Titanium matrix composite lattice structures

Composites Part A: Applied Science and Manufacturing

Volumn 39, Issue 2, 2008, Pages 176-187

  Moongkhamklang, Pimsiree ^a   Elzey, Dana M ^a   Wadley, Haydn N G ^a  

^a University of Virginia   (United States)

Author keywords

A. Metal matrix composites (MMCs); B. Mechanical properties; Cellular materials

Indexed keywords

BUCKLING; COMPOSITE MATERIALS; COMPRESSIVE STRENGTH; HIGH TEMPERATURE EFFECTS; SILICON CARBIDE; TITANIUM COMPOUNDS;

CELLULAR MATERIALS; ELASTIC BUCKLING; METAL-MATRIX COMPOSITES (MMC); MONOFILAMENT FRACTION;

CRYSTAL LATTICES;

EID: 38749089013     PISSN: 1359835X     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.compositesa.2007.11.007     Document Type: Article

References (62)

1. Gibson L.J., and Ashby M.F. Cellular solids: structure and properties. 2nd ed. (1997), Cambridge University Press, Cambridge
2. Bitzer T. Honeycomb technology: materials, design, manufacturing, applications and testing (1997), Chapman & Hall
3. Foo C.C., Chai G.B., and Seah L.K. Mechanical properties of Nomex material and Nomex honeycomb structure. Compos Struct 80 (2007) 588-594
4. Kintscher M., Kärger L., Wetzel A., and Hartung D. Stiffness and failure behaviour of folded sandwich cores under combined transverse shear and compression. Compos Part A - Appl S 38 (2007) 1288-1295
5. Jung W.Y., and Aref A.J. A combined honeycomb and solid viscoelastic material for structural damping applications. Mech Mater 35 (2003) 831-844
6. Paik J.K., Thayamballi A.K., and Kim G.S. The strength characteristics of aluminum honeycomb sandwich panels. Thin Wall Struct 35 (1999) 205-231
7. Doyoyo M., and Mohr D. Microstructural response of aluminum honeycomb to combined out-of-plane loading. Mech Mater 35 (2003) 865-876
8. Wenbo H., Kaifeng Z., and Guofeng W. Superplastic forming and diffusion bonding for honeycomb structure of Ti-6Al-4V alloy. J Mater Process Tech 183 (2007) 450-454
9. Williams J.M., and Kelly R.G. An analysis of corrosive species ingress into IM7/PETI-5 Ti honeycomb composites. Compos Sci Technol 64 (2004) 1875-1883
10. Wadley H.N.G. Multifunctional periodic cellular metals. Philos T R Soc A 364 (2006) 31-68
11. Ashby M.F., Evan A.G., Fleck N.A., Gibson L.J., Hutchison J.W., and Wadley H.N.G. Metal foams: a design guide (2000), Butterworth Heinemann, Boston
12. Evan A.G., Hutchinson J.W., Fleck N.A., Ashby M.F., and Wadley H.N.G. The topological design of multifunctional cellular metals. Prog Mater Sci 46 (2001) 309-327
13. Lu T.J., Stone H.A., and Ashby M.F. Heat transfer in open-cell metal foams. Acta Mater 46 (1998) 3619-3635
14. Boomsma K., Poulikakos D., and Zwick F. Metal foams as compact high performance heat exchangers. Mech Mater 35 (2003) 1161-1176
15. Deshpande V.S., and Fleck N.A. High strain rate compressive behavior of aluminium alloy foams. Int J Impact Eng 24 (2000) 277-298
16. Hall I.W., Guden M., and Yu C.J. Crushing of aluminum closed cell foams: density and strain rate effects. Scripta Mater 43 (2000) 515-521
17. Paul A., and Ramamurty U. Strain rate sensitivity of a closed-cell aluminum foam. Mater Sci Eng A 281 (2000) 1-7
18. Jiejun W., Chenggong L., Dianbin W., and Manchang G. Damping and sound absorption properties of particle reinforced Al matrix composite foams. Compos Sci Technol 63 (2003) 569-574
19. Deshpande V.S., and Fleck N.A. Collapse of truss core sandwich beams in 3-point bending. Int J Solid Struct 38 (2001) 6275-6305
20. Chiras S., Mumm D.R., Evans A.G., Wicks N., Hutchinson J.W., Dharmasena K., et al. The structural performance of near-optimized truss core panels. Int J Solid Struct 39 (2002) 4093-4115
21. Wadley H.N.G., Fleck N.A., and Evans A.G. Fabrication and structural performance of periodic cellular metal sandwich structures. Compos Sci Technol 63 (2003) 2331-2343
22. Kooistra G.W., Deshpande V.S., and Wadley H.N.G. Compressive behavior of age hardenable tetrahedral lattice truss structures made from aluminium. Acta Mater 52 (2004) 4229-4237
23. Lim J.H., and Kang K.J. Mechanical behavior of sandwich panels with tetrahedral and Kagomé truss cores fabricated from wires. Int J Solid Struct 43 (2006) 5228-5246
24. Queheillalt D.T., and Wadley H.N.G. Pyramidal lattice truss structures with hollow trusses. Mater Sci Eng A 397 (2005) 132-137
25. Kooistra G.W., and Wadley H.N.G. Lattice truss structures from expanded metal sheet. Mater Design 28 (2007) 507-514
26. Queheillalt DT, Wadley HNG. Titanium alloy pyramidal lattice truss structures. Mater design, submitted for publication.
27. Wang J., Evans A.G., Dharmasena K., and Wadley H.N.G. On the performance of truss panels with Kagomé cores. Int J Solid Struct 40 (2003) 6981-6988
28. Sypeck D.J., and Wadley H.N.G. Multifunctional microtruss laminates: textile synthesis and properties. J Mater Res 16 (2001) 890-897
29. Tian J., Kim T., Lu T.J., Hodson H.P., Queheillalt D.T., and Wadley H.N.G. The effects of topology upon fluid-flow and heat-transfer within cellular copper structures. Int J Heat Mass Tran 47 (2004) 3171-3186
30. Queheillalt D.T., and Wadley H.N.G. Cellular metal lattices with hollow trusses. Acta Mater 53 (2005) 303-313
31. Rathbun H.J., Zok F.W., Waltner S.A., Mercer C., Evans A.G., Queheillalt D.T., et al. Structural performance of metallic sandwich beams with hollow truss cores. Acta Mater 54 (2006) 5509-5518
32. Wicks N., and Hutchinson J.W. Optimal truss plates. Int J Solids Struct 38 (2001) 5165-5183
33. Wallach J.C., and Gibson L.J. Mechanical behavior of a three-dimensional truss material. Int J Solids Struct 38 (2001) 7181-7196
34. Zok F.K., Rathbun H.J., Wei Z., and Evans A.G. Design of metallic textile core sandwich panels. Int J Solids Struct 40 (2003) 5707-5722
35. Ashby M.F. Properties of foams and lattices. Philos T R Soc A 364 (2006) 15-30
36. McCormick T.M., Miller R., Kesler O., and Gibson L.J. Failure of sandwich beams with metallic foam cores. Int J Solids Struct 38 (2001) 4901-4920
37. Bart-Smith H., Hutchinson J.W., and Evans A.G. Measurement and analysis of the structural performance of cellular metal sandwich construction. Int J Mech Sci 43 (2001) 1945-1963
38. Côté F., Fleck N.A., and Deshpande V.S. Fatigue performance of sandwich beams with a pyramidal core. Int J Fatigue 29 (2007) 1402-1412
39. Boyer R, Welsch G, Collings EW. Material properties handbook: titanium alloys, Materials Park: ASM International, 1994.
40. Guo Z.X., and Derby B. Solid-state fabrication and interfaces of fibre reinforced metal matrix composites. Prog Mater Sci 39 (1995) 411-495
41. Ward-Close CM, Loader C. In: Froes FH, Storer J, editors. Recent advances in titanium metal matrix composites, Warrendale: TMS, 1995. p. 19.
42. McCullough C, Storer J, Berzins LV. In: Froes FH, Storer J, editors. Recent advances in titanium metal matrix composites, Warrendale: TMS, 1995. p. 259.
43. Yang J.-M. Creep behavior. In: Mall S., and Nicholas T. (Eds). Titanium matrix composites: mechanical behavior (1998), Lancester, Technomic Publishing Company 273-312
44. SCS silicon carbide fibers technical data sheet, Specialty Materials, Lowell, MA.
45. DeBolt H.E., Krukonis V.J., and Wawner F.E. High strength, high modulus SiC filament via CVD. In: Marshall R.C., Faust J.W., and Ryan C.E. (Eds). Silicon carbide (1973), University of South Carolina Press 68
46. Queheillalt D.T., Deshpande V.S., and Wadley H.N.G. Truss waviness effects in cellular lattice structures. J Mech Mater Struct 2 (2007) 1657-1675
47. Gere J.M., and Timoshenko S.P. Mechanics of materials (1984), PWS Engineering, Boston
48. Shanley F.R. Mechanics of materials (1967), McGraw-Hill, New York
49. Zupan M., Deshpande V.S., and Fleck N.A. The out-of-plane compressive behavior of woven-core sandwich plates. Eur J Mech A-Solid 23 (2004) 411-421
50. Rosen B.W. Mechanics of composite strengthening. Fiber composite materials (1965), American Society of Metals 37-75
51. Fleck N.A. Compressive failure of fiber composites. Adv Appl Mech 33 (1997) 43-117
52. Hutchinson RG. Mechanics of lattice materials. PhD thesis. Cambridge University. Department of Engineering, 2004.
53. Hopper RW, Pekala RW. Low density microcellular carbon or catalytically impregnated carbon forms and process for their preparation. US Patent 4,806,290; 1989.
54. Ultrafoam technical data sheet: Ultramet, Pacoima, CA.
55. Duocel RVC foam technical data sheet, ERG Materials and Aerospace Corporation. Oakland, CA.
56. Hardcastle LA, Sheppard RG, Dingus DF. Process for making carbon foam induced by process depressurization. US Patent 6,576,168; 2003.
57. Maricle DL, Nagle DC. Carbon foam fuel cell components. US Patent 4,125,676; 1978.
58. Han Y., Li J., Wei Q., and Tang K. The effect of sintering temperatures on alumina foam strength. Ceram Int 28 (2002) 755-759
59. Han Y., Li J., and Chen Y. Fabrication of bimodal porous alumina ceramics. Meter Res Bull 38 (2003) 373-379
60. ® SiC foams technical data sheet, ERG Materials and Aerospace Corporation, Oakland, CA.
61. Jun I., Koh Y., and Kim H. Fabrication of ultrahigh porosity ceramics with biaxial pore channels. Mater Lett 60 (2006) 878-882
62. Jun I., Koh Y., Song J., Lee S., and Kim H. Improved compressive strength of reticulated porous zirconia using carbon coated polymeric sponge as novel template. Mater Lett 60 (2006) 2507-2510