RemanLab – Lernfabrik für Remanufacturing/RemanLab – Learning Factory for Remanufacturing

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Bibliographic information

Cover of Volume: wt Werkstattstechnik online Volume 115 (2025), Issue 04
Open Access Full access

wt Werkstattstechnik online

Volume 115 (2025), Issue 04

Authors:
Publisher
VDI fachmedien, Düsseldorf
Copyright Year
2025
ISSN-Online
1436-4980
ISSN-Print
1436-4980

Chapter information

Open Access Full access

Volume 115 (2025), Issue 04

RemanLab – Lernfabrik für Remanufacturing/RemanLab – Learning Factory for Remanufacturing

Authors:
ISSN-Print
1436-4980
ISSN-Online
1436-4980
Preview:

Remanufacturing is becoming increasingly important in the context of resource scarcity and sustainability. Research and skills development on real objects are key to overcoming the specific challenges. RemanLab transfers the established concept of learning factory to remanufacturing while teaching the process chain in a practical way. This enables knowledge transfer, product evaluations, and the development of efficient process chains, particularly via digital technologies.

Bibliography

  1. [1] Schuh, G.; Schmidt, C. (Hrsg.): Produktionsmanagement: Handbuch Produktion und Management 5. Heidelberg: Springer Verlag 2014. DOI: doi.org/10.1007/978–3–642–54288–6 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  2. [2] Kara, S.; Hauschild, M.; Sutherland, J. et al.: Closed-loop systems to circular economy: A pathway to environmental sustainability? CIRP Annals 71 (2022) 2, pp. 505–528 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  3. [3] Cerdas, F.; Kurle, D.; Andrew, S. et al.: Defining Circulation Factories – A Pathway towards Factories of the Future. Procedia CIRP 29 (2015), pp. 627–632 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  4. [4] DIN SPEC 91345: Referenzarchitekturmodell Industrie 4.0 (RAMI4.0) Ausgabe April 2016 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  5. [5] Industry IoT Consortium: The Industrial Internet Reference Architecture. Stand: 2022. Internet: www.iiconsortium.org/iira/. Zugriff am 14.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  6. [6] ISO/IEC 30141: Internet of things (IoT) – Reference architecture. Ausgabe August 2024 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  7. [7] Heinz, C.; Krämer, J.; Riemenschneider, T. et al.: Auf dem Weg zur allwissenden Fabrik – Vertikale Integration auf Basis kontinuierlicher Datenverarbeitung. Workshop ‚Die allwissende Fabrik – Informatik in der Produktion‘, INFORMATIK 2007, Informatik trifft Logistik, Lecture Notes in Informatics (LNI), P-110, 2007, S. 339–344 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  8. [8] Theorin, A.; Bengtsson, K.; Provost, J. et al.: An event-driven manufacturing information system architecture for Industry 4.0. International Journal of Production Research 55 (2017) 5, pp. 1297–1311 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  9. [9] Thiede, S.; Marc-André, F.; Thiede, B. et al.: Integrative simulation of information flows in manufacturing systems. Procedia CIRP 81 (2019), pp. 647–652 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  10. [10] Vater, J.; Harscheidt, L.; Knoll, A.: A Reference Architecture Based on Edge and Cloud Computing for Smart Manufacturing. 2019 28th International Conference on Computer Communication and Networks (ICCCN), Valencia, Spain, 2019, pp. 1–7 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  11. [11] Oluyisola, O. E.; Bhalla, S.; Sgarbossa, F. et al.: Designing and developing smart production planning and control systems in the industry 4.0 era: a methodology and case study. Journal of Intelligent Manufacturing 33 (2022) 1, pp. 311–332 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  12. [12] Zietsch, J.: Planning of Edge Computing for Factories. Dissertation, Technische Universität Braunschweig, 2023 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  13. [13] Reis, J.; Housley, M.: Fundamentals of Data Engineering: Plan and Build Robust Data Systems. Sebastopol, CA: O’Reilly Media 2022 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  14. [14] Thiede, S.; Juraschek, M.; Herrmann, C.: Implementing Cyber-physical Production Systems in Learning Factories. Procedia CIRP 54 (2016), pp. 7–12 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  15. [15] Blömeke, S.; Mennenga, M.; Herrmann, C. et al.: Recycling 4.0: An Integrated Approach Towards an Advanced Circular Economy. ICT4S2020: Proceedings of the 7th International Conference on ICT for Sustainability, 2020, pp. 66–76 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  16. [16] Oks, S. J.; Fritzsche, A.; Möslein, K. M.: An Application Map for Industrial Cyber-Physical Systems. In: Jeschke, S.; Brecher, C.; Song, H. et al. (Hrsg.): Industrial Internet of Things. Cham: Springer International Publishing 2017, S. 21–46 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  17. [17] Seitz, M.: Speicherprogrammierbare Steuerungen im Industrial IoT: Objektorientierter System- und Programmentwurf, Motion Control, Sicherheit, Digital Engineering. München: Carl Hanser Verlag 2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  18. [18] Munro, K.; Papp, S.; Toth, Z. et al.: Handbuch Data Science und KI: Mit Machine Learning und Datenanalyse Wert aus Daten generieren. München: Carl Hanser Verlag 2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  19. [19] Beims, M.; Bischof, C.; Hengstberger, W.: Handbuch IT-System- und Plattformmanagement. München: Carl Hanser Verlag 2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  20. [20] Riggert, W.; Lübben, R.: Rechnernetze: ein einführendes Lehrbuch. München: Carl Hanser Verlag 2020 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  21. [21] ISO/IEC 7498–1: Information technology – Open Systems Interconnection – Basic reference model: The basic model. Ausgabe November 1994 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  22. [22] IPCOMM GmbH: Standardprotokolle. Stand: 2025. Internet: www.ipcomm.de/protocols_de.html. Zugriff am 14.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  23. [23] Bockholt, H.; Indrikova, M.; Netz, A. et al.: The interaction of consecutive process steps in the manufacturing of lithium-ion battery electrodes with regard to structural and electrochemical properties. Journal of Power Sources 325 (2016), pp. 140–151 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-5
  24. [1] Ellen MacArthur Foundation: Towards the Circular Economy Volume 1. Economic and business rationale for an accelerated transition. Stand: 2013. Internet: emf.thirdlight.com/file/24/xTyQj3oxiYNMO1xTFs9xT5LF3C/Towards%20the%20circular%20economy%20Vol%201%3A%20an%20economic%20and%20business%20rationale%20for%20an%20accelerated%20transition.pdf. Zugriff am 28.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  25. [2] European Commission: Commission Staff Working Document – Impact Assessment. Accompanying the document Proposal for a Regulation of the European Parliament and of the Council establishing a framework for setting ecodesign requirements for sustainable products and repealing Directive 2009/125/EC. Stand: 2022. Internet: https://environment.ec.europa.eu/system/files/2022–03/SWD_2022_82_1_EN_impact_assessment_part3_v2.pdf. Zugriff am 28.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  26. [3] DIN Deutsches Institut für Normung: DIN SPEC 91472:2023–06 Remanufacturing (Reman) – Qualitätsklassifizierung für zirkuläre Prozesse. Berlin: Beuth Verlag 2023 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  27. [4] Westkämper, E.; Warnecke, H.-J.: Einführung in die Fertigungstechnik. Wiesbaden: Vieweg+Teubner Verlag 2010 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  28. [5] VDI Verein Deutscher Ingenieure: VDI 2243:2002–07: Recyclingorientierte Produktentwicklung. Berlin: Beuth Verlag 2002 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  29. [6] Lange, U.: Ressourceneffizienz durch Remanufacturing – Industrielle Aufarbeitung von Altteilen. Berlin: VDI ZRE Kurzanalyse 2017 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  30. [7] Köhler, D. C. F.: Regenerative Supply Chains. Regenerative Wertschöpfungsketten. Aachen: Shaker Verlag 2011 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  31. [8] Koop, C.; Grosse Erdmann, J.; Koller, J. et al.: Circular Business Models for Remanufacturing in the Electric Bicycle Industry. Frontiers in Sustainability 2 (2021), doi.org/10.3389/frsus.2021.785036 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  32. [9] Parker, D.; Riley, K.; Robinson, S. et al.: Remanufacturing Market Study. Stand: 2015. Internet: www.remanufacturing.eu/assets/pdfs/remanufacturing-market-study.pdf. Zugriff am 28.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  33. [10] Roland Berger; CLEPA European Association of Automotive Suppliers: The Electrification of Light Vehicles. Boon or bane for the European aftermarket? Stand: 2022. Internet: https://content.rolandberger.com/hubfs/07_presse/22_2088_COP_Automotive_Aftermarket_CLEPA_online_DS_(2).pdf. Zugriff am 28.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  34. [11] Guide, V. R.: Production planning and control for remanufacturing: industry practice and research needs. Journal of Operations Management 18 (2000) 4, pp. 467–483 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  35. [12] Kurilova-Palisaitiene, J.; Sundin, E.; Poksinska, B.: Remanufacturing challenges and possible lean improvements. Journal of Cleaner Production 172 (2018), pp. 3225–3236 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  36. [13] Miehe, R.; Gross, E.; Ackermann, T. et al.: Learning factories for biointelligent production – design aspects and required competencies. SSRN Electronic Journal (2023). Proceedings of the 13th Conference on Learning Factories (CLF 2023), dx.doi.org/10.2139/ssrn.4458036 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  37. [14] Ackermann, T.; Miehe, R.; Reimann, P. et al.: A cross-disciplinary training concept for future technologists in the dawn of biointelligent production systems. SSRN Electronic Journal (2023). Proceedings of the 13th Conference on Learning Factories (CLF 2023), dx.doi.org/10.2139/ssrn.4458051 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  38. [15] Abele, E.; Metternich, J.; Tisch, M. et al.: Learning Factories. Featuring New Concepts, Guidelines, Worldwide Best-Practice Examples. Cham: Springer International Publishing 2024 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  39. [16] Tisch, M.; Ranz, F.; Abele, E. et al.: Learning Factory Morphology – Study Of Form And Structure Of An Innovative Learning Approach In The Manufacturing Domain. Turkish Online Journal of Educational Technology Special Issue (2015), pp- 356–363 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  40. [17] Koller, J.; Grosse Erdmann, J.; Herold, M. et al.: RemanLab – Conceptualization and Realization of a Learning Factory for Remanufacturing. Proceedings of the 13th Conference on Learning Factories (CLF 2023), dx.doi.org/10.2139/ssrn.4469183 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  41. [18] ZIV – Die Fahrradindustrie (Hrsg.): Marktdaten Fahrräder und E-Bikes für 2023. In Kooperation mit dem VSF – Verbund Service und Fahrrad. Stand: 2024. Internet: www.mtb-news.de/news/wp-content/uploads/2024/03/0fcb98eaa8cc63ccf908048a4d57a8cbb3773020.pdf. Zugriff am 28.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  42. [19] Schlesinger, L.; Koller, J.; Oechsle, O. et al.: Remanufacturing of E-mobility Components – Five-Step Implementation Strategy to increase Sustainability within Circular Economy. 2021 11th International Electric Drives Production Conference (EDPC), Erlangen, Germany, 2021, pp. 1–8 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  43. [20] Koller, J.: E-Bike Remanufacturing: potential & technical feasibility. In: Weiland, F. (Hrsg.): Remanufacturing Components of Electric Vehicles. Selbstverlag: Köln 2022, pp. 69–88, Internet: www.fjwconsulting.com/. Zugriff am 28.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  44. [21] Brose Antriebstechnik GmbH & Co. KG: Remanufacturing-Antriebe von Brose jetzt bei RA-CO erhältlich. Stand: 2024. Internet: www.brose-ebike.com/de-de/presse/reman-ra-co/. Zugriff am 28.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  45. [22] Steinhilper, R.: Produktrecycling. Vielfachnutzen durch Mehrfachnutzung. Stuttgart: Fraunhofer IRB Verlag 1999 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  46. [23] Errington, M.; Childe, S. J.: A business process model of inspection in remanufacturing. Journal of Remanufacturing 3 (2013) 7, doi.org/10.1186/2210–4690–3–7 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  47. [24] Erdmann, J. G.; Koller, J.; Brimaire, J. et al.: Assessment of the Disassemblability of Electric Bicycle Motors for Remanufacturing. Journal of Remanufacturing 13 (2023) 2, pp. 137–159 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  48. [25] Sprenger, K.; Klein, J.-F.; Wurster, M. et al.: Industrie 4.0 im Remanufacturing. Industrie 4.0 Management 2021 (2021) 4, pp. 37–40 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  49. [26] Yang, S.; M. R., A. R.; Kaminski, J. et al.: Opportunities for Industry 4.0 to Support Remanufacturing. Applied Sciences 8 (2018) 7, #1177 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  50. [27] Ahmeti, E.; Erdmann, J. G.; Herold, M. et al.: Demontage, Automation und KI: Das Remanufacturing von Elektrokleingeräten. atp magazin (2024) 8, pp. 20–23 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  51. [28] Kärcher, S.; Grabi, F.; Maier, J. et al.: Automatisierte Montageanalyse und -ablaufplanung. wt Werkstattstechnik online 110 (2020) 10, S. 722–727. Internet: www.werkstattstechnik.de. Düsseldorf: VDI Fachmedien Open Google Scholar DOI: 10.37544/1436-4980-2025-04-14
  52. [1] Armstrong McKay, D. I.; Staal, A.; Abrams, J. F. et al.: Exceeding 1.5°C global warming could trigger multiple climate tipping points. Science 377 (2022) 6611, doi.org/10.1126/science.abn7950 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  53. [2] International Energy Agency: Cars and Vans. . Internet: www.iea.org/energy-system/transport/cars-and-vans#tracking. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  54. [3] European Parliament: EU ban on the sale of new petrol and diesel cars from 2035 explained. Internet: www.europarl.europa.eu/topics/en/article/20221019STO44572/eu-ban-on-sale-of-new-petrol-and-diesel-cars-from-2035-explained. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  55. [4] International Energy Agency: Comparative life-cycle greenhouse gas emissions of a mid-size BEV and ICE vehicle. Stand: 2021. Internet: www.iea.org/data-and-statistics/charts/comparative-life-cycle-greenhouse-gas-emissions-of-a-mid-size-bev-and-ice-vehicle. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  56. [5] Ginster, R.; Blömeke, S.; Popien, J.-L. et al.: Circular battery production in the EU: Insights from integrating life cycle assessment into system dynamics modeling on recycled content and environmental impacts. Journal of Industrial Ecology 28 (2024) 5, pp. 1165–1182 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  57. [6] European Commission: Study on the critical raw materials for the EU 2023. Final report. Publications Office of the European Union, Luxembourg, Stand: 2023. Internet: single-market-economy.ec.europa.eu/publications/study-critical-raw-materials-eu-2023-final-report_en. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  58. [7] European Union: Regulation (EU) 2023/1542 of the European Parliament and of the Council of 12 July 2023 concerning batteries and waste batteries, amending Directive 2008/98/EC and Regulation (EU) 2019/1020 and repealing Directive 2006/66/EC (Text with EEA relevance). Stand: 2023. Internet: eur-lex.europa.eu/eli/reg/2023/1542/oj/eng. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  59. [8] Choux, M.; Pripp, S. W.; Kvalnes, F. et al.: To shred or to disassemble – A techno-economic assessment of automated disassembly vs. shredding in lithium-ion battery module recycling. Resources, Conservation and Recycling 203 (2024), #107430 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  60. [9] Thompson, D. L.; Hyde, C.; Hartley, J. M. et al.: To shred or not to shred: A comparative techno-economic assessment of lithium ion battery hydrometallurgical recycling retaining value and improving circularity in LIB supply chains. Resources, Conservation and Recycling 175 (2021), #105741 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  61. [10] Thompson, D. L.; Hartley, J. M.; Lambert, S. M. et al.: The importance of design in lithium ion battery recycling – a critical review. Green Chemistry 22 (2020) 22, pp. 7585–7603 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  62. [11] Rettenmeier, M.; Eckstein, S.; Hackenbeck, C. et al.: Model-driven evaluation of exoskeletons for efficient traction battery dismantling. Procedia CIRP 130 (2024), pp. 1850–1855 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  63. [12] Rettenmeier, M.; Möller, M.; Sauer, A.: Disassembly technologies of end-of-life automotive battery packs as the cornerstone for a circular battery value chain: A process-oriented analysis. Resources, Conservation and Recycling 209 (2024), #107786 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  64. [13] Harper, G.; Sommerville, R.; Kendrick, E. et al.: Recycling lithium-ion batteries from electric vehicles. Nature 575 (2019) 7781, pp. 75–86 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  65. [14] Wu, X.; Ma, J.; Wang, J. et al.: Progress, Key Issues, and Future Prospects for Li-Ion Battery Recycling. Global Challenges 6 (2022) 12, #2200067 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  66. [15] Gerlitz, E.; Greifenstein, M.; Hofmann, J. et al.: Analysis of the Variety of Lithium-Ion Battery Modules and the Challenges for an Agile Automated Disassembly System. Procedia CIRP 96 (2021), pp. 175–180 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  67. [16] Schäfer, J.; Singer, R.; Hofmann, J. et al.: Challenges and Solutions of Automated Disassembly and Condition-Based Remanufacturing of Lithium-Ion Battery Modules for a Circular Economy. Procedia Manufacturing 43 (2020), pp. 614–619 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  68. [17] Klohs, D.; Offermanns, C.; Heimes, H. et al.: Automated Battery Disassembly—Examination of the Product- and Process-Related Challenges for Automotive Traction Batteries. Recycling 8 (2023) 6, #89 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  69. [18] Miloradović, B.; Bigorra, E. M.; Nolte, T. et al.: Challenges in the Automated Disassembly Process of Electric Vehicle Battery Packs. IEEE International Conference on Emerging Technologies and Factory Automation, ETFA 2023, Sinaia,/Romania, 2023, pp. 1–4, doi.org/10.1109/ETFA54631.2023.10275389 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  70. [19] Hathaway, J.; Contreras, C. A.; Asif, M. E. et al.: Technoeconomic Assessment of Electric Vehicle Battery Disassembly-Challenges and Opportunities From a Robotics Perspective. IEEE Access 13 (2025), pp. 716–733 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  71. [20] Zhou, L.; Garg, A.; Zheng, J. et al.: Battery pack recycling challenges for the year 2030: Recommended solutions based on intelligent robotics for safe and efficient disassembly, residual energy detection, and secondary utilization. Energy Storage 3 (2021) 3, e190 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  72. [21] Rehman, S.; Al-Greer, M.; Burn, A. S. et al.: High-Volume Battery Recycling: Technical Review of Challenges and Future Directions. Batteries 11 (2025) 3, #94 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  73. [22] Windisch-Kern, S.; Gerold, E.; Nigl, T. et al.: Recycling chains for lithium-ion batteries: A critical examination of current challenges, opportunities and process dependencies. Waste Management 138 (2022), pp. 125–139 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  74. [23] Fan, E.; Li, L.; Wang, Z. et al.: Sustainable Recycling Technology for Li-Ion Batteries and Beyond: Challenges and Future Prospects. Chemical Reviews 120 (2020) 14, pp. 7020–7063 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  75. [24] Elwert, T.; Goldmann, D.; Römer, F. et al.: Current Developments and Challenges in the Recycling of Key Components of (Hybrid) Electric Vehicles. Recycling 1 (2016) 1, pp. 25–60 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  76. [25] Yu, X.; Li, W.; Gupta, V. et al.: Current Challenges in Efficient Lithium-Ion Batteries‘ Recycling: A Perspective. Global Challenges 6 (2022) 12, #2200099 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  77. [26] Elwert, T.; Römer, F.; Schneider, K. et al.: Recycling of Batteries from Electric Vehicles. In: Pistoia, G.; Liaw, B. Y. (eds.): Behaviour of lithium-ion batteries in electric vehicles. Battery health, performance, safety, and cost. Cham: Springer 2018, pp. 289–321 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  78. [27] Lander, L.; Tagnon, C.; Nguyen-Tien, V. et al.: Breaking it down: A techno-economic assessment of the impact of battery pack design on disassembly costs. Applied Energy 331 (2023), #120437 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  79. [28] Glöser-Chahoud, S.; Huster, S.; Rosenberg, S. et al.: Industrial disassembling as a key enabler of circular economy solutions for obsolete electric vehicle battery systems. Resources, Conservation and Recycling 174 (2021), #105735 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  80. [29] Pražanová, A.; Míka, M. H.; Knap, V.: Lithium-ion battery module-to-cell: disassembly and material analysis. Journal of Physics: Conference Series 2382 (2022) 1, #012002, doi.org/10.1088/1742–6596/2382/1/012002 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  81. [30] Jin, T.; Singer, G.; Liang, K. et al.: Structural batteries: Advances, challenges and perspectives. Materials Today 62 (2023), pp. 151–167 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  82. [31] Beghi, M.; Braghin, F.; Roveda, L.: Enhancing Disassembly Practices for Electric Vehicle Battery Packs: A Narrative Comprehensive Review. designs 7 (2023) 5, #109, doi.org/10.3390/designs7050109 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  83. [32] Kampker, A.; Heimes, H. H.; Ordung, M. et al.: Evaluation Of A Remanufacturing For Lithium Ion Batteries From Electric Cars. International Journal of Mechanical and Mechatronics Engineering 3 (2016), pp. 1929–1935 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  84. [33] Wegener, K.; Andrew, S.; Raatz, A. et al.: Disassembly of Electric Vehicle Batteries Using the Example of the Audi Q5 Hybrid System. TS 2014 – CIRP Conference on Assembly Systems and Tech Conference on Assembly Technologies and Systems 23 (2014), pp. 155–160 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  85. [34] Rosenberg, S.; Huster, S.; Baazouzi, S. et al.: Field Study and Multimethod Analysis of an EV Battery System Disassembly. Energies 15 (2022) 15, #5324 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  86. [35] Meng, K.; Xu, G.; Peng, X. et al.: Intelligent disassembly of electric-vehicle batteries: a forward-looking overview. Resources, Conservation and Recycling 182 (2022), #106207 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  87. [36] Zhang, S.; Zhang, Y.; Wang, Z. et al.: Design and Implementation of a Multifunctional Screw Disassembly Workstation. 16th International Conference, ICIRA 2023, Proceedings, Part VIII 14274 LNAI (2023), pp. 506–519 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  88. [37] Rettenmeier, M.; Sauer, A.; Möller, M.: Laser-based battery pack disassembly: a compact benchmark analysis for separation technologies. Procedia CIRP 122 (2024), pp. 181–186 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  89. [38] Rettenmeier, M.; Schilling, N. J.; Möller, M. et al.: Laser-based disassembly of end-of-life automotive traction batteries: A systematic patent analysis. World Patent Information 79 (2024), #102322 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  90. [39] Zorn, M.; Ionescu, C.; Klohs, D. et al.: An Approach for Automated Disassembly of Lithium-Ion Battery Packs and High-Quality Recycling Using Computer Vision, Labeling, and Material Characterization. Recycling 7 (2022) 4, #48 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  91. [40] Baazouzi, S.; Rist, F. P.; Weeber, M. et al.: Optimization of Disassembly Strategies for Electric Vehicle Batteries. Batteries 7 (2021) 4, #74 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  92. [41] Ali, H.; Khan, H. A.; Pecht, M.: Preprocessing of spent lithium-ion batteries for recycling: Need, methods, and trends. Renewable and Sustainable Energy Reviews 168 (2022), #112809 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  93. [42] Wang, X.-T.; Gu, Z.-Y.; Ang, E. H. et al.: Prospects for managing end‐of‐life lithium‐ion batteries: Present and future. Interdisciplinary Materials 1 (2022) 3, pp. 417–433 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  94. [43] Zang, Y.; Wang, Y.; Yang C. et al.: Robotic disassembly of electric vehicle batteries: an overview. 27th International Conference on Automation and Computing: Smart Systems and Manufacturing (ICAC) 2022, Bristol, United Kingdom, 2022, pp. 1–6 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  95. [44] Yang, J.; Gu, F.; Guo, J.: Environmental feasibility of secondary use of electric vehicle lithium-ion batteries in communication base stations. Resources, Conservation and Recycling 156 (2020), #104713 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  96. [45] Tan, W. J.; Chin, C. M. M.; Garg, A. et al.: A hybrid disassembly framework for disassembly of electric vehicle batteries. International Journal of Energy Research 45 (2021) 5, pp. 8073–8082 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  97. [46] Gerbers, R.; Wegener, K.; Dietrich, F. et al.: Safe, Flexible and Productive Human-Robot-Collaboration for Disassembly of Lithium-Ion Batteries. In: Kwade, A.; Diekmann, J. (eds.): Recycling of Lithium-Ion Batteries. Cham: Springer International Publishing 2018, pp. 99–126 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  98. [47] Rettenmeier, M.; Petrik, D.; Möller, M. et al.: A modeling framework and benchmark for end-of-life automotive traction battery pack forecasting. Journal Of Cleaner Production 491 (2025), #144752 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  99. [48] Harper, G.; Kendrick, E.; Anderson, P. et al.: Roadmap for a sustainable circular economy in lithium-ion and future battery technologies. Journal of Physics: Energy 5 (2023) 2, #021501 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  100. [49] Borchardt, I.; Finkbeiner, S.: Approach for a Systematic Assessment of Electrical Risks During Disassembly of Traction Batteries. 10th Annual World Conference of the Society for Industrial and Systems Engineering (2021), pp. 26–32 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-21
  101. [1] Bundesministerium für Umwelt, Naturschutz, nukleare Sicherheit und Verbraucherschutz (BMUV): Nationale Kreislaufwirtschaftsstrategie. Stand: 2024. Internet: https://www.bmuv.de/download/nationale-kreislaufwirtschaftsstrategie-nkws. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  102. [2] European Commission: Circular economy action plan. The EU’s new circular action plan paves the way for a cleaner and more competitive Europe. Internet: environment.ec.europa.eu/strategy/circular-economy-action-plan_en. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  103. [3] Die Bundesregierung: Klimaschutzprogramm 2023. Mit großen Schritten zur Klimaneutralität. Stand: 04.10.2023. Internet: www.bundesregierung.de/breg-de/aktuelles/klimaschutzprogramm-2023–2226992. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  104. [4] Fraunhofer-Institut für Produktionsanlagen und Konstruktionstechnik: Kreislaufwirtschaft. Stand: 2025. Internet: www.ipk.fraunhofer.de/de/kompetenzen-und-loesungen/industrietrends/kreislaufwirtschaft.html. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  105. [5] Kirchherr, J.; Reike, D.; Hekkert, M.: Conceptualizing the Circular Economy: An Analysis of 114 Definitions. Resources, Conservation and Recycling 127 (2017), pp. 221–232 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  106. [6] Potting, J.; Worrell, E.; Hekkert, M. P.: Circular Economy: Measuring innovation in the product chain, The Hague: PBL Netherlands Assessment Agency 2017 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  107. [7] Europäische Investitionsbank: Kreislaufwirtschaft – Überblick 2024. Internet: www.eib.org/attachments/lucalli/20240104_circular_economy_overview_2024_de.pdf. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  108. [8] Wiechen, J.; Denter, L.; Wolf, S.: Kreislaufwirtschaft für eine klimaneutrale Industrie. Positionspaper Germanwatch e.V.. Internet: www.germanwatch.org/sites/default/files/germanwatch_kreislaufwirtschaft_fuer_eine_klimaneutrale_industrie_2024_0.pdf. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  109. [9] Agora Industrie, Systemiq: Resilienter Klimaschutz durch eine zirkuläre Wirtschaft. Perspektiven und Potenziale für energieintensive Grundstoffindustrien. Studie. Stand: 2023. Internet: www.agora-industrie.de/fileadmin/Projekte/2022/2022–11_IND_Kreislaufwirtschaft/A-EW_309_Kreislaufwirtschaft_WEB.pdf. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  110. [10] European Commission: Ecodesign for Sustainable Products Regulation. Stand: 04.02.2025. Internet: commission.europa.eu/energy-climate-change-environment/standards-tools-and-labels/products-labelling-rules-and-requirements/ecodesign-sustainable-products-regulation_en. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  111. [11] Europäisches Parlament und Rat: VERORDNUNG (EU) 2024/1781 DES EUROPÄISCHEN PARLAMENTS UND DES RATES vom 13. Juni 2024 zur Schaffung eines Rahmens für die Festlegung von Ökodesign-Anforderungen für nachhaltige Produkte, zur Änderung der Richtlinie (EU) 2020/1828 und der Verordnung (EU) 2023/1542 und zur Aufhebung der Richtlinie 2009/125/EG. Stand: 2024. Internet: https://eur-lex.europa.eu/legal-content/DE/TXT/?uri=OJ:L_202401781. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  112. [12] Martínez Leal, J.; Pompidou, S.; Charbuillet, C. et al.: Design for and from Recycling: A Circular Ecodesign Approach to Improve the Circular Economy. Sustainability 12 (2020) 23,#9861 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  113. [13] Büttner, S.; Handmann, U.; Irrek, W.: Transformation zur Circular Economy. Kleine und mittlere Unternehmen im Wandel begleiten. Heidelberg: Springer-Verlag 2024 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  114. [14] DIN SPEC 91472:2023–06: Remanufacturing (Reman) – Qualitätsklassifizierung für zirkuläre Prozesse. Deutsche Fassung Juni 2023 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  115. [15] Hermandi, C.; Dierke, L.; Grundmann, M. et al.: Potenzialcheck Circular Economy. In: Büttner, S.; Handmann, U.; Irrek, W. (Hrsg.): Transformation zur Circular Economy. Wiesbaden: Springer Fachmedien Wiesbaden 2024, S. 85–96 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  116. [16] Golta, K.: So funktioniert Circular Design. Das Fortschrittsdenken kommt an seine Grenzen. Zeit für eine neue Art, die Welt zu denken – und zu gestalten. Stand: 11.02.2022. Internet: page-online.de/tools-technik/circular-design-prozess-projekte/. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  117. [17] Draser, B.; Sander, E.: Nachhaltiges Design. Herkunft, Zukunft, Perspektiven. München: oekom 2022 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  118. [18] Ellen MacArthur Foundation: Design and the circular economy – deep dive. Stand: 16.09.2019. Internet: www.ellenmacarthurfoundation.org/design-and-the-circular-economy-deep-dive. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  119. [19] CIRCO: Methodology. Internet: www.circonl.nl/international/methodology/. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  120. [20] Stölzle, M.; Giunta, S.; Rietdorf, C. et al.: Towards Sustainable Urban Mobility: Integrating Design for Circular Economy Principles in E-Scooter Development. 35th CIRP Design 2025, 02–04 April 2025, Patras, Greece. [Accepted paper, in press] Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  121. [21] Siwiec, D.; Pacana, A.; Gazda, A.: A New QFD-CE Method for Considering the Concept of Sustainable Development and Circular Economy. Energies 16 (2023) 5, #2474 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  122. [22] Umweltbundesamt: Homepage Ecodesign Kit. Stand: 2025. Internet: ecodesignkit.de/. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  123. [23] CIRCit Nord: Tools – CIRCit Nord. Stand:2025. Internet: circitnord.com/tools/. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  124. [24] DDC – Dansk Design Center: Designing Your Circular Transition. Internet: ddc.dk/tools/designing-your-circular-transition/. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  125. [25] Ellen MacArthur Foundation: Tools and resources to help transition to a circular economy. Stand: 2025. Internet: www.ellenmacarthurfoundation.org/topics/circular-design/tools. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  126. [26] Institute of Design Research Vienna: Circular Design Rules. Stand: 2023. Internet: cdr.tools/. Zugriff am 31.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-30
  127. [1] Dusseldorp, M.: Zielkonflikte der Nachhaltigkeit. Wiesbaden: Springer Fachmedien 2017 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  128. [2] Elkington, J.: Cannibals with forks. The triple bottom line of 21st century business. Oxford, U.K.: Capstone 1997 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  129. [3] Dusseldorp, M.: Die Krux mit Zielkonflikten. TATuP – Zeitschrift für Technikfolgenabschätzung in Theorie und Praxis 27 (2018) 2, S. 61–67, doi.org/10.14512/tatup.27.2.61 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  130. [4] Hahn, T.; Figge, F.; Pinkse, J. et al.: Trade‐offs in corporate sustainability: you can‘t have your cake and eat it. Business Strategy and the Environment 19 (2010) 4, pp. 217–229 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  131. [5] Gbededo, M. A.; Liyanage, K.; Garza-Reyes, J. A.: Towards a Life Cycle Sustainability Analysis: A systematic review of approaches to sustainable manufacturing. Journal of Cleaner Production 184 (2018), pp. 1002–1015 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  132. [6] Koch, D.; Sauer, A.: Identifying and Dealing with Interdependencies and Conflicts between Goals in Manufacturing Companies’ Sustainability Measures. Sustainability 16 (2024). 9, #3817 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  133. [7] Herrmann, C.: Ganzheitliches Life Cycle Management. Nachhaltigkeit und Lebenszyklusorientierung in Unternehmen. Heidelberg: Springer 2010 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  134. [8] Leiden, A.; Thiede, S.; Herrmann, C.: Synergetic Modelling of Energy and Resource Efficiency as well as Occupational Safety and Health Risks of Plating Process Chains. International Journal of Precision Engineering and Manufacturing-Green Technology 9 (2022) 3, pp. 795–815 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  135. [9] Figge, F.; Hahn, T.; Schaltegger, S. et al.: The Sustainability Balanced Scorecard – linking sustainability management to business strategy. Business Strategy and the Environment 11 (2002) 5, pp. 269–284 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  136. [10] Meißner, M.; Myrzik, J.; Wiederkehr, P.: Representation of energy efficiency interdependencies of manufacturing processes on the shop floor level. Procedia CIRP 88 (2020), pp. 252–257 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  137. [11] Huang, A.; Badurdeen, F.: Sustainable Manufacturing Performance Evaluation: Integrating Product and Process Metrics for Systems Level Assessment. Procedia Manufacturing 8 (2017), pp. 563–570 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  138. [12] Kononova, N.; Juraschek, M.; Kohlgrüber, M. et al.: Advanced Sustainability Action Plan: Supporting manufacturing SMEs on a sustainability pathway. Procedia CIRP 122 (2024), pp. 354–359 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  139. [13] Gebler, M.; Warsen, J.; Meininghaus, R. et al.: Implementing Zero Impact Factories in Volkswagen’s Global Automotive Manufacturing System: A Discussion of Opportunities and Challenges from Integrating Current Science into Strategic Management. Sustainability 16 (2024) 7, #3011 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  140. [14] Gerdes, C.; Maier-Speredelozzi, V.: A Case Study for Sustainable Routing in Manufacturing Enterprises. In: Barker, K.; Berry, D.; Rainwater, C. (Hrsg.): IISE Annual Conference and Expo 2018. Orlando, Florida, USA, 2018, pp. 913–918 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  141. [15] Gerbens-Leenes, P.; Moll, H.; Schoot Uiterkamp, A.: Design and development of a measuring method for environmental sustainability in food production systems. Ecological Economics 46 (2003) 2, pp. 231–248 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  142. [16] Erdil, N. O.; Aktas, C. B.; Arani, O. M.: Embedding sustainability in lean six sigma efforts. Journal of Cleaner Production 198 (2018), pp. 520–529. Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  143. [17] Weise, S.; Ali, A.-R.; Cerdas, F. et al.: Determination of circular economy targets based on absolute sustainability: A case study on plastics. Procedia CIRP 122 (2024), pp. 743–747 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  144. [18] Ali, A.-R.; Castillo, M. S.; Cerdas, F. et al.: A stepwise approach for determining absolute environmental sustainability targets for an electric vehicle battery. CIRP Annals 73 (2024) 1, pp. 1–4 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  145. [19] Rüegg-Stürm, J.; Grand, S.: Das St. Galler Management-Modell. Management in einer komplexen Welt. Bern: Haupt Verlag 2019 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  146. [20] Eisenführ, F.; Weber, M.; Langer, T.: Rationales Entscheiden. Heidelberg: Springer 2010. Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  147. [21] Al-Aomar, R.: Sustainability Function Deployment: A system-level design-for-sustainability. In: 2019 IEEE International Systems Conference (SysCon). 2019 IEEE International Systems Conference (SysCon), Orlando, FL, USA, 2019, pp. 1–6 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  148. [22] Yim, H.; Herrmann, C.: Eco-voice of consumer (VOC) on QFD. In: 2003 EcoDesign 3rd International Symposium on Environmentally Conscious Design and Inverse Manufacturing – EcoDesign ‚03, Tokyo, Japan, 2003, pp. 618–625 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  149. [23] Mizuno, S.; Akao, Y.: Quality function deployment: a company-wide quality approach. Tokyo: JUSE Press 1978 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  150. [24] Akao, Y. (Hrsg.): Quality function deployment. Integrating customer requirements into product design. Cambridge, Mass.: Productivity Jurík, L.; Horňáková, N.; Šantavá, E. et al.: Application of AHP method for project selection in the context of sustainable development. Wireless Netorks. 28 (2022) 2, pp. 893–902 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  151. [25] Pattanaik, L. N.; Baug, T. K.; Koteswarapavan, C.: A hybrid ELECTRE based prioritization of conjoint tools for lean and sustainable manufacturing. Production Engineering 13 (2019) 6, pp. 665–673 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  152. [26] Rao, R. V.; Patel, B. K.: Novel method for decision making in the manufacturing environment. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture 225 (2011) 3, pp. 422–434 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  153. [27] Koltze, K.; Souchkov, V.: Systematische Innovation. TRIZ-Anwendung in der Produkt- und Prozessentwicklung. München: Cal Hanser Verlag 2017 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  154. [28] Stehr, J.; Yang, C. J.; Chen, a. L. et al.: A Cladistic and TRIZ-based Approach for Enhancing Decision Making in Technology and Innovation Management. Proceedings of the 17th CIRP International Conference on Life Cycle Engineering, Hefei, China, 2010, no pages Open Google Scholar DOI: 10.37544/1436-4980-2025-04-38
  155. [1] Hingst, L.; Dér, A.; Herrmann, C. et al.: Towards a Holistic Life Cycle Costing and Assessment of Factories: Qualitative Modeling of Interdependencies in Factory Systems. Sustainability 15 (2023) 5, #4478 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  156. [2] Moldavska, A.; Abreu-Peralta, J. V.: Learning Factories for the Operationalization of Sustainability Assessment Tools for Manufacturing: Bridging the Gap between Academia and Industry. Procedia CIRP 54 (2016), pp. 95–100 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  157. [3] European Commission: Gerechte und nachhaltige Wirtschaft: Kommission legt Unternehmensregeln für Achtung der Menschenrechte und der Umwelt in globalen Wertschöpfungsketten fest. Stand: 23.02.2022. Internet: https://ec.europa.eu/commission/presscorner/detail/de/ip_22_1145. Zugriff am 03.04.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  158. [4] Statistisches Bundesamt (Hrsg.): Industrie-Investitionen in Klimaschutz binnen zehn Jahren um 74 % gestiegen. Stand: 28.11.2023. Internet: www.destatis.de/DE/Presse/Pressemitteilungen/2023/11/PD23_N062_32.html. Zugriff am 27.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  159. [5] ifaa – Institut für angewandte Arbeitswissenschaft e. V.: Nachhaltigkeitsmanagement – Handbuch für die Unternehmenspraxis. Gestaltung und Umsetzung von Nachhaltigkeit in kleinen und mittleren Betrieben. Heidelberg: Springer Vieweg 2021 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  160. [6] Chen, D.; Schudeleit, T.; Posselt, G. et al.: A State-of-the-art Review and Evaluation of Tools for Factory Sustainability Assessment. Procedia CIRP 9 (2013), pp. 85–90 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  161. [7] Feng, C.; Huang, S.: The Analysis of Key Technologies for Sustainable Machine Tools Design. Applied Sciences 10 (2020) 3, #731 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  162. [8] Züst, S.; Züst, R.; Schudeleit, T. et al.: Development and Application of an Eco-design Tool for Machine Tools. Procedia CIRP 48 (2016), pp. 431–436 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  163. [9] Domingo, R.; Aguado, S.: Overall Environmental Equipment Effectiveness as a Metric of a Lean and Green Manufacturing System. Sustainability 7 (2015) 7, pp. 9031–9047 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  164. [10] Cercós, M. P.; Calvo, L. M.; Domingo, R.: An exploratory study on the relationship of Overall Equipment Effectiveness (OEE) variables and CO2 emissions. Procedia Manufacturing 41 (2019), pp. 224–232 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  165. [11] Durán, O.; Capaldo, A.; Duran Acevedo, P.: Sustainable Overall Throughputability Effectiveness (S.O.T.E.) as a Metric for Production Systems. Sustainability 10 (2018) 2, p. 362 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  166. [12] Schlagenhauf, T.; Netzer, M.; Fleischer, J.: OEE+ : Ein Vorschlag zur zeitgemäßen Erweiterung der OEE um Nachhaltigkeitsaspekte. wt Werkstattstechnik 112 (2022) 7–8, S. 481–486. Internet: www.werkstattstechnik.de. Düsseldorf: VDI Fachmedien Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  167. [13] Garza-Reyes, J. A.: From measuring overall equipment effectiveness (OEE) to overall resource effectiveness (ORE). Journal of Quality in Maintenance Engineering 21 (2015) 4, pp. 506–527 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  168. [14] Keller, F.; Schultz, C.; Simon, P. et al.: Integration and Interaction of Energy Flexible Manufacturing Systems within a Smart Grid. Procedia CIRP 61 (2017), pp. 416–421 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  169. [15] Dehli, M.: Abwärmenutzung in Industrie und Gewerbe. In: Dehli, M. (Hrsg.): Energieeffizienz in Industrie, Dienstleistung und Gewerbe. Energietechnische Optimierungskonzepte für Unternehmen. Heidelberg: Springer Vieweg 2020, S. 145–201 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  170. [16] Mert, G.; Bohr, C.; Waltemode, S. et al.: Increasing the Resource Efficiency of Machine Tools by Life Cycle Oriented Services. Procedia CIRP 15 (2014), pp. 176–181 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  171. [17] Winroth, M.; Almström, P.; Andersson, C.: Sustainable production indicators at factory level. Journal of Manufacturing Technology Management 27 (2016) 6, pp. 842–873 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  172. [18] Fechter, M.; Dietz, T.: Bewertung der Wandlungsfähigkeit eines Produktionssystems. ARENA2036. Heidelberg: Springer 2020 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  173. [19] Centoamore, P.; Pinto, L. F. R.: Remanufacturing Assessment of Machine Tools under a Circular Economy Perspective: A Resource Conservation Initiative. Sustainability 16 (2024) 8, p. 3109 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  174. [20] Schudeleit, T.; Züst, S.; Weiss, L. et al.: The Total Energy Efficiency Index for machine tools. Energy 102 (2016), pp. 682–693 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  175. [21] Hegab, H. A.; Darras, B.; Kishawy, H. A.: Towards sustainability assessment of machining processes. Journal of Cleaner Production 170 (2018), pp. 694–703 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  176. [22] Gottmann, J.: Produktionscontrolling. Wertströme und Kosten optimieren. Heidelberg: Springer Gabler 2019 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  177. [23] Faulkner, W.; Badurdeen, F.: Sustainable Value Stream Mapping (Sus-VSM): methodology to visualize and assess manufacturing sustainability performance. Journal of Cleaner Production 85 (2014), pp. 8–18 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  178. [24] Hollmann, S.; Klimmer, F.; Schmidt, K. H. et al.: Validation of a questionnaire for assessing physical work load. Scandinavian journal of work, environment & health 25 (1999) 2, pp. 105–114 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-47
  179. [1] Bundesministerium für wirtschaftliche Zusammenarbeit und Entwicklung: Klimaabkommen von Paris. Stand: 2025. Internet: www.bmz.de/de/service/lexikon/klimaabkommen-von-paris-14602. Zugriff am 12.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-55
  180. [2] Mitteilung der Kommission: Der europäische Grüne Deal. Brüssel 11.12.2019. Internet: eur-lex.europa.eu/legal-content/DE/TXT/?qid=1588580774040&uri=CELEX%3A52019DC0640. Zugriff am 12.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-55
  181. [3] Wissenschaftliche Dienste des Deutschen Bundestages: Nationale Klimaschutzziele in Deutschland. Stand: 2023. Internet: www.bundestag.de/resource/blob/988664/b64883e7649ec1fde09e333c8a547a5b/WD-8–071–23-pdf.pdf. Zugriff am 12.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-55
  182. [4] Agora Energiewende: Die Energiewende in Deutschland: Stand der Dinge 2024. Stand: 2025. Internet: www.agora-energiewende.de/publikationen/die-energiewende-in-deutschland-stand-der-dinge-2024. Zugriff am 12.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-55
  183. [5] Bundesministerium der Justiz: Bundes-Klimaschutzgesetz vom 12. Dezember 2019 (BGBl. I S. 2513), das zuletzt durch Artikel 1 des Gesetzes vom 15. Juli 2024 (BGBl. 2024 I Nr. 235) geändert worden ist. Stand: 2019. Internet: www.gesetze-im-internet.de/ksg/BJNR251310019.html. Zugriff am 12.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-55
  184. [6] Bundesministerium der Justiz: Gesetz zur Steigerung der Energieeffizienz in Deutschland: Energieeffizienzgesetz vom 13. November 2023 (BGBl. 2023 I Nr. 309). EnEfG. Stand: 2023. Internet: www.gesetze-im-internet.de/enefg/EnEfG.pdf. Zugriff am 12.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-55
  185. [7] Viebahn, P.; Schüwer, D.; Holz, G. et al.: Dekarbonisierung der industriellen Produktion (DekarbInd). Ganzheitliches Bewertungsschema für Technologien. Stand: 2024. Internet: /www.umweltbundesamt.de/sites/default/files/medien/11850/publikationen/05_2024_cc_dekarblnd_tb1.pdf. Zugriff am 12.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-55
  186. [8] Universität Stuttgart, Institut für Energieeffizienz in der Produktion: Der Energieeffizienz-Index der deutschen Industrie. Stand: 23.01.2025. Internet: https://www.eep.uni-stuttgart.de/eei/. Zugriff am 12.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-55
  187. [9] Torolsan, K.; Grabisch, M.: Energieeffizienz-Index der deutschen Industrie: Ergebnisse der Wintererhebung 2024. Institut für Energieeffizienz in der Produktion. Universität Stuttgart. Stand: 2024. Internet: www.eep.uni-stuttgart.de/dokumente/EEI-Winter-2024_25/EEIndex_Briefing-Event_Wintererhebung-2024.pdf. Zugriff am 13.03.2025 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-55
  188. [10] Sauer, A.; Schneider, C.: Energieeffizienz in der Industrie. München: Carl Hanser Verlag 2021 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-55
  189. [1] Kluth, A.; Kübler, P.: Transparenzmessung in der Produktionslogistik. wt Werkstattstechnik online 108 (2018) 03, S. 143–147 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  190. [2] Ungern-Sternberg, R.: Analyse der Dispositionskomplexität in der wertstromorientierten Variantenfertigung. Dissertation, Universität Stuttgart, 2023 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  191. [3] Wiendahl, H.-H.: Auftragsmanagement der industriellen Produktion. Grundlagen, Konfiguration, Einführung. Berlin: Springer 2011 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  192. [4] Bach, T.; Schuh, G.; Reschke, J.: Produktionsplanung und -steuerung im Kontext von Industrie 4.0. Zeitschrift für wirtschaftlichen Fabrikbetrieb 114 (2019) 12, S. 815–818 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  193. [5] Wiendahl, H.-H.: Situative Konfiguration des Auftragsmanagements im turbulenten Umfeld. Dissertation, Universität Stuttgart, 2002 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  194. [6] Hänggi, R.; Fimpel, A.; Siegenthaler, R.: LEAN Production - einfach und umfassend. Ein praxisorientierter Leitfaden zu schlanken Prozessen mit Bildern erklärt. Berlin: Springer 2021 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  195. [7] Erlach, K.: Wertstromdesign. Der Weg zur schlanken Fabrik. Berlin: Springer Vieweg 2020 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  196. [8] Ohno, T.: Das Toyota-Produktionssystem. Frankfurt/New York: Campus-Verlag 1993 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  197. [9] Gudehus, T.: Logistik. Grundlagen - Strategien - Anwendungen. Heidelberg: Springer 2010 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  198. [10] Lödding, H.: Verfahren der Fertigungssteuerung. Grundlagen, Beschreibung, Konfiguration. Berlin, Heidelberg: Springer Vieweg 2016 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  199. [11] Schönsleben, P.: Handbuch Integrales Logistikmanagement. Operations und Supply Chain Management innerhalb des Unternehmens und unternehmensübergreifend. Berlin: Springer 2024 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  200. [12] Nyhuis, P.; Wiendahl, H.-P.: Logistische Kennlinien. Grundlagen, Werkzeuge und Anwendungen. Berlin: Springer Vieweg 2012 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  201. [13] Wiendahl, H.-P.; Wiendahl, H.-H.: Betriebsorganisation für Ingenieure. München: Hanser 2019 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  202. [14] Verein Deutscher Ingenieure: VDI 3601. Warehouse-Management-Systeme. Berlin: Beuth Verlag 2015 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  203. [15] Baltes, O.; Daniel, M.; Rosenhauer, J. et al.: Materialwirtschaft mit SAP S/4HANA. Das Praxishandbuch. Bonn: Rheinwerk Verlag 2022 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  204. [16] Käber, A.: Warehouse Management mit SAP. Effektive Lagerverwaltung mit WM. Bonn: Rheinwerk Verlag 2021 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  205. [17] Licha, I.: Bestandsführung und Kontenfindung mit SAP ERP (MM). Gleichen: Espresso Tutorials GmbH 2022 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  206. [18] Schuh, G.; Stich, V.: Produktionsplanung und -steuerung 1. Grundlagen der PPS. Berlin: Springer 2012 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  207. [19] Wehking, K.-H.: Technisches Handbuch Logistik 2. Fördertechnik, Materialfluss, Intralogistik. Berlin: Springer 2020 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  208. [20] Kletti, J.; Rieger, J.: Die Perfekte Produktion. Manufacturing Excellence in der Smart Factory. Wiesbaden: Springer Vieweg 2023 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  209. [21] Bauernhansl, T.; Krüger, J.; Reinhart, G. et al.: WGP-Standpunkt Industrie 4.0. Darmstadt 2016 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  210. [22] Ungern-Sternberg, R.; Merz, C. K.: Design Guidelines For Digital Kanban Systems With High Service Level. Proceedings of the Conference on Production Systems and Logistics (2023) 2, S. 824–836 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-63
  211. [1] Fang, X.; Kloska, T.: Hybrid forming of sheet metals with long Fiber-reinforced thermoplastics (LFT) by a combined deep drawing and compression molding process. International Journal of Material Forming 13 (2020), pp. 561–575, doi.org/10.1007/s12289–019–01493–4 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-73
  212. [2] Lin, Y.; Min, J.; Teng, H. et al.: Flexural Performance of Steel–FRP Composites for Automotive Applications. Automotive Innovation 3 (2020), pp. 280–295, doi.org/10.1007/s42154–020–00109-x Open Google Scholar DOI: 10.37544/1436-4980-2025-04-73
  213. [3] Kavitha, K.; Vijayan, R.; Sathishkumar, T.: Fiber-metal laminates: a review of reinforcement and formability characteristics. Materials Today. Proceedings 22 (2020), pp. 601–605, doi.org/10.1016/j.matpr.2019.08.232 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-73
  214. [4] Reisgen, U.; Schiebahn, A.; Lotte, J. et al.: Innovative joining technology for the production of hybrid components from FRP and metals. Journal of Materials Processing Technology 282 (2020), doi.org/10.1016/j.jmatprotec.2020.116674 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-73
  215. [5] Drössler, R.; Waffler, R.; Krahl, M. et aö.: Tool technology for lightweight structures in 3-D hybrid designs. Lightweight Design Worldwide 11 (2018), pp. 42–47, doi.org/10.1007/s41777–018–0040-x Open Google Scholar DOI: 10.37544/1436-4980-2025-04-73
  216. [6] Lee, M.; Seo, H.; Kang, C.: Comparison of collision test results for center-pillar reinforcements with TWB and CR420/CFRP hybrid composite materials using experimental and theoretical methods. Composite Structures 168 (2017), pp. 698–709, doi.org/10.1016/j.compstruct.2017.02.068 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-73
  217. [7] Sheikh-Ahmad, J.: Machining of polymer composites. New York: Springer- 2009, doi.org/10.1007/978–0–387–68619–6 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-73
  218. [8] Nguyen-Dinh, N.; Hejjaji, A.; Zitoune, R. et al.: Machining of FRP Composites: Surface Quality, Damage, and Material Integrity: Critical Review and Analysis. In: Sidhu, S.; Bains, P.; Zitoune, R et al.. (eds) Futuristic Composites. Materials Horizons: From Nature to Nanomaterials. Singapore: Springer 2018, doi.org/10.1007/978–981–13–2417–8_1 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-73
  219. [9] Fleischer, J.; Teti, R.; Lanza, G. et al.: Composite materials parts manufacturing. CIRP Annals 67 (2018) 2, pp. 603–626, doi.org/10.1016/j.cirp.2018.05.005 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-73
  220. [10] Ge, J.; Catalanotti, G.; Falzon, B. et al.: Process characteristics, damage mechanisms and challenges in machining of fibre reinforced thermoplastic polymer (FRTP) composites: A review. Composites Part B: Engineering 273 (2024) #111247, doi.org/10.1016/j.compositesb.2024.11124 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-73
  221. [11] Bhatnagar, N.; Singh, I.; Nayak, D.: Damage Investigation in Drilling of Glass Fiber Reinforced Plastic Composite Laminates. Materials and Manufacturing Processes, 19 (2004) 6, pp. 995–1007, doi.org/10.1081/AMP-200034486 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-73
  222. [12] Wang, F.; Zhao, M.; Fu, R. et al.: Novel chip-breaking structure of step drill for drilling damage reduction on CFRP/Al stack. Journal of Materials Processing Technology 291 (2021) #117033, doi.org/10.1016/j.jmatprotec.2020.117033. Open Google Scholar DOI: 10.37544/1436-4980-2025-04-73
  223. [13] Uhlmann, E.; Sammler, F.; Richarz, S. et al.: Machining of Carbon and Glass Fibre Reinforced Composites. Procedia CIRP 46 (2016), pp. 63–66, doi.org/10.1016/j.procir.2016.03.197 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-73
  224. [14] Gebhardt, A.; Esch, P.; Hertrich, M.: Bohrbearbeitung von Luftfahrt-Stack-Werkstoffen. Lightweight Design 9 (2016) 4, pp. 12–15, doi.org/10.1007/s35725–016–0037–5 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-73
  225. [15] Modler, N.; Adam, F.; Maaß, J. et al.: Intrinsic Lightweight Steel-Composite Hybrids for Structural Components. Materials Science Forum 825–826 (2015), pp. 401–408, doi.org/10.4028/www.scientific.net/msf.825–826.401 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-73
  226. [16] Bader, B.; Berlin, W.; Demes, M.: Multimaterialbauweise in der Fahrzeugstruktur. ATZ Produktion 7 (2020) 3–4, pp. 34–39, doi.org/10.1007/s35726–020–0089–9 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-73
  227. [1] Sonsino, C. M.: „Dauerfestigkeit“ - Eine Fiktion. Konstruktion 4 (2005), S. 87–92 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-82
  228. [2] DIN EN ISO/ASTM 52900:2022-03: Additive Fertigung - Grundlagen - Terminologie (ISO/ASTM 52900:2021); Deutsche Fassung EN ISO/ASTM 52900:2021, DOI: 10.31030/3290011 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-82
  229. [3] Basquin, O. H.: The exponential law of endurance tests, 1910, S. 625–630 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-82
  230. [4] Coffin, L. F.: A study of the effects of cyclic thermal stresses on a ductile metal. Trans. ASME 76 (1954), S. 931–981 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-82
  231. [5] Manson, S. S.: Fatigue: a complex subject – some simple approximations. Experimental Mechanics 5 (1965) 7, S. 193–226 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-82
  232. [6] Morrow, J. D.: Cyclic plastic strain energy and fatigue of metals. In: ASTM STP 378. American Society for Testing and Materials (ASTM) 1965, S. 45–87 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-82
  233. [7] Ramberg, W.; Osgood, W. R.: NACA technical notes, No. 902, Description of stress-strain curves by three parameters, National Advisory Committee for Aeronautics (NACA), 1943 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-82
  234. [8] Wagener, R.: Zyklisches Werkstoffverhalten bei konstanter und variabler Beanspruchungsamplitude, Dissertation: IMAB, TU Clausthal, Clausthal-Zellerfeld (2007) Open Google Scholar DOI: 10.37544/1436-4980-2025-04-82
  235. [9] Wagener, R.; Melz, T.: Deriving a Continuous Fatigue Life Curve from LCF to VHCF. SAE Technical Paper 2017-01-0330, 2017, DOI: 10.4271/2017-01-0330 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-82
  236. [10] VDA Recommendation 239-300: Experimental Determination of Mechanical Properties of Aluminum Sheets for CAE-Calculation – Testing and Documentation, February 2021 (2021) Open Google Scholar DOI: 10.37544/1436-4980-2025-04-82
  237. [11] Möller, B.; Kiel, M.; Wagener, R., Taliani, E.; Kordaß, R.; Schramm, M.; Gradinger, R.: Development and fatigue assessment of wire arc additively manufactured hollow structures made of AA6063 as a basis for functional integrated sections applied to a motorcycle handlebar. Procedia Structural Integrity 53 (2024), S. 190–202, DOI: 10.1016/j.prostr.2024.01.024 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-82
  238. [12] Wagener, R.; Kiel, M.: Deriving Representative Structural Elements for the fatigue approach of Wire Arc Additively Manufactured components. Procedia Structural Integrity 53 (2024), S. 161–171, DOI: 10.1016/j.prostr.2024.01.019 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-82
  239. [13] Wagener, R; Melz, T.; Fischer, C.; Matthias, M.; Kaufmann, H.: Neue experimentelle Methoden zur Untersuchung des Einflusses variabler zyklischer Belastungen in HCF- und VHCF-Bereich. Materialwissenschaft und Werkstofftechnik 42 (2011) 10, S. 929-933, DOI: 10.1002/mawe.201100866 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-82
  240. [14] Wagener, R.; Möller, B.; Scurria, M.; Bein, T.: A fatigue life approach for additively manufactured structures. TMS 2020, 149th Annual Meeting & Exhibition Supplemental Proceedings, The Minerals, Metals and Materials Society (TMS Annual Meeting and Exhibition) 2020, FS 127-137, DOI: 10.1007/978-3-030-36296-6_12 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-82
  241. [15] Wagener, R.; Chiocca, A.: Representative structure elements for the fatigue assessment of additively manufactured components. Procedia Structural. Integrity 34 (2021), S. 259–265, DOI: 10.1016/j.prostr.2021.12.037 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-82
  242. [16] Wagener, R.; Kiel, M.: Enhancing the fatigue life approach by the usage of Representative Structural Elements. Procedia Structural Integrity 53 (2024), S. 151-160, DOI: 10.1016/j.prostr.2024.01.019 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-82
  243. [17] Schnabel, K.; Baumgartner, J.; Möller, B.: Fatigue Assessment of Additively Manufactured Metallic Structures Using Local Approaches Based on Finite-Element Simulations. Procedia Structural Integrity 19 (2019), S. 442-451. DOI: 10.1016/j.prostr.2019.12.048 Open Google Scholar DOI: 10.37544/1436-4980-2025-04-82

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