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Method for preparing self-toughening silicon nitride ceramics

A technology of tough silicon nitride ceramics and tough silicon nitride, which is applied in the field of preparing self-toughened silicon nitride ceramics, can solve the problems of poor toughening effect and small aspect ratio of crystal grains, and achieve surface tension reduction and finished products High rate, good toughening effect

Inactive Publication Date: 2013-03-06
AEROSPACE INST OF ADVANCED MATERIALS & PROCESSING TECH
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

By the end of the 1980s, many researchers controlled the β-Si 3 N 4 Self-toughening Si with excellent mechanical properties due to small grain size 3 N 4 Materials, Luo Xuetao and others have done a lot of research in this area, studying the growth of silicon nitride whiskers in homogeneous or dense silicon nitride, and the β-Si in the prepared silicon nitride ceramics 3 N 4 The aspect ratio is about 10, and the longest is no more than 15. The obtained grain has a small aspect ratio and the toughening effect is not good.

Method used

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  • Method for preparing self-toughening silicon nitride ceramics

Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0044] (1) Preparation of silicon nitride foam ceramic body

[0045] Weigh 40g of silicon nitride powder, add 2.4g of sintering aids (0.8g of aluminum oxide and 1.6g of yttrium oxide), 0.4g of dispersant, 3.2g of molding solidification medium, 6g of carboxymethylcellulose (CMC) solution ( Carboxymethylcellulose (CMC) aqueous solution concentration is 4%) and 0.8g foaming agent, add 60g deionized water to form a mixture, utilize concentrated ammonia water to adjust the pH value of the mixture to 10, and make a slurry after ball milling for 12h; The slurry after ball milling was continued to be stirred at high speed for 20 minutes to foam, then an appropriate amount of initiator and catalyst was added, stirred for 5 minutes, injection molded, solidified and formed, and then the green body was dried (in the air) and debinding (burned out organic matter).

[0046] (2) Preparation of silicon nitride whisker framework

[0047] During the sintering process, the heating rate below 80...

Embodiment 2

[0055] (1) Preparation of silicon nitride foam ceramic body

[0056] Weigh 40g of silicon nitride powder, add 2.4g of sintering aids (0.8g of alumina and 1.6g of yttrium oxide), 0.4g of dispersant, 3.2g of forming and curing medium, and add 4g of carboxymethylcellulose (CMC) solution (the concentration of carboxymethyl cellulose (CMC) solution is 3%) and 0.8g foaming agent, add 60g deionized water to form a mixture, utilize concentrated ammonia water to adjust the pH of the mixture to be 10, and make a slurry after ball milling for 12h ; The slurry after ball milling continues to be stirred at high speed for 20 minutes to foam, and an appropriate amount of initiator and catalyst is added, stirred for 5 minutes, injection molded, solidified and formed, and then the green body is dried (in the air) and debinding (burning out organic matter).

[0057] (2) Preparation of silicon nitride whisker framework

[0058] During the sintering process, the heating rate below 800°C is 15°C / ...

Embodiment 3

[0066] (1) Preparation of silicon nitride foam ceramic body

[0067] Weigh 40g of silicon nitride powder, add 2.4g of sintering aids (0.8g of alumina and 1.6g of yttrium oxide), 0.4g of dispersant, 3.2g of forming and curing medium, and add 8g of carboxymethylcellulose (CMC) solution (the concentration of carboxymethyl cellulose (CMC) solution is 3%) and 0.8g foaming agent, add 60g deionized water to form a mixture, utilize concentrated ammonia water to adjust the pH of the mixture to be 10, and make a slurry after ball milling for 12h The slurry after ball milling continues to be stirred at high speed for 20 minutes to foam, add an appropriate amount of initiator and catalyst, stir for 5 minutes, injection mold, solidify and form, and then dry the green body (in the air) and debinding (burn out organic matter)

[0068] (2) Preparation of silicon nitride whisker framework

[0069] During the sintering process, the heating rate below 800°C is 15°C / min, and the atmosphere is va...

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Abstract

The invention provides a method for preparing self-toughening silicon nitride ceramics, and the method comprises the following steps that first a silicon nitride foam ceramic billet is prepared, then sintered to prepare a silicon nitride crystal whisker skeleton body, and finally a silicon nitride organic precursor is dipped, cracked and made into ceramics and the self-toughening silicon nitride ceramics is prepared. According to the method for preparing self-toughening silicon nitride ceramics, the silicon nitride ceramic foam body is obtained by directly foaming; then the silicon nitride ceramic foam body is sintered; a long column-shaped beta-silicon nitride crystal bar is fully grown through the special structure of a large number of pore spaces of the ceramic foam when in sintering; the grown long column-shaped beta-silicon nitride (Si3N4) crystal bar is nearly fully filled in each foam pore in the silicon nitride foam ceramic body; the average slenderness ratio of the beta-Si3N4 crystal bar is 20, and the maximum slenderness ratio can reach about 30; and the silicon nitride crystal whisker skeleton body which is obtained by sintering the silicon nitride foam ceramic billet is dipped and cracked to obtain the self-toughening silicon nitride ceramics, and the toughening effect is good.

Description

technical field [0001] The invention relates to a method for preparing self-toughened silicon nitride ceramics, belonging to the technical field of silicon nitride ceramics. Background technique [0002] Silicon nitride (Si 3 N 4 ) Ceramic is a high-temperature structural ceramic with excellent performance developed in the 1950s. It has high high-temperature strength, high hardness (Mohs hardness is 9), low high-temperature creep, low thermal conductivity, small thermal expansion coefficient, and good thermal shock resistance. , stable chemical performance, corrosion resistance and other characteristics. Taking advantage of the above properties, silicon nitride, as a high-temperature structural ceramic, has been applied to cutting tools, wear-resistant parts, automobile bearings, piston tops, cylinder liners, precision machinery and aircraft bearings, etc. In the end parts, there are also broad application prospects. [0003] However, since silicon nitride ceramics is a ...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): C04B35/584C04B35/622C04B38/02
Inventor 余娟丽杨金龙吕毅张天翔赵英民裴雨辰曾庆川
Owner AEROSPACE INST OF ADVANCED MATERIALS & PROCESSING TECH
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