000000941 001__ 941
000000941 005__ 20141118153510.0
000000941 04107 $$acze
000000941 046__ $$k2002-05-13
000000941 100__ $$aŠtětina, Josef
000000941 24500 $$aOPTIMIZATION CASTING OF CERAMIC MATERIAL USING MODEL OF THE TEMPERATURE FIELD
000000941 24630 $$n8.$$pEngineering Mechanics 2002
000000941 260__ $$bInstitute of Mechanics and Solids, FME, TU Brno
000000941 506__ $$arestricted
000000941 520__ $$2cze$$aAbstrakt: EUCOR, a corundo-badelleyit material, which is not only resistant to wear but also to extremely high temperatures, is seldom discussed in literature. The solidification and cooling of this ceramic material in a non-metallic mould is a very complicated problem of heat and mass transfer with a phase and structure change. Investigation of the temperature field, which can be described by the 3D Fourier equation, is not possible without the engagement of a numerical model of the temperature field of the entire system-comprising the casting, the mould and the surroundings.  A temperature field had been investigated on a 350x200x400 mm block casting-the so-called "stone"-with a riser of 400 mm using a numerical model with graphical input and output. The computation included the automatic generation of the network, and the successive display of the temperature field using iso-zones or iso-lines. The thermophysical properties of the cast, as well as the mould materials, were gathered and the initial derivation of the boundary conditions was conducted on all boundaries of the system. The initial measurements were conducted using thermocouples in a limited number of points. The paper provides results of the initial computation of the temperature field, which prove that the transfer of heat is solvable, and also that using the numerical model it is possible to optimise the technology of production of this ceramic material, which enhances its utilisation. The results are complemented with an approximated measurement of the chemical heterogeneity of EUCOR.
000000941 520__ $$2eng$$aAbstract: EUCOR, a corundo-badelleyit material, which is not only resistant to wear but also to extremely high temperatures, is seldom discussed in literature. The solidification and cooling of this ceramic material in a non-metallic mould is a very complicated problem of heat and mass transfer with a phase and structure change. Investigation of the temperature field, which can be described by the 3D Fourier equation, is not possible without the engagement of a numerical model of the temperature field of the entire system-comprising the casting, the mould and the surroundings.  A temperature field had been investigated on a 350x200x400 mm block casting-the so-called "stone"-with a riser of 400 mm using a numerical model with graphical input and output. The computation included the automatic generation of the network, and the successive display of the temperature field using iso-zones or iso-lines. The thermophysical properties of the cast, as well as the mould materials, were gathered and the initial derivation of the boundary conditions was conducted on all boundaries of the system. The initial measurements were conducted using thermocouples in a limited number of points. The paper provides results of the initial computation of the temperature field, which prove that the transfer of heat is solvable, and also that using the numerical model it is possible to optimise the technology of production of this ceramic material, which enhances its utilisation. The results are complemented with an approximated measurement of the chemical heterogeneity of EUCOR.
000000941 540__ $$aText je chráněný podle autorského zákona č. 121/2000 Sb.
000000941 7112_ $$aEngineering Mechanics 2002$$cSvratka (CZ)$$d2002-05-13 / 2002-05-16$$gEM2002
000000941 720__ $$aŠtětina, Josef$$iRamík, Pavel$$iKavička, František$$iHeger, Jaromír
000000941 8560_ $$ffischerc@itam.cas.cz
000000941 8564_ $$s394002$$uhttps://invenio.itam.cas.cz/record/941/files/Stetina.pdf$$y
             Original version of the author's contribution as presented on CD, .
            
000000941 962__ $$r451
000000941 980__ $$aPAPER