Microscale damage evolution and stress redistribution in Ti-SiC fiber composites

Jay C. Hanan; Ersan Üstündag; Irene J. Beyerlein; Geoffrey A. Swift; Jonathan D. Almer; Ulrich Lienert; Dean R. Haeffner

doi:10.1016/S1359-6454(03)00240-4

Microscale damage evolution and stress redistribution in Ti-SiC fiber composites

Jay C. Hanan, Ersan Üstündag^*, Irene J. Beyerlein, Geoffrey A. Swift, Jonathan D. Almer, Ulrich Lienert, Dean R. Haeffner

^*Bu çalışma için yazışmadan sorumlu yazar

Araştırma sonucu: Dergiye katkı › Makale › bilirkişi

18 Atıf (Scopus)

Özet

Local damage evolution in a composite is the primary micromechanical process determining its fracture toughness, strength, and lifetime. In this study, high energy X-ray microdiffraction was used to measure the lattice strains of both phases in a Ti-SiC fiber composite laminate. The data provided in situ load transfer information under applied tensile stress at the scale of the microstructure. To better understand damage evolution, predictions of a modified shear lag model were compared to the strain data. This comparison (1) demonstrated the importance of accounting for the matrix axial and shear stiffness, (2) optimized the stiffness ratio for load transfer, and (3) improved the interpretation of the ideal planar geometry commonly used in micromechanical composite models. In addition, the results proved the matrix within and around the damage zone sustained substantial axial load and locally yielded. It was also shown that an area detector is essential in such a diffraction study as it provides multi-axial strain data and helps eliminate the "graininess" problem.

Orijinal dil	İngilizce
Sayfa (başlangıç-bitiş)	4239-4250
Sayfa sayısı	12
Dergi	Acta Materialia
Hacim	51
Basın numarası	14
DOI'lar	https://doi.org/10.1016/S1359-6454(03)00240-4
Yayın durumu	Yayınlandı - 15 Ağu 2003
Harici olarak yayınlandı	Evet

Finansman

This study was supported by the National Science Foundation (CAREER grant no. DMR-9985264) at Caltech and a Laboratory-Directed Research and Development Project (no. 2000043) at Los Alamos. The work at the Advanced Photon Source was supported by the US Department of Energy, Office of Basic Energy Sciences (contract no. W-31-109-ENG-38). The authors are grateful to Dr. H. Deve at 3M Corp. for providing the specimens and helpful discussions about the properties of Ti–SiC composites. They also express their gratitude to Dr. I.C. Noyan at IBM Watson Research Center for the use of his stress fixture.

Finansörler	Finansör numarası
Laboratory-Directed Research and Development Project	2000043
Los Alamos
National Science Foundation	DMR-9985264
U.S. Department of Energy
Basic Energy Sciences	W-31-109-ENG-38

Belgeye Erişim

10.1016/S1359-6454(03)00240-4

Diğer Dosyalar ve Linkler

Link to publication in Scopus

Alıntı Yap

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title = "Microscale damage evolution and stress redistribution in Ti-SiC fiber composites",

abstract = "Local damage evolution in a composite is the primary micromechanical process determining its fracture toughness, strength, and lifetime. In this study, high energy X-ray microdiffraction was used to measure the lattice strains of both phases in a Ti-SiC fiber composite laminate. The data provided in situ load transfer information under applied tensile stress at the scale of the microstructure. To better understand damage evolution, predictions of a modified shear lag model were compared to the strain data. This comparison (1) demonstrated the importance of accounting for the matrix axial and shear stiffness, (2) optimized the stiffness ratio for load transfer, and (3) improved the interpretation of the ideal planar geometry commonly used in micromechanical composite models. In addition, the results proved the matrix within and around the damage zone sustained substantial axial load and locally yielded. It was also shown that an area detector is essential in such a diffraction study as it provides multi-axial strain data and helps eliminate the {"}graininess{"} problem.",

keywords = "Damage evolution, Mechanical properties, Metal matrix composites, Micromechanical modeling, X-ray diffraction",

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AU - Hanan, Jay C.

AU - Üstündag, Ersan

AU - Beyerlein, Irene J.

AU - Swift, Geoffrey A.

AU - Almer, Jonathan D.

AU - Lienert, Ulrich

AU - Haeffner, Dean R.

PY - 2003/8/15

Y1 - 2003/8/15

N2 - Local damage evolution in a composite is the primary micromechanical process determining its fracture toughness, strength, and lifetime. In this study, high energy X-ray microdiffraction was used to measure the lattice strains of both phases in a Ti-SiC fiber composite laminate. The data provided in situ load transfer information under applied tensile stress at the scale of the microstructure. To better understand damage evolution, predictions of a modified shear lag model were compared to the strain data. This comparison (1) demonstrated the importance of accounting for the matrix axial and shear stiffness, (2) optimized the stiffness ratio for load transfer, and (3) improved the interpretation of the ideal planar geometry commonly used in micromechanical composite models. In addition, the results proved the matrix within and around the damage zone sustained substantial axial load and locally yielded. It was also shown that an area detector is essential in such a diffraction study as it provides multi-axial strain data and helps eliminate the "graininess" problem.

AB - Local damage evolution in a composite is the primary micromechanical process determining its fracture toughness, strength, and lifetime. In this study, high energy X-ray microdiffraction was used to measure the lattice strains of both phases in a Ti-SiC fiber composite laminate. The data provided in situ load transfer information under applied tensile stress at the scale of the microstructure. To better understand damage evolution, predictions of a modified shear lag model were compared to the strain data. This comparison (1) demonstrated the importance of accounting for the matrix axial and shear stiffness, (2) optimized the stiffness ratio for load transfer, and (3) improved the interpretation of the ideal planar geometry commonly used in micromechanical composite models. In addition, the results proved the matrix within and around the damage zone sustained substantial axial load and locally yielded. It was also shown that an area detector is essential in such a diffraction study as it provides multi-axial strain data and helps eliminate the "graininess" problem.

KW - Damage evolution

KW - Mechanical properties

KW - Metal matrix composites

KW - Micromechanical modeling

KW - X-ray diffraction

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JO - Acta Materialia

JF - Acta Materialia

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Microscale damage evolution and stress redistribution in Ti-SiC fiber composites

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