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References

  • 1
    Global Industry Analysts. Sporting Goods. A Global Outlook. Global Industry Analysts: San Jose, 2008.
  • 2
    McWilliams A. Materials and Devices for High-Performance Sports Products. BBC Research Report AVN053A: London, January, 2006.
  • 3
    Cunliffe AM, Jones N, Williams PT. Pyrolysis of composite plastic waste. Environmental Technology 2003; 24: 653663.
  • 4
    Mayes JS. Recycling of fibre-reinforced plastics. JEC Composites Magazine 2005; 42: 2426.
  • 5
    BaillieC (ed). Green Composites: Polymer Composites and the Environment. Woodhead Publishing: Cambridge, 2004.
  • 6
    Giulvezan G, Carberry W. Composite recycling and disposal––an environmental R&D issue. Boeing Environment Technotes 2003; 8: 14.
  • 7
    Feih S, Mathys Z, Gibson AG, Mouritz AP. Strength degradation of glass fibers at high temperatures. Journal of Materials Science 2009; 44: 392400.
  • 8
    Lee SM, Jonas T, DiSalvo G. The beneficial energy and environmental impact of composite materials––an unexpected bonus. SAMPE Journal 1991; 27 (March/April): 1925.
  • 9
    Williams P. Recycling of automotive composites––the pyrolysis process and its advantages. Materials World 2003; 11: 2426.
  • 10
    Henshaw JM, Han W, Owens AD. An overview of recycling issues for composite materials. Journal of Thermoplastic Composite Materials 1996; 9: 420.
  • 11
    Henshaw JM. Recycling and Disposal of Polymer–Matrix Composites. ASM Handbook (vol. 21): Composite. American Society of Metals: Ohio, 2001; 10061012.
  • 12
    Easterling KE. Advanced Materials for Sports Equipment. Chapman and Hall: London, 1993.
  • 13
    Spry WJ, Klein A. Sports and Recreation Equipment Applications. ASM Handbook (vol. 21). American Society of Metals: Ohio, 2001; 10711077.
  • 14
    Jenkins M. Materials in Sports Equipment. Woodhead Publishing Limited: Cambridge, 2003.
  • 15
    Kennerley JR, Kelly RM, Fenwick NJ, Pickering SJ, Rudd CD. The characterization and reuse of glass fibres recycled from scrap composites by the action of a fluidized bed process. Composites 1998; 29(A): 839845.
  • 16
    Anastas PT, Lankey L. Life cycle assessment and green chemistry: the yin and yang of industrial ecology. Green Chemistry 2000; 2: 289295.
  • 17
    Goedkoop M, Spriensma R. The Eco-Indicator 99. A damage oriented method for life cycle impact assessment (3rd edn), 2000. Methodology report. Available: www.pre.nl/eco-indicator99/ei99-reports.htm [accessed June 2009].
  • 18
    Racquet Tech. Factory Tour: The Making of a Racquet, 2003. Available: www.racquettech.com [accessed June 2009].
  • 19
    Subic A, Paterson N. Life cycle assessment and evaluation of environmental impact of sports equipment. In: MoritzEF, HaakeS (eds). The Engineering of Sport 6. Springer: Munich, 2006; 4147.
  • 20
    Subic A, Paterson N. Integrating design for environment approach in sports products development. In: FussFK, SubicA, UjihashiS (eds). The Impact of Technology on Sport II. Taylor & Francis: London, 2008; 2537.
  • 21
    Subic A. Materials in Sports Equipment 2. Woodhead Publishing and CRC Press: Cambridge, 2007.
  • 22
    Hanna K, Subic A. Towards sustainable design in the sports and leisure industry. International Journal of Sustainable Design 2008; 1(1): 6074.
  • 23
    Subic A. Transdisciplinary dimensions of sustainable design practice. International Journal of Sustainable Design 2009; 1(2): 127130.
  • 24
    Seuring S. Strategy and Organization in Supply Chains. Springer: New York, 2003.
  • 25
    Zebedin H. Design for disassembly and recycling for small and medium sized companies for the next generation. Computer Science. Computer Aided Systems Theory 2000; 1798: 282300.
  • 26
    http://www.x-bionic.com [accessed 25 August 2009].
  • 27
    Dewberry E. Ecodesign-Present Attitudes and Future Directions: Studies of UK Company and Design Consultancy Practice (PhD Thesis). Open University: UK, 1996.
  • 28
    Wilson A, Mowbray J. Eco-Textile Labelling. A Guide for Manufacturers, Retailers and Brands. Mowbray Communications: London, 2008.
  • 29
    Humblet C. A System Dynamics Analysis of a Capilene Supply Loop (MBA Thesis). Sloan School of Management, MIT: Boston, 2006.
  • 30
    http://www.teijinfiber.com [accessed 25 August 2009].
  • 31
    Morana R, Seuring S. End-of-life returns of long-lived products from end customer–insights from an ideally set up closed-loop supply chain. International Journal of Production Research 2007; 45(18/19): 44234437.
  • 32
    Domina T, Koch K. The textile waste lifecycle. Clothing and Textiles Research Journal 1997; 15(2): 96102.
  • 33
    Woolridge A, Ward G, Phillips P, Collins M, Gandy S. Life cycle assessment for reuse/recycling of donated waste textiles compared to use of virgin material: An UK energy saving perspective. Resources, Conservation and Recycling 2006; 46(1): 94103.
  • 34
    Simpson P. Global trends in fibre prices, production and consumption. Textiles Outlook International 2006; 125: 82106.
  • 35
    Allwood JM, Laursen SE, Malvido de Rodríguez C, Bocken NMP. Well dressed? The Present and Future Sustainability of Clothing and Textiles in the United Kingdom. University of Cambridge, Institute for Manufacturing: Cambridge, 2006.
  • 36
    Wilson A, Mowbray J. Eco-textile labelling. A guide for manufacturers, retailers and brands. Mowbray Communications 2008; 1415.
  • 37
    Walsh JAH, Brown MS. Pricing environmental impacts: a tale of two T-shirts. Illahee 1995; 11(3/4): 175182.
  • 38
    Gupta B, Revagade N, Hilborn J. Poly (lactic acid) fiber: An overview. Progress in Polymer Science 2007; 32(4): 455482.
  • 39
    Hemmings J. Corn on the job. EcoTextile News 2007; 2: 1617.
  • 40
    Cicero JA, Dorgan JR. Physical properties and fiber morphology of poly (lactic acid) obtained from continuous two-step melt spinning. Journal of Polymers and the Environment 2001; 9: 110.
  • 41
    Xu Y, Lu Z, Tang R. Structure and thermal properties of bamboo viscose, Tencel and conventional viscose fiber. Journal of Thermal Analysis and Calorimetry 2007; 89(1): 197201.
  • 42
    Yu L. Biodegradable Polymer Blends and Composites from Renewable Resources. John Wiley and Sons: Portland, 2009.
  • 43
    Lodha P, Netravali AN. Characterization of stearic acid modified soy protein isolate resin and ramie fiber reinforced ‘green’ composites. Composites Science and Technology 2005; 65: 12111225.
  • 44
    Brasquet C, Roussy J, Subrenat PL. Adsorption and selectivity of activated carbon fibers application to organics. Environmental Technology 1996; 17(11): 12451252.
  • 45
    Lou C-W, Lin C-W, Lei C-H, Su K-H, Hsu C-H, Lin Z-H, Lin J-H. PET/PP blend with bamboo charcoal to produce functional composites. Journal of Materials Processing Technology 2007; 192–193: 428433.
  • 46
    Schuh–Daimler G. Renewable Materials for Automotive Applications. Chrysler AG: Stuggart, 2000.
  • 47
    Watkins P. Survey of the European yarn fairs for spring/summer 2010. Textile Outlook International 2009; 139: 5365.
  • 48
    Scheirs J, Timothy E. Long Modern Polyesters: Chemistry and Technology of Polyesters and Copolyesters. John Wiley and Sons: New York, 2004.
  • 49
    Kumar S, Malegeant P. Strategic alliance in a closed-loop supply chain, a case of manufacturer and eco-non-for-profit organisation. Technovation 2006; 26(10): 1127–1135.