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2017 | OriginalPaper | Buchkapitel

14. Carbon Fibre Polymer Matrix Structural Composites

verfasst von : R. J. H. Wanhill

Erschienen in: Aerospace Materials and Material Technologies

Verlag: Springer Singapore

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Abstract

This chapter concisely surveys the applications and properties of polymer matrix structural composites (PMCs), concentrating on carbon fibre reinforced composites. These are the most widely used composite materials, notably in aerospace, and are commonly called carbon fibre reinforced plastics (CFRP). A major source for this chapter is Baker et al. (Composite materials for aerospace structures. American Institute of Aeronautics and Astronautics, Inc., Reston, Virginia, USA, 2nd edn, 2004).

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Vorheriges Kapitel GLARE®: A Versatile Fibre Metal Laminate (FML) Concept

Nächstes Kapitel C/C and C/SiC Composites for Aerospace Applications

Baker A, Dutton S, Kelly D (2004) Composite materials for aerospace structures, 2nd edn. American Institute of Aeronautics and Astronautics Inc., Reston, VA 20191, USA

Prasad NE, Gokhale AA, Wanhill RJH (eds) (2014) Aluminum–lithium alloys: processing, properties and applications. Butterworth-Heinemann, Elsevier Inc., Oxford, UK

Wanhill RJH (2013) Aerospace applications of aluminum-lithium alloys. In: Prasad NE, Gokhale AA, Wanhill RJH (eds) Aluminum-lithium alloys, processing, properties and applications. Butterworth-Heinemann, Elsevier Inc., Oxford, UK, pp 503–535

Grimshaw MN, Grant CG, Diaz JML (2001) Advanced technology tape laying for affordable manufacturing of large composite structures. In: Repecka L, Garemi FF (eds) 2001: a materials and processes odyssey. Society for the Advancement of Material and Process Engineering, Covina, CA 91724-3759, USA, pp 2484–2494

Department of Defense Handbook (2002) Composite materials handbook. Volume 1, polymer matrix composites guidelines for characterization of structural materials, MIL-HDBK-17-1F. Document Automation and Production Service (DAPS), Philadelphia, PA 19111-5094, USA

Department of Defense Handbook (2002) Composite materials handbook. Volume 2: polymer matrix composites materials properties, MIL-HDBK-17-2F. Document Automation and Production Service (DAPS), Philadelphia, PA 19111-5094, USA

Department of Defense Handbook (2002) Composite materials handbook. Volume 3: polymer matrix composites materials usage, design, and analysis, MIL-HDBK-17-3F. Document Automation and Production Service (DAPS), Philadelphia, PA 19111-5094, USA

Mouritz AP (2012) Introduction to aerospace materials. Woodhead Publishing Limited, Cambridge, UKCrossRef

AGARD Report 785 (1992) The utilization of advanced composites in military aircraft. Advisory Group for Aerospace Research and Development, Neuilly-sur-Seine, France

10.

Peel CJ (1990) The development of aluminium lithium alloys: an overview. In: New light alloys. AGARD Lecture Series No. 174, Advisory Group for Aerospace Research and Development, Neuilly-sur-Seine, France, pp 1-1–1-55

11.

Campbell FC (2010) Structural composite materials. ASM International, Materials Park, OH 44073-0002, USA

12.

Wright GA (1992) An overview of concerns relating to fluid effects on composites. In: The utilization of advanced composites in military aircraft. AGARD Report 785, Advisory Group for Aerospace Research and Development, Neuilly-sur-Seine, France, pp 13-1–13.6

13.

Brosius D (2003) Advanced pultrusion takes off in commercial aircraft structures. Gardner Business Media, Inc., Cincinnati, OH 45244, USA. www.compositesworld.com

14.

Lequeu P, Lassince P, Warner T (2007) Aluminium alloy development for the Airbus A380—Part 2. Adv Mater Processes 165(7):41–44

15.

Vogelesang LB (2004) Fibre metal laminates, the development of a new family of hybrid materials. In: Guillaume G (ed) ‘ICAF 2003: fatigue of aeronautical structures as an engineering challenge, vol I, pp 3–27. Engineering Materials Advisory Services, Warrington, UK

16.

Halpin JC, Kim H (2007) Managing impact risk for composite structures: unifying durability and damage tolerance perspective. FAA/EASA/Industry composite damage tolerance and maintenance workshop, 7–11 May 2007, Amsterdam, the Netherlands

17.

Halpin JC, Kim H (2009) Managing damage threats for composite structures: unifying durability and damage tolerance perspective. In: 3rd FAA/EASA/Industry composite damage tolerance and maintenance workshop, 1–5 June 2009, Tokyo, Japan

18.

Fawcett AJ Jr, Oakes GD (2006) Boeing composite airframe damage tolerance and service experience. In: FAA/Wichita State University composite damage tolerance & maintenance workshop, 19–21 July 2006, Chicago, Illinois, USA

19.

Waite S (2006) Damage/defect types and inspection—some regulatory concerns. FAA/Wichita State University composite damage tolerance & maintenance workshop, 19–21 July 2006, Chicago, Illinois, USA

20.

Clark G, Saunders DS (1991) Morphology of impact damage growth by fatigue in carbon fibre composite laminates. Mater Forum 15:333–342

21.

Ilcewicz L (2006) Composite damage tolerance and maintenance safety issues. In: FAA/Wichita State University composite damage tolerance & maintenance workshop, 19–21 July 2006, Chicago, Illinois, USA

22.

Fualdes C, Thévenin R (2006) Composites @ airbus damage tolerance methodology. FAA/Wichita State University composite damage tolerance & maintenance workshop, 19–21 July 2006, Chicago, Illinois, USA

23.

Ilcewicz L (2009) Updates to AC 20-107B ‘Composite Aircraft Structure’. In: 3rd FAA/EASA/Industry composite damage tolerance and maintenance workshop, 1–5 June 2009, Tokyo, Japan

24.

Waite S (2014) Composite materials: developing continued airworthiness issues. In: SIASA (Support to the Improvement of Aviation Safety in Africa) workshop on technology evolution—impact on airworthiness, 23–24 Sept 2014, Windhoek, Namibia

25.

Federal Aviation Administration (2010) Composite aircraft structure. Advisory Circular FAA AC-20-107B, Change 1, 24 Aug 2010. U.S. Department of Transportation, Washington, DC 20590, USA

26.

Smith RA (2009) Composite defects and their detection. In: Rawlings RD (ed) Materials science and engineering, vol III. Encyclopedia of Life Support Systems, UNESCO, Paris, France, pp 103–143

27.

Ilcewicz LB (2004) Composite technology development for commercial airframe stru ctures. In: Kelly A, Zweben C, Bader MG, Kedward KT, Sawada Y (eds) Comprehensive composite materials, volume 6: design and applications. Elsevier Science Ltd., Oxford, UK, pp 121–163

28.

Modlin CT, Zipay JJ (2014) The 1.5 & 1.4 ultimate factors of safety for aircraft and spacecraft—history, definition and applications. ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/2 140011147

29.

Calomfirescu M, Hickethier H (2010) Damage tolerance of composite structures in aircraft industry. Composites Europe 2010, 14–16 Sept 2010, Essen, Germany

30.

Ball DL, Norwood DS, TerMaath SC (2006) Joint Strike Fighter airframe durability and damage tolerance certification. AIAA paper 2006-1867, In: 47th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference, 1–4 May 2006, Newport, Rhode Island, USA

31.

Gorss J (2003) High performance carbon fibers. American Chemical Society Commemorative Booklet, 17 Sept 2003, Washington, DC 20036, USA

32.

Dow MB, Smith DL (1989) Damage tolerant composite materials produced by stitching carbon fabrics. In: Proceedings of the 21st International SAMPE Technical Conference 25–28 Sept 1989, Atlantic City, New Jersey. Society for the Advancement of Materials and Process Engineering, Covina, CA 91724-3759, USA, pp 595–605

33.

Davis JG Jr, Bohon HL (eds) (1991) First NASA advanced composites technology conference. NASA Conference Publication 3104, Parts 1 and 2, NASA Scientific and Technical Information Program STI Support Services, NASA Langley Research Center, Hampton, VA 23681-2199, USA

34.

NASA Facts (1997) The advanced stitching machine: making composite wing structures of the future. National Aeronautics and Space Administration FS-1997-08-31-LaRC, Aug 1997, Langley Research Center, Hampton, VA 23681, USA

35.

Velicki A, Thrash P, Jegley D (2009) Airframe development for the Hybrid Wing Body aircraft. Paper AIAA 2009-932, 47th AIAA Aerospace Sciences Meeting Including the New Horizons Forum and Aerospace Exposition, 5–8 Jan 2009, Orlando, Florida, USA

36.

Velicki A, Jegley D (2011) PRSEUS development for the Hybrid Wing Body aircraft. Paper AIAA 2011-7025, AIAA centennial of naval aviation forum “100 years of achievement and progress”. 21–22 Sept 2011, Virginia Beach, Virginia, USA

37.

Velicki A, Jegley D (2014) PRSEUS structural concept development. Paper AIAA-2014-0259, 55th AIAA/ASME/ASCE/AHS/SC Structures, Structural Dynamics, and Materials Conference, 13–17 Jan 2014, National Harbor, MD 20745, USA

38.

Jegley DC, Velicki A (2015) Development of the PRSEUS multi-bay pressure box for a Hybrid Wing Body vehicle. Paper in: AIAA 2015 Science and Technology Forum and Exposition, 5–9 Jan 2015, Kissimmee, Florida, USA

39.

Liebeck RH (2004) Design of the blended wing body subsonic transport. J Aircr 41(1):10–25MathSciNetCrossRef

40.

Blaiszik BJ, Kramer SLB, Olugebefola SC, Moore JS, Sottos NR, White SR (2010) Self-healing polymers and composites. Annu Rev Mater Res 40:179–211CrossRef

41.

Smith JG Jr (2012) An assessment of self-healing fiber reinforced composites. NASA Technical Memorandum NASA/TM-2012-217325, NASA Center for Aerospace Information, Hanover, MD 21076-1320, USA

42.

Yin T, Zhou L, Rong MZ, Zhang MQ (2008) Self-healing woven glass fabric/epoxy composites with the healant consisting of micro-encapsulated epoxy and latent curing agent. Smart Mater Struct 17(1), 15019 (8 pp)

Tong L, Mouritz AP, Bannister MK (2002) 3D fibre reinforced polymer composites. Elsevier Science Ltd., Oxford, UK

Titel: Carbon Fibre Polymer Matrix Structural Composites
verfasst von: R. J. H. Wanhill
Verlag: Springer Singapore
Buch: Aerospace Materials and Material Technologies
Print ISBN: 978-981-10-2133-6

Electronic ISBN: 978-981-10-2134-3

Copyright-Jahr: 2017
DOI: https://doi.org/10.1007/978-981-10-2134-3_14

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