Residual Strength and Fatigue Lifetime of ... - Solid Mechanics
Residual Strength and Fatigue Lifetime of ... - Solid Mechanics Residual Strength and Fatigue Lifetime of ... - Solid Mechanics
Ratcliffe J. and Cantwell W. J. (2001), Center Notched Flexure Sandwich Geometry for Characterizing Skin–Core Adhesion in Thin-Skinned Sandwich Structures, Journal of Reinforced Plastics and Composites, 20(11): 945–70. Reeder J. and Crews J. H. (1990), Mixed-Mode Bending Method for Delamination Testing, AIAA Journal, 28(7):1270–6. Riccio A., Perugini P. and Scaramuzzino F. (2001), Embedded Delamination Growth in Composite Panels under Compressive Load, Composites Part B – Engineering, 32(3): 209-218. Sallam S. and Simitses G. J. (1985), Delamination Buckling and Growth of Flat, Cross/ply Laminates, Composite Structures, 4(4): 361-381. Sankar B. V. and Narayan M. (2001), Finite Element Analysis of Debonded Sandwich Beams Under Axial Compression, Journal of sandwich structures and materials, 3: 197-219. Shen F., Lee K. and Tay T. (2001), Modeling Delamination Growth in Laminated Composites, Composite Science and Technology, 61: 1239–1251. Shenoi R. A., Clark S. D. and Allen H. G. (1995), Fatigue Behavior of Polymer Composite Sandwich Beams, Journal of Composite Materials, 29: 2423–2445. Shi Z. and Zhang R. (2009), Numerical Simulation of Interfacial Crack Growth Under Fatigue Load, Fatigue Fracture in Engineering Materials & Structures, 32: 26–32. Shipsha A. and Zenkert D. (2003), Fatigue Behaviour of Foam Core Sandwich Beams with Sub- Interface Impact Damage, Journal of Sandwich Structures and Materials, 5(1): 147-160. Shipsha A., Burman M. and Zenkert D. (1999), Interfacial Fatigue Crack Growth in Foam Core Sandwich Structures, Fatigue and Fracture of Engineering Materials and Structures, 22: 123- 131. Shipsha, A., Burman, M. and Zenkert, D. (2000), On Mode I Fatigue Crack Growth in Foam Core Materials for Sandwich Structures, Journal of Sandwich Structures & Materials, 2(2): 103- 116. Sou Z. (1990), Singularities, Interfaces and Cracks in Dissimilar Anisotropic Media, Proceedings of the Royal Society of London, 427: 331-358. Southwell R. (1932), On the Analysis of Experimental Observations in Problems of Elastic Stability, Proceedings of the Royal Society of London, 601–616. Suo, Z. (1989), Singularities Interacting with Interface and Cracks. International Journal of Solids and Structures, 25: 1133-1142. 142
Suo, Z. (1990), Singularities, Interfaces and Cracks in Dissimilar Anisotropic Media, Proc. Royal Society of London, A(427): 331-358. Vadakke V. and Carlsson L. A. (2004), Experimental Investigation of Compression Failure of Sandwich Specimens with Face/Core Debond, Composites Part B: Engineering, 35: 583-590. Van Paepegem W., Degrieck J. and De Baets P. (2001), Finite Element Approach for Modeling Fatigue Damage in Fiber-Reinforced Composite Materials, Composites Part B – Engineering, 32: 575–88. Veedu V. and Carlsson L. A. (2005), Finite Element Buckling Analysis of Sandwich Columns Containing a Face/Core Debond, Composite Structures, 69(2): 143–148. Williams M. L. (1959), The Stresses Around a Fault or Crack in Dissimilar Media, Bull. Seismological Sot. America, 49: 199-404. Xie Z. and Vizzini A. J. (2005), Damage Propagation in a Composite Sandwich Panel Subjected to Increasing Uniaxial Compression after Low-Velocity Impact, Journal of sandwich structures and materials, 7: 269-290. Zenkert D, Burman M. (2008), Tension, Compression and Shear Fatigue of a Closed Foam, Composite Science and Technology, 69: 785–92. Zenkert D. (1997), An Introduction to Sandwich Construction, London: EMAS. Zenkert D. And Burman M. (2010), Fatigue of Closed Cell Foams in Compression, Journal of Sandwich Structures and Materials, 13(4): 467-478. Zenkert D. and Burman M. (2011), Failure Mode Shifts During Constant Amplitude Fatigue Loading of GFRP/Foam Core Sandwich Beams, International Journal of Fatigue, 33: 217–222. 143
- Page 114 and 115: H250 Specimen H100 Specimen H45 Spe
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- Page 124 and 125: Crack length [mm] Crack length [mm]
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- Page 128 and 129: should be taken into account for a
- Page 130 and 131: Figure 5.25: Kinking of the crack i
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- Page 136 and 137: compared to the 65% efficiency obta
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- Page 142 and 143: Figure 5.42: Zero and ninety degree
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- Page 146 and 147: 110 q=qG=0.4 Test #1 100 Test #2 Te
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- Page 188: DTU Mechanical Engineering Section
Ratcliffe J. <strong>and</strong> Cantwell W. J. (2001), Center Notched Flexure S<strong>and</strong>wich Geometry for<br />
Characterizing Skin–Core Adhesion in Thin-Skinned S<strong>and</strong>wich Structures, Journal <strong>of</strong><br />
Reinforced Plastics <strong>and</strong> Composites, 20(11): 945–70.<br />
Reeder J. <strong>and</strong> Crews J. H. (1990), Mixed-Mode Bending Method for Delamination Testing,<br />
AIAA Journal, 28(7):1270–6.<br />
Riccio A., Perugini P. <strong>and</strong> Scaramuzzino F. (2001), Embedded Delamination Growth in<br />
Composite Panels under Compressive Load, Composites Part B – Engineering, 32(3): 209-218.<br />
Sallam S. <strong>and</strong> Simitses G. J. (1985), Delamination Buckling <strong>and</strong> Growth <strong>of</strong> Flat, Cross/ply<br />
Laminates, Composite Structures, 4(4): 361-381.<br />
Sankar B. V. <strong>and</strong> Narayan M. (2001), Finite Element Analysis <strong>of</strong> Debonded S<strong>and</strong>wich Beams<br />
Under Axial Compression, Journal <strong>of</strong> s<strong>and</strong>wich structures <strong>and</strong> materials, 3: 197-219.<br />
Shen F., Lee K. <strong>and</strong> Tay T. (2001), Modeling Delamination Growth in Laminated Composites,<br />
Composite Science <strong>and</strong> Technology, 61: 1239–1251.<br />
Shenoi R. A., Clark S. D. <strong>and</strong> Allen H. G. (1995), <strong>Fatigue</strong> Behavior <strong>of</strong> Polymer Composite<br />
S<strong>and</strong>wich Beams, Journal <strong>of</strong> Composite Materials, 29: 2423–2445.<br />
Shi Z. <strong>and</strong> Zhang R. (2009), Numerical Simulation <strong>of</strong> Interfacial Crack Growth Under <strong>Fatigue</strong><br />
Load, <strong>Fatigue</strong> Fracture in Engineering Materials & Structures, 32: 26–32.<br />
Shipsha A. <strong>and</strong> Zenkert D. (2003), <strong>Fatigue</strong> Behaviour <strong>of</strong> Foam Core S<strong>and</strong>wich Beams with Sub-<br />
Interface Impact Damage, Journal <strong>of</strong> S<strong>and</strong>wich Structures <strong>and</strong> Materials, 5(1): 147-160.<br />
Shipsha A., Burman M. <strong>and</strong> Zenkert D. (1999), Interfacial <strong>Fatigue</strong> Crack Growth in Foam Core<br />
S<strong>and</strong>wich Structures, <strong>Fatigue</strong> <strong>and</strong> Fracture <strong>of</strong> Engineering Materials <strong>and</strong> Structures, 22: 123-<br />
131.<br />
Shipsha, A., Burman, M. <strong>and</strong> Zenkert, D. (2000), On Mode I <strong>Fatigue</strong> Crack Growth in Foam<br />
Core Materials for S<strong>and</strong>wich Structures, Journal <strong>of</strong> S<strong>and</strong>wich Structures & Materials, 2(2): 103-<br />
116.<br />
Sou Z. (1990), Singularities, Interfaces <strong>and</strong> Cracks in Dissimilar Anisotropic Media,<br />
Proceedings <strong>of</strong> the Royal Society <strong>of</strong> London, 427: 331-358.<br />
Southwell R. (1932), On the Analysis <strong>of</strong> Experimental Observations in Problems <strong>of</strong> Elastic<br />
Stability, Proceedings <strong>of</strong> the Royal Society <strong>of</strong> London, 601–616.<br />
Suo, Z. (1989), Singularities Interacting with Interface <strong>and</strong> Cracks. International Journal <strong>of</strong><br />
<strong>Solid</strong>s <strong>and</strong> Structures, 25: 1133-1142.<br />
142
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