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Online since: April 2018
Authors: Chi Bo, Wu Lei, Ben Ma, Jian Pu, Li Jian
[6] Jinfeng Xia, Hongqiang Nian, Wei Liu, et al., Synthesis, Sintering Behavior, Structure, and Electrical Properties of 5YSZ Electrolyte, Journal of Materials Engineering and Performance, 2015. 24: 2191-3299
[9] Huang Xuening, Patrick S Nicholson, Mechanical Properties and Fracture Toughness of α-Al2O3-Platelet-Reinforced Y-PSZ Composites at Room and High Temperatures, Journal of the American Ceramic Society, 1993.76(5):294
[11] GhateeM,Farid S,Electrical and Mechanical Properties of 5YSZTubular Thin Film Prepared by Screen Printing Method, International Journal of Applied Ceramic Technology, 2016.13(2): 373-381
[12] H.Aripin,S.Mitsudo,E.S.Prima et.al,Crystalline mullite formation from mixtures of alumina and a novel material-Silica xerogel converted from sago waste ash, Ceramics International, 2015, 41: 6488-6497
[14] E.Garcia, J.Mesquita, P.Miranzo et.al, Crystallization studies in mullite and mullite-YSZ beads, Journal of the European Ceramic Society,2010.30:2003-2008.
[9] Huang Xuening, Patrick S Nicholson, Mechanical Properties and Fracture Toughness of α-Al2O3-Platelet-Reinforced Y-PSZ Composites at Room and High Temperatures, Journal of the American Ceramic Society, 1993.76(5):294
[11] GhateeM,Farid S,Electrical and Mechanical Properties of 5YSZTubular Thin Film Prepared by Screen Printing Method, International Journal of Applied Ceramic Technology, 2016.13(2): 373-381
[12] H.Aripin,S.Mitsudo,E.S.Prima et.al,Crystalline mullite formation from mixtures of alumina and a novel material-Silica xerogel converted from sago waste ash, Ceramics International, 2015, 41: 6488-6497
[14] E.Garcia, J.Mesquita, P.Miranzo et.al, Crystallization studies in mullite and mullite-YSZ beads, Journal of the European Ceramic Society,2010.30:2003-2008.
Online since: October 2011
Authors: Heng Zhen Dai, Feng Wei Huo, Shang Gao, Zhu Ji Jin, Zhan Chun Tao
The tool A, not only scraped the reactant film on Al2O3 ceramic surface,but also scratched the ceramic surface and caused some surface damage.
Yoshikawa: Journal of Materials Processing Technology Vol. 132 (2003), p. 353 [2] M.Jiang,R.Komanduri,Chemical-mechanical polishing(CMP) in magnetic float polishing(MFP) of advanced ceramic (silicon nitride) and glass(silicon dioxide),Key Eng.Mater Vol1-14(2001),p.202-203 [3] F.
Eda: International Journal of Manufacturing Technology and Management Vol. 7 (2005), p. 441 [5] L.
Kamiya, etc: CIRP Annals- Manufacturing Technology Vol. 55 (2006), p. 313 [6] Nobuo Yasunaga: Journal of the Surface Science Society of Japan Vol. 22 (2001), p. 187 [7] N.
Yasunuga: Journal of Japan Society for Precision Engineering Vol. 44 (1978), p. 65 [8] Y.
Yoshikawa: Journal of Materials Processing Technology Vol. 132 (2003), p. 353 [2] M.Jiang,R.Komanduri,Chemical-mechanical polishing(CMP) in magnetic float polishing(MFP) of advanced ceramic (silicon nitride) and glass(silicon dioxide),Key Eng.Mater Vol1-14(2001),p.202-203 [3] F.
Eda: International Journal of Manufacturing Technology and Management Vol. 7 (2005), p. 441 [5] L.
Kamiya, etc: CIRP Annals- Manufacturing Technology Vol. 55 (2006), p. 313 [6] Nobuo Yasunaga: Journal of the Surface Science Society of Japan Vol. 22 (2001), p. 187 [7] N.
Yasunuga: Journal of Japan Society for Precision Engineering Vol. 44 (1978), p. 65 [8] Y.
Online since: December 2005
Authors: Charles Lewinsohn, Hisashi Serizawa, Mrityunjay Singh, Hidekazu Murakawa
Kohyama:
Ceramic Engineering and Science Proceedings, Vol. 20 [4] (1999), pp.443-450
Needleman: International Journal of Fracture, Vol. 42 (1990), pp.21-40
Wu: Ceramic Engineering and Science Proceedings, Vol. 20 [3] (1999), pp.309-316
Kohyama: Ceramic Engineering and Science Proceedings, Vol. 22 [4] (2001), pp.621-625
Murakawa: Ceramic Engineering and Science Proceedings, Vol. 22 [4] (2001), pp.635-642
Needleman: International Journal of Fracture, Vol. 42 (1990), pp.21-40
Wu: Ceramic Engineering and Science Proceedings, Vol. 20 [3] (1999), pp.309-316
Kohyama: Ceramic Engineering and Science Proceedings, Vol. 22 [4] (2001), pp.621-625
Murakawa: Ceramic Engineering and Science Proceedings, Vol. 22 [4] (2001), pp.635-642
Online since: December 2022
Authors: Simeon Agathopoulos, Konstantinos Dimitriadis
Shen, Laser sintering of ceramics, Journal of Asian Ceramic Societies 1 (2013) 315–321
Shi, Microstructure and mechanical properties of 3Y-TZP dental ceramics fabricated by selective laser sintering combined with cold isostatic pressing, International Journal of Lightweight Materials and Manufacture 1 (2018) 239-245
Mazzoli, Selective laser sintering in biomedical engineering.
Candiani (Eds.), Foundations of Biomaterials Engineering, Elsevier, Philadelphia, 2019, pp 199-287
Dalgarno, Fabrication of bioactive glass-ceramics by Selective Laser Sintering, Key Engineering Materials 309-311 (2006) 289-292
Shi, Microstructure and mechanical properties of 3Y-TZP dental ceramics fabricated by selective laser sintering combined with cold isostatic pressing, International Journal of Lightweight Materials and Manufacture 1 (2018) 239-245
Mazzoli, Selective laser sintering in biomedical engineering.
Candiani (Eds.), Foundations of Biomaterials Engineering, Elsevier, Philadelphia, 2019, pp 199-287
Dalgarno, Fabrication of bioactive glass-ceramics by Selective Laser Sintering, Key Engineering Materials 309-311 (2006) 289-292
Online since: August 2009
Authors: M. El-Hofy
Non-Ohmic Behavior of Some ZnO Ceramic
Defective Ions with Different Valences
M.El-Hofy
Physics department, Faculty of Science,
Menoufia University, Shebin El-Koom,
Egypt
elhofy2000@yahoo.com
Keywords: Cu
2+-Doped, Fe
3+-Doped, Linear Scan, Microstructure, Mo
6+-Doped, Non-Ohmic
Behavior, Ti
4+-Doped, V
5+-Doped, X-Ray Diffraction, ZnO Ceramic
Abstract
ZnO ceramic samples with the chemical formula, 97ZnO-2BaO-1(X)Mol% (where X= CuO, Fe2O3,
TiO2, V2O5, MoO3) have been prepared by using conventional ceramics techniques.
Figure 4 nd linear scan data for the doped ceramics ceramics studied, the doped ions reside at the grain boundaries.
case of Cu- and Mo-doped ceramics Conclusion In the present samples, the non-linearity the doped ion.
References [1] A.Peigney, F.X.Lamy de La Chapelle, A.Rousset: Key Engineering Materials, 1977, 132136, 1301 [2] C.Sugn-Yong, W.Naoki, F.Hi-Roshi, S.Kazuo, M.Nobuyasu: Journal of the American Ceramic Society, 1997, 80[4], 995 [3] W.Naoki, M.Kazuo: Seramikkusu, 1997, 32[5], 393 [4] G.Agarwal, F.R.Speyer: Journal of Materials Research, 1997, 12[9], 2447 [5] Z.Ling, J.D.Russel and C.Leach: Key Engineering Materials, 1997, 132-136, 1305 [6] I.A.Ivon, B.A.Glot, V.A.Gaponor and V.S.Mazurik: Key Engineering Materials, 1997, 132136, 1289 [7] J.K.Tsai and T.B.Wu: Journal of Applied Physics, 1994, 76, 8 [8] H.H.Hng and K.M.Knowles: Journal of the European Ceramic Society, 1999, 19, 721 [9] M.El-Hofy and A.H.Salama: Interceram, 2003, 52[5], 276 [10] S.Ezhilvalavan and T.R.N.Kutty: Journal of Materials Science - Materials in Electronics, 1996, 7, 137 [11] S.Tanaka, K.Takahashi, I.Sakaguchi and J.Tanaka: Proceedings of the International Conference on Electronic Components
and Materials Sensors and Actuators (International Academic Publishers, China Xi'an 1995) [12] M.El-Hofy: Defect and Diffusion Forum, 2005, 242-244, 107 [13] M.El-Hofy: Defect and Diffusion Forum, 2006, 251-252, 13 [14] L.F.Grigoreva, S.A.Petrov, O.Yu.Sinelshehikova, I.A.Drozdova and V.V.Gusarov: Glass Physics and Chemistry, 2007, 33[1], 72 [15] W.Onreabroy, N.Sirikulrat, A.P.Brown, C.Hammond, S.J.Milne: Solid State Ionics, 2005, 177[3-4], 411 [16] Shenglin, Jaing, Haibo Zhang, Yanqiu Huang, Meidong Liu, Ruzhan Lin: Materials Science and Engineering, 2005, B117, 317
Figure 4 nd linear scan data for the doped ceramics ceramics studied, the doped ions reside at the grain boundaries.
case of Cu- and Mo-doped ceramics Conclusion In the present samples, the non-linearity the doped ion.
References [1] A.Peigney, F.X.Lamy de La Chapelle, A.Rousset: Key Engineering Materials, 1977, 132136, 1301 [2] C.Sugn-Yong, W.Naoki, F.Hi-Roshi, S.Kazuo, M.Nobuyasu: Journal of the American Ceramic Society, 1997, 80[4], 995 [3] W.Naoki, M.Kazuo: Seramikkusu, 1997, 32[5], 393 [4] G.Agarwal, F.R.Speyer: Journal of Materials Research, 1997, 12[9], 2447 [5] Z.Ling, J.D.Russel and C.Leach: Key Engineering Materials, 1997, 132-136, 1305 [6] I.A.Ivon, B.A.Glot, V.A.Gaponor and V.S.Mazurik: Key Engineering Materials, 1997, 132136, 1289 [7] J.K.Tsai and T.B.Wu: Journal of Applied Physics, 1994, 76, 8 [8] H.H.Hng and K.M.Knowles: Journal of the European Ceramic Society, 1999, 19, 721 [9] M.El-Hofy and A.H.Salama: Interceram, 2003, 52[5], 276 [10] S.Ezhilvalavan and T.R.N.Kutty: Journal of Materials Science - Materials in Electronics, 1996, 7, 137 [11] S.Tanaka, K.Takahashi, I.Sakaguchi and J.Tanaka: Proceedings of the International Conference on Electronic Components
and Materials Sensors and Actuators (International Academic Publishers, China Xi'an 1995) [12] M.El-Hofy: Defect and Diffusion Forum, 2005, 242-244, 107 [13] M.El-Hofy: Defect and Diffusion Forum, 2006, 251-252, 13 [14] L.F.Grigoreva, S.A.Petrov, O.Yu.Sinelshehikova, I.A.Drozdova and V.V.Gusarov: Glass Physics and Chemistry, 2007, 33[1], 72 [15] W.Onreabroy, N.Sirikulrat, A.P.Brown, C.Hammond, S.J.Milne: Solid State Ionics, 2005, 177[3-4], 411 [16] Shenglin, Jaing, Haibo Zhang, Yanqiu Huang, Meidong Liu, Ruzhan Lin: Materials Science and Engineering, 2005, B117, 317
Online since: December 2010
Authors: Xu Hong Guo, Wei Wang, Chun Juan Tu, Chi Hong Wang
Comparison Research on the Machinability of Hardened Steel when Dry Turning with Ceramic and CBN Cutting Tools
Chunjuan Tu1,2, a, Xuhong Guo1,b, Wei Wang 1,c and Chihong Wang1,d
1School of Mechanical & Electrical Engineering of Soochow University, Suzhou, 215021, China
2Suzhou Institute of Industrial Technology, Suzhou 215104, China
a tucj@siit.cn, bxuhongguo@suda.edu.cn, cwwsunshine@foxmail.com,
dchihongwang.mee@gmail.com
Keywords: Ceramic cutting tools; CBN cutting tools; Dry turning; Hardened steel; Cutting force; Chip characteristics; Experimental equations.
References [1] G.C.Benga,A.M.Abrao: Journal of Materials Processing Technology Vol. 143-144(2003), pp. 237-241 [2] E.G.Ng,D.K.Aspinwall,D.Brazil: International Journal of Machine Tools and Manufacture Vol. 39(1999), pp. 885-903 [3] D.H.
Zhu etc: Mechanical engineer material Vol. 11(2004), pp. 10-12 [5] Y.Q.
Zhang etc: Chinese mechanic and engineer Vol. 21(2006), pp. 2305-2308 [6] L.G.
Ge etc: Journal of Guangxi University(Science & Philosophy) Vol. 3 (1993), pp. 39-43
References [1] G.C.Benga,A.M.Abrao: Journal of Materials Processing Technology Vol. 143-144(2003), pp. 237-241 [2] E.G.Ng,D.K.Aspinwall,D.Brazil: International Journal of Machine Tools and Manufacture Vol. 39(1999), pp. 885-903 [3] D.H.
Zhu etc: Mechanical engineer material Vol. 11(2004), pp. 10-12 [5] Y.Q.
Zhang etc: Chinese mechanic and engineer Vol. 21(2006), pp. 2305-2308 [6] L.G.
Ge etc: Journal of Guangxi University(Science & Philosophy) Vol. 3 (1993), pp. 39-43
Online since: August 2011
Authors: Chuan Zhen Huang, Han Lian Liu, Bin Zou, Ming Hong
Experimental Study on the Cutting Performance of TiC-based Nanocomposite Ceramic Tools in turning 40Cr Steel
Hanlian Liu1, a, Ming Hong2, b, Chuanzhen Huang1, c, Bin Zou1, d
1Center for Advanced Jet Engineering Technologies (CaJET), Key Laboratory of High Efficiency
and Clean Mechanical Manufacture, Ministry of Education, School of Mechanical Engineering, Shandong University, Jinan 250061 China
2LG Electronics, Tianjin, 300402 China
alhl70@sdu.edu.cn, bhm53007@163.com, cchuanzhenh@sdu.edu.cn, dzb78@sdu.edu.cn
Keywords: TiC-based; Ceramics; Cutting tool; 40Cr steel; Wear
Abstract.
It is reported that the wear properties of ceramic tools are not merely decided by its hardness [2, 3].
Beijing, China, 1988; (in Chinese) [2] Evans A.G. and Marshall P.B.: Wear Mechanism in Ceramics.Proceeding of International Conference on Fundamentals of Friction and Wear of Materials.
:Chinese Journal of Mechanical Engineering Vol. 20(2007), p. 5 [6] Teng X.
Mater.Vol. 443(2010), p. 318 [9] Xu S.H.: Equipment Manufacturing Technology Vol.2 (2007), p. 72 [10] Xu L.Q., Huang C.Z., Liu H.L. and Shi Y.X.: Journal of Harbin Institute of Technology (new series) Vol.17 (2010), Sup.1, p. 74 [11] Li P.N., Tang S.W., Zhang H.A. and Zhang Y.Z.: The Chinese Journal of Nonferrous Metals Vol. 18(2008), p. 1286 [12] Chen Y. and Liu N.: Cemented Carbide Vol. 24(2007), p. 226 [13] Novak S. and Komac M.: Wear Vol. 205(1997), p. 160.
It is reported that the wear properties of ceramic tools are not merely decided by its hardness [2, 3].
Beijing, China, 1988; (in Chinese) [2] Evans A.G. and Marshall P.B.: Wear Mechanism in Ceramics.Proceeding of International Conference on Fundamentals of Friction and Wear of Materials.
:Chinese Journal of Mechanical Engineering Vol. 20(2007), p. 5 [6] Teng X.
Mater.Vol. 443(2010), p. 318 [9] Xu S.H.: Equipment Manufacturing Technology Vol.2 (2007), p. 72 [10] Xu L.Q., Huang C.Z., Liu H.L. and Shi Y.X.: Journal of Harbin Institute of Technology (new series) Vol.17 (2010), Sup.1, p. 74 [11] Li P.N., Tang S.W., Zhang H.A. and Zhang Y.Z.: The Chinese Journal of Nonferrous Metals Vol. 18(2008), p. 1286 [12] Chen Y. and Liu N.: Cemented Carbide Vol. 24(2007), p. 226 [13] Novak S. and Komac M.: Wear Vol. 205(1997), p. 160.
Online since: April 2011
Authors: R. S. Jadoun
Machinability Evaluation in the Ultrasonic Drilling (USD) Process of Aluminum Oxide-based Ceramics
R S Jadoun
Professor and Head, Production Engineering Department, College of Technology, G.
A.: Journal of Engineering for Industries, Transactions of the ASME, 87(series B): 39-46 (1965)
[8] Komaraiah, M. and Reddy, N.: Precision Engineering, Vol. 10, No. 2, (1988), pp. 59-65
A. et al.: Russian Engineering Journal, Vol. 52, No. 4 (1976), pp. 37-39
[15] Jadoun, R.S., Kumar, P., Mishra, B.K. and Mehta, R.C.S.: Engineering Optimization, Vol. 38, No. 7 (2006a), pp.771–787
A.: Journal of Engineering for Industries, Transactions of the ASME, 87(series B): 39-46 (1965)
[8] Komaraiah, M. and Reddy, N.: Precision Engineering, Vol. 10, No. 2, (1988), pp. 59-65
A. et al.: Russian Engineering Journal, Vol. 52, No. 4 (1976), pp. 37-39
[15] Jadoun, R.S., Kumar, P., Mishra, B.K. and Mehta, R.C.S.: Engineering Optimization, Vol. 38, No. 7 (2006a), pp.771–787
Online since: September 2013
Authors: Chang Sheng Hu, Xi Wang
Using Red Mud Manufacturing Building Glass-ceramics
Changsheng Hu, Xi Wang
School of Materials Science and Engineering,
Qilu University of Technology, Jinan, 250353, P.R.
In this paper, red mud of aluminum industrial residue has been studied to make the glass-ceramic, quartz sand, magnesite, fluorite and red mud was mixed to melt, molten glass was poured into the model in shape, then annealing, glass-ceramic was make, the color of glass-ceramic is brown or black, the crystals in glass-ceramic body is iron oxide by XRD, Strength, the expansion coefficient and morphology of the sample were measured.
The crystals in glass-ceramic body is iron oxide, surface color of glass-ceramic depends on the melting temperature of the batch.
[2] H.Z Yang, C P Chen,L J Pan, H X ;Lu, H W Sun,X Hu. .Journal of the European Ceramic Society,Vol.29(2009) NO.1,1887-1894
[3] J K Yang, D D Zhang, H, Jian, and B P He, B Xiao: Ceramics International, Vol.34 (2008), No.1, 125-130.
In this paper, red mud of aluminum industrial residue has been studied to make the glass-ceramic, quartz sand, magnesite, fluorite and red mud was mixed to melt, molten glass was poured into the model in shape, then annealing, glass-ceramic was make, the color of glass-ceramic is brown or black, the crystals in glass-ceramic body is iron oxide by XRD, Strength, the expansion coefficient and morphology of the sample were measured.
The crystals in glass-ceramic body is iron oxide, surface color of glass-ceramic depends on the melting temperature of the batch.
[2] H.Z Yang, C P Chen,L J Pan, H X ;Lu, H W Sun,X Hu. .Journal of the European Ceramic Society,Vol.29(2009) NO.1,1887-1894
[3] J K Yang, D D Zhang, H, Jian, and B P He, B Xiao: Ceramics International, Vol.34 (2008), No.1, 125-130.
Online since: June 2010
Authors: Xian Zhang Feng, Jun Wei Cheng, Ai Min Liu
With the flourishing development of nanotechnology, it is clear
that its research and development have become the hot spot these days for the international scientific
community and the engineering community.
New type metal nano-ceramic cutting tools: Professor Liu Ning is in charge of the projects, local nano-TiN, AiN modified Tic cermets Knife technologies for their manufacture, technology Materials Science and Engineering, Hefei University.
Lubrication Engineering, 2004(3):52-56
Journal of Adhesion, 1997, 64:31-59
International Journal of Mechanical Sciences, 2001, 43(9): 1985-1996
New type metal nano-ceramic cutting tools: Professor Liu Ning is in charge of the projects, local nano-TiN, AiN modified Tic cermets Knife technologies for their manufacture, technology Materials Science and Engineering, Hefei University.
Lubrication Engineering, 2004(3):52-56
Journal of Adhesion, 1997, 64:31-59
International Journal of Mechanical Sciences, 2001, 43(9): 1985-1996