Development and experimental investigation of duplex turning process

doi:10.1007/s40436-017-0177-6

摘要/Abstract

摘要：

The aim of the present study was to develop a novel turning process with the simultaneous application of two cutting tools in place of a single cutting tool during machining of rotating surfaces. This process is referred to as duplex turning, and is used to eliminate the need for a secondary final cut operation following the turning process. To achieve this, a secondary (auxiliary) tool post is mounted on the cross slide of the centre lathe machine after fabrication. The secondary tool post is used to hold a secondary cutting tool that penetrates the workpiece from opposite side of the primary cutting tool to perform the finish cut operation during turn machining of the cylindrical workpiece. The performance of the developed process was tested on AISI 1040 alloy steel, using two single point cutting tools made of high speed steel. The effects of cutting velocity, feed rate, primary depth of cut and secondary depth of cut were analyzed and discussed with regard to average surface roughness, and were also compared with normal turning process. From the results, it was concluded that duplex turning process was capable of providing better surface finishes compared to those generated by normal turning. It was also found that higher cutting velocity yielded better surface finishes within the determined ranges of the selected parameters.

关键词: Cutting, Design of experiment, Machining, Surface roughness, Turning

Abstract:

Key words: Cutting, Design of experiment, Machining, Surface roughness, Turning

Ravindra Nath Yadav. Development and experimental investigation of duplex turning process[J]. Advances in Manufacturing, 2017, 5(2): 149-157.

参考文献

1. Lal GK (1994) Introduction to machining science. New Age International Publisher, New Delhi
2. Saini M, Yadav RN, Kumar S (2015) An overview on turning process. In: Proceedings of 1st international conference on advancements and recent innovations in mechanical, production and industrial engineering (ARIMPIE-2015), vol 2. ITS Engineering College Greater Noida, India, pp, 377-386
3. Yildiz AR (2012) A comparative study of population-based optimization algorithms for turning operations. Inf Sci 210:81-88
4. Grzesik W (2008) Influence of tool wear on surface roughness in hard turning using differently shaped ceramic tools. Wear 265:327-335
5. Dhar NR, Kamruzzaman M, Ahmed M (2006) Effect of minimum quantity lubrication (MQL) on tool wear and surface roughness in turning AISI-4340 steel. J Mater Process Technol 172:299-304
6. Munawar M, Chen JC, Mufti NA (2011) Investigation of cutting parameters effect for minimization of surface roughness in internal turning. Int J Precis Eng Manuf 12:121-127
7. Das SR, Dhupal D, Kumar A (2015) Study of surface roughness and flank wear in hard turning of AISI 4140 steel with coated ceramic inserts. J Mech Sci Technol 29:4329-4340
8. Balasundaram MK, Ratnam MM (2014) In-process measurement of surface roughness using machine vision with sub-pixel edge detection in finish turning. Int J Precis Eng Manuf 15:2239-2249
9. Jia P, Zhou M (2012) Tool wear and its effect on surface roughness in diamond cutting of glass soda-lime. Chin J Mech Eng 25:1224-1230
10. Krolczyk GM, Legutko S (2014) Experimental analysis by measurement of surface roughness variations in turning process of duplex stainless steel. Metrol Meas Syst 21:759-770
11. Wojciechowski S, Twardowski P, Wieczorowski M (2014) Surface texture analysis after ball end milling with various surface inclination of hardened steel. Metrol Meas Syst 21:145-156
12. Cheung CF, Lee WB (2000) Study of factors affecting the surface quality in ultra-precision diamond turning. Mater Manuf Process 15:481-502
13. Cheung CF, Lee WB (2001) Characterisation of nano surface generation in single-point diamond turning. Int J Mach Tool Manuf 41:851-875
14. Duong TH, Kim CH, Lee DU (2013) Selection of machining conditions for microchannels in ultraprecision diamond turning. Proc IMechE Part B: J Eng Manuf 227:1558-1570
15. Jung HS (2009) Environmentally conscious hard turning of cemented carbide materials on the basis of micro-cutting in SEM (2nd report): stress turning with three kinds of cutting tools. J Mech Sci Technol 23:1959-1966
16. Kalidasan R, Ramanuj V, Sharma VK et al (2014) Influence of cutting parameters and offset distance over cutting tool vibration in multi tool turning process. Adv Mater Res 984-985:100-105
17. Maruda RW, Krolczyk GM, Feldshtein E et al (2016) A study on droplets sizes, their distribution and heat exchange for minimum quantity cooling lubrication (MQCL). Int J Mach Tools Manuf 100:81-92
18. Krolczyk G, Maruda R, Nieslony P et al (2016) Surface morphology analysis of duplex stainless steel (DSS) in clean production using the power spectral density. Measurement 94:464-470
19. Arif M, Stroud AI, Akten O (2014) A model to determine the optimal parameters for sustainable-energy machining in a multipass turning operation. Proc IMechE Part B: J Eng Manuf 228:866-877
20. Hodgson T, Trendler P, Ravignani G (2001) Turning hardened tool steels with cubic boron nitride inserts. Ann CIRP 30:63-66
21. Aslan E (2005) Experimental investigation of cutting tool performance in high speed cutting of hardened X210 Cr12 cold-work tool steel (62 HRC). Mater Des 26:21-27
22. Bouacha K, Yallese MA, Khamel S et al (2014) Analysis and optimization of hard turning operation using cubic boron nitride tool. Int J Refract Metal Hard Mater 45:160-178
23. Dureja JS, Singh R, Bhatti MS (2014) Optimizing flank wear and surface roughness during hard turning of AISI D3 steel by Taguchi and RSM methods. Prod Manuf Res 2:767-783
24. Bartarya G, Choudhury SK (2014) Influence of machining parameters on forces and surface roughness during finish hard turning of EN 31 steel. Proc IMechE Part B: J Eng Manuf 228:1068-1080
25. Bhandari VB (2007) Design of machine elements. TMH Publishing Ltd., New Delhi
26. Ahamed AR, Asokan P, Aravindan S et al (2008) Drilling of hybrid Al-5%SiC_p-5%B₄C_p metal composites. Int J Adv Manuf Technol 49:871-877
27. Montgomery DC (2013) Design and analysis of experiments. Wiley India, New Delhi
28. Yadav RN, Yadava V (2014) A new way of electro-abrasion hybrid machining (EAHM) using slotted-diamond grinding wheel. Int J Manuf Technol Manag 28:132-145

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