Research on Notch Plasticity May Contribute to the Understanding of Stress Corrosion Cracking

J. Spretnak, C. A. Griffis
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引用次数: 2

Abstract

RESEARCH JUST COMPLETED AT THE OHIO STATE UNIVERSITY ON FACTORS LIMITING PLASTIC STRAIN UNDER A NOTCH (OR CRACK) MAY PROVE IMPORTANT IN ELUCIDATING CERTAIN ASPECTS OF PLASTIC ZONE BEHAVIOR IN STRESS CORROSION CRACKING. IT WAS FOUND THAT THE PLASTIC ZONE AT THE TIP OF THE CRACK EXPANDS ON LOADING UNTIL A CRITICAL STRAIN AT THE NOTCH ROOT IS ATTAINED. AT THIS STRAIN, THE MATERIAL UNDERGOES A RHEOLOGICAL TRANSFORMATION INTO FLUID-LIKE FLOW (VISCO- PLASTIC), IN WHICH IT IS SUSCEPTIBLE TO LOCALIZATION OF FLOW ALONG "CHARACTERISTICS" (SLIP LINES IN FIELDS), WHICH ARE DIRECTIONS OF CRITICAL MAXIMUM SHEAR STRESS AND ALSO DIRECTION OF PURE SHEAR. PLASTIC INSTABILITIES MAY BE MOUNTED ALONG THESE DIRECTIONS. WEAK INSTABILITIES LEAD TO STABLE SLOW CRACK PROPAGATION; STRONG INSTABILITIES LEAD TO UNSTABLE FAST PROPAGATION (BRITTLE FRACTURE). AGGRESSIVE CHEMICAL ENVIRONMENTS MAY AFFECT ONE OR BOTH OF THESE NEW MATERIAL PARAMETERS WHICH HAVE BEEN DISCLOSED, NAMELY THE CRITICAL STRAIN AT WHICH FLOW IS CONCENTRATED ALONG CHARACTERISTICS AND THE NATURE OF THE INSTABILITIES (STRONG OR WEAK) THAT CAN BE GENERATED ALONG CHARACTERISTICS. PLASTIC ZONE BEHAVIOR, THUS, INVOLVES METALLURGICAL STRUCTURE, RHEOLOGY, AND FORMAL PLASTICITY THEORY. /AUTHOR/
对缺口塑性的研究有助于对应力腐蚀开裂的认识
俄亥俄州立大学刚刚完成的一项关于缺口(或裂纹)下限制塑性应变的因素的研究,可能对阐明应力腐蚀开裂中塑性区行为的某些方面具有重要意义。结果表明,裂纹尖端的塑性区在加载过程中不断扩大,直至缺口根部达到临界应变。在此应变下,材料经历流变转变为类流体流动(粘塑性),在此过程中,材料容易受到沿“特征”(场中的滑移线)流动的局部化影响,这些“特征”是临界最大剪切应力方向,也是纯剪切方向。塑性不稳定性可以沿着这些方向安装。弱失稳导致稳定的缓慢裂纹扩展;强不稳定性导致不稳定快速扩展(脆性断裂)。腐蚀性化学环境可能会影响已披露的这些新材料参数中的一个或两个,即沿特征流动集中的临界应变和沿特征可能产生的不稳定性(强或弱)的性质。因此,塑性区行为涉及到金相组织、流变学和形式塑性理论。/作者/
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