Development of a cutting edge temperature measurement of end mill tool by using infrared radiation technique

Authors

  • M. A. Kiprawi Department of Mechanical and Manufacturing Engineering, Faculty of Engineering, Universiti Malaysia Sarawak, 94300 Kota Samarahan, Sarawak, Malaysia Phone: +6013-8152273; Fax: +6082-583409
  • A. Yassin Department of Mechanical and Manufacturing Engineering, Faculty of Engineering, Universiti Malaysia Sarawak, 94300 Kota Samarahan, Sarawak, Malaysia Phone: +6013-8152273; Fax: +6082-583409
  • A. M. N. A. Kamaruddin Department of Mechanical and Manufacturing Engineering, Faculty of Engineering, Universiti Malaysia Sarawak, 94300 Kota Samarahan, Sarawak, Malaysia Phone: +6013-8152273; Fax: +6082-583409
  • S. T. S. Shazali Department of Mechanical and Manufacturing Engineering, Faculty of Engineering, Universiti Malaysia Sarawak, 94300 Kota Samarahan, Sarawak, Malaysia Phone: +6013-8152273; Fax: +6082-583409
  • M. S. Islam Department of Mechanical and Manufacturing Engineering, Faculty of Engineering, Universiti Malaysia Sarawak, 94300 Kota Samarahan, Sarawak, Malaysia Phone: +6013-8152273; Fax: +6082-583409
  • M. A. M. Said Department of Mechanical and Manufacturing Engineering, Faculty of Engineering, Universiti Malaysia Sarawak, 94300 Kota Samarahan, Sarawak, Malaysia Phone: +6013-8152273; Fax: +6082-583409

DOI:

https://doi.org/10.15282/jmes.13.1.2019.22.0392

Keywords:

Pyrometer, end milling, infrared radiation, signal processing, cutting temperature

Abstract

This paper describes the development of cutting temperature measurement of end mill tool by using infrared radiation technique approach. Compared to conventional thermocouple technique, infrared radiation technique is an advance method of measuring temperature which featured high accuracy, high response rate, wide range of temperature scale detection and almost compatible with all materials used in the manufacturing industry. We measures the emission of infrared radiation from the source, which is cutting edge of tool by using photocells that contains InAs and InSb photovoltaic detectors. Photocells converts the infrared radiation to a voltage signal and then recorded by oscilloscope followed with a calibration with its corresponding temperature. This paper discussed about the calibration method, cutting experiment setup, the limit of infrared radiation level detected by photocells, signal correction of output signal, and relations of peak signal formation with rotation of end mill tool. The developed pyrometer is also capable to profile the cutting tool’s rotation based on the movements of infrared radiation’s emission at cutting tool’s edge. The conclusion was that the measurement of cutting temperature of high speed machining by using infrared radiation technique is possible. The developed pyrometer are capable to detect temperature changes at a span of 0.01 ms.

References

Hou J, Zhou W, Duan H, Yang G, Xu H, Zhao N. Influence of cutting speed on cutting force, flank temperature, and tool wear in end milling of Ti-6Al-4V alloy. International Journal of Advanced Manufacturing Technology 2014; 70(9–12): 1835–1845.

Abukhshim NA, Mativenga PT, Sheikh MA. Heat generation and temperature prediction in metal cutting: A review and implications for high speed machining. International Journal of Machine Tools and Manufacture 2006; 46(7–8): 782–800.

KaruppannaRaja PG, Rajkumar M, Senthil Kumaran S. A study on backing block arrangement of dissimilar metal joining process of seamless ferritic and austenitic alloy by using an external tool. Journal of Alloys and Compounds 2016; 687(1): 773–785.

Venkatesan K. The study on force, surface integrity, tool life and chip on laser assisted machining of inconel 718 using Nd:YAG laser source. Journal of Advanced Research 2017; 8(4): 407–423.

Sato M, Tamura N, Tanaka H. Temperature Variation in the Cutting Tool in End Milling. Journal of Manufacturing Science and Engineering 2011; 133(2): 21005.

Ueda T, Hosokawa A, Oda K, Yamada K. Temperature on Flank Face of Cutting Tool in High Speed Milling. CIRP Annals - Manufacturing Technology 2001; 50(1): 37–40.

Kiprawi MA, Yassin A, Syed Shazali ST, Islam MS, Mohd Said MA. Study of Cutting Edge Temperature and Cutting Force of End Mill Tool in High Speed Machining. MATEC Web Conference 2017; 87(1): 02030.

Teo CY, Yassin A. Cutting Temperature and Tool Wear Assessment of Turning Process with Minimal Quantity Lubrication. Applied Mechanics and Materials 2015; 761(1): 313–317.

Yassin A, Ueda T, Furumoto T, Hosokawa A, Tanaka R, Abe S. Experimental investigation on cutting mechanism of laser sintered material using small ball end mill. Journal of Materials Processing Technology 2009; 209(15–16): 5680–5689.

Jamaludin, AS, Yassin A. Analysis of laser sintered materials using finite element method. Sains Malaysiana 2013; 42(12): 1727–1733.

Jamaludin, AS, Yassin A, Osman MS. Study on Ball End Milling Process Using Two Dimensional Finite Element Method. Jurnal Mekanikal 2012; 34(1): 1–15.

Zhao GY, Liu ZY, He Y, Cao HJ, Guo YB. Energy consumption in machining: Classification, prediction, and reduction strategy. Energy 2017; 133(1): 142-157.

Liew PJ, Shaaroni A, Sidik NAC, Yan J. An overview of current status of cutting fluids and cooling techniques of turning hard steel. International Journal of Heat and Mass Transfer 2017; 144(1): 380-394.

Sasahara H, Satake K, Takahashi W, Goto M, Yamamoto H. The effect of oil mist supply on cutting point temperature and tool wear in driven rotary cutting. Precision Engineering 2017; 48(1): 158–163.

Yassin A, Teo CY. Effect of Pressure and Nozzle Angle of Minimal Quantity Lubrication on Cutting Temperature and Tool Wear in Turning. Applied Mechanics and Materials 2015; 695(1): 676–679.

Di C, Dinghua Z, Baohai W, Ming L. An Investigation of Temperature and Heat Partition on Tool-chip Interface in Milling of Difficult-to-Machine Materials Procedia CIRP 2017; 58(1): 49–54.

Ma Y, Feng P, Zhang J, Wu Z, Yu D. Prediction of surface residual stress after end milling based on cutting force and temperature. Journal of Materials Processing Technology 2016; 235(1): 41–48.

Ma Y, Yu D, Feng P, Wu Z, Zhang J. Finite element method study on the influence of initial stress on machining process. Advances in Mechanical Engineering 2015; 7(3): 1–10.

Di C, Dinghua Z, Baohai W, Ming L. An investigation of tool temperature in end milling considering the flank wear effect. International Journal of Mechanical Sciences 2017; 131-132(1): 613–624.

Furumoto T, Ueda T, Kobayashi N, Yassin A, Hosokawa A, Abe S. Study on laser consolidation of metal powder with Yb: fiber laser-Evaluation of line consolidation structure. Journal of Materials Processing Technology 2009; 209(18–19): 5973–5980.

Ueda T. 熱輻射線による加工温度計測技術の開発 [Development of Infrared Radiation Pyrometer with Optical Fiber]. Journal of the Japan Society for Precision Engineering 2015; 81(8): 735–739.

Usamentiaga R, Venegas P, Guerediaga J, Vega L, Molleda J, Bulnes F, Infrared Thermography for Temperature Measurement and Non-Destructive Testing. Sensors 2014; 14(7): 12305–12348.

Ueda T, Sato M, Sugita T. Measurement of Tool-Workpiece Interface Temperature by Two-Color Pyrometer. Journal of the Japan Society for Precision Engineering 1995; 61(10): 1448–1452.

Tapetado A, Diaz-Alvarez J, Miguelez MH, Vazquez C. Two-color pyrometer for process temperature measurement during machining. Journal of Lightwave Technology 2016; 34(4): 1380–1386.

Grzesik W. Advanced Machining Processes of Metallic Materials. 2nd ed. Netherland: Elsevier; 2017.

Planck M, Phys A. On the Law of the Energy Distribution in the Normal Spectrum 1901; 4(553): 1–11.

Norton JD. Atoms, entropy, quanta: Einstein’s miraculous argument of 1905. Studies in History and Philosophy of Science Part B: Studies in History and Philosophy of Modern Physics. Elsevier 2006; 37(1): 71–100.

ASTM E20.02. ASTM E2847-14: Standard Test Method for Calibration and Accuracy Verification of Wideband Infrared Thermometers. West Conshohocken: Annual Book of ASTM Standards; 2014.

Jiang F, Liu Z, Yang F, Zhong Z, Sun S. Investigations on tool temperature with heat conduction and heat convection in high-speed slot milling of Ti6Al4V. The International Journal of Advanced Manufacturing Technology 2018; 96(5-8): 1847-1858.

Karatsori TA, Pastorek M, Theodorou CG, Fadjie A, Wichmann N, Desplanque L, Ghibaudo G. Static and low frequency noise characterization of ultra-thin body InAs MOSFETs. Solid-State Electronics 2017; 143(1): 56-61.

Moschetti G, Lefebvre E, Fagerlind M, Nilsson PÅ, Desplanque L, Wallart X, Grahn J. DC, RF and noise performance of InAs/AlSb HEMTs with in situ CVD SiNx-film for early-protection against oxidation. Solid-State Electronics 2013; 87(1): 85–89.

Wörl A, Rehm R, Walther M. Excess noise in InAs/GaSb type-II superlattice pin-photodiodes. Infrared Physics and Technology 2013; 61(1): 5–8.

Wieder HH. Chapter 5: Devices and applications. Intermetallic Semiconducting Films 1970; 248a(249-288):231-248

de Silva CW. Sensors and Actuators: Engineering System Instrumentation. 2nd Ed. Boca Raton: CRC Press, 2015, p 322–340.

Cuomo S, De Pietro G, Farina R, Galletti A, Sannino G. A novel O(n) numerical scheme for ECG signal denoising. Procedia Computer Science 2015; 51(1): 775–784.

Luo Y, Hargraves RH, Belle A, Bai O, Qi X, Ward K, Najarian K. A hierarchical method for removal of baseline drift from biomedical signals: Application in ECG analysis. The Scientific World Journal 2013; 2013(1): 1-10.

Nazarpour K, Al-Timemy AH, Bugmann G, Jackson A. A note on the probability distribution function of the surface electromyogram signal. Brain Research Bulletin 2013; 90(1): 88–91.

Mathworks. Remove Trends from Data. Retrieved from https://www.mathworks.com/help/pdf_doc/signal/signal_tb.pdf; 1 April, 2018.

Putz M, Schmidt G, Semmler U, Oppermann C, Bräunig M, Karagüzel U. Modeling of Heat Fluxes during Machining and Their Effects on Thermal Deformation of the Cutting Tool. Procedia CIRP 2016; 46(1): 611–614.

Schindler S, Zimmermann M, Aurich JC, Steinmann P. Modeling deformations of the workpiece and removal of material when turning. Procedia CIRP 2013; 8(1): 39–44.

Jomaa W, Songmene V, Bocher P. Surface finish and residual stresses induced by orthogonal dry machining of AA7075-T651. Materials 2014; 7(3): 1603–1624.

Furutani K, Sakata A. Reduction of Residual Vibration of Piezoelectric Actuator Driven by Series of Current Pulses. IEEJ Transactions on Sensors and Micromachines 2017; 137(1): 8–14.

Rizal M, Ghani JA, Husni, Husaini. Design and construction of a strain gauge-based dynamometer for a 3-axis cutting force measurement in turning process. Journal of Mechanical Engineering and Sciences (JMES) 2018; 12(4): 4072-4087.

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Published

2019-03-29

How to Cite

[1]
M. A. Kiprawi, A. Yassin, A. M. N. A. Kamaruddin, S. T. S. Shazali, M. S. Islam, and M. A. M. Said, “Development of a cutting edge temperature measurement of end mill tool by using infrared radiation technique”, J. Mech. Eng. Sci., vol. 13, no. 1, pp. 4661–4678, Mar. 2019.

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