WO2020011583A1

WO2020011583A1 - Process for producing a material composite, material composite and use of the material composite as a heat conductor and heat exchanger

Info

Publication number: WO2020011583A1
Application number: PCT/EP2019/067593
Authority: WO
Inventors: Jens Rießelmann; Thomas Hutsch; Thomas WEISSGÄRBER
Original assignee: Fraunhofer-Gesellschaft zur Förderung der angewandten Forschung e.V.; Technische Universität Berlin
Priority date: 2018-07-09
Filing date: 2019-07-01
Publication date: 2020-01-16
Also published as: DE102018116559B4; DE102018116559A1; EP3821045A1; EP3821045B1; US20210339314A1

Abstract

The invention relates to a process for producing a material composite (200) comprising the steps: producing (S100) a composite material (20) that extends along an axis of elongation (z), composed of carbon nanostructures anchored in a matrix of a first metal (24), preferably carbon nanostructures (22) wherein the carbon nanostructures (22) extend along the axis of elongation (z) of the composite material (20); subdividing (S200) the composite material (20) into segments (30) of the composite material (20); arranging (S400) the segments (30) in a plane of a die (100); filling (S500) cavities in the die (120) with a filler material (130); sintering (S600) in the die (100) to form a material composite (200), and exposing the carbon nanostructures (22) of the composite material (20) on at least one surface of the composite material (200), so that the carbon nanostructures (22) project from this surface. Also proposed are a material composite and the use thereof as a heat conductor and/or heat exchanger.

Description

Process for producing a composite material, a composite material and use of the composite material as a heat conductor and heat exchanger

The invention relates to a method for producing a composite material, a composite material and a use of the composite material as a heat conductor and heat exchanger.

Wherever heat occurs in electronic components as a result of a power loss, this must also be dissipated in order to avoid overheating of the components. There are a number of applications in the prior art which benefit from an increased heat flow between two surfaces. Especially in spacecraft, in which convection cannot take place due to the environmental conditions, the conduction-based heat transfer between two surfaces is crucial. The temperature in the components can be better regulated by an increased thermal connection of the components to the remaining satellite bus and in particular to radiators. If surfaces are connected to one another, heat flows between them depending on, among other things, the contact area, the roughness, the contact pressure and the material properties. The effective contact area is significantly reduced because the surfaces are not flat microscopically. This is shown in FIGS. 1 and 2 using two different contact layers 1 and 2. One way to increase this area is to polish or lap the surface, but a microscopic residual roughness remains even then.

The heat flow between the surfaces takes place not only via the contact surfaces, but also via the gaps between the surfaces via radiation or thermal conduction or convection of the medium located between them. However, there is no convective heat conduction in a vacuum.

In order to increase the heat conduction between two surfaces, various "Thermal Interface Materials (TIMs)" have been developed so far, which are filled in the gaps.

As a standard, thermally conductive gels, pastes or other materials, some of which are based on carbon, are used, but usually not are reusable, but must be replaced when contacting them again.

Carbon nanostructure arrays can be used as thermal interface materials, since the carbon nanostructures, preferably carbon nanotubes (CNT), have a thermal conductivity of up to 3500 W / m K along their growth direction. The US Pat. No. 7,416,019 offers such an option for an interface based on carbon nanotubes as “thermal interface materials”. In this, the carbon nanotubes are attached to the surface or grown on the surface of a metal.

The task is to provide a reusable and effective interface for heat conduction and transfer between two surfaces.

The method according to the invention for producing a composite material basically comprises the following steps: producing a composite material, which extends along an expansion axis, from carbon nanostructures anchored in a matrix of a first metal; Divide the composite into segments, especially by sawing, e.g. along or perpendicular to the axis of expansion of the composite; Arranging the segments in a plane of a die; Filling free spaces in the die with a filler material, sintering in the die to form a composite material, exposing the carbon nanostructures of the composite material from at least one surface of the composite material so that the carbon nanostructures protrude from this surface and in some cases remain anchored in the base material.

This method has the advantage that, on the one hand, due to the outstanding carbon nanostructures, the contact area between two surfaces is enlarged and, on the other hand, an interface made from such a composite material is designed to be releasable by means of carbon nanostructures stably integrated in the metal matrix.

Structures such as round carbon nanoparticles, such as, for example, fullerenes and amorphous carbons, or layered carbon nanoparticles, such as, for example, graphene and nanoplatelets, or fibrous carbon nanoparticles, such as, for example, carbon nanotubes and Carbon nanofibers, understood. The carbon nanostructures are preferably carbon nanotubes.

The invention thus enables an enlargement of the interface area and / or contact area of a releasable and reusable thermal interface, as a result of which the heat flow between two surfaces is increased.

The carbon nanostructures can extend randomly in the metal. In a preferred exemplary embodiment, the carbon nanostructures extend along the axis of expansion of the composite material. After the carbon nanostructures have been exposed, they preferably protrude in one direction from the surface of the composite material. This enables improved contact, improved heat transport and improved reusability of the interface.

The composite material can in particular be a rod-shaped composite material and the cross-sectional area of the rod-shaped composite material can have any geometric basic shape, in particular a circular, trapezoidal, rectangular or square basic shape or be formed from circular segments.

The method preferably comprises the following steps, which follow the sintering in the die: The shaping of the sintered body by reshaping, e.g. by extrusion, ECAP (Equal Channel Angular Pressing) or round hammers, machining, and grinding the surface of the composite material from which the carbon nanostructures are to be exposed.

The composite material is preferably produced by powder metallurgy and comprises the following steps: producing a homogeneous powder mixture from a first metal and from carbon nanostructures, sintering the powder mixture to form a composite material, and extruding the composite material. Direct extrusion of the homogeneous powder mixture is also possible.

The carbon nanostructures are preferably exposed for 5-30pm, more preferably 10-20pm.

The first metal is preferably copper. However, any other metal can also be used. According to the invention, an enlargement of the interface area and / or contact area of a releasable and reusable thermal interface is therefore proposed to increase the heat flow between two surfaces made of metal-carbon composite materials, in particular copper-carbon nanostructures, by forming a composite material, in particular using copper or copper-carbon composite materials for different atmospheres, preferably in a vacuum in the pressure range less than 1 ^* 10 ^L (-2) mbar.

The filler material preferably has a higher thermal conductivity than the composite material. As a result, the overall thermal conductivity can be improved. The filler material can be introduced by powder metallurgical and / or melt metallurgical methods.

The filler material in particular comprises a second metal. This can be copper. The filler material can be a metal-carbon composite. Metal-diamond composite, preferably copper-diamond, or a metal-graphite composite, preferably copper-graphite, are possible. These materials are particularly suitable for improving the thermal conductivity.

In one embodiment, at least one first layer of at least one other material can be introduced into the die in the plane of the composite material. Alternatively or additionally, before the step of introducing the segments into the die, the die can already be filled with at least one second layer of at least one other material and the segments can be arranged thereon. The first and second layers preferably have a higher thermal conductivity than the composite material.

In this way, an interface from the composite material can be specifically adapted to the dimensions of components and requirements for thermal conductivity.

Furthermore, the invention comprises a composite material which was produced according to the invention as described above.

Furthermore, a use of a composite material according to the invention is proposed as heat conducting and heat transfer material. The features, features and advantages of this invention described above, and the manner in which they are achieved, will become clearer and more fully understood in

In connection with the following description of the exemplary embodiments, which in

Connection with the drawings will be explained in more detail. Show it:

1 schematically shows a non-contacted thermal interface of the prior art, which consists of two contact layers,

2 schematically shows a contacted thermal interface of the prior art of FIG. 1,

3 shows the composite material according to the invention after extrusion with exposed carbon nanostructures,

4 schematically shows a non-contacted thermal interface with a composite material according to the invention in a first exemplary embodiment,

5 schematically shows a contacted thermal interface of FIG. 4,

6 schematically shows a second exemplary embodiment of a non-contacted thermal interface according to the invention,

7 schematically shows a further possible arrangement of a thermal interface according to the invention,

Fig. 8 shows an example of a possible rod of the composite material after the

Extrusion,

9 shows a cut segment of the extruded composite material,

10 shows an example of the arrangement of several segments in the die in FIG

Preparation for sintering,

11 shows a composite of materials mechanically and thermally connected by the sintering according to the invention, 12 shows an exemplary / schematic representation of a machined, ground and etched composite material according to the invention,

13 shows a photo of a manufactured and ground composite material,

14 shows a photo of a composite of materials which has been produced, ground and etched to verify the method,

Fig. 15 shows schematically an embodiment of a thermal according to the invention

Interface connected to a body with a material with lower, equal or higher thermal conductivity,

16 schematically shows an embodiment of a thermal according to the invention

Interface (21) connected to a body with a material with lower thermal conductivity and the same or higher thermal conductivity at several points to form targeted thermal conduction paths,

17 schematically shows the method according to the invention for producing a composite material.

A non-contacted thermal interface of the prior art is shown in FIG. The thermal interface here consists, for example and not in a limiting manner, of a metallic contact layer 1 and 2, each of which has facing microscopically roughened surfaces. If these two surfaces are brought together for contacting, as shown in FIG. 2, an effective area for contact-bound heat transfer results from the sum of the contact points 3 between the contact layers 1 and 2. The heat can only be removed via the gaps 4 between the contact points 3 Radiation or convection of the enclosed medium. However, convection cannot take place in a vacuum.

Therefore, according to the invention, a composite material consisting of metal-carbon composite materials is proposed, in particular of copper and carbon nanostructures, such as, but not limited to, carbon nanotubes. The carbon nanostructures are anchored in the matrix of a metal in the composite material. They protrude from a surface and can therefore be used as "Thermal Interface Materials (TIM)" for a thermal interface. The metal-carbon composite material is manufactured using powder metallurgy. A first metal serves as a matrix and the carbon primarily as a reinforcing component. As a result, there are advantageously various possibilities for the subsequent shaping of the composite material. By way of example but not by way of limitation, after the production of a homogeneous powder mixture, the metal-carbon nanostructure composite material can be given a shape, in particular using extrusion presses. The

Carbon nanostructures, preferably carbon nanotubes, aligned one-dimensionally almost parallel to the extrusion direction. After extrusion, the composite materials can be machined as normal. The surface can therefore be brought to the shape suitable for the thermal interface and by methods such as lapping to a roughness depth of up to 10 pm, preferably up to 1 pm and below.

By etching away the uppermost metal layer on the end face, the previously embedded carbon nanostructures can be exposed, preferably up to 10 pm in length, more preferably up to 20-30 pm. The carbon nanostructures that protrude from the surface are still firmly anchored in the metal matrix. Such a composite material 20 after extrusion is shown in FIG. 3. The

Carbon nanostructures 22 are exposed after the extrusion by etching away a first metal 24 on the surface. By anchoring the carbon nanostructures 22 in the first metal 24, preferably copper, the carbon nanostructures 22 cannot be detached so easily when the corresponding contact layers 1 and 2 are separated. As a result, the composite material 20 is more suitable for the releasability and reusability of the interface. The surface of the composite material 20 has regions made of the first metal 24, through which the carbon nanostructures 22 penetrate or protrude from the surface. In FIG. 3, the composite material 20 extends along an expansion axis in the z direction. The side surface (s) of the composite material 20 are formed from the first metal 24. This can also be etched away on the sides.

FIG. 4 now schematically shows a non-contacted thermal interface, which has, for example, a metallic contact layer 1 on one side and on the other side a contact layer 2 made of a metal-carbon nanostructure composite material 20 produced as described above. The

Carbon nanostructures 22 of the end face of the composite material 20 were exposed here by way of example by etching. Figure 5 shows schematically the contacted thermal interface of Figure 4. The number of contact points 3 is compared to the number of contact points 3 in FIG. 2 significantly increased by the carbon nanostructures 22 embedded in the first metal 24.

FIG. 6 schematically shows a further exemplary embodiment of a non-contacted interface according to the invention. This now consists of two metal-carbon nanostructure composite materials 20 with exposed ones, as described

Carbon nanostructures 22. In the contacted state, the carbon nanostructures 22 each touch the surface made of the first metal 24 or the carbon nanostructures 22 of the other contact layer. This increases the thermal conductivity even further. In FIG. 6, carbon nanotubes 22 are shown purely by way of example. However, it can also be in any other carbon nanostructure 22, such as round carbon nanoparticles, e.g. Fullerenes and more amorphous carbons, or layered carbon nanoparticles, e.g. Graphene and nanoplatelets, or fibrous carbon nanoparticles, e.g. Carbon nanofibers. Those are preferred but not restrictive

Carbon Nanostructures Carbon Nanotubes.

FIG. 7 schematically shows a further possible arrangement of the thermal interface. In addition to the variants shown so far, the surfaces with and without carbon nanostructures 22 on both sides of the thermal interface are each offset from one another. The staggered arrangement of the regions with and without carbon nanostructures on the two contact layers 1 and 2 can improve the releasability of the interface.

The contact surfaces that can be produced and a possible shape of the thermal interface are limited in the method that leads to the composite material 20. In order to enlarge this and to enable adaptive shaping, a manufacturing method for producing a composite material is proposed, which enables interface elements, which were produced by the method just described, to be mechanically and thermally connected to one another.

As a result, the contact area of an interface body can be enlarged and brought into any shape. In particular, interface rings can thus also be produced from circular segments.

For this purpose, a powder metallurgical method is presented below according to the invention. FIG. 8 shows, by way of example and not by way of limitation, a rod-shaped composite material 20 with a cross-sectional area 26 from a circular segment after an extrusion step. The cross-sectional area 26 of the rod-shaped composite material 20 can, however, have any basic geometric shape, in particular a circular, trapezoidal, rectangular or square basic shape. This rod extends along an axis of expansion z and, in the example shown, is used to produce circular segments in FIG. 9. The carbon nanostructures 22 likewise extend along the axis of expansion z out of a surface of the composite material 20. The composite material 20 is preferably rod-shaped so that it can be partitioned easily, for example by sawing. The rod resulting from the extrusion is divided into segments 30 with a corresponding thickness, but is preferably sawn, but not by way of limitation. These segments 30 are shown in FIG. 9. The shape and base area of the composite material 20 is not limited to the exemplary embodiment shown. The base area can take any shape, for example square, rectangular, circular, elliptical, etc. Around the composite material 20 there can be a sheath made of the first metal 24 for production reasons, which can be removed by machining if necessary. This cover can also be used for further joining (e.g. by soldering).

The segments 30 are arranged in a die 100 of a selected shape. In FIG. 10, for example and not by way of limitation, a circular shape has been selected as the die 100. The segments 30 are arranged in the die so that they form a circular ring 110 and the free spaces 120 located therebetween are then filled with a filling material 130, as shown in FIG. 11. The fill material 130 is preferably a metal powder, more preferably copper powder. In the exemplary embodiment shown, no composite material 20 is arranged in the interior of the die 100 around the center of the circle, but only the filling material 130. The filling material 130 and the segments 30 are connected to a common body 200, for example by sintering.

In the case of circular rings in particular, the inner region can be filled with the filling material 130 in order to be used as a clamping surface for later machining. After sintering, the composite material can be machined for final shaping. In one exemplary embodiment, segments of the composite material can be arranged in one die in a die, which can be used as a melt infiltration tool. The die is then preheated to temperatures between 400 to 600 ° C, preferably in vacuo. The cavities between the segments are then, for example, with molten metal or a metal alloy, e.g. B. copper with a temperature between 1200 and 1300 ° C, for example under vacuum (<20 mbar) and infiltrated with a predetermined pressure. The predetermined pressure can be between 50 MPa and 100 MPa and is, for example, approximately 80 MPa. The infiltration time can be between 35 and 50 seconds. Then the solidification takes place under pressure. The composite material can then be ejected from the die and cooled further in air.

FIG. 12 shows a representation of a machined, ground and etched composite material 200, which was produced from the previous steps. The material composite 200 is designed as a ring, for example, and has individual holes in the ring that can be used for fastening. The last process steps are the grinding of the material composite surface, the result of which is shown in FIG. 13, and the etching to expose the carbon nanostructures (FIG. 14).

The interface can be used both when the carbon nanostructures 22 are exposed on one or on both sides of the contact areas. Use against another solid is also possible.

The thermal conductivity of the composite material 200 can be adjusted as desired. Metal-diamond or metal-graphite composites have a higher thermal conductivity than pure metal or as the metal-carbon nanostructure composite material 20. The thermal conductivity of copper-diamond is up to 700 W / m K and that of copper-graphite up to 600 W / m K, while the thermal conductivity of pure copper is approx. 400 W / m K. Therefore, they can also be used for passive cooling. This can also be used in particular for this invention. To increase the thermal conductivity, in particular the filler material 130 can be replaced by a metal-diamond composite material for connecting the composite material. Metal-diamond composites are characterized in all spatial directions by an increased thermal conductivity compared to pure metal, which means that the total amount of heat to be transferred can be increased again. The composite material 200 can be shaped and adapted in many ways. FIG. 15 schematically shows a composite material 200 with a first partial region 210 made of composite material 20, connected to a body with a second partial region 220, which is formed from a material with lower, identical or higher thermal conductivity. The connection can also be made by sintering or melt infiltration. The material of the second section 220 can be arranged together with the segments 30 of the composite material 20 in the die 100. By choosing the material of the second partial region 220 with a higher or lower thermal conductivity, specific heat conduction paths can be formed. This can also increase stiffness and strength.

A more complex embodiment of a composite material 200 is shown in FIG. 16. The composite material 200 here consists of two layers of different materials. For example, a third section 230 can be arranged below the composite material 20 and have a lower thermal conductivity than the composite material 20 of the first section 210. The fourth section 240 can have the same or preferably higher thermal conductivity, as a result of which the heat is dissipated laterally.

FIG. 17 shows a method according to the invention for producing a composite material. In step S100, a composite material 20 is first produced from carbon nanostructures 22 anchored in a matrix of a first metal 24. The composite material 20 extends along an expansion axis z. The carbon nanostructures 22 likewise extend along the expansion axis z of the composite material 20. In step S200, the composite material 20 is divided into segments 30, preferably cut segments 30. The segments 30 are then arranged in a die 100 in at least one plane S300. A material composite 200 is then formed in step S400. This can be done by filling S410 of free spaces in the die 120 with a filler material 130 and then sintering S420 in the die 100. Alternatively, this can also be done by melt infiltration S430 in the die 100. In step S500, the carbon nanostructures 22 are then exposed from at least one surface of the composite material 200, so that the carbon nanostructures 22 protrude from this surface.

In summary, carbon nanostructures anchored in a metal matrix have been proposed as heat-conducting materials (TIM) and heat transfer materials. These are advantageous for a releasable and reusable thermal interface used. A composite material can be produced according to the invention by sintering for the local integration of the thermally active interface surface in a metal, a metal alloy and / or a composite material (metal / diamond, metal / graphite).

Thermally active interface surfaces can also be formed from metal / carbon nanostructures, a composite material for heat transfer and a material with a lower thermal conductivity (ceramic, metal, metal alloys and composite materials) than the composite material for the formation of targeted thermal conductive paths (thermal partitioning).

The thermally active interface surface can advantageously be regenerated by targeted etching and can be adapted to contours.

Although the invention has been illustrated and described in detail by means of preferred exemplary embodiments, the invention is not restricted by the disclosed examples and other variations can be derived therefrom by the person skilled in the art without departing from the scope of protection of the invention.

LIST OF REFERENCE NUMBERS

1 first contact layer

2 second contact layer

3 contact points

4 gaps between contact points

20 composite material

22 carbon nanostructures 24 first metal

26 cross-sectional area

30 segments

100 die

110 die segment

120 free space

130 padding material

200 composite material

210 first section

220 second section

230 third section

240 fourth section

Claims

claims

1. A method for producing a composite material (200) comprising:

Manufacture (S100) of a composite material (20), which extends along an extension axis (z), from carbon nanostructures (22) anchored in a matrix of a first metal (24),

Dividing (S200) the composite material (20) into segments (30),

Arranging (S300) the segments (30) in at least one plane in a die (100),

Form (S400) a composite material (200)

Filling (S410) of free spaces in the die (120) with a filler material (130) and subsequent sintering (S420) in the die (100), or

Enamel infiltration (S430) in the die (100),

Exposing (S500) the carbon nanostructures (22) from at least one surface of the composite material (200) so that the carbon nanostructures (22) protrude from this surface.

2. The method for producing a composite material (200) according to claim 1, wherein the carbon nanostructures (22) are round, layered or fibrous carbon nanoparticles.

3. The method for producing a composite material (200) according to claim 1 or 2, wherein the composite material (20) is a rod-shaped composite material (20) and the cross-sectional area (26) of the rod-shaped composite material (20) has any geometric basic shape, in particular a circular one , trapezoidal, rectangular or square basic shape or partial areas of such a basic shape.

4. The method for producing a composite material (200) according to one of the preceding claims, further comprising the following steps, which follow the sintering of the die (100):

- shaping by machining, and

- Grinding the surface of the composite material (20) from which the carbon nanostructures (22) are to be exposed.

5. The method for producing a composite material (200) according to one of the preceding claims, wherein the composite material is produced by powder metallurgy and comprises the following steps:

- producing a homogeneous powder mixture from a first metal (24) and from carbon nanostructures (22), and

- Sintering the powder mixture into a composite material (20), and / or

- Extrusion of the composite material (20).

6. A method for producing a composite material (200) according to one of the preceding claims, wherein the carbon nanostructures (22) are exposed on the length of the composite material surface for a length of 5-50pm, preferably 10-30pm.

7. A method for producing a composite material (200) according to one of the preceding claims, wherein the first metal (24) is copper.

8. A method for producing a composite material (200) according to one of the preceding claims, wherein filler material (130) has a higher thermal conductivity than the composite material (20).

9. The method for producing a composite material (200) according to claim 8, wherein the filling material (130):

- comprises a second metal,

- copper is,

- is a metal-diamond composite, preferably copper-diamond, or

- A metal-graphite composite material, preferably copper-graphite.

10. The method for producing a composite material (200) according to one of the preceding claims, wherein in the plane of the composite material (20) at least one first layer (210) made of at least one other material is introduced into the die (100).

1 1. A method for producing a composite material (200) according to one of the preceding claims, wherein before the step of introducing the segments (30) into the die (100), the die (100) already with at least a second layer (220, 230 ) is filled from at least one other material and the segments (100) are arranged thereon.

12. The method for producing a composite material (200) according to claim 10 or 1 1, wherein the first and second layers for forming heat conducting paths have a lower or higher thermal conductivity than the composite material (20).

13. Composite material (200), which was produced according to one of the preceding claims 1 to 12.

14. Use of a composite material according to claim 13 as a heat conductor and / or heat exchanger.