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Online since: October 2012
Authors: Chun Hui Chung
Kao, Technology and Research of Slurry Wiresaw Manufacturing Systems in Wafer Slicing with Free Abrasive Machining, International Journal of Advanced Manufacturing Systems, 7 (2004) 10-23
Moller, Basic mechanisms and models of multi-wire sawing, Advanced Engineering Materials, 6 (2004) 501-513
Williams, Engineering Tribology, Cambridge University Press, New York, 2005
Marshall, Elastic/Plastic Indentation Damage in Ceramics: The Median Radial Crack System, Journal of the American Ceramic Society, 63 (1980) 574-581
Evans, Elastic/Plastic Indentation Damage in Ceramics: The Lateral Crack System, Journal of the American Ceramic Society, 65 (1982) 561-566
Moller, Basic mechanisms and models of multi-wire sawing, Advanced Engineering Materials, 6 (2004) 501-513
Williams, Engineering Tribology, Cambridge University Press, New York, 2005
Marshall, Elastic/Plastic Indentation Damage in Ceramics: The Median Radial Crack System, Journal of the American Ceramic Society, 63 (1980) 574-581
Evans, Elastic/Plastic Indentation Damage in Ceramics: The Lateral Crack System, Journal of the American Ceramic Society, 65 (1982) 561-566
Online since: January 2002
After the manuscripts were reviewed, 97 were
accepted for publication in this special issue of Materials Science Forum I Journal of
Metastable and Nanocrystalline Materials.
This symposium has brought together an interdisciplinary group of scientists and engineers.
These included papers in mechanochemistry, the effect of mechanical attrition on the chemical behavior of solids, covering many classes of materials, including metals, polymers and ceramics.
The Department of Nuclear Engineering at the University of Michigan has provided much appreciated support for the symposium preparation.
Finally, several sponsors have contributed to the success of the symposium through their generous financial support: the University of Michigan College of Engineering, U.S.
This symposium has brought together an interdisciplinary group of scientists and engineers.
These included papers in mechanochemistry, the effect of mechanical attrition on the chemical behavior of solids, covering many classes of materials, including metals, polymers and ceramics.
The Department of Nuclear Engineering at the University of Michigan has provided much appreciated support for the symposium preparation.
Finally, several sponsors have contributed to the success of the symposium through their generous financial support: the University of Michigan College of Engineering, U.S.
Online since: March 2010
Preface
ICSAM 2009 was the 10th International Conference on Superplasticity in Advanced Materials.
The meeting was held in Seattle at the Bell Harbor International Conference Center on the central downtown waterfront.
Peer reviewed papers are published in this book and the Key Materials Journal, both of which are Trans.
However, discoveries made around the globe have led to the advancement of superplastic ceramics, inter-metallics, nano materials, plastics, glasses and other materials.
Support for the conference came from the Boeing Company, the University of Washington Mechanical Engineering Department, ASM International, FormTech Gmbh., the Institute of Materials, Minerals and Mining and the University of Washington Educational Outreach group.
The meeting was held in Seattle at the Bell Harbor International Conference Center on the central downtown waterfront.
Peer reviewed papers are published in this book and the Key Materials Journal, both of which are Trans.
However, discoveries made around the globe have led to the advancement of superplastic ceramics, inter-metallics, nano materials, plastics, glasses and other materials.
Support for the conference came from the Boeing Company, the University of Washington Mechanical Engineering Department, ASM International, FormTech Gmbh., the Institute of Materials, Minerals and Mining and the University of Washington Educational Outreach group.
Online since: February 2007
Authors: C.C. Ribeiro, Mario A. Barbosa, Maria-Teresa Freire Vieira, Ana P. Piedade, A.R. Ribeiro
Introduction
There has recently been an increasing interest in the development of injectable materials for bone
regeneration, both ceramic and/or polymer based, via minimally invasive surgery, thus providing
less discomfort to the patients and lower costs [1,2].
In previous works of our group, [3-6] an injectable system was developed in the form of ceramic based microspheres of calcium titanium phosphate (CTP) to be used as bone regeneration scaffolds and enzyme delivery systems.
After deposition and in order to increase the crystallinity of the ceramic films, samples were heat treated at 600ºC for 5 hours in controlled atmosphere (Ar at 5 Pa).
In what concerns surface morphology, AFM analysis indicated that the insertion of Ti in the ceramic films leads to smoother surfaces when compared to HAp films (Fig. 4) a) b) Figure 4.
A: Injury-International Journal of the Care of the Injured: 33 Suppl. 2 (2002), p. 88 [4] Ooms EM, Wolke JGC, van der Waerden JPCM.: Journal of Biomedical Materials Research: 61 (1) (2002), p. 9 [5] Barrias CC, Ribeiro CC, Rodriguez D, Sá Miranda C, Barbosa MA.: Key Engineering Materials: vol. 284-286 (2005), p. 689 [6] Ribeiro CC, Barrias CC, Barbosa MA.: Biomaterials: 25 (2004), p. 4363 [7] van Dijk K., Schaeken H.G., Marée C.H.M., Verhoeven J., Wolke J.C.G., Habraken F.H.P.M., Jansen J.A.: Surface and Coatings Technology: 76-77 (1995), p. 206 [8] Hulshoff JEG, van Dijk K, de Ruijter JE: Journal of Biomedical Materials Research: 40 (3) (1998), p. 464 [9] Yang YZ, Kim KH, Ong JL.: Biomaterials: 26 (3) (2005), p. 327 [10] Ong JL, Lucas LC: Biomaterials 19 (4-5) (1998), p. 455 [11] Thian E.S., Huang J., Best S.M., Barber Z.H., Bonfield W.: Biomaterials: 26 (2005), p. 2947 a) HA b) HATi8 c) HATi16 d) Ti (Sa 17.11 nm) (Sa 14.03) nm (Sa 11.90 nm) (Sa 2.48 nm
In previous works of our group, [3-6] an injectable system was developed in the form of ceramic based microspheres of calcium titanium phosphate (CTP) to be used as bone regeneration scaffolds and enzyme delivery systems.
After deposition and in order to increase the crystallinity of the ceramic films, samples were heat treated at 600ºC for 5 hours in controlled atmosphere (Ar at 5 Pa).
In what concerns surface morphology, AFM analysis indicated that the insertion of Ti in the ceramic films leads to smoother surfaces when compared to HAp films (Fig. 4) a) b) Figure 4.
A: Injury-International Journal of the Care of the Injured: 33 Suppl. 2 (2002), p. 88 [4] Ooms EM, Wolke JGC, van der Waerden JPCM.: Journal of Biomedical Materials Research: 61 (1) (2002), p. 9 [5] Barrias CC, Ribeiro CC, Rodriguez D, Sá Miranda C, Barbosa MA.: Key Engineering Materials: vol. 284-286 (2005), p. 689 [6] Ribeiro CC, Barrias CC, Barbosa MA.: Biomaterials: 25 (2004), p. 4363 [7] van Dijk K., Schaeken H.G., Marée C.H.M., Verhoeven J., Wolke J.C.G., Habraken F.H.P.M., Jansen J.A.: Surface and Coatings Technology: 76-77 (1995), p. 206 [8] Hulshoff JEG, van Dijk K, de Ruijter JE: Journal of Biomedical Materials Research: 40 (3) (1998), p. 464 [9] Yang YZ, Kim KH, Ong JL.: Biomaterials: 26 (3) (2005), p. 327 [10] Ong JL, Lucas LC: Biomaterials 19 (4-5) (1998), p. 455 [11] Thian E.S., Huang J., Best S.M., Barber Z.H., Bonfield W.: Biomaterials: 26 (2005), p. 2947 a) HA b) HATi8 c) HATi16 d) Ti (Sa 17.11 nm) (Sa 14.03) nm (Sa 11.90 nm) (Sa 2.48 nm
Online since: July 2011
Authors: Yong Bo Wu, Yin Biao Guo, Zhi Qiang Liang, Yun Feng Peng, T. Jiang, X. Chen
Sreejith: International Journal of Advanced Manufacturing Technology Vol. 16 (2000), pp: 547–550
Scattergood: American Ceramic Society Bulletin Vol. 67(6) (1988), pp: 1038-1044
Wu et al.: The International Journal of Advanced Manufacturing Technology Vol. 33 (2007), pp: 449-459
Broek: Elementary Engineering Fracture Mechanics (Martinus Nijihoff Publishers.
Liang: International Journal of Advanced Manufacturing Technology Vol. 33 (2007), pp: 875-884
Scattergood: American Ceramic Society Bulletin Vol. 67(6) (1988), pp: 1038-1044
Wu et al.: The International Journal of Advanced Manufacturing Technology Vol. 33 (2007), pp: 449-459
Broek: Elementary Engineering Fracture Mechanics (Martinus Nijihoff Publishers.
Liang: International Journal of Advanced Manufacturing Technology Vol. 33 (2007), pp: 875-884
Online since: March 2010
Authors: Xiao Ping Zhou, Xin Bin Hu, Yi Sheng Xu
The Microstructure and Properties of Coating from Mo2FeB2 Cermet on
Surface of H13 Steel by Reactive Flame Spraying
Xiao Ping Zhou1,a, Xin Bin Hu
1,b
, Yi Sheng Xu
1,c
1
School of Mechanical Engineering, Hubei University of Technology, Wuhan Hubei,China 430064
a
zxp_zhn@163.com,b huxinbin@163.com,cxys281141481@yahoo.cn
Keywords: H13 steel, Reactive Flame Spraying, Cermet, Ternary Boride, Wear Resistance,
Thermal Fatigue Resistance
Abstract.
Reactive flame spraying as a new technology to prepare ceramic/metal composite coating has been developed recently, which combines self-propagating high-temperature synthesis with common reactive flame spraying technology.
The materials synthesis and synthetic materials sediment can be simultaneous, the ceramic phase is synthesized by in-situ synthesis with a fine grain size and the bonding with metal substrate is good[12-16].
:submitted to Journal of Journal ofMaterials Processing Technology,153-154(2004),p.1089-1096 [4] A.Persson, S.Hogmark and J.BergstrÖm:submitted to Journal of International Journal of Fatigue,Vol.26(2004),p.1095-1107 [5] Gong Yi Kui:submitted to Journal of Surface Technology,Vol.36(6)(2007),p.77-80 [6] Yu Hua Chen,Xiao Chun Wu and Hong Bin Wang:submitted to Journal of Heat Treatment of Metals,Vol.33(6)(2008),p.47-49 [7] Yu Feng Li and Wen Bin Shi:submitted to Journal of Die&Mould Industry,Vol.33(3)(2007), p.65-67 [8] K.Takagi, M.Komai and S.Matsuo:Powder Metallurgy Proceeding of World Congress, PM94,Paris,European Powder Metallurgy Association, 1994.1,p.227-234 [9] K.Takagi, S.Ohira, T.Ide etal: submitted to Journal of Modern Developments in Powder Metallurgy, Vol.16(1985),p.153-166 [10] Xiao Ping Zhou and Lin Hua:submitted to Journal of Journal of Steel and Related Materials,Vol.3(6)(2005),p. 450-452 [11] Xiao Ping Zhou and Xin Bin Hu:submitted to Journal of
Taylor:submitted to Journal of Journal of Alloys and Compounds,Vol.287(1999),p.121-125 [15] Motohiro Yamada,Yoshihisa Kouzaki and Toshiaki Yasui:submitted to Journal of Surface & Coatings Technology,Vol.201(2006),p.1745-1751 [16] F.
Reactive flame spraying as a new technology to prepare ceramic/metal composite coating has been developed recently, which combines self-propagating high-temperature synthesis with common reactive flame spraying technology.
The materials synthesis and synthetic materials sediment can be simultaneous, the ceramic phase is synthesized by in-situ synthesis with a fine grain size and the bonding with metal substrate is good[12-16].
:submitted to Journal of Journal ofMaterials Processing Technology,153-154(2004),p.1089-1096 [4] A.Persson, S.Hogmark and J.BergstrÖm:submitted to Journal of International Journal of Fatigue,Vol.26(2004),p.1095-1107 [5] Gong Yi Kui:submitted to Journal of Surface Technology,Vol.36(6)(2007),p.77-80 [6] Yu Hua Chen,Xiao Chun Wu and Hong Bin Wang:submitted to Journal of Heat Treatment of Metals,Vol.33(6)(2008),p.47-49 [7] Yu Feng Li and Wen Bin Shi:submitted to Journal of Die&Mould Industry,Vol.33(3)(2007), p.65-67 [8] K.Takagi, M.Komai and S.Matsuo:Powder Metallurgy Proceeding of World Congress, PM94,Paris,European Powder Metallurgy Association, 1994.1,p.227-234 [9] K.Takagi, S.Ohira, T.Ide etal: submitted to Journal of Modern Developments in Powder Metallurgy, Vol.16(1985),p.153-166 [10] Xiao Ping Zhou and Lin Hua:submitted to Journal of Journal of Steel and Related Materials,Vol.3(6)(2005),p. 450-452 [11] Xiao Ping Zhou and Xin Bin Hu:submitted to Journal of
Taylor:submitted to Journal of Journal of Alloys and Compounds,Vol.287(1999),p.121-125 [15] Motohiro Yamada,Yoshihisa Kouzaki and Toshiaki Yasui:submitted to Journal of Surface & Coatings Technology,Vol.201(2006),p.1745-1751 [16] F.
High Strength of Aluminium-Based Composites by Different Methods of Severe Plastic Deformation (SPD)
Online since: March 2022
Authors: Andinnie Juniarsih, Suryana Suryana, Anne Zulfia, Agus Pramono, Klodian Dhoska, Yeni Muriani Zulaida, Anistasia Milandia
Advanced Nano-engineering Materials Laboratory.
International Journal of Innovative Technology and Interdisciplinary Sciences, 3 (4) 513–520
Materials Science & Engineering A. 627 374–380
Key Engineering Materials. 604 273‒276
TEKNIKA-Journal of Science and Engineering, 17 (02) 7-12
International Journal of Innovative Technology and Interdisciplinary Sciences, 3 (4) 513–520
Materials Science & Engineering A. 627 374–380
Key Engineering Materials. 604 273‒276
TEKNIKA-Journal of Science and Engineering, 17 (02) 7-12
Online since: March 2017
Authors: Amierson Castro Tilendo, Bryan B. Pajarito
Wozniak, et.al.: Journal of the European Ceramic Society Vol. 29 (2009), p. 2259-2265
[3] F.P.W.
Music, et. al.: Brazilian Journal of Chemical Engineering Vol. 28 (2011), p. 89-95 [6] J.C.
Kardos: Polymer Engineering and Science Vol. 16 (1976), p. 344-352 [7] G.
Zak, et.al.: Journal of Manufacturing Science and Engineering Vol. 3 (1997), p. 17-24 [8] Y.J.V.
Madueke, et.al.: IOSR Journal of Polymer and Textile Engineering Vol.1 (2014), p. 39-44 [10] S.Y.
Music, et. al.: Brazilian Journal of Chemical Engineering Vol. 28 (2011), p. 89-95 [6] J.C.
Kardos: Polymer Engineering and Science Vol. 16 (1976), p. 344-352 [7] G.
Zak, et.al.: Journal of Manufacturing Science and Engineering Vol. 3 (1997), p. 17-24 [8] Y.J.V.
Madueke, et.al.: IOSR Journal of Polymer and Textile Engineering Vol.1 (2014), p. 39-44 [10] S.Y.
Online since: August 2011
Authors: Biao Zhou, Ping Ma, Hai Peng Li
Finite Element Analysis on Thermal Characteristics of lathe motorized Spindle
Ping MA 1,a, Biao Zhou 2,b, Haipeng Li 3,c
1, 2, 3Faculty of Electromechanical Engineering, Guangdong University of Technology, Guangzhou, China, 51006
apingma@gdut.edu.cn, bzhoubiao1026@163.com, c420296455@qq.com
Key words: thermal characteristics, lathe motorized spindle, finite element method, temperature field, heat transfer coefficient.
The motorized spindle is driven directly by a built-in servo motor, the shaft is supported by five high precision ceramic ball bearings with angular 15°contact.
Characterizations and models for the thermal growth of a motorized high speed spindle[J], International Journal of Machine Tools and Manufacture, 2003, 43:1345—1366
[3] ZHAO Haitao, YANG Jiangguo, SHEN Jinhua, Simulation of thermal behavior of a CNC machine tool spindle[J], International Journal of Machine Tool & Manufacture, 2006, 46:1-8
Tu, A Power Flow Model for High Speed Motorized Spindles — Heat Generation Characterization, ASME Journal of Manufacturing Science and Engineering, 2001, Vol.123, 494-505
The motorized spindle is driven directly by a built-in servo motor, the shaft is supported by five high precision ceramic ball bearings with angular 15°contact.
Characterizations and models for the thermal growth of a motorized high speed spindle[J], International Journal of Machine Tools and Manufacture, 2003, 43:1345—1366
[3] ZHAO Haitao, YANG Jiangguo, SHEN Jinhua, Simulation of thermal behavior of a CNC machine tool spindle[J], International Journal of Machine Tool & Manufacture, 2006, 46:1-8
Tu, A Power Flow Model for High Speed Motorized Spindles — Heat Generation Characterization, ASME Journal of Manufacturing Science and Engineering, 2001, Vol.123, 494-505
Online since: June 2003
Authors: Krzysztof Jan Kurzydlowski
Kurzydłowski
Deputy Chairman of the State Committee for Scientific Research, Warsaw University of
Technology, Department of Materials Science and Engineering, Woloska 141, 02-504 Warsaw,
Poland
Abstract.
The Materials Engineering and Technology sub-committee reviewed over 40 research organizations with the majority representing research institutes supervised by the Ministry of Economy.
For example the Materials Engineering and Technology sub-committee agreed to a maximum of 12 points.
The Nano-materials project is coordinated by the Faculty of Materials Science and Engineering of Warsaw University of Technology (for more information see www.inmat.pw.edu.pl).
It combines a total of 26 research topics covering all major types of engineering materials such as metals, ceramics, polymers and composites.
The Materials Engineering and Technology sub-committee reviewed over 40 research organizations with the majority representing research institutes supervised by the Ministry of Economy.
For example the Materials Engineering and Technology sub-committee agreed to a maximum of 12 points.
The Nano-materials project is coordinated by the Faculty of Materials Science and Engineering of Warsaw University of Technology (for more information see www.inmat.pw.edu.pl).
It combines a total of 26 research topics covering all major types of engineering materials such as metals, ceramics, polymers and composites.