用于扩大铵回收规模的最小双极膜电池配置。

Minimal Bipolar Membrane Cell Configuration for Scaling Up Ammonium Recovery.

作者信息

Rodrigues Mariana, de Mattos Thiago T, Sleutels Tom, Ter Heijne Annemiek, Hamelers Hubertus V M, Buisman Cees J N, Kuntke Philipp

机构信息

Wetsus, European Centre of Excellence for Sustainable Water Technology, Oostergoweg 9, 8911MA Leeuwarden; P.O. Box 1113, Leeuwarden 8900CC, The Netherlands.

Environmental Technology, Wageningen University, Bornse Weilanden 9, 6708 Wageningen; P.O. Box 17, Wageningen 6700 AA, The Netherlands.

出版信息

ACS Sustain Chem Eng. 2020 Nov 30;8(47):17359-17367. doi: 10.1021/acssuschemeng.0c05043. Epub 2020 Nov 18.

DOI:10.1021/acssuschemeng.0c05043

PMID:33282569

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7709195/

Abstract

Electrochemical systems for total ammonium nitrogen (TAN) recovery are a promising alternative compared with conventional nitrogen-removal technologies. To make them competitive, we propose a new minimal stackable configuration using cell pairs with only bipolar membranes and cation-exchange membranes. The tested bipolar electrodialysis (BP-ED) stack included six cell pairs of feed and concentrate compartments. Critical operational parameters, such as current density and the ratio between applied current to nitrogen loading (load ratio), were varied to investigate the performance of the system using synthetic wastewater with a high nitrogen content as an influent (NH ≈ 1.75 g L). High TAN removal (>70%) was achieved for a load ratio higher than 1. At current densities of 150 A m and a load ratio of 1.2, a TAN transport rate of 1145.1±14.1 g m d and a TAN-removal efficiency of 80% were observed. As the TAN removal was almost constant at different current densities, the BP-ED stack performed at a high TAN transport rate (819.1 g m d) while consuming the lowest energy (18.3 kJ g ) at a load ratio of 1.2 and 100 A m. The TAN transport rate, TAN removal, and energy input achieved by the minimal BP-ED stack demonstrated a promising new cell configuration for upscaling.

摘要

与传统的脱氮技术相比，用于回收总铵氮（TAN）的电化学系统是一种很有前景的替代方案。为了使其具有竞争力，我们提出了一种新的最小可堆叠配置，该配置使用仅含双极膜和阳离子交换膜的电池对。测试的双极电渗析（BP-ED）堆叠包括六个进料室和浓缩室的电池对。改变关键操作参数，如电流密度和施加电流与氮负荷的比率（负荷率），以研究该系统使用高氮含量的合成废水作为进水（NH₄⁺≈1.75 g/L）时的性能。当负荷率高于1时，实现了较高的TAN去除率（>70%）。在电流密度为150 A/m²和负荷率为1.2时，观察到TAN传输速率为1145.1±14.1 g/m²·d，TAN去除效率为80%。由于在不同电流密度下TAN去除率几乎恒定，BP-ED堆叠在负荷率为1.2和电流密度为100 A/m²时，以较高的TAN传输速率（819.1 g/m²·d）运行，同时消耗最低的能量（18.3 kJ/g）。最小BP-ED堆叠实现的TAN传输速率、TAN去除率和能量输入表明了一种有前景的新型电池配置，可用于扩大规模。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5d70/7709195/6e80000953ba/sc0c05043_0002.jpg

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用于扩大铵回收规模的最小双极膜电池配置。

Minimal Bipolar Membrane Cell Configuration for Scaling Up Ammonium Recovery.

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