D. Yu. Khanukaeva, P. A. Aleksandrov, A. N. Filippov
{"title":"溶液膜分离中不稳定性的影响","authors":"D. Yu. Khanukaeva, P. A. Aleksandrov, A. N. Filippov","doi":"10.1134/S2517751624600468","DOIUrl":null,"url":null,"abstract":"<p>Nonstationary diffusion problems are considered within the framework of the homogeneous membrane model for a closed membrane cell and a cross-flow cell with a tangential flow of feed solution and permeate in the absence and presence of convection (as applied to dialysis and any pressure-driven membrane process for separating solutions of neutral substances). Characteristic features of a steady state establishment in each of the three cases considered have been revealed, and simple algebraic formulae have been obtained for calculating the time it takes the process to reach a steady state depending on each of the problem parameters. It has been found that membrane characteristics, such as the diffusion coefficient of solute molecules in the membrane and the magnitude of the potential barrier for diffusing components, have a lesser effect on the process stabilization rate than the thickness of the diffusion layer or the flow regime in the case of convective diffusion. It is the additional surface forces, as well as stirring, that make a decisive contribution to the unsteady-state period of the convective diffusion regime. It has been established that purely diffusion processes (for example, dialysis) are not only slower than convective-diffusion processes, but also reach a steady state more slowly. At the same time, it was revealed that the time to reach a steady state in each process is significantly shorter than the characteristic time of the process itself. This fact provides additional justification for the validity of stationary formulations of the problems studied.</p>","PeriodicalId":700,"journal":{"name":"Membranes and Membrane Technologies","volume":"6 4","pages":"213 - 224"},"PeriodicalIF":2.0000,"publicationDate":"2024-12-12","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Effects of Unsteadiness in Membrane Separation of Solutions\",\"authors\":\"D. Yu. Khanukaeva, P. A. Aleksandrov, A. N. Filippov\",\"doi\":\"10.1134/S2517751624600468\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Nonstationary diffusion problems are considered within the framework of the homogeneous membrane model for a closed membrane cell and a cross-flow cell with a tangential flow of feed solution and permeate in the absence and presence of convection (as applied to dialysis and any pressure-driven membrane process for separating solutions of neutral substances). Characteristic features of a steady state establishment in each of the three cases considered have been revealed, and simple algebraic formulae have been obtained for calculating the time it takes the process to reach a steady state depending on each of the problem parameters. It has been found that membrane characteristics, such as the diffusion coefficient of solute molecules in the membrane and the magnitude of the potential barrier for diffusing components, have a lesser effect on the process stabilization rate than the thickness of the diffusion layer or the flow regime in the case of convective diffusion. It is the additional surface forces, as well as stirring, that make a decisive contribution to the unsteady-state period of the convective diffusion regime. It has been established that purely diffusion processes (for example, dialysis) are not only slower than convective-diffusion processes, but also reach a steady state more slowly. At the same time, it was revealed that the time to reach a steady state in each process is significantly shorter than the characteristic time of the process itself. 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Effects of Unsteadiness in Membrane Separation of Solutions
Nonstationary diffusion problems are considered within the framework of the homogeneous membrane model for a closed membrane cell and a cross-flow cell with a tangential flow of feed solution and permeate in the absence and presence of convection (as applied to dialysis and any pressure-driven membrane process for separating solutions of neutral substances). Characteristic features of a steady state establishment in each of the three cases considered have been revealed, and simple algebraic formulae have been obtained for calculating the time it takes the process to reach a steady state depending on each of the problem parameters. It has been found that membrane characteristics, such as the diffusion coefficient of solute molecules in the membrane and the magnitude of the potential barrier for diffusing components, have a lesser effect on the process stabilization rate than the thickness of the diffusion layer or the flow regime in the case of convective diffusion. It is the additional surface forces, as well as stirring, that make a decisive contribution to the unsteady-state period of the convective diffusion regime. It has been established that purely diffusion processes (for example, dialysis) are not only slower than convective-diffusion processes, but also reach a steady state more slowly. At the same time, it was revealed that the time to reach a steady state in each process is significantly shorter than the characteristic time of the process itself. This fact provides additional justification for the validity of stationary formulations of the problems studied.
期刊介绍:
The journal Membranes and Membrane Technologies publishes original research articles and reviews devoted to scientific research and technological advancements in the field of membranes and membrane technologies, including the following main topics:novel membrane materials and creation of highly efficient polymeric and inorganic membranes;hybrid membranes, nanocomposites, and nanostructured membranes;aqueous and nonaqueous filtration processes (micro-, ultra-, and nanofiltration; reverse osmosis);gas separation;electromembrane processes and fuel cells;membrane pervaporation and membrane distillation;membrane catalysis and membrane reactors;water desalination and wastewater treatment;hybrid membrane processes;membrane sensors;membrane extraction and membrane emulsification;mathematical simulation of porous structures and membrane separation processes;membrane characterization;membrane technologies in industry (energy, mineral extraction, pharmaceutics and medicine, chemistry and petroleum chemistry, food industry, and others);membranes and protection of environment (“green chemistry”).The journal has been published in Russian already for several years, English translations of the content used to be integrated in the journal Petroleum Chemistry. This journal is a split off with additional topics.
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