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The purity of a quartz ore is relatively low at a SiO2 content of 97.18%, and the main impurity in the ore is Fe, Al, and Ca bearing minerals. The main component in an industrial waste bacteria (WJ) is polysaccharides, which may be used as depressors for inhibiting iron minerals in quartz flotation. Moreover, WJ belongs to microbial inhibitors because it is mainly composed of bacteria. As a result of this study, a concentrate grade of 99.88% at recovery over 80% was obtained under the condition of 2000 g/Mg WJ dosage, a grinding fineness of 70% -0.074 mm, pH 11.7, 400 g/Mg CaCl2, and 800 g/Mg NaOL in the flotation experiments for the quartz ore. Moreover, a SiO2 grade of 99.97% at a recovery of 68.85% was obtained at an acid dosage of 40 kg/Mg by using mixed acid of H2SO4, HCl, HNO3, and HF in mass ratios of 20%, 30%, 20%, and 30%, respectively, in subsequent acid leaching of the quartz flotation concentrate. Zeta potential analysis before and after the interaction of quartz and hematite with WJ showed that WJ increased the zeta potential of hematite significantly but had little impact on the zeta potential of quartz, indicating stronger adsorption of WJ on hematite than on quartz. FTIR analysis showed that there exist not only –COOH, –CH2–, and –CH3, which are the functional groups of starch but also NH2 and –C=O-NH– in WJ. The NH2 and –C=O-NH– in WJ are the important groups for adsorption, so the depressing effect on hematite was better for WJ than starch.
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Tom
Strony
18--28
Opis fizyczny
Bibliogr. 26 poz.
Twórcy
autor
- School of Mining Engineering, University of Science and Technology Liaoning, Anshan , China
autor
- School of Mining Engineering, University of Science and Technology Liaoning, Anshan , China
autor
- School of Mining Engineering, University of Science and Technology Liaoning, Anshan , China
autor
- School of Mining Engineering, University of Science and Technology Liaoning, Anshan , China
Bibliografia
- BERNARD, R.G., JACK, J.P., 2005. Molecular biotechnology. Chemical Industry Press, Beijing. 3.
- GUO, J.S., GUO, C.S., 1975. Quartz glass. China Construction Industry Press, Beijing.
- HAO, H.Q., LI, L.X., YUAN, Z.T., LIU, J.T., 2018. Molecular arrangement of starch, Ca2+ and oleate ions in the sideritehematite-quartz flotation system. Journal of Molecular Liquids. 254: 349-356.
- JIANG, H., HAN, W.P., ZHAO, C., LUO, H.F., XIANG, G.Y., 2019. Adsorption behaviors and mechanisms of quaternary ammonium salt collectors on quartz samples with different particle sizes. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 581.
- LI, Y., XU, S., 1995. Mineral processing of quartzite and its deep process new technique. Conservation and Utilization of Mineral Resources. (5), 23-26.
- LIU, Y.C., 1993. Research on new technology and mechanism of flotation separation of feldspar and quartz. Northeastern University, Shenyang. 85-95.
- LI, H.P., 2002. Structure-performance of modified polymers and the mechanism for flotation of aluminum and silicate minerals. Central South University, Changsha.
- LIU, J.T., DAI, S.J., YANG, S.Y., LI, X.A., ZHOU, D.Q., 2013. Application of microorganism depressor in reverse flotation of hematite ore for removal of silicate. Mining R & D. 33(5), 25-28.
- LI, X.X., LI, T.H., GAO, J.X., HUANG, H.Q., LI, L.B., LI, J.S., 2016. A novel ‘‘green’’ solvent to deeply purify quartz sand with high yields: A case study. Journal of Industrial and Engineering Chemistry. (35), 383-387.
- LV, H.Z., PENG, Z., TONG, X., CHEN, L.Z., CHEN, Y.M., 2017. Pulsating high gradient magnetic separation for purification of quartz. Physicochemical Problems of Mineral Processing. 53, 617-627.
- LIU, W.B., LIU, W.G., WANG, B.Y., DUAN, H., PENG, X.Y., CHEN, X.D., ZHAO, Q., 2019. Novel hydroxy polyamine surfactant N-(2-hydroxyethyl)-N-dodecyl-ethanediamine: Its synthesis and flotation performance study to quartz. Minerals Engineering. 142, 105894.
- LARSEN, E., KOWALCZUK, P.B., KLEIV, R.A., 2019. Non-HF collectorless flotation of quartz. Minerals Engineering. 133, 115-118.
- MA, S.B., HAN, Y.X., YANG, X.SH., LI, Y.J., 2006. The effect of different kinds of starches on the flotability of hematite. Nonferrous Mining and Metallurgy. 22(5), 23-25.
- NATARAJAN, K.A., PADUKONE, S.U., 2012. Microbially induced separation of quartz from hematite using yeast cells and metabolites. Minerals & Metallurgical Processing. 29(2), 81-87.
- POTAPINE, C., 1954. Quartzite, vein quartz and sandstone. Geology Press, Beijing. 2-5.
- PAULA, R.M.C.N., TEREZA, N.C.D., MOURA, M.C.P.A., ANTÔNIO, E.C.P., AFONSO, A.D.N., 2019. Depressants in nanoemulsion systems applied to quartz and hematite microflotation. Journal of Materials Research and Technology. 8(6), 5529-5535.
- SUN, C.Y., YIN, W.Z., 2001. The principle of silicate mineral flotation. Science Press, Beijing, 312.
- SUN, W.H., LIU, W.G., DAI, S.J., YANG, T., DUAN, H., LIU, W.B., 2020. Effect of Tween 80 on flotation separation of magnesite and dolomite using NaOL as the collector. Journal of Molecular Liquids. 315, 113712, 1-8.
- TUNCUK, A., AKCIL, A., 2014. Removal of iron from quartz ore using different acids: A laboratory-scale reactor study. Mineral Processing & Extractive Metallurgy Review. 35(4), 217-228.
- TENG, Q., WANG, H., 2020. Effect of silicate bacteria on quartz flotation separation. Separation Science and Technology. (4), 1-9.
- WEN, Q.B., TENG, Q., YANG, Z.C., GUO, Y.J., LIU, S.Y., 2020. Effect and mechanism of causticized starch on flotation separation of magnetite and phlogopite. Conservation and utilization of mineral resources. 40(2), 62-69.
- ZHAO, H.L., ZHENG, S.Y., ZHANG, W.Q., 2005. Comparison of effects on removing iron from silica sand by different types of high magnetic intensity separators. Non-Metallic Mines. 28(3), 39-40.
- ZHOU, Y.H., 2005. Study on refining quartz powder by leaching in HF acid solution. Mineralogy and Petrology. 25(3), 23-26.
- ZHU, H.W., 2005. Spectrum analysis of organic molecule structure. Chemical Technical Press, Beijing.
- ZHANG, X.R., ZHU, Y.G., XIE, Y., SHANG, Y.B., ZHENG, G.B., 2017. A novel macromolecular depressant for reverse flotation: Synthesis and depressing mechanism in the separation of hematite and quartz. Separation & Purification Technology. 186, 175-181.
- ZIVKO, S., ZORAN, B., SLAVICA, M., MIROSLAV, I., LJUBINKO, S., VLADIMIR, J., DRAGANA, N., 2017. The choice of high gradient magnetic separation processes for removal of Fe2O3 carriers from quartz raw material. Gospodarka Surowcami Mineralnymi. 33(4), 93-106
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-a7ff201d-3792-4e12-94cb-4e2a836a39a4