Abstract
Drinking water treatment, wastewater treatment, and water distribution are energy-intensive processes. The goal of this study was to design the unit processes of an existing drinking water treatment plant (DWTP), evaluate the associated energy consumption, and then offset it using solar photovoltaics (PVs) to reduce carbon emissions. The selected DWTP, situated in the southwestern United States, utilizes coagulation, flocculation, sedimentation, filtration, and chlorination to treat 3.94 m3 of local river water per second. Based on the energy consumption determined for each unit process (validated using the plant’s data) and the plant’s available landholding, the DWTP was sized for solar PV (as a modeling study) using the system advisor model. Total operational energy consumption was estimated to be 56.3 MWh day−1 for the DWTP including water distribution pumps, whereas energy consumption for the DWTP excluding water distribution pumps was 2661 kWh day−1. The results showed that the largest consumers of energy—after the water distribution pumps (158.1 Wh m−3)—were the processes of coagulation (1.95 Wh m−3) and flocculation (1.93 Wh m−3). A 500 kW PV system was found to be sufficient to offset the energy consumption of the water treatment only operations, for a net present value of $0.24 million. The net reduction in carbon emissions due to the PV-based design was found to be 450 and 240 metric tons CO2-eq year−1 with and without battery storage, respectively. This methodology can be applied to other existing DWTPs for design and assessment of energy consumption and use of renewables.
Highlights
Energy conservation and sustainability is one of the pressing issues being faced by the water industry today as drinking water treatment and wastewater treatment are highly energy-intensive processes [1]
The techno-economic evaluation was only conducted for scenario S-2, i.e., to offset the energy consumption of the drinking water treatment plant (DWTP) excluding distribution pumps
For the same PV system, if battery storage is not provided, a debt % of 85% or less, loan term of 18 years or less, discount rate of 4% or less, interest rate of 6% or higher, and inflation rate of zero or less rendered a negative net present value (NPV) and higher levelized cost of electricity (LCOE) values
Summary
Energy conservation and sustainability is one of the pressing issues being faced by the water industry today as drinking water treatment and wastewater treatment are highly energy-intensive processes [1]. These processes account for about 2% of the United States’ total energy use, resulting in the emissions of about 45 million tons of greenhouse gases (GHG) [2]. The objective of this study was evaluation of the energy consumption of a large-scale drinking water treatment plant (DWTP), associated carbon emissions, and offsetting that energy consumption by utilizing photovoltaics (PVs). Energy use for water treatment depends on various factors such as raw water quality, water source, age of water delivery system, conveyance distance, water storage
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