Informationen und Networking für Outgoings des FB04

Gemeinsame Begrüßung aller neuen Studierenden des Fachbereichs Produktionstechnik aus den Studiengängen B.Sc. Berufliche BIldung Mechatronik, B.Sc. Maschinenbau & Verfahrenstechnik, B.Sc. Systems Engineering, B.Sc. Wirtschaftsingenieurwesen Produktionstechnik, M.Sc. Produktionstechnik, M.Sc. Wirtschaftsingenieurwesen Produktionstechnik, M.Sc. Systems Engineering, M.Sc. Space Engineering und M.Sc. ProMat

Pflichtveranstaltung für neue Studierende der Studienfächer mit laborpraktischen Inhalten die Sicherheitsschulung (in englischer Sprache) mit praktischer Feuerlöschübung stattfinden.
The safety training (in English) with practical fire-fighting exercises will take place as a compulsory event for new students of the study programmes with practical laboratory contents.

Teilnahme ist verpflichtend!
Participation is mandatory!

https://www.fb4.uni-bremen.de/o-woche/

This course focuses on the fundamental equations governing the motion of fluids (liquids and gases) and their application in the field of aerospace engineering. The equations are simplified and solved analytically and/or numerically for specific problems.

This course focuses on the fundamental equations governing the motion of fluids (liquids and gases) and their application in the field of aerospace engineering. The equations are simplified and solved analytically and/or numerically for specific problems.

Space Vehicle Design (ECTS 3):
< to be completed >

Space Systems Engineering (ECTS 3):
As part of the module "Design of Space Systems" the basics of Space Systems Engineering, Space Project Management as well as the modern process of Space Concurrent Engineering is tought amongst others wrt the following content as frontal lessons and in the form of examples and small exercises: Space Project Management Process, ECSS Standards, Project Planning, Project Phases and Reviews, Project Structure, Cost Estimation, Configuration and Information Management, Risk Management, V-Model, Requirements, Concurrent Engineering, MBSE (i. e. Virtual Satellite), Collaborative Engineering and more.

Space Vehicle Design (ECTS 3):
< to be completed >

Space Systems Engineering (ECTS 3):
As part of the module "Design of Space Systems" the basics of Space Systems Engineering, Space Project Management as well as the modern process of Space Concurrent Engineering is tought amongst others wrt the following content as frontal lessons and in the form of examples and small exercises: Space Project Management Process, ECSS Standards, Project Planning, Project Phases and Reviews, Project Structure, Cost Estimation, Configuration and Information Management, Risk Management, V-Model, Requirements, Concurrent Engineering, MBSE (i. e. Virtual Satellite), Collaborative Engineering and more.

Overview of various rocket engine types, fundamentals of combustion, and design of propulsion systems and stages.

Overview of various rocket engine types, fundamentals of combustion, and design of propulsion systems and stages.

This module focuses on key physical parameters and processes of the near-earth space environment and how these affect spacecraft design and operation as well as the design of space habitats and space suits.

This module focuses on key physical parameters and processes of the near-earth space environment and how these affect spacecraft design and operation as well as the design of space habitats and space suits.

This module aims at conveying a comprehensive understanding of the principles, technologies and applications of utilizing extraterrestrial resources. The primary focus will be laid on the understanding of the fundamentals of ISRU (defining ISRU and its importance for space exploration, identifying key resources available on extraterrestrial bodies such as water ice, regolith and minerals, understanding the environmental conditions on extraterrestrial bodies and their impact on ISRU operations).

This module aims at conveying a comprehensive understanding of the principles, technologies and applications of utilizing extraterrestrial resources. The primary focus will be laid on the understanding of the fundamentals of ISRU (defining ISRU and its importance for space exploration, identifying key resources available on extraterrestrial bodies such as water ice, regolith and minerals, understanding the environmental conditions on extraterrestrial bodies and their impact on ISRU operations).

The Haber-Bosch process is an indispensable part of the modern chemical industry, enabling large scale ammonia production particularly for fertilizers. Its potential implementation on Mars is of significant interest for supporting long-term human exploration through in-situ resource utilization (ISRU). This literature based project investigates the feasibility of deploying Haber-Bosch ammonia synthesis under Martian environmental conditions, with a particular focus on comparing key process parameters between Earth and Mars.

Students will systematically analyze differences in nitrogen availability, hydrogen sourcing, operating pressure, temperature requirements, and overall energy demand. The Martian atmosphere, composed predominantly of CO₂ and only about 2 % nitrogen, presents significant challenges for nitrogen extraction and compression. In contrast to Earth, where hydrogen is primarily derived from fossil fuels, Martian hydrogen production relies on energy-intensive water electrolysis from sub surface ice deposits or hydrated minerals. With the core reaction conditions of the Haber-Bosch process remaining unchanged, the additional energy requirements associated with gas capture, purification, and high-pressure compression are expected to substantially increase the total system energy demand on Mars. The project will further evaluate potential energy sources, including solar power, and assess their suitability for sustaining ammonia production.

Crewed spacecraft and surface habitats continuously produce CO₂ as a metabolic byproduct, which must either be scrubbed and vented or actively converted into useful products. Electrochemical CO₂ reduction reaction (CO₂RR) offers a dual benefit: removing a cabin atmosphere contaminant while producing valuable chemicals such as carbon monoxide, methane, formate, or methanol that can serve as fuel precursors or feedstocks for further synthesis. This literature project examines the electrochemical reduction of CO₂ as a component of a closed-loop life support and ISRU strategy, with particular attention to how microgravity and the CO₂-rich Martian atmosphere alter the design requirements relative to terrestrial systems.
Students will survey catalyst materials and selectivity for relevant CO₂RR products, review existing space-heritage carbon dioxide removal systems such as the Sabatier reactor on the ISS, and assess how an electrochemical approach compares in terms of mass, power consumption, and product flexibility. Simple Faradaic efficiency and power budget calculations will be performed to estimate the CO₂ conversion rate achievable within the electrical power envelope of a Mars surface habitat. The project will equip students to critically evaluate CO₂RR as a candidate technology for integration into future closed-loop planetary life support architectures.

Electrochemical water splitting (2 H2O → 2 H2 + O2) is essential for terrestrial hydrogen production - supporting future energy storage technologies - and for extraterrestrial oxygen production for life support systems on space missions, e.g. the Oxygen Generator Assembly on the ISS. Extraterrestrial factors such as microgravity, radiation exposure, and extreme thermal fluctuations impact electrolyser performance compared to Earth-based systems. In the near absence of gravity, phase separation between the solid electrode, liquid electrolyte and gaseous products becomes problematic as no buoyant forces occur naturally. This literature project explores the differences in electrolyser designs for terrestrial and space applications, focusing on their efficiency, durability, and performance. By examining electrolyser design modifications, material selection strategies and well-known operational challenges, the results of this projects will provide insights into the optimization of future electrolyser technologies for space applications.

The Electrical Power Subsystem (EPS) is a core element of CubeSat platforms, responsible for power regulation and distribution. The EPS must handle unregulated DC input from solar panels, provide stable output voltages (3.3 V, 5 V, 12 V), and interface with, e.g., USB-C and PC/104. It must also integrate protection circuits, telemetry, and power management functions.
This project covers the design, implementation, validation and testing of an EPS for CubeSat. The system will convert solar panel input into regulated outputs, implement overcurrent and overvoltage protection, and include Maximum Power Point Tracking (MPPT) for solar array efficiency. Telemetry will include input/output current, voltage, power, cell voltage, and temperature and system health status. The additional design of a simple, first prototype of a compatible battery / power storage subsystem is desired.
Tasks:

• System Requirements and Architecture: Reflect power requirements, select battery technology, and design the EPS architecture.
• Component Selection and Circuit Design: Select solar panels, electrical components (voltage regulators, MPPT controllers, protection components, battery management, …). Design the PCB layout in KiCAD.
• Telemetry Implementation: Develop hardware and firmware for data acquisition/sensor readout and subsystem communication.
• Prototype Assembly and Testing: Build the EPS prototype and validate performance under simulated LEO conditions, including power cycling and fault scenarios.
• Documentation: Provide scientific background, schematics, test reports, and a final report documenting the design process, results, and recommendations.

The outcome of this project will be a functional EPS prototype on a custom PCB and a compatible battery (subsystem).
Experience in the design of electronics / PCBs is mandatory.

Entwicklung einer Machbarkeitsstudie zum Einsatz von
Thermalkameras zur Erkennung vom Strömungsabriss am
Tragflügel eines Ultraleichtflugzeuges

The C.R.O.P (Combined Regenerative Organic Food Production) technology was based on sustainable practices that integrate circular resource use into space systems. This system relied on natural biological processes, where micro-organisms convert components of urine into plant fertilizers. These fertilizers are then used to grow crops in controlled environments, contributing to food production while simultaneously managing waste. This integration of waste recycling and agriculture aimed to reduce the need for continuous resupply from Earth, which is one of the major challenges in space exploration. Developed and demonstrated in experiments such as the Eu: CROPIS mission by the German Aerospace Centre (DLR), this approach focused on converting human waste into a usable fertilizer for plant cultivation. Rather than treating waste as a disposal problem, C.R.O.P utilized it as a valuable resource, aligning with the principles of closed-loop life support systems that are essential for long-duration extra-terrestrial missions to the Mars.

In this project, students will analyse how systems like C.R.O.P function, compare them with other existing space fertilizer development strategies, and assess their advantages and limitations in space environments. They will also be encouraged to think creatively by proposing simple conceptual designs for closed-loop fertilizer systems tailored to Martian habitats. By the end of the project, students will have developed the ability to critically engage with interdisciplinary research and appreciate the role of sustainable technologies in shaping the future of space exploration.

In-situ resource utilization (ISRU) on the Moon and Mars relies on the ability to generate and store chemical energy from locally available resources, most notably water ice and solar irradiance. Photoelectrochemical (PEC) and photovoltaic-coupled electrolysis (PV-E) systems have been proposed as compact, scalable routes to producing hydrogen and oxygen from surface water without continuous resupply from Earth. This literature project compares PEC and PV-E architectures for solar hydrogen production under extraterrestrial conditions, examining how reduced solar flux, dust accumulation, and day-night cycles constrain system design on the lunar surface versus Mars.
Students will survey efficiency benchmarks reported for state-of-the-art PEC devices under terrestrial and simulated space conditions and assess how radiation degradation of semiconductor photoelectrodes impacts long-term performance. Back-of-envelope calculations will quantify the required solar collector area, electrolyser power rating, and hydrogen storage volume to sustain oxygen production for a four-person surface habitat over a 500-day mission at both locations. The project provides students with an integrated perspective on the interdependencies between solar energy conversion, electrochemistry, and ISRU mission architecture.

Electrochemical systems such as water electrolysers and fuel cells are critical components of closed-loop life support systems for long-duration space missions. On Earth, convective heat dissipation passively assists thermal regulation. In microgravity, the absence of natural convection fundamentally alters heat and mass transfer at electrochemical interfaces. This literature project investigates thermal management strategies for electrochemical energy systems operating under space-relevant conditions, including microgravity, Lunar, and Martian surface environments. Students will review how the operating temperature affects the electrolyser efficiency, membrane durability, and electrolyte conductivity, and compare passive versus active thermal control approaches applicable to spacecraft volume and mass constraints.
Simple steady-state heat balance calculations will be performed to estimate acceptable operating power envelopes under representative mission scenarios (ISS, Lunar Gateway, Mars surface habitat). By the end of the project, students will be able to quantitively assess the feasibility of electrochemical life support components under thermal constraints and propose design guidelines for thermally robust space electrochemical systems.