Experimental evaluation of 3D printed Venturi-type Fine Bubble Generators with internal obstacles

Toma, Gabriel; Ikemoto, Riku; Batalu, Dan; Alcántara Avila, J. Rafael

doi:10.14293/PR2199.000216.v1

ScienceOpen: research and publishing network

For Publishers

For Researchers

Blog
About

Search
Advanced search

773

views

recommends

One-Click Submission System Now Available for SO Preprints, learn more on how this works in our blog post and don't forget to check the video, too!

scite_

Smart Citations

Citing PublicationsSupportingMentioningContrasting

View Citations

See how this article has been cited at scite.ai

scite shows how a scientific paper has been cited by providing the context of the citation, a classification describing whether it supports, mentions, or contrasts the cited claim, and a label indicating in which section the citation was made.

Header Abstract Content Author and article information References Comments

Record: found
Abstract: found
Article: found

Is Open Access

Experimental evaluation of 3D printed Venturi-type Fine Bubble Generators with internal obstacles

Preprint

In review

research-article

Author(s): Gabriel Toma ¹ , Riku Ikemoto ¹ , Dan Batalu ² , J. Rafael Alcántara Avila ¹ ^,

Publication date (Electronic preprint): 6 July 2023

Journal: ScienceOpen Preprints

Publisher: ScienceOpen

Keywords: Fine Bubbles, Hydrodynamic cavitation, Gas absorption, Fine bubble stability

Bookmark

Abstract

Content

Author and article information

Journal

Title: ScienceOpen Preprints

Publisher: ScienceOpen

Publication date (Electronic preprint): 6 July 2023

Affiliations

[1 ] Department of Chemical Engineering, Kyoto University, Katsura Campus Nishikyo-ku, Kyoto 615-8510, Japan;

[2 ] Metallic Materials Science and Physical Metallurgy Department, Politehnica University of Bucharest, 060042, Bucharest, Romania;

Author notes

[* ]Email: jrafael.cheme@ 123456gmail.com .

Author information

J. Rafael Alcántara Avila https://orcid.org/0000-0001-5974-2760

Article

DOI: 10.14293/PR2199.000216.v1

SO-VID: 7e71da02-6dda-40e5-a833-23af2ad1b705

License:

This work has been published open access under Creative Commons Attribution License CC BY 4.0 , which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Conditions, terms of use and publishing policy can be found at www.scienceopen.com .

History

Date received : 6 July 2023

Funding

Funded by: funder-id http://dx.doi.org/10.13039/501100001691, Japan Society for the Promotion of Science;

Award ID: 19K15337

References

Alheshibri Muidh, Al Baroot Abbad, Shui Lingling, Zhang Minmin. Nanobubbles and nanoparticles. Current Opinion in Colloid & Interface Science. Vol. 55:2021. Elsevier BV. [Cross Ref]
Nirmalkar N., Pacek A. W., Barigou M.. On the Existence and Stability of Bulk Nanobubbles. Langmuir. Vol. 34(37):10964–10973. 2018. American Chemical Society (ACS). [Cross Ref]
Calgaroto S., Wilberg K.Q., Rubio J.. On the nanobubbles interfacial properties and future applications in flotation. Minerals Engineering. Vol. 60:33–40. 2014. Elsevier BV. [Cross Ref]
Sun Le, Zhang Fenghua, Guo Xiaoming, Qiao Zhengming, Zhu Yi, Jin Nuo, Cui Yan, Yang Weimin. Research progress on bulk nanobubbles. Particuology. Vol. 60:99–106. 2022. Elsevier BV. [Cross Ref]
Huang Jiang, Sun Licheng, Mo Zhengyu, Feng Yi, Bao Jingjing, Tang Jiguo. Experimental investigation on the effect of throat size on bubble transportation and breakup in small Venturi channels. International Journal of Multiphase Flow. Vol. 142:2021. Elsevier BV. [Cross Ref]
Pawar Sandip K., Mahulkar Amit V., Pandit Aniruddha B., Roy Kuldeep, Moholkar Vijayanand S.. Sonochemical effect induced by hydrodynamic cavitation: Comparison of venturi/orifice flow geometries. AIChE Journal. Vol. 63(10):4705–4716. 2017. Wiley. [Cross Ref]
Nazari Sabereh, Hassanzadeh Ahmad, He Yaqun, Khoshdast Hamid, Kowalczuk Przemyslaw B.. Recent Developments in Generation, Detection and Application of Nanobubbles in Flotation. Minerals. Vol. 12(4)2022. MDPI AG. [Cross Ref]
Gordiychuk Andriy, Svanera Michele, Benini Sergio, Poesio Pietro. Size distribution and Sauter mean diameter of micro bubbles for a Venturi type bubble generator. Experimental Thermal and Fluid Science. Vol. 70:51–60. 2016. Elsevier BV. [Cross Ref]
Huang Jiang, Sun Licheng, Du Min, Liang Zhao, Mo Zhengyu, Tang Jiguo, Xie Guo. An investigation on the performance of a micro-scale Venturi bubble generator. Chemical Engineering Journal. Vol. 386:2020. Elsevier BV. [Cross Ref]
Huang Jiang, Sun Licheng, Liu Hongtao, Mo Zhengyu, Tang Jiguo, Xie Guo, Du Min. A review on bubble generation and transportation in Venturi-type bubble generators. Experimental and Computational Multiphase Flow. Vol. 2(3):123–134. 2020. Springer Science and Business Media LLC. [Cross Ref]
Sakamatapan Kittipong, Mesgarpour Mehrdad, Mahian Omid, Ahn Ho Seon, Wongwises Somchai. Experimental investigation of the microbubble generation using a venturi-type bubble generator. Case Studies in Thermal Engineering. Vol. 27:2021. Elsevier BV. [Cross Ref]
De Oro Ochoa Esteban, Carmona García Mauricio, Durango Padilla Néstor, Martínez Remolina Andrés. Design and experimental evaluation of a Venturi and Venturi-Vortex microbubble aeration system. Heliyon. Vol. 8(10)2022. Elsevier BV. [Cross Ref]
Wilson Dillon Alexander, Pun Kul, Ganesan Poo Balan, Hamad Faik. Geometrical Optimization of a Venturi-Type Microbubble Generator Using CFD Simulation and Experimental Measurements. Designs. Vol. 5(1)2021. MDPI AG. [Cross Ref]
Wu Mian, Yuan Shiyan, Song Haoyuan, Li Xiaobing. Micro-nano bubbles production using a swirling-type venturi bubble generator. Chemical Engineering and Processing - Process Intensification. Vol. 170:2022. Elsevier BV. [Cross Ref]
Wu Mian, Song Haoyuan, Liang Xing, Huang Neng, Li Xiaobing. Generation of micro-nano bubbles by self-developed swirl-type micro-nano bubble generator. Chemical Engineering and Processing - Process Intensification. Vol. 181:2022. Elsevier BV. [Cross Ref]
Epstein P. S., Plesset M. S.. On the Stability of Gas Bubbles in Liquid-Gas Solutions. The Journal of Chemical Physics. Vol. 18(11):1505–1509. 1950. AIP Publishing. [Cross Ref]
Sun Le, Zhang Fenghua, Guo Xiaoming, Qiao Zhengming, Zhu Yi, Jin Nuo, Cui Yan, Yang Weimin. Research progress on bulk nanobubbles. Particuology. Vol. 60:99–106. 2022. Elsevier BV. [Cross Ref]
Bhattacharjee Sourav. DLS and zeta potential – What they are and what they are not? Journal of Controlled Release. Vol. 235:337–351. 2016. Elsevier BV. [Cross Ref]
Yasui Kyuichi, Tuziuti Toru, Kanematsu Wataru. Interaction of Bulk Nanobubbles (Ultrafine Bubbles) with a Solid Surface. Langmuir. Vol. 37(5):1674–1681. 2021. American Chemical Society (ACS). [Cross Ref]
Wu Jiajia, Zhang Kejia, Cen Cheng, Wu Xiaogang, Mao Ruyin, Zheng Yingying. Role of bulk nanobubbles in removing organic pollutants in wastewater treatment. AMB Express. Vol. 11(1)2021. Springer Science and Business Media LLC. [Cross Ref]
An Seong Soo A., Kim Kyoung–Min, Kim Hye Min, Lee Won–Jae, Lee Chang–Woo, Kim Tae–il, Lee Jong-Kwon, Jeong Jayoung, Paek Seung–Min, Shin Jae-Ho. Surface treatment of silica nanoparticles for stable and charge-controlled colloidal silica. International Journal of Nanomedicine. 2014. Informa UK Limited. [Cross Ref]
Almeida Teresa Cristina Abreu, Larentis Ariane Leites, Ferraz Helen Conceição. Evaluation of the Stability of Concentrated Emulsions for Lemon Beverages Using Sequential Experimental Designs. PLOS ONE. Vol. 10(3)2015. Public Library of Science (PLoS). [Cross Ref]
Kouchakzadeh Hasan, Shojaosadati Seyed Abbas, Maghsoudi Amir, Vasheghani Farahani Ebrahim. Optimization of PEGylation Conditions for BSA Nanoparticles Using Response Surface Methodology. AAPS PharmSciTech. Vol. 11(3):1206–1211. 2010. Springer Science and Business Media LLC. [Cross Ref]

Comments

Comment on this article

[1] Alheshibri Muidh, Al Baroot Abbad, Shui Lingling, Zhang Minmin. Nanobubbles and nanoparticles. Current Opinion in Colloid & Interface Science. Vol. 55:2021. Elsevier BV. [Cross Ref]

[2] Nirmalkar N., Pacek A. W., Barigou M.. On the Existence and Stability of Bulk Nanobubbles. Langmuir. Vol. 34(37):10964–10973. 2018. American Chemical Society (ACS). [Cross Ref]

[3] Calgaroto S., Wilberg K.Q., Rubio J.. On the nanobubbles interfacial properties and future applications in flotation. Minerals Engineering. Vol. 60:33–40. 2014. Elsevier BV. [Cross Ref]

[4] Sun Le, Zhang Fenghua, Guo Xiaoming, Qiao Zhengming, Zhu Yi, Jin Nuo, Cui Yan, Yang Weimin. Research progress on bulk nanobubbles. Particuology. Vol. 60:99–106. 2022. Elsevier BV. [Cross Ref]

[5] Huang Jiang, Sun Licheng, Mo Zhengyu, Feng Yi, Bao Jingjing, Tang Jiguo. Experimental investigation on the effect of throat size on bubble transportation and breakup in small Venturi channels. International Journal of Multiphase Flow. Vol. 142:2021. Elsevier BV. [Cross Ref]

[6] Pawar Sandip K., Mahulkar Amit V., Pandit Aniruddha B., Roy Kuldeep, Moholkar Vijayanand S.. Sonochemical effect induced by hydrodynamic cavitation: Comparison of venturi/orifice flow geometries. AIChE Journal. Vol. 63(10):4705–4716. 2017. Wiley. [Cross Ref]

[7] Nazari Sabereh, Hassanzadeh Ahmad, He Yaqun, Khoshdast Hamid, Kowalczuk Przemyslaw B.. Recent Developments in Generation, Detection and Application of Nanobubbles in Flotation. Minerals. Vol. 12(4)2022. MDPI AG. [Cross Ref]

[8] Gordiychuk Andriy, Svanera Michele, Benini Sergio, Poesio Pietro. Size distribution and Sauter mean diameter of micro bubbles for a Venturi type bubble generator. Experimental Thermal and Fluid Science. Vol. 70:51–60. 2016. Elsevier BV. [Cross Ref]

[9] Huang Jiang, Sun Licheng, Du Min, Liang Zhao, Mo Zhengyu, Tang Jiguo, Xie Guo. An investigation on the performance of a micro-scale Venturi bubble generator. Chemical Engineering Journal. Vol. 386:2020. Elsevier BV. [Cross Ref]

[10] Huang Jiang, Sun Licheng, Liu Hongtao, Mo Zhengyu, Tang Jiguo, Xie Guo, Du Min. A review on bubble generation and transportation in Venturi-type bubble generators. Experimental and Computational Multiphase Flow. Vol. 2(3):123–134. 2020. Springer Science and Business Media LLC. [Cross Ref]

[11] Sakamatapan Kittipong, Mesgarpour Mehrdad, Mahian Omid, Ahn Ho Seon, Wongwises Somchai. Experimental investigation of the microbubble generation using a venturi-type bubble generator. Case Studies in Thermal Engineering. Vol. 27:2021. Elsevier BV. [Cross Ref]

[12] De Oro Ochoa Esteban, Carmona García Mauricio, Durango Padilla Néstor, Martínez Remolina Andrés. Design and experimental evaluation of a Venturi and Venturi-Vortex microbubble aeration system. Heliyon. Vol. 8(10)2022. Elsevier BV. [Cross Ref]

[13] Wilson Dillon Alexander, Pun Kul, Ganesan Poo Balan, Hamad Faik. Geometrical Optimization of a Venturi-Type Microbubble Generator Using CFD Simulation and Experimental Measurements. Designs. Vol. 5(1)2021. MDPI AG. [Cross Ref]

[14] Wu Mian, Yuan Shiyan, Song Haoyuan, Li Xiaobing. Micro-nano bubbles production using a swirling-type venturi bubble generator. Chemical Engineering and Processing - Process Intensification. Vol. 170:2022. Elsevier BV. [Cross Ref]

[15] Wu Mian, Song Haoyuan, Liang Xing, Huang Neng, Li Xiaobing. Generation of micro-nano bubbles by self-developed swirl-type micro-nano bubble generator. Chemical Engineering and Processing - Process Intensification. Vol. 181:2022. Elsevier BV. [Cross Ref]

[16] Epstein P. S., Plesset M. S.. On the Stability of Gas Bubbles in Liquid-Gas Solutions. The Journal of Chemical Physics. Vol. 18(11):1505–1509. 1950. AIP Publishing. [Cross Ref]

[17] Sun Le, Zhang Fenghua, Guo Xiaoming, Qiao Zhengming, Zhu Yi, Jin Nuo, Cui Yan, Yang Weimin. Research progress on bulk nanobubbles. Particuology. Vol. 60:99–106. 2022. Elsevier BV. [Cross Ref]

[18] Bhattacharjee Sourav. DLS and zeta potential – What they are and what they are not? Journal of Controlled Release. Vol. 235:337–351. 2016. Elsevier BV. [Cross Ref]

[19] Yasui Kyuichi, Tuziuti Toru, Kanematsu Wataru. Interaction of Bulk Nanobubbles (Ultrafine Bubbles) with a Solid Surface. Langmuir. Vol. 37(5):1674–1681. 2021. American Chemical Society (ACS). [Cross Ref]

[20] Wu Jiajia, Zhang Kejia, Cen Cheng, Wu Xiaogang, Mao Ruyin, Zheng Yingying. Role of bulk nanobubbles in removing organic pollutants in wastewater treatment. AMB Express. Vol. 11(1)2021. Springer Science and Business Media LLC. [Cross Ref]

[21] An Seong Soo A., Kim Kyoung–Min, Kim Hye Min, Lee Won–Jae, Lee Chang–Woo, Kim Tae–il, Lee Jong-Kwon, Jeong Jayoung, Paek Seung–Min, Shin Jae-Ho. Surface treatment of silica nanoparticles for stable and charge-controlled colloidal silica. International Journal of Nanomedicine. 2014. Informa UK Limited. [Cross Ref]

[22] Almeida Teresa Cristina Abreu, Larentis Ariane Leites, Ferraz Helen Conceição. Evaluation of the Stability of Concentrated Emulsions for Lemon Beverages Using Sequential Experimental Designs. PLOS ONE. Vol. 10(3)2015. Public Library of Science (PLoS). [Cross Ref]

[23] Kouchakzadeh Hasan, Shojaosadati Seyed Abbas, Maghsoudi Amir, Vasheghani Farahani Ebrahim. Optimization of PEGylation Conditions for BSA Nanoparticles Using Response Surface Methodology. AAPS PharmSciTech. Vol. 11(3):1206–1211. 2010. Springer Science and Business Media LLC. [Cross Ref]

One-Click Submission System Now Available for SO Preprints, learn more on how this works in our blog post and don't forget to check the video, too!

Experimental evaluation of 3D printed Venturi-type Fine Bubble Generators with internal obstacles

Journal

Affiliations

Author notes

Author information

Article

History

Funding

Categories

Comment on this article