A2O设施处理长三角平原地区农村生活污水的效果
- Title:
- Performance of A2O Facilities for Rural Domestic Sewage Treatment in Yangtze River Delta Plain
- Keywords:
- font-size: 10pt; ">anaerobic-anoxic-oxic (A font-size: 10pt; "> 2 O); rural domestic sewage; nitrogen and phosphorus removal; Yangtze River Delta plain
- 摘要:
-
厌氧/缺氧/好氧(A2O)设施在长三角平原地区农村生活污水处理中应用广泛,此次调研了5个镇39个A2O设施对污染物的去除效果和进水量。结果表明,A2O设施进水COD、氨氮、TN、TP的浓度分别为(95±80)、(56.2±40.0)、(61.6±40.1)、(4.6±2.8) mg/L,部分设施进水浓度较低,说明污水收集有问题。由于进水量不稳定,A2O设施受降雨量影响很大,与设计规模有较大偏差。A2O设施对COD、氨氮、TN、TP的去除率分别为(46.9±30.5)%、(46.0±37.3)%、(19.7±18.7)%和(25.1±21.9)%,各设施之间对污染物的去除情况差别很大,出水COD达标率较高,但氮、磷达标率较低。进水COD浓度低引起的有机负荷与进水COD/TN值偏低、雨污分流不彻底引起的较大水力冲击负荷、进水水质水量波动大、设施运维工作不到位引起的生物脱氮除磷效果不佳,是A2O设施应用效果不理想的重要原因。
- Abstract:
-
Anaerobic-anoxic-oxic (A2O) facilities are widely applied in rural domestic sewage treatment in the Yangtze River Delta plain. Pollutants removal performance and influent flow rate of 39 A2O facilities in five towns were investigated. The influent concentrations of COD, ammonia nitrogen (NH 3 -N),total nitrogen (TN)and total phosphorus (TP) were (95±80) mg/L,(56.2±40.0) mg/L,(61.6±40.1) mg/L and (4.6±2.8) mg/L, respectively. The very low influent concentration in some facilities indicated that there was a problem in sewage collection. Due to the unstable influent flow rate, the A2O facilities were greatly affected by rainfall and deviated from the design capacity.The removal rates of COD, NH3-N, TN and TP by the A2O facilities were (46.9±30.5)%, (46.0±37.3)%, (19.7±18.7)% and (25.1±21.9)%, respectively,and the removal performances varied greatly among facilities. The standard achieving rate of effluent COD was high, but those of effluent nitrogen and phosphorus were low. Important reasons for the poor performance of the facilities were as follows: the too low organic load and influent COD/TN ratio caused by the low concentration of influent COD, high shocking load caused by incomplete diversion of rain and sewage, dramatic fluctuation in quality and quantity of the influent, as well as poor biological removal of nitrogen and phosphorus caused by inadequate operation and maintenance of the facilities.
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