The main goal of this project is to enhance the charging system for the existing electric bike. The former group who worked on the bike had a less than ideal charging system that rectified wall voltage at 120 V AC 60 Hz three-phase power down to a suitable voltage for their project. Eventually, this charging led to the damaging of the Optima Yellow Top batteries that we used, meaning that we had to spend a lot of money (approx $1200) just to replace the batteries the motorcycle used before beginning to test our project. Taking the previous groups’ frame, mounting system, batteries, and motor controller, our goal was to improve the charging and peripheral display subsystems to a point where the vehicle could be used more frequently.
Our new charger had the goal of following the specced charging profiles as per Optima’s website while allowing for a shorter charge time and a reconditioning period that should extend the lifetime of the batteries. At an average cost of $160 per battery while using a total of six batteries in the stack, preserving lifetime is of the utmost importance. Well-maintained, a stack of batteries in a Tesla Model S can last up to 10 years. A great deal of engineering goes into allowing those batteries to safely charge and discharge in a way that provides a stable ride while allowing the batteries to live indefinitely.
While electric vehicles are still far from the norm, sound and safe charging practices can go a long way toward making batteries more feasible. Our exercise in controls has shown the need for more reliable and accurate charging systems. A motorcycle provides a unique opportunity to prototype an electric vehicle due to its small size, short usage intervals, and low cost to maintain. As the world turns more toward electrical systems to meet its energy needs, well-designed and precisely engineered battery systems will be necessary to supply the power that the world demands.