Abstract

This paper presents the conceptual design and performance analysis of a hydrogen-powered, high-altitude aircraft developed for long-endurance aerosol dispersion missions. Raymer’s methodology is used for initial sizing of the aircraft, followed by utilizing a hybrid weight estimation method comparing the Raymer, Torenbeek, NASA, and Roskam weight estimation methodologies to create a robust weight estimation. Analysis of aerodynamic, propulsion, weight, stability, and mission performance is conducted in RDSwin to demonstrate a sustained operation for a mission including a 65,000 ft altitude, 3.5-hour cruise segment for dispersing a 50,000 lb aerosol payload. Numerous iterations of the aircraft are performed to refine aircraft performance towards a more robust and efficient design. Simulation results showed that a conventional tube-wing aircraft using hydrogen propulsion is capable of efficient high-altitude flight with adequate thrust margin, structural feasibility, and subsystem compatibility per the mission requirements. Overall, the study verifies the hydrogen tube-wing concept as a viable platform for long-duration, high-altitude missions requiring substantial payload capacity and endurance.

Document Type

Final Report

Author's School

McKelvey School of Engineering

Author's Department

Mechanical Engineering and Materials Science

Class Name

Mechanical Engineering and Material Sciences Independent Study

Language

English (en)

Date of Submission

12-21-2025

Download

Share

COinS