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The importance of style design has increased tremendously in Indian two-wheeler market and at the same time new styles become obsolete in a short period. This rapidly changing market trend demands simulation methodology to evaluate the component for various loads in the design stage itself to reduce the product development cycle time. Aluminum cast footrest is preferred for better looks compared to sheet metal or tubular footrest. Normal load carried by the footrest is quite low but consideration should be given for severe loads experienced by the footrest during adverse conditions, like for example, hitting against potholes at high speed. In this current work an initial design of a die-cast footrest bracket with a particular geometric configuration and material was analyzed using finite element analysis for static and dynamic loads.

Scooters are becoming increasingly popular in India. Competition in this segment has forced the product developers to put focus on development time reduction and quality improvement. Any physical failure of critical parts in the actual customer usage conditions can delay the product launch. The present study is about simulation of failure of crankcase during field trials. This involved creation of Finite Element model, evolution of proper loading and boundary conditions which capture the failure area, development of a static and an accelerated dynamic test in laboratory to reproduce the field failure, the optimization of the crankcase design through FEM to achieve acceptable stress values at critical areas and validation of these results through newly developed laboratory tests. Simultaneously, field trials, which initially produced this failure were conducted and no failures were observed. Thus, the current study has saved time of actual field trials (3∼4 weeks) after the redesign.

Two wheelers are very popular as means of transportation in ASIA. It is also used as load carrier in some places. Chassis frame is a very critical part of a two wheeler taking most of the loads coming from the roads. During the design and development stage, structural integrity of the frame needs to be established. Bump test is one of the critical life tests performed on the vehicle for evaluating the fatigue life of the frame. Normally, three to four iterations take place before frame passes this bump test. This is a time taking test process (1week per iteration) and does not guarantee the end result. In the new approach, the bump test simulation is made using ADAMS software. The ADAMS model is validated by using the axle accelerations measured in the physical bump test. Subsequently, the loads obtained from ADAMS model are used in FEM software and the stresses are predicted. The stress pattern helped in identifying the critical areas.

Fatigue life prediction is the most promising technique for drastic reduction of durability evaluation time, which is a critical element in the product development cycle. By using this technique, it is possible to reduce development time and cost, identify failure modes early in the development cycle, and design the component for optimum life. This paper discusses the optimisation of an important two-wheeler component namely, the center stand, using fatigue life prediction techniques. Also, it aims at establishing correlation among various customer usage patterns, accelerated endurance tests, and fatigue life prediction results using both experimental data and finite element (FE) models.

Two wheelers are becoming increasingly popular in India. Competition in this segment has made the product developers to develop the vehicles with short time without compromising durability. Vibration Fatigue Analysis is an advanced technique to evaluate the life of components undergoing vibration, thereby the drastic reduction in durability evaluation time. Front fender is a styling component generally made with plastic material and undergoes vibrations. Therefore, it is very difficult to design the fender based only on static load cases. Vibration fatigue analysis using Finite Element Method (FEM) is used to ensure the durability in design stage itself. Various customer usage modes of the vehicle are considered. Accelerometers and strain gauges are mounted on the fender on appropriate locations. First, the instrumented fender is mounted on the electro dynamic shaker. The fender is excited with sinusoidal inputs.