Design and Analysis of a Topology-Optimized Quadcopter Drone Frame

Berke Bay; Meltem Eryıldız

doi:10.29109/gujsc.1316791

Research Article

Design and Analysis of a Topology-Optimized Quadcopter Drone Frame

Year 2024, Erken Görünüm, 1 - 1

Berke Bay Meltem Eryıldız

https://doi.org/10.29109/gujsc.1316791

Abstract

This study focuses on the analysis and optimization of a drone frame design to enhance its performance characteristics. The design underwent drop testing, stress analysis, displacement analysis, and flow simulation to evaluate its structural integrity, deformation resistance, and aerodynamic performance. Furthermore, topology optimization techniques were employed to achieve a 30% weight reduction while maintaining the structural integrity of the drone frame. The results of the drop test analysis revealed that Design 2 exhibited lower stress levels compared to Design 1, indicating improved load distribution and structural integrity. However, Design 1 demonstrated lower displacement values, suggesting better resistance to deformation. The flow analysis indicated that Design 1 achieved lower flow velocities, indicating superior propulsion and aerodynamic performance. Through topology optimization, the mass of the drone frame was successfully reduced by 30% without compromising structural integrity. The optimized design exhibited improved stress management, reduced displacement, and slightly higher flow velocities compared to the initial design. These improvements contribute to enhanced agility, maneuverability, and energy efficiency of the drone. The findings of this study highlight the importance of considering stress distribution, displacement, and aerodynamic performance in drone design and optimization. The results provide valuable insights for the development of efficient and reliable drones.

Keywords

Drone, drop test, topology optimization, FEA analysis, flow simulation

Supporting Institution

TÜBİTAK 2209-A - Research Project Support Programme for Undergraduate Students

Project Number

1919B012214339

Thanks

This study was supported with the project number 1919B012214339 under the program of "TÜBİTAK 2209-A - Research Project Support Programme for Undergraduate Students".

References

[1] Sundararaj, S., Dharsan, K., Ganeshraman, J., & Rajarajeswari, D. Structural and modal analysis of hybrid low altitude self-sustainable surveillance drone technology frame. Materials Today: Proceedings, 37 (2021) 409-418.
[2] Mohsan S.A.H., Khan M.A., Noor F., Ullah I., & Alsharif M.H. Towards the unmanned aerial vehicles (UAVs): A comprehensive review. Drones, 6(6) (2022) 147-149.
[3] Agarwal H., Singhal A., & Raj K.H. 3D Printed Quadcopter. In Advances in Systems Engineering: Select Proceedings of NSC 2019. Singapore: Springer, (2021) 491-499,
[4] Zhu J.H., Zhang W.H., & Xia L. Topology optimization in aircraft and aerospace structures design. Archives of Computational Methods in Engineering, 23 (2016) 595-622.
[5] Bajirao M.S., Vijay K.P., Sudhir G.R., Pandurang Z.H., & Prasanna R. Design Optimization of Drone Frame. International Journal of Mechanics and Design, 8(1) (2022) 25-32.
[6] Satam S., Topology Optimization of UAV Drone frame. https://www.linkedin.com/pulse/topology-optimization-uav-drone-frame-sanay-satam/?trackingId=rwnSsEkvRq%2BvfnaCQMSFXw%3D%3D
[7] Nvss S., Esakki B., Yang L.J., Udayagiri C., & Vepa K.S. Design and development of unibody quadcopter structure using optimization and additive manufacturing techniques. Designs, 6(1) (2022) 8-12.
[8] Bright J., Suryaprakash R., Akash S., & Giridharan A. Optimization of quadcopter frame using generative design and comparison with DJI F450 drone frame. In IOP Conference Series: Materials Science and Engineering, 1012(1) (2021) 012019.
[9] Dev, P. K., Balaji, C., & Gurusideswar, S. Material characterization of sugarcane bagasse/epoxy composites for drone frame material. Materials Today: Proceedings, 68 (2022) 2586-2590.
[10] Anand, S., & Mishra, A. K. High-Performance Materials used for UAV Manufacturing: Classified Review. International Journal of All Research Education and Scientific Methods, 10(7) (2022) 2811-2819.
[11] Shelare, S., Belkhode, P., Nikam, K. C., Yelamasetti, B., & Gajbhiye, T. A payload based detail study on design and simulation of hexacopter drone. International Journal on Interactive Design and Manufacturing, 18 (2023) 1-18.
[12] Husaini, H., Putra, D. I. O., Syahriza, S., & Akhyar, A. Stress and strain analysis of UAV hexacopter frame using finite element method. In AIP Conference Proceedings, 2613 (2023), 1-8.
[13] Yap, Y. L., Toh, W., Giam, A., Yong, F. R., Chan, K. I., Tay, J. W. S., & Ng, T. Y. Topology optimization and 3D printing of micro-drone: Numerical design with experimental testing. International Journal of Mechanical Sciences, 237 (2023), 107771.
[14] Parsons, J. S., Goodson, R.E., & Goldschmied, F.R. Shaping of axisymmetric bodies for minimum drag in incompressible flow. Journal of Hydronautics, 8(3) (1974) 100-107.
[15] Bras M., Warwick S., & Suleman A. Aeroelastic evaluation of a flexible high aspect ratio wing UAV: Numerical simulation and experimental flight validation, Aerospace Science and Technology, 122 (2022) 107400.
[16] Quintana, A., Graves, G., Hassanalian, M., & Abdelkefi, A. Aerodynamic analysis and structural integrity for optimal performance of sweeping and spanning morphing unmanned air vehicles. Aerospace Science and Technology, 110 (2021) 106458.
[17] Bergonti, F., Nava, G., Wüest, V., Paolino, A., L'Erario, G., Pucci, D., & Floreano, D. Co-Design Optimisation of Morphing Topology and Control of Winged Drones. arXiv preprint, 2309 (2023) 1-7.
[18] Ajanic, E., Feroskhan, M., Mintchev, S., Noca, F., & Floreano, D. Bioinspired wing and tail morphing extends drone flight capabilities. Science Robotics, 5(47) (2020) 1-12.
[19] Zhu H., Nie H., Zhang L., Wei X., & Zhang M. Design and assessment of octocopter drones with improved aerodynamic efficiency and performance. Aerospace Science and Technology, 106 (2020) 106206.
[20] Papadopoulos, C., Mitridis, D., & Yakinthos, K. Conceptual design of a novel unmanned ground effect vehicle (ugev) and flow control integration study. Drones, 6(1) (2022) 25-31.

Year 2024, Erken Görünüm, 1 - 1

Berke Bay Meltem Eryıldız

https://doi.org/10.29109/gujsc.1316791

Abstract

Project Number

1919B012214339

References

[1] Sundararaj, S., Dharsan, K., Ganeshraman, J., & Rajarajeswari, D. Structural and modal analysis of hybrid low altitude self-sustainable surveillance drone technology frame. Materials Today: Proceedings, 37 (2021) 409-418.
[2] Mohsan S.A.H., Khan M.A., Noor F., Ullah I., & Alsharif M.H. Towards the unmanned aerial vehicles (UAVs): A comprehensive review. Drones, 6(6) (2022) 147-149.
[3] Agarwal H., Singhal A., & Raj K.H. 3D Printed Quadcopter. In Advances in Systems Engineering: Select Proceedings of NSC 2019. Singapore: Springer, (2021) 491-499,
[4] Zhu J.H., Zhang W.H., & Xia L. Topology optimization in aircraft and aerospace structures design. Archives of Computational Methods in Engineering, 23 (2016) 595-622.
[5] Bajirao M.S., Vijay K.P., Sudhir G.R., Pandurang Z.H., & Prasanna R. Design Optimization of Drone Frame. International Journal of Mechanics and Design, 8(1) (2022) 25-32.
[6] Satam S., Topology Optimization of UAV Drone frame. https://www.linkedin.com/pulse/topology-optimization-uav-drone-frame-sanay-satam/?trackingId=rwnSsEkvRq%2BvfnaCQMSFXw%3D%3D
[7] Nvss S., Esakki B., Yang L.J., Udayagiri C., & Vepa K.S. Design and development of unibody quadcopter structure using optimization and additive manufacturing techniques. Designs, 6(1) (2022) 8-12.
[8] Bright J., Suryaprakash R., Akash S., & Giridharan A. Optimization of quadcopter frame using generative design and comparison with DJI F450 drone frame. In IOP Conference Series: Materials Science and Engineering, 1012(1) (2021) 012019.
[9] Dev, P. K., Balaji, C., & Gurusideswar, S. Material characterization of sugarcane bagasse/epoxy composites for drone frame material. Materials Today: Proceedings, 68 (2022) 2586-2590.
[10] Anand, S., & Mishra, A. K. High-Performance Materials used for UAV Manufacturing: Classified Review. International Journal of All Research Education and Scientific Methods, 10(7) (2022) 2811-2819.
[11] Shelare, S., Belkhode, P., Nikam, K. C., Yelamasetti, B., & Gajbhiye, T. A payload based detail study on design and simulation of hexacopter drone. International Journal on Interactive Design and Manufacturing, 18 (2023) 1-18.
[12] Husaini, H., Putra, D. I. O., Syahriza, S., & Akhyar, A. Stress and strain analysis of UAV hexacopter frame using finite element method. In AIP Conference Proceedings, 2613 (2023), 1-8.
[13] Yap, Y. L., Toh, W., Giam, A., Yong, F. R., Chan, K. I., Tay, J. W. S., & Ng, T. Y. Topology optimization and 3D printing of micro-drone: Numerical design with experimental testing. International Journal of Mechanical Sciences, 237 (2023), 107771.
[14] Parsons, J. S., Goodson, R.E., & Goldschmied, F.R. Shaping of axisymmetric bodies for minimum drag in incompressible flow. Journal of Hydronautics, 8(3) (1974) 100-107.
[15] Bras M., Warwick S., & Suleman A. Aeroelastic evaluation of a flexible high aspect ratio wing UAV: Numerical simulation and experimental flight validation, Aerospace Science and Technology, 122 (2022) 107400.
[16] Quintana, A., Graves, G., Hassanalian, M., & Abdelkefi, A. Aerodynamic analysis and structural integrity for optimal performance of sweeping and spanning morphing unmanned air vehicles. Aerospace Science and Technology, 110 (2021) 106458.
[17] Bergonti, F., Nava, G., Wüest, V., Paolino, A., L'Erario, G., Pucci, D., & Floreano, D. Co-Design Optimisation of Morphing Topology and Control of Winged Drones. arXiv preprint, 2309 (2023) 1-7.
[18] Ajanic, E., Feroskhan, M., Mintchev, S., Noca, F., & Floreano, D. Bioinspired wing and tail morphing extends drone flight capabilities. Science Robotics, 5(47) (2020) 1-12.
[19] Zhu H., Nie H., Zhang L., Wei X., & Zhang M. Design and assessment of octocopter drones with improved aerodynamic efficiency and performance. Aerospace Science and Technology, 106 (2020) 106206.
[20] Papadopoulos, C., Mitridis, D., & Yakinthos, K. Conceptual design of a novel unmanned ground effect vehicle (ugev) and flow control integration study. Drones, 6(1) (2022) 25-31.

There are 20 citations in total.

Details

Primary Language	English
Subjects	Machine Design and Machine Equipment, Mechanical Engineering (Other)
Journal Section	Tasarım ve Teknoloji
Authors	Berke Bay This is me 0000-0002-0164-2473 Meltem Eryıldız 0000-0002-2683-560X
Project Number	1919B012214339
Early Pub Date	March 27, 2024
Publication Date
Submission Date	June 19, 2023
Published in Issue	Year 2024 Erken Görünüm

Cite

APA	Bay, B., & Eryıldız, M. (2024). Design and Analysis of a Topology-Optimized Quadcopter Drone Frame. Gazi University Journal of Science Part C: Design and Technology1-1. https://doi.org/10.29109/gujsc.1316791

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e-ISSN:2147-9526