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Online since: June 2011
Authors: Iis Sopyan, Ramesh Singh, K.L. Aw, Chou Yong Tan, Wan Dung Teng, R. Tolouei, Wei Hong Yeo, H. Kelvin
Department of Manufacturing and Materials Engineering, Faculty of Engineering, International Islamic University Malaysia, Malaysia
3.
Colloids and Surfaces A: Physicochemical and Engineering Aspects, Vol. 322, 29-33
Journal of Alloys and Compounds, Vol. 430, 330-333
ASTM International
Journal of Biomechanical Science and Engineering, Vol. 3 [1] 1-12
Colloids and Surfaces A: Physicochemical and Engineering Aspects, Vol. 322, 29-33
Journal of Alloys and Compounds, Vol. 430, 330-333
ASTM International
Journal of Biomechanical Science and Engineering, Vol. 3 [1] 1-12
Online since: April 2012
Authors: Yoke San Wong, De Ping Yu, Geok Soon Hong
Falter: Precision Engineering Vol. 13 (1991), p. 243-250
[2] W.
Yamanaka: Precision Engineering Vol. 27 (2003), p. 289-298 [3] C.
Scattergood: Journal of the American Ceramic Society Vol. 73 (1990), p. 949-957 [8] H.K.
Hong: Key Engineering Materials Vol. 443 (2010), p. 669-674 [13] D.P.
Scattergood: Journal of Engineering for Industry Vol. 113 (1991), p. 184-189 [18] D.P.
Yamanaka: Precision Engineering Vol. 27 (2003), p. 289-298 [3] C.
Scattergood: Journal of the American Ceramic Society Vol. 73 (1990), p. 949-957 [8] H.K.
Hong: Key Engineering Materials Vol. 443 (2010), p. 669-674 [13] D.P.
Scattergood: Journal of Engineering for Industry Vol. 113 (1991), p. 184-189 [18] D.P.
Online since: June 2019
Authors: Chao Li, Hasigaowa Hasigaowa, Zhi Peng Li, Yu Guang Bao, Yan Li Wang, Shuang Yan Yang, Peng Man, Xiao Ju Gao
[6] F Keisuke, Y Eiichi, A Takashi, et al, Effect of Characteristics of Materials on Fracture Behavior and Modeling Using Graphite-related Materials with a High-Velocity Steel Sphere, International Journal of Impact Engineering. 28(2003): 985-999
[7] M S Liu, Y L Li, F Xu, et al, Dynamic compressive mechanical properties and a new constitutive model of 2D-C/SiC composites, Materials Science and Engineering A. 489 (2008): 120-126
[10] C P Yang, G Q Jiao, B Wang, Tensile damage behavior of 2D-C-SiC composite, Journal of Aeronautical Materials. 30(2010): 87-92.
[25] Y L Li, T Suo, M S Liu, Influence of the Strain Rate on the Mechanical Behavior of the 3D Needle-Punched C/SiC Composite, Materials Science and Engineering A. 507(2009): 6-12
[26] M S Liu, A Study on the Dynamic Compressive Mechanical Properties of C/SiC Composites, In: Dissertation for a Degree of Engineering Master, Northwestern Polytechnical University, China. (2007): 31-33.
[7] M S Liu, Y L Li, F Xu, et al, Dynamic compressive mechanical properties and a new constitutive model of 2D-C/SiC composites, Materials Science and Engineering A. 489 (2008): 120-126
[10] C P Yang, G Q Jiao, B Wang, Tensile damage behavior of 2D-C-SiC composite, Journal of Aeronautical Materials. 30(2010): 87-92.
[25] Y L Li, T Suo, M S Liu, Influence of the Strain Rate on the Mechanical Behavior of the 3D Needle-Punched C/SiC Composite, Materials Science and Engineering A. 507(2009): 6-12
[26] M S Liu, A Study on the Dynamic Compressive Mechanical Properties of C/SiC Composites, In: Dissertation for a Degree of Engineering Master, Northwestern Polytechnical University, China. (2007): 31-33.
Online since: June 2010
Authors: Hui Huang, Xi Peng Xu, Guo Qing Zhang
Huang: Key Engineering Materials, Vol. 404 (2009), p.11
[2] H.
Hu, and et al: Journal of Superhard Materials Engineering, Vol. 20 No.1 (2008), p.45 [4] K.
Kanayama: Journal of Japan Society of Mechanical Engineering, Vol. 60 No.573 (1994), p.1818 [5] G.Q.
Xu: Key Engineering Materials, Vols. 389-390 (2009), p.436 [6] J.C.
Sung: International Journal of Refractory Metals & Hard Materials, Vol. 27 (2009), p.382 [7] H.Y.
Hu, and et al: Journal of Superhard Materials Engineering, Vol. 20 No.1 (2008), p.45 [4] K.
Kanayama: Journal of Japan Society of Mechanical Engineering, Vol. 60 No.573 (1994), p.1818 [5] G.Q.
Xu: Key Engineering Materials, Vols. 389-390 (2009), p.436 [6] J.C.
Sung: International Journal of Refractory Metals & Hard Materials, Vol. 27 (2009), p.382 [7] H.Y.
Online since: September 2021
Authors: Onuchukwu Godwin Chike, Norhayati Binti Ahmad, Uday M. Basheer Al-Naib
Material engineering processes have advanced as a feasible substitute for conventional steel fragment construction methods.
Now it seems to be a global necessity in the engineering methods and is alleged to reach a slanting juncture before long.
Chauhan, "An overview of rapid prototyping technology," International Journal of Application of Engineering and Technology, vol. 2, no. 3, pp. 224-227, 2015
Günster, "Additive manufacturing of ceramics: issues, potentialities, and opportunities," Journal of the American Ceramic Society, vol. 98, no. 7, pp. 1983-2001, 2015. https://doi.org/10.1111/jace.13700 [17] F.
Pinkerton, "Direct laser deposition with different types of 316L steel particle: A comparative study of final part properties," Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, vol. 227, no. 4, pp. 520-531, 2013. https://doi.org/10.1177/0954405413475961 [62] K.
Now it seems to be a global necessity in the engineering methods and is alleged to reach a slanting juncture before long.
Chauhan, "An overview of rapid prototyping technology," International Journal of Application of Engineering and Technology, vol. 2, no. 3, pp. 224-227, 2015
Günster, "Additive manufacturing of ceramics: issues, potentialities, and opportunities," Journal of the American Ceramic Society, vol. 98, no. 7, pp. 1983-2001, 2015. https://doi.org/10.1111/jace.13700 [17] F.
Pinkerton, "Direct laser deposition with different types of 316L steel particle: A comparative study of final part properties," Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, vol. 227, no. 4, pp. 520-531, 2013. https://doi.org/10.1177/0954405413475961 [62] K.
Online since: August 2013
Authors: Ramesh Singh, W.D. Teng, K.Y. Sara Lee, K.M. Christopher Chin, C.Y. Tan
Teng2,e
1 Centre of Advanced Manufacturing an Material Prrocessing (AMMP), Department of Mechanical Engineering, Faculty of Engineering, University of Malaya, 50603, Kuala Lumpur, Malaysia
2Ceramics Technology Group, SIRIM Berhad,40911 Shah Alam, Malaysia
achrisckm@siswa.um.edu.my, bkityee7@siswa.um.edu.my, cchouyong@um.edu.my, dramesh79@um.edu.my, ewdteng@sirim.my
Keywords: Forsterite, solid-state reaction, fracture toughness, hardness
Abstract.
Chang, Preparation and characterization of forsterite (Mg2SiO4) bioceramics, Ceramics International. 33 (2007) 83-88
Cavin, Poly(methacrylate) precursor to forsterite, Journal of American Ceramic Society. 75 (1992) 1831-1838
Rao D, Investigation on mechanical properties of A356 nanocomposites fabricated by ultrasonic assisted cavitaion, Journal of Mechanical Engineering. 41 (2) (2010) 121-129
Hench, Bioceramics: From concept to clinic, Journal of American Ceramic Society. 74 (1991) 1487-1506
Chang, Preparation and characterization of forsterite (Mg2SiO4) bioceramics, Ceramics International. 33 (2007) 83-88
Cavin, Poly(methacrylate) precursor to forsterite, Journal of American Ceramic Society. 75 (1992) 1831-1838
Rao D, Investigation on mechanical properties of A356 nanocomposites fabricated by ultrasonic assisted cavitaion, Journal of Mechanical Engineering. 41 (2) (2010) 121-129
Hench, Bioceramics: From concept to clinic, Journal of American Ceramic Society. 74 (1991) 1487-1506
Online since: June 2023
Authors: Azwar Hayat, Andi Erwin E. Putra, Novriany Amaliyah, Ismail Rahim, Asriadi Sakka
Semiconductor TiO2 Coating Deposited by Microwave Plasma Method
NOVRIANY Amaliyah1,a*, AZWAR Hayat1,b, ANDI ERWIN Eka Putra1,c
ISMAIL Rahim2,d, ASRIADI Sakka1,e
1Mechanical Engineering Department, Faculty of Engineering, Hasanuddin University
Gowa Kampus, Poros Malino Km. 6 Bontomarannu, Gowa, South Sulawesi, Indonesia 92171
2Automotive Technology Vocational Education Department, Faculty of Engineering, Universitas
Negeri Makassar.
Jaworek, Protective properties of Al2O3 + TiO2 coating produced by the electrostatic spray deposition method, Ceramics International. 43 (2017) 2126–12137
Wang et al., Effect of MgO microparticles on characteristics of microarc oxidation coatings fabricated on pure titanium, International Journal of Electrochemical Science. 14 (2019) 287–300
Li, Microstructure and properties of rare earth CeO2-doped TiO2 nanostructured composite coatings through micro-arc oxidation, Ceramics International. 41 (2015) 6178–6186
Herman, Plasma spray synthesis of nanomaterial powders and deposits, Material Science & Engineering A. 238 (1997) 275–286.
Jaworek, Protective properties of Al2O3 + TiO2 coating produced by the electrostatic spray deposition method, Ceramics International. 43 (2017) 2126–12137
Wang et al., Effect of MgO microparticles on characteristics of microarc oxidation coatings fabricated on pure titanium, International Journal of Electrochemical Science. 14 (2019) 287–300
Li, Microstructure and properties of rare earth CeO2-doped TiO2 nanostructured composite coatings through micro-arc oxidation, Ceramics International. 41 (2015) 6178–6186
Herman, Plasma spray synthesis of nanomaterial powders and deposits, Material Science & Engineering A. 238 (1997) 275–286.
Online since: October 2010
Authors: Yücel Onüralp, Filiz Çinar Şahin, G. Göller, Berkay Uygun
Production And Characterization of Boron Carbide – Titanium Diboride Ceramics by Spark Plasma Sintering Method
Berkay Uygun1,a, Gültekin Göller1,b, Onuralp Yücel1,c, Filiz Çınar Şahin1,d
1Istanbul Technical University, Faculty of Chemical and Metallurgical Engineering, Department of Metallurgical and Materials Engineering; Maslak, Istanbul, 34469, Turkey
auygunberkay@yahoo.com, bgoller@itu.edu.tr, cyucel@itu.edu.tr, dcinar@itu.edu.tr
Keywords: Spark Plasma Sintering, SPS, B4C, TiB2, B4C-TiB2
Abstract.
This study was carried out to produce and characterize B4C - TiB2 ceramics by spark plasma sintering.
“Boron Carbide – A Comprehensive Review”, Journal of the European Ceramic Society, 6, 205-225
“Pressureless Sintering of Boron Carbide”, Ceramics International, 32, 227-233
“High Strength-High Toughness B4C-TiB2 Composites”, Journal of Materials Science Letters, 19, 237-239.
This study was carried out to produce and characterize B4C - TiB2 ceramics by spark plasma sintering.
“Boron Carbide – A Comprehensive Review”, Journal of the European Ceramic Society, 6, 205-225
“Pressureless Sintering of Boron Carbide”, Ceramics International, 32, 227-233
“High Strength-High Toughness B4C-TiB2 Composites”, Journal of Materials Science Letters, 19, 237-239.
Online since: April 2014
Authors: Xin Yi Qiao, Rui Jun Wang
References
[1] QIAN Yangbao, ZHANG Weiguang, Phase-transformation Behavior of Plasma-sprayed ZrSiO4 Coating Materials, Journal of the Chinese Ceramic Society. 36(2008) 1103-1108
[4] HUANG Minghao, DONG Xiaoqiang, The Simulation and Comparison of Powder Feeding Systems in Plasma Spraying Gun, China Surface Engineering. 19(2006) 40-42
Development of Plasma Spray Technology and Low Energy Plasma Spray in Internal Feedstock Mode, Proceeding of the 5th Domestic Surface Engineering Proseminar
[13] GAO Yang, YAN Zhijun, XIN Gang, Great Hardness Al2O3 Coating Prepared by Low Energy Plasma Spray Process, Proceeding of the 5th Domestic Surface Engineering Proseminar
[24] ZHAI Changsheng, WU Ruizhi, Study on Performance of Al2O3 Coatings Prepared by Plasma Spraying, Material Engineering. 12 (2004) 47-50.
[4] HUANG Minghao, DONG Xiaoqiang, The Simulation and Comparison of Powder Feeding Systems in Plasma Spraying Gun, China Surface Engineering. 19(2006) 40-42
Development of Plasma Spray Technology and Low Energy Plasma Spray in Internal Feedstock Mode, Proceeding of the 5th Domestic Surface Engineering Proseminar
[13] GAO Yang, YAN Zhijun, XIN Gang, Great Hardness Al2O3 Coating Prepared by Low Energy Plasma Spray Process, Proceeding of the 5th Domestic Surface Engineering Proseminar
[24] ZHAI Changsheng, WU Ruizhi, Study on Performance of Al2O3 Coatings Prepared by Plasma Spraying, Material Engineering. 12 (2004) 47-50.
Online since: October 2011
Authors: J.W. Kim, C.H. Park, T.G. Park, S.S. Jeong, M.H. Kim, H.H. Chong
The same phase voltages were applied to the ceramics on horizontal surfaces, and 90 degree phase difference voltages were applied to the ceramics on vertical surfaces.
ET (elastic thickness) is the thickness of the elastic frame, and CT (ceramic thickness) is the thickness of the ceramics.
The width of the elastic body and ceramics are the same, and the sizes of the four ceramics are also the same [4].
The same phase voltages were applied to the ceramics on horizontal surfaces, and 90 degree phase difference voltages were applied to the ceramics on vertical surfaces.
Hughes, “Finite element for piezoelectric vibration,” International Journal Numerical Methods of Engineering, vol. 13, June, 1970, pp. 151-157
ET (elastic thickness) is the thickness of the elastic frame, and CT (ceramic thickness) is the thickness of the ceramics.
The width of the elastic body and ceramics are the same, and the sizes of the four ceramics are also the same [4].
The same phase voltages were applied to the ceramics on horizontal surfaces, and 90 degree phase difference voltages were applied to the ceramics on vertical surfaces.
Hughes, “Finite element for piezoelectric vibration,” International Journal Numerical Methods of Engineering, vol. 13, June, 1970, pp. 151-157