This work is licensed under the Creative Commons Attribution 4.0 International License.
Dai, W., Zhang, L., Fu, J., et al. (2020). Model-data-based switching adaptive control for dense medium separation in coal beneficiation. Control Engineering Practice, 98, 104241.Search in Google Scholar
Zhang, L., Xia, X., Bing, Z. (2017). A dual-loop control system for dense medium coal washing processes with sampled and delayed measurements. IEEE Transactions on Control Systems Technology, PP(6), 1-8.Search in Google Scholar
Wei, J., Zhang, J., Wu, X., et al. (2022). Governance in mining enterprises: An effective way to promote the intensification of resources—Taking coal resources as an example. Resources Policy, 76, 102623-.Search in Google Scholar
Jiang, H., Huang, L., Lu, Q., et al. (2019). Separation performance of coal in an air dense medium fluidized bed at varying feeding positions. Fuel, 243(MAY 1), 449-457.Search in Google Scholar
Zhou, E., Fan, X., Dong, L., et al. (2018). Process optimization for arsenic removal of fine coal in vibrated dense medium fluidized bed. Fuel, 212(jan.15), 566-575.Search in Google Scholar
Zhang, M. Q. (2019). Effect of coaxial electromagnetic field on separation density of dense-medium cyclone. Minerals Engineering, 138.Search in Google Scholar
Pan, J. H., Zhou, C. C., Cong, L. F., et al. (2016). Mercury in Chinese Coals: Modes of Occurrence and its Removal Statistical Laws during Coal Separation. Energy & Fuels, 31(1), 986-995.Search in Google Scholar
Fu, Z., Zhu, J., Barghi, S., et al. (2020). Mixing and segregation behavior in an air dense medium fluidized bed with binary mixtures for dry coal beneficiation. Powder Technology, 371(9).Search in Google Scholar
Niksa, S. (2019). Simulating volatiles conversion in dense burning coal suspensions. Part 3. Extrapolations to entrained flow gasification conditions. Fuel, 252(Sep.15), 841-847.Search in Google Scholar
Zhou, E., Zhang, Y., Zhao, Y., et al. (2017). Collaborative optimization of vibration and gas flow on fluidization quality and fine coal segregation in a vibrated dense medium fluidized bed. Powder Technology, 322, 497-509.Search in Google Scholar
S, Cierpisz. (2017). Strategies for control of parallel gravitational coal separation processes. International Journal of Mineral Processing.Search in Google Scholar
Bu, XiangningNi, ChaoXie, GuangyuanPeng, YaoliGe, LinhanSha, Jie. (2017). Preliminary study on foreign slime for the gravity separation of coarse coal particles in a teeter bed separator. International Journal of Mineral Processing, 160.Search in Google Scholar
Bahrami, A. (2018). The beneficiation of tailing of coal preparation plant by heavy-medium cyclone. International Journal of Coal ence & Technology, 5(3), 374-384.Search in Google Scholar
Dong, L., Zhu, F., Li, Y., et al. (2021). Characteristics of Forced Oscillation in a Pulsation Fluidized Bed (PFB) for Coal Separation by Experimental and Numerical Methods. Chemical Engineering Science, 234(2), 116459.Search in Google Scholar
Sriramoju, S. K., Kumar, D., Majumdar, S., et al. (2021). Sustainability of coal mines: Separation of clean coal from the fine-coal rejects by ultra-fine grinding and density-gradient-centrifugation. Powder Technology, 383, 356-370.Search in Google Scholar
Sun, Q., Chen, B., Li, Y., et al. (2019). Enhanced separation of coal bed methane via bioclathrates formation. Fuel, 243(MAY 1), 10-14.Search in Google Scholar
Eshaq, R., Hu, E., Li, M., et al. (2020). Separation Between Coal and Gangue Based on Infrared Radiation and Visual Extraction of the YCbCr Color Space. IEEE Access, PP(99), 1-1.Search in Google Scholar
Marion, C., Williams, H., Langlois, R., et al. (2017). The potential for dense medium separation of mineral fines using a laboratory Falcon Concentrator. Minerals Engineering, 105, 7-9.Search in Google Scholar