This website uses cookies primarily for visitor analytics. Certain pages will ask you to fill in contact details to receive additional information. On these pages you have the option of having the site log your details for future visits. Indicating you want the site to remember your details will place a cookie on your device. To view our full cookie policy, please click here. You can also view it at any time by going to our Contact Us page.

Electric flight from Mannheim to Berlin in a 19-seater aircraft

18 February 2020

The German Aerospace Centre (DLR) has teamed up with Bauhaus Luftfahrt to work on the CoCoRe (Cooperation for Commuter Research) project, which examines the possibilities and potential for hybrid-electric 19-seater aircraft.

Conceptual study of a hybrid-electric 19-seater aircraft as part of the CoCoRe research project (Image: DLR/BHL)

This has revealed that electric propulsion systems can be used to reduce carbon dioxide emissions from this class of aircraft on short, frequently flown routes over distances of up to 217 miles. In the future, this distance range will also include air taxi connections from airports in less well-connected, medium-sized cities.

Batteries over landing gear nacelles

Today, approximately 3,000 commuter-class aircraft are in use worldwide, but only just over a dozen new 19-seaters have been delivered to the civilian sector annually in recent years. "In our study, we investigated a sample configuration that, with a few modifications, is based closely on the 19-seater Do 228 and, in particular, the Jetstream 31, which are currently flying," says Project Manager Wolfgang Grimme of the DLR Institute of Air Transport and Airport Research. In their design, the researchers put a particular focus on modifying the landing gear nacelles, which were extended above the wings to accommodate easily replaceable battery packs. "This allows us to place the weight of the batteries, which are comparatively heavy, exactly where it is most convenient during take-off and landing – directly above the landing gear. This also means that empty batteries can be replaced quickly and easily."

The researchers' concept for a range of 124 miles flown using electric power alone is limited by the weight of the batteries, at two tonnes for a total take-off weight of 8.6 tonnes. The range can be extended to over 621 miles by using two range extenders that take the form of gas turbines that can be coupled to and decoupled from the propellers. "According to our research, 56 percent of 19-seaters worldwide fly distances of less than 124 miles and 83 percent fly less than 217 miles. This usage pattern means that the combination of fully electric flight enhanced by range extenders will prevent the majority of carbon dioxide emissions caused by commuter aircraft," explains Annika Paul of Bauhaus Luftfahrt. The range extender is also crucial to the safety of this kind of electric aircraft, since if the aircraft needs to divert to a more distant alternative airport in the event of poor weather conditions or other problems, this allows it to cover the necessary additional distance. "The range extenders also enable longer fully electric flights, as the battery does not have to be used for reserves," adds Georgi Atanasov of the DLR Institute of System Architectures in Aeronautics.

A purely electric range of over 124 miles with the same battery weight is also expected to be possible with potential improvements in the storage capacity of batteries. In addition, the particularly cost-intensive development of new aircraft configurations, for example with numerous distributed electrically driven propellers on the wings in combination with a modern, lighter structural design, would also extend the range of fully electric flight. For these reasons, fully electric flights of over 248 miles are entirely conceivable in the future.

Direct connections to medium-sized cities

In addition to analysing the technical potential, as part of the CoCoRe project the researchers also carried out market analysis of possible areas of application for electric commuter aircraft. Together with widespread conventional use as small commuter aircraft for remote regions with a low volume of passengers, such as in Canada, the researchers also identified a need for medium-sized cities in Europe that currently have inadequate direct connections, including to major urban areas. An economically sustainable regional flying taxi service from smaller airports may be possible for these cities. Examples of such routes within Germany include Mannheim to Berlin, Bremen to Berlin and Münster to Leipzig. Until now, the low figure of around 1000 charge/discharge cycles for batteries and comparatively low carbon dioxide prices have posed an economic challenge in such scenarios when compared with conventionally powered commuter aircraft. If these factors improve in future, the economic prospects of electric aircraft will also increase.

Print this page | E-mail this page