Abstract
The efficacy of an uncoupled electro-peroxone (E-peroxone) prototype reactor system for the treatment of synthetic graywater is determined. The two-stage E-peroxone process integrates ozonation with the in situ production of hydrogen peroxide (H2O2) in a first stage reactor before ozone (O3) is converted via the peroxone reaction to a hydroxyl radical (•OH). The two-stage prototype reactor system allows for the generation of H2O2 via cathodic oxygen reduction in the first-stage reactor before mixing with O3 in the second-stage reactor. This approach prevents the degradation of polytetrafluoroethylene (PTFE) coated carbon cathodes by •OH that takes place in a single well-mixed reactor that combines electrochemical peroxide generation with O3. The dosage of H2O2 into the second-stage reactor is optimized to enhance graywater treatment. Under these conditions, the uncoupled E-peroxone system is capable of treating synthetic graywater with an initial chemical oxygen demand (COD0) of 358 mg O2/L, a total organic carbon (TOC0) of 96.9 mg/L, a biochemical oxygen demand (BOD0) of 162 mg O2/L, and a turbidity of 11.2 NTU. The two-stage electro-peroxone system can reduce the initial COD0 by 89%, the TOC0 by 91%, BOD0 by 86%, and the turbidity by 95% after 90 min of treatment. At this performance level, the reactor effluent is acceptable for discharge and for use in nonpotable applications such as toilet-water flushing. A portion of the effluent is recycled back into the first-stage reactor to minimize water consumption. Recycling can be repeated consecutively for four or more cycles, although the time required to achieve the desired H2O2 concentration increased slightly from one cycle to another. The two-stage E-peroxone system is shown to be potentially useful for onsite or decentralized graywater treatment suitable for arid water-sensitive areas.
Highlights
Climate change has increased water scarcity in many parts of the world, leading to the need for development of new practices for water supply management.[1,2] Onsite water reuse is one of the key opportunities to increase water supply without a detrimental impact on the environment.[3]
The average percent Chemical Oxygen Demand (COD) removal was 94% in solution and 89% when adjusted for dilution
In addition to observing COD removal, the Total Organic Carbon (TOC) of the solution was degraded by 92% (86% adjusted for dilution) during the E-peroxone process with starting TOC concentrations of 96.95 ± 9.84 mg/L and final TOC concentrations of 7.29 ± 7.86 mg/L
Summary
Climate change has increased water scarcity in many parts of the world, leading to the need for development of new practices for water supply management.[1,2] Onsite water reuse is one of the key opportunities to increase water supply without a detrimental impact on the environment.[3]. The level of desired treatment can range from treating graywater for reuse in low contact systems (e.g., as flushing water) or as a first-step treatment to convert processed water into potable water.[1,2]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
