第 41 卷 第 4 期         单鸣雷等： 曲面固壁附近空化泡溃灭动力学的流体体积数值研究                                          557


                                                                [16] Vokurka K, Plocek J. Experimental study of the thermal
                                                                   behavior of spark generated bubbles in water[J]. Experi-
                            参 考     文   献                          mental Thermal & Fluid Science, 2013, 51: 84–93.
                                                                [17] Meadley S L, Escobedo F A. Thermodynamics and ki-
              [1] 黄继汤. 空化与空蚀的原理及应用 [M]. 北京: 清华大学出版                 netics of bubble nucleation: simulation methodology[J].
                 社, 1991.                                          Journal of Chemical Physics, 2012, 137(7): 946–1082.
              [2] 李根生, 沈晓明, 施立德, 等. 空化和空蚀机理及其影响因                [18] Qin Z, Alehossein H. Heat transfer during cavitation bub-
                 素 [J]. 石油大学学报 (自然科学版), 1997, 21(1): 97–102.       ble collapse[J]. Applied Thermal Engineering, 2016, 105:
              [3] 李欣. 水轮机的空化与空蚀 [J]. 科技创新与应用, 2016,                1067–1075.
                 162(14): 109.                                  [19] Kyriazis N, Koukouvinis P, Gavaises M. Numerical inves-
              [4] Chahine G L, Courbiere P. Noise and erosion of self-  tigation of bubble dynamics using tabulated data[J]. Inter-
                 resonating cavitating jets[J]. Journal of Fluids Engineer-  national Journal of Multiphase Flow, 2017, 93: 158–177.
                 ing, 1987, 109(4): 429–435.                    [20] Xu Z, Yasuda K, Liu X. Simulation of the formation and
              [5] Philipp A, Lauterborn W. Cavitation erosion by single  characteristics of ultrasonic fountain[J]. Ultrasonics Sono-
                 laser-produced bubbles[J]. Journal of Fluid Mechanics,  chemistry, 2016, 32: 241–246.
                 1998, 361(1): 75–116.                          [21] Yuan H, Prosperetti A. Gas-liquid heat transfer in a bub-
              [6] Chahine G L, Kapahi A, Choi J K, et al. Modeling of  ble collapsing near a wall[J]. Physics of Fluids, 1997, 9(1):
                 surface cleaning by cavitation bubble dynamics and col-  127–142.
                 lapse[J]. Ultrasonics Sonochemistry, 2016, 29: 528–549.  [22] Yang Y, Shan M, Kan X, et al. Thermodynamic of collaps-
              [7] Verhaagen B, Fernández R. Measuring cavitation and its  ing cavitation bubble investigated by pseudopotential and
                 cleaning effect[J]. Ultrasonics Sonochemistry, 2015, 29:  thermal MRT-LBM[J]. Ultrasonics Sonochemistry, 2019,
                 619–628.                                          62: 104873.
              [8] Chahine G L, Conn A F, Johnson V E, et al. Cleaning  [23] Liu B, Cai J, Huai X, et al. Cavitation bubble collapse
                 and cutting with self-resonating pulsed water jets[C]. 2nd  near a heated wall and its effect on the heat transfer[J].
                 U.S. Water Jet Conference, Rolla, MO, USA, 1983.  Journal of Heat Transfer, 2013, 136(2): 022901.
              [9] Izadifar Z, Babyn P, Chapman D. Ultrasound cavita-  [24] 刘斌. 液体空化强化微通道传热机理研究 [D]. 北京: 中国科
                 tion/microbubble detection and medical applications[J].  学院研究生院, 2014.
                 Journal of Medical and Biological Engineering, 2019,  [25] 李疆, 陈皓生. Fluent 环境中近壁面微空泡溃灭的仿真计
                 39(3): 259–276.                                   算 [J]. 摩擦学学报, 2008, 28(4): 311–315.
             [10] Coussios C C, Roy R. Applications of acoustics and cavita-  Li Jiang, Chen Haosheng. Numerical simulation of micro
                 tion to noninvasive therapy and drug delivery[J]. Annual  bubble collapse near solid wall in fluent environment[J].
                 Review of Fluid Mechanics, 2008, 40: 395–420.     Tribology, 2008, 28(4): 311–315.
             [11] Tomita Y, Robinson P B, Tong R P, et al. Growth and  [26] 魏梦举, 陈力, 伍涛, 等. 微尺度空泡溃灭驱使微球运动的机
                 collapse of cavitation bubbles near a curved rigid bound-  理研究 [J]. 物理学报, 2017, 66(16): 183–192.
                 ary[J]. Journal of Fluid Mechanics, 2002, 466: 259–283.  Wei Mengju, Chen Li, Wu Tao, et al.  Mechanism of
             [12] Ma C, Shi D, Chen Y, et al. Experimental research on the  the motion of spherical microparticle induced by a col-
                 influence of different curved rigid boundaries on electric  lapsed microbubble[J]. Acta Physica Sinica, 2017, 66(16):
                 spark bubbles[J]. Materials (Basel, Switzerland), 2020,  183–192.
                 13(18): 3941.                                  [27] 王效贵, 罗冲, 顾桢标. 固壁面附近空化泡溃灭过程的数值模
             [13] Brujan E A, Matsumoto Y. Collapse of micrometer-sized  拟 [J]. 浙江工业大学学报, 2015, 43(5): 512–516, 591.
                 cavitation bubbles near a rigid boundary[J]. Microfluidics  Wang Xiaogui, Luo Chong, Gu Zhenbiao. Collapse sim-
                 and Nanofluidics, 2012, 13(6): 957–966.            ulation of a cavitation bubble near a rigid boundary[J].
             [14] Li B B, Jia W, Zhang H C, et al. Investigation on the col-  Journal of Zhejiang University of Technology, 2015, 43(5):
                 lapse behavior of a cavitation bubble near a conical rigid  512–516, 591.
                 boundary[J]. Shock Waves, 2014, 24(3): 317–324.  [28] 张凌新, 尹琴, 邵雪明. 水中气泡溃灭的理论与数值研究 [J].
             [15] 魏梦举, 陈力, 伍涛, 等. 微尺度空泡溃灭驱使微球运动的机                  水动力学研究与进展: A 辑, 2012, 27(1): 68–73.
                 理研究 [J]. 物理学报, 2017, 66(16): 167–175.             Zhang Lingxin, Yin Qin, Shao Xueming, et al. Theoretical
                 Wei Mengju, Chen Li, Wu Tao, et al.  Mechanism of  and numerical studies on the bubble collapse in water[J].
                 the motion of spherical microparticle induced by a col-  Journal of Hydrodynamics: A, 2012, 27(1): 68–73.
                 lapsed microbubble[J]. Acta Physica Sinica, 2017, 66(16):  [29] 王家梁. 微尺度空泡与微球相互作用中的冲击波加速机制研
                 167–175.                                          究 [D]. 西安: 西安建筑科技大学, 2019.