Electric buses are an eco-friendly alternative to diesel. With several project partners, Fraunhofer researchers have developed a concept to swiftly recharge buses while they operate routes. System testing in Dresden has been underway since November last year.
Electric vehicles are supposed to make urban transport more environmentally friendly in the future. Using buses for short-range public transportation is a good way of helping to implement this vision: fixed routes and stops make it easier to plan and provide the requisite infrastructure. In addition, public transport sets an example to the wider public. “However, electric buses will only gain acceptance if they adapt to established operational practices and do not create a need for additional vehicles or personnel,” says Dr. Thoralf Knote from the Fraunhofer Institute for Transportation and Infrastructure Systems IVI. This poses some challenges: regular urban public transport buses travel up to 400 kilometers a day without returning to the depot. To supply the electric energy this requires, huge batteries would be needed, for which there is not enough space available in a bus. The alternative is to quickly recharge the vehicle’s battery while it is serving its route – for example, while the bus is waiting at the terminus. This requires high charging capacity.
Contact system for recharging fitted to roof of bus
Working with several partners in the EDDA Bus project, Fraunhofer scientists have developed a solution that permits fast, uncomplicated recharging. EDDA Bus is part of the Fast Charging Systems for Electric Buses in Public Transport joint research project funded by the German Federal Ministry of Education and Research (BMBF). The solution is based on four core technologies: the Dresden-based company M&P GmbH designed a charging station with very high charging capacities; HOPPECKE Advanced Battery Technology GmbH supplied special batteries designed for such high power capacities; Vossloh Kiepe GmbH was responsible for adapting the power electronics; and finally, the heart of the development work is the contact system located on the roof of the bus, which was realized by Fraunhofer IVI together with Schunk Bahn- und Industrietechnik GmbH.
For the contact head, six powerful contacts were housed in a small installation space. There are two contact poles – one positive, one negative – on each side. Fitted to the top, there is an earth contact and a control pilot, which monitors the earthing. “This means our system meets the most stringent safety requirements,” explains Knote. Schunk Bahn- und Industrietechnik GmbH developed heat-stable components for the contact system. This was necessary because, in contrast to streetcars for instance, where energy is transferred while the vehicle is moving, transferring power to a stationary vehicle generates high local temperatures that would damage conventional components.
The charging process is very straightforward: “We don’t want to burden drivers with extra tasks,” emphasizes Knote. All drivers have to do is position the bus beneath the contact hood at the charging station. While doing so, they can use a marker at the edge of the curbstone for orientation. An acoustic signal assists drivers when positioning the bus at the stop. To ensure some leeway, the contact head adjusts itself on a slide rail and then docks with the contact hood. The charging process begins automatically. During charging, drivers can follow the battery’s charge status on a display. If required, the charging process can also be interrupted.
EDDA Bus passed its first practice assignments in regular service in Dresden with flying colors. Following the test phase, the vehicle served a more challenging route of around 20 kilometers in length and containing several hills. “Once again in this second phase, the results have exceeded our expectations,” says a delighted Knote. The average energy consumption is 1.19 kWh per kilometer – it should be noted here, however, that the bus is not heated electrically, but using engine-independent diesel heating. Recharging takes less than 6.5 minutes.