Mou Sun scite author profile

Mou Sun

5Publications

16Citation Statements Received

89Citation Statements Given

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Beihang University

Publications

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Flight Strategy Optimization for High-Altitude Solar-Powered Aircraft Based on Gravity Energy Reserving and Mission Altitude

Sun

et al. 2020

Applied Sciences

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High-altitude long-duration (HALE) flight capability is one of the ultimate goals pursued by human aviation technology, and the high-altitude solar-powered aircraft (SPA) is the most promising technical approach to achieve this target as well as wide application prospects. Due to the particularity of the energy system, the flight strategy optimization through the storage of gravity potential energy and other methods is a significant way to enhance the flight and application abilities for the SPA. In this study, a flight strategy optimization model has been proposed for the aim of HALE flight capability, which is based on the gravity energy reserving and mission altitude in practical engineering applications. This integrated model contains the five flight path phase model, the three-dimensional kinematic model, aerodynamic model, solar irradiation model and energy store and loss model. To solve the optimization problem of three-dimensional flight strategy, the Gauss pseudo-spectral Method (GPM) was employed to establish and calculate the optimal target as its advantages in treating process constraints and terminal constraints for the multiphase optimization problem. At last, the flight trajectory optimization with minimal battery mass for Zephyr 7 was studied by the GPOPS with some function files in MATLAB. The results indicate that the Zephyr 7 can reduce the battery mass from 16 kg to 12.61 kg for the day and night cycle flight and missions, which equals to increasing the battery specific energy by 23.1%. Meanwhile, the optimization results also show that the attitude angel may contribute to increasing the energy gained by photovoltaic cells. In addition, this optimized flight strategy brings the possibility of monthly or annual continuous flight for SPA as the simulation date is set to the autumnal day.

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Numerical Simulation and Thermal Analysis of Stratospheric Airship

Sun

Yang

et al. 2015

Procedia Engineering

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This paper proposed a mathematical model and numerical model to investigate the output characteristics of photovoltaic (PV) array of stratospheric airship. In addition, considering with the influence of flight time, flight status, flight location, flight height, environmental temperature and other factors on the output power of the PV array, the model of solar radiation, and PV array on the surface of Stratospheric Airship are established. Then, the thermal effects of the PV array on the airship is investigated using CFD/Fluent, based on which the three-dimensional temperature profile of PV array and airship are presented.

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Research on Management Software Design of Energy Storage System for Stratospheric Airship

Sun

Dong

et al. 2017

Procedia Computer Science

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Design and simulation of energy system for stratospheric airships

Sun

Liang

Guo

et al. 2018

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Energy Management Strategy for High-Altitude Solar Aircraft Based on Multiple Flight Phases

Sun

Shan

Sun

et al. 2020

Mathematical Problems in Engineering

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Making use of solar energy to fly is an up-and-coming technology in the human aviation field since solar energy is renewable and inexhaustible, and more and more attention and efforts have been directed to the development of high-altitude solar aircraft (HSA). Due to the technical constraints of the rechargeable battery, the HSA must carry sufficient batteries to meet the flight power consumption at night, which seriously limits the flight endurance of HSA. To solve this contradiction, the paper has proposed a new energy management strategy (EMS) of multiple flight phases for HSA based on the gravitational energy storage and mission altitude, which aims to achieve the goal of long-endurance flight for HSA. The integrated model of this new EMS includes the aerodynamic model, the kinematic model, the solar irradiation model, the battery model, and the energy management model. Compared with the current EMS of level flight, the flight path of HSA in the new EMS has been divided into five phases: the lower altitude level flight at night, the maximum power ascending for mission altitude, the level flight at mission altitude, the maximum power ascending for higher altitude, and the longest gliding endurance. At last, the calculation of the new EMS for Zephyr 7 is studied by MATLAB/Simulink, and the calculation results indicate that about 22.9% of energy surplus can be stored in battery with the new EMS for Zephyr 7 compared with the current EMS, which is equal to reducing the rechargeable battery weight from 16.0 kg to 12.3 kg. Besides, the results of simulation in the four seasons also show that the new EMS is a very promising way to achieve the long-endurance goal for high-altitude HSA when the flight conditions satisfy some constraints like the deficiency of solar flux and the limit of battery mass.

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Mou Sun

Flight Strategy Optimization for High-Altitude Solar-Powered Aircraft Based on Gravity Energy Reserving and Mission Altitude

Numerical Simulation and Thermal Analysis of Stratospheric Airship

Research on Management Software Design of Energy Storage System for Stratospheric Airship

Design and simulation of energy system for stratospheric airships

Energy Management Strategy for High-Altitude Solar Aircraft Based on Multiple Flight Phases

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