WO2015086291A1

WO2015086291A1 - Method for producing a composite component formed by carbon fibers coated with pyrolitic carbon

Info

Publication number: WO2015086291A1
Application number: PCT/EP2014/075254
Authority: WO
Inventors: Rudolf Weck; Steffen Weller; Ralf Gärtner
Original assignee: Schunk Kohlenstofftechnik Gmbh
Priority date: 2013-12-13
Filing date: 2014-11-21
Publication date: 2015-06-18
Also published as: DE102013225939A1; EP3080324A1; US20160319410A1; EP3080325A1; WO2015086290A9; WO2015086290A1

Abstract

The invention relates to a method for producing a composite component and to a composite component, said composite component being formed from a metal matrix composite material of carbon fibers and a metal or a metal alloy, wherein a fiber composite is formed from the carbon fibers, wherein a preform is formed from the fiber composite, wherein the carbon fibers of the fiber composite are coated with pyrolytic carbon in order to form the preform, and wherein the preform is infiltrated at least partially with molten metal.

Description

PROCESS FOR PREPARING A PYROLITICHE

CARBON / CARBON FIBERS COMPOSITE COMPONENTS

The invention relates to a method for producing a composite component and to a composite component, wherein the composite component is formed from a metal matrix composite of carbon fibers and a metal or a metal alloy.

The metal matrix composites used to form composite components are typically a continuous metal matrix having carbon fiber reinforcement inside it. Due to their high stability and low weight, these composite components are generally used in lightweight construction, for example in aircraft construction or in space travel. The metal matrix reinforcing carbon fibers may be short cut fibers or endless filaments. For example, the short cut fibers may be added to a molten metal and potted. However, it can easily come to inhomogeneities in the distribution of the fiber material. Thus, depending on the shape of the mold or the type of casting method used, an added amount of fibers within the composite component thus formed may undesirably distribute unevenly. This is particularly favored by the fact that carbon fibers compared to metal have a significantly different density.

When casting or infiltrating carbon fibers with, for example, aluminum, it may also lead to the formation of carbides or aluminum carbide, resulting in a longer residence time of the carbon fibers in an aluminum melt for dissolution of the carbon fibers, which in turn the mechanical strength properties of the thus formed composite component deteriorated. Further, it is known to use carbon fiber reinforced carbon as a material for forming a composite component. In a carbon fiber reinforced carbon, first, carbon fibers are impregnated with, for example, a resin, whereby the resin is subsequently pyrolyzed. However, a preform formed in this way can then no longer or no longer be completely infiltrated with a metal because the interstices between the carbon fibers are then almost completely filled with pyrocarbon, which then forms the matrix of the composite material. However, it is possible to coat a carbon fiber-reinforced carbon or such a composite component with a metal, in which case, however, the mechanical strength properties of a metal matrix composite material can not be achieved.

The present invention is therefore based on the object of proposing a method for producing a composite component and a composite component produced by the method with improved strength properties.

This object is achieved by a method having the features of claim 1 and a composite component having the features of claim 21. In the method according to the invention for producing a composite component, the composite component is formed from a metal matrix composite of carbon fibers and a metal or a metal alloy, wherein a fiber composite is formed from the carbon fibers, wherein a preform is formed from the fiber composite, wherein the carbon fibers of the Fiber composite are coated to form the preform with pyrolytic carbon, and wherein the preform is at least partially infiltrated with geschmo lzenem metal. The mechanical strength properties of the composite component can accordingly be improved by first forming a fiber composite of the carbon fibers which has a defined geometry. Undesirable inhomogeneities of the carbon fibers in the composite component can thus be avoided. From the fiber composite, a dimensionally stable preform is formed by coating the carbon fibers of the fiber composite with pyrolytic carbon. The carbon fibers are then completely surrounded by the pyrolytic carbon, the carbon fibers being bonded together at their respective mutual contact points by means of the pyrolytic carbon coating. Since the carbon fibers are coated with a comparatively thin layer of pyrolytic carbon, there still remains a space between the carbon fibers which ensures sufficient porosity of the preform suitable for infiltration with a molten metal. The dimensionally stable preform can thus be infiltrated with the molten metal without the geometric shape of the preform is dissolved or changed. Also, the pyrolytic carbon forms a protective layer on the carbon fibers, which prevents the formation of carbides, and thus a dissolution of the carbon fibers. In addition, the pyrolytic carbon coating provides improved wettability of the carbon fibers. Overall, such a geometric orientation of the Carbon fibers are fixed, the carbon fibers themselves are preserved and adhere to each other. A composite component produced by the method according to the invention then has improved mechanical strength properties compared to a conventional composite component, also with regard to a comparable component weight.

In the process, the pyrolytic carbon can be deposited on the carbon fibers from the gas phase. This makes it possible to coat the carbon fibers with a comparatively thin layer of pyrolytic carbon. Further, a layer thickness in a coating from the gas phase is particularly easy to adjust as needed. It is also possible to coat fiber composites with virtually arbitrary geometries and carbon fiber densities with pyrolytic carbon, since the gas in question can penetrate the fiber composite well. Preferably, the pyrolytic carbon may be formed as a deposit formed on the carbon fibers by a CVD method or a CVI method. The coating of the carbon fibers with pyrolytic carbon can be carried out so easily. It is also possible to provide several treatment steps in which the fiber composite is coated by means of the CVD or / and CVI method with pyrolytic carbon or so-called glassy carbon by deposition.

In an alternative variant of the method, the coating with the pyro lytic carbon on the carbon fibers by pyrolysis of a thin resin or pitch layer on the carbon fibers can be formed. A part size is due to a wall thickness of the fiber composite or composite component in a coating from the gas phase due to a penetration of the fiber composite with gas and a regularly process-related limited size of a reactor chamber for gas phase coating. The coating with the thin, low-viscous, liquid resin layer makes it almost possible manufacture any size composite components. Furthermore, the pyrolysis can take place in a conventional pyrolysis furnace whose size is not limited by the process.

Preferably, a thickness of the resin or pitch layer may be made smaller than a thickness of the carbon fibers. This may be necessary in order to ensure sufficient porosity of the preform for infiltration. In particular, gaps between the carbon fibers are then not completely filled with resin or pyrocarbon, so that coherent interspaces are formed. Preferably, the thickness of the resin layer may be formed 50 percent smaller, and more preferably 80 percent smaller than a thickness of the carbon fibers.

The resin layer can be prepared simply by soaking the fiber composite in a highly diluted phenolic resin solution, e.g. B. Phenol resin diluted with ethanol or acetone. It is thus possible for liquid resin to fully penetrate into the fiber composite, regardless of a wall thickness. The impregnation with resin can also meet under a vacuum atmosphere. In the case of subsequent pyrolysis by, for example, curing and coking or pyroplating at about 1000 to 2000 ° C., a coating of the carbon fibers can be produced from pyrolytic, glassy carbon.

Advantageously, the coated carbon fibers can be provided with a further coating of silicon carbide. This makes it possible to change the mechanical properties of the composite component in any desired manner, and, for example when using aluminum as the matrix material, to avoid an undesired chemical reaction of the aluminum during an infiltration. Carbon fibers coated in this way, or a braid or fabric of carbon fibers forming the preform, also exhibit increased rigidity, which is particularly advantageous for the subsequent process step of infiltration. It may further be provided to form an at least partially unidirectional orientation of the carbon fibers of the fiber composite. For example, continuous filaments can be formed into a desired geometric shape by winding or any other technique. In principle, however, it is also possible to use short-cut fibers without a specific spatial orientation for a coating with pyrolytic carbon. The short cut fibers can be in the form of a fiber mat or a nonwoven, wherein the fiber mat or the nonwoven itself can be used for the geometric shaping of the preform. Preferably, however, fiber fabric mats or filament yarns can be used to form an optionally multi-layer fiber composite.

Further, it can be provided to compress the fiber composite before the formation of the preform by coating. Thus it can be achieved that the carbon fibers lie close together and a volume fraction of carbon fibers in the composite component is substantially increased. The fiber composite can be added during compression auxiliaries, which can adhere the fiber composite or the carbon fibers to each other and so provisionally fix, without significantly reduce a porosity of the fiber composite.

Particularly preferably, the fiber composite can be formed as a spatially oriented support structure of the composite component, which is adapted to a load case of the composite component. Ideally, the fiber composite can be arranged in the composite component or the carbon fibers can be aligned in the composite component, that in a proposed use of the composite component forces or stresses within the composite component substantially in the direction of the longitudinal extent of the carbon fibers extend to a maximum mechanical To achieve strength of the composite component. A composite component, for example primarily tensile loaded, can then have a support structure made of carbon fibers, which in the direction of the tensile stresses spatially oriented. Depending on the intended load case of the composite component, the carbon fibers of the fiber composite can also be arranged in a combination of different spatial orientations. Composite components with particularly complex geometric shapes are particularly easy to produce when a support structure of the composite component is formed by a plurality of preforms. Thus, individual preforms can be formed, which are assembled to form a support structure of the composite component. For example, the preforms can then engage in one another in a form-fitting manner or can also be arranged independently of one another within the composite component. This then makes it possible to produce composite components with virtually any geometry, since any geometric restrictions in the formation of fiber composite from carbon fibers need not necessarily be taken into account. It is also conceivable a preform before an infiltration mechanically, for

Example machined to obtain a desired geometric shape of the support structure or the preform. This is particularly possible because the preform is dimensionally stable by the coating with pyrolytic carbon.

An infiltration of the preform can be done with aluminum, titanium, magnesium, copper or an alloy of one of these metals. In principle, any metal or alloy which has a melting point which does not lead to the dissolution of the pyrolytic carbon coating of the carbon fibers is suitable for infiltration.

In particular, aluminum is particularly suitable because of its low weight and good processability as a matrix material for lightweight composite components.

Essential for the production of a composite component is that the preform can be formed with an open pore structure. So it becomes possible that the preform easily with the molten Metal can be infiltrated. At least partially closed pore structures prevent complete infiltration of the preform with metal and have the formation of a negative impact on mechanical strength of the composite component impacting voids. Thus, the preform can be completely infiltrated with molten metal. Thus, a coherent matrix of metal can then be obtained, which completely fills substantially all interstices of the fiber composite of the carbon fibers of the preform. In a particularly simple variant of the method, it may be provided to infiltrate the preform only by immersion in a molten metal with the geschmo lzenen metal. In this case, the preform can remain in the molten metal for a comparatively long time since a dissolution of the carbon fibers or a carbide formation due to the coating of pyrolytic carbon is prevented. It is also possible to infiltrate the preform several times with molten metal in order to achieve complete infiltration.

In a further embodiment of the method, it is possible to arrange the preform in a casting mold. Thus, a composite component can be cast with a desired geometric shape, wherein the preform can then be infiltrated during the casting process with geschmo lzenem metal. For example, one or more preforms can be inserted in the manner of a core into a casting mold, wherein the preform can fill the casting mold completely or even only partially. Furthermore, the preform can be arranged in the casting mold so that the preform is infiltrated only partially with metal, that is, a portion of the composite component thus obtained can consist exclusively of coated carbon fibers without a metal matrix, wherein a further portion of the composite component coated carbon fibers with a metal matrix includes. The

Composite component may also have a section, the is formed exclusively of the matrix material or the metal. This makes it possible to produce composite components which have component sections adapted to load cases or specific applications.

An infiltration of the preform can be done by die casting, compression molding or vacuum casting. For example, by means of die casting particularly dimensionally stable composite components can be produced. Vacuum casting makes it easy to achieve complete infiltration of the preform with metal. Because the preform is dimensionally stable, it can be integrated particularly easily into the aforementioned casting methods for producing the composite component.

In one embodiment of the method, the composite member may be formed to have a metal content of more than 50% by volume. This is particularly advantageous if, according to the intended use of the composite component, a higher metal content has a particularly favorable effect on its properties.

In a further embodiment of the method, the composite component may be formed to have a carbon fiber content of more than 50% by volume. This is particularly advantageous if an intended use of the composite component is favored by a particularly high proportion of carbon fiber in the composite component.

It may also be advantageous if the composite component is formed so that the carbon fibers are homogeneously distributed within the composite component. The composite component then consists of a homogeneous metal matrix composite material, apart from a fiber orientation, regular material properties.

The composite component can, however, also be designed so that the carbon fibers are distributed heterogeneously within the composite component. This means that sections of the composite component have a more or may have a lower proportion of carbon fibers. Due to the dimensionally stable preform, it is possible to selectively determine or predetermine the proportion of carbon fibers within the composite component as well as the spatial orientation of the carbon fibers in order to influence the mechanical properties of the composite component.

The composite component according to the invention is formed from a metal matrix composite of carbon fibers and a metal or a metal alloy, wherein from the carbon fibers a fiber composite is formed, wherein from the fiber composite, a preform is formed, wherein the carbon fibers of the fiber composite to form the preform with pyrolytic Carbon are coated, wherein the preform is at least partially infiltrated with geschmo lzenem metal. The composite component according to the invention can be produced by the method according to the invention. For the advantageous effects of the composite component according to the invention, reference is made to the description of advantages of the method according to the invention. Further embodiments of the composite component resulting from the dependent on the method claim 1 dependent claims.

Claims

claims

Method for producing a composite component, wherein the composite component is formed from a metal matrix composite of carbon fibers and a metal or a metal alloy,

characterized ,

that from the carbon fibers, a fiber composite is formed, wherein from the fiber composite, a preform is formed, wherein the carbon fibers of the fiber composite are coated to form the pre-molding with pyrolytic carbon, wherein the preform is at least partially infiltrated with molten metal.

Method according to claim 1,

characterized,

that the pyrolytic carbon is deposited on the carbon fibers from the gas phase. Method according to claim 2,

characterized,

the pyrolytic carbon is formed as a deposit formed on the carbon fibers by a CVD method or a CVI method.

Method according to claim 1,

characterized,

that the pyrolytic carbon is formed on the carbon fibers by pyrolysis of a thin resin or pitch layer on the carbon fibers.

5. The method according to claim 4,

characterized,

a thickness of the resin or pitch layer is made smaller than a thickness of the carbon fibers. 6. The method according to claim 4 or 5,

characterized,

that the resin layer is formed by impregnating the fiber composite in a dilute phenolic resin solution.

Method according to one of the preceding claims,

characterized ,

that the coated carbon fibers are provided with a further coating of silicon carbide.

8. The method according to any one of the preceding claims,

characterized ,

that an at least partially unidirectional orientation of the carbon fibers of the fiber composite is formed.

9. Method according to one of the preceding claims, characterized in that

that the fiber composite is pressed.

10. The method according to any one of the preceding claims,

characterized ,

that the fiber composite is formed as a spatially oriented support structure of the composite component, which is adapted to a load case of the composite component.

11. The method according to any one of the preceding claims,

characterized ,

a supporting structure of the composite component is formed by a plurality of preforms.

12. The method according to any one of the preceding claims,

characterized ,

the infiltration takes place with aluminum, titanium, magnesium, copper or an alloy of one of these metals.

13. The method according to any one of the preceding claims,

characterized ,

that the preform is formed with an open pore structure.

14. The method according to any one of the preceding claims,

characterized ,

that the preform is completely infiltrated with molten metal.

15. The method according to any one of the preceding claims, characterized e e e c e e n e,

that the preform is placed in a mold.

16. The method according to claim 15,

characterized ,

that the infiltration is done by die casting, compression molding or vacuum casting.

17. The method according to any one of the preceding claims,

characterized ,

that the composite component is formed so that it has a metal content of more than 50 percent by volume.

18. The method according to any one of claims 1 to 15,

characterized ,

that the composite member is formed to have a carbon fiber content of more than 50% by volume.

19. The method according to any one of the preceding claims,

characterized ,

that the composite component is formed so that the carbon fibers are homogeneously distributed within the composite component.

20. The method according to any one of claims 1 to 18,

characterized ,

that the composite component is formed so that the carbon fibers are distributed heterogeneously within the composite component. Composite component formed from a metal matrix composite of carbon fibers and a metal or a metal alloy, characterized geke nn zeic hn et,

in that a fiber composite is formed from the carbon fibers, a preform being formed from the fiber composite, the carbon fibers of the fiber composite being coated with pyrolytic carbon to form the preform, the preform being at least partially infiltrated with molten metal.