Abstract
A proton exchange membrane (PEM) fuel cell is particularly considered as a prime power supply for a fuel cell-powered unmanned aircraft system (UAS) as it possesses a very high-power density in comparison with other fuel cell types, hence a high potential to be used for high altitude long endurance (HALE) UAS flights. This paper will focus on examining the design requirements for the UAS-based 1 kW PEM fuel cell for high altitude operation (10–11 km), which can be correlated into a quantitative data to produce a design constraints diagram. The maximum take-off mass, endurance, and geometries for potential UAS design are estimated. Four different geometrical design profiles are developed and presented. The resulting geometries are analysed and the design parameters of the estimated 1 kW design yielded an aircraft of maximum take-off mass 34.8 kg, wingspan of 10.4 m, cruising speed 20 m/s, stall speed 11.23 m/s, and maximum endurance of 4 h. The constraint diagram deploys these assumptions as well as values generated through the design calculations to form a possible design of which the 1 kW UAS falls slightly outside of the possible design space; this is due to the minimum thrust-to-weight ratio required to achieve the desired service ceiling; however, further alterations and adjustments on the design and mission requirements are provided to place the design of the UAS within the possible design space.
Highlights
An unmanned aircraft system (UAS) is an integration of the unmanned aerial vehicle (UAV) and a control system which allows users to remote control the aircraft
This paper will focus on examining the design requirements for an unmanned aircraft system based on 1-kW proton exchange membrane (PEM) fuel cell for high-altitude operation (10–11 km), which can be correlated into a quantitative data to produce a design constraints diagram, where there is a limited research in this area for small-scale UAS which is powered by the relatively new power source
The design requirements of a UAS system powered by a 1 kW PEM fuel cell system for high-altitude operation (10–11 km) are presented, which has been correlated into the design constraints diagram
Summary
An unmanned aircraft system (UAS) is an integration of the unmanned aerial vehicle (UAV) and a control system which allows users to remote control the aircraft. A PEM fuel cell-powered UAS could have a greater balance of the desired design requirements (e.g., endurance and robust) than a solar or lithium-ion-powered UAS. This paper will focus on examining the design requirements for an unmanned aircraft system based on 1-kW PEM fuel cell for high-altitude operation (10–11 km), which can be correlated into a quantitative data to produce a design. The impact of changing the capacity of the power system on the design requirements of the UAS and the design constraints will be investigated, the estimation of the power required for each flying segment and the potential endurance of 1 kW fuel cell system, and the impact of take-off distance up on the wing loading and stall speed of the proposed UAS design, and different wing geometries, will be examined and addressed
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
