@inproceedings{64820, abstract = {{Political goals, emerging EU sustainability regulations, and industrial digitalization are driving the introduction of Digital Product Passports (DPPs) to enhance transparency, traceability, and compliance across product life cycles. However, the appropriate granularity of DPP integration across product architectures remains ambiguous. This paper introduces a structured, decision-oriented framework that links product structure, regulatory relevance, and information depth to define consistent DPP levels, supporting both industry implementation and future standardization.}}, author = {{Rohde, Katharina and Budde, Finn Lukas and Patrício, Bárbara and Ferreira, Tânia and Gonçalves, Ana and Ott, Manuel and Mozgova, Iryna}}, booktitle = {{Proceedings of the Design Society}}, keywords = {{digital product passport, product architecture, circular economy, information granularity, decision-making framework}}, location = {{Cavtat, Dubrovnik, Croatia}}, title = {{{Digital product passports and the challenge of product structure granularity: A decision-making framework for the level of DPP integration}}}, volume = {{6}}, year = {{2026}}, } @inbook{60834, author = {{Ott, Manuel and Jung, Philipp and Bödger, Christian and Mozgova, Iryna and Koch, Rainer and Tröster, Thomas}}, booktitle = {{Innovative Produktentwicklung durch additive Fertigung}}, editor = {{Lachmayer, Roland and Kaierle, Stefan and Oel, Marcus}}, pages = {{117--127}}, title = {{{Fused Deposition Modeling and its Extension Through Metal-Filled Filaments as a Means of Self-Help for Individuals with Physical Disabilities}}}, doi = {{doi.org/10.1007/978-3-662-69327-8}}, year = {{2025}}, } @inproceedings{63917, author = {{Koepler, Oliver and Mozgova, Iryna and Nürnberger, Florian and Steinbeck, Christoph and Pleiss, Jürgen}}, location = {{Heidelberg}}, pages = {{S. 23–39}}, publisher = {{LibreCat University}}, title = {{{Data Management in INF Projects of Collaborative Research Centres: Building Bridges Between Research, Infrastructure and Practice}}}, doi = {{10.11588/HEIBOOKS.1652.C23912}}, year = {{2025}}, } @article{62727, abstract = {{With the increasing amount of data in collaborative engineering research, the need for effective and efficient data management is growing. This paper uses a maturity-based process model to examine the implementation of research data management (RDM) in engineering projects. A process model visualizes a research-supported implementation of RDM and helps researchers evaluate their data management strategies through maturity level assessment. For this approach, activities are assigned to different maturity levels based on a maturity level characteristic providing a differentiated view of the implementation of RDM. An example from an ongoing project shows the application and support of the developed maturity-based process model. The work emphasizes the importance of standardized and quality-assured data management for the success of research projects and their contribution to the scientific community}}, author = {{Wawer, Max Leo and Müller, Laura and Khaled, Jaouhar Ben and Stauß, Timo and Wurst, Johanna and Mozgova, Iryna and Lachmayer, Roland}}, issn = {{2732-527X}}, journal = {{Proceedings of the Design Society}}, pages = {{169--178}}, publisher = {{Cambridge University Press (CUP)}}, title = {{{A maturity based data management integration in engineering research projects}}}, doi = {{10.1017/pds.2025.10031}}, volume = {{5}}, year = {{2025}}, } @inproceedings{62728, author = {{Müller, Laura and Hinterthaner, Marc and Ortlieb, Eduard and Mohnfeld, Norman and Schultz, Andreas Maximilian and Uhe, Johanna and Koepler, Oliver and Mozgova, Iryna}}, booktitle = {{IFIP Advances in Information and Communication Technology}}, isbn = {{9783032097033}}, issn = {{1868-4238}}, pages = {{140--150}}, publisher = {{Springer Nature Switzerland}}, title = {{{Getting Things Done: How to Make Simulation Data FAIR and Ready to Reuse}}}, doi = {{10.1007/978-3-032-09704-0_14}}, year = {{2025}}, } @misc{63716, author = {{Schultz, Andreas Maximilian and Mozgova, Iryna and Altun, Osman and Karras, Oliver and Koepler, Oliver and Müller, Laura and Nuenberger, Florian and Röwenstrunk, Daniel and Wawer, Max Leo}}, publisher = {{LibreCat University}}, title = {{{Strukturierte FDM-Plattformen: Aktuelle Lösungen und Herausforderungen in Informationsinfrastrukturprojekten}}}, doi = {{10.5281/ZENODO.17670597}}, year = {{2025}}, } @inproceedings{64616, abstract = {{The circular economy offers decisive advantages over the currently prevalent linear economy in industry. Firstly, the reuse of products, individual parts and material reduces the need for new production or generation and the associated consumption of energy and resources. Secondly, it helps to avoid the generation of waste. Early consideration of circular economic principles in product development processes is essential to specifically promote reuse, reparability and recycling. Efficient recycling of assemblies requires well-defined strategies. However, various challenges hinder the efficiency of technical recycling processes in industrial applications. This paper presents an Ishikawa (fishbone) diagram-based approach to systematically identify and categorize these influences. The method is implemented within an industrial framework, highlighting key obstacles such as material composition, design constraints, use of technology, framework conditions, economic limitations and regulatory challenges. By applying a scenario analysis, this approach examines potential future developments and their impact on recycling-oriented design choices. This helps to identify critical influencing factors and supports the development of resilient and sustainable industrial practices. This framework will serve as the foundation for developing an automated approach to circular design, enabling industries to more effectively integrate sustainability into their processes and adapt to changing environmental demands.}}, author = {{Rohde, Katharina and Gonzalez, Barbara Fernandez and Budde, Finn Lukas and Ott, Manuel and Mozgova, Iryna and Mendibe, Alain Alonso}}, booktitle = {{Safe and Sustainable Value Creation by Design - Proceedings of the 21st Global Conference on Sustainable Manufacturing}}, editor = {{Kohl, Holger and Seliger, Günther and Dietrich, Franz and Campana, Giampaolo}}, location = {{Bologna, Italy}}, publisher = {{Springer Nature Switzerland AG}}, title = {{{Unveiling Barriers to Recycling with a Focus on Design: An Ishikawa Diagram-Based Approach with Industrial Application}}}, volume = {{1}}, year = {{2025}}, } @inproceedings{64786, author = {{Müller, Laura and Meihöfener, Niclas and Siemoneit, Johannes Gabriel and Mozgova, Iryna}}, booktitle = {{Engineering Education for Sustainable Development (EESD2025)}}, title = {{{Introduction of electronic lab notebooks in engineering education - opportunities for a cultural change}}}, doi = {{https://doi.org/10.71779/776}}, year = {{2025}}, } @inproceedings{64611, abstract = {{Für die Aufrechterhaltung der natürlichen Ressourcen ist eine effiziente Nutzung dieser essenziell. Vor diesem Hintergrund untersucht das vorliegende Paper die Rolle der Kreislaufwirtschaft als wegweisendes Wirtschaftsmodell, das von der Europäischen Union gefördert wird. Ziel der Kreislaufwirtschaft ist es, den Ressourcenverbrauch und die Abfallproduktion zu minimieren, indem ein kontinuierlicher Kreislauf aus Nutzung, Wiederverwendung und Recycling von Materialien geschaffen wird. Ein zentraler Aspekt dabei ist der Produktentwicklungsprozess (PEP) - ein vielschichtiger Prozess mit zahlreichen Einflussfaktoren und theoretisch unbegrenzten Gestaltungsmöglichkeiten. Diese Vielfalt führt jedoch zu erheblichen Entscheidungsunsicherheiten, die die Umsetzung von Kreislaufwirtschaftsprinzipien erschweren können. Um diese Herausforderungen zu adressieren, wird ein methodischer Prozess vorgestellt, der eine systematische Klassifizierung im Zusammenhang mit umliegenden Bauteilen ermöglicht. Die Methodik basiert auf einer strukturierten Bewertung von Bauteilen hinsichtlich ihrer Relevanz für die Kreislaufwirtschaft. Dabei werden zentrale Aspekte wie Wiederverwendbarkeit, Recyclingfähigkeit und Ressourceneffizienz berücksichtigt, darunter: • Handelt es sich um ein Gebrauchs- oder Verbrauchsprodukt? • Ist das Bauteil eine Wiederverwendung oder eine Neufertigung? • Ist das Bauteil standardisiert, zugekauft oder individuell ausgerichtet? • Welche primäre Funktion nimmt das Bauteil ein? Diese strukturierte Klassifizierung unterstützt die Entscheidungsfindung bereits früh im PEP. Sie ermöglicht es Produktentwickelnden, Potenziale für die Kreislaufwirtschaft frühzeitig zu erkennen und gezielt nachhaltige Maßnahmen zu ergreifen. Die entwickelte Methodik bildet somit eine Grundlage für die Integration kreislaufwirtschaftlicher Prinzipien in den Entwicklungsprozess. Insbesondere im Kontext moderner Anforderungen des Mobility Management zeigt sich ihr Potenzial, nachhaltige Innovationen gezielt zu fördern und die Umsetzung der Kreislaufwirtschaft in der industriellen Praxis zu erleichtern.}}, author = {{Rohde, Katharina and Ott, Manuel and Budde, Finn Lukas and Mozgova, Iryna}}, booktitle = {{Solving Conflicts on the Way to Sustainable Mobility: Technische und betriebswirtschaftliche Aspekte}}, editor = {{Proff, Heike}}, location = {{Duisburg}}, publisher = {{Springer Nature Meteor}}, title = {{{Optimierung modularer Produkte für die Mobilität: Ein Klassifizierungsrahmen für zirkuläre Produkte}}}, year = {{2025}}, } @inbook{56299, author = {{Schultz, Andreas Maximilian and Dotzki, Fabian and Eisenbach, Thomas and Mozgova, Iryna}}, booktitle = {{Next Chapter in Mobility}}, isbn = {{9783658426460}}, location = {{Duisburg}}, publisher = {{Springer Fachmedien Wiesbaden}}, title = {{{Sicherheit bei Großveranstaltungen – Mobilitätsverhalten und Personenströme im Fokus}}}, doi = {{10.1007/978-3-658-42647-7_54}}, year = {{2024}}, } @inbook{58304, author = {{Altun, Osman and Hinterthaner, Marc and Barienti, Khemais and Nürnberger, Florian and Lachmayer, Roland and Mozgova, Iryna and Koepler, Oliver and Auer, Sören}}, booktitle = {{IFIP Advances in Information and Communication Technology}}, isbn = {{9783031625770}}, issn = {{1868-4238}}, publisher = {{Springer Nature Switzerland}}, title = {{{Contextualization for Generating FAIR Data: A Dynamic Model for Documenting Research Activities}}}, doi = {{10.1007/978-3-031-62578-7_11}}, year = {{2024}}, } @misc{63714, author = {{Schultz, Andreas Maximilian and Mozgova, Iryna}}, title = {{{Wissensmanagement in Feuerwehren skalierbare IT-Architektur für Erweiterung und Austausch}}}, year = {{2024}}, } @inproceedings{56655, author = {{Müller, Laura and Schultz, Andreas Maximilian and Altun, Osman and Uhe, Johanna and Koepler, Oliver and Auer, Soeren and Mozgova, Iryna}}, booktitle = {{Proceedings of NordDesign 2024}}, pages = {{514--520}}, publisher = {{The Design Society}}, title = {{{Requirements Analysis of a Research Data Management System in Collaborative Projects}}}, doi = {{10.35199/norddesign2024.55}}, year = {{2024}}, } @inproceedings{46451, abstract = {{New technologies and materials carry significant potential for sustainable production and use of products. As an example, Additive Manufacturing technologies and materials promise lightweight design and energy efficient use of parts. Exhausting the full potential requires: a) consideration of uncertainties with respect to future capabilities, and b) upgradeable design guidelines to cover advancements consistently. The proposed approach merges concepts of Design-for-X with foresight algorithms of Scenario-Technique to derive actionable knowledge. It is validated by an application in the field of Additive Manufacturing, namely Metal Fused Deposition Modelling. Engineers benefit from the intuitive access to heterogeneous types of sustainability related information.}}, author = {{Gräßler, Iris and Mozgova, Iryna and Pottebaum, Jens and Ott, Manuel and Jung, Philipp and Hesse, Philipp}}, booktitle = {{17th CIRP Conference on Intelligent Computation in Manufacturing Engineering}}, keywords = {{Design-for-X, Scenario-Technique, sustainability, uncertainty, Life-Cycle Engineering, Additive Manufacturing, Circular Economy}}, location = {{Gulf of Naples}}, pages = {{549--554}}, publisher = {{Elsevier}}, title = {{{Handling of uncertainties in the design of sustainable Additive Manufacturing products by merging Design-for-X and Scenario-Technique}}}, doi = {{10.1016/j.procir.2024.08.238}}, volume = {{126}}, year = {{2024}}, } @inproceedings{57445, abstract = {{Knowledge management is essential for successful disaster management. This paper conducts a Systematic Literature Review at the intersection of the knowledge management field and disaster management and examines the available body of literature. Fire departments are chosen as the focus group as they are the most prevalent emergency services. There are many publications that deal with knowledge management during the response phase of an emergency. Often, the literature focuses on the application of knowledge management in large-scale disasters to link the various organizations on-scene. What is missing in most approaches is a prior step of implementing and training the knowledge management system. Therefore, this literature review seeks to provide an overview of approaches for daily routines and small-to-medium incidents that serve as a training ground. However, literature on non-incident phases and smaller incidents is scarce. As information technologies are developing rapidly, there is no modern and recent description of the current use of knowledge management solutions in this area.}}, author = {{Schultz, Andreas Maximilian and Dotzki, Fabian and Mozgova, Iryna}}, booktitle = {{Proceedings of the 16th International Joint Conference on Knowledge Discovery, Knowledge Engineering and Knowledge Management}}, keywords = {{Knowledge Management, Civil Protection, Systematic Literature Review, Fire Brigade}}, location = {{Porto, Portugal}}, publisher = {{SCITEPRESS - Science and Technology Publications}}, title = {{{Knowledge Management in Civil Protection at the Example of Fire Brigades}}}, doi = {{10.5220/0012947700003838}}, year = {{2024}}, } @inproceedings{57182, abstract = {{Generative design suggestions and topology optimizations can help to reduce iterative process loops between calculation and design departments during product development processes. However, precise topology optimizations are computationally intensive, while generative designs benefit from swift suggestions to address design problems efficiently. Using artificial neural networks (ANN) can address this contrast of pre-defined aims by predicting topology-optimized designs, thereby combining both advantageous features. However, a challenge in Mass Customization is, that ANN are usually trained on specific geometries, making transfer to other applications impractical or requiring the creation of new datasets, which is economically unfeasible. Authors have already demonstrated a solution in other publications: dividing a geometry into geometric primitives like cuboids to perform abstraction. An ANN can then be trained to recognize optimized cuboids, which can be assembled back into a complete geometry, comparable to the finite element methods, which divide geometries of parts in finite elements enable mechanical property calculation. This publication aims to illustrate the steps of the approach in which the complete geometry of a part is segmented into these primitives, and the benefits obtained. Various methods will be explored, including automated workflows on modern low-code platforms, to enable generalized use.}}, author = {{Ott, Manuel and Meihöfener, Niclas and Mozgova, Iryna}}, booktitle = {{Proceedings of the 11. Conference on Mass Customization and Personalization (MCP)}}, editor = {{Anisic, Zoran and Forza, Cipriano}}, isbn = {{978-86-6022-686-2}}, location = {{Novi Sad, Serbia}}, publisher = {{Faculty of Technical Science, Department of Industrial Engineering and Management }}, title = {{{An approach to use generic data sets for neural networks in product designs through geometric abstraction via primitives}}}, year = {{2024}}, } @inproceedings{54301, author = {{Schultz, Andreas Maximilian and Dotzki, Fabian and Mozgova, Iryna}}, booktitle = {{Proceedings of the 21st ISCRAM Conference}}, editor = {{Penkert, Berthold and Hellingrath, Bernd and Rode, Monika and Widera, Adam and Middelhoff, Michael and Boersma, Kees and Kalthöner, Matthias}}, location = {{Münster}}, title = {{{State of Knowledge Management among German firefighters}}}, doi = {{https://doi.org/10.59297/ndd24w94}}, year = {{2024}}, } @inproceedings{52673, abstract = {{Dieser Beitrag stellt eine rechnergestützte Modellierungsstrategie vor, um Prozesskettenwissen, wie die Gestaltung der Fertigungsstufen, prozessübergreifende Fertigungsrestriktionen oder Fertigungshilfsmittel, für die Produktgestaltung zu formalisieren und im Kontext des Design for Manufacturing für Produkt- und Prozessgestaltungsentscheidungen bereitzustellen. Dabei werden am Beispiel einer Tailored-Forming-Prozesskette die Herstellungsschritte einer Multimaterial-Welle mittels eines Constraint-Satisfaction-Problems (CSP) modelliert, indem die geometrischen Transformationen einzelner Fertigungsstufen sowie Fertigungsrestriktionen in Form von Constraints und Fertigungsstufen sowie Fertigungshilfsmittel über Parameter in den CSP-Variablen formuliert werden. Das CSP ist damit in der Lage, ausgehend von einem Geometriemodell eines Bauteils eine prozesskettenorientierte Restriktionsprüfung zur Herstellbarkeitsbewertung durchzuführen und automatisiert Fertigungsstufen sowie Fertigungshilfsmittel zu konfigurieren.}}, author = {{Herrmann, Kevin and Pusch, Felix and Plappert, Stefan and Bode, Behrend and Mozgova, Iryna and Gembarski, Paul Christoph and Lachmayer, Roland}}, booktitle = {{Stuttgarter Symposium für Produktentwicklung SSP 2023: Tagungsband zur Konferenz}}, pages = {{79--90}}, publisher = {{Stuttgart: Fraunhofer IAO}}, title = {{{Prozesskettenorientierte Herstellbarkeitsanalyse von Produkten durch die Nutzung eines Constraint-Satisfaction-Problems}}}, doi = {{https://doi.org/10.15488/14221}}, year = {{2023}}, } @article{52677, abstract = {{Several modules in automotive are usually modified and adapted for various project-specific applications. Due to a standardized safety concept a high reusability is accessible. A safety element out of context (SEooC) according to ISO 26262 can be a suitable approach. Based on the same safety concept and analysis, common modules can reach high reusability. For developing according to a module out of context, an appropriate and detailed development approach is required. This paper shows how to deduce this development processes for platform modules. Therefore, the detailed approach of the SEooC is derived. The aim is to create a detailed workflow for all phases of the development and integration of any kind of system modules. As an application example, an automotive project for an actuator control module is considered.}}, author = {{Noun, H. and Mozgova, Iryna and Abdelfattah, M. and Zeller, G. and Rajesh, G. and Lachmayer, R.}}, journal = {{International Journal of Industrial and Manufacturing Engineering}}, number = {{6}}, pages = {{237--243}}, title = {{{Approach for a Safety Element out of Context for an Actuator Circuit Control Module}}}, volume = {{17}}, year = {{2023}}, } @inproceedings{44521, author = {{Wurst, Johanna and Steinhoff, Timon and Mozgova, Iryna and Hassel, Thomas and Lachmayer, Roland}}, title = {{{Aspects of a Sustainability Focused Comparison of the Wire Arc Additive Manufacturing (WAAM) and the Laser Powder Bed Fusion (LPBF) Process}}}, doi = {{10.1007/978-981-19-9205-6_9}}, year = {{2023}}, }