Volume 7 Issue 3
May  2017
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Article Navigation >  Journal of Environmental Engineering Technology  > 2017  >  7(3): 332-339
ZHANG Hengliang, ZHU Tiequn, WANG Haiyan, CHU Zhaosheng, HANG Qianyu, HOU Zeying. Influence of Phragmites australis carbon dosage on enhanced nitrogen removal start-up of pilot-scale surface flow constructed wetland[J]. Journal of Environmental Engineering Technology, 2017, 7(3): 332-339. doi: 10.3969/j.issn.1674-991X.2017.03.047
Citation: ZHANG Hengliang, ZHU Tiequn, WANG Haiyan, CHU Zhaosheng, HANG Qianyu, HOU Zeying. Influence of Phragmites australis carbon dosage on enhanced nitrogen removal start-up of pilot-scale surface flow constructed wetland[J]. Journal of Environmental Engineering Technology, 2017, 7(3): 332-339. doi: 10.3969/j.issn.1674-991X.2017.03.047
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Influence of Phragmites australis carbon dosage on enhanced nitrogen removal start-up of pilot-scale surface flow constructed wetland

doi: 10.3969/j.issn.1674-991X.2017.03.047

  • 1. School of Environmental and Municipal Engineering, North China University of Water Resources and Electric Power, Zhengzhou 450045, China

  • 2. State Key Laboratory of Environment Criteria and Risk Assessment, Chinese Research Academy of Environmental Sciences, Beijing 100012, China

  • 3. Research Center for Water Pollution Control Technology, Chinese Research Academy of Environmental Sciences, Beijing 100012, China

  • 4. National Engineering Laboratory of Lake Water Pollution Control and Ecological Restoration Technology, Chinese Research Academy of Environmental Sciences, Beijing 100012, China

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  • Corresponding author: Haiyan WANG E-mail: wanghy@craes.org.cn
  • Received Date: 2017-01-07
  • Publish Date: 2017-05-20
    Abstract
  • Slow-released plant carbon, Phragmites australis pieces, was added to the surface flow constructed wetland (SFW) to enhance the denitrification nitrogen removal of the low C/N ratio agricultural runoff. The characteristics of the simulated agricultural runoff were as follows: (8.00±1.00)mg/L N O 3 - -N, (9.00±1.00)mg/L TN, (0.70±0.10)mg/L N H 4 + -N, 0.01mg/L N O 2 - -N and (1.00±0.05)mg/L TP. Three pilot-scale SFWs were designed for experiment as follows: the blank SFW without Phragmites australis pieces dosage, 1 # SFW with 1/4 areal proportion of Phragmites australis pieces to enhanced denitrification wetland and 2 # SFW with 1/2 areal proportion of Phragmites australis pieces to enhanced denitrification wetland. A 40-day start-up operation was carried out in static mode. The results showed that the N O 3 - -N removal efficiency increased gradually to 84.2%, 89.1% and 97.8% on the 18 th, 18 th and 7 th day for the blank, 1 # and 2 # SFW respectively, while their TN removal efficiency gradually increased to 75.1%, 79.4% and 90.0% on the 15 th, 15 th and 7 th day in the early stage (1-18 d). The N O 3 - -N was added to (8.00 ± 1.00) mg/L when it was almost completely consumed on the 18 th day. In the latter stage (19-40 d), the N O 3 - -N removal gradually increased to 78.0%, 92.2% and 95.8% on the 40 th, 37 th and 35 th day for the blank, 1 # and 2 # SFW respectively, while their TN removal efficiency increased gradually to 71.4%, 75.2% and 77.1% accordingly. The start-up period of SFW could be greatly shortened by adding Phragmites australis pieces as carbon source, and 2 # SFW started with the higher speed. Moreover, the N O 3 - -N and TN removal rates of 2 # SFW were also higher than those of 1 # and the blank SFWs. It was indicated that the higher-speed start-up and better nitrogen removal efficiency could be obtained for SFW with more Phragmites australis pieces carbon dosage.

     

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