187 research outputs found
The use of thermodynamic modeling to examine alkali recirculation in the iron blast furnace
It is widely recognized that alkali metals, such as, potassium and sodium can cause operational problems in the iron blast furnace. These elements can influence properties, such as, the softening and melting of ores, formation of scaffolds, coke properties, and refractory life. It has been established that recirculation of these elements occurs within the furnace. In the lower furnace vaporization occurs in the high temperature hearth and bosch regions, and condensation occurs in the upper furnace below or in the cohesive zone. For these reasons the input of alkalis into the furnace is strictly controlled. Optimized thermodynamic databases describing slags in the system Al2O3-CaO-FeO-Fe2O3-Na2O-K2O-MgO-SiO2 have been developed and, combined with the computer software FactSage; these databases have been used to predict the possible behaviour of alkalis in the blast furnace and to examine the effects of changing process variables on reactor performance. To demonstrate this approach to process modeling the furnace is considered as a two-stage equilibrium reaction system and the results of initial analysis are reported
High-temperature experimental and thermodynamic modelling research on the pyrometallurgical processing of copper
Uncertainty in the metal price and competition between producers mean that the daily operation of a smelter needs to target high recovery of valuable elements at low operating cost. Options for the improvement of the plant operation can be examined and decision making can be informed based on accurate information from laboratory experimentation coupled with predictions using advanced thermodynamic models. Integrated high-temperature experimental and thermodynamic modelling research on phase equilibria and thermodynamics of copper-containing systems have been undertaken at the Pyrometallurgy Innovation Centre (PYROSEARCH). The experimental phase equilibria studies involve high-temperature equilibration, rapid quenching and direct measurement of phase compositions using electron probe X-ray microanalysis (EPMA). The thermodynamic modelling deals with the development of accurate thermodynamic database built through critical evaluation of experimental data, selection of solution models, and optimization of models parameters. The database covers the Al-Ca-Cu-Fe-Mg-O-S-Si chemical system. The gas, slag, matte, liquid and solid metal phases, spinel solid solution as well as numerous solid oxide and sulphide phases are included. The database works within the FactSage software environment. Examples of phase equilibria data and thermodynamic models of selected systems, as well as possible implementation of the research outcomes to selected copper making processes are presented
Integrated experimental and modelling research methodology for phase equilibria, thermodynamics and viscosities of metallurgical slags
Coupled experimental and modelling studies are combined into an integrated research program on phase equilibria, thermodynamics and viscosities of the metallurgical slag systems. Key issues derived from experiences in continuing development and application of both experimental and thermodynamic modelling research are outlined. Particular emphasis is given to the details of the research methodologies, analysis of reasons for uncertainties and the ways to continuously improve the accuracy of both studies. The ways how the advanced research tools can be implemented into industrial operations are presented
Thermodynamic modelling of the "cu2O"-SiO2, "cu2O"-CaO, and "cu2O"-CaO-SiO 2 systems in equilibrium with metallic copper
Phase equilibrium and thermodynamic experimental data in the Cu 2O - SiO2, Cu2O - CaO, and Cu2O - CaO - SiO2 systems in equilibrium with metallic copper have been critically reviewed. The Modified Quasichemical and Bragg-Williams models in the FactSage computer package were used to describe the Gibbs energy of the molten slag phase as a function of composition and temperature. The available data have been used to optimize simultaneously a set of parameters in thermodynamic model equations for the Gibbs energy of liquid slag. The present thermodynamic optimization was carried out as part of the development of a thermodynamic database of copper-containing slag systems
Experimental phase equilibria studies of the PbO–SiO2 system
Phase equilibria of the PbO–SiO system have been established for a wide range of compositions: (i) liquid in equilibrium with silica polymorphs (quartz, tridymite, and cristobalite) between 740°C and 1580°C, at 60-90 mol% SiO; (ii) with lead silicates (PbSiO, PbSiO, and PbSiO) and lead oxide (PbO) between 700°C and 810°C. A high-temperature equilibration/quenching/electron probe X-ray microanalysis (EPMA) technique has been used to accurately determine the compositions of the phases in equilibrium in the system. Significantly, no liquid immiscibility has been found in the high-silica range, and the liquidus in this high-silica region has been accurately measured. The phase equilibria information in the PbO–SiO system is of practical importance for the improvement of the existing thermodynamic database of lead-containing slag systems (Pb–Zn–Fe–Cu–Si–Ca–Al–Mg–O)
Critical assessment and thermodynamic modeling of the Cu-As system
Thermodynamic assessment and modeling of the Cu-As system are presented. The experimental dataset includes phase equilibrium data, activity measurements, heat contents, enthalpies of formation and mixing. The liquid phase and two non-stoichiometric copper arsenide solid solutions are developed within the framework of the Modified Quasichemical Model (MQM) in pair approximation. It is demonstrated that the unconventional choice of model for solid solution phases is beneficial for this particular system. The resulting set of model parameters will be a part of a large multicomponent thermodynamic database. It is aimed for predictions of phase equilibria, heat balance and distribution of elements in arsenic-containing chemical systems in pyrometallurgical copper and lead industrial operations
Experimental liquidus studies of the Zn-Fe-Si-O system in air
The liquidus of the ternary system ZnO-\FeO"-SiO in air has been experimentally investigated in the tridymite and cristobalite, spinel, and zincite primary phase fields in the temperature range 1 623 - 1 923 K (1 350 - 1 650 8C). Slags containing up to 65 mol.% \FeO" have been studied for the first time. The slag-spinel-zincite eutectic in the binary ZnO-\FeO" system in air has been estimated by extrapolation of the low-SiO part of the ternary system to x(SiO) = 0. High-temperature equilibration on primary phase (silica) or inert metal (platinum) substrates, followed by quenching and direct measurement of Zn, Fe and Si concentrations in the equilibrium phases with electron probe X-ray microanalysis has been used to accurately characterize the system in equilibrium with air. The discrepancies of the previous experimental work in this system have been resolved. The obtained data have been used to reoptimise the existing thermodynamic model
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