To know more precise the value of overall heat transfer coefficient is on a special importance to programs (software) that models the solidification process for project casting technology in order to optimize them by dimensioning and appropriate placement both the gating system and the risers for eliminate casting defects, shrinkages. The paper aims to determin the value of overall heat transfer coefficient on the cooling curve recorded in casting-solidification real conditions. The values obtained for the overall heat transfer coefficient (2.34 to 25.41) · 10−4 [cal/s.grad.cm2]) for different casting conditions prove that this parameter can not be considered as a constant of the casting mould material.
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 Varga Bela Musteaţă Florin Ciobanu Ioan Bedo Tibor Munteanu Ion Sorin Crişan Aurel: Study on Shrinkage Development Inside an Al-Si Alloy Casting by Computer Solidification Simulation RECENT Vol. 17 no. 1(47) March 2016 pp. 55-68
 Bedo Tibor Dăian Marcel Varga Bela Stoicănescu Maria Crişan Aurel Ciobanu Ioan: A Simulation and Experiment Concerning the Solidification of an Al-Zn Alloy Casting RECENT Vol. 17 no. 2(48) July 2016 pp. 83
 Bencomo A. Bisbal R. Morales R.: Simulation of the aluminum alloy A356 solidification cast in cylindrical permanent molds Revista Matéria v. 13 n. 2 pp. 294 – 303 2008
 Konopka Z. Łągiewka M. Zyska A.: Evaluation of the heat transfer coefficient at the metal-mould interface during flow Archives of Foundry Engineering Volume 7 Issue 4/2007 101-104
 Ulkarni S.N. K. Adhakrishna D.K. R: Effect of casting/mould interfacial heat transfer during solidification of aluminium alloys cast in CO2-sand mould Materials Science-Poland 29(2) 2011 pp. 135-142
 Jabbari M. Fardi Ilkhchy A. Davami P.: Effect of pressure on heat transfer coefficient od A356 aluminium alloy Journal of Materials Science and Engineering with Advanced Technology Volume 4 Number 1 2011 Pp 1-20
 Sahin H. M. Kocatepe K. Kayıkcı R. Akar N.: Determination of unidirectional heat transfer coefficient during unsteady-state solidification at metal casting–chill interface Energy Conversion and Management 47 (2006) 19–34
 Felczak G. De Mey and B. Więcek Determination of the heat transfer coefficient distribution Quantitative InfraRed Thermography 2016 pp 236-241
 Fardi Ilkhchy A. Varahraam N. Davami P. Evaluation of Pressure Effect on Heat Transfer Coefficient at The Metal-Mold Interface For Casting of A356 Al Alloy Iranian Journal of Materials Science & Engineering Vol. 9 Number 1 March 2012
 Fardi Ilkhchy A. Jabbari M. Davami P. Effect of pressure on heat transfer coefficient at the metal/mold interface of A356 aluminum alloy International Communications in Heat and Mass Transfer 39 (2012) 705–712
 Jer-Haur Kuo Ruey-Jer Weng Weng-Sing Hwang Effects of Solid Fraction on the Heat Transfer Coefficient at the Casting/Mold Interface for Permanent Mold Casting of AZ91D Magnesium Alloy Materials Transactions Vol. 47 No. 10 (2006) pp. 2547 to 2554 The Japan Institute of Metals
 Alloy Kuo J H Hsu F L Hwang W S Yeh J L Chen S J Effects of Mold Coating and Mold Material on the Heat Transfer Coefficient at the Casting / Mold Interface for Permanent Mold Casting of A356 Aluminum Transactions of American Foundry Society Volume 109 Pp 1-17 2001
 Pedram Mehraram Measuring Heat Transfer during Twin Roll Casting of Metals A thesis presented to the University of Waterloo in fulfillment of the thesis requirement for the degree of Master of Applied Science in Mechanical Engineering Waterloo Ontario Canada 2010 pp. 115
 Pehlke R.D. John M. Cookson Shouwei Hao Prasad Krishna Kevin T. Bilkey: Heat Transfer at the Mold - Metal Interface in Permanent Mold Casting of Aluminum Alloys Project Final Report Department of Materials Science and Engineering The University of Michigan Ann Arbor MI 48109-2136 December 14200 1 Prepared for THE U.S. DEPARTMENT OF ENERGY AWARD NO. DE-FC07-97ID13559
 Mirela Popescu Bela Varga: Structures of Aluminium Base Alloys Solidified by Vibrations in Advanced Materials Research vol. 1128 Advanced Technologies of Materials Processing 2015 pp. 88-97.