1 黄继汤. 空化与空蚀的原理及应用. 北京: 清华大学出版社,1991(Huang Jitang. Principle and Application of Cavita- tion and Cavitation Erosion. Beijing: Tsinghua University Press, 1991 (in Chinese))
[2]
2 田方宝,林缅. 水射流辅助破岩机理研究-气泡空蚀. 力学与实践,2007,29(1): 29-33 (Tian Fangbao, Lin Mian. Studies on the mechanicsm of water jet-assited drilling technology- cavitation and erosion. Mechanics in Engineering,2007,29(1): 29-33 (in Chinese))
[3]
3 Petrier C, Micolle M, Merlin G, et al. Characteristics of pentachl orophenate degradation in aqueous solution by means of ultrasound. Environ Sci Technol, 1992, 26(8):1639-1642
[4]
4 吴胜举. 超声降解处理水体污染物的研究状况与发展. 物理,2001, 30(12): 782-786 (Wu Shengju. The research survey of degradation organic pollutant using ultrasonic. Physics,2001, 30(12): 782-786 (in Chinese))
[5]
5 Didenko YT, Suslick KS. The energy efficiency of forma- tionof photons, radicals and ions during single-bubble. Na- ture, 2002, 418(6896): 394-397
[6]
6 Kalumuck KM, Chahine GL. The use of cavitating jets to oxidize organic compounds in water. American Social Ma- chine Engineering, 1998(3): 245-250
[7]
7 Sivakumar M, Pandit AB. Hydrodynamic cavitation as- sisted rodamine B degradation: A technologically viable water treatment technique. In: Int Conf on Science and Technology, New Delhi, India, 2000. 12-13
[8]
8 Jyoti KK, Pandit AB. Effect of cavitation on chemical dis- infection efficiency. Water Research, 2004, 38(9): 2249-2258
[9]
9 Arrojo S, Benito Y. A parametrical study of disinfection with hydrodynamic cavitation. Ultrasonic Sonochemistry,2008, (15): 903-908
[10]
10 Mezule L, Tsyfansky S. A simple technique for water dis- infection with hydrodynamic cavitation: Effect on survival of escherichia coli. Desalination, 2009, 248(1-3): 152-159
[11]
11 Chakinala AG, Gogate PR. Treatment of industrial wastewater e?uents using hydrodynamic cavitation and the advanced fenton process. Ultrasonics Sonochemistry,2008, 15(1): 49-54
[12]
12 李志义, 张晓冬, 刘学武等. 水力空化及其对化工过程的强化作用. 化学工程, 2004, 32(4): 27-29 (Li Zhiyi, Zhang Xi- aodong, Liu Xuewu, et al. Hydrodynamic cavitation and its enhancement effects on chemical processes. Chemical Engineering, 2004, 32(4): 27-29 (in Chinese))
[13]
13 乔慧琼, 孙三祥, 张健东. 水力空化技术降解含苯酚, 二甲苯废水的实验研究. 能源环境保护, 2007, 21(2): 18-21 (Qiao Huiqiong, Sun Sanxiang, Zhang Jiandong. Study on degra- dation of phenol and xylene in wastewater by hydrody- namic cavatation. Energy Environmental Protection, 2007,21(2): 18-21 (in Chinese))
[14]
14 王琪, 蔡美强, 关怡新等. 强化两相混合的超临界技术制备聚乳酸微粒. 浙江大学学报(工学版), 2010, 44(1): 2383-2390 (Wang Qi, Cai Meiqiang, Guan Yixin, et al. Micronization of poly(lactic acid)by supercritical fluid assisted atomiza- tion with intensifying two-phase mixing. Journal of Zhe- jiang University (Engineering Science), 2010, 44(1): 2383-2390 (in Chinese))
[15]
15 蔡军, 淮秀兰, 闫润生等. 湍流作用下水力空化气泡内温度演变的动力学分析. 科学通报, 2012, 56 (12):947-955 (Cai Jun, Huai Xiulan, Yan Runsheng, et al. Dynamic analysis on temperature evolution inside a single bubble due to hy- drodynamic cavitation under turbulence. Chinese Science Bulletin, 2012, 56 (12):947-955 (in Chinese))
[16]
16 武金明. 多孔板水力空化装置最佳水力条件的确定. 能源与环境, 2012, 4: 12-15 (Wu Jinming. Porous plate hydrody- namic cavitation device determine the optimum hydraulic conditions. Energy and Environment, 2012, 4: 12-15 (in Chinese))
