화학공학소재연구정보센터
로그인 로그아웃 연락처 사이트맵
Korean Journal of Chemical Engineering, Vol.31, No.10, 1720-1731, October, 2014
DOI10.1007/s11814-014-0202-4  Export Citation
Recovery of acids from dilute streams : A review of process technologies
Vivek Digambar Talnikar1, 2, and Yogesh Shankar Mahajan2, †
  • 1Chemical Engineering Department, Pravara Rural Engineering College, Loni, Ahmednagar, Maharashtra 413 736, India
  • 2Chemical Engineering Department, Dr. Babasaheb Ambedkar Technological University, Lonere, Raigad, Maharashtra 402 103, India
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Chemical process industries convert raw materials into useful products. Acids, among other chemicals, are used in many industries as reactants, solvents and also as catalysts in a few instances as well. Resulting streams are dilute, from which the acids must be recovered. For recovery, many technologies can be used by which acids can be regained as such or can be converted into other value-added products like esters. Membrane processes and biological processes are being researched academically and practiced industrially. These have their own advantages and disadvantages in view of conversion, energy consumption etc. These are not always advantageous and hence an alternate process technology is necessary like reactive separation (RS). RS is advantageous especially when the acid is to be converted to other useful products by reaction, due to additional advantages or because no other technology is well suited or due to cost considerations alone. Conventional process technologies use the reactor configuration followed by the subsequent separation sequence. This approach can sometimes suffer from lesser conversion, difficulties in separation etc. To overcome these problems, RS has an edge over other processes in terms of the recovery of the useful compounds. Reactive distillation (RD), reactive extraction (RE) and reactive chromatography (RC) are the separation technologies that can be useful for acid recovery in an economically feasible way. This review covers the various processes of acid recovery along with the recent work in the field of reactive separations.
Keywords:Recovery;Reactive Distillation;Reactive Chromatography;Membrane Processes;Separation
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