CIRP Encyclopedia of Production Engineering

2019 Edition
| Editors: Sami Chatti, Luc Laperrière, Gunther Reinhart, Tullio Tolio

Cleaner Production

  • Joost R. DuflouEmail author
  • Karel Kellens
Reference work entry
DOI: https://doi.org/10.1007/978-3-662-53120-4_6635

Synonyms

Definition

Cleaner production has been defined by the United Nations Environment Programme (UNEP) (UNEP 2012) as “the continuous application of an integrated preventative environmental strategy to processes, products and services to increase efficiency and reduce risks to humans and the environment” (UNEP/DTIE/SCP 1990).

Theory and Application

Functional performance and purchase price have long been the key selection criteria for the purchase of new machine tools. Today, an evolution toward environmentally benign manufacturing can be observed that is stimulated by three drivers: more stringent regulatory mandates and standards (e.g., ISO 14955-1 2014; ISO 50001 2011), competitive economic advantage, and proactive green behavior (Gutowski et al. 2005).

Several complementary techniques and measures toward cleaner production can be applied, ranging from low- or even no-cost solutions to...
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References

  1. Alting L (1995) Life cycle engineering and design. CIRP Ann Manuf Technol 44(2):569–580CrossRefGoogle Scholar
  2. Aurich JC, Herzenstiel P, Sudermann H, Magg T (2008) High-performance dry grinding using a grinding wheel with a defined grain pattern. CIRP Ann Manuf Technol 57(1):357–362CrossRefGoogle Scholar
  3. Bay N, Azushima A, Groche P, Ishibashi I, Merklein M, Morishita M, Nakamura T, Schmid S, Yoshida M (2010) Environmentally benign tribo-systems for metal forming. CIRP Ann Manuf Technol 59(2):760–780CrossRefGoogle Scholar
  4. Bourell D, Leu M, Rosen D (2009) Roadmap for additive manufacturing: identifying the future of freeform processing. University of Texas at Austin, Laboratory for Freeform Fabrication, AustinGoogle Scholar
  5. Brezet H, van Hemel C (1997) EcoDesign: a promising approach to sustainable production and consumption. UNEP, ParisGoogle Scholar
  6. Chen D, Heyer S, Ibbotson S, Salonitis K, Steingrimsson JG, Thiede S (2015) Direct digital manufacturing: definition, evolution, and sustainability implications. J Cleaner Prod 107:615–625CrossRefGoogle Scholar
  7. Dewulf W (2003) A pro-active approach to eco-design: framework and tools. PhD Dissertation, K.U. LeuvenGoogle Scholar
  8. 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 approach. CIRP Ann Manuf Technol 61(2):587–609CrossRefGoogle Scholar
  9. Duflou JR, Tekkaya AE, Haase M, Welo T, Vanmeensel K, Kellens K, Dewulf W, Paraskevas D (2015) Environmental assessment of solid state recycling routes for aluminium alloys: can solid state processes significantly reduce the environmental impact of aluminium recycling? CIRP Annals – Manufacturing Technology 64(1):37–40CrossRefGoogle Scholar
  10. Gutowski T, Murphy C, Allen D, Bauer D, Bras B, Piwonka T, Sheng P, Sutherland JW, Thurston D, Wolff E (2005) Environmentally benign manufacturing: observations from Japan, Europe and the United States. J Clean Prod 13(1):1–17CrossRefGoogle Scholar
  11. Hauschild M, Jeswiet J, Alting L (2005) From life cycle assessment to sustainable production: status and perspectives. CIRP Ann Manuf Technol 54(2):1–21CrossRefGoogle Scholar
  12. Herrmann C, Thiede S, Kara S, Hesselbach J (2011) Energy oriented simulation of manufacturing systems: concept and application. Manuf Technol 60(1):45–48CrossRefGoogle Scholar
  13. ISO 14955-1 (2014) Machine tools – environmental evaluation of machine tools. Part I: design methodology for energy efficient machine tools. International Organization for Standardization, GenevaGoogle Scholar
  14. ISO 50001 (2011) Energy management systems – requirements with guidance for use. International Organization for Standardization, GenevaGoogle Scholar
  15. Kellens K (2013) Energy and resource efficient manufacturing – unit process analysis and optimisation. PhD Dissertation, KU Leuven, ISBN: 978-94-6018-765-0Google Scholar
  16. Kellens K, Dewulf W, Overcash M, Hauschild M, Duflou JR (2012) Methodology for systematic analysis and improvement of manufacturing unit process life cycle inventory (UPLCI). Part 1: methodology description. Int J Life Cycle Assess 17(1):69–78CrossRefGoogle Scholar
  17. Mori M, Fujishima M, Inamasu Y, Oda Y (2011) A study on energy efficiency improvement for machine tools. CIRP Ann Manuf Technol 60(1):145–148CrossRefGoogle Scholar
  18. Paraskevas D, Vanmeensel K, Vleugels J, Dewulf W, Deng Y, Duflou JR (2014) Spark plasma sintering as a solid-state recycling technique: the case of aluminium alloy scrap consolidation. Materials 7(8):5664–5687CrossRefGoogle Scholar
  19. Saidur R, Rahim NA, Hasanuzzaman M (2010) A review on compressed-air energy use and energy savings. Renew Sustain Energy Rev 14(4):1135–1153CrossRefGoogle Scholar
  20. Tekkaya E, Schikorra M, Becker D, Biermann D, Hammer N, Pantke K (2009) Hot profile of AA-6060 aluminium chips. J Mater Process Technol 209(7):3343–3350CrossRefGoogle Scholar
  21. Thiede S (2012) Energy efficiency in manufacturing systems. PhD Dissertation TU Braunschweig, Springer, BerlinGoogle Scholar
  22. United Nations Environment Programme (UNEP) (1990) Division of Technology, Industry, and Economics (DTIE), Sustainable Consumption & Production Branch (SCP), themes: resource efficient and cleaner production. http://www.unep.fr/scp/cp/. Accessed 13 Dec 2012
  23. United Nations Environment Programme (UNEP) www.unep.org. Accessed 13 Dec 2012
  24. United Nations Industrial Development Organization (UNIDO) (2012) Cleaner and sustainable production unit. http://www.unido.org/index.php?id=o5152. Accessed 13 Dec 2012
  25. Wahl E, Vincke K, Himmelsbach M (2011) Recovery of energy from a laser machining system. US patent application publication US2011/0024401Google Scholar
  26. Weinert K, Inasaki I, Sutherland J, Wakabayashi T (2004) Dry machining and minimum quantity lubrication. CIRP Ann Manuf Technol 53(2):511–537CrossRefGoogle Scholar
  27. Weinert N, Chiotellis S, Seliger G (2011) Methodology for planning and operating energy-efficient production systems. CIRP Ann Manuf Technol 60(1):41–44CrossRefGoogle Scholar
  28. Wimmer W, Züst R, Lee K-M (2004) Ecodesign implementation – a systematic guidance on integrating environmental considerations into product development. Springer, DordrechtGoogle Scholar
  29. Yuan C, Zhang T, Rangarajan A, Dornfeld D, Ziemba B, Whitbeck R (2006) A decision-based analysis of compressed air usage patterns in automotive manufacturing. J Manuf Syst 25(4):293–300CrossRefGoogle Scholar
  30. Zein A (2012) Transition towards energy efficient machine tools. PhD dissertation TU Braunschweig, Springer, BerlinGoogle Scholar

Copyright information

© CIRP 2019

Authors and Affiliations

  1. 1.Department of Mechanical EngineeringCentre for Industrial Management, KU LeuvenLeuvenBelgium

Section editors and affiliations

  • Wim Dewulf
    • 1
  1. 1.Science, Engineering and Technology GroupKU Leuwen, Department of Mechanical EngineeringLeuvenBelgium