1) aluminothermic reduction-carbonization
铝热还原碳化
1.
WC-TiC-Al2O3 powders were synthesized by means of aluminothermic reduction-carbonization with metallic Al powder,H2WO4,H4TiO4 and graphite as raw materials under the protection of coke granules.
以铝粉、钨酸、钛酸和石墨粉为原材料,利用埋碳保护法铝热还原碳化合成WC-TiC-Al2O3复合粉。
2) aluminothermic reduction-nitridation
铝热还原氮化
1.
Synthesizing temperature and content of aluminum were both the important influence factors on the phase composition of the products synthesized by aluminothermic reduction-nitridation.
本文利用铝灰和粉煤灰为原料,经原位铝热还原氮化法合成了Spinel-Sialon复相材料。
3) carbothermal reduction-nitridation
碳热还原氮化
1.
Preparation of nanocrystalline Ti(C,N) solid solution powders via carbothermal reduction-nitridation reaction of nano TiO_2 in close nitrogen atmosphere was investigated.
在封闭系统中,对纳米TiO2碳热还原氮化反应合成纳米晶Ti(C,N)固溶体粉末进行研究。
2.
With titanium-bearing blast furnace slag, silica fume, bauxite chalmette and carbon black as raw materials, (Ca, Mg)α′-Sialon-AlN-TiN powders were synthesized by carbothermal reduction-nitridation (CRN).
以含钛高炉渣、硅灰、高铝矾土熟料和炭黑为原料,采用碳热还原氮化法合成了(Ca,Mg)α′2Sialon2AlN2TiN粉。
3.
Factors influencing synthesis of β-Sialon by carbothermal reduction-nitridation are reviewed.
综述了采用碳热还原氮化法制备β-Sialon的影响因素。
4) CRN
碳热还原氮化
1.
Carbothermal Reduction and Nitridation(CRN) process is one of the effective methods with the potential for large-scaled industrial application, using for the preparation of low cost & high performance SiAlON ceramic materials.
碳热还原氮化工艺是近年来制备低成本高性能SiAlON陶瓷材料的一种实用方法,具有产业化生产潜力。
2.
TiN/β′-Sialon electroconductive ceramic powder was synthesized by CRN(carbothermal reduction-nitridation) with high-titania slag,bauxite chalmette,silicon fume and carbon black as starting materials.
以高钛渣、高铝矾土熟料、硅灰和炭黑为原料,采用碳热还原氮化法合成TiN/β′-Sialon导电陶瓷粉体。
3.
Carbothermal Reduction and Nitridation (CRN) process is one of the effective methods with the potential for large-scale industrial application, particularly for the preparation of low cost & high performance SiAlON refractories which can be used in future purifying metallurgy.
碳热还原氮化工艺具有低成本且有产业化生产的潜力等特点,因而被认为是制备洁净冶炼用SiAlON耐火材料的实用方法。
5) carbothermal reduction and nitridation
碳热还原氮化
1.
Based on thermodynamic analysis,Si3N4 powders were synthesized by carbothermal reduction and nitridation from iron ore tailings and carbon black as raw materials.
在热力学分析的基础上,以铁尾矿和碳黑为原料,采用碳热还原氮化法合成了Si3N4粉。
2.
Sialon powders were prepared by carbothermal reduction and nitridation method at 1450 ℃ and 1500 ℃ using high-alumina fly ash and carbon coke as raw materials.
以焦炭粉作为还原剂,在温度为1450℃,保温3 h时,配碳量为理论值的200%,碳热还原氮化高Al2O3粉煤灰可以获得的Fe-Sialon材料。
6) carbothermal reduction-nitriding
碳热还原-氯化
补充资料:三碳化四铝
国标编号 43026
CAS号 1299-86-1
分子式 Al4C3
分子量 143.91
黄色或绿灰色结晶块或粉末,有吸湿性;沸 点 2200℃(分解);熔点2100℃;溶解性:不溶于丙酮;密度:相对密度(水=1)2.36;稳定性:稳定;危险标记 10(遇湿易燃物品);主要用途:用作甲烷发生剂、催化剂、干燥剂等
2.对环境的影响:
一、健康危害
侵入途径:吸入、食入。
健康危害:对眼睛、粘膜和上呼吸道有刺激性。
二、毒理学资料及环境行为
危险特性:与水接触,会很快放出易燃气体甲烷,遇热源或火种能引起燃烧和爆炸。与酸类物质能发生剧烈反应。
燃烧(分解)产物:氧化铝、一氧化碳、二氧化碳。
3.现场应急监测方法:
4.实验室监测方法:
原子吸收法
5.环境标准:
前苏联 车间卫生标准 2mg/m3 [Al]
6.应急处理处置方法:
一、泄漏应急处理
隔离泄漏污染区,限制出入。切断火源。建议应急处理人员戴自给式呼吸器,穿消防防护服。不要直接接触泄漏物。小量泄漏:避免扬尘,用洁净的铲子收集于干燥、洁净、有盖的容器中。转移至安全场所。大量泄漏:用塑料布、帆布覆盖,减少飞散。与有关技术部门联系,确定清除方法。
二、防护措施
呼吸系统防护:作业时,应该佩戴自吸过滤式防尘口罩。
眼睛防护:戴化学安全防护眼镜。
身体防护:穿化学防护服。
手防护:戴橡胶手套。
其它:工作现场严禁吸烟、进食和饮水。保持良好的卫生习惯。
三、急救措施
皮肤接触:脱去被污染的衣着,用肥皂水和清水彻底冲洗皮肤。
眼睛接触:提起眼睑,用流动清水或生理盐水冲洗。就医。
吸入:迅速脱离现场至空气新鲜处。保持呼吸道通畅。如呼吸困难,给输氧。如呼吸停止,立即进行人工呼吸。就医。
食入:饮足量温水,催吐,就医。
灭火方法:禁止用水或泡沫灭火。灭火剂:干粉、干燥砂土。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条