JPS6236076A - Method of bonding different materials - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [Object of the Invention] (Industrial Application Field) This invention is directed to carbon rim fa/carbon composite material or metal fiber/double fiber! The present invention relates to a method for joining dissimilar materials, which is used to join an IT/carbon composite material and a heat-resistant metal material.

(Prior Art) Conventionally, as a method for bonding (joining) inorganic materials such as ceramics and metal materials, 1, for example, metallizes the surface of ceramic or tux, and performs metal plating if necessary, and then Refractory metal method for brazing metals,
An active metal is produced by inserting a highly active metal and a metal that forms an alloy with this metal with a relatively low melting point between the ceramic and the metal to form a eutectic composition, and then heating the mixture in a vacuum or in an inert atmosphere. There were several methods, including a method in which an oxide solder was placed between the ceramic and the metal and heated. (Ceramics Technology Collection, Ceramics Materials Technology Editorial Committee Line,
Published on April 10, 1978.

Pages 738 to 747 Futatsuki Institute of Metals Bulletin Vol. 22 No. 1
No. 3 to 7).

(Problems to be Solved by the Invention) In such conventional methods of bonding ceramic materials and metal materials, a brazing material or an oxide solder is used.
3. If a material containing CaO as the main component is used, its melting point is about 1500°C, and in particular, it is used as an inorganic material such as carbon fiber / carbon composite material, metal fiber / carbon fiber /
Like carbon composite materials, the heat resistance temperature is 2000°C to 25°C.
When joining a material with a temperature of 00''C or higher and a high melting point metal material, there is a problem in that it is difficult to maintain the bonding strength with the above-mentioned conventional bonding.

This invention was made by focusing on such conventional problems, and by significantly increasing the heat resistance strength at the joint part,
The object of the present invention is to provide a method for bonding a composite material and a heat-resistant metal material, which can maintain sufficient bonding strength even in a high-temperature environment and has extremely good bonding and sealing properties.

[Structure of the Invention] (Means for Solving the Problems) Is the method of combining the fiber composite material and the fully flexible material 4 according to the present invention carbon fiber/carbon composite material or metal fiber fist carbon fiber?
d1/When bonding the carbon composite material and the heat-resistant metal material, a metal carbide is interposed between the composite material and the heat-resistant metal material, and the composite material and the heat-resistant metal material are bonded via the metal carbide. It is characterized by the fact that it is made to do so.

Composite materials to which this invention is applied include carbon fiber/carbon composite materials, metal fibers/carbon IA fibers/carbon composite materials, and metal fibers/carbon IA fibers/carbon composite materials that are further composited with metal fibers and whiskers such as Ti, Nb, Ta, and B.
Examples include carbon composite materials.

Among these, pitch (petroleum pitch or coal pitch) type carbon fibers, rayon type fibers, PAN type fibers, etc. are used as carbon fibers.

In addition, the matrix (mother phase) of the carbon fibers and metal fibers
Carbon and graphite are used as the carbon.

There are no particular limitations on the method for producing carbon #a fiber/carbon composite material or metal fiber/carbon fiber/carbon composite material, but for example, FRP made of carbon fiber/phenol or graphite mfa/phenol is carbonized by primary firing. Alternatively, there is a method of graphitizing and repeating pitch impregnation and firing to further increase the density, or chemical vapor deposition (CVD) of carbon produced by pyrolyzing hydrocarbons on aggregates woven with carbon fibers or graphite fibers. There are ways to do this.

Furthermore, heat-resistant metal materials to which the present invention is applied include materials that tend to form carbides because the bonding partner material is a carbon (carbon, graphite)-based composite material, such as Ti.

Mo, Nb, Ta, Zr, W
, Cr, V, etc. Other metals and alloys may also be used, such as Ni-based or Co-based heat-resistant and corrosion-resistant alloys such as Hastelloy, Inconel, and Haynes, heat-resistant steel, and alloy steel.

In one embodiment of the present invention, when bonding the above carbon fiber/carbon composite material or metal fiber/carbon fiber/carbon composite material and the above heat-resistant metal material, as schematically shown in FIG. First, in FIG. 1(a), metal carbide (MC) is added to at least the bonding surface of the composite material (C70) 1.
) 2, as shown in FIG. 1(b), the metal carbide 2 and the heat-resistant metal material (M) 3 are brought into contact with each other and subjected to high temperature treatment, as shown in FIG. 1(C). The composite material 1 is formed by forming an intermediate layer (MC/M, cermet layer) 4 between the gold B carbide 2 and the heat-resistant metal material 3.
and a heat-resistant metal material 3 are bonded via the metal carbide 2.

In this embodiment, the means for forming the metal carbide 2 on the surface of the composite material 1 is a metal that easily forms the metal carbide 2, such as Nb or Ta.

Metal powder such as Ti, Mo, Cr, W, Zr, Hf, V, etc. is made into a paste and applied to the surface of the composite material 1, and then subjected to high temperature treatment in a non-oxidizing atmosphere, for example, a carbon atmosphere. A means for reacting the metal powder with carbon in the composite material 1 and/or carbon in a treatment atmosphere to form a metal carbide 2, and a means for plasma spraying the metal powder toward the surface of the composite material 1 in a carbon atmosphere. Alternatively, after providing the above-mentioned ultrafine wire or foil material of a metal that does not form metal carbide on the surface of the composite material 1, the ultrafine wire is treated at high temperature in a non-oxidizing atmosphere, for example, a carbon atmosphere. A method of reacting the metal carbide or the foil material with carbon in the composite material 1 and/or carbon in the treatment atmosphere to form the metal carbide 2 is adopted.

After forming the metal carbide 2 on at least the bonding surface of the composite material 1 in this way, the metal carbide 2 and the heat-resistant metal material 3 are subjected to high-temperature treatment in a state where they are in contact with each other, so that the composite material 1 and the heat-resistant metal material 3 through the metal carbide 2. In this case, as shown in FIG. 1(C), the structure of the bonded part changes sequentially from composite material 11 - metal carbide 2 - metal carbide/metal cermet layer 4 - metal material 3. Therefore, it becomes extremely strong against thermal shocks such as rapid heating and rapid cooling.

In another embodiment of this invention, the above carbon fiber/
When bonding a carbon composite material or a metal fiber/carbon fiber/carbon composite material and the above-mentioned heat-resistant metal material, first, as schematically shown in FIG. 2, the composite material (C /C) 11 and the heat-resistant metal material (M) 13 are subjected to high temperature treatment in a state in which they are in contact with each other, and as shown in FIG. 2(b),
Metal carbide (
MC) 12, the composite material 11
and a heat-resistant metal material 13 are bonded via the metal carbide 12.

In this embodiment, a composite material 11 and a heat-resistant metal material 1
When bringing the composite material 11 and the heat-resistant metal material 13 into contact with each other, as shown in FIG. The carbide powder is mixed with the composite material 11 and the heat-resistant metal material 1.
It is also possible to make an indirect contact state between the two parts and the third part.

In addition, in the bonding method according to the present invention, the types of metals in the metal fibers, metal carbide, and heat-resistant metal material in the composite material do not necessarily have to be the same. Appropriate selections can be made, such as using different metals, using the same metal as the champion, or using metals that belong to the same family even if they are different.

(Example 1) As shown in FIG. 3, a rocket nozzle has a threaded portion 21a on the outer periphery of one end, an O-ring groove 21b on the end surface of the same end, and a throat portion 21c on the other end. 21 was fabricated from carbon fiber/carbon composite material.

Next, a paste containing a mixture of Nb powder and an organic binder is applied to the surface of the male threaded portion 21a, and then heated to 2100° C. to 2200”C! in a carbon atmosphere to coat the surface layer of the male threaded portion 21a with the Nb. A metal carbide (NbC) 22 was produced by the reaction of C and C.

Next, as shown in FIG. 4, the male thread part 2 of the nozzle 21 is
1a, a holder ring 23 made of a heat-resistant metal material, here made of Nb, having a female threaded portion 23a and a flange portion 23b.
Then, a ring-shaped pressure adapter 24 made of carbon fiber/carbon composite material is attached to both threaded parts 21.
a, after installing the tube around the outer periphery of 23a, heat it again to 2100℃~2
Perform high temperature treatment by heating to 200°C.

This high-temperature treatment causes diffusion between the metal carbide 22 and the holder ring 23 made of a heat-resistant metal material to form a cermet layer. The portion 23a is made of the metal carbide (NbC) and the cermet layer (NbC).
bC+Nb).

In this way, the holder ring 23 made of a heat-resistant metal material is connected to the - end of the nozzle 21, and as shown in FIG.
With the O-ring 24 installed in the O-ring groove 21b, it is combined with a mating material 25 (such as an injector made of a high-melting point metal such as Nb), and the nozzle 21 is connected to the mating material 25 through the holder ring 23 by a large number of heat-resistant ports 26. Fixed.

(Example 2) As shown in FIG. 4, a male threaded portion 21a of a nozzle 21 made of metal (Poron) wire fiber/carbon fiber/carbon composite material
and a female threaded portion 23 of a holder ring 23 made of titanium.
a and one double threaded portion 21a.

23a with or without intervening gold E carbide, and then heated at 2100°C to 22°C in a carbon atmosphere with the pressure adapter 24 attached.
A high-temperature treatment was performed by heating to 00''C.

Through this high-temperature treatment, Ti, which is the material of the holder ring 23, and carbon, which constitutes the nozzle 21, react to form metal carbide (T i C
) was formed, and the nozzle 21 and the holder ring 23 were connected via this metal carbide.

After that, as shown in Figure 5, a large number of heat-resistant port 2
#6 through the holder ring 23
A mating member 25 made of hot metal and the nozzle 21 were fixed.

[Effect of the invention] As explained above, according to this invention.

Carbon fiber, / carbon composite material or metal fiber - carbon fiber /
When bonding the carbon composite material and the heat-resistant metal material, a metal carbide is interposed between the composite material and the heat-resistant metal material, and (1) the composite material and the heat-resistant metal material are bonded via the metal carbide. Because of this, it is possible to bond the composite material and metal material extremely well, and the mechanical strength of the bonded part is high enough that it is possible to maintain the bond strength sufficiently high even in extremely high temperature environments. In addition,
It has extremely high bonding strength against thermal expansion and contraction, and has the remarkable effect of being able to significantly improve the sealing performance (sealability, airtightness) at the bonded part.

[Brief explanation of the drawing]

FIGS. 1(a), (b), and (c) are explanatory diagrams sequentially showing the bonding process of a composite material and a metal material according to one embodiment of the present invention, and FIG. 2(L) (b) is another embodiment of the present invention. FIG. 3 is an explanatory diagram showing the bonding process of a composite material and a metal material according to an embodiment of the present invention, and FIG. , Fig. 4 is a cross-sectional explanatory view showing the state after the holder ring and pressurizing adapter are attached to the nozzle shown in Fig. 3, and Fig. 5 shows the combined body of the nozzle and holder ring shown in Fig. 4 as a mating member. FIG. 1.11.21...Fiber-containing composite material. 2.12.22...Metal carbide, 3.13.23...Heat-resistant metal material.

Claims (3)

[Claims] (1) When bonding carbon fiber/carbon composite material or metal fiber/carbon fiber/carbon composite material and heat-resistant metal material,
A method for joining dissimilar materials, characterized in that a metal carbide is interposed between the composite material and the heat-resistant metal material, and the composite material and the heat-resistant metal material are joined via the metal carbide. (2) When bonding carbon fiber/carbon composite material or metal fiber/carbon fiber/carbon composite material and heat-resistant metal material,
After forming a metal carbide on at least a bonding surface of the composite material, high temperature treatment is performed in a state where the metal carbide and the heat-resistant metal material are in contact with each other, and the composite material and the heat-resistant metal material are bonded via the metal carbide. A method for joining dissimilar materials according to claim (1). (3) Carbon fiber/carbon composite material or metal fiber. When bonding the carbon fiber/carbon composite material and the heat-resistant metal material, the composite material and the heat-resistant metal material are subjected to high-temperature treatment while in contact with each other, and the composite material and the heat-resistant metal material are bonded via a metal carbide. A method for joining dissimilar materials according to claim (1).