Search results

Defect Reduction in Forming Process of Fired Clay Floor Tiles by Six Sigma Approach Wansika Sirimongkol1,a, Parames Chutima1,2,b* and Siriphan Nilpairach3,c 1Industrial Engineering, Faculty of Engineering, Chulalongkorn University, Thailand 2The Royal Society of Thailand 3Metallurgy and Materials Science Research Institute, Chulalongkorn University, Thailand awansika.s@chula.ac.th, bcparames@chula.ac.th, csiripan.n@chula.ac.th Keywords: Defect Reduction, Fired Clay Floor Tiles, Six Sigma Approach Abstract.
"Processing defects in ceramic powders and powder compacts."
Journal of operations Management 26, no. 4 (2008): 536-554
In 2019 IEEE 6th International Conference on Industrial Engineering and Applications (ICIEA), pp. 852-855.
In IOP Conference Series: Materials Science and Engineering, vol. 215, no. 1, p. 012007.

Development of Double-axis Double-rest CNC Machining Center Jie Wang1, a and Lin Zhang1,b 1College of Mechanical-Electrical Engineering, Nanjing University of Aeronautics and Astronautics, Nanjing, Jiangsu, 210016, China awjienuaa@163.com, bzhanglin05@nuaa.edu.cn Keywords: Machining center, multi-body system, topological structure, volumetric error model Abstract.
Table 1 The specification of the machining center Configuration double-axis double-rest CNC machining center Base cast iron Axes X1,Z1,X2 and Z2 axis W axis Spindles Type Aerostatic slideway Aerostatic slideway Ceramic ball bearing Stroke X1,X2:600mm Z1,Z2:2500mm 2300mm N/A Motion accuracy 0.003mm 0.006mm 0.001mm (a) Photograph showing the machining center (b) The configuration of the machining center Fig. 1 The double-axis double-rest CNC machining center The Volumetric Error Model for The Machining Center To reduce the mechanical error and improve processing quality, machining error must be compensated and controlled.
International Journal of Automation Technology 1(2) (2007):78–86
Proceedings of the 12th International Conference on Machine Tool Engineers, (2006) 157–166
International Journal of Machine Tools and Manufacture, 1995, 35( 9): 1321-1337.

Chemical engineering journal, 171(3), pp.811-840
International Journal of Science, Engineering and Technology Research, 4(11), pp.3663-3676
Chemical Engineering Journal, 150(2-3), pp.485-491
Chemical Engineering Journal, 140(1-3), pp.6-14
Chemical engineering journal, 169(1-3), pp.68-77.

Tool Wear Characteristics of TiCn/Al2O3 Coated Carbide Inserts while Turning Glass Fiber Reinforced Epoxy Resin under Cryogenic Cooling, Key Engineering Materials. (2021) [3] Eneyew, E.D. and M.
Rao, Influence of different cooling methods on drill temperature in drilling GFRP, The International Journal of Advanced Manufacturing Technology. (2015) 609-621
Wang, The effect of cutting fluids applied in metal cutting process, Proceedings of the Institution of Mechanical Engineers., Part B: Journal of Engineering Manufacture. (2016) 19-37
Sharifah, Study on tool wear during milling CFRP under dry and chilled air machining, Procedia Engineering. (2017) 506-517
Drill Bit Flank Wear Monitoring System in Composite Drilling Process Using Image Processing, 10th International Conference on Robotics, Vision, Signal Processing and Power Applications. (2019) [18] Celik, A., et al., Investigation on the performance of SiAlON ceramic drills on aerospace grade CFRP composites, Journal of Materials Processing Technology. (2015) 39-47

Study on Shape Recovery Behaviors of Epoxy-based Shape Memory Polymer Bo ZHOU1, 2, a, Xuelian WU1, Yanju LIU3 and Jinsong LENG1, b 1Center of Composite Materials and Structures, Science Park of Harbin Institute of Technology, No.2 Yikuang Street, Harbin 150080, China 2College of Aerospace and Civil Engineering, Harbin Engineering University, No.145 Nantong Street, Harbin 150001, China 3Department of Aerospace Science and Mechanics, Harbin Institute of Technology, No.92 Western Dazhi Street, Harbin 150001, China azhoubo@hrbeu.edu.cn, blengjs@hit.edu.cn Keywords: Shape memory polymer, shape recovery behaviors, shape recovery equation.
Lagoudas: Journal of the Mechanics and Physics of Solids Vol.56 (2008), p.1752 [2] Y.
Lagoudas: Journal of the Mechanics and Physics of Solids Vol.56 (2008), p.1766 [3] H.
Yoon: International Journal of Modern Physics B Vol.23 (2010), p.1248 [7] B.
Li: Key Engineering Materials Vol.419-420 (2010) p.497

Rahman: International Journal of Machine Tools and Manufacture, Vol. 47(1) (2007), p. 75-80 [4] J.W.
Tay: International Journal of Machine Tools and Manufacture, Vol. 47(3-4) (2007), p. 562-569 [6] M.
Ikeda: Precision Engineering, Vol. 18(2-3) (1996), p. 129-137 [10] Y.C.
Moriwaki: International Journal of Machine Tools and Manufacture, Vol. 49(3-4) (2009), p. 339-343 [11] P.N.
Scattergood: Journal of the American Ceramic Society, Vol. 73(4) (1990), p. 949-957

Lofland and S.M.Bhagat: Journal of Applied Physics Vol. 83 (1998), p. 2866-2868 [2] J.
Wong: Journal of Applied Physics Vol. 79 (1996), p. 1910-1812 [3] Soma Das and T.
Arul Raj: International Journal of Hydrogen Energy Vol. 32(2007), p. 4267-4271 [6] ZHOU Ke-sheng, WANG Da and HUANG Ke-long: Trans.Nonferrous Met.
[10] Jiang S P: Journal of Power Sources Vol. 124(2003), p. 390-420 [11] LI Daguang, ZHANG Hongyi and ZHANG Hefeng: Materials Science Vol. 20(2006), p. 296-299 [12] ZHU Baojun, GONG Tao and TANG Yuanhong: Materials Science and Engineering of Powder Metallurgy Vol. 10(2005), p.264-267 [13] Hammouche A, Siebert E and Hammou A: Electrochem Soc Vol. 138(1991), p. 1212-1218 [14] Szabo V, Bassir M and Van Neste A: Environm Vol. 37(2002), p. 175 [15] Wang W and Jiang S P: Solid State Ionies Vol. 177(2006), p.1361-1369
[16] ZHU Baojun, GONG Tao and TANG Yuanhong: Materials Science and Engineering of Powder Metallargy Vol. 10(2005), p. 264-267 [17] LEI Liwen: Wuhan University of Technology Vol. 5(2006), p.7-11

Bhat3,c 1Research Scholar, Mechanical Engineering Department, M.N.I.T.
Jaipur, 302017, India 2Assistant Professor, Mechanical Engineering Department, M.N.I.T.
Kailera, Tribo chemical wear of cutting-tool ceramics in sliding Contact against a nickel-base alloy, Journal of the European Ceramic Society. 36 (2016) 705–717
Kumaraswamidhas, Wear behaviour of Al 2618 alloy reinforced with Si3N4, AlN and ZrB2 in situ composites at elevated temperatures, Alexandria Engineering Journal. 55 (2016) 19–36
Kailera, Tribo chemical wear of cutting-tool ceramics in sliding Contact against a nickel-base alloy, Journal of the European Ceramic Society. 36 (2016) 705–717 [28] P.

Yano 2,c 1 JWRI, Osaka University, 11-1 Mihogaoka, Ibaraki, Osaka 567-0047, JAPAN 2 Graduate School of Engineering, Osaka University, Yamadaoka, Suita, Osaka 567 0047, JAPAN a kobayasi@jwri.osaka-u.ac.jp, bvelu1976@yahoo.co.in, cyano@jwri.osaka-u.ac.jp Keywords: plasma spraying, thermal barrier coating, oxidation, X-ray diffraction, scanning electron microscope, hardness, bond strength, wear resistance.
Fig. 2 shows the microhardness distribution of the ceramic top coatings for as-sprayed condition.
Kobayashi; Proceedings of International Thermal Spray Conference (1992), p. 57
Kitamura; Journal of IAPS Vol. 5 (1997), p. 62
Ghoniem; Journal of IAPS Vol. 9 (2001), p. 113

Analysis of Flowing Characteristics of Abrasive Flow Machining in Slit Zhiguo Dong1, a, Xiaodong Zhang1,b and Yuanzong Li1,c 1 College of Mechanical Engineering Taiyuan Univercity of Technology,Taiyuan,030024, China adong_zhiguo@126.com, bzhangxiaodong@tyut.edu.cn, cliyz@tyut.edu.cn Keywords: Abrasive flow machining, Wall slip, Slip velocity, Grinding force Abstract.
References [1] E.Uhlmann, V.Mihotovic, Modelling the abrasive flow machining process on advanced ceramic materials ,Journal of Materials Processing Technology, Vol. 209 (2009) p. 6062–6066
[2] L.Fang, J.Zhao, B.Li, Movement patterns of ellipsoidal particle in abrasive flow machining, Journal of Materials Processing Technology, Vol. 209 (2009) p. 6048–6056
[3] R.K.Jain, V.K.Jain, Specific energy and temperature determination in abrasive flow machining process, International Journal of Machine Tools & Manufacture, Vol. 41(2001) p. 1689–1704
[4] A.C.Wang, S.H.Weng, Developing the polymer abrasive gels in AFM processs, Journal of Materials Processing Technology, Vol. 192–193 (2007) p. 486–490 [5] V.K.Jain, S.G.Adsul, Experimental investigations into abrasive flow machining, International Journal of Machine Tools & Manufacture, Vol. 40(2000) p. 1003–1021.