Hybrid energy systems in unmanned aerial vehicles

Purpose The presented research is carried out in reaction to the soaring costs of fuel and tight control over environmental issues such as carbon dioxide emissions and noise. The purpose of this paper is to study the feasibility of applying the environmental-friendly energy source in an unmanned aer...

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Bibliographic Details
Published in:Aircraft engineering 2019-07, Vol.91 (5), p.736-746
Main Authors: Mazur, Anna Maria, Domanski, Roman
Format: Article
Language:English
Subjects:
Aircraft
Aircraft performance
Altitude
Aviation
Carbon dioxide
Controllability
Efficiency
Electric propulsion
Endurance
Energy
Energy consumption
Energy management
Energy resources
Energy sources
Feasibility studies
Fuel cells
Hybrid propulsion systems
Hybrid vehicles
Hybridization
Hydrogen
Industrial plant emissions
Laboratories
Lithium-ion batteries
Noise
Noise levels
Photovoltaic cells
Power plants
Propulsion system design
R&D
Rechargeable batteries
Research & development
Solar cells
Stability
Surveillance
Unmanned aerial vehicles
Vehicles
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Summary:Purpose The presented research is carried out in reaction to the soaring costs of fuel and tight control over environmental issues such as carbon dioxide emissions and noise. The purpose of this paper is to study the feasibility of applying the environmental-friendly energy source in an unmanned aerial vehicles (UAVs) propulsion system. Design/methodology/approach Currently, the majority of UAVs are still powered by conventional combustion engines. An electric propulsion system is most commonly found in civilian micro and mini UAVs. The UAV classification is reviewed in this study. This paper focuses mainly on application of electric propulsion systems in UAVs. Investigated hybrid energy systems consist of fuel cells, Li-ion batteries, super-capacitors and photovoltaic (PV) modules. Current applications of fuel cell systems in UAVs are also presented. Findings The conducted research shows that hybridization allows for better energy management and operation of every energy source onboard the UAV within its limits. The hybrid energy system design should be created to maximize system efficiency without compromising the performance of the aircraft. Practical implications The presented study highlights the reduction of the energy consumption, necessary to perform the mission and maximizing of the endurance with simultaneous decrease in emissions and noise level. Originality/value The conducted research studies the feasibility of implementing the environmental-friendly hybrid electric propulsion systems in UAVs that offers high efficiency, reliability, controllability, lack of thermal and noise signature, thus, providing quiet and clean drive with low vibration levels. This paper highlights the main challenges and current research on fuel cell in aviation and draws attention to fuel cell – electric system modeling, hybridization and energy management.
ISSN:1748-8842
1758-4213
DOI:10.1108/AEAT-08-2018-0218