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This surface engineering technology enables the generation of dome-shaped, elevated and highly wear resistant microfeatures on tool surfaces in consequence of a localized dispersing of hard ceramic particles via pulsed laser radiation.
For this purpose, a promising surface engineering technique named laser implantation process has been investigated within the scope of this work.
Based on this research work, further investigations with varying laser parameters and hard phase compositions will be performed in future studies, in order to enhance the effectiveness of this surface engineering technology successively.
Tekkaya, A review on hot stamping, Journal of Materials Processing Technology 210 (2010) 2103–2118
Hilgenberg, Microstructural evolution and geometrical properties of TiB2 metal matrix composite protrusions on hot work tool steel surfaces manufactured by laser implantation, The International Journal of Advanced Manufacturing Technology 106 (2020) 481-501

Branda: Ceramics International 19 (1993), pp. 105-111 [8] M.A.
Saitoh: Review of Automotive Engineering 25 (2004), pp. 285-289 [10] W.A.
Bachiorrini: Ceramics International 20 (1994), pp. 169-174 [12] D.
Branda: Journal of the European Ceramic Society 13 (1994), pp. 275-282 [15] L.
Montanaro: Ceramics International 25 (1999), pp. 437-445 [17]A.

Fabrication of Cordierite Honeycomb from Fly Ash Sung-Jin Kim 1,a, Sung-Jin Park1,b, Hee-Gon Bang 1,2,c , Sang-Yeup Park 1,2,d 1 Department of Ceramic Engineering, Kangnung National University, Kangnung, Kangwondo, 210-702, South Korea 2 Technology Innovation Center for Fine Ceramics, Kangnung National University, Kangnung, Kangwondo, 210-702, South Korea a k9s8j7@hotmail.com, bdark sung jin@hanmail.net, chgbang@ kangnung.ac.kr d sypark@knusun.kangnung.ac.kr Keywords: Cordierite, Fly ash, Porous honeycomb filter, Extrusion process Abstract.
References � [1] Jin Yang: Journal of the Korean Ceramic Society Vol.35, No. 4, pp. 399-405 (1998)
[4] Alessandro Bachiorrini, Ceramics International 22, 73-77 (1996)
[6] Young-Bae Kim, Eul-Hoon Cho, Yoon-Young Chang, Hee-Soo Lee and Duck-Kyun Choi: Korean Journal of Material Research Vol. 12, No. 2 (2002)
[7] M.A.Camerucci , G.Urretavizcaya , A.L.Cavalieri: Ceramics International 29 (2003) 159-168.

Series: Materials Science and Engineering. 432 (2018) 1-7
Laonapakul, Synthesis of hydroxyapatite from biogenic wastes, KKU Engineering Journal. 42 (2015) 269-275
Shahrabi, Effect of triethanolamine on the electrophoretic deposition of hydroxyapatite nanoparticles in isopropanol, Ceramics International. 39 (2013) 7007–7013
Abdulkareem, Evaluation of Surface Roughness of 316L Stainless Steel Substrate on Nanohydroxyapatite by Electrophoretic Deposition, Al-Nahrain Journal for Engineering Sciences, 21 (2018) 28-35
Hideki, Hydroxyapatite coating on Ti plate by a dipping method, Bio-medical Materials and Engineering. 5 (1995) 49-58

China; 2Chongqing Engineering Research Center for Material Surface Precision Machining and Whole Set Equipments, Nanqiaosi 16, Jiangbei District, Chongqing, 400021, P.R.
That means that ceramic abrasive grain can produce sharp micro cutting edges continually.
Mamoru: Journal of Japan Society of Lubrication Engineers Vol. 6 (1985), pp: 157-162
Bernd: International Journal of Advanced Manufacturing Technology Vol. 35 (2008), pp: 1090-1099
Sun: Key Engineering Materials Vol. 202-203(2001), pp: 53-56

Dow, "Review of vibration-assisted machining," Precision Engineering, vol. 32, pp. 153-172, 2008
Abdullah, "Investigation of the effect of cutting speed and vibration amplitude on cutting forces in ultrasonic-assisted milling," Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, vol. 226, pp. 1185-1191, 2012
Abootorabi Zarchi, "Effect of cutting speed on tool life in ultrasonic-assisted milling process," Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, vol. 227, pp. 1157-1164, 2013
Cheng, "Two-dimensional vibration-assisted micro end milling: cutting force modelling and machining process dynamics," Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, vol. 224, pp. 1775-1783, 2010
Tawakoli, "Development of a novel ultrasonic unit for grinding of ceramic matrix composites," The International Journal of Advanced Manufacturing Technology, vol. 57, pp. 945-955, 2011

Sorrell c, a Faculty of Materials and Manufacturing Technology, MUT University of Technology, Tehran 4817-75631, Iran; b Institute for Biomedical Engineering and Technology, AMME J07, University of Sydney, NSW Australia; c School of Materials Science and Engineering, University of NSW, Australia.
A 1.5 kW, 2.45 GHz variable-power microwave furnace (Ceramic Engineering, Sydney, Australia), with proportional power control (amplitude variation) and built-in mode stirrer, was used at the 65% power level for all experiments.
Ramachandra Rao, T.S Kannan, Synthesis and sintering of hydroxyapatite-zirconia composites, Materials Science and Engineering C (2002), 20 (1-2), 187-193
Agathopoulos, F.N Oktar, Composites of bovine hydroxyapatite (BHA) and ZnO, Journal of Material Science, (2008), 43 (8), 2536-40,
Brandwood, Interfacial Analysis of Hydroxyapatite-Particulate Addition Composites, pp. 623-28 in Ceramics: Adding the Value, Vol. 2 (proceedings of the International Ceramic Conference, Austceram 92).

The Ultrafine Grinding Process of Zirconium Silicate Jie Lv1, a, Linfeng Zhu2, b, Guosheng Gai1, c and Yufen Yang1, d 1Department of Material Science and Engineering, Tsinghua University, China 2School of Chemical and Environmental Engineering, China University of Mining and Technology, Beijing, China aLvjie1006@163.com, byanzhuchangkong@139.com, cgaigs@139.com, dyangyufen@mail.tsinghua.edu.cn Keywords: Zircon.Zirconium silicate.Ball grinding.Stirred mill Abstract.
[5] Jianhua Liu, Wenmao Liu, Huajin Liu, The preparation of ceramic pigment from zircon, J, Journal of Jingdezhen Comprehensive College.
[6] ZengJian, Zhenfeng Hu, The engineering research of the ultrafine grinding of zircon, J.
  [9] Reinsch, E, Bernhardt, C, Husemann, K, The influence of the additives during wet ultra-fine grinding agitator bead mills, J, CFI-Ceramic Forum International.
Jankovic, Variables affecting the fine grinding of minerals using stirred mills, Minerals Engineering. 

Research on the treatment of oily sludge Ping Chen1,2,a, Lianbao Kan1,2 1 Heilongjiang Key Laboratory of Disaster Prevention, Mitigation and Protection Engineering; Daqing, Heilongjiang, 163318, China 2 College of Civil and Architecture Engineering, Northeast Petroleum University; Daqing, Heilongjiang, 163318, China; aemail:shenjiangong22@126.com Keywords: Oily sludge; Ultrasound; Biodegradation; Sludge dewatering Abstract: The oily sludge was more serious polluted to the environment, it is necessary to harmless treatment.
The results showed that practically no change occurred in the main technological properties required to specify porous red ceramic products.
Stefanescu: Journal of Petroleum Science and Engineering Vol. 22 (1999) , p.151–160 [11] C.
Tahhan, Rouba Youssef Abu-Ateih: International Biodeterioration & Biodegradation Vol. 63 (2009) , p.1054–1060 [14] Vanessa S.
Holanda: Ceramics International Vol.39 (2013) , p. 57–63 [20] Patricia Fernanda Andrade, Thiago Figueiredo Azevedo, Iara F.

In the present study modeling of permeability of open-porosity ceramic materials used in non-polarizing electrodes is addressed.
The structure of the material filling the electrode determines the infiltration of its ceramic structure by electrolyte.
Brebbia, , Book Series: WIT Transactions on Engineering Sciences, Series Volume: 74, UK, ISBN: 978-1-84564-600-4
Wejrzanowski, Pressure drop in flow across ceramic foams – A numerical and experimental study, Chemical Engineering Science, Volume 137 (2015) Pages 320-337 [10] J.
Kurzydlowski, Image based analysis of complex microstructures of engineering materials, International Journal of Applied Mathematics and Computer Science, Vol. 18, No. 1 (2008), p. 33-39