张昆明,陆小菊,黄永春,杨锋,黄承都,任仙娥,黄琼

• 1:广西科技大学生物与化学工程学院
• 2:广西糖资源绿色加工重点实验室(广西科技大学)
• 3:广西高校糖资源加工重点实验室(广西科技大学)

摘要(Abstract)：

水力空化作为液体特有的现象,其本质属于相变过程,相变产生的空化泡在溃灭瞬间引起的空化效应,除广泛应用于水处理领域外,还被用于生物资源领域中.文章对水力空化的概念、优点、产生机理和空化判据,及其近年来在生物资源领域中的研究与应用新进展等进行了概述;最后提出,水力空化相比于超声空化能耗更低、能效更高和规模放大更易,其作为一种新型过程强化手段在生物资源领域的应用是其重要的研究方向,同时也将具有更广阔的的应用前景.

关键词(KeyWords)： 水力空化;生物资源;过程强化

Abstract:

Keywords:

基金项目(Foundation): 国家自然科学基金项目(31701646,31660472);; 广西自然科学基金项目(2017GXNSFBA198036);; 广西高等学校高水平创新团队及卓越学者计划项目(桂教人[2014]7号);; 广西高校中青年教师基础能力提升项目(2017KY0344);; 广西高校糖资源加工重点实验室开放基金项目(2016TZYKF04);; 广西科技大学博士基金项目(校科博17Z04)资助

作者(Author): 张昆明,陆小菊,黄永春,杨锋,黄承都,任仙娥,黄琼

DOI: 10.16375/j.cnki.cn45-1395/t.2018.02.002

参考文献(References)：

• [1]ARNDT R E A.Recent advances in cavitation research[J].Advances in Hydroscience,1981,12:1-78.
• [2]潘森森,彭晓星.空化机理[M].北京:国防工业出版社,2013.
• [3]ARNDT R E A.Handbook of fluid dynamics[M].2nd ed.Boca Raton:CRC Press,2016.
• [4]黄永春,袁媛,吴宇,等.壳聚糖溶液水力空化泡动力学的数值模拟[J].现代食品科技,2014,30(5):150-155.
• [5]GOGATE P R,PANDIT A B.A review and assessment of hydrodynamic cavitation as a technology for the future[J].Ultrasonics Sonochemistry,2005,12:21-27.
• [6]GOGATE P R.Cavitation:an auxiliary technique in wastewater treatment schemes[J].Advances in Environmental Research,2002,6(3):335-358.
• [7]MAHULKAR A V,RIEDEL C,GOGATE P R,et al.Effect of dissolved gas on efficacy of sonochemical reactors for microbial cell disruption:experimental and numerical analysis[J].Ultrasonics Sonochemistry,2009,16(5):635-643.
• [8]GAIKWAD S G,PANDIT A B.Ultrasound emulsification:effect of ultrasonic and physicochemical properties on dispersed phase volume and droplet size[J].Ultrasonics Sonochemistry,2008,15(4):554-563.
• [9]CHEMAT F,ROMBAUT N,SICAIRE A G,et al.Ultrasound assisted extraction of food and natural products.mechanisms,techniques,combinations,protocols and applications.a review[J].Ultrasonics Sonochemistry,2017,34:540-560.
• [10]MEROUANI S,HAMDAOUI O,SAOUDI F,et al.Sonochemical degradation of rhodamine B in aqueous phase:effects of additives[J].Chemical Engineering Journal,2010,158(3):550-557.
• [11]PANDIT A B,KUMAR P S,KUMAR M S.Improve reaction with hydrodynamic cavitation[J].Chemical Engineering Progress,1999,95(5):43-50.
• [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[J].化学工程,2004,32(4):27-29.
• [13]刘宝彪,张昆明,黄永春,等.涡流空化强化载药壳聚糖微球制备效果初探[J].广西科技大学学报,2017,28(3):52-60.
• [14]吴玉林,唐学林,刘树红,等.水力机械空化和固液两相流体动力学[M].北京:中国水利水电出版社,2007.
• [15]HAMMITT F G.Cavitation and multiphase flow phenomena[M].New York:Mc Graw-Hill,1980.
• [16]GOGATE P R,PANDIT A B.Hydrodynamic cavitation reactors:a state of the art review[J].Reviews in Chemical Engineering,2001,17(1):1-85.
• [17]朱孟府,曾艳,邓橙,等.水力空化在水处理中的应用与研究进展[J].环境科学与技术,2010,33(12):445-449.
• [18]GOGATE P R,KABADI A M.A review of applications of cavitation in biochemical engineering/biotechnology[J].Biochemical Engineering Journal,2009,44(1):60-72.
• [19]黄继汤.空化与空蚀的原理及应用[M].北京:清华大学出版社,1991.
• [20]OBA R,YASU S.Spatial cavitation nuclei measurements by means of laser velocimeter[J].Rep Inst High Speed Mech Tohoku Univ,1978,38:1-12.
• [21]CHA Y S.On the equilibrium of cavitation nuclei in liquid-gas solutions[J].Journal of Fluids Engineering,1981,103(3):425-430.
• [22]KNAPP R T,DAILY J W,HAMMITT F G.Cavitation[M].New York:Mc Graw-Hill,1970.
• [23]PLESSET M S,WHIPPLE C G.Viscous effects in Rayleigh-Taylor instability[J].Physics of Fluids,1974,17(1):1-7.
• [24]MOHOLKAR V S,SENTHIL KUMAR P,PANDIT A B.Hydrodynamic cavitation for sonochemical effects[J].Ultrasonics Sonochemistry,1999,6:53-65.
• [25]PANDIT A B,JOSHI J B.Hydrolysis of fatty oils:effect of cavitation[J].Chemical Engineering Science,1993,48(19):3440-3442.
• [26]HUANG Y,WU Y,HUANG W,et al.Degradation of chitosan by hydrodynamic cavitation[J].Polymer Degradation and Stability,2013,98(1):37-43.
• [27]WU Y,HUANG Y,ZHOU Y,et al.Degradation of chitosan by swirling cavitation[J].Innovative Food Science&Emerging Technologies,2014,23:188-193.
• [28]许佳丽,黄永春,袁媛,等.基于文丘里管的水力空化降解壳聚糖的研究[J].食品工业科技,2016,37(2):244-248.
• [29]HUANG Y,WANG P,YUAN Y,et al.Synergistic degradation of chitosan by impinging stream and jet cavitation[J].Ultrasonics Sonochemistry,2015,27:592-601.
• [30]张伟伟,任仙娥,杨锋,等.氧气对涡流空化降解壳聚糖的影响[J].食品科学,2016,37(9):45-49.
• [31]ZHANG S J,HE B,ZHANG D L.The degradation of chitosan using hydrodynamic cavitation with Na NO2 enhancement[J].Advanced Materials Research,2014,1015:585-589.
• [32]何冰,张淑君,信志强,等.水力空化联合H2O2降解壳聚糖的研究[J].重庆理工大学学报(自然科学版),2014,28(11):52-56.
• [33]毛善巧,杨锋,黄永春,等.水力空化对果胶粘度的影响及其凝胶色谱表征[J].食品工业科技,2017,38(21):65-68,75.
• [34]李聪.水力空化对木质纤维素降解过程的影响[D].长春:长春工业大学,2015.
• [35]黄永春,高海芳,吴修超,等.水力空化强化糖液亚硫酸法脱色的研究[J].食品与机械,2014,30(3):5-8.
• [36]黄永春,熊叶,吴修超,等.水力空化强化亚硫酸钙吸附糖液中非糖分的研究[J].食品工业科技,2014,35(15):229-231.
• [37]SAVE S S,PANDIT A B,JOSHI J B.Use of hydrodynamic cavitation for large scale microbial cell disruption[J].Food and Bioproducts Processing,1997,75(1):41-49.
• [38]MILLY P J,TOLEDO R T,HARRISON M A,et al.Inactivation of food spoilage microorganisms by hydrodynamic cavitation to achieve pasteurization and sterilization of fluid foods[J].Journal of Food Science,2007,72(9):414-422.
• [39]MILLY P J,TOLEDO R T,KERR W L,et al.Hydrodynamic cavitation:characterization of a novel design with energy considerations for the inactivation of saccharomyces cerevisiae in apple juice[J].Journal of Food Science,2008,73(6):298-303.
• [40]宋源,王帅,于水利,等.微气泡水力空化强化混凝除藻的试验研究[J].中国给水排水,2015,31(3):116-119.
• [41]JAYA H S,WARDANA I N G,NURKHOLIS M H,et al.Palm oil hydrolysis reaction with hydrodynamic jet cavitations[J].International Journal of Applied Engineering Research,2015,10(21):42725-42730.
• [42]SAINTE BEUVE R,MORISON K R.Enzymatic hydrolysis of canola oil with hydrodynamic cavitation[J].Chemical Engineering and Processing:Process Intensification,2010,49(10):1101-1106.
• [43]任仙娥,黄永春,杨锋,等.水力空化对大豆分离蛋白功能性质的影响[J].食品与机械,2014,30(2):4-6,31.
• [44]刘雪,杨锋,任仙娥,等.涡流空化对大豆分离蛋白黏度的影响[J].食品工业科技,2016,37(16):142-145.
• [45]BOKHARI A,YUSUP S,CHUAH L F,et al.Pilot scale intensification of rubber seed(hevea brasiliensis)oil via chemical interesterification using hydrodynamic cavitation technology[J].Bioresource Technology,2017,242:272-282.
• [46]MADDIKERI G L,GOGATE P R,PANDIT A B.Intensified synthesis of biodiesel using hydrodynamic cavitation reactors based on the interesterification of waste cooking oil[J].Fuel,2014,137:285-292.
• [47]GOLE V L,NAVEEN K R,GOGATE P R.Hydrodynamic cavitation as an efficient approach for intensification of synthesis of methyl esters from sustainable feedstock[J].Chemical Engineering and Processing:Process Intensification,2013,71:70-76.
• [48]CHUAH L F,YUSUP S,ABD AZIZ A R,et al.Intensification of biodiesel synthesis from waste cooking oil(Palm Olein)in a hydrodynamic cavitation reactor:effect of operating parameters on methyl ester conversion[J].Chemical Engineering and Processing:Process Intensification,2015,95:235-240.
• [49]CRUDO D,BOSCO V,CAVAGLI G,et al.Biodiesel production process intensification using a rotor-stator type generator of hydrodynamic cavitation[J].Ultrasonics Sonochemistry,2016,33:220-225.
• [50]何相君,聂勇,陆向红,等.水力空化强化制备生物柴油过程的研究[J].精细石油化工进展,2011,12(5):47-51.
• [51]TERA..N H R,DE ALMEIDA G F,AHMED M A,et al.Hydrodynamic cavitation as an efficient pretreatment method for lignocellulosic biomass:a parametric study[J].Bioresource Technology,2017,235:301-308.
• [52]KIM I,LEE I,JEON S H,et al.Hydrodynamic cavitation as a novel pretreatment approach for bioethanol production from reed[J].Bioresource Technology,2015,192:335-339.
• [53]PATIL P N,GOGATE P R,CSOKA L,et al.Intensification of biogas production using pretreatment based on hydrodynamic cavitation[J].Ultrasonics Sonochemistry,2016,30:79-86.

文章评论(Comment)：