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Better Tissue Engineering Materials Through the use of Nanotechnology Batur Ercan 1 and Thomas J.
Webster 1,2 1Division of Engineering and 2Orthopaedics Brown University Providence, RI 02912 USA E-mail: Batur_Ercan@Brown.edu; Thomas_Webster@Brown.edu Keywords: Tissue Engineering, Nanotechnology, Bionanotechnology Abstract.
[8] M Sato, YH An, EB Slamovich, and TJ Webster, International Journal of Nanomedicine 2006; in press
International Journal of Nanomedicine (2006) 1(1): 65-72
Tissue Engineering (2001) 7: 291- 301

Seven typical engineering ceramic materials are analyzed using the method, the objective and comprehensive results are gained.
The sample matrix of ceramic mateials performance parameters can be presented as (1) Where m is the number performance parameters of ceramic material, n is the number of ceramic materials.
The evaluation results of workability of ceramic materials are objective, stable and reasonable using this method, it can be applied as a valid refrence to design ceramic materials and select machining parameters of ceramic materials.
Rao: International Journal of Machine Tools and manufacture.
[5] Yu A B, Chen Y, Jia DW: Key Engineering Materials.

The ceramic coat and bond coat thickness [7].
Stoever., Ceramic materials for thermal barrier coatings, Journal of the European Ceramic Society 24 (2004) 1–10
Manivannan, Design and Analysis of new Type slots on Piston to control Thermal Expansion, International journal of applied engineering research, volume 8, number 7 (2013) pp. 831-836
[7] Muhammet Cerit., Mehmet Coban., Temperature and thermal stress analyses of a ceramic-coated aluminum alloy piston used in a diesel engine, International Journal of Thermal Sciences 77 (2014) 11-18
Narasimha., Thermal barrier Analysis in Diesel, International Journal of Modern Engineering Research, Vol.3, Issue.3, May-June. (2013) pp-1435-1441.

Fang-Jung Shiou, Jian-Chi Fang, Department of Mechanical Engineering, National Taiwan University of Science and Technology, Taiwan a shiou@mail.ntust.edu.tw, bM9103206@mail.ntust.edu.tw Keywords: bio-ceramics ZrO2, Taguchi's experimental method, PC-based muli-axis engraving machine, reverse engineering Abstract.
Liu, A Finishing Model of Spherical Grinding Tools for Automated Surface Finishing Systems, The International Journal for Manufacturing Science & Production, Vol. 1 (1) (1997), p.17
Li, Automated surface finishing of plastic injection mold steel with spherical grinding and ball burnishing processes, The International Journal of Advanced Manufacturing Technology, Vol. 28 (2006), p.61
Sergeev, Dry high speed milling as a new machining technology of ceramics for biomedical and other applications, Ceramic Engineering and Science Proceedings, Proc.
Phadke, Quality engineering using robust design (Prentice-Hall, N.

El-Tamimi3,c 1,2,3Industrial Engineering Department, College of Engineering, King Saud University, P.O.
RUM, shown in Fig. 1, is recognized as a reliable and cost effective machining method that is being applied in a number of critical engineering applications [1-3].
Ghani: Application of Taguchi Method in the Optimization of Turning Parameters for Surface Roughness, International Journal of Science Engineering and Technology Vol. 1, No. 3, (2008)
Chandramohan: Optimization Of Surface Roughness Of Aisi 304 Austenitic Stainless Steel In Dry Turning Operation Using Taguchi Design Method, Journal of Engineering Science and Technology Vol. 5, No. 3 (2010), p. 293 – 301
[16] Jitendra Verma, Pankaj Agrawal and Lokesh Bajpai: Turning Parameter Optimization For Surface Roughness Of Astm A242 Type-1 Alloys Steel By Taguchi Method, International Journal of Advances in Engineering & Technology, March (2012)

Llanes: Journal of the European Ceramic Society 27 (2007), p. 1443-1448 [2] R.
Lube: Key Engineering Materials 290 (2005), p. 191-198 [3] F.
Sih: Journal of Basic Engineering, 85D(4) (1963), p. 519-527 [4] G.C.
Methods of analysis and solutions of crack problems (Noordhoff International Publishing, Leyden 1973)
Knésl: accepted for publication in Proceedings of International Conference on Fracture (ICF-12), Ottawa, 2009

Reinforced Green Ceramic Shell Mould for Investment Casting Process ZAWATI Harun1,a *, NOOR HASLIZA Kamarudin1,b, MUSTAFFA Ibrahim2,c, MAIZLINDA IZWANA Idris2,d, SUFIZAR Ahmad2,e 1 Advanced Material and Manufacturing Centre, Faculty of Mechanical Engineering, Universiti Tun Hussein Onn Malaysia, Batu Pahat 86400,Johor,Malaysia 2Faculty of Mechanical and Manufacturing Engineering, Universiti Tun Hussein Onn Malaysia, 86400 Parit Raja, Johor, Malaysia a zawati@uthm.edu.my, bainul_qatrunnada@yahoo.com, cmustaffa@uthm.edu.my, dmaizlinda@uthm.edu.my, esufizar@uthm.edu.my Keywords: brittle green ceramic body, cracking mechanism, reinforced shell mould, rice husk Abstract.
Multilayer ceramic composites with high failure resistance, Journal of the European Ceramic Society. 27 (2007)1373–1377
The influence of autoclave steam on polymer and organic fibre modified ceramic shells, Journal of the European Ceramic Society. 25 (2005) 1081–1087
Key Engineering Materials. 471-472 (2011) 922-927
Material Science and Engineering, 8 ed, John Wiley & Sons Inc., 2011.

Machinability of Aluminum Nitride Ceramic using TiAlN and TiN Coated Carbide Tool Insert Mohan Reddy.M 1, a, Alexander Gorin 2,b , Abou-El-Hossein.K.A. 3,c and Sujan.D1,a 1 Mechanical Engineering Department, Curtin University of Technology (Malaysia Campus), CDT 250, Miri, Sarawak, 98009, Malaysia 2Chemical Engineering Department, Swinburne University of Technology,Kuching, 93350, Malaysia 3Mechanical & Aeronautical Department of Mechatronics Engineering, Nelson Mandela Metropolitan University, Port Elezebeth, 6031, South Africa amohan.m@curtin.edu.my Keywords: Aluminum nitride ceramic, Surface roughness, Tool wear, and End milling Abstract: This research presents the performance of Aluminum nitride ceramic in end milling using TiAlN and TiN coated carbide tool insert under dry machining.
ASME, Journal of engineering for Industry 1989; 111:2111-18
[5] Daudin.B, Martin.PN, Mega-electronvolt ion beam polishing of anodically grown alumina, Materials Science and Engineering, 1989; A: 63-66
Ceramics Industry 1990; 134(4):53–57 [7] Rajurkar.K.P, Wang.Z.Y, Kuppattan.A, “Micro removal of ceramic material (AL2O3) in the precision ultrasonic machining.”, Precision Engineering 23, 1999, 73-78
International Journal of Machine Tools and Manufacture 43 (8),2003: 811-823

Rombach, Residual stresses and damage in ceramics due to contact loading, Proceeding of the Fifth International Conference on Residual Stresses (1998), Linköping University, Sweden, Vol. 1, 302-307
Frey, Strengthening of ceramics by shot peening, Ceramic Engineering & Science Proceedings (2004), Vol. 25 (3), 195-200
Gumbsch, Strengthening of silicon nitride ceramics by shot peening, International Journal of Materials Research (2006), Vol. 97, 1673-1678
Cramer, Numerical modeling of a wing skin peen forming process, Journal of Materials Engineering and Performance (1996), 5, 753-760
Han, Combined finite/discrete element and explicit/implicit simulations of peen forming process, Engineering Computations (2002), Vol. 19, 1, 92-118

In engineering is for determination of cutting tools durability used T-vc dependence.
Introduction Engineering consists of extensive set of elements, where one of the most important elements is machining.
Panda et al., Accompanying phenomena in the cutting zone machinability during turning of stainless steels, International Journal of Machining and Machinability of Materials 5/4 (2009) 383-400
Duplák, T-vc dependence for cutting ceramic in standard ISO 3685, Manufacturing Engineering 9/4 (2010) 58-62
Hatala et.al, T-Vc Dependence for sintered metal in standard ISO 3685, Technological Engineering 7/2 (2010) 6-9