EP3576894A1

EP3576894A1 - Method for producing a cooling device

Info

Publication number: EP3576894A1
Application number: EP18700336.3A
Authority: EP
Inventors: Martin ROETTGEN; Silvan Hippchen; Zsolt DUDAS; Juergen Steinbach; Robert Schenk; Daniel Engelhardt
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2017-02-01
Filing date: 2018-01-11
Publication date: 2019-12-11
Also published as: WO2018141521A1; CN110248749A; DE102017201583A1; US11478847B2; CN110248749B; US20200001356A1

Abstract

The invention relates to a method for producing a cooling device (10), which has at least one hollow body (30) made of a first material having good thermal conduction and a base body made of a second material having good thermal conduction, and a pre-product for the production of a cooling device (10) and a cooling device (10) for an electrical assembly and an electrical assembly having a cooling device of this kind. The hollow body (30) is coated on the outside with a third material and is filled on the inside with the third material, which has a lower melting temperature than the first material and the second material, wherein the filling (5) completely fills the hollow body and is then cooled, wherein the filled hollow body (30) is placed in a die-casting mould, wherein the second material is introduced into the die-casting mould as die casting with a first temperature and flows around the hollow body (30) at least partially, wherein the die casting melts off the third material of the surface coating (36) and melts on the first material of the hollow body (30) so that at least in regions an integral connection is formed between the die casting of the second material, which forms the base body (20), and the first material of the hollow body (30), wherein the die casting of the second material becomes rigid and solid, wherein during the solidification phase, the die casting of the second material heats the filling (5) made of the third material in the interior of the hollow body (30) until the melting temperature is reached, and wherein the melted third material is removed from the hollow body (30) under pressure.

Description

description

title

The invention is based on a method for producing a cooling device according to the preamble of independent claim 1. The present invention also provides a precursor for the manufacture of a cooling device, a cooling device for an electrical assembly and an electrical assembly with a such cooler.

From the prior art, the pouring of pipe inserts is generally a common method also for automotive assemblies, such as a cooling coil in a die-cast cooler, an oil line in a gearbox, etc. Especially during the production of aluminum die castings into which aluminum tubes are inserted, should during the casting process the stability of the aluminum tube inserts are maintained. The high melting temperature and pressure of the aluminum die casting melt can be particularly critical for the aluminum tube inserts. Therefore, it is known from the prior art to fill the aluminum tube inserts with a salt or sand core to ensure tube stability during the casting process.

After pouring the insert, the salt or sand core filling is removed by an additional rinsing process to ensure the continuity of the tube. DE 10 2008 039 208 A1 discloses the production of aluminum die-cast components with cores which are to form a cavity in the aluminum component and a surface layer of a metal or a metal alloy, in particular copper, nickel, zinc, tin, bismuth (or bismuth), Silicon, copper-tin base alloy, copper-nickel base alloy, copper-zinc base alloy, which for economic reasons after the Casting process remain in the casting. The surface coating acts as a bonding layer between the melt and the core shell and specifically influences the functionality of the core shell part remaining in the casting, in particular with regard to the thermal conductivity between the casting wall of the finished component and the later cavity of the casting filled with a cooling medium.

From DE 10 2011 076 312 AI a cooling device for a housing is known in which at least one component of a power electronics is added. A hollow cooling structure to be encapsulated provides a cooling surface to the housing. The cooling structure to be encapsulated is supported during the production of the housing by a medium which acts on the cooling structure to be encapsulated. Here, the cooling structure to be encapsulated made of aluminum or an aluminum alloy and extends meandering or in a U-shape of an inflow of the medium to a drain of the medium.

Disclosure of the invention

The method for producing a cooling device having the features of independent claim 1 has the advantage that the coating and filling of the at least one hollow body is combined in one process and no additional transport is required. Instead of an additional rinsing process, the filling is removed from the third material due to the material properties in the hot and liquid state directly after pouring advantageously quickly and inexpensively. Since the coating material is used simultaneously to fill the hollow body, the number of materials in the assembly can be reduced, since no additional filler material, such as salt or sand, is required to ensure the stability of the hollow body during the casting process. In addition, the surface coating of the third material protects the surface of the hollow body from oxidation before the hollow body is further processed. The surface coating is advantageously melted due to the high temperature of the die casting of the second material, which is higher than the melting temperature of the third material and washed away from the first material of the hollow body, so that at least partially a cohesive connection between the first material of the hollow body and the second material of the die-cast or the base body is made possible.

Embodiments of the present invention provide a method for producing a cooling device, which comprises at least one hollow body made of a good heat-conducting first material and a base body made of a good heat-conducting second material. In this case, the hollow body is externally coated with a third material and internally filled with the third material, which has a lower melting temperature than the first and second material. The filling fills the hollow body and is then cooled. The filled hollow body is placed in a die-casting mold. Subsequently, the second material is introduced as a die-cast with a first temperature in the die and flows around the hollow body at least partially, wherein the die casting melts the third material of the surface coating and the first material of the hollow body melts, so that at least partially a cohesive connection between the , the main body forming die casting of the second material and the first material of the hollow body is formed. Subsequently, the pressure casting of the second material solidifies and solidifies, wherein the pressure casting of the second material during the solidification phase heats the filling of the third material inside the hollow body until reaching the melting temperature, and wherein the molten third material under pressure from the hollow body Will get removed.

In addition, a precursor for the production of a cooling device is proposed. The precursor comprises a tubular hollow body made of a good heat-conducting first material. Here, the unbent hollow body has on its outer side a surface coating and a filling of a good heat-conducting third material, which has a lower melting point than the first material. The filling completely fills the hollow body. The handling of an unbent hollow body during the coating and filling is easier than with an already bent hollow body.

In addition, embodiments of the present invention provide a cooling device for an electrical assembly. Such a cooling device comprises at least one hollow body made of a good heat-conducting first terial, which is embedded in a base body made of a good heat-conducting second material. Here, between the first material of the at least one hollow body and the second material of the base body on the outside of the at least one hollow body, at least in regions, a material-locking connection is formed. In addition, the hollow body has on its inside a surface coating of a good heat-conducting third material, which has a lower melting temperature than the good heat-conducting first material of the hollow body and the good heat-conducting second material of the base body. Due to the cohesive connection and integration of the hollow body in the base body, a low thermal resistance between the main body and the hollow body can be implemented, so that in an advantageous manner to further measures, such as applying a thermal adhesive, to improve the thermal conductivity between the body and the Hollow body can be dispensed with. In addition, the Oberflächenbe- layering on the inside of the hollow body has the advantage that oxidation of the surface of the hollow body is prevented, so that a good heat transfer between the hollow body and a flowing through the hollow body cooling medium is possible. Such a cooling device can be used in an electrical assembly for cooling at least one electric power component.

The measures and refinements recited in the dependent claims are advantageous improvements of the method specified in the independent patent claim 1 for producing a cooling device, specified in the independent claim 8 precursor for the production of a cooling device, the specified in the independent claim 10 cooling device for an electric Assembly and the specified in the independent claim 14 electrical assembly possible.

It is particularly advantageous that the first material of the hollow body can be aluminum or an aluminum alloy. The second material of the base body may also be aluminum or an aluminum alloy. By using aluminum or an aluminum alloy, the lightweight construction concept and good thermal conductivity can be implemented inexpensively and simply because it is possible to use reliable processes and processes during production. The third material of the surface coating of the hollow body may be, for example, zinc or a zinc alloy or tin or a tin alloy. The tin or zinc materials have significantly higher thermal conductivity values than salt or sand, ie they support during the

Casting process the hollow body not only mechanically, but also thermally. In addition, the low melting temperatures of tin (231 ° C) and zinc (419 ° C) allow a simple and rapid coating or filling of the hollow body made of aluminum, which has a much higher melting temperature (660 ° C), with a maximum temperature of the viscous Die-cast aluminum has a value in the range of about 560 to 580 ° C. Various alloys could further reduce the melting point of the surface coating to aid in the melting of the surface coating of the hollow body by die-casting aluminum. During casting, the tin or zinc material of the filling in the hollow body is still solid, i. of the

Hollow body remains stable. After a very short time (about 1 sec.) The pressure solidifies and becomes solid. In parallel, the tin or zinc material is warmed up in the hollow body and reaches or exceeds its melting point. From this moment, the molten tin or zinc material can be removed from the hollow body with high pressure, for example via a gas injection. That from the

Hollow body removed tin or zinc material can be collected and reused (recycling).

In an advantageous embodiment of the method, the hollow body can be treated with a zincate process before coating and filling. As a result, in particular when using aluminum as the first material, an oxide layer on the hollow body surface can be removed before the surface of the hollow body is protected from renewed oxidation by a surface coating, preferably of a tin or zinc material.

In a further advantageous embodiment of the method, the hollow body can be coated and filled in a coating bath with the third material. By means of such a coating bath, the coating and filling of the hollow body with the third material can be carried out in one process step. In addition, the filling of the hollow body with the molten liquid third material faster and cheaper than the filling with salt or sand feasible.

In a further advantageous embodiment of the method, the filled and cooled hollow body can be cut and bent into a desired shape. It is much easier to bend and cut a precursor which comprises a filled and coated hollow body than to first bend and cut the hollow body and then coat and fill it.

In a further advantageous embodiment of the method, the temperature of the filling can be determined during the solidification phase at the ends of the hollow body. Thus, the pressure to remove the filling may be applied to the hollow body when the temperature of the filling reaches and / or exceeds a predetermined threshold. The predetermined temperature threshold can be chosen so that the third material of the filling has exceeded its melting point and is liquid. In order to recognize this time window optimally and independently of the product, temperature sensors can be provided at the ends of the hollow body. The pressure for blowing out the hollow body can then be controlled by the measured values of the temperature sensors.

In an advantageous embodiment of the precursor, the coated and filled tubular hollow body can be bent and cut into a desired shape directly after cooling.

In an advantageous embodiment of the electrical assembly, the cooling device can be used for example as a base plate of the electrical assembly and / or as part of a housing of the electrical assembly. On this base plate or the housing part then the power components to be cooled can be arranged. Here, the cooling device can be used as a gas cooler, in which a gas for heat removal through the hollow body is passed, or as a liquid cooler, in which a liquid for heat removal is passed through the hollow body.

Embodiments of the invention are illustrated in the drawings and will be explained in more detail in the following description. In the drawing, Draw the same reference numerals components or elements that perform the same or analog functions.

Brief description of the drawings

Fig. 1 shows a longitudinal sectional view of an embodiment of a cooling device according to the invention for an electrical assembly.

FIG. 2 shows a cross-sectional view of the exemplary embodiment of a cooling device according to the invention for an electrical assembly from FIG. 1.

3 shows a schematic flow diagram of an exemplary embodiment of a method according to the invention for producing a cooling device.

Fig. 4 shows a schematic representation of a coating bath with an embodiment of a precursor according to the invention for the production of a cooling device.

5 shows a characteristic curve diagram which represents a first characteristic curve with the temperature profile of a pressure casting and a second characteristic curve with the temperature profile of a filling of a hollow body during the production of a cooling device according to the invention for an electrical assembly.

Embodiments of the invention

As is apparent from FIGS. 1 and 2, the illustrated embodiment of a cooling device 10 for an electrical assembly comprises at least one hollow body 30 made of a good heat-conducting first material, which is embedded in a base body 20 made of a good heat-conducting second material. Here, between the first material of the at least one hollow body 30 and the second material of the base body 20 on the outer side 34 of the at least one hollow body 30 at least partially a cohesive connection is formed. In addition, the hollow body 30 has on its inner side 32 a surface coating 36 made of a good heat-conducting third material, which has a lower melting temperature than the first heat-conducting first Material of the hollow body 30 and the good heat-conducting second material of the base body 20 has.

In the illustrated embodiment of the cooling device 10, the first material of the hollow body 30 is an aluminum wrought alloy and the second material of the

Base is 20 an aluminum die-cast. The third material of the surface coating 36 of the hollow body 30 is zinc in the illustrated embodiment. Of course, other combinations of materials are conceivable, the hollow body 30 can be made for example of copper or a copper alloy or other suitable good heat conducting metal or a metal alloy. The surface coating 36 of the hollow body 30 may, for example, also be a zinc alloy or tin or a tin alloy. In the illustrated embodiment, the hollow body 30 is formed as a meandering curved tube having a round cross section. Of course, the hollow body 30 may also have other shapes and cross sections and be designed, for example, as a U-shaped bent tube with a polygonal cross-section.

Embodiments of the cooling device 10 according to the invention are preferably used for cooling at least one electric power component in an electrical subassembly, which is not shown in greater detail, and which is designed, for example, as a control unit. Thus, the cooling device 10 can be used for example as a base plate of the electrical assembly and / or as part of a housing of the control unit. On this base plate or the housing part then the power components to be cooled can be arranged. Here, the cooling device 10 can be used as a gas cooler, in which a gas for heat removal through the hollow body 30 is passed, or as a liquid cooler, in which a liquid for heat removal is passed through the hollow body 30.

As can be seen from FIGS. 3 and 4, the exemplary embodiment illustrated comprises a method 1 according to the invention for producing a cooling device 10, which comprises at least one hollow body 30 made of a good heat-conducting first material and a base body 20 made of a good heat-conducting second material Steps: In a step S100, the hollow body 30 is externally coated with a third material and internally filled with the third material, which has a lower melting temperature than the first material of the hollow body 30 and the second material of the base body 20. The filling 5 fills the hollow body 30. Subsequently, the filled hollow body is cooled in step S110 and in step S120, the filled hollow body 30 is inserted into a die-casting mold. In a step S130, the second material is introduced as diecasting at a first temperature into the die casting mold and flows around the hollow body 30 at least partially. Here, the die casting melts the third material of the surface coating 36 and the first material of the hollow body 30, so that at least partially a cohesive connection between the, the main body 20 ausbildenden die casting of the second material and the first material of the hollow body 30 is formed. In step S140, the pressure casting of the second material solidifies and solidifies, wherein the pressure casting of the second material during the solidification phase in step S140 heats the filling 5 of the third material in the interior of the hollow body 30 until reaching the melting temperature. In step S150, the molten third material is removed from the hollow body 30 under pressure.

In the illustrated embodiment of the method 1 according to the invention, aluminum or an aluminum alloy is used as the first material for the hollow body 30 and as the second material for the main body 20. As the third material for the surface coating 36 and filling 5 of the hollow body 30, zinc or a zinc alloy is used. Of course, there are others too

Material combinations conceivable, the hollow body 30 can be made for example of copper or a copper alloy or other suitable highly thermally conductive metal or a metal alloy. The surface coating 36 of the hollow body 30 may, for example, also be tin or a tin alloy.

As can also be seen from FIG. 3, the hollow body 30 can be treated with a zincate process in an optional step S50, shown in dashed lines, before the coating and filling in order to remove an oxide layer on the surface of the hollow body 30. 4, the hollow bodies 30 are coated as precursor 3 unbent with a length of about 6 m after the zincate process in step S50 in step S100 in a coating bath 9 with the third material and completely filled. As can be seen from FIG. 4, the hollow body 30 is immersed obliquely into the coating bath 9 and retains this position during the coating and the filling, so that the hollow body 30 is completely filled with the third material, in this case zinc, and air 7 can escape the hollow body 30. When the hollow body 30 is lifted out of the coating bath 9, the lower end of the hollow body 30 is closed tightly. In this state, the hollow body 30 is cooled, so that the third material in the still liquid state can not flow out.

As can also be seen from FIG. 3, the filled and cooled hollow body 30 or the precursor 3 can be in an optional step shown in dashed lines

S115 be bent and cut into a desired shape. The filling 5 increases the stability of the hollow body 30 already during the bending process or the mechanical processing. To an optimal time window for removing the filling 5 from the hollow body

30, the temperature of the filling 5 can be determined at the ends of the hollow body 30 during the solidification phase in step S140. In step S150, the pressure for removing the filling 5 can then be applied to the hollow body 30 when the temperature of the filling 5 reaches and / or exceeds a predetermined threshold value. The predetermined temperature threshold can be chosen so that the third material of the filling 5 has exceeded its melting point and is liquid. In order to recognize this time window optimally and independently of the product, temperature sensors can be provided at the ends of the hollow body 30. The pressure for blowing out the hollow body 30 can then be controlled by the measured values of the temperature sensors. In a filling of the hollow body 30 with zinc, the pressure could be activated, for example, at a temperature of the filling 5 of about 450 ° C. The pressure could be deactivated again if the temperature drops below 420 ° C. With a filling 5 of the hollow body 30 with tin, the pressure could be activated, for example, at a temperature of the filling 5 of more than 250 ° C. the. The pressure could be deactivated again if the temperature drops below 235 ° C. During this process, the pressure loss can be measured and thus the continuity of the hollow body 30 can be checked or checked. For example, temperature sensors can be provided at the position of the ends of the hollow body 30. The third material of the filling 5, which is removed from the hollow body 30 can be collected used again (recycling).

As can be seen from FIG. 5, the aluminum used in the illustrated embodiment, which is introduced into the die mold as a pressure casting in step S130 and whose temperature profile shows a first characteristic curve K, has a fixed first state ZI up to the time t1. During a first time window tF (AI) between the time t1 and a second time t2, the aluminum alloy casting introduced has a liquid or viscous state Z2 and a temperature in the range from 400 to 580 ° C. From the time t2 solidifies the aluminum die-cast and again has the fixed first state ZI. As the first characteristic curve Kl shows, the die-cast aluminum cools slowly. As can also be seen from FIG. 5, the filling 5 of the hollow body 30, whose temperature profile shows a second characteristic K2, still has the fixed first state ZI during the casting, ie the hollow body 30 remains stable. After the first time window tF (AI), which is very short (about 1 second), the pressure casting solidifies and becomes solid. In parallel, the filling 5 is warmed up in the hollow body 30 by the hot die casting and the melting temperature of the filling 5 is reached or exceeded. When tin is used, the filling 5 reaches its melting temperature at a third time t3 and changes to the liquid or viscous state Z2 for the duration of a second time window tF (Zn). When using zinc, the filling 5 reaches its melting temperature at a fourth time t4 and changes to the liquid or viscous state Z2 for the duration of a third time window tF (Sn). From a fifth point in time t5, the filling 5 again solidifies again to the fixed first state ZI. Thus, with the use of tin during the second time window tF (Zn), the molten charge 5 can be removed from the hollow body 30 at high pressure. When using zinc, the molten filling may be 5 times The third time window tF (Sn) is substantially shorter than the second time window tF (Zn), the end of which and the transition to the fixed first state due to the third time window tF (Sn) are removed from the hollow body 30 at high pressure Scaling the graph is no longer visible.

Claims

claims

1. A method (1) for producing a cooling device (10) which comprises at least one hollow body (30) made of a good heat-conducting first material and a base body (20) made of a good heat-conducting second material, characterized in that the hollow body (30) externally coated with a third material and internally filled with the third material, which has a lower melting temperature than the first and second material, wherein the filling (5) fills the hollow body and is then cooled, wherein the filled hollow body (30) in a Die casting mold is inserted, wherein the second material is introduced as a die-cast with a first temperature in the die and at least partially flows around the hollow body (30), wherein the die-casting the third material of the surface coating (36) melts and the first material of the hollow body (30) melts, so that at least partially a cohesive connection between the, the main body (20) forming die casting of the second material and the first material of the hollow body (30) is formed, wherein the die casting of the second material solidifies and solidifies, wherein the die casting of the second material during the solidification phase, the filling (5) from the heated third material in the interior of the hollow body (30) until reaching the melting temperature, and wherein the molten third material under pressure from the hollow body (30) is removed.

2. Method (1) according to claim 1, characterized in that the first material of the hollow body (30) and / or the second material of the base body (20) is aluminum or an aluminum alloy and the third material of the surface coating (36) of the hollow body ( 30) is zinc or a zinc alloy or tin or a tin alloy. Method (1) according to claim 1 or 2, characterized in that the hollow body (30) is treated prior to coating and filling with a zincate process.

Method (1) according to one of Claims 1 to 3, characterized in that the hollow body (30) is coated and filled with the third material in a coating bath (9).

Method (1) according to one of claims 1 to 4, characterized in that the filled and cooled hollow body (30) is bent and cut into a desired shape.

Method (1) according to one of claims 1 to 5, characterized in that the temperature of the filling (5) is determined during the solidification phase at the ends of the hollow body (30).

Method (1) according to claim 6, characterized in that the pressure for removing the filling (5) is applied to the hollow body (30) when the temperature of the filling (5) is a predetermined one

Threshold reached and / or exceeds.

Preproduct (3) for the production of a cooling device (10), with a tubular hollow body (30) made of a good heat-conducting first material, characterized in that the unbent hollow body (30) on its outer side (34) has a surface coating (36) and a Filling (5) of a good heat-conducting third material having a lower melting point than the first material, wherein the filling (5) completely fills the hollow body (30).

Precursor (3) according to claim 8, characterized in that the coated and filled tubular hollow body (30) is bent and cut to a desired shape.

Cooling device (10) for an electrical assembly, comprising at least one hollow body (30) made of a good heat-conducting first material, which is embedded in a base body (20) made of a good heat-conducting second material, characterized in that between the first material of the at least one hollow body (30) and the second material of the base body (20) on the outer side (34) of the at least one hollow body (30) at least partially a cohesive connection is formed, wherein the hollow body (30) on its inner side (32) has a surface coating (36) of a good heat-conducting third material, which has a lower melting temperature than the good heat-conducting first material of the hollow body (30 ) and the good heat-conducting second material of the base body (20).

Cooling device (10) according to claim 10, characterized in that the first material is aluminum or an aluminum alloy.

Cooling device (10) according to claim 10 or 11, characterized in that the second material is aluminum or an aluminum alloy.

Cooling device (10) according to one of claims 10 to 12, characterized in that the third material is zinc or a zinc alloy or tin or a tin alloy.

Electrical assembly with at least one electrical power component and a cooling device (10) which cools the at least one electrical power component, characterized in that the cooling device (10) is designed according to at least one of claims 10 to 13.

Electrical assembly according to claim 14, characterized in that the cooling device (10) is integrated in a housing of the electrical assembly and / or forms a base plate of the electrical assembly.