Creep limitations of current polycrystalline ceramic fibers

IF 8.3 1区 材料科学 Q1 MATERIALS SCIENCE, COMPOSITES Composites Science and Technology Pub Date : 1994-01-01 DOI:10.1016/0266-3538(94)90191-0
James A. DiCarlo
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引用次数: 85

Abstract

The objective of this paper is to present an overview of the issues, property status, and potential for use of creep-prone polycrystalline ceramic fibers in thermostructural ceramic composites. Issues arise because the fine-grained microstructures of high-strength fibers can result in creep-related property changes, often at temperatures as low as 800°C. The underlying mechanism is grain boundary sliding controlled by grain size and grain boundary character, and thus by the fiber processing method. With the assumption of upper and lower limit creep requirements, the creep properties of a variety of current SiC and Al2O3 polycrystalline fibers are reviewed and discussed. Property evaluation is based on the results of a simple bend stress relaxation test which allows predictive creep equations to be developed for each fiber type describing the effects of time, temperature, and applied stress. It is shown that sintered SiC fibers with grain sizes below 1000 nm appear to offer the best performance in terms of strength and creep resistance. However, even these fibers may not be capable of long-term service above 1400°C.

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当前多晶陶瓷纤维的蠕变限制
本文综述了易蠕变多晶陶瓷纤维在热结构陶瓷复合材料中的问题、性能现状和应用潜力。问题的出现是因为高强度纤维的细粒度微观结构可能导致蠕变相关的性能变化,通常在低至800°C的温度下。其基本机理是晶界滑动,由晶粒尺寸和晶界特性控制,从而受纤维加工方法的影响。在蠕变要求的上下限假设下,综述和讨论了当前各种SiC和Al2O3多晶纤维的蠕变性能。性能评估是基于一个简单的弯曲应力松弛测试的结果,该测试允许为每种纤维类型开发预测蠕变方程,描述时间、温度和施加应力的影响。结果表明,晶粒尺寸小于1000 nm的烧结SiC纤维在强度和抗蠕变性能方面表现最佳。然而,即使是这些光纤也可能无法在1400°C以上长期使用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Composites Science and Technology
Composites Science and Technology 工程技术-材料科学:复合
CiteScore
16.20
自引率
9.90%
发文量
611
审稿时长
33 days
期刊介绍: Composites Science and Technology publishes refereed original articles on the fundamental and applied science of engineering composites. The focus of this journal is on polymeric matrix composites with reinforcements/fillers ranging from nano- to macro-scale. CSTE encourages manuscripts reporting unique, innovative contributions to the physics, chemistry, materials science and applied mechanics aspects of advanced composites. Besides traditional fiber reinforced composites, novel composites with significant potential for engineering applications are encouraged.
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