O_3/H_2O_2湿式催化氧化处理垃圾渗滤液研究
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摘要
采用湿式催化氧化法对垃圾渗滤液进行处理,制备了活性炭载铜、铁系列催化剂,以O_3/H_2O_2为氧化剂, COD去除率为考察指标,考察了反应工艺条件对垃圾渗滤液的处理效果。结果表明:在焙烧温度为600℃,Cu、 Fe物质的量比为3∶1时,制得的Cu-Fe/AC复合催化剂的催化剂活性相对较好;当水样体积为20 m L, H_2O_2投加量为0.5 mL, O_3通入时间为25 min(O3流量为5 g/h),催化剂投加量为1 g时, pH值在2~4和10~12时的COD去除率较好。
Wet catalytic oxidation was used to teat landfill leachate, series catalysts of copper and iron carrying activated carbon were prepared. With H_2 O_2/O_3 as oxidant, removal rate of COD as investigation indicator,the effect of reaction condition on landfill leachate treatment was studied. The results showed that, Cu-Fe/AC composite catalyst prepared under the condition that calcinations temperature was 600 ℃, mass ratio of Cu to Fe was 3 ∶ 1, had relatively good activity. When the water sample quantity was 20 mL, the H_2O_2 dosage was 0.5 mL, the O_3 aeration time was 25 min(flow of O_3 was 5 g/h), the catalyst dosage was 1 g, the pH value was 2-4 or 10-12, good removal efficiency of COD could be obtained.
Wet catalytic oxidation was used to teat landfill leachate, series catalysts of copper and iron carrying activated carbon were prepared. With H_2 O_2/O_3 as oxidant, removal rate of COD as investigation indicator,the effect of reaction condition on landfill leachate treatment was studied. The results showed that, Cu-Fe/AC composite catalyst prepared under the condition that calcinations temperature was 600 ℃, mass ratio of Cu to Fe was 3 ∶ 1, had relatively good activity. When the water sample quantity was 20 mL, the H_2O_2 dosage was 0.5 mL, the O_3 aeration time was 25 min(flow of O_3 was 5 g/h), the catalyst dosage was 1 g, the pH value was 2-4 or 10-12, good removal efficiency of COD could be obtained.
引文
[1]任婉侠,耿涌,薛冰.沈阳市生活垃圾排放现状及产生量预测[J].环境科学与技术, 2011, 34(9):105-112.
[2]张玉清,刘明华.混凝沉淀-Fenton氧化法在垃圾渗滤液生化处理出水中的研究[J].工业用水与废水, 2017, 48(1):28-32.
[3]陈新芳. DTRO处理垃圾渗滤液膜浓缩液的中试研究[J].工业用水与废水, 2018, 49(3):41-44.
[4]谭艳来,黄力彦,罗晓栋,等.微波协同氧化预处理垃圾渗滤液NF膜滤浓缩液研究[J].环境科学与管理, 2016, 41(8):95-98.
[5]薛红琴,速宝玉,盛金昌,等.垃圾填埋场渗滤液的防渗措施和地下水的污染防护[J].安全与环境学报, 2002, 2(4):18-22.
[6]朱斌,费兆阳,陈献,等. Al-PILC负载铜铁复合氧化物在NH3选择性催化还原NO中的协同作用[J].燃料化学学报,2014, 42(9):1102-1110.
[7]齐旭东,李志会.铜铁双组分催化剂用于黑臭河道水处理研究[J].河北工业大学学报, 2017, 46(5):56-61.
[8]韩利华,李国江,炳玉兰.铜系催化剂湿式氧化处理高浓度焦化废水[J].河北理工学院学报, 2003, 25(3):80-85.
[9]仇婷,刘志强,苗群,等.臭氧氧化法进一步去除制罐废水中COD[J].西南给排水, 2006, 28(3):24-26.
[10]芮旻,黄智,覃思晗,等. Cu2O光催化降解水中对硝基苯酚的研究[J].环境污染治理技术与设备, 2003, 4(10):36-39.
[11]张进. Cu/Fe/C作为非均相Fenton催化剂处理含酚废水的研究[D].南京:南京大学, 2018.
[12]隋铭皓.水处理多相臭氧催化氧化技[J].现代化工, 2007,27(3):15-19.
[2]张玉清,刘明华.混凝沉淀-Fenton氧化法在垃圾渗滤液生化处理出水中的研究[J].工业用水与废水, 2017, 48(1):28-32.
[3]陈新芳. DTRO处理垃圾渗滤液膜浓缩液的中试研究[J].工业用水与废水, 2018, 49(3):41-44.
[4]谭艳来,黄力彦,罗晓栋,等.微波协同氧化预处理垃圾渗滤液NF膜滤浓缩液研究[J].环境科学与管理, 2016, 41(8):95-98.
[5]薛红琴,速宝玉,盛金昌,等.垃圾填埋场渗滤液的防渗措施和地下水的污染防护[J].安全与环境学报, 2002, 2(4):18-22.
[6]朱斌,费兆阳,陈献,等. Al-PILC负载铜铁复合氧化物在NH3选择性催化还原NO中的协同作用[J].燃料化学学报,2014, 42(9):1102-1110.
[7]齐旭东,李志会.铜铁双组分催化剂用于黑臭河道水处理研究[J].河北工业大学学报, 2017, 46(5):56-61.
[8]韩利华,李国江,炳玉兰.铜系催化剂湿式氧化处理高浓度焦化废水[J].河北理工学院学报, 2003, 25(3):80-85.
[9]仇婷,刘志强,苗群,等.臭氧氧化法进一步去除制罐废水中COD[J].西南给排水, 2006, 28(3):24-26.
[10]芮旻,黄智,覃思晗,等. Cu2O光催化降解水中对硝基苯酚的研究[J].环境污染治理技术与设备, 2003, 4(10):36-39.
[11]张进. Cu/Fe/C作为非均相Fenton催化剂处理含酚废水的研究[D].南京:南京大学, 2018.
[12]隋铭皓.水处理多相臭氧催化氧化技[J].现代化工, 2007,27(3):15-19.
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