一种加压溶气式微泡发生器的设计
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摘要
为进一步提高微泡在治理黑臭水体中的可行性,利用加压溶气气浮原理,开发一种加压溶气式微泡发生器;考察气水体积比、压力、水流量对反应器性能的影响;研究液面位置及表面活性剂对微泡尺寸分布、体积分数和水体溶解氧的影响,论证了微泡发生器的可行性。实验结果表明:在压力P=0. 4 MPa,气水体积比为1. 5∶1,水流量QL=20 L/min时,得到微泡中位径最小值为34. 65μm,水中的溶解氧质量浓度达到10. 2 mg/L。在添加0. 025 g/L的十二烷基硫酸钠后,同样条件下,微泡中位径最小值为26. 68μm,溶解氧质量浓度达到11. 1 mg/L。设备停止运行1 h后水中溶解氧质量浓度保持在7. 5 mg/L左右。综上,加压式微泡发生器可有效地增加水中的溶解氧,延长氧气在水中的停留时间,其应用具有可行性。
In order to further improve the feasibility of micro-bubbles in the treatment of black and odorous water,a pressurized dissolved air micro-bubbles generator was developed based on the principle of pressurized dissolved air flotation.The effects of gas-water volume ratio,pressure and water flow rate on the reactor performance were investigated. The effects of liquid surface position and surfactant on the size distribution,volume fraction and dissolved oxygen in water were studied,and the feasibility of the micro-bubbles generator was demonstrated. The experimental results show that: When P = 0. 4 MPa,gas-water ratio = 1. 5 ∶ 1 and QL= 20 L/min,the minimum median diameter of micro bubbles is 34. 65 μm and mass concentration of dissolved oxygen is 10. 2 mg/L in water. Adding sodium dodecyl sulfate of 0. 025 g/L,the minimum median diameter D50 of micro-bubbles was 26. 68 μm under the same conditions,dissolved oxygen reached 11. 1 mg/L.Dissolved oxygen in water remained about 7. 5 mg/L after the equipment stopped running for 1 hour. In conclusion,pressurized micro-bubble generator can effectively increase dissolved oxygen in water,prolong the residence time of oxygen in water,and provide possibility for its application.
In order to further improve the feasibility of micro-bubbles in the treatment of black and odorous water,a pressurized dissolved air micro-bubbles generator was developed based on the principle of pressurized dissolved air flotation.The effects of gas-water volume ratio,pressure and water flow rate on the reactor performance were investigated. The effects of liquid surface position and surfactant on the size distribution,volume fraction and dissolved oxygen in water were studied,and the feasibility of the micro-bubbles generator was demonstrated. The experimental results show that: When P = 0. 4 MPa,gas-water ratio = 1. 5 ∶ 1 and QL= 20 L/min,the minimum median diameter of micro bubbles is 34. 65 μm and mass concentration of dissolved oxygen is 10. 2 mg/L in water. Adding sodium dodecyl sulfate of 0. 025 g/L,the minimum median diameter D50 of micro-bubbles was 26. 68 μm under the same conditions,dissolved oxygen reached 11. 1 mg/L.Dissolved oxygen in water remained about 7. 5 mg/L after the equipment stopped running for 1 hour. In conclusion,pressurized micro-bubble generator can effectively increase dissolved oxygen in water,prolong the residence time of oxygen in water,and provide possibility for its application.
引文
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[2]张其殿,刘淑杰,芦嵩林,等.加压溶气生化气浮法降解生活污水中有机物[J].环境工程学报,2014,8(3):1051-1056.
[3]陆晖,胡湛波,蒋哲,等.微纳米曝气技术对城市景观水体修复的影响[J].环境工程学报,2016,10(4):1755-1760.
[4]王美丽,袁震,何连生,等.微纳米曝气技术处理黑臭河道废水的研究[D].石家庄:河北科技大学,2014.
[5]李红云.微泡对水处理的作用机理及应用研究[D].昆明:昆明理工大学,2014.
[6]李帅,孙龙泉,张阿漫.水中上浮气泡动态特性研究[J].物理学报,2014,63(18):291-303.
[7]杨丽,廖传华,朱跃钊,等.微纳米气泡特性及在环境污染控制中的应用[J].化工进展,2012,31(6):1333-1337.
[8]LI H,HU L,XIA Z.Impact of groundwater salinity on bioremediation enhanced by micro-nano bubbles[J].Materials,2013,6(9):3676-3687.
[9]靳明伟,丁建宁,凌智勇,等.超微细气泡水体修复技术[J].功能材料与器件学报,2008,14(1):19-22.
[10]刘季霖.微纳米气泡发生装置研究[D].杭州:浙江大学,2012.
[11]邓久帅,李浙昆,何伟,等.一种旋流式微泡发生器及生成微泡的方法:201410324868.7[P].2014-07-09.
[12]王永磊,王文浩,代莎莎,等.微纳米气泡发生机理及其应用研究进展[J].山东建筑大学学报,2017,32(5):474-480.
[13]高东.工业废水处理之“气浮法”[J].科技传播,2010,2(15):147.
[14]时玉龙,王三反,武广,等.加压溶气气浮微气泡产生机理及工程应用研究[J].工业水处理,2012,32(2):20-23.
[15]汪群慧,张健,翟学东,等.微气泡气浮与溶气气浮预处理餐饮含油废水的研究[J].黑龙江大学自然科学学报,2008,25(6):798-801.
[16]熊永磊,杨小丽,宋海亮.微纳米气泡在水处理中的应用及其发生装置研究[J].环境工程,2016,34(6):23-27.
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