JPH0222146A - Hybrid fiber-reinforced glass - Google Patents

Abstract

PURPOSE:To obtain a reinforced glass having a high elastic modulus, strength and great fracture energy without dispersion in strength and fracture toughness by compounding two or more kinds of fibers having different components or mechanical characteristics in a glass matrix. CONSTITUTION:Two or more kinds of fibers or fiber bundles 1 and 2 having different components or mechanical characteristics even if of the same components are, e.g., randomly arranged in a glass matrix 4, to form a hybrid fiber-reinforced glass 5. A material having excellent mechanical characteristics of conventionally well-known fiber-reinforced glass with great fracture energy and extremely small dispersion in strength and fracture toughness is obtained by the above-mentioned hybrid fiber reinforcing.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a glass reinforced with two or more types of fibers having different components or having the same components but different mechanical properties.

[Conventional technology]

Conventionally, glass materials have been widely used as structural materials that take advantage of their mechanical properties. In order to find wider uses for these structural glasses, it is essential to improve the mechanical properties of the glasses, such as their modulus of elasticity, strength, and fracture toughness.

Controlling the composition of glass has long been a method of improving the mechanical properties of glass. However, there are limits to the improvement of properties using this method, and recently,
As a method of improving the above-mentioned mechanical properties, glass has been manufactured in which continuous or discontinuous fibers are dispersed in the glass.

These composite materials, such as glass reinforced with carbon fibers and glass reinforced with SiC fibers, are known to have better elastic modulus, strength, and fracture toughness than conventional non-reinforced glasses (Japanese Patent Application Laid-Open No. 1983-1999) 145668),.

[Problem to be solved by the invention]

However, these glass matrix composite materials still have a large room for improvement in terms of strength, fracture toughness, fracture energy, and variations in these.

For example, glass composites reinforced with carbon fibers
Although the levels of elastic modulus, strength, and fracture toughness far exceed those of conventional glass, fractures of this composite material often occur instantaneously, and the fracture energy is small;
There were also large variations in the strength and fracture toughness of the materials themselves. In addition, in the case of glass composite materials reinforced with SiC fibers, Ag2O, and J1m fibers, the strength and fracture toughness far exceed that of conventional glass, and there is little variation, just as in the case of carbon fiber reinforcement. However, in these cases, the density of the fiber itself is especially high, and the so-called specific modulus and specific strength, which are the elastic modulus and strength of the composite material divided by the density, have the disadvantage that they are not as good as carbon fiber reinforced glass. The present invention solves the above-mentioned drawbacks of conventional fiber-reinforced glass, and as a structural glass matrix composite material, it has a high modulus of elasticity, high strength, large fracture toughness and fracture energy, and has high strength. The aim is to obtain a hybrid fiber-reinforced glass having a matrix of glass with less variation in fracture toughness.

[Means to solve the problem]

The hybrid fiber-reinforced glass according to the present invention is a composite of two or more types of fibers having different mechanical properties or having different mechanical properties even if the components are the same.

The present invention uses such hybrid fiber reinforcement to obtain a material that has excellent mechanical properties of conventionally known fiber-reinforced glass, has large fracture energy, and has extremely small variations in strength and fracture toughness. The drawbacks of glass are eliminated.

The fibers targeted by the present invention are selected from a group of inorganic fibers having an average diameter of 1 to 200 μm and having excellent elastic modulus and strength. , the fibers include carbon fiber, silicon carbide fiber, silicon nitride fiber, 5i-Ti-C fiber,
Alumina fibers, glass fibers, etc. are preferred. Further, it is also possible to use carbon fibers in which reconstituted materials such as silicon carbide and silicon nitride, nitrides, or mixtures thereof are adhered onto carbon fibers.

In the present invention, from among these fiber groups, two or more types of fibers having different components or having the same components but different mechanical properties are selected and used. For example, combinations such as carbon fiber and silicon carbide fiber, carbon fiber and alumina fiber, silicon carbide fiber and silicon nitride fiber, and alumina fiber and glass fiber are used. Further, a combination of carbonaceous carbon fiber and graphite carbon fiber, or a combination of silicon carbide fiber and carbon fiber with silicon carbide adhered thereto may be used. Furthermore, three or more types of fibers may be combined.

The combination of these fibers depends on the fiber material used or
Preferably, the structures are different. If the strength and breaking strain of the fibers are different, even if the fiber breaks in the composite material targeted by the present invention, the stress concentration in the composite material will be reduced due to the action of the fiber with different characteristics from the broken fiber. It has not been significantly increased. Therefore, it is possible to improve the shortcoming of conventional glass matrix composite materials reinforced with a single type of reinforcing fiber, where the entire composite material breaks instantly. You can get energy. Furthermore, by using fibers with different mechanical properties, a composite material with an extremely high elastic modulus compared to conventional glass matrix composite materials can be obtained due to the composite effect. Furthermore, by using two or more types of fibers with different diameters, it is possible to increase the total volume fraction of fibers in the glass matrix compared to conventional glass matrix composite materials that use fibers with the same diameter. .

The glass matrix targeted by the present invention includes: 5
Glass containing 60% or more of in2 by total weight is used. In particular, quartz glass (for example, Corning Co., USA code number 7940), SiO□ of 95% by weight
High silicate glass (for example, Corning Co., USA code number 7913), high silicate glass (for example, Corning Co., USA code number 7740.7720.
7070.7056.7050), aluminosilicate glass (for example, Corning Co., Ltd. code number 031)
7.1720.1723) is preferred. Further, a glass that is a mixture of two or more of silicate glass, high silicate glass, and aluminosilicate glass may be used.

The total volume fraction of fibers in the glass matrix is 15-75
Set to %. If the total volume fraction of fibers is less than 15%, it is difficult to exhibit the excellent properties of the fibers used for reinforcement, and it is difficult to obtain a greater elastic modulus, strength, and fracture toughness than the glass used for the matrix. . Further, since it is difficult to maintain uniform spacing of the fibers in the glass matrix, the volume fraction of the fibers is selected to be 15% or more. The total volume fraction of fibers in the glass matrix is 75%
If it exceeds the above, fibers tend to contact each other, and cracks tend to occur in the glass matrix due to the difference in thermal expansion coefficient between the fibers and the glass matrix during molding, making it difficult to achieve the target elastic modulus, strength, fracture toughness, etc. The disadvantage is that mechanical properties cannot be obtained. The total volume fraction of fibers in the glass matrix is therefore set between 15% and 75%.

The fibers used for reinforcement are preferably continuous. When the fibers are discontinuous, it is difficult to obtain the desired fiber arrangement in the glass matrix, making it difficult to maximize the properties of the fibers.

As for the arrangement of the fibers in the glass matrix, the arrangements illustrated in FIGS. 1 to 4 and arbitrary combinations thereof can be used. 1 to 4 show examples of fiber arrangement in the matrix used in the present invention. In Figure 1, two different types of reinforcing fibers or fiber bundles (1) and (2) are inserted into a glass matrix (4).
Hybrid fiber-reinforced glass (5) is formed randomly arranged therein. In Figure 2, reinforcing fibers or fiber bundles (1) and (2) each form a layered composite material by themselves, and they are combined into one glass matrix (4).
). In Fig. 3, unlike in Fig. 1, three different types of reinforcing fibers or fiber bundles (1),
(2) and (3) are used. In Figure 4,
A composite material having the basic fiber arrangement shown in FIG.
This figure shows a hybrid structure that combines composite materials with the basic structure shown in Figure 2. As described above, the types of reinforcing fibers used in the present invention and their arrangement in the matrix can be arbitrarily selected depending on the properties required of the composite material.

Hybrid fiber-reinforced glass can be manufactured using methods that are normally used for manufacturing fiber-reinforced glass. For example, reinforcing fibers or fiber bundles are passed through a slurry of glass matrix powder, the fibers or fiber bundles with glass powder attached are cut, arranged in the desired shape, laminated, and hot pressed in a vacuum or inert atmosphere. You can get it by doing this.

[For production]

In this invention, the glass matrix is reinforced using different components or fibers with different mechanical properties even if the components are the same, thereby achieving a modulus of elasticity that is unattainable when using a single type of fiber. In addition to being able to improve strength and fracture toughness, it is also possible to significantly improve fracture energy, and it is also possible to obtain products with small variations in various mechanical properties.

[Embodiments of the invention]

Examples of the present invention will be described in detail below, but the present invention is not limited to the following examples unless the gist thereof is exceeded.

Example 1 A hybrid fiber-reinforced glass having an interlayer and intralayer hybrid structure was manufactured using high-strength carbon fiber (T300) and high-modulus carbon fiber (M2O). As the glass matrix, silicate glass (Corning, USA, code number 7740) was used. The sufficiently opened carbon fibers are passed through a slurry of glass powder dispersed in isopropyl alcohol to impregnate the spaces between the fibers, and then thoroughly dried. Next, the carbon fibers are cut to a predetermined length, and the cut pieces are arranged in a graphite mold so as to form the desired hybrid structure. This was hot pressed in a vacuum or in an argon or nitrogen atmosphere to obtain a plate-shaped hybrid fiber reinforced glass.

Test pieces for measuring various mechanical properties were cut out from the hybrid fiber-reinforced glass thus obtained and tested. As a result, the results shown in Tables 1, 3 to 8 were obtained. In addition, as a comparative example, high-strength carbon fiber (Toshiku Co., Ltd., T300) that is not hybrid fiber reinforced glass
The cases of fiber-reinforced glass composite materials reinforced with high-modulus carbon fibers (Toshishiku Co., Ltd., M2O) are also listed in Tables 1 and 2.

Example 2 A hybrid fiber-reinforced glass having an interlayer and intralayer hybrid structure was manufactured using SiC fiber (Nicalon, trademark of Nippon Carbon Co., Ltd.) and high modulus carbon fiber (M2O, manufactured by Toshiku Co., Ltd.). As a glass matrix,
Silicate glass (Corning, USA, code number 7)
740) was used. The preparation of the composite material was the same as in Example 1.

Test pieces for measuring various mechanical properties were cut out from the hybrid fiber-reinforced glass thus obtained and tested, and the results shown in Table 2 3 to 8 were obtained.

As a comparative example, a fiber-reinforced glass composite material reinforced with SiC fiber (Nippon Carbon Co., Ltd., Nicalon) and high-modulus carbon fiber (Toshiku Co., Ltd., M2O), which is not a hybrid fiber-reinforced glass, was also used. It is described in Tables 1 and 2.

Example 3 SiC fiber (Nippon Carbon Co., Ltd., Nicalon) and CVD
SiC fiber manufactured by the method (Abco, USA, 5C3
-2) was used to manufacture fiber reinforced glass with a hybrid structure. As the glass matrix, silicate glass (for example, Corning Co., USA, code number 774) is used.
0) was used. The method for manufacturing the composite material is the same as in Example 1. The arrangement of fibers and fiber bundles in the glass matrix was an interlayer hybrid arrangement. Test pieces for measuring mechanical properties were cut out from the composite material thus obtained, and the results shown in Tables 3 to 8 were obtained.

Fig. 1 Fig. 2 [Effects of the Invention] As described above, according to the present invention, compared to conventional fiber reinforced glass, two or more types of fibers with different properties are used, so A glass matrix composite material with high toughness can be obtained, and a material with high fracture energy and small variations in mechanical properties can also be obtained.

[Brief explanation of the drawing]

1 to 4 are block diagrams of a hybrid fiber-reinforced glass according to another embodiment of the present invention. In each figure, the same reference numerals indicate the same or corresponding parts, (1)
, (2), (3) are reinforcing fibers or fiber bundles, (4
) is a glass matrix, and (5) is a hybrid fiber reinforced glass.

Claims (1)

[Claims] (1) In fiber-reinforced glass, hybrid fiber reinforcement is characterized in that at least two or more types of fibers with different components or the same components but with different mechanical properties are composited into a glass matrix. glass.