Integration of Hydraulic Wind Turbines for Seawater Reverse Osmosis Desalination

A. Jarquin-Laguna, F. Greco
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引用次数: 3

Abstract

The integration of renewable energy sources to power seawater desalination is crucial to mitigate CO2 emissions and to face the increasing challenges that are stressing fresh water resources depletion. In particular wind energy is one of the most cost-effective forms of renewable energy with a high potential to reduce the seawater desalination”s environmental impact. While most applications are aimed at using conventional wind technologies to produce the electricity required by the desalination processes, wind turbines with hydraulic transmission can bring new opportunities to avoid the multiple energy conversion steps and make fresh water production from wind energy more simple and cost-effective. This paper elaborates on two potential configurations, numerical modelling and possible control strategies which are able to directly combine a horizontal axis wind turbine rotor, a hydraulic transmission and a seawater reverse osmosis (SWRO) desalination unit. The integration of an ideal pressure exchanger as energy recovery devices (ERD) to increase the operating efficiency of the SWRO unit is analysed. Results are shown for the most relevant operating conditions of the integrated system in terms of wind speeds, pressures, brine salinity and fresh water productions. Intermediate results are also shown for the dynamic analysis and simulation of the wind powered direct-driven SWRO system subject to turbulent wind speed conditions.
用于海水反渗透淡化的水力风力涡轮机集成
整合可再生能源为海水淡化提供动力,对于减少二氧化碳排放和面对日益严峻的挑战至关重要,这些挑战正在加剧淡水资源的枯竭。特别是风能是最具成本效益的可再生能源之一,在减少海水淡化对环境的影响方面具有很大的潜力。虽然大多数应用旨在使用传统的风能技术来产生海水淡化过程所需的电力,但液压传动的风力涡轮机可以带来新的机会,避免多个能量转换步骤,使风能生产淡水更加简单和经济。本文详细阐述了两种可能的配置、数值建模和可能的控制策略,这些配置可以直接结合水平轴风力涡轮机转子、液压传动和海水反渗透(SWRO)淡化装置。分析了将理想压力交换器集成为能量回收装置以提高SWRO机组的运行效率。结果显示了综合系统在风速、压力、盐水盐度和淡水产量方面最相关的操作条件。在紊流风速条件下,风力直驱SWRO系统的动力学分析和仿真也得到了中间结果。
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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