As the DALER is being designed to be used in search and rescue operations, the duality of modes of locomotion will be used principally to fly long distances to survey large spaces in a short timespan, and then to walk into dangerous or inaccessible areas.
One of the main issues in using a flying robot to navigate in small areas when walking is the surface areas of the wings. On a flying wing shaped robot, in order to maintain flight the wings must be wide, meaning that they cannot fit into smaller spaces. By observing D. rotundus the team has produced an elegant solution where a foldable actuator is used to allow the wings to fold into a smaller space and to rotate around a hinge attaching the whegs to the body, allowing walking. D. rotundus doesn’t look very pretty when it walks, but it has certainly perfected the art of using all four limbs for two purposes.
In order to design the robot, the team had to first designate the primary mode of locomotion – in this case flight, as the DALER will cover the longest distances this way. With this in mind, a method of using the wings also for walking was devised in a way that does not give extra weight. The resulting wing is equipped with wingerons on the tip which rotate to allow the robot to “walk” when it is on the ground.
An issue in creating a fixed wing drone capable of walking on the ground is with the morphology due to the different centre of mass requirements for the two modes of locomotion. For this reason the DALER is equipped with foldable wings, so much like the bat that inspired it, the DALER can walk on its haunches.
The team have found the optimal distance between the centre of mass of the robot and the axis of rotation of the wingerons, in order to minimize the cost of transport (i.e. energy efficiency) and allow the DALER to reach 20m/s in the air and 6cm/s on the floor, with a maximum step distance of 6cm.
It is hoped that a future application of the DALER might be to find victims in dangerous areas after a natural disaster. The DALER can be remotely deployed to fly to an affected area, and then can walk through a disaster zone (e.g. a damaged building) to locate victims, meaning that human rescue teams can concentrate their efforts where they are needed, rather than using time to search for victims in a dangerous environment. Future development of the DALER will include the possibility to hover and to take off autonomously from the ground in order to allow the robot to return to the air and come back to base after the mission.