An investigation on quantitative analysis of energy consumption and carbon footprint in the grinding process

Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture

Volumn 228, Issue 6, 2014, Pages 950-956

  Ding, Hui ^a   Guo, Dengyue ^a   Cheng, Kai ^a,b   Cui, Qi ^a  

^a HARBIN INSTITUTE OF TECHNOLOGY   (China)

^b BRUNEL UNIVERSITY   (United Kingdom)

Author keywords

Energy consumption; ERWC modelling; Grinding; Low carbon manufacturing; Machining carbon footprint

Indexed keywords

CARBON DIOXIDE; CARBON FOOTPRINT; ENERGY UTILIZATION; GLOBAL WARMING; MATLAB;

CARBON DIOXIDE EMISSIONS; COLLECTIVE EFFECTS; INTEGRATED MODELLING; LOW-CARBON MANUFACTURING; MATLAB ENVIRONMENT; MODELLING AND SIMULATIONS; RESOURCE UTILIZATIONS; WASTE GENERATION;

GRINDING (MACHINING);

EID: 84904169035     PISSN: 09544054     EISSN: 20412975     Source Type: Journal    
DOI: 10.1177/0954405413508280     Document Type: Article

References (17)

1. Dahmus J and Gutowski T. An environmental analysis of machining. In: 2004 ASME International Mechanical Engineering Congress (IMECE) and RD&D Expo, Anaheim, CA, 13-19 November 2004, pp.1-10. New York: ASME.
2. Li W and Kara S. An empirical model for predicting energy consumption of manufacturing processes: a case of turning process. Proc IMechE, Part B: J Engineering Manufacture 2011; 225(9): 1636-1646.
3. Dietmair A and Verl A. A generic energy consumption model for decision making and energy efficiency optimisation in manufacturing. Int J Sustain Eng 2009; 2(2): 123-133.
4. Tridech S and Cheng K. Low carbon manufacturing: characterisation, theoretical models and implementation. Int J of Man Res 2011; 6(2): 110-121.
5. Behrendt T, Zein A and Min S. Development of an energy consumption monitoring procedure for machine tool. CIRP Ann: Manuf Techn 2012; 61(1): 43-46.
6. He Y, Liu F, Wu T, et al. Analysis and estimation of energy consumption for numerical control machining. Proc IMechE, Part B: J Engineering Manufacture 2012; 226(2): 255-266.
7. Ball PD, Evans S, Levers A, et al. Zero carbon manufacturing facility - towards integrating material, energy, and waste process flows. Proc IMechE, Part B: J Engineering Manufacture 2009; 223(9): 1085-1096.
8. Wang LS, Li GF and Yang LB. Multi-parameter optimization and control of the cylindrical grinding process. J Mater Process Tech 2002; 129(1-3): 232-236.
9. Wang SY and Ding N. Grinding force model of cylindrical vertical grinding processing. J Changchun Univ 2005; 15(6): 1-3.
10. Zhu XH. Basic of mechanics in grinding process. Beijing: China Machine Press, 1988, pp.43-57.
11. Zhou XY. Study and simulation on the dynamic roundness forming model in centreless forming model. MS Thesis, Jiangnan University, Wuxi, China, 2011.
12. Zhang HP. Research on prediction techniques of carbon emission during NC milling processes. MS Thesis, Harbin Institute of Technology, Harbin, China, 2012.
13. Narita H, Kawamura H, Norihisa, et al. Development of prediction system for environmental burden for machine tool operation. JSME Int J C: Mech Sy 2006; 49(4): 1188-1195.
14. Gutowski T, Dahmus J and Thiriez A. Electrical energy requirements for manufacturing processes. In: 13th CIRP international conference on life cycle engineering, Leuven, 31 May-2 June 2006. CIRP Press, 2006.
15. Rajemi MF, Mativenga PT and Jaffery SI. Energy and carbon footprint analysis for machining titanium Ti-6Al-4V Alloy. J Mach Eng 2009; 9(1): 103-112.
16. Kardonowy DN. A power assessment of machining tools. Bachelor of Science Thesis, Mechanical Engineering, Massachusetts Institute of Technology, Cambridge, MA, 2002.
17. Rajemi MF, Mativenga PT and Aramcharoen A. Sustainable machining: selection of optimum turning conditions based on minimum energy considerations. J Clean Prod 2010; 18: 1059-1065.