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Each year approximately 12 million automobiles reach the end of their useful life and enter a complex infrastructure designed to recover usable parts and materials of value (primarily the ferrous and nonferrous metals). The remaining material, a mixture of glass, rubber, plastics, foam, and dirt, is referred to as shredder residue (SR) and is currently sent to landfills for disposal. However, a new Thermal Conversion Process (TCP) developed by Changing World Technologies may make it possible to convert this waste into a light hydrocarbon oil. TCP is a new technology under investigation by the Vehicle Recycling Partnership (VRP) and its partners. This process converts hydrocarbons and other organic materials into marketable oils and specialty chemicals for potential industrial and commercial use. Early research has demonstrated the ability to take SR and convert it into a light hydrocarbon oil, fuel gas, and carbon.

In the past there has been a concentration on performing LCAs of car components. Based on the increasing experience and know-how gained in the past by performing LCAs of car components truck designers get the chance to make a statement about the ecological impact of each alternative. The most significant difference between LCAs of car and truck components is the use phase. This paper describes a Life-Cycle-Assessment (LCA) of different air deflection systems made of composite materials. The actually used system is produced by Resin Transfer Molding (RTM) while a possible alternative could be made out of Sheet Molding Compound (SMC). The calculations have shown that there exists a potential to improve the ecological profiles of composite components by replacing glass fibers with natural fibers.

Mercedes-Benz at DaimlerChrysler has been developing and applying Life-Cycle-Engineering (LCE) and Life-Cycle-Assessment (LCA) since almost 10 years. Extensive experience and know-how has been gained by two complete car LCAs and more than 100 LCAs for parts. According to our experience LCA/LCE is most effectively and efficiently used to support the development of new products. One of DaimlerChrysler's Environmental Guidelines includes a statement, that our approach to environmentally acceptable design covers the entire product spectrum of the DaimlerChrysler Group, taking into account the product life cycle from design through disposal or recycling. The organisation of environmental management at DaimlerChrysler has a distinct structure of tasks: the central Environmental Protection Division coordinates all organisation/ plant related aspects, while all product related aspects are the responsibility of the divisonal business units.

In previous projects, the Vehicle Recycling Partnership (VRP) and Salyp N.V. have demonstrated the ability to separate plastics, foams, ferrous metals, and non-ferrous metals from shredder residue using the Salyp recovery process. Salyp's recovery process consists of a number of different stages, which are discussed in a previous SAE paper by the VRP and Salyp1. These include a sized-based material separation, a foam cleaning system, additional material separation based on material type, etc. However, during the previous project, the potential impact of the process on the environment via air emissions, waste emissions, or in terms of energy consumption were not determined. Understanding the overall environmental impact of this recycling process is important. Therefore, the VRP concluded that a life cycle approach was necessary to investigate the energy and specific environmental impacts of this technology.