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Abstract

Estimating the energy consumed by machining process is substantial because it has a large share of environmental effects in the manufacturing industry. In this paper, a generic energy consumption model was developed for milling processes that is able to be applied in all milling machine tools. Energy consumption of each segment was estimated according to power characteristics and parameters extracted from numerical control (NC) codes, then the total energy consumption was estimated by adding energy consumption of the machine components. Energy consumption of milling process was measured and compared in conventional (wet) and minimum quantity lubrication (MQL) conditions. The developed method was verified by comparing the estimated values of energy consumption with experimental results. Various studies have suggested different types of energy consumption modeling with machining, however; only a few studies have focused on the use of these modeling techniques. Thus, the MQL method has been rarely compared with the wet milling in terms of energy consumption. In the proposed model, energy consumption for workpiece adjustment, accounting for a major part of the costs in machining economics was considered for the first time. The results showed that the proposed method is efficient and practical for predicting energy consumption, with the possibility of occurring 5% error. Analysis of the results revealed that using the MQL method in milling process leads to 33% lower power consumption than wet milling and therefore, the MQL method can reduce the cost of production.

Keywords

Milling minimum quantity lubrication power consumption energy consumption model workpiece adjustment 316L stainless steel

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References

Garetti

Taisch

Sustainable manufacturing: trends and research challenges. Prod Plann Control 2012; 23: 83–104.

Wippermann

Gutowski

Denkena

, et al. Electrical energy and material efficiency analysis of machining, additive and hybrid manufacturing. J Cleaner Prod 2020; 251: 119731.

Abdalla

Patel

The performance and oxidation stability of sustainable metalworking fluid derived from vegetable extracts. Proc IMechE, Part B: J Engineering Manufacture 2006; 220: 2027–2040.

Ghosh

Rao

PV.

Application of sustainable techniques in metal cutting for enhanced machinability: a review. J Cleaner Prod 2015; 100: 17–34.

Sanchez

Pombo

Alberdi

, et al. Machining evaluation of a hybrid MQL-CO2 grinding technology. J Cleaner Prod 2010; 18: 1840–1849.

Sinha

Madarkar

Ghosh

, et al. Application of eco-friendly nanofluids during grinding of inconel 718 through small quantity lubrication. J Cleaner Prod 2017; 141: 1359–1375.

Boswell

Islam

Davies

, et al. A review identifying the effectiveness of minimum quantity lubrication (MQL) during conventional machining. Int J Adv Manuf Technol 2017; 92: 321–340.

Rahimifard

Seow

Childs

Minimizing embodied product energy to support energy-efficient manufacturing. CIRP Ann 2010; 59: 25–28.

Verl

Abele

Heisel

, et al. Modular modeling of energy consumption for monitoring and control. In: Glocalized solutions for sustainability in manufacturing – proceedings of the 18th CIRP international conference on life cycle engineering, Braunschweig, Germany, 2-4 May 2011, pp.341–342.

10.

Balogun

Mativenga

PT.

Modeling of direct energy requirements in mechanical machining processes. J Cleaner Prod 2013; 41: 179–186.

11.

Zein

Kara

, et al. An investigation into fixed energy consumption of machine tools. In: Glocalized solutions for sustainability in manufacturing. Berlin: Springer, 2011, pp.268–273.

12.

Kaneko

Horio

Planning method for fixture conditions of work piece in continuous multi-axis controlled machining process with consideration of energy consumption about translational axes of machine tool. Procedia CIRP 2012; 1: 126–131.

13.

Liu

Sealy

Guo

, et al. Energy consumption characteristics in finish hard milling of tool steels. Procedia Manuf 2015; 1: 477–486.

14.

Warsi

Jaffery

Ahmad

, et al. Development and analysis of energy consumption map for high-speed machining of Al 6061-T6 alloy. Int J Adv Manuf Technol 2018; 96: 91–102.

15.

Zein

Kara

, et al. An investigation into fixed energy consumption of machine tools. In: Localized solutions for sustainability in manufacturing. Berlin: Springer, 2011, pp.268–273.

16.

Campatelli

Lorenzini

Scippa

Optimization of process parameters using a response surface method for minimizing power consumption in the milling of carbon steel. J Cleaner Prod 2014; 66: 309–316.

17.

Mori

Fujishima

Inamasu

, et al. A study on energy efficiency improvement for machine tools. CIRP Ann 2011; 60: 145–148.

18.

Liu

, et al. Analysis and estimation of energy consumption for numerical control machining. Proc IMechE, Part B: J Engineering Manufacture 2012; 226: 255–266.

19.

Qin

Guo

, et al. Analysis of minimum quantity lubrication (MQL) for different coating tools during turning of TC11 titanium alloy. Materials 2016; 9: 804. Oct

20.

Khan

Mithu

Dhar

NR.

Effects of minimum quantity lubrication on turning AISI 9310 alloy steel using vegetable oil-based cutting fluid. J Mater Process Technol 2009; 209: 5573–5583.

21.

Vara Prasad

Rao

Murthy

PB.

Mechanistic models for prediction of cutting forces and power consumption considering chip geometry. Proc IMechE, Part E: J Process Mechanical Engineering 2021; 235: 479–488.

22.

Nguyen

Mia

Dang

, et al. Green machining for the dry milling process of stainless steel 304. Proc IMechE, Part B: J Engineering Manufacture 2020; 234: 881–899.

23.

Wang

Liu

Song

, et al. An approach for reducing cutting energy consumption with ultra-high speed machining of super alloy inconel 718. Int J Precis Eng Manuf Green Technol 2020; 7: 35–51.

24.

Huang

, et al. A novel intelligent reasoning system to estimate energy consumption and optimize cutting parameters toward sustainable machining. J Cleaner Prod 2020; 261: 121160.

25.

Guerra-Zubiaga

Mamun

Gonzalez-Badillo

An energy consumption approach in a manufacturing process using design of experiments. Int J Comput Integr Manuf 2018; 31: 1067–1077.

26.

Aramcharoen

Mativenga

PT.

Critical factors in energy demand modeling for CNC milling and impact of tool path strategy. J Cleaner Prod 2014; 78: 63–74.

27.

Kalpakjian

Manufacturing processes for engineering materials. New Delhi: Pearson Education India, 1984.

28.

Lee

Min

BK.

Feed drive model for machine tool energy consumption simulation. Trans N Am Manuf Res Inst SME 2014; 42: 409–416.

29.

Sharma

Tiwari

Dixit

, et al. Investigation into performance of SiO2 nanoparticle based cutting fluid in machining process. Mater Today Proc 2017; 4: 133–141.

30.

Gopal

Prakash

KS.

Minimization of cutting force, temperature and surface roughness through GRA, TOPSIS and Taguchi techniques in end milling of Mg hybrid MMC. Measurement 2018; 116: 178–192.

31.

Zhu

, et al. Investigation of machining Ti-6Al-4V with graphene oxide nano fluids: tool wear, cutting forces and cutting vibration. J Manuf Process 2020; 49: 35–49.

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Comparison of minimum quantity lubrication and wet milling based on energy consumption modeling

Abstract

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