Development of mass and heat transfer coupled model of hollow fiber membrane for salt recovery from brine via osmotic membrane distillation

IF 6 3区 环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES
Sher Ahmad, Gabriela Vollet Marson, Waheed Ur Rehman, Mohammad Younas, Sarah Farrukh, Mashallah Rezakazemi
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引用次数: 6

Abstract

In this research work, a coupled heat and mass transfer model was developed for salt recovery from concentrated brine water through an osmotic membrane distillation (OMD) process in a hollow fiber membrane contactor (HFMC).The model was built based on the resistance-in-series concept for water transport across the hydrophobic membrane. The model was adopted to incorporate the effects of polarization layers such as temperature and concentration polarization, as well as viscosity changes during concentration.

The modeling equations were numerically simulated in MATLAB? and were successfully validated with experimental data from literature with a deviation within the range of 1–5%. The model was then applied to study the effects of key process parameters like feed concentrations, osmotic solution concentration, feed, and osmotic solution flow rates and feed temperature on the overall heat and mass transfer coefficient as well as on water transport flux to improve the process efficiency. The mass balance modeling was applied to calculate the membrane area based on the simulated mass transfer coefficient. Finally, a scale-up for the MD process for salt recovery on an industrial scale was proposed.

This study highlights the effect of key parameters for salt recovery from wastewater using the membrane distillation process. Further, the applicability of the OMD process for salt recovery on large scale was investigated. Sensitivity analysis was performed to identify the key parameters. From the results of this study, it is concluded that the OMD process can be promising in salt recovery from wastewater.

Abstract Image

渗透膜蒸馏法回收卤水盐中空纤维膜传质传热耦合模型的建立
在中空纤维膜接触器(HFMC)中建立了渗透膜蒸馏(OMD)工艺回收浓盐水盐的传热传质耦合模型。该模型是基于水在疏水膜上的串联阻力概念建立的。该模型考虑了温度、浓度极化等极化层的影响,以及浓缩过程中粘度的变化。在MATLAB中对模型方程进行了数值模拟。并与文献中的实验数据进行了验证,误差在1-5%范围内。应用该模型研究了进料浓度、渗透溶液浓度、进料、渗透溶液流速、进料温度等关键工艺参数对整体传热传质系数和输水通量的影响,以提高工艺效率。根据模拟的传质系数,采用质量平衡模型计算膜面积。最后,提出了在工业规模上扩大MD工艺回收盐的方案。研究了膜蒸馏法回收废水中盐的关键工艺参数的影响。进一步研究了OMD工艺在大规模采盐中的适用性。进行敏感性分析以确定关键参数。本研究结果表明,OMD工艺在废水盐回收中具有广阔的应用前景。
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来源期刊
Environmental Sciences Europe
Environmental Sciences Europe Environmental Science-Pollution
CiteScore
11.20
自引率
1.70%
发文量
110
审稿时长
13 weeks
期刊介绍: ESEU is an international journal, focusing primarily on Europe, with a broad scope covering all aspects of environmental sciences, including the main topic regulation. ESEU will discuss the entanglement between environmental sciences and regulation because, in recent years, there have been misunderstandings and even disagreement between stakeholders in these two areas. ESEU will help to improve the comprehension of issues between environmental sciences and regulation. ESEU will be an outlet from the German-speaking (DACH) countries to Europe and an inlet from Europe to the DACH countries regarding environmental sciences and regulation. Moreover, ESEU will facilitate the exchange of ideas and interaction between Europe and the DACH countries regarding environmental regulatory issues. Although Europe is at the center of ESEU, the journal will not exclude the rest of the world, because regulatory issues pertaining to environmental sciences can be fully seen only from a global perspective.
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