Literaturverweise

  1. Garnich, M.R. (1996) "A Multicontinuum Theory for Structural Analysis of Composite Materials", Thesis (PhD), University of Wyoming, Laramie, WY
  2. Garnich, M.R., and Hansen, A.C. (1997) "A Multicontinuum Approach to Structural Analysis of Linear Viscoelastic Composite Materials," J. Applied Mechanics ., 64(4):795-803.
  3. Garnich, M.R., and Hansen, A.C. (1997) "A Multicontinuum Theory for Thermal-Elastic Finite Element Analysis of Composite Materials", Journal of Composite Materials, 31(1):71-86.
  4. Garnich, M.R., and Hansen, A.C. (1997) "A Multicontinuum Approach to Structural Analysis of Linear Viscoelastic Composite Materials", J. Applied Mech., 64(4):795-803.
  5. Mayes, J.S. (1999) Multicontinuum Failure Analysis of Composite Structural Laminates, Ph.D. Thesis, University of Wyoming, Laramie, WY
  6. Mayes, J.S., and Hansen, A.C. (2001) "Multicontinuum Failure Analysis of Composite Structural Laminates", Mechanics of Composites Materials and Structures, 8(4):249-262.
  7. Key, C.T., Six, R.W., and Hansen, A.C. (2003) "A Three-Constituent Multicontinuum Theory for Woven Fabric Composite Materials", Composites Science and Technology, 63(13):1857-1864.
  8. Nelson, E.E. (2003) "Multiscale and Shear Damage Modeling of a Satin Weave Composite", Thesis (MS), University of Wyoming, Laramie, WY
  9. Key, C.T., Garnich, M.R., and Hansen, A.C. (2004) "Progressive Failure Predictions for Rib-Stiffened Panels Based on Multicontinuum Technology", Composite Structures, 65(3-4):357-366.
  10. Mayes, J.S. and Hansen A.C. (2004) "Composite laminate failure analysis using multicontinuum theory", Part A of the Worldwide Failure Exercise sponsored by DERA, Great Britain, Composites Science and Technology, 64(3-4).
  11. Mayes, J.S. and Hansen, A.C. (2004) "A Comparison of Multicontinuum Theory Based Failure Simulation with Experimental Results", Part B of the Worldwide Failure Exercise sponsored by DERA, Great Britain, Composites Science and Technology, 64:517-527.
  12. Knops, M., and Bögle, C. (2006) "Gradual Failure in Fibre/Polymer Laminates", Composite Science and Technology, 66:616-625.
  13. Kenik, D.J., "Advanced Techniques for Constituent-Based Progressive Failure Analysis of Composite Structures", Master of Science Thesis, University of Wyoming, June 2009.
  14. Tsai, S. W. and Wu, E. M. (1971), "A general theory of strength for anisotropic materials", Journal of Composite Materials, 5:58-80.
  15. Tsai, S.W., (1968) "Strength Theories of Filamentary Structures", Fundamental Aspects of Fiber Reinforced Plastic Composites, Eds. R.T. Schwartz and H.T. Schwartz, Wiley Interscience, New York, pp. 3-11.
  16. Hashin, Z., (1980) "Failure Criteria for Unidirectional Fiber Composites", J. of Applied Mechanics, 47:329 - 334.
  17. Christensen, R. M., (1998) "The Numbers of Elastic Properties and Failure Parameters for Fiber Composites", J. Eng. Mater. Tech., Trans. ASME, 120:110-113.
  18. Puck, A., and Schurmann, H., (1998) "Failure Analysis of FRP Laminates by Means of Physically Based Phenomenological Models", Composites Science and Technology, 58:1045-1067.
  19. Puck, A., and Schurmann, H., (2002) "Failure Analysis of FRP Laminates by Means of Physically Based Phenomenological Models", Composites Science and Technology, 62:1633-1662.
  20. Puck, A., and Mannigel,M., (2007) "Physically-Based Non-linear stress-strain relations for the inter-fiber fracture analysis of FRP laminates", Composites Science and Technology, 67(9):1955-1964.
  21. T. Murphey, G. Sanford, and M. Grigoriev, "Nonlinear Elastic Constitutive Modeling of Large Strains in Carbon Fiber Composite Flexures", 16th International Conference on Composite Structures, ICCS, 2011.
  22. Hashin, Z., and Rotem, A., (1973) "A Fatigue Failure Criterion for Fiber Reinforced Materials," Journal of Composite Materials,7:448
  23. Awerbuch, J., and Hahn, H., (1981) "Off-Axis Fatigue Graphite/Epoxy Composite," San Francisco: ASTM,243-247.
  24. Peterman, J., and Plumtree, A., (2001) "A Unified Fatigue Failure Criterion for Unidirectional Laminates," Composites: Part A.,32:107-118.
  25. Talreja, R., (1981) "Fatigue of Composite Materials: Damage Mechanisms and Fatigue Life Diagrams," Proceedings of the Royal Society of London A,378:461-475.
  26. Fuji, T., and Lin, F., (1995) "Fatigue Behavior of a Plain-Woven Glass Fabric Laminate under Tension/Torsion Biaxial Loading," Journal of Composite Materials,573-590.
  27. Fuki, T., Amijima, S., and Okubu, K., (1993) "Microscopic Fatigue Processes in a Plain-Weave Glass-Fiber Composite," Composites Science and Technology,327-333.
  28. Naik, R., Patel, S., and Case, S., (2001) "Fatigue Damage Mechanism Characterization and Modeling of a Woven Graphite/Epoxy Composite," Journal of Thermoplastic Composite Materials,404-420.
  29. Regal, V., and Tamuzh, V., (1977) "Fracture and Fatigue of Polymers and Composites (Survey)," Mechanics of Composite Materials,13:392-408.
  30. Regal, V., Leksovskii, A., Slutsker, A., and Tamuzh, V., (1977) "Polymer Breakdown and Fatigue," Mechanics of Composite Materials,8:516-527.
  31. Sauer, J., and Richardson, G., (1980) "Fatigue of Polymers," International Journal of Fracture,16:499-532.
  32. Coleman, B., (1956) "Time Dependence of Mechanical Breakdown Phenomena," Journal of Applied Physics,27:862-866.
  33. Zhurkov, S., (1965) "Kinetic Concept of the Strength of Solids," International Journal of Fracture,1:311-323.
  34. Tomashevskii, E., Zakrevskii, V., Novak, I., Korsukov, V., Tegel, V., Pozdnyakov, O., Slutsker, A., and Kuksenko, V., (1975) "Kinetic Micromechanics of Polymer Fracture," International Journal of Fracture,11:803-815.
  35. Fertig, R., (2009) "Bridging the Gap Between Physics and Large-Scale Structural Analysis: A Novel Method for Fatigue Life Prediction of Composites", in SAMPE.
  36. Kireenko, O., Leksovskii, A., and Regel, V., (1971) "Polymer Fractography and Fracture Kinetics 3. Fractographic Method of Estimating the Local Heating at the Ends of Cracks in Cyclically Loaded Polymers," Mechanics of Composite Materials,7:776-780.
  37. Tobolsky, A., and Eyring, H., (1943) "Mechanical Properties of Polymeric Materials," The Journal of Chemical Physics,11:125-134.
  38. Ward, I., (1983) Mechanical Properties of Solid Polymers, New York: John Wiley & Sons.
  39. Hansen, A, and Baker-Jarvis, A., (1990) "A Rate Dependent Kinetic Theory of Fracture for Polymers," International Journal of Fracture,44:221-231.
  40. Zhurkov, S., and Kuksenko, V., (1975) "The Micromechanics of Polymer Fracture," International Journal of Fracture,11:629-239.
  41. Coleman, B., (1957) "Time Dependence of Mechanical Breakdown in Bundles of Fibers. I. Constant Total Load," Journal of Applied Physics,28:1058-1064.
  42. Coleman, B., and Marquardt, D., (1957) "Time Dependence of Mechanical Breakdown in Bundles of Fibers. II. The Infinite Ideal Bundle Under Linearly Increasing Loads," Journal of Applied Physics,28:1065-1067.
  43. Regel, V., Pozdnyakov, O., and Amelin, A., (1975) "Investigation of the Process of Thermal and Mechanical degradation of Polymers Using Mass Spectrometers. Review," Mechanics of Composite Materials,11:13-26.
  44. Regel, V., (1971) "Kinetic Theory of Strength as a Scientific Basis for Predicting the Lifetime of Polymers Under Load," Mechanics of Composite Materials,7:82-93.
  45. Kireenko, O., Leksovskii, A., and Regel, V., (1971) "Polymer Fractography and Fracture Kinetics 2. The Relationship Between Fracture Surface Relief and the Dependence of Strength on Time and Temperature," Mechanics of Composite Materials,7:193-198.
  46. Pandita, S., Huysmans, G., Wevers, M., and Verpoest, I., (2001) "Tensile Fatigue Behavior of Glass Plain-Weave Fabric Composites in On- and Off-Axis Directions," Composites: Part A,32:1533-1539.
  47. Kawai, M., and Taniguchi, T., (2006) "Off-Axis Fatigue Behavior of Plain Weave Carbon/Epoxy Fabric Laminates at Room and High Temperatures and its Mechanical Loading," Composites:Part A,37:243-256.
  48. Greaves, P., and Dominy, R., (2012) "Analysis of Large Wind Turbine Blade Laminates using Multi-Continuum Theory", Durham University, Durham, UK.
  49. Wicaksono, S., and Boay, C., (2012) "Report on Static, Fatigue and Burn Tests", DSO.
  50. Kozin, F., and Bogdanoff, J., (1990) "Cumulative Damage Model for Mean Fatigue Crack Growth Based on The Kinetic Theory of Thermally Activated Failure," Engineering Fracture Mechanics,37:995-1010.
  51. Kawai, M., Yajima, A., Hachinohe, A., and Takano, Y., (2001) "Off-Axis Fatigue Behavior of Unidirectional Carbon Fiber-Reinforced Composites at Room and High Temperatures," Journal of Composite Materials,35:545-576.
  52. Awerbuch, J., and Hahn, H., (1977) "Fatigue and Proof-Testing of Unidirectional Graphite/Epoxy Composite," American Society for Testing and Materials,248-266.
  53. Kawai, M., and Suda, H., (2004) "Effects of Non-Negative Mean Stress on the Off-Axis Fatigue Behavior of Unidirectional Carbon/Epoxy Composites at Room Temperature," Journal of Composite Materials,38:833-854.
  54. Sauer, J., Foden, E., Morrow, D., (1977) "Influence of Molecular Weight on Fatigue Behavior of Polyethylene and Polystyrene," Polymer Engineering and Science,17:246-250.
  55. Davila, C., Jaunky, N., and Goswami, S., "Failure Criteria for FRP Laminates in Plane Stress", 44Th AIAA/AME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference, Norfolk, Virginia, April 7-10, 2003.