Self-regulating behavior of hybrid membrane systems as demonstrated in an element-scale forward osmosis-reverse osmosis hybrid system

IF 4.7 Q1 ENGINEERING, CHEMICAL

Journal of Membrane Science Letters Pub Date : 2025-06-18 DOI:10.1016/j.memlet.2025.100102

Noah Ferguson, Maqsud Chowdhury, Colin Fitzsimonds, Nicole Beauregard, Mayur Ostwal, Marianne Pemberton, Edward Wazer, Caylin Cyr, Ranjan Srivastava, Jeffrey R. McCutcheon

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Abstract

Hybrid membrane systems can be difficult to design due to the requisite flow rate matching between up- and downstream unit operations. In this work, we use a forward osmosis-reverse osmosis (FO-RO) hybrid system to demonstrate how some membrane systems can exhibit self-regulating behavior due to osmotic coupling. This can reduce the need for complex control systems for flow balancing. We show this behavior using a module-scale test bed that can mimic the behavior of larger scale operations. The system shows permeate flow rate near-convergence between the FO and RO modules after startup or when perturbed by a change in RO module pressure. The behavior of this hybrid system demonstrates that some membrane operations can exploit osmotic interdependence, rather than expensive control systems, to achieve steady state operation.

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元尺度正渗透-反渗透混合膜系统的自调节行为

由于上下游装置操作之间需要流量匹配，混合膜系统可能很难设计。在这项工作中，我们使用正向渗透-反渗透（FO-RO）混合系统来演示一些膜系统如何由于渗透耦合而表现出自我调节行为。这可以减少对流量平衡的复杂控制系统的需求。我们使用一个模块规模的测试平台来展示这种行为，该平台可以模拟更大规模操作的行为。系统显示，在启动后或受到RO模块压力变化的干扰时，FO和RO模块之间的渗透流量接近收敛。这种混合系统的行为表明，一些膜操作可以利用渗透相互依赖，而不是昂贵的控制系统，以实现稳态操作。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Membrane Science Letters

CiteScore

4.00

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0.00%

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