Comparative Analysis of the Energy Consumption of Different Wastewater Treatment Plants

Soares, Renan Barroso

doi:10.11648/j.ijaaa.20170306.11

Cited by 18 publications

(8 citation statements)

References 26 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…However, the aeration system is the most energy-consuming part of process, which consumes 0.18 to 0.80 kW·h/m 3 , accounting for approximately 50.0–60.0% of the energy expenditure of wastewater treatment plants (Figure ). , Moreover, the aeration process produces excess waste gas, the disturbed water body produces a large amount of water wave energy, and the noise of the blower room produces vibrational energy. If these potential energies can be effectively used to improve the efficiency of wastewater treatment, the energy consumption of secondary treatments will be mitigated.…”

Section: Energy Harvesting and Application During Wastewater Treatmentmentioning

confidence: 99%

Improving Wastewater Treatment by Triboelectric-Photo/Electric Coupling Effect

et al. 2022

View full text Add to dashboard Cite

The ability to meet higher effluent quality requirements and the reduction of energy consumption are the biggest challenges in wastewater treatment worldwide. A large proportion of the energy generated during wastewater treatment processes is neglected and lost in traditional wastewater treatment plants. As a type of energy harvesting system, triboelectric nanogenerators (TENGs) can extensively harvest the microscale energies generated from wastewater treatment procedures and auxiliary devices. This harvested energy can be utilized to improve the removal efficiency of pollutants through photo/electric catalysis, which has considerable potential application value in wastewater treatment plants. This paper gives an overall review of the generated potential energies (e.g., water wave energy, wind energy, and acoustic energy) that can be harvested at various stages of the wastewater treatment process and introduces the application of TENG devices for the collection of these neglected energies during wastewater treatment. Furthermore, the mechanisms and catalytic performances of TENGs coupled with photo/electric catalysis (e.g., electrocatalysis, photoelectric catalysis) are discussed to realize higher pollutant removal efficiencies and lower energy consumption. Then, a thorough, detailed investigation of TENG devices, electrode materials, and their coupled applications is summarized. Finally, the intimate coupling of self-powered photoelectric catalysis and biodegradation is proposed to further improve removal efficiencies in wastewater treatment. This concept is conducive to improving knowledge about the underlying mechanisms and extending applications of TENGs in wastewater treatment to better solve the problems of energy demand in the future.

show abstract

Section: Energy Harvesting and Application During Wastewater Treatmentmentioning

confidence: 99%

Improving Wastewater Treatment by Triboelectric-Photo/Electric Coupling Effect

et al. 2022

View full text Add to dashboard Cite

show abstract

“…All these treatment stages involve significant energy consumption, primarily determined by the pollutant content of the water, the processing temperature, and the purification technology [20,[41][42][43][44] that is implemented. The values reported in the literature range from 2.8 kWh/m 3 [45] for wastewater treatment plants up to 1000 m 3 /day, to 0.240 kWh/m 3 in large wastewater treatment plants, that are usually equipped with digesters for biogas production [46,47].…”

Section: Introductionmentioning

confidence: 99%

Saving Energy in Biological Wastewater Treatment by Using Extremely Low-Frequency Electric Field—Pilot-Scale Study

et al. 2023

View full text Add to dashboard Cite

The results of a pilot-scale study on the influence of electric field use for stimulating the active sludge in the biological purification tank of a small capacity wastewater treatment plant (up to 600 m3/day) are presented. Through specific comparative chemical tests (DO, COD, N-NH4, and Pt) it was found that, by applying a sinusoidal electric field of 5 Vrms/m at 49.9 Hz on the active sludge suspension, the overall pollutant denitrification process speed is doubled compared with the reference case when no stimulation is used. Also, under identical operating conditions, the residual pollutant content of the biological treatment tank outlet water is reduced approximately three times for COD and approximately two times for N-NH4 and Pt compared to the reference tank. These findings lead to the conclusion that, by stimulating the active sludge microbial activity of the wastewater treatment plants by a sinusoidal electric field of 5 Vrms/m at 49.9 Hz, the time of the biological purification treatment can be reduced by approx. 50%. This leads to a corresponding decrease in energy consumption, which usually represents more than 30% of a wastewater treatment plant’s specific electricity consumption.

show abstract

“…To solve this, wastewater treatment technologies have been developed with lower operating costs or the ability to obtain subproducts from wastewater that can generate a profit. Some of these are designed to harness the chemical energy contained in wastewater, as it can be between 6 and 13 times greater than that required for conventional wastewater treatment (Barroso-Soares et al 2017;Beegle & Borole 2018).…”

Section: Introductionmentioning

confidence: 99%

Bibliometric analysis of artificial intelligence algorithms used for microbial fuel cell research

Coy-Aceves

Corona-Vasquez

2022

Water Practice and Technology

View full text Add to dashboard Cite

Research regarding microbial fuel cells has been stimulated to reduce the operating costs and energy consumption of conventional wastewater treatment, and increase its profitability. However, these devices are challenging to study due to their complexity and sensitivity to both internal and external factors. Artificial intelligence (AI) has been used to analyze microbial fuel cells as an effective alternative to the use of mathematical models, which are still in development. In this study, the main goals were to perform the first bibliometric analysis of AI applied to microbial fuel cell research and to find the most popular algorithms used to date. Using the Web of Science Database, a total of 102 articles published between 1999 and 2022 were retrieved. The cumulative number of articles has greatly increased over the last 10 years. About 55% were contributed by researchers from China and USA, leading among 20 countries. Some 50 algorithms were used, with Principal Component Analysis and Feed-Forward Neural Networks being the most popular used to study and optimize microbial fuel cells.

show abstract

Comparative Analysis of the Energy Consumption of Different Wastewater Treatment Plants

Cited by 18 publications

References 26 publications

Improving Wastewater Treatment by Triboelectric-Photo/Electric Coupling Effect

Improving Wastewater Treatment by Triboelectric-Photo/Electric Coupling Effect

Saving Energy in Biological Wastewater Treatment by Using Extremely Low-Frequency Electric Field—Pilot-Scale Study

Bibliometric analysis of artificial intelligence algorithms used for microbial fuel cell research

Contact Info

Product

Resources

About