莫来石基复合陶瓷高温摩擦表面粘附机理的研究

摘要/Abstract

摘要： 研究莫来石基复合陶瓷（ZTM、ZTM/Al）与氧化钇稳定氧化锆（TZP）陶瓷构成的摩擦副，在干摩滑动条件下，ZTM、ZTM/Al陶瓷的磨损率随环境温度的升高而逐渐降低，其摩擦表面可生成粘附保护层并出现负磨损现象。ZTM、ZTM/Al陶瓷高温摩擦表面产生粘附保护层的主要机理是对偶件TZP陶瓷中的Zr原子或磨屑向其摩擦表面扩散和吸附的结果。详细分析这种Zr原子表面扩散转移地主要影响因素，以及磨屑在摩擦表面的物理吸附和化学吸附的机理，得出了“ZTM、ZTM/Al摩擦表面粘附层的形成，其实质是由‘被动受磨’向‘主动抗磨’的机制转变”的结论，并展望了该抗磨机理的工程应用前景。

关键词: 高温摩擦, 磨损机理, 莫来石基复合陶瓷, 氧化锆, 粘附层

Abstract: The friction and wear properties of mullite-based composites, such as ZTM and ZTM/Al, are dealt with when they wore against TZP ceramics under dry sliding. It is found that the wear rates of ZTM and ZTM/Al ceramics decrease with the increase of temperatures and adhesive layers emerge on their surfaces. The main mechanisms of the formation of adhesive layers are surface diffusion of Zr atoms form TZP to ZTM and ZTM/Al and /or the adsorption of debris on the surface of ZTM and ZTM/Al surfaces during the friction processed. The main factors affecting the Zr atom diffusion are analyzed. The physical and chemical adsorption mechanisms of debris on ZTM and ZTM/Al surfaces are also studied. Therefore, a very important conclusion is that the formation of surface adhesive protective layers on the surfaces of ZTM and ZTM/Al ceramics is the wear mechanism transition from ‘passive wear’ to ‘active anti-wear’. The applied fields of the anti-wear mechanism are proposed as well.

Key words: Adhesive layer, High temperature tribology, Mullite-based composites, Wear mechanism, Zirconia oxide

中图分类号:

TQ174.758.12

谭业发;王耀华;徐燕申;于爱兵. 莫来石基复合陶瓷高温摩擦表面粘附机理的研究[J]. , 2000, 36(9): 76-82.

Tan Yefa;Wang Yaohua;Xu Yanshen;Yu Aibing. STUDY ON ADHESIVE MECHANISM OF MULLITE-BASED COMPOSITES AT ELEVATED TEMPERATURES[J]. , 2000, 36(9): 76-82.

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莫来石基复合陶瓷高温摩擦表面粘附机理的研究

STUDY ON ADHESIVE MECHANISM OF MULLITE-BASED COMPOSITES AT ELEVATED TEMPERATURES

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