Como escrever as Referencias Bibliográficas para os relatorios de BAC014

Como escrever as Referencias Bibliográficas para os relatorios de BAC014

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VIII - REFERÊNCIAS BIBLIOGRÁFICAS

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BATTAGLIA, J. L., COIS, O., PUIGSEGUR, L., OUSTALOUP, A. (2001), “Solving an Inverse Heat Conduction Problem Using a Non-Integer Identified Model”, Experimental Heat Trasnfer, v. 18, pp.13 – 25.

BATTAGLIA, J. L., PUIGSEGUR, L., CAHUC, O. (2005), “Estimated Temperature on a Machined Surface Using an Inverse Approach”, International Journal of Heat and Mass Transfer, Vol 44, pp.2671 – 2680.

BECK, J. V., BLACKWELL, B., ST CLAIR JR, C. R. (1985), “Inverse Heat Conduction Ill-Posed Problems”, John Wiley & Sons.

BIRD, R. B., LIGHTFOOT, E. N., STEWART, W. E. (2004), “Fenômenos de Transporte”, LTC, Rio de Janeiro, 838p.

CARVALHO, S. R., LIMA (2005), “Determinação do Campo de Temperatura em Ferramentas de Corte Durante um Processo de Usinagem por Torneamento”, Tese de Doutorado, Programa de Pós- Graduação em Engenharia Mecânica da Universidade Federal de Uberlândia, Minas Gerais, Brasil.

CARVALHO, S. R., LIMA E SILVA, S. M. M., MACHADO, A. R., GUIMARÃES G. (2006), “Temperature Determination at the Chip-tool Interface using an Inverse Thermal Model considering the Tool and Tool Holder”, Journal of Materials Processing Technology, Vol. 179, pp. 97 – 104.

CARVALHO, S. R., SANTOS, M. R., SOUZA, P. F. B., GUIMARÃES, G, LIMA E SILVA, S. M. M., (2009), “Comparison of Inverse Methods in the Determination of Heat Flux and Temperature in Cutting Tools During a Machining Process”, High Temperatures High Pressures, Vol. 38, mº 2, pp. 119 – 136.

CAROLLO, L. F. S., (2010), Estimação Simultânea de Propriedades Termofísicas de Materiais Metálicos”, Dissertação de Mestrado, Programa de Pós-Graduação em Engenharia Mecânica da Universidade Federal de Itajubá, Minas Gerais, Brasil.

CHANG, H. H., HUNG, C. L., (2005), “A Three-Dimensional Inverse Problem in Predicting the Heat Fluxes Distribution in the Cutting Tools”, Numerical Heat Transfer, Vol. 48, pp. 1009 - 1034

CHANG, C. L., CHANG, M. (2006), “Non-Iteration Estimation of Thermal Conductivity Using Finite Volume Method”, International Comunication in Heat and Mass Transfer, Vol 33, pp 1013 – 1030.

CHENG, H. H., LI, C. J., LI, R., SHIH, A. J., 2007), “A Three-Dimensional Inverse Problem in Estimating the Applied Heat Flux of a Titanium Drilling: Theoretical and Experimental Studies”, International Journal of Heat and Mass Transfer, Vol. 50, pp. 3265 – 3277.

DOWDING, K. J., BECK, J. V., BLACKWELL, B. F. 1996, “Estimations of Directional – Dependent Thermal Properties in a Carbon – Carbon Composite”, International Journal of Heat and Mass Transfer, Vol 39, n 15, pp 3157 - 3164

ECKHARDT, B., ZORI, L. (2002), “Computer Simulation Helps Keep Down Costs For NASA´s Lifeboat For The International Space Station”, Aircraft Engineering and Space Technology, Vol 74, nº 5, pp 441 - 446

FREUND, S., KABELAC, S. (2010), “Investigation of Local Heat Transfer Coefficient in Plate Heat Exchangers With Temperature Oscilations IR Thermography and CFD”, International Journal of Heat and Mass Transfer, Vol 53, pp 3764 – 3781.

GRZESIK, W., BARTOSZUK, M., NIESLONY, P. (2005), “Finite Element Modeling of Temperature Distribution in the Cutting Zone in Turning Process With Difference Coated Tools”, Journal of Materials and Processing Technology, pp 1024 - 1211

JEN, T. C., GUITIERREZ, G., EAPEN, S. (2001), Numerical Analysis in Interrupted Cutting Tool Temperatures”, Numerical Heat Transfer, Vol. 39, pp. 1 - 20.

HAMILTON, R., MACKENZIE, D., LI, H. (2010), “Multi- physics Simulation of Friction Stir Welding Process”, International Journal for Computer Aided Engineering and Software, Vol 27 nº 7, pp 967 - 985.

HOLMAN, J. P. (2001), “Experimental Methods for Engineers”, 7th ed., McGraw-Hill Book

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HUANG, C. H., WANG, S. P. (1999), “A Three-dimensional Inverse Heat Conduction Problem in Estimating Surface Heat Flux by Conjugate Gradient Method”, International Journal of Heat and Mass Transfer, Vol 42, pp 3387 - 3403.

HUANG, C. H., WANG, S. P. (2000), “A Three-dimensional Inverse Forced Convection Problem in Estimating Surface Heat Flux by Conjugate Gradient Method”, International Journal of Heat and Mass Transfer, Vol 42, pp 3387 - 3403.

KOMANDURI, R., HOU, Z. B. (2001a), “A Review of the Experimental Techniques for the Measurement of Heat and Temperature Generated in Some Manufacturing Process and Tribology”, Tribology International, Vol 34, pp 653 - 682.

KOMANDURI, R., HOU, Z. B. (2001b), “Thermal Analysis of Dry Bearing – A Comparison Between Analytical, Numerical (Finite Element) and Experimental Results”, Tribology International, Vol 34, pp 145 - 160.

LÖHNER, R., CAMELI, F. (2005), “Optimal Placement of Sensors for Contaminant Detection Based on Datailed 3D CFD Simulation”, International Journal for Computer – Aided engineering and Software, Vol 22, nº 3, pp 260 - 273

MALISKA, C. R. (2004), “Transferência de Calor e Mecânica dos Fluidos Computacional”, LTC, 2ª Edição, 453p.

MIRADE, P. S., DAUDIN, J. D., DUCEPT, F., TRYSTRAM, G., CLEMENT, J. (2004), “Characterizations and CFD Modeling of Air Temperature and Velocity Profiles in an Industrial Biscuit Backing Tunnel Oven”, Food Research international, Vol 37, pp 1031 - 1039

ÖZEL, T., ALTAN, T. (2000), “Process Simulation Using Finite Element Method – Prediction of Cutting Forces, Tool Stress and Temperatures in High – Speed Flat in Milling”, International Journal of Machine Tools and Manufacture, Vol 40, pp 713 - 738.

Özisik, N. M. (1993), “Heat Conduction”, 2nd ed.,Wiley, New York, 716 p.

ÖZISIK, M. N., ORLANDE, H. R. B. (2000), “Inverse Heat Transfer”, Taylor & Francis, PP 3,7 -8.

PATNAIK, G., BORIS, J. P., GRINSTEIN, F. F. (2003), “Large Scale Urban Simulation With The Miles Approach”, CFD Conference, Orlando, Florida, June, 23 - 26, 2003

ROUBOA, A., MONTEIRO, E. (2008), “Heat Transfer in Multi-block Grid During Solidification: Performance of Finite difference and Finite Volume Method”, Journal of Materials Processing Technology, Vol 204, pp 451 - 458

SHIQUEMORI, E. H., HARTER, F. P., CAMPOS VELHO, H. F., da SILVA, J. D. S. (2002), “Estimation of Boundary Conditions in Conductions Heat Transfer by Neural Networks”, Tendências em Matemática Aplicada e Computacional, Vol 3, nº 2, pp 189 - 195

SILVA, C. P. (2011) Comparação de Técnicas de Problemas Inversos em Transferência de Calor”, Dissertação de Mestrado, Programa de Pós- Graduação em Engenharia Mecânica da Universidade Federal de Itajubá, Minas Gerais, Brasil.

STEPHENSON, D. A. (1991), “Assessment of Steady-State Metal Cutting Temperature Models Based on Simultaneous Infrared and Thermocouple Data”, Journal of Engineering for Industry, Vol. 113, pp. 121 - 128.

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VERSTEEG, H. K., MALALASEKERA. (1995), “An Introduction To Computational Fluid Dynamic: The Finite Volume Method”, Longman Scientific and Technical, 2st ed, England, 257p

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XIAOXIANG, C., WEIHAO, V. (2010), “Numerical Simulation of the Temperature Field Within New Typo of Monolayer Freezing – Shaft Lining”, Mining Science and Technology, Vol 20, pp 198 - 203

ZENG, Z., WANG, L., WANG, Y., ZHANG, H. (2009), “Numerical and Experimental Investigation on Temperature Distribution of the Discontinuous Welding”, Computational Materials Science, Vol 44, pp 1153 - 1162

ZHOU, M., CLODE, M. P. (1998), “A Finite Element Analysis for the Least Temperature Rise in a Hot Torsion Specimen”, Finite Element in Analysis and Design, Vol 31, pp 1 - 14

ZUECO, J., ALHAMA, F., GONZALEZ FERNANDEZ, C. F. (2004),“Inverse Determination of the Specific Heat of Foods”, Journal of Food Engineering, Vol 64, pp. 347 - 353.

WANG, B. L., TIAN, Z. H. (2005), “Application of Finite Element – Finite Difference Method To The Determinations of Transient Temperature Field in Functionally Graded Materials”, Finite Element Analysis and Design, Vol 41, pp 335 – 349.

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