UAS Design
Niveau
Beginner
Lernergebnisse der Lehrveranstaltungen/des Moduls
Upon completing this course, students will be able to:
- Master Aerodynamic Principles for Drones: Explain how aerodynamic principles such as lift, drag, thrust, and weight management apply to drone design; optimize flight performance and efficiency by applying these aerodynamic principles in drone development.
- Select and Integrate Materials and Structures: Identify appropriate materials for drone construction, considering strength, weight, and durability trade-offs; design drone structures that effectively accommodate selected materials while meeting design specifications.
- Demonstrate Understanding of the Fundamentals of Additive Manufacturing Processes: Describe additive manufacturing processes relevant to drone design, including fused deposition modeling (FDM), selective laser sintering (SLS), and stereolithography (SLA); explain the principles of these processes in the context of drone manufacturing.
- Apply Design for Additive Manufacturing (DfAM) Principles: Implement DfAM principles to optimize drone designs for weight reduction, part consolidation, and performance enhancement; leverage additive manufacturing capabilities to improve structural geometries and overall design efficiency.
- Select Materials for Additive Manufacturing: Evaluate and select appropriate materials for drone components based on their mechanical properties, weight, durability, and compatibility with additive manufacturing processes; justify material choices by assessing their suitability for specific drone parts and functions.
- Prototype and Test Drone Designs: Utilize additive manufacturing for rapid prototyping of drone designs, facilitating quick iterations based on testing and feedback; conduct testing protocols specific to drones to evaluate and refine prototypes effectively.
- Master Aerodynamic Principles for Drones: Explain how aerodynamic principles such as lift, drag, thrust, and weight management apply to drone design; optimize flight performance and efficiency by applying these aerodynamic principles in drone development.
- Select and Integrate Materials and Structures: Identify appropriate materials for drone construction, considering strength, weight, and durability trade-offs; design drone structures that effectively accommodate selected materials while meeting design specifications.
- Demonstrate Understanding of the Fundamentals of Additive Manufacturing Processes: Describe additive manufacturing processes relevant to drone design, including fused deposition modeling (FDM), selective laser sintering (SLS), and stereolithography (SLA); explain the principles of these processes in the context of drone manufacturing.
- Apply Design for Additive Manufacturing (DfAM) Principles: Implement DfAM principles to optimize drone designs for weight reduction, part consolidation, and performance enhancement; leverage additive manufacturing capabilities to improve structural geometries and overall design efficiency.
- Select Materials for Additive Manufacturing: Evaluate and select appropriate materials for drone components based on their mechanical properties, weight, durability, and compatibility with additive manufacturing processes; justify material choices by assessing their suitability for specific drone parts and functions.
- Prototype and Test Drone Designs: Utilize additive manufacturing for rapid prototyping of drone designs, facilitating quick iterations based on testing and feedback; conduct testing protocols specific to drones to evaluate and refine prototypes effectively.
Voraussetzungen der Lehrveranstaltung
None
Lehrinhalte
- Drone Components and Materials: Detailed exploration of drone components, including frame, propulsion system, power supply, control system, and payloads; selection of materials to optimize weight, durability, and performance.
- Design for Specific Applications: Approaches to designing drones for specific applications, such as aerial photography, payload delivery, or environmental monitoring; considerations for payload integration, flight range, and durability.
- Manufacturing and Assembly Processes: Overview of the manufacturing and assembly processes for drones, including prototyping techniques, mass production challenges, and quality control measures.
- Design for Specific Applications: Approaches to designing drones for specific applications, such as aerial photography, payload delivery, or environmental monitoring; considerations for payload integration, flight range, and durability.
- Manufacturing and Assembly Processes: Overview of the manufacturing and assembly processes for drones, including prototyping techniques, mass production challenges, and quality control measures.
Empfohlene Fachliteratur
- Gundlach, J. (2014). Designing Unmanned Aircraft Systems: A Comprehensive Approach (2nd ed). AIAA Education Series. ISBN: 978-1624102615.
- Karakoc, T. H., & Özbek, E. (2024). Unmanned Aerial Vehicle Design and Technology. Springer Cham. ISBN: 978-3031453205, https://doi.org/10.1007/978-3-031-45321-2.
- Quan, Q., Dai, X., & Wang, S. (2020). Multicopter Design and Control Practice. Springer Singapore. ISBN: 978-9811531378. https://doi.org/10.1007/978-981-15-3138-5.
- Karakoc, T. H., & Özbek, E. (2024). Unmanned Aerial Vehicle Design and Technology. Springer Cham. ISBN: 978-3031453205, https://doi.org/10.1007/978-3-031-45321-2.
- Quan, Q., Dai, X., & Wang, S. (2020). Multicopter Design and Control Practice. Springer Singapore. ISBN: 978-9811531378. https://doi.org/10.1007/978-981-15-3138-5.
Bewertungsmethoden und -Kriterien
Portfolio tests
Unterrichtssprache
Englisch
Anzahl der zugewiesenen ECTS-Credits
5
E-Learning Anteil in %
15
Semesterwochenstunden (SWS)
2.5
Geplante Lehr- und Lernmethode
Presentation, group work, discussion, exercises
Semester/Trisemester, In dem die Lehrveranstaltung/Das Modul Angeboten wird
4
Name des/der Vortragenden
Studienjahr
Kennzahl der Lehrveranstaltung/des Moduls
4_3
Art der Lehrveranstaltung/des Moduls
Integrierte Lehrveranstaltung
Art der Lehrveranstaltung
Pflichtfach