The art and science of glass engineering, specifically applied to automotive projects, are not at all commonplace. Although windshields, side and backlites seem to be obvious parts of any car, truck, or bus, designing, sourcing, and manufacturing them are unique challenges. From the business perspective, cost control makes the choice of the ideal supplier a vital decision, greatly impacting availability and production. From the technical standpoint, the most creative designs can be rendered impractical due to regulations, lack of economies of scale, or convoluted logistics. Glass Engineering: Design Solutions for Automotive Applications tackles all these variables using a no-nonsense, step-by-step approach. Written by Lyn R. Zbinden, a mechanical engineer and glass specialist, this book narrows the gap between the reader and a technical subject by using language that is easy to understand, a good variety of examples, and a series of invaluable reference design tables.
The years following the Second World War saw Britain in the grip of shortages, rationing and recession. For those wanting a high-performance car there was little choice - either buy a pre-war model, or build your own. This led to the conversion of the most unlikely vehicles into genuine sports cars, and a whole industry grew up using the newly-developed fiberglass material to facilitate conversions. Operating from a tiny back-street woolen mill, Rochdale Motor Panels became a market leader, and made it possible to construct genuine 100mph+ vehicles at a fraction of market prices. The late 1950s were a boom time, and by 1960 Rochdale was ready for a huge leap forward. The exquisite Lotus Elite had proved it was possible to use the material for structural purposes: Rochdale cleverly avoided all the problems faced by that vehicle in their breathtakingly simple Olympic design.
The automotive industry is under constant pressure to design vehicles capable of meeting increasingly demanding challenges such as improved fuel economy, enhanced safety and effective emission control. Drawing on the knowledge of leading experts, Advanced Materials in Automotive Engineering explores the development, potential and impact of using such materials. Beginning with a comprehensive introduction to advanced materials for vehicle lightweighting and automotive applications, it goes on to consider nanostructured steel for automotive body structures, aluminum sheet and high pressure die-cast aluminum alloys for automotive applications, magnesium alloys for lightweight powertrains and automotive bodies, and polymer and composite molding technologies.