Fiber damage during the consolidation of PVD Ti6Al4V coated nextel 610TM alumina fibers

Acta Metallurgica et Materialia Pub Date : 1995-10-01 DOI:10.1016/0956-7151(95)90145-0

J. Warren, D.M. Elzey, H.N.G. Wadley

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引用次数: 20

Abstract

Titanium matrix composites reinforced with sol-gel synthesized α-alumina fiber tows have attracted interest as a potentially low cost continuous fiber reinforced metal matrix composite system. We have conducted a detailed investigation of fiber damage during high temperature consolidation of PVD Ti6Al4V metallized sol-gel alumina fiber tows. Using both hot isostatic pressing and interrupted vacuum hot press consolidation cycles, the two principal mechanisms of fiber damage have been experimentally identified to be microbending/fracture and fiber matrix reaction. A time dependent micromechanics model incorporating the evolving geometry and mechanical properties of both the fibers and matrix has been formulated to simulate the fiber bending/failure mechanism in a representative unit cell and explore the effect of fiber strength loss due to reaction with the matrix. This model has been used to design a process cycle that minimizes damage by exploiting the enhanced superplastic deformation of the initially nanocrystalline PVD Ti6Al4V matrix.

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PVD Ti6Al4V涂层nextel 610TM氧化铝纤维固结过程中的纤维损伤

溶胶-凝胶合成α-氧化铝纤维束增强钛基复合材料作为一种潜在的低成本连续纤维增强金属基复合材料体系而备受关注。我们对PVD Ti6Al4V金属化溶胶-凝胶氧化铝纤维束在高温固结过程中的纤维损伤进行了详细的研究。通过热等静压和间断真空热压固结循环，实验确定了纤维损伤的两种主要机制是微弯曲/断裂和纤维基质反应。建立了一个包含纤维和基体几何和力学性能变化的随时间变化的微观力学模型，以模拟具有代表性的单元胞中的纤维弯曲/破坏机制，并探讨纤维与基体反应导致的强度损失的影响。该模型已被用于设计一个工艺周期，通过利用初始纳米晶PVD Ti6Al4V基体的增强超塑性变形来最大限度地减少损伤。

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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Acta Metallurgica et Materialia

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