A novel process for cost effective manufacturing of fiber metal laminate with textile reinforced pCBT composites and aluminum alloy

Composite Structures

Volumn 108, Issue 1, 2014, Pages 172-180

  Wu, Wangqing ^a,b   Abliz, Dilmurat ^a   Jiang, Bingyan ^b   Ziegmann, Gerhard ^a   Meiners, Dieter ^a  

^a CLAUSTHAL UNIVERSITY OF TECHNOLOGY   (Germany)

^b CENTRAL SOUTH UNIVERSITY   (China)

Author keywords

A. Fiber metal laminate; B. Hybrid laminate; C. Aluminum; D. Interlaminar Shear Strength; E. Charpy Impact Strength

Indexed keywords

COST EFFECTIVENESS; MANUFACTURE; MOLDING; PREFORMING; PRESSURE VESSELS; REINFORCEMENT; RESINS; SURFACE TREATMENT; TEXTILES;

CYCLIC BUTYLENE TEREPHTHALATES; FIBER METAL LAMINATES; HYBRID LAMINATES; INTER-LAMINAR SHEAR STRENGTHS; INTERLAMINAR SHEAR STRENGTH; MECHANICAL CHARACTERIZATIONS; MECHANICAL PERFORMANCE; RESIN INFUSION PROCESS;

LAMINATES;

EID: 84896904134     PISSN: 02638223     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.compstruct.2013.09.016     Document Type: Article

References (40)

1. Pitzer C, Yang JM. Hybrid Metal Laminate (HML) Manufacturing Planning Evaluation and Assessment. 2008. http://pitzerconsulting.com.
2. Zhu S., Chai G.B. Low-velocity impact response of fibre-metal laminates - experimental and finite element analysis. Compos Sci Technol 2012, 72:1793-1802.
3. Beumler T., Pellenkoft F., Tillich A., Wohlers W., Smart C. Airbus contumer benefit from fiber metal laminates 2006, Airbus Deutschland GmbH, [May, Ref. no.: L53pr0605135-Issue 1].
4. Dinca I., Stefan A., Stan A. Aluminum/glass fibre and aluminum/carbon fibre hybrid laminates. INCAS Bull 2010, 2:33-39.
5. Reyes Villanueva G., Cantwell W.J. The high velocity impact response of composite and FML-reinforced sandwich structures. Compos Sci Technol 2004, 64:35-54.
6. Lopes C.S., Remmers J.J.C., Gürdal Z. Influence of porosity on the interlaminar shear strength of fibre-metal laminates. Key Eng Mater 2008, 282:35-52.
7. Morinière F.D., Alderliesten R.C., Sadighi M., Benedictus R. An integrated study on the low-velocity impact response of the GLARE fibre-metal laminate. Compos Struct 2013, 100:89-103.
8. Bernhardt S., Ramulu M., Kobayashi A. Low-velocity impact response characterization of a hybrid titanium composite laminate. J Eng Mater Technol 2007, 129:220-226.
9. Sinke J. Manufacturing of GLARE parts and structures. Appl Compos Mater 2003, 10:290-305.
10. Wu G., Yang J.M. The mechanical behavior of GLARE laminates for aircraft structures. JOM 2005, 57:72-129.
11. Bourlegat L.L., Damato C.A., Silva D., Botelho E.C., Pardini L.C. Processing and mechanical characterization of titanium-graphite hybrid laminates. J Reinforced Plast Compos 2010, 29:3392-3400.
12. Botelho E.C., Silva R.A., Pardini L.C., Rezende M.C. A review on the development and properties of continuous fiber/epoxy/aluminum hybrid composites for aircraft structures. Mater Res 2006, 9:247-256.
13. Sinmazçelik T., Avcu E., Bora M.Ö., Çoban O. A review: fibre metal laminates, background, bonding types and applied test methods. Mater Des 2011, 32:3671-3685.
14. Sexton A., Cantwell W., Kalyanasundaram S. Stretch forming studies on a fibre metal laminate based on a self-reinforcing polypropylene composite. Compos Struct 2012, 94:431-437.
15. Drakonakis V.M., Seferis J.C., Doumanidis C.C. Curing pressure influence of out-of-autoclave processing on structural composites for commercial aviation. Adv Mater Eng 2013, 10.1155/356824.
16. Jensen BJ, Cano RJ, Hales SJ, Alexa JA, Weiser ES, Loos AC, et al. Fiber metal laminate made by the VARTM process. In: 17th International conference on composite materials. Edinburgh, Scotland, 2009.
17. Kalyanasundaram S., DharMalingam S., Venkatesan S., Sexton A. Effect of process parameters during forming of self reinforced - PP based fiber metal laminate. Compos Struct 2013, 97:332-337.
18. Mosse L., Compston P., Cantwell W.J., Cardew-Hall M., Kalyanasundaram S. The effect of process temperature on the formability of polypropylene based fibre-metal laminates. Compos Part A: Appl Sci Manuf 2005, 36:1158-1166.
19. Reyes G., Gupta S. Manufacturing and mechanical properties of thermoplastic hybrid laminates based on DP500 steel. Compos Part A: Appl Sci Manuf 2009, 40:176-183.
20. Ye L., Friedrich K., Kästel J. Consolidation of GF/PP commingled yarn composites. Appl Compos Mater 1995, 1:415-429.
21. Santulli C., Gil R.G., Long A.C., Clifford M.J. Void content measurements in commingled e-glass/polypropylene composites using image analysis from optical micrographs. Sci Eng Compos Mater 2011, 10:77-90.
22. Shahzad MA, Steeg M, Mitschang P. Development and characterization of glass fiber reinforced in-situ polymerized thermoplastic matrix composite material. SAMPE 2010. Seattle; 2010.
23. Tripathy A.R., Elmoumni A., Winter H.H., MacKnight W.J. Effects of catalyst and polymerization temperature on the in situ polymerization of cyclic poly(butylene terephthalate) oligomers for composite applications. Macromolecules 2005, 38:709-715.
24. Parton H., Verpoest I. In situ polymerization of thermoplastic composites based on cyclic oligomers. Polym Compos 2005, 26:60-65.
25. Pillay S., Vaidya U., Janowski G.M. Liquid Molding of carbon fabric-reinforced nylon matrix composites laminates. J Thermoplast Compos Mater 2005, 18:509-527.
26. Ishak Z.A.M., Leong Y.W., Steeg M., Karger-Kocsis J. Mechanical properties of woven glass fabric reinforced in situ polymerized poly(butylene terephthalate) composites. Compos Sci Technol 2007, 67:390-398.
27. Mairtin P., McDonell P., Connor M., Eder R., Bradaigh C. Process investigation of a liquid PA-12/carbon fiber moulding system. Compos Part A: Appl Sci Manuf 2001, 32.
28. Eder R, Winchler S. Processing of advanced thermoplastic composites using cyclic thermoplastic polyester. In: 22nd International SAMPE Europe conference. Paris 2001; p. 661-7.
29. Parton H., Baets J., Lipnik P., Goderis B., Devaux J., Verpoest I. Properties of poly(butylene terephthatlate) polymerized from cyclic oligomers and its composites. Polymer 2005, 46:9871-9880.
30. Zingraff L., Michaud V., Bourban P.E. Resin transfer molding of anionically polymerised polyamide 12. Compos Part A: Appl Sci Manuf 2005, 36:1675-1686.
31. Wu W., Xie L., Jiang B., Ziegmann G. Simultaneous binding and toughening concept for textile reinforced pCBT composites: manufacturing and flexural properties. Compos Struct 2013, 105:279-287.
32. Rijswijk K., Geenen A., Bersee H. Textile fiber reinforced anionic polyamide-6 composites: Part II: Investigation on interfacial bond formation by short beam shear test. Compos Part A: Appl Sci Manuf 2009, 40:1033-1043.
33. Rijswijk K., Teuwen J., Bersee H. Textile fiber-reinforced anionic polyamide-6 composites. Part I: The vacuum infusion process. Compos Part A: Appl Sci Manuf 2009, 41:1-10.
34. David M., Roman T., Dino W., Nakanishi H., Kasai H., Ando N., et al. Polybutylene terephthalate on metals: a density functional theory and cluster models investigation. J Phys: Condens Matter 2006, 18:1137-1142.
35. Xue J., Wang W.-X., Takao Y., Matsubara T. Reduction of thermal residual stress in carbon fiber aluminum laminates using a thermal expansion clamp. Compos Part A: Appl Sci Manuf 2011, 42:986-992.
36. Lin C.T., Kao P.W., Jen M.H.R. Thermal residual strains in carbon fibre-reinforced aluminium laminates. Composites 1994, 25:303-307.
37. Wu W, Klunker F, Xie L, Jiang B, Ziegmann G. Simultaneous binding and ex situ toughening concept for textile reinforced pCBT composites: Influence of preforming binders on interlaminar fracture properties. Compos Part A: Appl Sci Manuf; 2013. [in press].
38. 2-Plasma Treatment on Copper Surface. Jpn J Appl Phys 2004, 43:7415-7418.
39. Belitskus D. Reaction of aluminum with sodium hydroxide solution as a source of hydrogen. J Electrochem Soc 1970, 117:1097-1099.
40. Ruiz E., Achim V., Soukane S., Trochu F., Breard J. Optimization of injection flow rate to minimize micro/macro-voids formation in resin transfer molded composites. Compos Sci Technol 2006, 66:475-486.