Horizontal Subsurface Flow Gravel Bed Constructed Wetland with Phragmites Karka in Central India

Billore, S. K.; Singh, Naresh Pal; Sharma, J. K.; Dass, Preeti; Nelson, R. M.

doi:10.2166/wst.1999.0158

Cited by 37 publications

(25 citation statements)

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“…The removal mechanisms of phosphorus from wastewater in constructed wetlands were mainly through substrate adsorption, iron exchange, and plant uptake (Billore et al 1999). During the whole experiment, the TP removal efficiency remained relatively steady, and mean TP removal efficiencies (68.01±17.45 %) was similar to the results of Chung et al (2008), Wu et al (2011) and Gikas and Tsihrintzis (2012), but lower than others (Xiong et al 2011;Dong et al 2011;Wang et al 2011).…”

Section: Evaluation Of Treatment Performance For Pollutantsmentioning

confidence: 60%

Treatment performance and microorganism community structure of integrated vertical-flow constructed wetland plots for domestic wastewater

Chang

Dai

et al. 2012

Environ Sci Pollut Res

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In order to investigate the treatment performance and microorganism mechanism of IVCW for domestic wastewater in central of China, two parallel pilot-scale IVCW systems were built to evaluate purification efficiencies, microbial community structure and enzyme activities. The results showed that mean removal efficiencies were 81.03 % for COD, 51.66 % for total nitrogen (TN), 42.50 % for NH 4 + -N, and 68.01 % for TP. Significant positive correlations between nitrate reductase activities and TN and NH 4 + -N removal efficiencies, along with a significant correlation between substrate enzyme activity and operation time, were observed. Redundancy analysis demonstrated gram-negative bacteria were mainly responsible for urease and phosphatase activities, and also played a major role in dehydrogenase and nitrate reductase activities. Meanwhile, anaerobic bacteria, gram-negative bacteria, and saturated FA groups, gram-positive bacteria exhibited good correlations with the removal of COD (p00.388), N (p0 0.236), and TP (p00.074), respectively. The IVCW system can be used to treat domestic wastewater effectively.

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Section: Evaluation Of Treatment Performance For Pollutantsmentioning

confidence: 60%

Treatment performance and microorganism community structure of integrated vertical-flow constructed wetland plots for domestic wastewater

Chang

Dai

et al. 2012

Environ Sci Pollut Res

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“…It has been observed by many researchers that plug flow conditions are seldom found in the constructed wetland treatment systems. The actual flow condition that occurs in practice can be more accurately modelled as first order kinetics and number of complex mix reactors in series [1][2][3][4][5][6].…”

Section: Flowmentioning

confidence: 99%

“…This new developing technology may offer a low cost and low maintenance option for domestic wastewater treatment, which is especially suitable for developing countries [2][3][4].…”

mentioning

confidence: 99%

Simulation of constructed wetland performance using the advection diffusion equation

Popov¹,

Ahmed²,

Qureshi³

2008

WIT Transactions on Ecology and the Environment

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The advection diffusion equation with variable coefficients was used to predict the performance of a subsurface constructed wetland (SSCW) treatment plant. The effect of evapo-transpiration on the velocity of flow and change of rate of biodegradation kinetics with the length of flow was considered. The differential equation was solved using the Frobenius method. The model was validated on experimental results from a pilot plant in Indian climatic conditions. The data used in this work were obtained from various hydraulic and BOD loadings. Records of biochemical oxygen demand (BOD) concentrations at inlet, outlet and intermediate levels through various stages of the treatment process over eighteen months were used for calibration of the model. The results of the model show that it is an efficient and a robust tool for prediction of the waste-water treatment performance of a constructed wetland.

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“…The initial sampling started after eight months i.e. April -2002 giving sufficient time for full growth of reeds since wetlands typically require a few months for vegetation and bio-film establishment according to [7]. Sizing of the wetland units was done by using basic relationship for plug flow reactor for the BOD loading as recommended by [8]:…”

Section: Constructed Wetland Pilot Plant and Experimental Set Upmentioning

confidence: 99%

Performance prediction of a constructed wetland wastewater treatment plant

Tomenko¹,

Ahmed²,

Popov³

2006

WIT Transactions on Ecology and the Environment, Vol 92

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Abstractperformance of a constructed wetland wastewater treatment plant (CWWTP). The model assesses the Biochemical Oxygen Demand (BOD) concentration at outlet of a treatment plant. Training of ANN models was based on experimental results of a pilot plant study in India. The data used in this work were obtained under various hydraulic and BOD loading. Regular records of BOD were made at inlet, and outlet levels through various stages of the treatment process for over 18 months. The ANN-based models were found to provide an efficient and a robust tool in predicting CWWTP performance. Keywords: neural networks, constructed wetland, model studies, prediction, optimization, biochemical oxygen demand. IntroductionThe proper operation and management of constructed wetland wastewater treatment plants (CWWTP) is receiving attention because of the rising concern about environmental issues and growing importance of sustainable and natural wastewater treatment techniques. Improper design and operation of a CWWTP may cause serious environmental and public health implications, as its effluent may contaminate receiving water body, causing severe aquatic pollution and spread various water born diseases. For proper design and assessment of quality of non-conventional wastewater treatment and thereafter to conserve the receiving water bodies, reliable prediction of effluent from Constructed Wetland (CW) is essential. A better control can be achieved by developing a mathematical tool for predicting the plant performance based on past observations of certain key parameters. However, modeling a CWWT is a difficult task due to the complexity of the treatment processes. The complex physical, biological and chemical processes involved in constructed wetland treatment process exhibit non-linear behaviors, which are difficult to describe by linear mathematical models. This paper presents predictive models based on the concept of neural networks (NN).Artificial intelligence concepts have been successfully used in a range of engineering, environmental, and financial problems [1,2]. The NN-based model that was applied to a pilot plant study of CW in India have performed consistently well in the face of varying accuracy and size of input data. Using these models, the planner and decision maker can easily make assessment of the expected plant effluent. Constructed wetland pilot plant and experimental set upWetlands are considered as low-cost alternatives for treating municipal, industrial, and agricultural effluents. Constructed wetlands (CW) are preferred because of low maintenance, shock loading absorbance capacity and less energy consumption [3]. They may be classified as surface flow marshes, vegetated subsurface flow beds, submerged aquatic beds, and floating leaved aquatics [4] This new developing technology may offer a low cost and low maintenance alternative for treatment of domestic wastewater which is especially suitable for developing countries [5,6].The scheme of the units designed in New Delhi is presented in Fig. 1. Wastew...

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Horizontal Subsurface Flow Gravel Bed Constructed Wetland with Phragmites Karka in Central India

Cited by 37 publications

References 0 publications

Treatment performance and microorganism community structure of integrated vertical-flow constructed wetland plots for domestic wastewater

Treatment performance and microorganism community structure of integrated vertical-flow constructed wetland plots for domestic wastewater

Simulation of constructed wetland performance using the advection diffusion equation

Performance prediction of a constructed wetland wastewater treatment plant

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