R. M. German, . History, and . Sintering, History of Sintering, Sintering: from Empirical Observations to Scientific Principles, pp.13-40, 2014.

R. M. German, History of sintering: empirical phase, Powder Metallurgy, vol.56, issue.2, pp.117-123, 2013.

E. A. Olevsky, Theory of sintering: from discrete to continuum, Materials Science and Engineering: R: Reports, vol.23, issue.2, pp.41-100, 1998.

V. N. Chougule, O. F. Daud, G. R. Gupta, V. H. Shelke, and R. V. Ugale, Numerical Analysis of Combustion Furnace Performance by CFD, IOSR Journal of Mechanical and Civil Engineering, pp.72-79, 2013.

V. N. Prokushin, A. A. Shubin, V. V. Kleimenov, V. V. Alekseev, and ?. N. Marmer, Carbon heating elements for high-temperature furnaces, Fibre Chemistry, vol.24, issue.6, pp.503-504, 1993.

A. Adriana, A review on analytical techniques for natural convection investigation in a heated closed enclosure: Case study, Thermal Science, vol.19, pp.1077-1095, 2015.

T. J. Brain, New thermal conductivity measurements for argon, nitrogen and steam, International Journal of Heat and Mass Transfer, vol.10, issue.67, pp.90133-90133, 1967.

S. V. Egorov, K. I. Rybakov, V. E. Semenov, Y. V. Bykov, O. N. Kanygina et al., Role of convective heat removal and electromagnetic field structure in the microwave heating of materials, Journal of Materials Science, vol.42, issue.6, pp.2097-2104, 2007.

A. Adriana, CFD Study on Heat Transfer in a Muffle Furnace, International Review of Mechanical Engineering, vol.3, p.133, 2009.

M. J. Sable, S. K. Bhor, S. B. Barve, P. A. Makasare, and S. J. Jagtap, Computational Analysis for Enhancement of Natural Convection Heat Transfer on Vertical Heated Plate by Multiple V-Fin Array, International Journal of Applied Engineering Research, vol.6, p.1617, 2011.

J. Kang and Y. Rong, Modeling and simulation of load heating in heat treatment furnaces, Journal of Materials Processing Technology, vol.174, issue.1-3, pp.109-114, 2006.

S. H. Han, D. Chang, and C. Y. Kim, A numerical analysis of slab heating characteristics in a walking beam type reheating furnace, International Journal of Heat and Mass Transfer, vol.53, issue.19-20, pp.3855-3861, 2010.

R. Prieler, B. Mayr, M. Demuth, B. Holleis, and C. Hochenauer, Prediction of the heating characteristic of billets in a walking hearth type reheating furnace using CFD, International Journal of Heat and Mass Transfer, vol.92, pp.675-688, 2016.

A. A. Minea, Simulation of heat transfer processes in an unconventional furnace, Journal of Engineering Thermophysics, vol.19, issue.1, pp.31-38, 2010.

V. Ovchinnikov, Analysis of Furnace Operational Parameters for Controllable Annealing of Thin Films, ICQNM, pp.32-37, 2014.

A. O. Nieckele, M. F. Naccache, and M. S. Gomes, Numerical Modeling of an Industrial Aluminum Melting Furnace, Journal of Energy Resources Technology, vol.126, issue.1, pp.72-81, 2004.

E. Hachem, G. Jannoun, J. Veysset, M. Henri, R. Pierrot et al., Modeling of heat transfer and turbulent flows inside industrial furnaces, Simulation Modelling Practice and Theory, vol.30, pp.35-53, 2013.
URL : https://hal.archives-ouvertes.fr/hal-00741954

E. Hachem, T. Kloczko, H. Digonnet, and T. Coupez, Stabilized finite element solution to handle complex heat and fluid flows in industrial furnaces using the immersed volume method, International Journal for Numerical Methods in Fluids, vol.68, issue.1, pp.99-121, 2010.
URL : https://hal.archives-ouvertes.fr/hal-00549730

E. Hachem, H. Digonnet, E. Massoni, and T. Coupez, Immersed volume method for solving natural convection, conduction and radiation of a hat?shaped disk inside a 3D enclosure, International Journal of Numerical Methods for Heat & Fluid Flow, vol.22, issue.6, pp.718-741, 2012.
URL : https://hal.archives-ouvertes.fr/hal-00730502

A. Alina and A. Dima, Saving energy through improving convection in a muffle furnace, Thermal Science, vol.12, pp.121-125, 2008.

C. Manière, T. Zahrah, and E. A. Olevsky, Inherent heating instability of direct microwave sintering process: Sample analysis for porous 3Y-ZrO2, Scripta Materialia, vol.128, pp.49-52, 2017.

E. A. Olevsky, C. Garcia-cardona, W. L. Bradbury, C. D. Haines, D. G. Martin et al., Fundamental Aspects of Spark Plasma Sintering: II. Finite Element Analysis of Scalability, Journal of the American Ceramic Society, vol.95, issue.8, pp.2414-2422, 2012.

V. V. Skorohod, Rheological basis of the theory of sintering, 1972.

C. Manière, U. Kus, L. Durand, R. Mainguy, J. Huez et al., Identification of the Norton-Green Compaction Model for the Prediction of the Ti-6Al-4V Densification During the Spark Plasma Sintering Process, Advanced Engineering Materials, vol.18, issue.10, pp.1720-1727, 2016.

F. Li and J. Pan, Modelling ?Nano-Effects? in Sintering, Sintering, pp.17-34, 2012.

C. Manière, T. Zahrah, and E. A. Olevsky, Fully coupled electromagnetic-thermal-mechanical comparative simulation of direct vs hybrid microwave sintering of 3Y-ZrO2, Journal of the American Ceramic Society, vol.100, issue.6, pp.2439-2450, 2017.

V. V. Yakovlev, S. M. Allan, M. L. Fall, and H. S. Shulman, Computational Study of Thermal Runaway in Microwave Processing of Zirconia, 2011.

C. Manière, L. Durand, E. Brisson, H. Desplats, P. Carré et al., Contact resistances in spark plasma sintering: From in-situ and ex-situ determinations to an extended model for the scale up of the process, Journal of the European Ceramic Society, vol.37, issue.4, pp.1593-1605, 2017.

T. W. Davies and B. Number, A-to-Z Guide to Thermodynamics, Heat and Mass Transfer, and Fluids Engineering, 2011.

, Muffle Furnace, 2007.

?. Complex-sample-shape, Modelling of gas flow in sintering furnace, Metal Powder Report, vol.50, issue.3, p.40, 1995.

, Plain bearings ? Sintered bushes ? Dimensions and tolerances