方法对比
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| Lerchs-Grossmann 算法× | Lane 的边际品位模型× | 矿山通风× | 采场布置优化× | |
|---|---|---|---|---|
| 领域 | 采矿工程 | 采矿工程 | 采矿工程 | 采矿工程 |
| 方法族 | Process / pipeline | Process / pipeline | Process / pipeline | Process / pipeline |
| 起源年份≠ | 1965 | 1988 | 1880 | 1960 |
| 提出者≠ | Helmut Lerchs and Israel Grossmann | K. F. Lane | Mining Engineering Practice | Mining Engineering Practice |
| 类型≠ | Graph-theoretic algorithm for pit limit optimization | Economic optimization framework for ore classification | System design for safe air quality and worker cooling in underground mines | Optimization framework for underground mine excavation design |
| 开创性文献≠ | Lerchs, H., & Grossmann, I. F. (1965). Optimum design of open-pit mines. Canadian Mining and Metallurgical Bulletin, 58(633), 47-54. link ↗ | Lane, K. F. (1988). The economic definition of ore: cutoff grades in theory and practice. Mining Journal Books, London. link ↗ | Hartman, H. L., Mutmansky, J. M., Ramani, R. V., & Wang, Y. J. (2012). Mine ventilation and ambient air quality. Society for Mining, Metallurgy & Exploration, Inc. link ↗ | Brady, B. H. G., & Brown, E. T. (2004). Rock mechanics for underground mining. Springer Science+Business Media. link ↗ |
| 别名≠ | Lerchs-Grossmann Method, LG Algorithm | Lane Model, Cut-off Grade Optimization, Lane's Optimization Model | Underground Mine Ventilation, Air Flow Design, Mine Haulage Ventilation | Stope Design, Underground Mine Layout, Panel Design |
| 相关≠ | 4 | 3 | 3 | 3 |
| 摘要≠ | The Lerchs-Grossmann Algorithm is a graph-theoretic method for determining the ultimate pit limit in open-pit mining operations. Introduced by Helmut Lerchs and Israel Grossmann in 1965, it maximizes the net present value of extracted ore while respecting slope stability constraints. This algorithm forms the theoretical foundation for most modern pit optimization software. | Lane's Cut-off Grade Model, developed by Kenneth F. Lane and formalized in his 1988 book, provides a rigorous economic framework for determining the minimum grade at which ore should be mined and processed. It accounts for variable mining costs, metallurgical recovery, and commodity prices to optimize profit per unit processed. The model is foundational in mining economics and underpins daily operational decisions at thousands of mines worldwide. | Mine ventilation is the design and operation of systems that deliver fresh air to underground mining areas and remove contaminated air, heat, and hazardous gases. It is critical for worker safety and productivity, maintaining breathable air (sufficient oxygen, low dust and gas concentrations) and acceptable temperatures. Proper ventilation design requires calculating heat loads from mining operations, determining required air volumes, and designing shaft/drift geometry to deliver adequate flow. | Stope layout optimization is the process of designing the size, shape, and spatial arrangement of underground mine excavations (stopes) to maximize ore recovery while maintaining safety and economic viability. It balances the desire for large extraction volumes against rock mechanics constraints and support costs. The layout determines mining productivity, capital investment in support systems, and long-term mine life. |
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