# Design of Glider Airborne Wind Turbine

**Authors:** Salih N. Akour, Tareq Al-Soud, Rami Al-Balbeisi, Ali Al-Kabneh, Wesam S. Akour

PMC · DOI: 10.1155/tswj/8814936 · The Scientific World Journal · 2025-12-05

## TL;DR

This paper presents a glider-based airborne wind turbine designed to harness high-altitude wind energy efficiently and stably.

## Contribution

The novel contribution is the design and analysis of a glider-mounted wind turbine system for high-altitude energy harvesting.

## Key findings

- The glider design successfully meets structural and aerodynamic performance objectives.
- Wind turbine rotation eliminates overshooting in lift and drag forces during flight.
- Stability is achieved within 0.2 seconds with a forward center of gravity.

## Abstract

Producing clean and renewable energy is the aim of many countries worldwide. Wind is one of the most vast renewable energy sources. High‐quality wind is available at high altitudes. To harvest such energy, wind turbines should reach such high altitudes. An airborne wind turbine system is conceptually designed to harvest wind energy at relatively high altitudes regardless of location. A glider is designed to carry a small wind turbine mounted at its nose. The glider is connected to the ground through a tether and electric wires to transmit power from the flying generator to the ground station. The resulting model airplane has a square wing with a Selig high‐lift, low‐Reynolds‐number airfoil section (S1223‐il) and a wingspan of 2 m. Tail airfoil sections are NASA airfoil 0012. The total mass of the glider is 3.35 kg. The aerodynamic design analysis is performed through CFD simulation. The forces and loads obtained from the CFD analysis are transferred to finite element software to perform structural analysis. Overshooting in lift and drag forces occurs in both cruise and nose‐up flights. Such overshoot behavior is eliminated by the wind turbine rotation effect. The developed model meets the design objectives successfully, since both structural and CFD analyses show the aircraft′s capability to carry the load. The CFD results prove that the glider is stable when the center of gravity is forward, and stability is achieved within 0.2 s. When the wind turbine is installed, there is slight oscillation in the lift force, but stability is reached within the design target of 0.2 s.

## Full-text entities

- **Chemicals:** Turbine (MESH:C524822)

## Full text

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## Figures

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## References

32 references — full list in the complete paper: https://tomesphere.com/paper/PMC12767584/full.md

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Source: https://tomesphere.com/paper/PMC12767584