Using Water and Wastewater Decentralization to Enhance the Resiliency and Sustainability of Cities

Manel Garrido Baserba, David Sedlak, Irene Barnosell, Maria Molinos-Senante, Oliver Schraa, Diego Rosso, Marta Verdaguer, Manel Poch
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Abstract

Abstract The imperative to make energy and resource consumption more sustainable is prompting a critical reconsideration of all human endeavors. Within urban water management, the drive to enhance sustainability is grounded in the recognition that water services consume a substantial amount of energy and that wastewater contains valuable resources, including water, heat, organic matter, and essential plant nutrients. To make urban water systems more sustainable, a paradigm shift is needed. Among the proposed strategies, source separation coupled with anaerobic co-digestion appears to be an effective means of recovering energy, water, and nutrients. Because existing centralized infrastructure that serves tens to hundreds of thousands of people is difficult to alter, and the technologies needed to realize this strategy are difficult to implement in single-family homes, we consider the scale of a city block. Using a quantitative model of unit processes that simulate energy, water, and nutrient flows, we consider the technical and economic feasibility of a representative decentralized system, as well as its environmental impacts. To realize potential synergies associated with on-site use of the recovered resources, we complement the decentralized water system with vertical farming, photovoltaic energy generation, and rainwater harvesting. Our analysis suggests that decentralized water systems can serve as a cornerstone of efforts to enhance resource efficiency and improve the resilience of cities.
利用水和废水的分散化来增强城市的弹性和可持续性
使能源和资源消耗更具可持续性的必要性促使人们对所有人类活动进行批判性的重新思考。在城市水管理中,提高可持续性的动力是基于这样一种认识,即供水服务消耗大量能源,废水含有宝贵的资源,包括水、热、有机物和必需的植物营养物质。为了使城市供水系统更具可持续性,需要转变思维模式。在提出的策略中,源分离与厌氧共消化相结合似乎是回收能量、水和营养物质的有效手段。由于现有的集中式基础设施为数万到数十万人服务,很难改变,而且实现这一战略所需的技术很难在单户住宅中实施,我们考虑了城市街区的规模。利用模拟能量、水和养分流动的单元过程的定量模型,我们考虑了具有代表性的分散系统的技术和经济可行性,以及它对环境的影响。为了实现与现场回收资源利用相关的潜在协同效应,我们用垂直农业、光伏发电和雨水收集来补充分散的水系统。我们的分析表明,分散的供水系统可以作为提高资源效率和改善城市弹性的基石。
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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