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Volume 39 Issue 3
Jul.  2021
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Article Contents
XIE You-you, JU Yi-wen, LIU Xin-chun, LIU Yan-ping, RAO Yu-feng, LAN Miao, JU Li-ting. PRETREATMENT OPTIMIZATION FOR MULTIPLE MEMBRANE TREATMENT AND REUSE OF WATER PROCED PRODUCED BY THREE-GAS CO-PRODUCTION FROM COAL MEASURES[J]. ENVIRONMENTAL ENGINEERING , 2021, 39(3): 61-67. doi: 10.13205/j.hjgc.202103009
Citation: XIE You-you, JU Yi-wen, LIU Xin-chun, LIU Yan-ping, RAO Yu-feng, LAN Miao, JU Li-ting. PRETREATMENT OPTIMIZATION FOR MULTIPLE MEMBRANE TREATMENT AND REUSE OF WATER PROCED PRODUCED BY THREE-GAS CO-PRODUCTION FROM COAL MEASURES[J]. ENVIRONMENTAL ENGINEERING , 2021, 39(3): 61-67. doi: 10.13205/j.hjgc.202103009

PRETREATMENT OPTIMIZATION FOR MULTIPLE MEMBRANE TREATMENT AND REUSE OF WATER PROCED PRODUCED BY THREE-GAS CO-PRODUCTION FROM COAL MEASURES

doi: 10.13205/j.hjgc.202103009
  • Received Date: 2020-03-12
    Available Online: 2021-07-19
  • Three natural gases in coal measure, including coalbed methane (CBM), tight sandstone gas and shale gas, are important unconventional gas resources. Firstly, the treatment process of the collected in-situ water sample was studied, according to the characteristics of ultra-high salinity and high turbidity of the water produced by three-gas co-production from coal measures in Linxing block on the eastern edge of the Erdos basin. Then, pilot treatment was carried out by the process of loading flocculation-microelectrolysis-nanofiltration-reverse osmosis for CBM produced water, on basis of characteristics of high salinity and turbidity. The process parameters and effect of pretreatment units was optimized. The effluent turbidity and COD of the loaded flocculation was 11.66 NTU and 1711 mg/L, respectively, and the removal rates were 98.9% and 34.57%, respectively. The removal of COD was 66.9% and the conductivity of effluent was 52.5 mS/cm by micro electrolysis unit. After NF-RO treatment, the effluent met the dry farming standard of irrigation water quality standard (GB 5084-2005).
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