विधियों की तुलना करें
चुनी हुई विधियों की आमने-सामने समीक्षा करें; भिन्नता वाली पंक्तियाँ रेखांकित हैं।
| धातुमल क्षारकता× | एलिंगम आरेख× | |
|---|---|---|
| क्षेत्र | खनन इंजीनियरिंग | खनन इंजीनियरिंग |
| परिवार | Process / pipeline | Process / pipeline |
| उद्भव वर्ष≠ | 1950 | 1944 |
| प्रवर्तक≠ | Pyrometallurgical Practice | Harold Jeffrey Torreyson Ellingham |
| प्रकार≠ | Slag composition parameter for controlling roast/smelt conditions | Gibbs free energy diagram for high-temperature reactions |
| मौलिक स्रोत≠ | Barnes, J. F., Edwards, C. C., & Sims, R. L. (2010). Copper smelting and refining: pyrometallurgical fundamentals. JOM, 52(12), 38-43. link ↗ | Ellingham, H. J. T. (1944). Reducibility of oxides and sulfides. Journal of the Society of Chemical Industry, 63(5), 125-160. link ↗ |
| उपनाम | Basicity Index, Slag Chemistry Parameter | Gibbs Free Energy Diagram, High-Temperature Reduction Diagram |
| संबंधित | 3 | 3 |
| सारांश≠ | Slag basicity is a measure of the composition of slag formed during smelting and roasting operations. It is typically expressed as the ratio of basic oxides (CaO, MgO) to acidic oxides (SiO2). Basicity controls slag fluidity, viscosity, and reactivity, directly affecting metal recovery, processing temperature, and product quality. It is a critical parameter in copper, nickel, and lead smelting. | The Ellingham Diagram, introduced by Harold Ellingham in 1944, is a graphical representation of the Gibbs free energy change for oxide formation and reduction as a function of temperature. It is an essential tool for predicting the thermodynamic feasibility of ore reduction and selecting appropriate reducing agents and temperatures for smelting and roasting operations. |
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