Zusammenfassung
Strategien zur Steigerung der ökonomischen und ökologischen Leistungsfähigkeit von Unternehmen werden in der Regel aus der lokalen Perspektive verfolgt, wobei Wechselwirkungen zwischen verschiedenen Akteuren einer unternehmensübergreifenden Wertschöpfungskette kaum Berücksichtigung finden. Dies führt häufig zu Problemverschiebungen, Zielkonflikten und letztendlich zu lokalen aber nicht zu globalen Verbesserungen. Vor diesem Hintergrund stellen die Autoren das Konzept einer Toolbox zur Aufdeckung von ungenutzten Ressourceneffizienzpotentialen sowie von Wechselwirkungen lokaler Verbesserungsstrategien und resultierender Zielkonflikte auf Ebene der Wertschöpfungskette vor. Die Anwendbarkeit der Toolbox und daraus resultierende Vorteile werden anhand eines realen Fallbeispiels aus der Industrie illustriert.
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Literaturverzeichnis
Alvandi S, Li W, Schönemann M, Kara S, Herrmann C (2016) Economic and environmental value stream map (E2VSM) simulation for multi-product manufacturing systems. Int. J. Sust. Eng.
Bleicher F, Duer F, Leobner I, Kovacic I, Heinzl B, Kastner W (2014) Co-simulation environment for optimizing energy efficiency in production systems. In: Annals – Manufacturing Technology, Vol. 63, pp 441-44
Blume S, Kurle D, Herrmann C, Thiede S (2017) Toolbox for Increasing Resource Efficiency in the European Metal Mechanic Sector. Akzeptiert zur Veröffentlichung in: Procedia CIRP
Bogdanski G, Schönemann M, Thiede S, Andrew S, Herrmann C (2012) An Extended Energy Value Stream Approach Applied on the Electronics Industry. In: IFIP International Conference on Advances in Production Management Systems, Berlin/Heidelberg/New York: Springer Verlag, pp 65-72
Devoldere T, Dewulf W, Deprez W, Willems B, Duflou JR (2007) Improvement Potential for Energy Consumption in Discrete Part Production Machines. In: Takata S, Umeda Y, editors. Proceedings of the 14th CIRP Conference on Life Cycle Engineering, Berlin/Heidelberg/New York: Springer Verlag, pp 311-316
Duflou JR, Sutherland JW, Dornfeld D, Herrmann C, Jeswiet J, Kara S, Hauschild M, Kellens K (2012) Towards energy and resource efficient manufacturing: A processes and systems ap-proach. In: CIRP Annals – Manufacturing Technology, Vol. 61, pp 587-609
Eisele C (2014) Simulationsgestützte Optimierung des elektrischen Energiebedarfs spanender Werkzeugmaschinen. Aachen: Shaker Verlag
European Commission (2011) Roadmap to a Resource Efficient Europe. COM, 571
Finnveden G, Hauschild MZ, Ekvall T, Guinée J, Heijungs R, Hellweg S, Koehler A, Pennington D, Suh S (2009) Recent developments in Life Cycle Assessment, Journal of Environmental Management, pp 1-21
Ghadimi P, Li W, Kara S, Herrmann C (2014) Integrated Material and Energy Flow Analysis towards Energy Efficient Manufacturing. Procedia CIRP, Vol. 15, pp 117-22
Gontarz A, Züst S, Weiss L, Wegener K (2012) Energetic machine tool modeling approach for energy consumption prediction. 10th Global Conf. on Sust. Man., Istanbul. Zürich, Switzerland: Institute of Machine Tools and Manufacturing, Swiss Federal Institute of Technology
Heinemann T (2016) Energy and Resource Efficiency in Aluminium Die Casting, Berlin/Heidelberg/New York: Springer Verlag
Heinzl B, Rossler M, Popper N, Leobner I, Ponweiser K, Kastner W, Dur NF, Bleicher F, Breitenecker F (2013) Interdisciplinary Strategies for Simulation-Based Optimization of Energy Efficiency in Production Facilities. In: 2013 UKSim 15th International Conference on Computer Modelling and Simulation, pp 304-309
Henriques I, Sadorsky P (2010) Can environmental sustainability be used to manage energy price risk? Energy Economics, Vol. 32. pp 1131-1138
Herrmann C, Thiede S, Kara S, Hesselbach J (2011) Energy oriented simulation of manufacturing systems - Concept and application. In: CIRP Annals – Manufacturing Technology, Vol. 60, pp 45–48
International Organization for Standardization (2006a) ISO 14040:2006: Environmental management – Life cycle assessment – Principles and framework, Geneva
International Organization for Standardization (2006b) ISO 14044:2006: Environmental management – Life cycle assessment – Requirements and guidelines, Geneva
Jahangirian M, Eldabi T, Naseer A, Stergioulas LK, Young T (2010) Simulation in manufacturing and business: A review. In: European Journal of Operational Research, Vol. 203. pp 1-13
Klöpffer W (1997) Life cycle assessment. Environ. In: Environmental Science and Pollution Research, Vol. 4, pp 223-228
Laurent A, Clavreul J, Bernstad A, Bakas I, Niero M, Gentil E, Christensen TH, Hauschild MZ (2014) Review of LCA studies of solid waste management systems - Part II: Methodological guidance for a better practice. In: Waste Management, Vol. 34, pp 589-606
Li W, Alvandi S, Kara S, Thiede S, Herrmann C (2016) Sustainability Cockpit: An integrated tool for continuous assessment and improvement of sustainability in manufacturing. CIRP Annals – Manufacturing Technology, Vol. 65, pp 5-8
Negahban A, Smith JS (2014) Simulation for manufacturing system design and operation: Literature review and analysis. In: Journal of Manufacturing, Vol. 33, pp 241-261
Posselt G, Fischer J, Heinemann T, Thiede S, Alvandi S, Weinert N, Kara S, Herrmann C (2014) Extending Energy Value Stream Models by the TBS Dimension – Applied on a Multi Product Process Chain in the Railway Industry. Procedia CIRP, Vol. 15, pp 80-85
Rother M, Shook J (1999) Learning to See: Value Stream Mapping to Add Value and Eliminate Muda. Cambridge: The Lean Enterprise Institute
Schönemann M, Thiede S, Herrmann C (2014) Integrating Product Characteristics into Extended Value Stream Modeling. Procedia CIRP, Vol. 17, pp 368-373
Schönemann M, Kurle D, Herrmann C, Thiede S (2016) Multi-product EVSM Simulation. Procedia CIRP, Vol. 41, pp 334-339
Seow Y, Rahimifard S (2011) A framework for modelling energy consumption within manufacturing systems. In: CIRP Journal of Manufacturing Science and Technology, Vol. 4, pp 258-264
Sewing E (1994) Die Principal-Agent-Theorie. In: Die Absatzwegewahl des Herstellers: Analyse vor dem Hintergrund der Principal-Agent-Theorie. Wiesbaden: Deutscher Universitätsverlag, S. 46-52
Suh S (2005) Theory of materials and energy flow analysis in ecology and economics. Ecological Modelling, Vol. 189, pp 251-269
Thiede S, Schönemann M, Kurle D, Herrmann C (2016a) Multi-level simulation in manufacturing companies: The waterenergy nexus case. Journal of Cleaner Production, Vol. 139, pp 1118-1127
Thiede S, Li W, Kara S, Herrmann C (2016b) Integrated Analysis of Energy, Material and Time Flows in Manufacturing Systems. Procedia CIRP, Vol. 48, pp 200
Torres MT, Barros MC, Bello PM, Casares JJ, Rodríguez-Blas JM (2008) Energy and material flow analysis: application to the storage stage of clay in the roof-tile manufacture. Energy, Vol. 33, pp 963-973
Weinert N, Chiotellis S, Seliger G (2011) Methodology for planning and operating energy-efficient production systems. CIRP Annals – Manufacturing Technology, Vol. 60, pp 41-44
World Business Council for Sustainable Development (2010) Vision 2050: The new agenda for business, Geneva
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Blume, S., Kurle, D., Herrmann, C., Thiede, S. (2018). Toolbox zur Steigerung der Ressourceneffizienz im metallverarbeitenden Gewerbe. In: Arndt, HK., Marx Gómez, J., Wohlgemuth, V., Lehmann, S., Pleshkanovska, R. (eds) Nachhaltige Betriebliche Umweltinformationssysteme. Springer Gabler, Wiesbaden. https://doi.org/10.1007/978-3-658-20380-1_21
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