DE102016222629A1 - Cooling device and method of manufacturing a cooling device - Google Patents

Abstract

Cooling device (1) for cooling heat-producing components (13), the cooling device (1) comprising at least one heat sink (2) with a bottom section (5) and pin sections (6), wherein the pin sections (6) each correspond to the bottom section (5). associated first end and a free second end, at least one cover element (3) and at least one flow channel (8) for a cooling medium, wherein the at least one flow channel (8) has a closed cross section with a first wall (9) and one of the first Wall (9) opposite the second wall (10), wherein the bottom portion (5) of the at least one heat sink (2), the first wall (9) and the pin sections (6) each from the first wall (9) up to extending the second wall (10), and methods of manufacturing a cooling device (1).

Description

The invention relates to a cooling device for cooling of heat-producing components, the cooling device having at least one heat sink with a bottom portion and pin portions, wherein the pin portions each having a bottom portion associated with the first end and a free second end, at least one cover element and at least one flow channel for a cooling medium ,

In addition, the invention relates to a method for producing a cooling device for cooling heat-producing components, the cooling device having at least one heat sink with a bottom portion and pin portions, the pin portions each having a base portion associated with the first end and a free second end, at least one cover element and at least an intermediate element, wherein the bottom portion of the at least one heat sink and the at least one intermediate element define a flow channel for a cooling medium.

From the DE 10 2014 214 209 A1 a cooling device is known for cooling electronic and / or electrical components, in particular arranged on a circuit board power semiconductors, comprising at least one heat sink with arranged on a surface of the heat sink, protruding heat sinks, wherein the heat sink for thermal coupling with the electronic and / or electrical Components is provided, at least one cooling medium distribution element for the targeted spatial distribution of a cooling medium at defined heat points of the heat sink, a cooling device interior, which is enclosed by the heat sink and connectable to the heat sink heat sink, which at least the protruding heat sinks of the heat sink and the cooling medium Distribution element includes and at least one inlet opening for a supply of the cooling medium in the cooling device interior and at least one outlet opening for a discharge de s Cooling fluid from the radiator interior.

From the KR 101396905 B designs of a pin structure are known to improve heat transfer in a pin heat sink. It is proposed to provide pins of the pin heat sink with a coolant channel extending at an angle to a heat sink base and to a pin axis. It is also proposed to provide the heat sink bottom with indentations.

The invention has for its object to improve an initially mentioned cooling device structurally and / or functionally. In addition, the invention has for its object to improve a method mentioned above.

The object is achieved with a cooling device having the features of claim 1.

The cooling device can serve for heat dissipation. The cooling device can serve for heat dissipation, in particular by heat conduction and / or convection. The heat-producing components may be electrical, electronic and / or power electronic components and / or components. The cooling device may be for use in a vehicle, in particular in a motor vehicle. The vehicle may have at least one drive machine, in particular an internal combustion engine and / or an electric machine. The vehicle may have a transmission. The vehicle may be a hybrid electric vehicle.

The at least one heat sink can be made in one piece. The at least one heat sink may be made of a plurality of interconnected parts. If the at least one heat sink is made of a plurality of interconnected parts, the parts can be positively non-positively, positively and / or cohesively connected thermally conductive. The at least one heat sink may be made of a good thermal conductive material, in particular of aluminum or an aluminum alloy, such as Al99.5, or of a plastic. The bottom portion may have a plate-like shape. The bottom portion may have a planar or curved shape. The pin portions may each have a longitudinal axis. The pin sections can be arranged with their longitudinal axes at an angle, in particular at least approximately at right angles, to the bottom section. The pin sections can be arranged regularly or irregularly distributed. The pin sections may be arranged in rows and columns. The pin sections can be distributed in a matrix-like or array-like manner. The pin portions may have the same or different lengths. The pin portions may each have a circular, oval or polygonal cross-section. The pin portions may each be connected at their first ends to the bottom portion. The at least one heat sink may be a pin heat sink. A pin heat sink may also be referred to as a PinFin heat sink.

The at least one flow channel may have a quadrangular cross-section. The at least one flow channel may have an inlet and an outlet. The first wall and the second wall may be at least approximately parallel to each other and spaced apart from each other. The at least one flow channel may have two side walls. The side walls For example, the first wall and the second wall may join together to form a closed cross-section.

Each of the pin portions may extend from the first wall to the second wall. A plurality of the pin portions may extend from the first wall to the second wall, with some of the pin portions not extending to the second wall. The pin portions may each extend with its second end to the second wall. The pin sections can each conclude gap-free with the second wall. In this context, "gap-free" refers in particular to a fluid-mechanical gap.

The at least one cover element may have a plate-like shape. The at least one cover element may have a planar or curved shape. The second wall may be formed by means of the at least one cover element.

The cooling device may have at least one intermediate element. The at least one intermediate element may have a plate-like shape. The at least one intermediate element may have a planar or curved shape. The second wall may be formed by means of the at least one intermediate element. The at least one intermediate element may be arranged between the second ends of the pin sections and the at least one cover element. The at least one intermediate element can be arranged on the at least one cover element and with its receptacles on the second ends of the pin sections. The at least one intermediate element can be arranged between the bottom section of the at least one heat sink and the at least one cover element and with its receptacles on the shafts of the pin sections. The at least one intermediate element may be arranged at a distance from the bottom section of the at least one heat sink and the at least one cover element. The at least one intermediate element may be arranged parallel to the bottom section of the at least one heat sink and / or to the at least one cover element. The cooling device may have a first intermediate element and at least one further intermediate element. The first intermediate element and the at least one further intermediate element may each extend over different sections of the cross section of the flow channel and / or over a different length of the cross section of the flow channel.

The at least one cover element can have receptacles. The at least one intermediate element may have receptacles. The recordings can be designed as through holes or as blind holes. In the recordings, the second ends of the pin sections may be included. The recordings can be arranged according to an arrangement of the pin sections. The recordings can be contoured according to a cross section of the pin sections.

The at least one cover element can be thermally conductively connected to the pin sections. The at least one intermediate element can be thermally conductively connected to the pin sections. The at least one cover element or the at least one intermediate element and the pin sections can be connected to one another in a force-locking, positive-locking and / or materially bonded thermally conductive manner.

The at least one cover element or the at least one intermediate element may comprise turbulators. The turbulators can be arranged regularly or irregularly distributed. The turbulators can be arranged in rows and columns. The turbulators can be distributed in a matrix-like or array-like manner. The turbulators may be arranged between the pin sections. The turbulators can serve to convert a laminar flow into a turbulent flow. The turbulators can be used for flow diversion. The turbulators can each convex, for example, as nubs, or concave, for example, as recesses, such as holes, be executed. The turbulators can each be wing-shaped.

The bottom portion of the at least one heat sink may serve for thermal bonding to the heat producing components. The at least one cover element can serve for thermal connection to the heat-producing components.

In addition, the object underlying the invention is achieved with a method having the features of claim 9.

When applied to the second ends of the pin portions of the heat sink, the intermediate element may have no or only preformed recordings. When pressing the intermediate element on the pin portions of the heat sink, the images can be formed or completed. The cover element and / or the pin sections of the heat sink can / can serve as pressing tool, punching tool and / or forming tool.

When pressing the intermediate element on the pin portions of the heat sink, the pin portions can penetrate the intermediate element and form the receptacles as recesses. When pressing the intermediate element on the Pin portions of the heat sink may be formed on the intermediate element turbulators. The turbulators can be formed by means of the cover element.

By "may" in particular optional features of the invention are referred to. Accordingly, there is an embodiment of the invention each having the respective feature or features.

In summary and in other words, the invention thus provides, inter alia, an electronic cooling by means of a cooling fluid flowing through a PinFin cooler whose PinFin base plate has direct contact with the electronics and whose fluid flow guidance is optimized by means of inserts (punching plates). By means of the invention, pressure losses for flow optimization are controlled by insert sheets. It can be used insert sheets of various designs and types. A lid can be designed as a negative mold. In addition to improved flow guidance, the cover can also be used as a punching, embossing and indenting tool. The invention can be used in any planar and curved surfaces with PinFin or ribs for improved heat dissipation. Here, too, the function can be optimized by means of inserts and / or a designed lid structure.

An insert plate (turbulator plate) placed on PinFins minimizes flow through the PinFin tip. Depending on how far the insert plate is inserted, a flow channel is reduced, so that the flow is managed skilfully. This change allows space-optimized inlet and outlet channels. So simple customer applications are feasible. The insert sheets can be connected to the PinFins and thus allow an increase in the heat delivery area. By impressing nubs, holes, turbulators heat transfer can be adjusted. Due to the thus excited turbulent flow, the cross section of the cooling channel can be increased with the same cooling performance and thus a pressure loss can be reduced. If a cap of the flow channel is designed with a negative shape to the PinFins, the flow through the PinFin tip can be minimized. An insert plate can be omitted. If the shape of the lid executed skillful, this can also take over a function of a punching tool. Thus it may be sufficient to prefabricate the insert plate flat with holes in the shape of the flow channel. An impression of a structure can be made by the shape of the lid. This can then take over a punching and inserting function for the insert sheet. In summary, a heat input into a cooling fluid can thus be optimized via the flow. There are significant cost advantages compared to conventional systems. Furthermore, this solution offers greater design freedom for the designer and thus better integration options.

If this invention is applied to housing surfaces of any technical design, it can be dispensed with by inserting one or more insert sheets and with or without a negative mold in the lid on an external heat exchanger. It is also conceivable that the heat transfer is improved on an inner side of the construction via PinFin structures. Again, the invention can be applied. In addition to flat walls, the invention is also suitable for round surfaces. It is conceivable to attach the pins on a side facing away from the electronics. If a bottom plate with corresponding holes is applied to a cooler, contact the pins with the bottom plate. This can be a cheap power module produce, which has a very good thermal connection to the cooling medium.

Hereinafter, embodiments of the invention will be described with reference to figures. From this description, further features and advantages. Concrete features of these embodiments may represent general features of the invention. Features associated with other features of these embodiments may also constitute individual features of the invention.

The invention provides a particularly compact and efficient cooling device or a method for the production thereof. A conventional heat transfer is increased. A pressure loss is reduced. A heat sink temperature is evened out. A manufacturing effort is reduced. Tolerance requirements are reduced.

• 1 eine Kühlvorrichtung mit einem Stiftkühlkörper und einem wandbildenden Zwischenelement in perspektivischer Ansicht,
• 2 eine Kühlvorrichtung mit einem Stiftkühlkörper, einem Deckelement und einem wandbildenden Zwischenelement in Schnittansicht,
• 3 ein Zwischenelement mit Turbulatoren einer Kühlvorrichtung,
• 4 ein Zwischenelement mit Turbulatoren, einen Stiftkühlkörper und ein Deckelement einer Kühlvorrichtung,
• 5 eine Kühlvorrichtung mit einem Stiftkühlkörper und einem wandbildenden Deckelement,
• 6 eine Kühlvorrichtung mit einem Stiftkühlkörper, einem wandbildenden Deckelement und einem wärmeproduzierenden Bauteil,
• 7 eine Kühlvorrichtung mit einem Stiftkühlkörper, einem Deckelement und einem strömungsleitenden Zwischenelement in perspektivischer Ansicht,
• 8 eine Kühlvorrichtung mit einem Stiftkühlkörper, einem Deckelement und einem strömungsleitenden Zwischenelement in Schnittansicht,
• 9 ein Zwischenelement mit Turbulatoren einer Kühlvorrichtung,
• 10 eine Kühlvorrichtung mit einem Stiftkühlkörper, einem Deckelement und mehreren strömungsleitenden Zwischenelementen mit Turbulatoren und
• 11 eine Kühlvorrichtung mit einem Stiftkühlkörper, einem Deckelement und mehreren strömungsleitenden Zwischenelementen mit Turbulatoren.

They show schematically and by way of example:

• 1 a cooling device with a pin heat sink and a wall-forming intermediate element in a perspective view,
• 2 a cooling device with a pin cooling body, a cover element and a wall-forming intermediate element in sectional view,
• 3 an intermediate element with turbulators of a cooling device,
• 4 an intermediate element with turbulators, a pin heat sink and a cover element of a cooling device,
• 5 a cooling device with a pin heat sink and a wall-forming cover element,
• 6 a cooling device with a pin heat sink, a wall-forming cover element and a heat-producing component,
• 7 a cooling device with a pin cooling body, a cover element and a flow-conducting intermediate element in a perspective view,
• 8th a cooling device with a pin cooling body, a cover element and a flow-conducting intermediate element in sectional view,
• 9 an intermediate element with turbulators of a cooling device,
• 10 a cooling device with a pin heat sink, a cover element and a plurality of flow-conducting intermediate elements with turbulators and
• 11 a cooling device with a pin heat sink, a cover element and a plurality of flow-conducting intermediate elements with turbulators.

1 shows a cooling device 1 with a pin heat sink 2 and a wall-forming intermediate element 4 in perspective view. 2 shows the cooling device 1 with the pin heat sink 2 , a cover element 3 and the wall-forming intermediate element 4 in sectional view. The cooling device 1 is used for cooling of heat-producing components, such as power electronic components of a motor vehicle by heat conduction and / or convection.

The pin heat sink 2 has a bottom section 5 and pin portions such as 6. The bottom section 5 has a flat plate-like shape. The bottom section 5 is used for thermal connection with a heat-producing component. The pen sections 6 are arranged distributed in a matrix and each have a bottom portion 5 associated first end and a free second end.

The cover element 3 and the intermediate element 4 Each has a flat plate-like shape and are arranged adjacent to each other. The intermediate element 4 indicates the pin sections 6 correspondingly arranged holes, such as 7, on. The bottom section 5 of the pin heat sink 2 on the one hand and the cover element 3 and the intermediate element 4 on the other hand are arranged parallel to each other and spaced from each other. The second ends of the pin sections 6 are in the holes 7 of the intermediate element 4 added.

The cooling device 1 has a flow channel 8th for a cooling medium. The flow channel 8th has a closed cross section with a first wall 9 and one of the first wall 9 opposite second wall 10 on. The bottom section 5 of the pin heat sink 2 forms the first wall 9 , The intermediate element 4 forms the second wall 10 , The pen sections 6 each extend from the first wall 9 up to the second wall 10 ,

For making the cooling device 1 becomes the intermediate element 4 on the free ends of the pin sections 6 of the pin heat sink 2 put on and using the cover element 3 pressed and punched. The intermediate element 4 serves to a cooling medium flow 11 to steer.

3 shows an intermediate element 4 with turbulators, like 12, a cooler. 4 shows the intermediate element 4 , a pin heatsink 2 and a cover element 3 a cooling device. The turbulators 12 are regularly distributed between the pen sections 6 arranged and serve to convert a laminar cooling medium flow in a turbulent cooling medium flow. The turbulators 12 In the present case, they are in each case ramp-shaped. The turbulators 12 are when pressing the intermediate element 4 on pen sections 6 of the pin heat sink 2 produced in one operation. Incidentally, in addition to particular 1 and 2 and the associated description.

5 shows a cooling device 1 with a pin heat sink 2 and a wall-forming cover element 3 , The cover element 3 indicates the pin sections 6 of the pin heat sink 2 correspondingly arranged holes 7 on, in which the free ends of the pin sections 6 of the pin heat sink 2 are included. In this embodiment, eliminates the intermediate element and the cover element 3 forms the second wall 10 , Incidentally, in addition to particular 1 to 4 and the associated description.

6 shows a cooling device 1 with a pin heat sink 2 , a wall-forming cover element 3 and a heat-producing component 13 , The heat-producing component 13 is outside of the cover element 3 arranged. Incidentally, in addition to particular 1 to 5 and the associated description.

7 shows a cooling device 1 with a pin heat sink, a cover element 3 and a flow-conducting intermediate element 4 in perspective view. 8th shows the cooling device 1 in sectional view. The pen sections 6 each have a the bottom section 5 associated first end, a free second end and a shaft disposed between the ends on. The intermediate element 4 is from both the bottom section 5 of Pin heat sink 2 as well as from the cover element 3 spaced with his holes 7 at the shanks of the pin sections 6 arranged. The intermediate element 4 is thus in the flow channel 8th between the first wall 9 and the second wall 10 arranged. Incidentally, in addition to particular 1 to 6 and the associated description.

9 shows an intermediate element 4 with turbulators, like 12, a cooler. The turbulators 12 are each plate-like or wing-like. The turbulators 12 are on the intermediate element 4 arranged flat or angularly employed. Incidentally, in addition to particular 1 to 8th and the associated description.

10 shows a cooling device 1 with a pin heat sink 2 , a cover element 3 and a plurality of flow-conducting intermediate elements 4 . 14 with turbulators, like 12. 11 shows a further cooling device 1 with a pin heat sink 2 , a cover element 3 and a plurality of flow-conducting intermediate elements 4 . 14 with turbulators, like 12. The intermediate elements 4 . 14 are each from both the bottom section 5 of the pin heat sink 2 as well as from the cover element 3 as well as spaced from each other with their holes 7 at the shanks of the pin sections 6 arranged. The intermediate elements 4 . 14 are thus in the flow channel 8th between the first wall 9 and the second wall 10 arranged. The intermediate element 4 extends at least approximately over the entire cross section of the flow channel 8th , The intermediate element 14 extends only over part of the cross section of the flow channel 8th , The turbulators 12 are at the intermediate elements 4 . 14 in this case arranged in each case flat or vertical. Incidentally, in addition to particular 1 to 9 and the associated description.

LIST OF REFERENCE NUMBERS

1

cooler

2

Heat sink, pin heat sink

3

cover element

4

intermediate element

5

bottom section

6

pin section

7

Recording, hole

8th

flow channel

9

first wall

10

second wall

11

Coolant flow

12

turbulator

13

heat-producing component

14

another intermediate element

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102014214209 A1 [0003]
• KR 101396905 B [0004]

Claims (10)

Cooling device (1) for cooling heat-producing components (13), the cooling device (1) comprising at least one heat sink (2) with a bottom section (5) and pin sections (6), wherein the pin sections (6) each correspond to the bottom section (5). associated first end and a free second end, at least one cover element (3) and at least one flow channel (8) for a cooling medium, characterized in that the at least one flow channel (8) has a closed cross-section with a first wall (9) and a the first wall (9) opposite the second wall (10), wherein the bottom portion (5) of the at least one heat sink (2) forms the first wall (9) and the pin portions (6) respectively starting from the first wall (9) extend to the second wall (10). Cooling device (1) after Claim 1 , characterized in that the second wall (10) is formed by means of the at least one cover element (3). Cooling device (1) after Claim 1 , characterized in that the at least one cooling device (1) comprises at least one intermediate element (4) arranged between the second ends of the pin sections (6) and the at least one cover element (3) and the second wall (10) by means of the at least one intermediate element ( 4) is formed. Cooling device (1) according to at least one of Claims 1 to 3 or after Claim 3 , characterized in that the at least one cover element (3) or the at least one intermediate element (4) receptacles (7), in which the second ends of the pin portions (6) are accommodated. Cooling device (1) according to at least one of Claims 1 to 4 or after at least one of Claims 3 to 4 , characterized in that the at least one cover element (3) or the at least one intermediate element (4) with the pin portions (6) is thermally conductively connected. Cooling device (1) according to at least one of Claims 1 to 5 or after at least one of Claims 3 to 5 , characterized in that the at least one cover element (3) or the at least one intermediate element (4) comprises turbulators (12). Cooling device (1) according to at least one of the preceding claims, characterized in that the bottom portion (5) of the at least one heat sink (2) for thermal connection with the heat-producing components (13). Cooling device (1) according to at least one of the preceding claims, characterized in that the at least one cover element (3) for thermal connection with the heat-producing components (13) is used. Method for producing a cooling device (1) for cooling heat-producing components (13), the cooling device (1) comprising at least one heat sink (2) with a bottom section (5) and pin sections (6), wherein the pin sections (6) each have a Bottom portion (5) associated first end and a free second end, at least one cover element (3) and at least one intermediate element (4), wherein the bottom portion (5) of the at least one heat sink (2) and the at least one intermediate element (4) Limiting flow channel (8) for a cooling medium, characterized in that the cover element (3) with the pin portions (6) of the heat sink (2) corresponding receptacles (7), first the intermediate element (4) at the second ends of the pin portions (6 ) of the heat sink (2) is applied and subsequently the intermediate element (4) by means of the cover element (3) on the pin portions of the heat sink (2) is pressed, the Au (7). Method according to Claim 9 , characterized in that upon pressing the intermediate element (4) on the pin portions (6) of the heat sink (2) on the intermediate element (4) turbulators (12) are formed.

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