不同咸水盐度谱条件下反渗透试验设备的实验性能分析

Q1 Chemical Engineering
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引用次数: 0

摘要

反渗透海水淡化工艺的主要障碍是高能耗和长期连续性。温度和压力对能源使用的影响最大也最显著。当前研究的主要目标是确定膜脱盐装置与压力和温度相关的最佳运行参数。为了确定膜装置的理想运行设置,研究了压力和温度变化对其性能的影响。这两个因素与各种运行情况下每立方米的能耗密切相关。目前的工作是在埃及国家水研究中心为海水淡化领域的能力建设和未来研究而建立的研究实验室中进行的。该实验室是埃及第一个多功能海水淡化研究站,用于海水、苦咸水和相关水处理领域。该设备配备了在线仪器和数据采集系统,以及 13 个传感器,用于测量对膜性能和海水淡化过程有经济影响的大多数物理参数。对这些参数,尤其是压力和温度,进行了测量、评估和分析。根据这项研究的结果,进料盐度和进料压力都有重大影响。在 13 巴压力下,最大盐排斥率为 98.8%。当进料压力从 5 巴增加到 13 巴时,渗透盐度降低了 73.3%。此外,对盐度为 1000 ppm 的水施加 13 巴的进水压力,可获得 12 ppm 的最佳水质。进料压力、盐水含盐量和膜水回收率之间似乎呈近似线性正相关关系。更重要的是,我们发现进料压力、盐度和水回收率都是水渗透性的常数。研究人员开发出了实验室最佳回收率的最大压力(范围从 15.6 到 10.8)和温度(范围从 21 到 35)的原型。此外,所开发的原型还包括相应的渗透 TDS 和每个最佳点的比能量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Experimental performance analysis for reverse osmosis pilot plant subjected to different brackish salinity spectrum
The main obstacles to reverse osmosis desalination processes are high energy intensity and long-term continuity. Temperature and pressure have the greatest and most significant effects on energy use. The main objectives of the current study are to determine the pressure and temperature-dependent optimal operating parameters for a membrane desalination unit. To determine the ideal operating settings for a membrane unit, the impact of changing pressure and temperature on its performance was investigated. These two elements are closely connected to the energy consumption per cubic meter under various operating situations. The present work is experimentally carried out in a research laboratory for capacity building and future research studies in the desalination field established in the National Center of Water Research – Egypt. This laboratory is Egypt’s first multi-functional Desalination Research Station for seawater, brackish water, and related water treatment areas. The plant is equipped with online instrumentation and Data Acquisition System and 13 sensors for most physical parameters which economically affect membrane performance and desalination processes. These parameters, particularly pressure and temperature, are measured, evaluated and analyzed. According to the findings in this study, feed salinity and feed pressure both have significant impacts.
At 13 bar pressure, the maximum salt rejection was 98.8%. When feed pressure is increased from 5 to 13 bars, there is a 73.3% decrease in permeate salinity. Additionally, applying a 13 bar feed pressure to water with a salinity of 1000 ppm results in the best water quality of 12 ppm. The relationship between feed pressure, brine salinity, and membrane water recovery appeared to be approximately linear and positive. More crucially, it was discovered that feed pressure, salinity, and water recovery are all constants for water permeability. A prototype for the maximum pressure (ranges from 15.6 to 10.8) and temperature (ranges from 21 to 35) at which the optimal recovery of the laboratory occurred was developed. Moreover, the developed prototype includes the corresponding permeate TDS and a specific energy for each optimal point.
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来源期刊
Journal of King Saud University, Engineering Sciences
Journal of King Saud University, Engineering Sciences Chemical Engineering-Fluid Flow and Transfer Processes
CiteScore
12.10
自引率
0.00%
发文量
87
审稿时长
63 days
期刊介绍: Journal of King Saud University - Engineering Sciences (JKSUES) is a peer-reviewed journal published quarterly. It is hosted and published by Elsevier B.V. on behalf of King Saud University. JKSUES is devoted to a wide range of sub-fields in the Engineering Sciences and JKSUES welcome articles of interdisciplinary nature.
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