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Weight Reduction in Automotive Design and Manufacture
The report also includes a detailed section on materials technology and examines the use of advanced steel, aluminium, magnesium, titanium, carbon fibre, plastics, bio-materials and textiles. Recycling and joining technology are also considered. Introduction The effect of policy initiatives Weight saving methods Competition between OEMs Mass reduction and vehicle lifecycle CO2 emissions Barriers to weight reduction DifferentiationSafety Process development Cost considerations The drivers for lightweighting Fuel economy and CO2 emissions The European Union Figure 1: Potential further gains in vehicle efficiency Figure 2: Segment average kerb weights 1990 – 2012 (Europe) Figure 3: US light duty vehicle trends for weight, acceleration, fuel economy, and weight-adjusted fuel economy for model years 1975-2009 (US EPA, 2009 data) Figure 4: Weight reduction in the current weight-based CO2 target system (left) and in a size based system (right) Figure 5: Average CO2 emissions levels for new passenger cars in the EU Figure 6: CO2 emissions for model year 2008 hybrids and their non-hybrid counterparts Figure 7: The cost of fuel efficiency gains through weight reduction compared to other technologies Figure 8: Fiat’s C-Evo Platform Figure 9: North American curb weight forecast Figure 10: The use phase dominates lifecycle vehicle emissions Figure 11: Analysing lifetime greenhouse http://www.prnewswire.com/news-releases/garcinia-cambogia-extract—crucial-data-released-231403591.html gas effects Figure 12: Relative CO2 reduction benefits vs. relative cost Figure 13: Drivers and areas of focus for vehicle weight reduction Figure 14: Global mandatory automobile efficiency and GHG standards Figure 15: Methods for reducing CO2 output Figure 16: Impact of vehicle weight on fuel consumption pure garcinia cambogia Figure 17: CO2 (g/km) performance and standards in the EU new cars 1994 – 2011 Figure 18: The effect of alternative German proposals for CO2 reduction regulation for Europe Figure 19: US targets for future GHG reductions (% reduction from 2005 levels) Figure 20: Average fuel efficiency 2010 and 2015 targets for gasoline vehicles Figure 21: Global passenger car and light vehicles emission legislation progress 2005 2025 Figure 22: Comparison of different test regimes for EU, US and Japan Figure 23: Comparison of different fuel efficiency regulations and test regimes Figure 24: US mass of passenger cars 1975 2010 with weight attributed to safety, emissions, comfort and convenience features Figure 25: Relative crash safety of mass reduced SUV and car combinations Figure 26: Weight and cost comparison for automotive components Figure 27: Challenges with materials application Figure 28: Changing cost implications in improving weight performance Figure 29: Average profit per vehicle versus CO2 compliance costs Figure 30: Average price of gasoline in the US 2002 to 2012 Figure 31: Average price of gasoline, diesel and natural gas in the US 2010 to 2012 Figure 32: US Regular Gasoline prices $/gallon, January 2011 to June 2013 Figure 33: Evolution of average Al content of passenger cars in Europe Figure 34: Progress in weight reduction through materials technology Figure 35: A schematic illustrating lifecycle considerations for CO2 equivalent Figure 36: Materials production average greenhouse gas emissions Figure 37: Demand shortfall of aluminium from end-of-life recycling Figure 38: Lower fuel consumption outweighs additional CO2 burden from lightweight material manufacturing Figure 39: Lifecycle system analysis schematic Figure 40: CO2 equivalent output per kWh of electricity produced Figure 41: Global automotive microelectromechanical systems (MEMS) sensors shipments Figure 42: Mini segment average kerb weights 1990 – 2012 (Europe) Figure 43: Lower mid segment average kerb weights 1990 – 2012 (Europe) Figure 44: Upper mid segment average kerb weights 1990 – 2012 (Europe) Figure 45: Luxury segment average kerb weights 1990 – 2012 (Europe) Figure 46: Trends in aluminium use Figure 47: The multi-material vehicle concept applied to the Audi A8 body-in-white Figure 48: Aluminium potential and market penetration in Europe Figure 49: Weight share of modules and their weight increase Figure 50: Changes in steel usage in BIW application Figure 51: Front bumper design for the new Fiat Panda delivers 0.88kg weight saving Figure 52: BIW materials 2006 data and 2015 forecast Figure 53: Front bumper design for the new Alpha Romeo Giulietta delivers 3.1kg weight saving Figure 54: Aluminium/ magnesium lightweight design 6 cylinder engine Figure 55: Engine weight and performance for aluminium and cast iron blocks Figure 56: 1.0L Ecoboost cylinder head with integrated exhaust manifold Figure 57: A lightweight strut with a fibreglass wheel carrier Figure 58: Aston Martin carbon fibre rear spoiler Figure 59: Cost comparison of lightweight vehicle structures Figure 60: Areas for chassis weight reduction Figure 61: Mass reduction in seat design Figure 62: Contribution to weight reduction Figure 63: Laser sintered manifold Figure 64: Implementation of advanced steel alloys over time for Ford models Figure 65: Overall demand for auto steel and other metals and materials Figure 66: Advanced high strength steel developments Figure 67: BIW materials by tensile strength BMW 6 Series Figure 68: Third generation advanced high strength steel development Figure 69: Microstructure of TRIP steel Figure 70: Use of boron steel in BMW’s 6 Series BIW Figure 71: Beyond third generation AHSS; NanoSteel alloys Figure 72: P-group elements in the periodic table Figure 73: Elongation versus alloy percent p-group elements conventional high strength steels Figure 74: Elongation versus alloy percent p-group elements NanoSteel AHSS Figure 75: Life cycle greenhouse gas emissions of the Future Steel Vehicle (FSV) programme vehicles Figure 76: Steel portfolio to technology portfolio flow diagram for the FSV programme Figure 77: Aluminium content per vehicle Figure 78: Primary aluminium production 2012 Figure 79: Global aluminium production including recycling 2012 Figure 80: US forecast market share of steel and aluminium Figure 81: Al growth by segment for Europe and North America Figure 82: Aluminium content by system/ component Figure 83: Aluminium content in 2012 Figure 84: Aluminium and plastic componentry BMW 7 Series body structure Figure 85: Aluminium content growth 2009 to 2012 Figure 86: Iso-strength curves for 6000 Series alloys Figure 87: Composition of 7000 Series alloys Figure 88: Aluminium front structure Figure 89: Weight reduction studies Figure 90: Federal Mogul’s Advanced Estoval II piston Figure 91: Aluminium steering knuckle Figure 92: Magnesium content per vehicle Figure 93: Specific strength versus specific stiffness for various materials Figure 94: Magnesium demand breakdown Figure 95: Magnesium pricing history Figure 96: Global magnesium production 1998 and 2011 by region Figure 97: Potential for weight saving replacing aluminium with magnesium in the powertrain Figure 98: Typical magnesium die castings Figure 99: Die cast three cylinder engine block in AM-SC1 alloy Figure 100: Stamped magnesium tailgate Figure 101: Thermally formed magnesium alloy sheet trunk lid inner Figure 102: Potential magnesium applications Figure 103: Potential magnesium extrusion use Figure 104: Proportions of different materials Audi R8 Figure 105: Application of titanium-Metal Matrix Composite (MMC) alloys for engine components Figure 106: Connecting rod made of Ti-SB62 split using laser cracking Figure 107: Turbocharger turbine wheel made from ?TiAl Figure 108: Titanium MMC crankshaft using Ti-4A-4V+12% TiCl Figure 109: Comparison between titanium and steel spring showing 50% weight saving Figure 110: VW Golf 4-Motion titanium exhaust Figure 111: Titanium use in the Bugatti Veyron Figure 112: laser sintered titanium components Figure 113: Price elasticity of demand for various engineering materials Figure 114: CFRP cost structure according to SGL Group Figure 115: Resin Transfer Moulding (RTM) process chain Figure 116: Resin Transfer Moulding (RTM) process schematic Figure 117: McLaren’s MP4-12C featuring a carbon fibre monocoque safety cell Figure 118: CFRP future development roadmap Figure 119: Schematic of the Resin Spray Transfer process Figure 120: Advanced engineering plastics use in the MX-0 design challenge vehicle Figure 121: Density strength relationships for various engineering materials Figure 122: Emerging automotive nanotechnology uses Figure 123: Emerging applications for carbon nanotube based materials technology Figure 124: Nanocomposite interior component Figure 125: Over injection moulding of metal structures Figure 126: A schematic illustrating a holistic interdisciplinary approach to multi-material design and manufacture Figure 127: Optimal continuous fibre reinforcement design for thermoplastic component Figure 128: Optimised component design achieved by intrinsic materials hybridisation Figure 129: Hybrid materials process schematic Figure 130: Wheat Straw/ Polypropylene storage bin and cover liner used in the 2010 Ford Flex Figure 131: ELV regulation implementation Figure 132: Joining technologies used in automotive manufacturing. Figure 133: Laser welded door containing three different steels.
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