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Life Cycle Impacts of Natural Fiber Composites for Automotive Applications: Effects of Renewable Energy Content and Lightweighting

CSS Publication Number
CSS16-20
Full Publication Date
February, 2016
Abstract

This study examines the life cycle energy demand and greenhouse gas (GHG) emissions associated with substituting natural cellulose and kenaf in place of glass fibers in automotive components. Specifically, a 30 wt% glass-fiber composite component weighing 3 kilograms (kg) was compared to a 30 wt% cellulose fiber composite component (2.65 kg) and 40 wt% kenaf fiber composite component (2.79 kg) for six cars, crossovers, and sport utility vehicles. The use-phase fuel consumption of the baseline and substitute components, with and without powertrain resizing, were determined using a mass-induced fuel consumption model based on U.S. Environmental Protection Agency test records. For all vehicles, compared to the baseline glass fiber component, using the cellulose composite material reduced life cycle energy demand by 9.2% with powertrain resizing (7.2% without) and reduced life cycle GHG emissions by 18.6% with powertrain resizing (16.3% without), whereas the kenaf composite component reduced energy demand by 6.0% with powertrain resizing (4.8% without) and GHG emissions by 10.7% with powertrain resizing (9.2% without). For both natural fiber components, the majority of the life cycle energy savings is realized in the use-phase fuel consumption as a result of the reduced weight of the component.

Co-Author(s)
Ellen Lee
Timothy J. Wallington
Research Areas
Mobility Systems
Transportation
Keywords

bio-based materials, biogenic carbon, industrial ecology, plastic composites, renewable energy, vehicle lightweighting

Publication Type
Journal Article
Digital Object Identifier
10.1111/jiec.12286
Full Citation

Boland, Claire, Robb De Kleine, Gregory Keoleian, Ellen C. Lee, Hyung Chul Kim, and Timothy J. Wallington. (2016) “Life Cycle Impacts of Natural Fiber Composites for Automotive Applications: Effects of Renewable Energy Content and Lightweighting.” Journal of Industrial Ecology 20(1): 179-189.