H<sub>2</sub>GO H<sub>2</sub>ERMES Launch Vehicle

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H₂GO H₂ERMES Launch Vehicle

Design Report for the H₂ERMES Reusable Launch Vehicle for Hydrogen Refueling

Bachelor Thesis (2025)

Author(s)

D.F. Cravo da Costa (TU Delft - Aerospace Engineering)

L. García Gutierrez (TU Delft - Aerospace Engineering)

T.J. van Haarst (TU Delft - Aerospace Engineering)

G. Homoki (TU Delft - Aerospace Engineering)

M. Karásek (TU Delft - Aerospace Engineering)

S. Katewale (TU Delft - Aerospace Engineering)

J. Kovář (TU Delft - Aerospace Engineering)

A. Krishnamoorthi (TU Delft - Aerospace Engineering)

A.E. Lupei (TU Delft - Aerospace Engineering)

D. Maggon (TU Delft - Aerospace Engineering)

A. Orban (TU Delft - Aerospace Engineering)

Contributor(s)

B.V.S. Jyoti – Mentor (TU Delft - Space Systems Egineering)

L.A. Afilal – Mentor (TU Delft - Group Pascoe)

N.S. Dangi – Mentor (TU Delft - Wind Energy)

Faculty

Aerospace Engineering

Sustainability Cryogenic Tanks Regenerative cooling Re-entry vehicle Reusable Launch Vehicle Aerospike Boil-off Liquid hydrogen (LH2) Orbital Refueling Reusable Second Stage Conical Tank Expander Bleed Cycle Blunted Cone Actively Cooled Heat Shield Newtonian Method

To reference this document use:

https://resolver.tudelft.nl/uuid:f9332f04-2547-4b58-b8a0-48b3a44ee7ee

More Info

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Publication Year

2025

Language

English

Coordinates

4.371251,52.006093

Graduation Date

27-06-2025

Awarding Institution

Delft University of Technology

Project

['AE3200 - Design Synthesis Exercise']

Programme

['Aerospace Engineering']

Faculty

Aerospace Engineering

Reuse Rights

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Abstract

The H2GO project presents the design of H2ERMES, a reusable launch vehicle developed to autonomously deliver liquid hydrogen (LH2) to orbital fuel depots, supporting the advancement of nuclear thermal rocket (NTR) propulsion for deep space missions. The vehicle, optimized for environmental and economic sustainability, features a reusable second stage with novel technologies, including a regeneratively cooled heat shield, aerospike-effect propulsion, and cryogenic LH2 storage integrated with structural elements. H2ERMES is designed for 25 or more missions with minimal refurbishment, meeting stringent performance, safety, and sustainability requirements. A comprehensive systems engineering approach defined user and stakeholder requirements, conducted risk analyses, and performed extensive subsystem trade-offs. The final design includes high-efficiency LH2 tanks, a 24-chamber aerospike engine using an expander bleed cycle, actively cooled heat shield, autonomous docking systems, and reliable recovery mechanisms. The project addresses growing market needs for sustainable space infrastructure, with first operational flights planned by 2032 to enable economical, reusable, and low-emission LH2 transport to orbit.

Files

7_H2GO_FinalReport.pdf

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H2GO H2ERMES Launch Vehicle

Design Report for the H2ERMES Reusable Launch Vehicle for Hydrogen Refueling

Abstract

Files

H₂GO H₂ERMES Launch Vehicle

Design Report for the H₂ERMES Reusable Launch Vehicle for Hydrogen Refueling