Sulfuric acid recovery from rare earth sulphate solutions by diffusion dialysis

Sulfuric acid recovery from rare earth sulphate solutions by diffusion dialysis was studied. The mass transfer model of diffusion dialysis was established, the comparison between the experimental results and mathematical results was carried out, and the numerical analysis on the effects of operation...

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Published in	Transactions of Nonferrous Metals Society of China Vol. 16; no. 4; pp. 951 - 955
Main Author	唐建军周康根张启修
Format	Journal Article
Language	English
Published	Elsevier Ltd 01.08.2006 School of Construction and Environmental Engineering, Shenzhen Polytechnic, Shenzhen 518055, China%School of Metallurgical Science and Engineering, Central South University, Changsha 410083, China
Subjects	diffusion dialysis mathematical model rare earth recovery sulfuric acid 数学模型硫磺酸腹膜透析 mathematical model rare earth recovery diffusion dialysis sulfuric acid
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ISSN	1003-6326
DOI	10.1016/S1003-6326(06)60358-0

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Abstract	Sulfuric acid recovery from rare earth sulphate solutions by diffusion dialysis was studied. The mass transfer model of diffusion dialysis was established, the comparison between the experimental results and mathematical results was carried out, and the numerical analysis on the effects of operational parameters was studied. The results indicate that the derived mathematical model shows good quantitative relation between sulphuric acid recovery ratio and operational parameters, and the mathematical results agree with the experimental results well. The numerical analysis results indicate that it is appropriate to keep the ratio of water and feed flow rates, processing capacity per membrane area and recovery ratio of sulphuric acid to be 1, 20 L/（m^2.d） and 0.7-0.8, respectively.
AbstractList	Sulfuric acid recovery from rare earth sulphate solutions by diffusion dialysis was studied. The mass transfer model of diffusion dialysis was established, the comparison between the experimental results and mathematical results was carried out, and the numerical analysis on the effects of operational parameters was studied. The results indicate that the derived mathematical model shows good quantitative relation between sulphuric acid recovery ratio and operational parameters, and the mathematical results agree with the experimental results well. The numerical analysis results indicate that it is appropriate to keep the ratio of water and feed flow rates, processing capacity per membrane area and recovery ratio of sulphuric acid to be 1, 20 L/(m 2·d) and 0.7-0.8, respectively. Sulfuric acid recovery from rare earth sulphate solutions by diffusion dialysis was studied. The mass transfer model of diffusion dialysis was established, the comparison between the experimental results and mathematical results was carried out, and the numerical analysis on the effects of operational parameters was studied. The results indicate that the derived mathematical model shows good quantitative relation between sulphuric acid recovery ratio and operational parameters, and the mathematical results agree with the experimental results well. The numerical analysis results indicate that it is appropriate to keep the ratio of water and feed flow rates, processing capacity per membrane area and recovery ratio of sulphuric acid to be 1, 20 L/（m^2.d） and 0.7-0.8, respectively. Sulfuric acid recovery from rare earth sulphate solutions by diSusion dialysis was studied. The mass transfer model of diffusion dialysis was established, the comparison between the experimental results and mathematical results was carried out, and the numerical analysis on the effects of operational parameters was studied. The results indicate that the derived mathematical model shows good quantitative relation between sulphuric acid recovery ratio and operational parameters, and the mathematical results agree with the experimental results well. The numerical analysis results indicate mat it is appropriate to keep the ratio of water and feed flow rates, processing capacity per membrane area and recovery ratio of sulphuric acid to be 1, 20 L/(m2*d) and 0.7-0.8, respectively. TG1; Sulfuric acid recovery from rare earth sulphate solutions by diffusion dialysis was studied. The mass transfer model of diffusion dialysis was established, the comparison between the experimental results and mathematical results was carried out, and the numerical analysis on the effects of operational parameters was studied. The results indicate that the derived mathematical model shows good quantitative relation between sulphuric acid recovery ratio and operational parameters, and the mathematical results agree with the experimental results well. The numerical analysis results indicate that it is appropriate to keep the ratio of water and feed flow rates, processing capacity per membrane area and recovery ratio of sulphuric acid to be 1, 20 L/(m2·d) and 0.7-0.8,respectively.
Author	唐建军周康根张启修
AuthorAffiliation	School of Construction and Environmental Engineering, Shenzhen Polytechnic, Shenzhen 518055, China School of Metallurgical Science and Engineering, Central South University, Changsha 410083, China
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Snippet	Sulfuric acid recovery from rare earth sulphate solutions by diffusion dialysis was studied. The mass transfer model of diffusion dialysis was established, the... Sulfuric acid recovery from rare earth sulphate solutions by diSusion dialysis was studied. The mass transfer model of diffusion dialysis was established, the... TG1; Sulfuric acid recovery from rare earth sulphate solutions by diffusion dialysis was studied. The mass transfer model of diffusion dialysis was...
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