The present invention provides a porous non-metallic material including a material body, the material body is composed of pore cavities and cavity walls formed by surrounding the pore cavities in three-dimensional space. The pore cavities are uniformly distributed, and each pore cavity is three-dimensionally interconnected. The pore cavities are uniformly distributed means that the pore cavities are uniformly distributed under any unit-level volume on the porous material. The present invention provides a specific and clear measurement method for pore cavities distribution uniformity of the porous material, that is, the pore distribution uniformity of the porous material and the hierarchical structure thereof is measured on the scale of the small unit-level volume. Such porous structure is highly uniform, thereby ensuring the uniformity of the properties of the porous material.

A preform for making a component of a braking system having a fibre-reinforced ceramic composite material, obtained by forming and subsequent pyrolysis of a pre-preg is described. Also described is a component of a braking system made wholly or in part from the preform, and a method for making a preform in a fibre-reinforced ceramic composite material.

The present invention is a granular material that can be well recoated regardless of the type of the granular material, and enables a refractory aggregate in an unprinted portion to be used without any regeneration process, in the manufacture of a three-dimensional laminated and shaped mold. This granular material is a granular material for use in three-dimensional laminated mold shaping, and obtained by adding a material that causes a hydration reaction having a moisture absorbing function and generates a catalytic effect to a coating material mixed with or coated with an acid as a catalyst which activates and hardens an organic binder for binding the granular material.

A slurry composition includes, by volume, a ceramic composition in an amount of from about 60 to about 75 percent and a binder in an amount of from about 25 to about 40 percent, plus a platinum group metal catalyst and a dopant. The ceramic composition includes, by volume of the ceramic composition, fine fused silica particles having a particle size d.sub.50 of from about 4 m to about 7 m, in an amount of from about 7 to about 40 percent; coarse fused silica particles having a d.sub.50 of from about 25 m to about 33 m, in an amount of from about 29 to about 60 percent; inert filler particles having a d.sub.50 of from about 5 m to about 25 m, in an amount of from about 8 to about 40 percent; and fumed silica particles, in an amount of up to about 15 percent.

Provided is a ceramic-resin composite body that has good mass productivity and product properties (heat dissipation properties, insulation properties and adhesive properties), and particularly a ceramic-resin composite that can dramatically improve the heat dissipation properties for electronic devices. The ceramic-resin composite body includes: 35 to 70% by volume of a sintered body having a monolithic structure in which non-oxide ceramic primary particles having an average major diameter of from 3 to 60 m and an aspect ratio of from 5 to 30 are three-dimensionally continuous; and 65 to 30% by volume of a thermosetting resin composition having an exothermic onset temperature of 180 C. or more and a curing rate of from 5 to 60% as determined with a differential scanning calorimeter, and having a number average molecular weight of from 450 to 4800, wherein the sintered body is impregnated with the thermosetting resin composition.

A composition including a binder and a variable thermal conductivity material satisfying a conditional expression 1, wherein a content of the variable thermal conductivity material is from 300 parts by weight to 10,000 parts by weight with respect to a content of 100 parts by weight of the binder:
?.sub.max/?.sub.25?1.2[conditional expression 1] (wherein, ?.sub.25 represents a thermal conductivity at 25? C., and ?.sub.max represents the maximum value of a thermal conductivity at 200? C. or 500? C.).

A sized yarn for subjecting to a textile operation, the yarn including a plurality of ceramic and/or carbon fibers; an interphase coating covering the fibers; and a film covering the interphase coating and including a linear polysiloxane.

Ceramic composite materials, devices and methods are shown. In selected examples, ceramic materials are processed at low temperatures that permit incorporation of low temperature components, such as polymer components. manufacturing methods include, but are not limited to, injection molding, autoclaving and calendaring.

A method for manufacturing a SiC ceramic part is provided. The method includes mixing SiC micron powders, nano carbon black and an additive in a solvent to obtain a spray slurry. The spray slurry is subjected to spray granulation to obtain SiC granulation powders. The SiC granulation powders and SiC unprocessed powders are mixed and printed by 3DP to obtain a green body. Then the green body is impregnated in a phenolic resin precursor and undergoes a cracking reaction to obtain a compact body. Finally, the compact body is subjected to reactive sintering to obtain the SiC ceramic part. The method is beneficial to improving the density and the strength of the SiC ceramic part.

Provided is a ceramic-resin composite body that has good mass productivity and product properties (heat dissipation properties, insulation properties and adhesive properties), and particularly a ceramic-resin composite that can dramatically improve the heat dissipation properties for electronic devices. The ceramic-resin composite body includes: 35 to 70% by volume of a sintered body having a monolithic structure in which non-oxide ceramic primary particles having an average major diameter of from 3 to 60 m and an aspect ratio of from 5 to 30 are three-dimensionally continuous; and 65 to 30% by volume of a thermosetting resin composition having an exothermic onset temperature of 180 C. or more and a curing rate of from 5 to 60% as determined with a differential scanning calorimeter, and having a number average molecular weight of from 450 to 4800, wherein the sintered body is impregnated with the thermosetting resin composition.