Optimization of Rotational Hydrodynamic Cavitation Reactor Geometry

被引：0

作者：

Omelyanyuk, Maxim ^{[1
]}

Ukolov, Alexey ^{[2
]}

Pakhlyan, Irina ^{[1
]}

Bukharin, Nikolay ^{[3
]}

El Hassan, Mouhammad ^{[4
]}

机构：

[1] Kuban State Technol Univ, Armavir Inst Mech & Technol, Armavir 352905, Russia

[2] Kerch State Maritime Technol Univ, Dept Math Phys & Informat, Kerch 298176, Russia

[3] Southern Alberta Inst Technol, Sch Mfg & Automat, 1301 16 Ave NW, Calgary, AB T2M 0L4, Canada

[4] Prince Mohammad Bin Fahd Univ, Mech Engn Dept, Al Khobar 34754, Saudi Arabia

来源：

FLUIDS | 2024年 / 9卷 / 10期

关键词：

cavitation; CFD; rotary-pulsation apparatus; dispersion; emulsion; optimization; cavitation reactor; BITUMEN SEPARATION; CONSUMPTION; MIXERS; FIELD;

D O I：

10.3390/fluids9100244

中图分类号：

O3 [力学];

学科分类号：

08 ; 0801 ;

摘要：

A Rotary-Pulsation Apparatus (RPA), also known in the literature as a Rotational Hydrodynamic Cavitation Reactor (RHCR), is a device which typically consists of a rotating mechanism that generates pulsations or vibrations within a fluid. This can be achieved through various means such as mechanical agitation, pneumatic pulses, or hydraulic forces. It is widely used in food, chemical, pharmaceutical, and microbiological industries to improve the mixing of different fluids, dispersion, pasteurization, and sterilization. In the present paper, a CFD study was conducted to develop and optimize the geometry of the RPA's rotor and stator to induce cavitation in the fluid flow. The effect of cavitation has the potential to improve dispersion and emulsion properties and to significantly reduce operation pressure, in comparison to conventional mixing systems.

引用

页数：15

共 50 条

[1] Optimization of a hydrodynamic cavitation reactor using salicylic acid dosimetry
Amin, Lekhraj P.
Gogate, Parag R.
Burgess, Arthur E.
Bremner, David H.
CHEMICAL ENGINEERING JOURNAL, 2010, 156 (01) : 165 - 169
[2] Conceptual design of a novel hydrodynamic cavitation reactor
Kumar, K. Sampath
Moholkar, Vijayanand S.
CHEMICAL ENGINEERING SCIENCE, 2007, 62 (10) : 2698 - 2711
[3] Study on the characteristics of cavitation and COD removal of an addendum rotational hydrodynamic cavitation reactors
Zhou, Faqi
Luo, Zhiwei
Wu, Xianbo
Xing, Yiming
Fu, Shuangcheng
Yuan, Huixin
ASIA-PACIFIC JOURNAL OF CHEMICAL ENGINEERING, 2024,
[4] Experimental study of cavitation intensity using a novel hydrodynamic cavitation reactor
Kim, Hyunsoo
Koo, Bonchan
Lee, Seungho
Yoon, Joon Yong
JOURNAL OF MECHANICAL SCIENCE AND TECHNOLOGY, 2019, 33 (09) : 4303 - 4310
[5] Recent Developments in Hydrodynamic Cavitation Reactors: Cavitation Mechanism, Reactor Design, and Applications
Zheng, Haoxuan
Zheng, Ying
Zhu, Jesse
ENGINEERING, 2022, 19 : 180 - 198
[6] Study of Venturi tube geometry on the hydrodynamic cavitation for the generation of microbubbles
Li, Mingda
Bussonniere, Adrien
Bronson, Matthew
Xu, Zhenghe
Liu, Qingxia
MINERALS ENGINEERING, 2019, 132 : 268 - 274
[7] Perspectives of Hydrogen Generation in Cavitation-Jet Hydrodynamic Reactor
Mamytbekov, G. K.
Danko, I. V.
Beksultanov, Zh. I.
Nurtazin, Y. R.
Rakhimbayev, A.
APPLIED SCIENCES-BASEL, 2024, 14 (20):
[8] Effect of the cavitation generation unit structure on the performance of an advanced hydrodynamic cavitation reactor for process intensifications
Sun, Xun
You, Weibin
Xuan, Xiaoxu
Ji, Li
Xu, Xingtao
Wang, Guichao
Zhao, Shan
Boczkaj, Grzegorz
Yoon, Joon Yong
Chen, Songying
CHEMICAL ENGINEERING JOURNAL, 2021, 412
[9] Analysis on transient hydrodynamic characteristics of cavitation process for reactor coolant pump
Wang, Xiu-Li
Wang, Peng
Yuan, Shou-Qi
Zhu, Rong-Sheng
Fu, Qiang
Wang, Xiu-Li, 1600, Atomic Energy Press (48): : 1421 - 1427
[10] Modeling of an industrial scale hydrodynamic cavitation multiphase reactor for Prileschajew epoxidation
Wu, Zhenyu
Cai, Jinjin
Liu, Zhonghui
Wu, Lihang
Liang, Xiaojiang
Xie, Qinglong
Lu, Meizhen
Yu, Fengwen
Nie, Yong
Ji, Jianbing
AICHE JOURNAL, 2020, 66 (05)

← 1 2 3 4 5 →