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Quartz sand purity dictates its applications, with current research focusing on flotation purification. To investigate the effects of ultrasonic pretreatment on quartz flotation, an RKIII single-tank flotation machine was employed at a neutral pH of 6.8, and the impacts of varying ultrasonic powers (120-300 W) and different treatment durations (0-25 min) were discussed. Additionally, ultrasonic pretreatments were carried out in acidic and alkaline environments simulated by 1%-5% solutions of hydrochloric acid and sodium hydroxide, respectively. Through the analysis of impurity content in quartz sand, it was found that under natural pH conditions and a power range of 120-300 W, the optimal purification effect was achieved by adding 100 g of quartz sand to 1200 cm3 of deionized water and subjecting it to ultrasonic treatment for 10-15 min. As the ultrasonic power increased, the purification effect was enhanced. The results showed that the removal of Fe2O3, TiO2, and Al2O3 was increased by 10.4%, 3.3%, and 1.2%, respectively, compared with that of the conventional flotation after ultrasonic pretreatment for 15 min with ultrasound power 240 W in a neutral environment. In the optimal 5% HCl solution, the removal rate of Fe2O3 was 11.2% and 21.6% higher than that of the control group and the untreated group, respectively. The removal rate of TiO2 was 4.6% and 7.9% higher, respectively. The removal rate of Fe2O3 increased by 23.2% and that of TiO2 increased by 9.1% with 240 W ultrasonic treatment in 4% NaOH solution.
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art. no. 190008
Opis fizyczny
Bibliogr. 40 poz., rys., tab., wykr.
Twórcy
autor
- College of Materials, Chemistry&Chemical Engineering, Chengdu University of Technology, Chengdu 610059, China
autor
- College of Materials, Chemistry&Chemical Engineering, Chengdu University of Technology, Chengdu 610059, China
autor
- College of Materials, Chemistry&Chemical Engineering, Chengdu University of Technology, Chengdu 610059, China
autor
- College of Materials, Chemistry&Chemical Engineering, Chengdu University of Technology, Chengdu 610059, China
Bibliografia
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- ALTUN, N. E., HWANG, J., HICYILMAZ, C., 2009. Enhancement of flotation performance of oil shale cleaning by ultrasonic treatment. Int. J. Miner. Process. 91(1-2), 1-13.
- AMBEDKAR, B., CHINTALA, T. N., NAGARAJAN, R., JAYANTI, S., 2011. Feasibility of using ultrasound-assisted process for sulfur and ash removal from coal. Chem. Eng. Process. 50(3), 236-46.
- AMIN, N., KHATTAK, S., NOOR, S., FERROZE, I., 2016. Synthesis and characterization of silica from bottom ash of sugar industry. J. Clean Prod. 117, 207-11.
- AZMI, A. A. B., SANKARAN, R., SHOW, P. L., LING, T. C., TAO, Y., MUNAWAROH, H. S. H., KONG, P. S., LEE, D., CHANG, J., 2020. Current application of electrical pre-treatment for enhanced microalgal biomolecules extraction. Bioresource Technol. 302.
- BAI, J., LUO, D., ZHANG, Y., WU, D., 2023. Flotation Application of Cationic and Mixed Anionic Collectors in Hanzhong Quartz Ore. J. Min. Sci. 59(4), 681-86.
- CHEN and PENG, 2018. Managing clay minerals in froth flotation—A critical review. MIN PROC EXT MET REV 39(5).
- CHEN, Y., TRUONG, V. N. T., BU, X., XIE, G., 2020. A review of effects and applications of ultrasound in mineral flotation. Ultrason. Sonochem. 60.
- CILEK, E. C., OZGEN, S., 2009b. Effect of ultrasound on separation selectivity and efficiency of flotation. Miner. Eng. 22(14), 1209-17.
- DENG, Y., SHU, J., LEI, T., ZENG, X., LI, B., CHEN, M., 2021. A green method for Mn2+ and NH4+-N removal in electrolytic manganese residue leachate by electric field and phosphorus ore flotation tailings. Sep. Purif. Technol. 270.
- FANG, S., XU, L., WU, H., XU, Y., WANG, Z., SHU, K., HU, Y., 2020. Influence of surface dissolution on sodium oleate adsorption on ilmenite and its gangue minerals by ultrasonic treatment. Appl. Surf. Sci., 500.
- FARMER, A. D., COLLINGS, A. F., JAMESON, G. J., 2000. Effect of ultrasound on surface cleaning of silica particles. Int. J. Miner. Process. 60(2), 101-13.
- GHADYANI, A., NOAPARAST, M., TONKABONI, S. Z. S., 2018. A Study on the Effects of Ultrasonic Irradiation as Pretreatment Method on High-Ash Coal Flotation and Kinetics. I Int. J. Coal Prep. Util., 38(7), 374-91.
- GUNGOREN, C., OZDEMIR, O., OZKAN, S. G., 2017. Effects of temperature during ultrasonic conditioning in quartz-amine flotation. Phys. Probl. Miner. Process. 53(2), 687-98.
- GUNGOREN, C., OZDEMIR, O., WANG, X., OZKAN, S. G., MILLER, J. D., 2019. Effect of ultrasound on bubble-particle interaction in quartz-amine flotation system. Ultrason. Sonochem. 52, 446-54.
- HAKIZIMANA, J. N., NAJID, N., GOURICH, B., VIAL, C., STIRIBA, Y., NAJA, J., 2017. Hybrid electrocoagulation/electroflotation/electrodisinfection process as a pretreatment for seawater desalination. Chem. Eng. Sci., 170, 530-41.
- HU, X., LUO, X., LIU, Z., ZHANG, Y., ZHOU, H., YANG, Z., TANG, X., 2024. Flotation separation of feldspar from quartz using sodium fluosilicate as a selective depressant. Rare Metals 43(3), 1288-300.
- JIANG, X., CHEN, J., WEI, M., LI, F., BAN, B., LI, J., 2020. Effect of impurity content difference between quartz particles on flotation behavior and its mechanism. Powder Technol., 375, 504-12.
- KANG, W. and LI, H., 2020. Effect of ultrasonic pretreatment on cleaner flotation of graphite. Journal of China University of Mining & Technology 49(6), 1193-98.
- KURSUN, H., 2014. A Study on the Utilization of Ultrasonic Pretreatment in Zinc Flotation. Sep. Sci. Technol. 49(18), 2975-80.
- LIU, Y., GUO, Y., ZHU, Y., AN, D., GAO, W., WANG, Z., MA, Y., WANG, Z., 2011. A sustainable route for the preparation of activated carbon and silica from rice husk ash. J. Hazard. Mater. 186(2-3), 1314-19.
- MAO, Y., BU, X., PENG, Y., TIAN, F., XIE, G., 2020. Effects of simultaneous ultrasonic treatment on the separation selectivity and flotation kinetics of high-ash lignite. Fuel, 259.
- MAO, Y., CHEN, Y., BU, X., XIE, G., 2019. Effects of 20 kHz ultrasound on coal flotation: The roles of cavitation and acoustic radiation force. Fuel, 256.
- MOWLA, D., KARIMI, G., OSTADNEZHAD, K., 2008. Removal of hematite from silica sand ore by reverse flotation technique. Sep. Purif. Technol. 58(3), 419-23.
- NG, C. Y., PARK, H., WANG, L., 2020. The potential of acoustic sound to improve flotation kinetics. Miner. Eng. 154. 2021. Improvement of coal flotation by exposure of the froth to acoustic sound. Miner. Eng. 168.
- ÖZBAYOĞLU, G., DEPCI, T., ATAMAN, N., 2009. Effect of Microwave Radiation on Coal Flotation. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects 31(6), 492-99.
- OZKAN, S. G., 2002. Beneficiation of magnesite slimes with ultrasonic treatment. Miner. Eng. 15(1-2), 99-101.
- OZKAN, S. G., 2012. Effects of simultaneous ultrasonic treatment on flotation of hard coal slimes. Fuel 93(1), 576-80.
- OZKAN, S. G., 2017. Further Investigations on Simultaneous Ultrasonic Coal Flotation. Minerals 7(10).
- PAN, X., LI, S., LI, Y., GUO, P., ZHAO, X., CAI, Y., 2022a. Resource, characteristic, purification and application of quartz: a review. Miner. Eng. 183.
- PAN, X., LI, S., LI, Y., GUO, P., ZHAO, X., CAI, Y., 2022b. Resource, characteristic, purification and application of quartz: a review. Miner. Eng. 183, 107600.
- PANDEY, J. C., SINHA, M., RAJ, M., 2010. Reducing alumina, silica and phosphorous in iron ore by high intensity power ultrasound. Irin Steel, 37(8), 583-89.
- PENG, Y., MAO, Y., XIA, W., LI, Y., 2018. Ultrasonic flotation cleaning of high-ash lignite and its mechanism. Fuel, 220, 558-66.
- SUN, Y., ZHOU, W., HAN, Y., LI, Y., 2020. Strengthening liberation and separation of magnetite ore via magnetic pulse pretreatment: An industrial test study. Adv. Powder. Technol. 31(5), 2101-09.
- VATALIS, K. I., CHARALAMPIDES, G., PLATIAS, S., BENETIS, N. P., 2014. Market developments and industrial innovative applications of high purity quartz refines. Procedia Economics and Finance 14, 624-33.
- VIDELA, A. R., MORALES, R., SAINT-JEAN, T., GAETE, L., VARGAS, Y., MILLER, J. D., 2016. Ultrasound treatment on tailings to enhance copper flotation recovery. Miner. Eng. 99, 89-95.
- XU, Y., YUAN, Z., MENG, Q., ZHAO, X., DU, Y., 2022. Enhancing the flotation performance of ilmenite with the magnetic treatment of water. Sep. Sci. Technol., 57(1), 83-93.
- YANG, L., LI, X., LI, W., YAN, X., ZHANG, H., 2019. Intensification of interfacial adsorption of dodecylamine onto quartz by ultrasonic method. SEP. PURIF. TECHNOL. 227.
- ZHANG, R., TANG, C., NI, W., YUAN, J., ZHOU, Y., LIU, X., 2023. Research Status and Challenges of High-Purity Quartz Processing Technology from a Mineralogical Perspective in China. Minerals, 13(12).
- ZHONG, T., YU, W., SHEN, C., WU, X., 2022. Research on Preparation and Characterisation of High-purity Silica Sands by Purification of Quartz Vein Ore from Dabie Mountain. Silicon-Neth 14(9), 4723-29.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-7737aab5-086a-4e9a-8b23-9ff60a2ce120