Notched Three‐Point Bend Testing of GFRP Woven Laminates at Cryogenic Temperatures and Analysis of Fracture and Damage Properties

Advances in cryogenic engineering Pub Date : 2006-04-21 DOI:10.1063/1.2192360

K. Sanada, Y. Shindo

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Abstract

The cryogenic damage and fracture properties of GFRP (glass fiber reinforced polymer) woven laminates has been investigated theoretically and experimentally. Three‐point bend tests were carried out with SENB (single‐edge‐notched bend) specimens at room temperature, liquid nitrogen temperature and liquid helium temperature. SENB specimens with different widths and thicknesses were prepared and tested. The results of SENB specimens were compared with those of CT (compact tension) specimens. A finite element analysis was also conducted to predict the response of the damaged SENB specimen. Effective elastic moduli were determined under the assumption of uniform strain inside the representative volume element. Hoffman failure criterion was selected as the criterion for fiber‐dominated failure, and matrix microcracking was detected by the maximum strain criterion. The virtual crack extension method was adopted to calculate strain energy release rate which leads to determination of stress intensity factor. In order to verify the model, correlations between experimental and analytical results were made, in terms of the load‐displacement response and the extent of damage growth. Reasonable agreements were found between the calculations and the experimental data.

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低温下GFRP编织层压板的缺口三点弯曲试验及断裂和损伤性能分析

对玻璃钢(GFRP)机织层合板的低温损伤和断裂性能进行了理论和实验研究。在室温、液氮温度和液氦温度下，用SENB(单刃缺口弯曲)试样进行三点弯曲试验。制备了不同宽度和厚度的SENB试样并进行了试验。将SENB试样的结果与CT(致密张力)试样的结果进行比较。通过有限元分析预测了受损SENB试件的响应。在假设具有代表性的体积单元内部应变均匀的情况下，确定了有效弹性模量。采用Hoffman破坏准则作为纤维主导破坏准则，采用最大应变准则检测基体微裂纹。采用虚拟裂纹扩展法计算应变能释放率，从而确定应力强度因子。为了验证该模型，在荷载-位移响应和损伤增长程度方面，将实验结果与分析结果进行了关联。计算结果与实验数据吻合较好。

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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Advances in cryogenic engineering

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