Abstract
With an ever-increasing world population and the resulting increase in industrialization and agricultural practices, depletion of one of the world’s most important natural resources, water, is inevitable. Water reclamation and reuse is the key to protecting this natural resource. Water reclamation using smaller decentralized wastewater treatment plants, known as satellite water reuse plants (WRP), has become popular in the last decade. Reuse plants have stricter standards for effluent quality and require a smaller land footprint (i.e., real estate area). They also require additional treatment processes and advanced treatment technologies. This greatly increases the energy consumption of an already energy intensive process, accentuating even more the nexus between energy use and wastewater processing. With growing concerns over the use of nonrenewable energy sources and resulting greenhouse gas (GHG) emissions, WRPs are in need of energy evaluations. This paper contrasts the energy consumption of both conventional and advanced treatment processes in satellite WRPs. Results of this research provide a means for engineers and wastewater utilities to evaluate unit processes based on energy consumption as well as a foundation for making decisions regarding the sustainability of using advanced treatment technologies at reuse facilities.
Highlights
A connection—or nexus—exists between water and energy
Water reclamation has been practiced in the form of wastewater treatment plants (WWTP) using centralized treatment facilities located at low elevations to allow gravity collection of wastewater from metropolitan areas
This research explored the energy consumption of conventional and advanced treatment processes used in satellite water reuse plants (WRP)
Summary
A connection—or nexus—exists between water and energy. Population growth and increase in industrialization and agricultural practices place tremendous pressure on the world’s most important resources, water and fossil fuels [1,2,3,4]. Water reclamation and reuse is the key to conserving this natural resource, yet this process requires energy [9,10]. In the United States, applications of water reuse in order of descending water volumes are agricultural irrigation, industrial recycling and reuse, landscape irrigation, groundwater recharge, recreational and environmental uses, nonpotable urban uses, and potable reuse [11,12]. With few exceptions, water reuse is being practiced in a similar fashion as in the United States, including in
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