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In this paper, an optimization method is proposed to improve the efficiency of a transmission equipped electric vehicle (EV) by optimizing gear shift strategy. The idea behind using a transmission for EV is to downsize the motor size and decrease overall energy consumption. The efficiency of an electric motor varies with its operating region (speed/torque) and this plays a crucial role in deciding overall energy consumption of EVs. A lot of work has been done to optimize gear shift strategy of internal combustion engines (ICE) based automatic transmission (AT), and automatic-manual transmissions (AMT), but for EVs this is still a new area. In case of EVs, we have an advantage of regeneration which makes it different from the ICE based vehicles. In order to maximize the efficiency, a heuristic search based algorithm - Genetic Algorithm (GA) is used.

There is an increased use of elastomers in the automotive industry for sealing, noise isolation, load dampening, insulation, etc., because of their key properties of elasticity and resilience. Elastomers are used in supercharger application for dampening the torsional fluctuation from the engine, to reduce noise issues. Finite element modeling of elastomers is challenging because of its non-linear behavior in different loading directions. It also undergoes very large elemental deformation (~up to 200%), which results in additional complexities in getting numerical convergence. Finally, it also exhibits viscous and elastic behavior simultaneously (viscoelastic effect) and it undergoes softening with progressive cyclic loading (Mullins effect). The present study deals with the characterization of elastomers for its modeling in commercial finite element software packages and verification of some predicted design parameters with physical testing.

Creep is responsible for creating time dependent changes in product dimensions and reducing strength that could affect the ability of products to resist design loads. Creep behavior is an important design consideration for polymers as this phenomenon is observed at very low temperatures compared to metals. Literature suggests many mathematical models to represent this complex creep phenomenon; however they are limited to most common polymers. Today's automotive industry is equipped with state of the art polymer materials considering specific design requirements from the stake holders. The current study is focused on the engine oil pan and its sealing requirements for the automotive business. Computer Aided Engineering (CAE) plays a very critical role in today's quest to reduce the design cycle and testing time.

The fundamental features in designing a valve gear are discussed in this paper. Covered are: valve types; operating mechanisms; valve gear design considerations; and component design considerations such as valves, valve guides, spring retainers and locks, the cam follower, the camshaft, and valve springs.

The bending fatigue, charpy impact, impact fatigue, and metallurgical properties of carburized 8620, EX 10, EX 15, and 1524 steel gears were evaluated to determine if equivalent hardenability is a criterian sufficient to merit the substitution of 8620 with EX 10 and EX 15 for gearing applications. Tests run on actual gear teeth using a unique test fixture show that the impact requirements of each application must be considered. Sufficient samples should be tested to insure that neither the substitute steel nor the heat treatment have reduced the performance under impact loading.

Exhaust valve guttering is a corrosive process that takes place on the valve seat face. Detroit Diesel Allison Division of General Motors and Eaton Corporation have developed an accelerated test to gutter exhaust valves. The test was used to rank seven factors considered to be significant oil consumption, lubrication oil ash content and injector timing were found to be the major contributors to guttering.

Optimization of vehicle air conditioning performance at various drive cycles and ambient conditions can be achieved by regulating and distributing the refrigerant flow entering evaporators. Thermostatic expansion valve (TXV), as a flow control device, has been a key element in improving vehicle A/C system operating efficiency and maximizing cooling capacity. Three scenarios are addressed in this paper: (a) the selection of TXVs for a sports utility vehicle (SUV) climate control system, in which a front HVAC unit and an auxiliary HVAC unit are installed; (b) the methodology of developing a goal-oriented criterion for identifying the TXV combination to fulfill the optimization of A/C system performance; and (c) the analytical and experimental evaluation of vehicle cooling performance by varying TXV combinations in various vehicle operating modes.

In order to determine the seizure limit of the main bearings of passenger vehicles under actual operating conditions, evaluations were conducted in environments containing noise factors (Various factors which designer cannot adjust and which make function vary were defined as noise factors in this paper.) [1,2] It was shown that noise factors have an effect on seizure limit performance in relation to performance under ideal test conditions (test conditions in which no noise is present). In relation to oil properties, the results showed that a reduction in viscosity as a result of dilution affected seizure limit performance. In relation to the shape of the sliding sections of the test shaft, seizure limit performance declined in a shaft in which the central section was swollen (“convex shaft” below).

We developed a windshield washer system that enhances washing performance while maintaining low consumption of windshield washer fluid. The system reduces user stress by shortening the amount of time required to remove dirt and maintaining visibility through the windshield. We analyzed the mechanism through which the windshield wiper and windshield washer remove dirt from the glass surface to improve cleaning efficiency. The mechanism consists of a sequence in which the windshield washer fluid splashes down on the glass surface and lifts dirt which is then wiped away by the windshield wiper blade. We defined the amount of windshield washer fluid needed and the time from splashdown to wiping required to lift dirt and wipe it away with the wiper. Based on this mechanism, we developed a wiper arm with built-in washer nozzles.