DE19600164A1 - Cooling body - Google Patents

Abstract

Cooling body consists of an upper and lower part (2,2') with pegs (5,5') extending into the cooling medium and arranged on one of the inner sides. The pegs are separated by trenches (6). The ratio from the volume amount of the pegs (5,5') and the volume amount of the trenches (6,6') inside both cooling body parts (2,2') along the direct connecting line (7) between a cooling medium outlet (4) and a cooling medium inlet (3) is larger than that in the regions outside of the connecting line (7).

Description

The invention relates to a heat sink according to the preamble of claim 1.

From the patent DE 40 17 749 a heat sink is known, which consists of an upper and a lower half is composed and on the inner surface of such a half cohesive pins are arranged vertically in the flow path of the cooling medium.

The problem with such an arrangement is that heat dissipation is more likely Components on the outer surfaces of the heat sink is inhomogeneous. Between coolant inlet and coolant outlet, the flow path is shorted. Therefore hot ones form Zones on the outside surfaces. The thermal resistance of the arrangement in DE 40 17 749 also has a high thermal resistance of approx. 30 K / kW which leads to overheating of the coolant.

The object of the invention is therefore to provide a heat sink with a pin arrangement the flow conditions in the heat sink improved.

The object is solved by the features of claim 1. Further and advantageous Refinements can be found in the subclaims and the description.

In the heat sink according to the invention, the local density of the pins is chosen so that in Interior of the heat sink there is an essentially homogeneous flow resistance. On Short circuit of the flow path of the coolant is prevented and the coolant flows evenly around the cones.

It is advantageous if the at least one material surface is cohesive attached pins have a shape tapering into the interior of the heat sink respective contact surface of a pin to an inner surface of the heat sink the largest Has cross-sectional area of the pin. The tip of the cones can be pointed or flattened. Of the The thermal resistance of the arrangement is reduced.

It is particularly advantageous to releasably assemble the heat sink from several parts.

The invention is described in more detail below with the aid of figures.

Show it:

Fig. 1a side view of a heat sink b top view of the inside of a heat sink part with unevenly distributed pins

Fig. 2 top view of the inside of a heat sink with aerodynamic pin

Fig. 3 side view of a heat sink with pins on top of each other

Fig. 4 side view of a heat sink with interlocking pins

Fig. 5 structure of a multi-part heat sink

Fig. 6 bracket for connecting the parts of a multi-part heat sink.

Fig. 1a shows the side view of a heat sink 1 according to the invention with an upper and a lower part 2 and 2 '. The connections for coolant inlet 3 and coolant outlet 4 are indicated. The connections 3 and 4 can be arranged on opposite sides or on the same side. The two parts 2 and 2 'are interconnected and can, for. B. glued sintered, screwed or clamped or connected to each other via an intermediate piece. The heat sink is e.g. B. suitable for liquid cooling media but can also be used for gaseous cooling media.

In Fig. 1b is a plan view of the inner surface of the heat sink member 2 is shown the heat sink 1. A plurality of pins 5 are arranged on the inner surface of the heat sink part 2 . The pins 5 are separated by channels 6 and distributed unevenly over the inner surface of the heat sink part 2 . The degree of filling of the pins 5 in the area of the imaginary shortest connecting line 7 between the coolant inlet 3 and the coolant outlet 4 is high, remote therefrom low, so that the flow resistance across the surface is approximately the same for every possible flow path between 3 and 4 . The area with the higher cone density is at least as wide as the smaller the diameter of the cooling water inlet and outlet 3 and 4 .

An average spigot density of 2-7 spigots / cm², in particular 4-6 spigots / cm² in this area is advantageous because with such a density, the tools are still easy to handle for the heat sink 1 in any ceramic process technology. The resulting narrow channel width is advantageous for the flow rate of the cooling medium. The arrangement has a low thermal resistance of only 20 K / kW.

The degree of filling preferably varies from approximately 1: 1 (cavity to volume fraction of material) to 2: 1.  

The advantage is that for the manufacture of the tools for producing such a heat sink, for. B. is still simple by pressing and sintering ceramic. Possible rejects by breaking out pins 5 , 5 or channels 6 are avoided. In addition, the flow rate at the usual coolant flow rates is around 10 l / min large enough for sufficient heat dissipation, but still small enough not to damage the heat sink 1 in an abrasive manner.

The variation in the degree of filling can be achieved by omitting or adding pins 5 , 5 'or by enlarging or reducing pins 5 , 5 ' or channels 6 or changing the pin size or channel size with unchanged channels 6 or pins 5 , 5 '. It is essential here that the maximum of the flow rate of the coolant along the channels 6 in each channel is not more than 50%, in particular not more than 30%, below or above the average flow rate maximum.

The cones can have any base areas and shapes. It turns out, however, that a special base of the pin 5 , 5 'is particularly advantageous.

In Fig. 3 is a plan view of the inner surface of a heat sink part 2 is shown the heat sink 1. On the inner surface of the heat sink part 2 , a multiplicity of aerodynamic pins 5 are arranged. The base of the pins is diamond-shaped, the long diagonal 8 of the pins 5 being arranged approximately parallel to the possible flow path of the cooling medium. The diamond shape is particularly favorable, since no stagnation point can form at the tip of the pin 5 against which flow flows. Instead, the flow of the cooling medium is divided and can flow around and cool the pin 5 .

It turns out that the ratio of surface to volume is very high, especially with this cone shape is cheap, which further improves the possible heat dissipation. When using one well thermally conductive material such. B. aluminum nitride is the heat transfer constant of this Arrangement at over 3000 W / (m² K).

The flow around the pegs 5 with a diamond-shaped base is particularly advantageous if the opening angle of the flowed front tip of each rhombus 5 is between 40 ° and 60 °, in particular between 46 ° -55 °, since the flow velocity around the peg is then maximum or the overflow length is small. At larger angles or z. B. in the case of cylindrical pegs, the formation of stagnation points on the upstream side of the pegs 5 worsens the flow, at lower angles the mechanical stability of the pegs 5 around which it flows decreases. In addition, the overflow length is too great for a given favorable pin density and worsens the heat flow out of the pin 5 .

In Fig. 3 a further advantageous pin shape is shown. The pins 5 run into the interior of the heat sink 1 in a conical shape and contact the inner surface 2 of the heat sink 1 with their largest cross-sectional area. The tip of the cones can be pointed or flattened. Thus, the heat dissipation can be further improved, since any hot side of the heat sink is contacted over a large area and the heat-dissipating pins 5 , 5 'have large-area contact with the cooling medium. At the same time, with this cone shape, expensive basic material can be saved in the manufacture of the heat sink 1 .

In the example shown, the structure of the two heat sink parts 2 , 2 'of the heat sink is symmetrical to the mirror plane 9 between the two heat sink parts 2 and 2 ', the pins 5 , 5 'are directly opposite one another in the fully assembled state of the heat sink 1 .

In FIG. 4 is shown an arrangement which allows a particularly high degree of filling of the pins. The pins 5 , 5 'of the upper and lower heat sink parts 2 , 2 ' are offset from one another and interlocking. So that the coolant speed can be increased even further, since the channels 6 are narrow in the central region of the heat sink 1 , where the two heat sink parts 2 and 2 'meet. In principle, different cone shapes and base areas can also be selected in this arrangement.

In principle, the heat dissipation is optimal when the coolant speed is so high that a turbulent flow develops. But it turns out that at such high Speeds the coolant the heat sink damaged by erosion.

The minimum heat transfer constant R _{th of} the heat sink 1 _{according to} the invention should not be less than 3000 W / (m² K). If the values of R _{th are} lower, the cooling is insufficient. For water as a possible cooling medium, z. B. at 1 kW power loss a minimum flow rate of 0.1 m / sec.

It is essential that the minimum flow rate is not less than 0.1 m / sec. As the upper limit of the flow speed, the coolant speed from which the heat sink 1 is damaged abrasively must not be exceeded. For aluminum nitride, this limit is e.g. B. at about 1 m / sec, with aluminum at about 1.5 m / sec.

Although the flow of the cooling medium, e.g. B. water, is still laminar, the heat sink 1 according to the invention achieves a significant reduction in thermal resistance. The thermal resistance is well below 30 K / kW. For the data mentioned in the example, the value is z. B. at 20 K / kW.

In Fig. 5 a further advantageous embodiment of a heat sink 1 according to the invention is shown with an upper part 2 , a lower part 2 'and an annular central part 2 ''. Coolant inlet and coolant outlet 3 and 4 can be arranged on the middle part 2 '' on opposite sides or the same sides of the circumference of the middle part 2 ''. On the inside of the upper part 2 and the lower part 2 'pins 5 and 5 ' are arranged (only indicated). The parts 2 and 2 'are sealed to the central part 2 ''by means of sealing means 10 and releasably connected. The lower sealant 10 'is not shown. Suitable sealing means are, for example, elastic flat seals or round cord rings, e.g. B. from Perbunan or Viton. The detachable connection can be made via clips, sleeves or the like.

In Fig. 6 such a connecting bracket is shown with which the heat sink parts 2 , 2 'and 2 ''can be detachably connected together. Several clips of this type are arranged on the outer edge of the heat sink 1 . This type of connection is particularly in the stacked arrangement with a plurality of heat sinks connected in series and power components to be cooled z. B. advantageous in electric motor power trains. The actual holding force, which presses the parts together, is applied via the clamping device of the stack, which is typically approximately 40 kN in the known heat sink stacks. Clamping the individual heat sinks considerably simplifies maintenance and the replacement of any defective components or heat sinks from the stack.

The middle part 2 '' itself is hollow and has connections 3 and 4 for the coolant. It is particularly advantageous if this middle part 2 '' consists of metal (aluminum or copper or other inexpensive materials) or of plastic. While the connection of coolant lines is technically complex in the case of ceramic bodies, this is considerably simplified in the arrangement according to the invention. The connections, such as commercially available flange connections or sockets, can e.g. B. via screw thread on the central part 2 '' or connected to this by soldering.

When using insulating, heat-conducting ceramics for the parts 2 and 2 ', a considerable saving of material in the manufacture of the heat sink 1 as a whole and thus a cost saving of the expensive raw materials is possible without deteriorating the required high-voltage suitability of such a cooling arrangement. Likewise, the sealing and the connection of the heat sink parts 2 , 2 ', 2 ''with each other is greatly simplified and the reliability of the heat sink 1 is increased.

A good heat-conducting material is advantageous as the material for the heat sink 1 according to the invention. If a high electrical insulation capacity is necessary, the heat sink 1 can preferably be made of insulator parts, such as. B. aluminum nitride. Silicon carbide, aluminum oxide. Beryllium oxide. Silicon oxide or be formed from laminates which are provided with heat-conducting coatings, for. B. from the above group of insulators or diamond.

Preferably, the multi-part heat sink 1 according to the invention is composed of insulating, preferably all-ceramic parts 2 and 2 'and a metallic or insulating middle part 2 ''.

Claims (20)

1. heat sink consisting of an upper and lower part ( 2 , 2 ') with at least one of the inner sides arranged cohesively and into the cooling medium projecting pins ( 5 , 5 '), which are separated by trenches ( 6 ), characterized in that the ratio of the volume fraction of the pins ( 5 , 5 ') and the volume fraction of the trenches ( 6 , 6 ') in the interior of the two heat sink parts ( 2 , 2 ') in a predetermined area along the imaginary direct connecting line ( 7 ) between a coolant outlet ( 4 ) and a coolant inlet ( 3 ) is larger than in the areas outside the imaginary connecting line ( 7 ). 2. Heat sink according to claim 1, characterized in that the degree of filling of the pin ( 5 , 5 ') is high in a predetermined area along the imaginary shortest connecting line ( 7 ) between a coolant outlet ( 4 ) and a coolant inlet ( 3 ), away therefrom low, so that the flow resistance across the surface is approximately the same for every possible flow path between a coolant outlet ( 4 ) and a coolant inlet ( 3 ). 3. Heat sink according to claim 1-2, characterized in that the predetermined area along the imaginary direct connecting line ( 7 ) between a coolant outlet ( 4 ) and a coolant inlet ( 3 ) is at least as wide as the smaller diameter of the coolant outlet ( 4 ) and Coolant inlet ( 3 ). 4. Heat sink according to claims 1-3, characterized in that the ratio of the volume fraction of the channels ( 6 ) to the volume fraction of the pin ( 5 , 5 ') is between 1: 1 and 2: 1. 5. Heat sink according to claims 1-4, characterized in that the pins ( 5 , 5 ') are formed substantially tapered into the interior of the heat sink, the largest cross-sectional area of the pins ( 5 , 5 ') with the heat sink inside ( 2 , 2 ') Is in contact. 6. Heat sink according to claims 1-5, characterized in that the base of the pins ( 5 , 5 ') is polygonal. 7. Heat sink according to claims 1-6, characterized in that the pins ( 5 , 5 ') are arranged along the flow path with an opening angle of 40 ° to 60 °. 8. Heatsink according to claims 1-7, characterized in that the base of the pin ( 5 , 5 ') is diamond-shaped, the bisector ( 7 ) of a corner of the pin ( 5 , 5 ') against which flow flows substantially parallel to the flow path of the Cooling medium are arranged. 9. Heat sink according to claims 1-8, characterized in that the upper and lower inner surface of the heat sink part ( 2 , 2 ') are provided with pins ( 5 , 5 '). 10. Heatsink according to claims 1-9, characterized in that the pins ( 5 ) of the upper inside of the heat sink ( 2 ) and the pins ( 5 ') of the lower inside of the heat sink ( 2 ') are arranged mirror-symmetrically to one another or offset from one another. 11. A heat sink according to claims 1-10, characterized in that the maximum flow rate of the coolant along the channels ( 6 ) is lower than the speed damaging the heat sink ( 1 ). 12. Heatsink according to claims 1-11, characterized in that the flow rate maximum of the coolant along the channels ( 6 ) in each channel ( 6 ) is not more than 50% below or above the average flow rate maximum. 13. Heat sink according to claims 1-12, characterized in that the thermal resistance of the heat sink ( 1 ) is less than 25 K / kW. 14. Heat sink according to claims 1-13, characterized in that the heat sink ( 1 ) is formed from an insulator such as aluminum nitride, silicon carbide, aluminum oxide, beryllium oxide and / or silicon oxide. 15. Heat sink according to claims 1-14, characterized in that the heat sink ( 1 ) is coated with a heat-conducting material, such as aluminum nitride, silicon carbide, aluminum oxide, silicon oxide and / or diamond. 16. Heat sink according to claims 1-15, characterized in that the heat sink ( 1 ) is equipped with an intermediate part ( 2 '') between the upper and the lower part ( 2 , 2 '). 17. A heat sink according to claim 16, characterized in that the heat sink middle part ( 2 '') is detachably connected to the upper and the lower part ( 2 , 2 '). 18. Heat sink according to claim 16-17, characterized in that the heat sink middle part ( 2 '') is formed from a metallic or electrically insulating material. 19. Heat sink according to claim 16-18, characterized in that the heat sink middle part ( 2 '') is formed from a laminated body with an electrically insulating coating. 20. Heat sink according to claim 16-19, characterized in that the heat sink middle part ( 2 '') is provided with cooling medium connections ( 3 , 4 ).