Dynamic compressive response and failure behavior of an epoxy syntactic foam

Journal of Composite Materials

Volumn 38, Issue 11, 2004, Pages 915-936

  Song, Bo ^a   Chen, Weinong ^a   Frew, Danny J ^b  

^a University of Arizona   (United States)

^b SANDIA NATIONAL LABORATORIES   (United States)

Author keywords

Compressive response; Constitutive model.; Epoxy syntactic foam; Failure behavior; Split hopkinson pressure bar; Strain rate sensitivity

Indexed keywords

CERAMIC MATERIALS; COMPRESSIVE STRENGTH; NAVAL VESSELS; OLIGOMERS; PIEZOELECTRIC TRANSDUCERS; POLYESTERS; POLYURETHANES; SILICON;

COMPRESSIVE RESPONSE; CONSTITUTIVE MODEL; EPOXY SYNTACTIC FOAM; FAILURE BEHAVIOR; SPLIT HOPKINSON PRESSURE BAR; STRAIN-RATE SENSITIVITY;

POLYMERS;

EID: 2942631452     PISSN: 00219983     EISSN: None     Source Type: Journal    
DOI: 10.1177/0021998304040552     Document Type: Article

References (45)

1. epoxy syntactic foam, split Hopkinson pressure bar, compressive response, failure behavior, strain-rate sensitivity, constitutive model. 1. Gibson, L.J. and Ashby, M.F. (1997). Cellular Solids, Structure and Properties, 2nd edn, Cambridge University Press, Cambridge, UK.
2. Shutov, F.A. (1986). Syntactic Polymer Foams, Advances in Polymer Science, 73(74): 63-123.
3. Shutov, F.A. (1991). Syntactic Polymer Foams, In: Klempner, D. and Frisch, K.C. (eds.), Handbook of Polymeric Foams and Foam Technology, pp. 355-374, Hanser Publishers, New York.
4. Gupta, N., Kishore, Woldesenbet E. and Sankaran, S. (2001). Studies on Compressive Failure Features in Syntactic Foam Material, Journal of Materials Science, 36: 4485-4491.
5. Young, K.S. (April 1985). Value-Adding Syntactic Foams Gain in Composites Applications, Modern Plastics, 92-97.
6. Ansermet, J.PH. and Baeriswyl, E. (1994). Dielectric Study of Hollow Microsphere Composites, Journal of Materials Science, 29: 2841-2846.
7. Kim, H.S. and Oh, H.H. (2000). Manufacturing and Impact Behavior of Syntactic Foam, Journal of Applied Polymer Science, 76: 1324-1328.
8. Harruff, P.W. and Sandman, B.E. (1983). Carbon/Epoxy Composite Structures for Underwater Pressure Hull Applications, The 28th National SAMPE Symposium and Exhibition, pp. 40-49, Society for the Advancement of Material and Process Engineering, April 12-14. Anaheim, CA.
9. Hiel, C., Dittman, D. and Ishai, O. (1993). Composite Sandwich Construction with Syntactic Foam Core: A Practical Assessment of Post-Impact Damage and Residual Strength, Composites, 24: 447-450.
10. Ishai, O. and Hiel, C. (1992). Damage Tolerance of a Composite Sandwich with Interleaved Foam Core, Journal of Composites Technology & Research, 14: 155-168.
11. Smiley, L.H. (1986). Hollow Microspheres: More Than Just Fillers, Materials Engineering, 103: 27-30.
12. Jackson, D. and Clay, P. (September 1983). Syntactic Foam Sphere Improves Oceanographic Mooring Performance, Sea Technology, 24-29.
13. Rizzi, E., Papa, E. and Corigliano, A. (2000). Mechanical Behavior of A Syntactic Foam: Experiments and Modeling, International Journal of Solids and Structures, 37: 5773-5794.
14. Corigliano, A., Rizzi, E. and Papa, E. (2000). Experimental Characterization and Numerical Simulations of a Syntactic-Foam/Glass-Fibre Composite Sandwich, Composites Science and Technology, 60: 2169-2180.
15. Huang, J.S. and Gibson, L.J. (1993). Elastic Moduli of A Composite of Hollowspheres in A Matrix, Journal of the Mechanics and Physics of Solids, 41: 55-75.
16. Bunn, P. and Mottram, J.T. (1993). Manufacture and Compression Properties of Syntactic Foams, Composites, 24: 565-571.
17. Narkis, M., Puterman, M. and Kenig, S. (1980). Syntactic Foams II. Preparation and Characterization of Three-Phase Systems, Journal of Cellular Plastics, 16: 326-330.
18. Palumbo, M. and Tempesti, E. (1998). On the Nodular Morphology and Mechanical Behavior of A Syntactic Foam Cured in Thermal and Microwave Fields, Acta Polymer, 49: 482-486.
19. Gupta, N., Woldesenbet, E. and Kishore (2002). Compressive Fracture Features of Syntactic Foams - Microscopic Examination, Journal of Materials Science, 37: 3199-3209.
20. Cohen, A., Yalvaç, S. and Wetters, D.G. (1992). Impact Fatigue Behavior of A Syntactic Composite Material, The 37th International SAMPE Symposium and Exhibition, March 9-12, pp. 641-653, Society for the Advancement of Material and Process Engineering, Anaheim, CA.
21. Kolsky, H. (1949). An Investigation of the Mechanical Properties of Materials at Very High Rates of Loading, In: Proceedings of the Royal Society of London, B62: 676-700.
22. Chen, W., Song, B., Frew, D.J. and Forrestal, M.J. (2003). Dynamic Small Strain Measurements of a Metal Specimen with a Split Hopkinson Pressure Bar, Experimental Mechanics, 43: 20-23.
23. -1, International Journal of Solids and Structures, 38: 8989-8998.
24. Chen, W. and Ravichandran, G. (1996). Static and Dynamic Compressive Behavior of Aluminum Nitride under Moderate Confinement, Journal of the American Ceramic Society, 79: 579-584.
25. Song, B., Chen, W. and Weerasooriya, T. (2003). Quasi-Static and Dynamic Compressive Behaviors of a S-2 Glass/SC15 Composite, Journal of Composite Materials, 37: 1723-1743.
26. Song, B. and Chen, W. (2003) Dynamic Compressive Constitutive Behavior of EPDM Rubber, Transactions of the ASME, Journal of Engineering Materials and Technology, 125: 294-301.
27. Chen, W., Lu, F. and Winfree, N. (2002). High-Strain-Rate Compressive Behavior of a Rigid Polyurethane Foam with Various Densities, Experimental Mechanics, 42: 65-73.
28. Gray, G.T. (2000). Classic Split-Hopkinson Pressure Bar Testing, Mechanical Testing and Evaluation, Metals Handbook, 8: 462-476, American Society for Metals, Materials Park, OH.
29. Song, B., Chen, W., Dou, S. and Winfree, N.A. Effects of Strain Rate on Elastic and Early Cell-Collapse Responses of a Polystyrene Foam, International Journal of Impact Engineering (revised).
30. Frew, D.J., Forrestal, M.J. and Chen, W. (2002). Pulse Shaping Techniques for Testing Brittle Materials with a Split Hopkinson Pressure Bar, Experimental Mechanics, 42: 93-106.
31. Song, B. and Chen, W. Dynamic Stress Equilibrium on a Rubber Specimen during a Split Hopkinson Pressure Bar Experiment, Experimental Mechanics (to appear).
32. Jones, F.R. (1990). Micromechanics and Properties of Fibre Composites, In: Middleton, D.H. (ed.), Composite Materials in Aircraft Structures, pp. 69-92, Longman Scientific & Technical Publishers, New York.
33. Chen, W., Lu, F. and Zhou, B. (2000). A Quartz Crystal Embedded Split Hopkinson Bar for Soft Materials, Experimental Mechanics, 40: 1-6.
34. Chen, W., Lu, F., Frew, F.J. and Forrestal, M.J. (2001). Dynamic Compression Testing of Soft Materials, Transactions of the ASME, Journal of Applied Mechanics, 69: 214-223.
35. Dighe, M.D., Gokhale, A.M., Horstemeyer, M.F. and Mosher, D.A. (2000). Effect of Strain Rate on Damage Evolution in a Cast Al-Si-Mg Base Alloy, Metallurgical and Materials Transactions A, 31A: 1725-1731.
36. Hodowany, J., Ravichandran, G., Rosakis, A. J. and Rosakis, P. (2000). Partition of Plastic Work into Heat and Stored Energy in Metals, Experimental Mechanics, 40: 113-123.
37. Randles, P.W. and Nemes, J.A. (1992). A Continuum Damage Model for Thick Composite Materials Subjected to High-Rate Dynamic Loading, Mechanics of Materials, 13: 1-13.
38. Park, S.W. and Schapery (1997). A Viscoelastic Constitutive Model for Particulate Composites with Growing Damage, International Journal of Solids and Structures, 34: 931-947.
39. Knauss, W.G. (1973). The Mechanics of Polymer Fracture, Applied Mechanics Reviews, 26: 1-17.
40. Kander, R.G. and Siegmann, A. (1992). The Effect of Strain Rate on Damage Mechanisms in a Glass/Polypropylene Composite, Journal of Composite Materials, 26: 1455-1473.
41. Gazonas, G.A. (1993). A Uniaxial Nonlinear Viscoelastic Constitutive Model with Damage for M30 Gun Propellant, Mechanics of Materials, 15: 323-335.
42. Bonora, N. and Milella, P.P. (2001). Constitutive Modeling for Ductile Metals Behavior Incorporating Strain Rates, Temperature and Damage Mechanics, International Journal of Impact Engineering, 26: 53-64.
43. Wang, L. and Yang, L. (1992). Nonlinear Viscoelastic Constitutive Relationship for Solid Polymers, In: Wang, L., Yu, T. and Li, Y. (eds), Advances in Impact Dynamics, pp. 88-116, The University of Science and Technology of China Publications, Hefei, China.
44. p Metal-Matrix Composite, Acta Materialia, 48: 1563-1573.
45. Cervera, M., Oliver, J. and Manzoli, O. (1996). A Rate-Dependent Isotropic Damage Model for the Seismic Analysis of Concrete Dams, Earthquake Engineering and Structural Dynamics, 25: 987-1010.