Residual Strength and Fatigue Lifetime of ... - Solid Mechanics

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Bezazi A., Mahi A. E., Berthelot J. M. and Bezzazi B. (2009), Experimental Analysis of Behavior and Damage of Sandwich Composite Materials in Three-Point Bending Part 2: Fatigue Test Results and Damage Mechanisms, Strength of Materials, 41(3): 257-267. Billardon R. (1989), Etude de la rupture par la mecanique de I’endommagement, These de Doctorat es Sciences, Universite Paris 6. Blasques, J. P., Stolpe, M. (2011), Multi-Material Topology Optimization of Laminated Composite Beam Cross Sections, International Journal for Numerical Methods in Engineering, (submitted). Boisse P., Bussy P. and Ladeveze P. (1990), A New Approach in Nonlinear Mechanics – the Large Time Increment Method, International Journal of Numerical Methods in Engineering, 29: 647–663. Bozhevolnaya E., Jakobsen J. and Thomsen O. T. (2009), Fatigue Performance of Sandwich Beams With Peel Stoppers, Strain, 45: 349–357. Burman M. and Zenkert D. (1997), Fatigue of Foam Core Sandwich Beams, Part I: Undamaged Specimens, International Journal of Fatigue, 19: 551–561. Burman M. and Zenkert D. (1997), Fatigue of Foam Core Sandwich Beams, Part II: Effect of Initial Damages, International Journal of Fatigue, 19: 563–578. Burman M. and Zenkert D. (2000), Fatigue of Undamaged and Damaged Honeycomb Sandwich Beams, Journal of Sandwich Structures and Materials, 2: 50-74. Burman, M. (1998), Fatigue Crack Initiation and Propagation in Sandwich Structures, Doctoral Thesis, Department of Aeronautics, Royal Institute of Technology. Cantwell W. J. and Davies P. (1994), A Test Technique for Assessing Core-Skin Adhesion in Composite Sandwich Structures, Journal of Material Science Letters, 13: 203–205. Cantwell W. J. and Davies P. (1996), A Study of Skin-Core Adhesion in Composite Sandwich Materials, Advanced Composite Materials, 3: 407-420. Cantwell W. J., Scudamore R., Ratcliffe J. and Davies P. (1999), Interfacial Fracture in Sandwich Laminates, Composites Science and Technology, 59: 2079–2085. Carlsson L. A, Sendlein L. S, and Merry S. L. (1991), Characterization of Face/Core Shear Fracture of Composite Sandwich Beams, Journal of Composite Materials, 25(1):101–16. Chen H. and Bai, R. (2002), Postbuckling Behavior of Face/Core Debonded Composite Sandwich Plate Considering Matrix Crack and Contact Effect, Composite structures, 57: 305- 313. 138

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Page 1: Residual Strength and Fatigue Lifet

Page 4 and 5: Published in Denmark by Technical U

Page 6 and 7: This page is intentionally left bla

Page 8 and 9: method to accelerate the simulation

Page 10 and 11: Synopsis Sandwich kompositter er i


Page 14 and 15: Contents Preface Executive Summary

Page 16 and 17: 5 Face/core Interface Fatigue Crack


Page 20 and 21: H11 bimaterial constant H22 bimater


Page 24 and 25: These peculiar damage modes often r

Page 26 and 27: 1.2 Overview of the Thesis In this

Page 28 and 29: Figure 1.3: Fracture modes, from Be

Page 30 and 31: In Equations (1.5) and (1.6) H11, H

Page 32 and 33: Figure 1.6: Schematic illustration

Page 34 and 35: The compact tension specimen (CT) i

Page 36 and 37: A Figure 1.10: CSB, DCB, TSD, DCB-U

Page 38 and 39: Chapter 2 Buckling Driven Face/Core

Page 40 and 41: (DIC) measurement system (ARAMIS 2M

Page 42 and 43: corresponds to the onset of debond

Page 44 and 45: Figure 2.7: Crack kinking into the

Page 46 and 47: (2.2) where and for plane str

Page 48 and 49: A modified version of the tilted sa

Page 50 and 51: previous observations of crack path

Page 52 and 53: of contact elements (CONTACT173 and

Page 54 and 55: the debond opening initially increa

Page 56 and 57: Table 2.4: Instability loads determ

Page 58 and 59: G (J/m2) 600 400 200 0 H100 IMP=0.1


Page 62 and 63: Hayman (2007) has described a damag

Page 64 and 65: Table 3.1: Panel test specimens. La

Page 66 and 67: sheet and the core thickness, respe

Page 68 and 69: Load (N) 250 200 150 100 50 0 H130

Page 70 and 71: Table 3.4: Parameters in the face/c

Page 72 and 73: was used to monitor 3D surface disp

Page 74 and 75: arising due to the junction between

Page 76 and 77: (a) Debonded face sheet Figure 3.16

Page 78 and 79: Figure 3.19 shows the determined en

Page 80 and 81: H130 MMB H130 Panel H250 MMB Interf

Page 82 and 83: 3.6 Conclusion In this chapter the


Page 86 and 87: composite laminates under thermal c

Page 88 and 89: S S y( t ) y( t ) ( t ) 2 1 12 2

Page 90 and 91: listed in Table 4.1. The length and

Page 92 and 93: The strain energy release rate, G,

Page 94 and 95: high growth rate of G (see Figure 4

Page 96 and 97: 4.4 Face/Core Fatigue Crack Growth

Page 98 and 99: Debond 310 mm Symmetry B. C. a Figu

Page 100 and 101: B 2 1/ 2 ( S44 S55 S45) (4.17) wh

Page 102 and 103: 75), which illustrates possible ina

Page 104 and 105: Figure 4.18 (a) presents the deflec

Page 106 and 107: Debond radius (mm) 100 90 80 70 60

Page 108 and 109: using the cycle jump method, more t

Page 110 and 111: Chapter 5 Face/Core Interface Fatig

Page 112 and 113: of this chapter, sandwich panels wi

Page 114 and 115: H250 Specimen H100 Specimen H45 Spe

Page 116 and 117: Figure 5.5: Test setup. Initially,

Page 118 and 119: H100 Specimen Fibre bridging Figure

Page 120 and 121: propagation, the crack continues to

Page 122 and 123: Figure 5.14: Kinking of the crack i

Page 124 and 125: Crack length [mm] Crack length [mm]

Page 126 and 127: mode-mixity phase angle was chosen

Page 128 and 129: should be taken into account for a

Page 130 and 131: Figure 5.25: Kinking of the crack i

Page 132 and 133: log (da/dN) (mm/cycle) 10 log G (J/

Page 134 and 135: erroneous extrapolations in the tra

Page 136 and 137: compared to the 65% efficiency obta

Page 138 and 139: the case of uneven debond growth, t

Page 140 and 141: Load (kN) 2 1.5 1 0.5 0 Panel 1 Pan

Page 142 and 143: Figure 5.42: Zero and ninety degree

Page 144 and 145: G(J/m 2 ) 180 150 210 120 150 100 5

Page 146 and 147: 110 q=qG=0.4 Test #1 100 Test #2 Te

Page 148 and 149: panels were determined for differen

Page 150 and 151: Chapter 6 Conclusion and Future Wor

Page 152 and 153: toughness using MMB fracture toughn

Page 154 and 155: For the specimens with H250 core th

Page 156 and 157: Development of testing methods for


Page 162 and 163: Kanny K. and Mahfuz H. (2005), Flex

Page 164 and 165: Ratcliffe J. and Cantwell W. J. (20


Page 168 and 169: Out-of-plane displacement (mm) 1 0.

Page 170 and 171: Out-of-plane displacement (mm) 3 2

Page 172 and 173: A.5 Out-of-plane deflection of Debo

Page 174 and 175: (a) Figure A.14: Out-of-plane defle

Page 176 and 177: (a) (b) Figure A.18: Out-of-plane d

Page 178 and 179: Load (kN) 250 200 150 100 50 250 30

Page 180 and 181: Displacement (mm) 4 3 2 1 0 8 9 (a)

Page 182 and 183: (a) (b) Figure B.11: Out-of-plane d

Page 184 and 185: (a) (b) Figure B.15: Out-of-plane d

Page 188: DTU Mechanical Engineering Section

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