CN102531622A - Method for producing high-strength silicon nitride doped neodymium dysprosium - Google Patents

Method for producing high-strength silicon nitride doped neodymium dysprosium Download PDF

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Publication number
CN102531622A
CN102531622A CN201010620801XA CN201010620801A CN102531622A CN 102531622 A CN102531622 A CN 102531622A CN 201010620801X A CN201010620801X A CN 201010620801XA CN 201010620801 A CN201010620801 A CN 201010620801A CN 102531622 A CN102531622 A CN 102531622A
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China
Prior art keywords
silicon nitride
dysprosium
neodymium
dysprosium oxide
high strength
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CN201010620801XA
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Chinese (zh)
Inventor
陈海
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SUZHOU ZHONGGAO NEW MATERIAL TECHNOLOGY CO LTD
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SUZHOU ZHONGGAO NEW MATERIAL TECHNOLOGY CO LTD
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Priority to CN201010620801XA priority Critical patent/CN102531622A/en
Publication of CN102531622A publication Critical patent/CN102531622A/en
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Abstract

The invention relates to the technical field of ceramic materials, in particular to a method for producing high-performance silicon nitride (Si3N4) ceramic through pressureless sintering by taking dysprosium oxide and neodymium oxide as additives. The ceramic comprises the following components in percentage by mass: 3 to 7 percent of dysprosium oxide, 5 to 8 percent of neodymium oxide and 85 to 92 percent of silicon nitride. The invention aims to overcome the disadvantages of the prior art and provide the method for producing the high-performance silicon nitride ceramic through pressureless sintering by taking the dysprosium oxide and the neodymium oxide as the additives. The ceramic can be widely applied to the preparation of parts in the fields of chemical industry, machinery, metallurgy, aerospace and the like.

Description

The working method of high strength silicon nitride doping neodymium dysprosium
[technical field]
The present invention relates to a kind of technical field of ceramic material, specifically is the method for a kind of dysprosium oxide Neodymium trioxide as additive pressureless sintering production high-performance silicon nitride ceramics.
[background technology]
Silicon nitride ceramics has excellent mechanical behavior under high temperature, is acknowledged as one of the most rising high temperature resistant structure ceramics.Silicon nitride is as a kind of covalent linkage platform thing, and spread coefficient is little, does not have fusing point, decomposes ammonification and silicon about 2173K, is difficult to sintering.Common silicon nitride ceramics respond sintering and hot pressed sintering, the reaction sintering density is poor, poor mechanical property, though hot pressed sintering density is high, mechanical property is good, cost is higher, is difficult to scale operation.And pressureless sintering falls between, because silicon nitride ceramics is the covalent linkage compound, and the pressureless sintering difficulty, the density that improves the pressureless sintering silicon nitride ceramics becomes the research focus, adds rare earth oxide usually as sintering aid, like iridium oxide.But the cost of iridium oxide is higher, and is unfavorable for the application of silicon nitride.We select for use the dysprosium oxide Neodymium trioxide as sintered density and the mechanical property of additive to improve silicon nitride for this reason.
[summary of the invention]
The objective of the invention is to overcome the deficiency of prior art, the method for a kind of dysprosium oxide Neodymium trioxide as additive pressureless sintering production high-performance silicon nitride ceramics is provided.Working method of the present invention is simple, and cost is low, is prone to realize industrialization production; The silicon nitride ceramics that dysprosium oxide Neodymium trioxide of the present invention is produced as additive pressureless sintering has the density height, the characteristics that mechanical property is good.
The present invention realizes through following technical scheme:
The silicon nitride ceramics that dysprosium oxide Neodymium trioxide involved in the present invention is produced as additive pressureless sintering, component and mass percentage content are: dysprosium oxide 3%~7%, Neodymium trioxide 5%~8%, silicon nitride 85%~92%.
3~6 microns of described dysprosium oxide granularities, 5~7 microns of Neodymium trioxide granularities, 0.4~0.7 micron of silicon nitride granularity.
The silicon nitride ceramics method that dysprosium oxide Neodymium trioxide involved in the present invention is produced as additive pressureless sintering comprises the steps:
Step 1; Take by weighing dysprosium oxide Neodymium trioxide and silicon nitride ceramics powder respectively; In planetary ball mill, change mixing 2 hours with PM 270~330, dispersion medium is an absolute ethyl alcohol, subsequently 60 ℃ of oven dry; Time is 2~3 hours, dysprosium oxide Neodymium trioxide that obtains mixing and silicon nitride ceramics mixed powder;
Step 2 at 75~100Mpa forming under the pressure, forms biscuit with the mixed powder of step 1;
Step 3, with the biscuit in the step 2 in vacuum carbon tube furnace under nitrogen protection, under 1400~1550 ℃ of temperature, be incubated 12~18 hours.
Step 4 is taken out the silicon nitride ceramics that burns till in the step 3 detection volume density and mechanical property.
In the step 1, the weight percent of said dysprosium oxide is 3%~7%, and the weight percent of Neodymium trioxide is 5%~8%, and the weight percent of silicon nitride is 85%~92%.
In the step 1, α-Si in the said silicon nitride 3N 4Content is greater than 90%.
In the step 1, said dysprosium oxide Neodymium trioxide content is all greater than 98%.
In the step 3, said nitrogen gas pressure is 1~2 normal atmosphere.
In the step 4, said mechanical property is a folding strength.
Among the present invention, described dysprosium oxide Neodymium trioxide plays the effect of sintering aid, under 1400~1550 ℃ of high temperature sintering conditions, forms liquid phase, makes the silicon nitride ceramics densification.
The present invention has following beneficial effect: the silicon nitride ceramics compactness extent is high, and mechanical property is good, satisfies the actual needs that use.This preparation method is simple, and cost is low, is prone to realize industrialization production.
[embodiment]
Below in conjunction with embodiment the present invention is described further.Production technology of the present invention is to implement easily to this professional people.Present embodiment provided detailed embodiment and process, but protection scope of the present invention is not limited to following embodiment being to implement under the prerequisite with technical scheme of the present invention.The experimental technique of unreceipted actual conditions in the following example, usually according to normal condition, or the condition of advising according to manufacturer.
Embodiment
The dysprosium oxide Neodymium trioxide is Ganzhou Jiarun novel material ltd, and silicon nitride powder is the M11 powder that German Starck company produces.Take by weighing 3% dysprosium oxide, 5% Neodymium trioxide and 92% silicon nitride powder respectively according to weight percent.
Above-mentioned two kinds of powder (QM-3SP2 of Nanjing Univ. Instrument Factory type) in planetary ball mill are mixed, and rotating speed 300 changes 1.5 hours time.With the forming under the pressure of powder mix, biscuit (the flourish electric furnace ZT-40-20 of ltd of Shanghai occasion type) 1450 ℃ in vacuum carbon tube furnace is incubated 16 hours at 80Mpa.
The volume density of the silicon nitride ceramics that present embodiment obtains is 3.61g/cm 3, folding strength is 678Mpa.

Claims (7)

1. the silicon nitride ceramics produced as additive pressureless sintering of the related dysprosium oxide Neodymium trioxide of the working method of high strength silicon nitride doping neodymium dysprosium, component and mass percentage content are: dysprosium oxide 3%~7%, Neodymium trioxide 5%~8%, silicon nitride 85%~92%.3~6 microns of described dysprosium oxide granularities, 5~7 microns of Neodymium trioxide granularities, 0.4~0.7 micron of silicon nitride granularity.
2. the silicon nitride ceramics method that the related dysprosium oxide Neodymium trioxide of the working method of high strength silicon nitride doping neodymium dysprosium according to claim 1 is produced as additive pressureless sintering comprises the steps:
Step 1; Take by weighing dysprosium oxide Neodymium trioxide and silicon nitride ceramics powder respectively; In planetary ball mill, change mixing 2 hours with PM 270~330, dispersion medium is an absolute ethyl alcohol, subsequently 60 ℃ of oven dry; Time is 2~3 hours, dysprosium oxide Neodymium trioxide that obtains mixing and silicon nitride ceramics mixed powder;
Step 2 at 75~100Mpa forming under the pressure, forms biscuit with the mixed powder of step 1;
Step 3, with the biscuit in the step 2 in vacuum carbon tube furnace under nitrogen protection, under 1400~1550 ℃ of temperature, be incubated 12~18 hours.
Step 4 is taken out the silicon nitride ceramics that burns till in the step 3 detection volume density and mechanical property.
3. the working method of high strength silicon nitride doping neodymium dysprosium according to claim 2; The weight percent that it is characterized in that dysprosium oxide described in the step 1 is 3%~7%; The weight percent of Neodymium trioxide is 5%~8%, and the weight percent of silicon nitride is 85%~92%.
4. the working method of high strength silicon nitride doping neodymium dysprosium according to claim 2 is characterized in that in the step 1, α-Si in the said silicon nitride 3N 4Content is greater than 90%.
5. the working method of high strength silicon nitride doping neodymium dysprosium according to claim 2 is characterized in that in the step 1, and content is all greater than 98% in the said dysprosium oxide Neodymium trioxide.
6. the working method of high strength silicon nitride doping neodymium dysprosium according to claim 2 is characterized in that in the step 3, and said nitrogen gas pressure is 1~2 normal atmosphere.
7. the working method of high strength silicon nitride doping neodymium dysprosium according to claim 2 is characterized in that in the step 4, and said mechanical property is a folding strength.
CN201010620801XA 2010-12-29 2010-12-29 Method for producing high-strength silicon nitride doped neodymium dysprosium Pending CN102531622A (en)

Priority Applications (1)

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CN201010620801XA CN102531622A (en) 2010-12-29 2010-12-29 Method for producing high-strength silicon nitride doped neodymium dysprosium

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Application Number Priority Date Filing Date Title
CN201010620801XA CN102531622A (en) 2010-12-29 2010-12-29 Method for producing high-strength silicon nitride doped neodymium dysprosium

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CN102531622A true CN102531622A (en) 2012-07-04

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Application publication date: 20120704