Search Results

With a significant increase in awareness of safety and sustainability among the automobile original equipment manufacturers and end users, every car manufacturer is looking for lightweight, safe and cost-effective solutions for every unit present in their vehicle. The latter gets much more focus in developing countries, where the automobile market is extremely cost sensitive. Further, with implementation of the proposed global technical regulations on pedestrian safety in the near future and low-speed vehicle damageability requirements, demand for a low-cost, lighter and safer bumper system is ever increasing. This paper focuses on development of a unique thermoplastic energy-absorbing device for vehicle bumpers. Conventionally, major energy absorbing members of these bumper systems consist of three separate pieces: energy absorber, bumper beam and crash cans. A hybrid approach based on logical reasoning and topology optimization is used to conceive the design.

Automotive industry is looking for weight out options to increase the fuel efficiency of automobiles. Thermoplastics usage is increasing to reduce the dead weight of different automotive components. Traditional steering wheel can be replaced with thermoplastic to make it lighter without compromising its performance requirements. Thermoplastic steering wheel offers overall reduction in cost as well as significant reduction in mass. In addition, thermoplastic steering wheel also offers part integration and styling flexibility. As steering wheel has to meet variety of loading criteria (vibration, static loading, dynamic loading and fatigue), the overall design is a multi objective optimization process. Major challenges of thermoplastic steering wheel are to design the effective model for any particular wheel geometry domain defined by OEM's (Original Equipment Manufacturer) styling studios.

Automotive steering wheel (SW) is generally manufactured with metal armature and polyurethane / polypropylene (PU / PP) overmolding. The metal armature is used to provide structural stiffness and strength while PU / PP foam gives shape, touch and feel. Developed market use cast Magnesium or Aluminum as armature material, however emerging markets use steel for armature construction. With additional requirements (airbag integration, functional integration, aesthetics, compact and light weigh) being added to steering wheel, the steering wheel design is becoming more and more complex in nature. Thermoplastic SW offers competitive stiffness, impact, ductility and chemical resistance characteristics needed for the global automotive markets. A thermoplastic SW had been developed from a unique recyclable polycarbonate.

Automobile manufacturers, designers, and cockpit system integrators are in constant search of solutions that reduce the number of interruptions across interior surfaces. Engineers require that this solution be efficient in terms of reliability, parts complexity, packaging space, and cost. The purpose of this paper is to describe the design and development of a cost effective, simplified seamless passenger airbag door system with an integrated chute for instrument panels. Through engineering thermoplastic material property advantages and scoring designs, this solution has a construction which may meet both styling and performance criteria while eliminating component parts such as a separate airbag chute, hinges, tethers, brackets, inserts, fabrics, and fasteners.

Automobile manufacturers, designers, and cockpit systems integrators are in constant search for solutions in instrument panel designs that reduce the number of interruptions across styled interior contours. Eliminating the breaks across surfaces caused by functional seams or styling lines in traditional passenger airbag doors provides cleaner, more desirable interior aesthetics. Engineers require that this solution be efficient in terms of reliability, parts complexity, packaging space, and cost. The purpose of this paper is to describe the design and development of a cost effective, simplified-architecture seamless passenger airbag door system for instrument panels. Through engineering thermoplastic material property advantages and scoring designs, this solution has a construction which may meet both styling and performance criteria while eliminating component parts such as hinges, tethers, brackets, inserts, fabrics, and fasteners.