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      (A) micromechanical approach for the prediction of fatigue life in composite laminates

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      https://www.riss.kr/link?id=T12336069

      • 저자
      • 발행사항

        서울 : 한양대학교 대학원, 2011

      • 학위논문사항

        학위논문(석사) -- 한양대학교 대학원 , 기계공학과 , 2011. 2

      • 발행연도

        2011

      • 작성언어

        영어

      • 주제어
      • 발행국(도시)

        서울

      • 형태사항

        iv, 40 p. : 삽도 ; 26 cm.

      • 일반주기명

        지도교수: 하성규
        Abstract: p. i
        References: p. 38-40

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        • 한양대학교 안산캠퍼스 소장기관정보
        • 한양대학교 중앙도서관 소장기관정보
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      다국어 초록 (Multilingual Abstract) kakao i 다국어 번역

      A micromechanics based fatigue life prediction of composite laminates under multi-axial loading was developed. Many mechanical tests are required to fully characterize the composite laminates made of various materials and having different layup sequences. In order to reduce number of tests, a methodology was presented in this paper to predict fatigue life of composite laminates based on fatigue life of constituents, i.e. the fiber, matrix and interface, using micromechanics of failure (MMF). For matrix, the equivalent stress model which is generally used for isotropic materials was employed to take care of multi-axial fatigue loading. For fiber, a maximum stress model considering only stress along fiber direction was used. Critical plane model was introduced for the interface of the fiber and matrix, but interface fatigue strength was presumed strong enough than that of matrix and fiber and, therefore, its failure was ignored. The modified Goodman approach was utilized to take into account the mean stress effect. In order to validate the proposed methodology, the fatigue life of three different GFRP laminates, UDT[90°], BX[±45°]S and TX[0°2/±45°]S, was examined experimentally. The predictions are compared with the experimental data, and are shown in good agreement. A comprehensive implementation example is also presented for the case of composite wind turbine rotor blade structure.
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      A micromechanics based fatigue life prediction of composite laminates under multi-axial loading was developed. Many mechanical tests are required to fully characterize the composite laminates made of various materials and having different layup sequen...

      A micromechanics based fatigue life prediction of composite laminates under multi-axial loading was developed. Many mechanical tests are required to fully characterize the composite laminates made of various materials and having different layup sequences. In order to reduce number of tests, a methodology was presented in this paper to predict fatigue life of composite laminates based on fatigue life of constituents, i.e. the fiber, matrix and interface, using micromechanics of failure (MMF). For matrix, the equivalent stress model which is generally used for isotropic materials was employed to take care of multi-axial fatigue loading. For fiber, a maximum stress model considering only stress along fiber direction was used. Critical plane model was introduced for the interface of the fiber and matrix, but interface fatigue strength was presumed strong enough than that of matrix and fiber and, therefore, its failure was ignored. The modified Goodman approach was utilized to take into account the mean stress effect. In order to validate the proposed methodology, the fatigue life of three different GFRP laminates, UDT[90°], BX[±45°]S and TX[0°2/±45°]S, was examined experimentally. The predictions are compared with the experimental data, and are shown in good agreement. A comprehensive implementation example is also presented for the case of composite wind turbine rotor blade structure.

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      목차 (Table of Contents)

      • List of Figures ii
      • List of Tables iii
      • Nomenclature iv
      • 1. Introduction 1
      • List of Figures ii
      • List of Tables iii
      • Nomenclature iv
      • 1. Introduction 1
      • 1.1. Problem Statement 3
      • 1.2. Objectives 4
      • 1.3. Approach 4
      • 1.4. Structure of the Thesis 5
      • 2. Theory and Methodology 6
      • 2.1. Micromechanics of Failure (MMF) Approach 6
      • 2.2. Macro and Micro Stresses 7
      • 2.3. Fatigue Life Prediction Models 9
      • 3. Experiments and Results 14
      • 3.1. Material System 14
      • 3.2. Mechanical Testing Equipment 15
      • 3.3. Static Testing 15
      • 3.4. Fatigue Testing 16
      • 3.5. Fiber Volume Fraction of Laminates 18
      • 4. Verification of Life Prediction Methodology 19
      • 5. Structural Application: Wind Turbine Blade 22
      • 6. Conclusion 35
      • Acknowledgement 37
      • References 38
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