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2020 | OriginalPaper | Chapter

Titanium Machining Using Indigenously Developed Sustainable Cryogenic Machining Facility

Authors : Navneet Khanna, Chetan Agrawal

Published in: Materials Forming, Machining and Post Processing

Publisher: Springer International Publishing

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Abstract

This chapter presents details of cryogenic machining of titanium alloys. It discusses different innovative methods used in literature for cryogenic machining of titanium alloys. A detailed methodology is presented to design a sustainable cryogenic fluid delivery setup. It also covers economic aspects of cryogenic machining in comparison to dry machining. Finally, a sustainable liquid nitrogen delivery setup is designed and developed to perform cryogenic machining of Ti-6Al-4V. The design of this retrofittable cryogen delivery solution for a range of available machine tools shall provide a direct cost based impetus for improving machining of such materials, which at present does not exist for indigenous industry. For experimental analyses, three machining process parameters i.e. the cutting speed (v), feed (f) and depth of cut (d), and different machining environment i.e. dry and cryogenic are selected. Response variables selected for this study are surface roughness, resultant force and power consumption. Experiments are designed as per hybrid design of experiments (DoE) technique. Hybrid DoE is a combination of orthogonal array and full factorial methods. To investigate the results, each combination of process parameters are compared under dry and cryogenic machining. Analysis of variance technique (ANOVA) is used to reveal the effect of process parameters on response variables. The results show that better surface finish obtained under cryogenic machining in comparison to dry machining. Results of power consumption suggest suitability of cryogenic machining over dry machining at higher levels of process parameters.

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Pusavec F, Krajnik P, Kopac J (2010) Transitioning to sustainable production—Part I: application on machining technologies. J Clean Prod 18:174–184CrossRef

Narutaki N, Yamane Y, Tashima S, Kuroki H (1997) A new advanced ceramic for dry machining. CIRP Ann—Manuf Technol 46:43–48CrossRef

Shokrani A, Dhokia V, Newman ST (2012) Environmentally conscious machining of difficult-to-machine materials with regards to cutting fluids. Int J Mach Tools Manuf 57:83–101CrossRef

Boswell B, Islam MN, Davies IJ, Ginting YR, Ong AK (2017) A review identifying the effectiveness of minimum quantity lubrication (MQL) during conventional machining. Int J Adv Manuf Technol, 1–20

Kaynak Y, Karaca HE, Noebe RD, Jawahir IS (2013) Tool-wear analysis in cryogenic machining of NiTi shape memory alloys: a comparison of tool-wear performance with dry and MQL machining. Wear 8:51–63CrossRef

Venugopal KA, Paul S, Chattopadhyay AB (2007) Growth of tool wear in turning of Ti-6Al-4V alloy under cryogenic cooling. Wear 262:1071–1078CrossRef

Zurecki Z, Ghosh R, Frey JH, Products A (2003) Investigation of white layers formed in conventional and cryogenic hard turning of steels. In: Proceedings of the IMECE’03, pp 1–10

Gunston B (2009) The Cambridge aerospace dictionary, vol 53

Ezugwu EO (2005) Key improvements in the machining of difficult-to-cut aerospace superalloys. Int J Mach Tools Manuf 45:1353–1367CrossRef

10.

Mathonsi T, Laubscher R, Gupta K (2018) Investigation on high speed machining of titanium grade 2 under MQL conditions. Adv Manuf Technol XXXII. In: Proceedings of 16th international conference on manufacturing research ICMR. 33rd national conference on manufacturing research, 11–13 Sept 2018. IOS Press, Univ. Skövde, Sweden, vol 8, p 69

11.

Khanna N, Davim JP (2015) Design-of-experiments application in machining titanium alloys for aerospace structural components. Meas J Int Meas Confed 61:280–290CrossRef

12.

Gupta K, Laubscher RF (2017) Sustainable machining of titanium alloys: a critical review. Proc Inst Mech Eng Part B J Eng Manuf 231:2543–2560CrossRef

13.

Hong SY (1999) Cryogenic machining. US PATENTS 5,901,623

14.

Hong SY, Ding Y, Jeong J (2002) Experimental evaluation of friction coefficient and liquid nitrogen lubrication effect in cryogenic machining. Mach Sci Technol 6:235–250CrossRef

15.

Wang J, Zou H, Li C, Qiu S, Shen B (2006) The effect of microstructural evolution on hardening behavior of type 17–4PH stainless steel in long-term aging at 350 C. Mater Charact 96:274–280CrossRef

16.

Dandekar CR, Shin YC, Barnes J (2010) Machinability improvement of titanium alloy (Ti-6Al-4V) via LAM and hybrid machining. Int J Mach Tools Manuf 50:174–182CrossRef

17.

Dhananchezian M, Pradeep Kumar M (2011) Cryogenic turning of the Ti-6Al-4V alloy with modified cutting tool inserts. Cryogenics (Guildf) 51:34–40CrossRef

18.

Bordin A, Sartori S, Bruschi S, Ghiotti A (2017) Experimental investigation on the feasibility of dry and cryogenic machining as sustainable strategies when turning Ti6Al4V produced by additive manufacturing. J Clean Prod 142:4142–4151CrossRef

19.

Bordin A, Bruschi S, Ghiotti A, Bariani PF (2015) Analysis of tool wear in cryogenic machining of additive manufactured Ti6Al4V alloy. Wear 328–329:89–99CrossRef

20.

Venugopal KA, Paul S, Chattopadhyay AB (2007) Tool wear in cryogenic turning of Ti-6Al-4V alloy. Cryogenics (Guildf) 47:12–18CrossRef

21.

Ayed Y, Germain G, Melsio AP, Kowalewski P, Locufier D (2017) Impact of supply conditions of liquid nitrogen on tool wear and surface integrity when machining the Ti-6Al-4V titanium alloy. Int J Adv Manuf Technol

22.

Aramcharoen A (2016) Influence of cryogenic cooling on tool wear and chip formation in turning of titanium alloy. Proc CIRP 46:83–86CrossRef

23.

Bermingham MJ, Kirsch J, Sun S, Palanisamy S, Dargusch MS (2011) New observations on tool life, cutting forces and chip morphology in cryogenic machining Ti-6Al-4V. Int J Mach Tools Manuf 51:500–511CrossRef

24.

Bermingham MJ, Palanisamy S, Kent D, Dargusch MS (2012) A comparison of cryogenic and high pressure emulsion cooling technologies on tool life and chip morphology in Ti-6Al-4V cutting. J Mater Process Technol 212:752–765CrossRef

25.

Rotella G, Dillon OW, Umbrello D, Settineri L, Jawahir IS (2014) The effects of cooling conditions on surface integrity in machining of Ti6Al4V alloy. Int J Adv Manuf Technol 71:47–55CrossRef

26.

Ahmed LS, Kumar MP (2015) Cryogenic drilling of Ti–6Al–4V alloy under liquid nitrogen cooling. Mater Manuf Process 31:951–959CrossRef

27.

Sartori S, Moro L, Ghiotti A, Bruschi S (2016) On the tool wear mechanisms in dry and cryogenic turning additive manufactured titanium alloys. Tribol Int 105

28.

Hanenkampa N, Amon S, Gross D (2018) Hybrid supply system for conventional and CO₂/MQL-based cryogenic cooling. In: 8th CIRP conference on high perform cut (HPC 2018), pp 219–222CrossRef

29.

Sun Y, Huang B, Puleo DA, Jawahir IS (2015) Enhanced machinability of Ti-5553 alloy from cryogenic machining: comparison with MQL and flood-cooled machining and modeling. Proc CIRP 31:477–482CrossRef

30.

Schoopa J, Salesb WF, Jawahir IS (2017) High speed cryogenic finish machining of Ti-6Al4V with polycrystalline diamond tools. J Mater Process Tech 250:1–8CrossRef

31.

Mia M, Gupta MK, Lozano JA, Carou D, Pimenov DY, Królczyk G et al (2019) Multi-objective optimization and life cycle assessment of eco-friendly cryogenic N₂ assisted turning of Ti-6Al-4V. J Clean Prod 210:121–133CrossRef

32.

Novella MF, Sartori S, Bellin M, Ghiotti A, Bruschi S (2017) Modelling the thermo-mechanical behavior of a redesigned tool holder to reduce the component geometrical deviations in cryogenic machining. In: 16th CIRP conference on modelling of machining operations 58:347–352

33.

Bordin A, Imbrogno S, Rotella G, Bruschi S, Ghiotti A, Umbrello D (2015) Finite element simulation of semi-finishing turning of electron beam melted Ti6Al4V under dry and cryogenic cooling. Proc CIRP 31:551–556CrossRef

34.

Imbrogno S, Sartori S, Bordin A, Bruschi S, Umbrello D (2017) Machining simulation of Ti6Al4V under dry and cryogenic conditions. Proc CIRP 58:475–480CrossRef

35.

Lequien P, Poulachon G, Outeiro JC, Rech J (2017) Hybrid experimental/modelling methodology for identifying the convective heat transfer coefficient in cryogenic assisted machining. Appl Therm Eng 128:500–507CrossRef

36.

Tahri C, Lequien P, Outeiro JC, Poulachon G (2017) Modelling of machining operations CFD simulation and optimize of LN₂ flow inside channels used for cryogenic machining : application to milling of titanium alloy Ti-6Al-4V. In: 16th CIRP conference on modelling of machining operations 58:584–589

37.

Khanna N, Agrawal C, Joshi V (2017) Zero vapor loss integrated cryogen phase separator. Indian Patents 201721031291 A

38.

Kant G, Sangwan KS (2014) Prediction and optimization of machining parameters for minimizing power consumption and surface roughness in machining. J Clean Prod 83:151–164CrossRef

Title: Titanium Machining Using Indigenously Developed Sustainable Cryogenic Machining Facility
Authors: Navneet Khanna
Chetan Agrawal
Publisher: Springer International Publishing
Book: Materials Forming, Machining and Post Processing
Print ISBN: 978-3-030-18853-5

Electronic ISBN: 978-3-030-18854-2

Copyright Year: 2020
DOI: https://doi.org/10.1007/978-3-030-18854-2_8

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