 3 and 4 with the enlarged representations of Figures 3a and 4a further preferred designs;

5 shows a front view schematically corresponding to FIG. 1 with FIG. 5a a corresponding perspective view of a cooling device according to the invention, in which an embossing stamp consisting of several stamp units is used;

Figures 6 and 6a corresponding representations when using embossing rollers for permanent deformation of base plate material parts

FIG. 7 shows a schematic cross section through a base plate of a cooling device according to the invention in the region of adjacent ribs and

Figure 8 with Figures 8a, 8b and 8c a preferred embossing stamp design and its embossing function. According to FIG. 1, one side of a base plate made, in particular, of aluminum is extruded with a number of longitudinal grooves or longitudinally extending grooves (2), while the electronic and electrical components (4) to be cooled are located on the opposite side of the base plate (1). are located. The cooling fins (3) made of aluminum sheet are anchored with their foot ends (3b) in the grooves (2) so that the surface parts of the base plate (1) between adjacent fins (3) each in the form of on the one hand undeformed surfaces (la) and on the other hand Alternate permanently deformed connecting surfaces (lb) between neighboring grooves.

In the embodiment of Figures 2 / 2a, the foot ends (3b) of the cooling fins (3) are inserted into the grooves (2) so that one side wall (2a) of each groove (2) extends in the normal direction N, that is forms an inclination angle of 90 ° to the flat surface (la) of the base plate (1) outside the groove. The opposite side wall (2b), on the other hand, is inclined at an opening angle β of preferably 10-15 ° to the normal direction N. As a result, the cooling fins (3) can be easily inserted into the grooves (2) up to the groove base (2c). After insertion, a deformation tool (5) is pressed onto the connecting surface (lb) with the embossing surface (5a) with a cross-section, so that this connecting surface (lb) between the oblique side walls (2b) is permanently deformed and base plate material from the transition of the side walls (2b) to the connecting surface (lb) is pressed into longitudinal grooves (3a) of the cooling fins in question, without the base plate material being deformed on the opposite side wall (2a). In the embodiment of Figures 3 / 3a, the side walls (2b) to be deformed or deformed have projections or profile webs (1c) at the transition points to the connection surface (lb), which are expediently rounded and when the deformation tool (5) engages with it here the cross-sectionally convex embossing surface (5b) is pressed onto the adjacent cooling fins (3) and in particular into the longitudinal grooves (3a) located there. The straight and undeformed side walls (2a) form a continuous contact surface K between the base plate (1) and the cooling fin (3).

A further improvement results from the exemplary embodiment in FIGS. 4 / 4a. Here the base plate material is constricted between adjacent deformed or to be deformed side walls (2b) by forming weakening grooves (ld). The projections or profile webs (lc) which are web-like or lobe-shaped in cross-section are then not only permanently deformed downwards when the deformation tool (5) engages, but are also spread out to the side, which additionally achieves a clamping effect which favors the anchoring of the cooling fins. By defining the "kink point", a favorable ratio of the required travel distance to the deformation achieved is approximately 1: 2. In other words: 0.1 mm working stroke of the deformation tool (5) leads to approx. 0.2 mm deformation on both sides. The middle embossing surface part (5b) of the shaping tool (5), which is convexly rounded in cross section, is guided in the longitudinal direction in particular through the groove-shaped depression (2d) shown in cross section in FIG. 7 in the connecting surface (lb).

This is particularly useful if, instead of the stamping technique shown in FIGS. 5 / 5a, the one shown in FIGS. 6 / 6a Embossing roller technology shown is used. In both techniques, a corresponding number of individual stamps or stamping rollers (these in the form of thin disks) are combined to form one stamping unit or one stamping roller unit, so that the permanent deformation of the relevant base plate parts in a single step according to FIG. 5a by moving the deformation tool (5 ) in the direction of the arrow and according to FIG. 6a by moving the rotating embossing roller tool (5) in the longitudinal direction L. There may be further spacers (5c) between the actual embossing rollers with the embossing surfaces (5b) which are convex in cross section, each of which holds adjacent embossing rollers at a defined distance from one another.

According to FIG. 8, the plate-like or sword-like embossing dies (5) on the edge (5d) used for deforming parallel to the longitudinal direction of the grooves have tooth-like embossing elements (5e) which are pyramid-shaped and corresponding pyramid-shaped depressions (2e) in accordance with FIG. 8c impress the material of the base plate (1) between the grooves (2) used for the cooling fins (3). According to FIG. 8a, a stack of embossing stamps provided with such embossing elements (5e) on the lower edge (5d) is used as deformation tools (5) and of plate-shaped elements without embossing tools on the lower edge so that this "embossing unit" comb-like between the in the grooves (2) of the base plate (1) already inserted cooling fins (3) engages. By appropriate pressure of this "embossing unit" on the surface of the base plate (1) between the grooves (2) then on those surface parts on which the pyramid-shaped embossing elements (5e) are arranged, rows of pyramid-shaped depressions (2e) pressed or impressed. Base plate material is pressed apart in the direction of the arrow (FIG. 8c).

This preferred design of embossing dies offers a number of advantages: less embossing force can be used. The base plate material is displaced on all sides. The relatively short distance between the pyramid-shaped or tooth-like embossing elements (5e) reduces the longitudinal extent; this results in a higher lateral expansion and in turn a better embossing or mechanical anchoring of the cooling fins (3). In addition, the embossing elements (5e) penetrate more easily into the base plate surface when the embossing stamps or embossing swords strike the surface of the base plate (1), as a result of which the shaping tool or the embossing sword is better fixed and secured against slipping sideways. This also makes it easier to compensate for profile tolerances.

Claims

wording of the claim

1. Cooling device for in particular electronic components, with a base plate (1), which is provided on one side with a number of longitudinally extending grooves (2) or longitudinal grooves, with plate-like or plate-like cooling fins

(3), whose foot ends (3b) are inserted into the grooves (2) with the formation of heat-transferring contact surfaces with groove walls, and in which parts of the side walls (2a, 2b) of the grooves (2) of the base plate (1) towards in particular the foot ends (3b) of cooling fins (3) are permanently deformed, characterized in that only one side wall (2b) of the respective groove (2) is permanently deformable or deformed, while the other side wall (2a) of the relevant groove (2) remains essentially undeformed.

2. Cooling device according to claim 1, so that the undeformed or non-deformable side wall (2a) forms a flat, in the normal direction (N) on the surface of the base plate (1) extending contact surface (K) for the cooling fin (3) in question.

3. Cooling device according to claim 1 or 2, characterized in that that the groove (2) in the undeformed state of the side walls (2a, 2b) has an essentially asymmetrical cross section, which extends from the groove base (2c) towards the adjacent surfaces (la) or connecting surfaces (lb) of the base plate (1) opens at an opening angle (ß) to the normal (N).

4. Cooling device according to claim 3, d a d u r c h g e k e n n z e i c h n e t that the opening angle (β) is between 2 ° and 20 °.

5. Cooling device according to one of the preceding claims, characterized in that the permanently deformable or deformed side walls (2b) of adjacent grooves (2) connecting connecting surface (lb) on the base plate surface compared to the undeformed surface (la) of the base plate (1) between not deformed side walls (2a) of adjacent grooves (2) is set back by a distance (A).

6. Cooling device according to one of the preceding claims, characterized in that the permanently deformed or deformable side walls (2b) connecting connecting surface (lb) between adjacent grooves (2) has a recess (2d) or a series of recesses which are parallel to the longitudinal direction of the groove extends.

7. Cooling device according to claim 6, characterized in that the depressions (2d) of the row of depressions are formed as pyramid-shaped press-in into the material of the base plate (1).

8. Cooling device according to one of the preceding claims, characterized in that the permanently deformable or to be deformed side walls (2b), in particular at the transition points to the connecting flat (lb), has a projection or profile web (lc) which is in particular rounded in cross section and which in Direction to the other, undeformed or non-deformable side wall (2c) of the groove (2) in question.

9. Cooling device according to one of the preceding claims, that the cooling fins (3) each have at least one longitudinally extending longitudinal groove (3a) at a distance from the ends, with which they preferably abut the groove base (2c).

10. Cooling device according to one of the preceding claims, since you rchgekennzeic hne t that the cross section of the base plate (1) between adjacent deformable or deformable side walls (2b) of adjacent grooves (2) at a distance from the connecting surface (lb) with formation is constricted by weakening grooves (ld).

11. A method for producing a cooling device according to claim 1, in which the cooling fins (3) are inserted into the grooves (2) and the groove wall material of the base plate (1) is permanently deformed by a deformation tool acting on the base plate surface (lb) between grooves (2) , since you rch characterized that the deformation tool (5) only in every second space between adjacent grooves (2) in the connecting surface (lb) is pressed or pressed, which is located between adjacent side walls (2b) of the grooves (2) to be deformed.

12. The method according to claim 11, d a d u r c h g e k e n n z e i c h n e t that stamping dies are used as deformation tools.

13. The method according to claim 11, d a d u r c h g e k e n n z e i c h n e t that embossing rollers are used as deformation tools.

14. The method according to claim 13, d a d u r c h g e k e n n z e i c h n e t that embossing rollers are used which have a convex embossing cross-section (5b) on the outer circumference.

15. The method according to claim 12 or 13, d a d u r c h g e k e n n z e i c h n e t that embossing stamps or embossing rollers are used which have an acute embossing cross-section.

16. Apparatus for carrying out the method according to claim 12, so that the edge (5d) of the sword-like embossing stamp used for the deformation is provided with pointed, in particular pyramid-shaped embossing elements (5e).