The Mathematical Model for the Secondary Breakup of Dropping Liquid

The Mathematical Model for the Secondary Breakup of Dropping Liquid

Investigating characteristics for the secondary breakup of dropping liquid is a fundamental scientific and practical problem in multiphase flow. For its solving, it is necessary to consider the features of both the main hydrodynamic and secondary processes during spray granulation and vibration sepa...

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Main Authors: Ivan Pavlenko, Vsevolod Sklabinskyi, Michał Doligalski, Marek Ochowiak, Marcin Mrugalski, Oleksandr Liaposhchenko, Maksym Skydanenko, Vitalii Ivanov, Sylwia Włodarczak, Szymon Woziwodzki, Izabela Kruszelnicka, Dobrochna Ginter-Kramarczyk, Radosław Olszewski, Bernard Michałek
Format: Article
Language:English
Published: MDPI AG 2020-11-01
Series:Energies
Subjects:
oscillatory wall
vibrational impact
Weber number
critical value
nonstable droplet
Online Access:https://www.mdpi.com/1996-1073/13/22/6078
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spelling doaj-7fc9893705ca4512ba75d7c770a8bc142020-11-25T04:11:45ZengMDPI AGEnergies1996-10732020-11-01136078607810.3390/en13226078The Mathematical Model for the Secondary Breakup of Dropping LiquidIvan Pavlenko0Vsevolod Sklabinskyi1Michał Doligalski2Marek Ochowiak3Marcin Mrugalski4Oleksandr Liaposhchenko5Maksym Skydanenko6Vitalii Ivanov7Sylwia Włodarczak8Szymon Woziwodzki9Izabela Kruszelnicka10Dobrochna Ginter-Kramarczyk11Radosław Olszewski12Bernard Michałek13Faculty of Technical Systems and Energy Efficient Technologies, Sumy State University, 40007 Sumy, UkraineFaculty of Technical Systems and Energy Efficient Technologies, Sumy State University, 40007 Sumy, UkraineFaculty of Computer, Electrical and Control Engineering, University of Zielona Góra, 65-516 Zielona Góra, PolandDepartment of Chemical Engineering and Equipment, Poznan University of Technology, 60-965 Poznan, PolandFaculty of Computer, Electrical and Control Engineering, University of Zielona Góra, 65-516 Zielona Góra, PolandFaculty of Technical Systems and Energy Efficient Technologies, Sumy State University, 40007 Sumy, UkraineFaculty of Technical Systems and Energy Efficient Technologies, Sumy State University, 40007 Sumy, UkraineFaculty of Technical Systems and Energy Efficient Technologies, Sumy State University, 40007 Sumy, UkraineDepartment of Chemical Engineering and Equipment, Poznan University of Technology, 60-965 Poznan, PolandDepartment of Chemical Engineering and Equipment, Poznan University of Technology, 60-965 Poznan, PolandDepartment of Chemical Engineering and Equipment, Poznan University of Technology, 60-965 Poznan, PolandDepartment of Chemical Engineering and Equipment, Poznan University of Technology, 60-965 Poznan, PolandFaculty of Chemistry, Adam Mickiewicz University, 61-614 Poznan, PolandFaculty of Chemistry, Adam Mickiewicz University, 61-614 Poznan, PolandInvestigating characteristics for the secondary breakup of dropping liquid is a fundamental scientific and practical problem in multiphase flow. For its solving, it is necessary to consider the features of both the main hydrodynamic and secondary processes during spray granulation and vibration separation of heterogeneous systems. A significant difficulty in modeling the secondary breakup process is that in most technological processes, the breakup of droplets and bubbles occurs through the simultaneous action of several dispersion mechanisms. In this case, the existing mathematical models based on criterion equations do not allow establishing the change over time of the process’s main characteristics. Therefore, the present article aims to solve an urgent scientific and practical problem of studying the nonstationary process of the secondary breakup of liquid droplets under the condition of the vibrational impact of oscillatory elements. Methods of mathematical modeling were used to achieve this goal. This modeling allows obtaining analytical expressions to describe the breakup characteristics. As a result of modeling, the droplet size’s critical value was evaluated depending on the oscillation frequency. Additionally, the analytical expression for the critical frequency was obtained. The proposed methodology was derived for a range of droplet diameters of 1.6–2.6 mm. The critical value of the diameter for unstable droplets was also determined, and the dependence for breakup time was established. Notably, for the critical diameter in a range of 1.90–2.05 mm, the breakup time was about 0.017 s. The reliability of the proposed methodology was confirmed experimentally by the dependencies between the Ohnesorge and Reynolds numbers for different prilling process modes.https://www.mdpi.com/1996-1073/13/22/6078oscillatory wallvibrational impactWeber numbercritical valuenonstable droplet
collection DOAJ
language English
format Article
sources DOAJ
author Ivan Pavlenko
Vsevolod Sklabinskyi
Michał Doligalski
Marek Ochowiak
Marcin Mrugalski
Oleksandr Liaposhchenko
Maksym Skydanenko
Vitalii Ivanov
Sylwia Włodarczak
Szymon Woziwodzki
Izabela Kruszelnicka
Dobrochna Ginter-Kramarczyk
Radosław Olszewski
Bernard Michałek
spellingShingle Ivan Pavlenko
Vsevolod Sklabinskyi
Michał Doligalski
Marek Ochowiak
Marcin Mrugalski
Oleksandr Liaposhchenko
Maksym Skydanenko
Vitalii Ivanov
Sylwia Włodarczak
Szymon Woziwodzki
Izabela Kruszelnicka
Dobrochna Ginter-Kramarczyk
Radosław Olszewski
Bernard Michałek
The Mathematical Model for the Secondary Breakup of Dropping Liquid
Energies
oscillatory wall
vibrational impact
Weber number
critical value
nonstable droplet
author_facet Ivan Pavlenko
Vsevolod Sklabinskyi
Michał Doligalski
Marek Ochowiak
Marcin Mrugalski
Oleksandr Liaposhchenko
Maksym Skydanenko
Vitalii Ivanov
Sylwia Włodarczak
Szymon Woziwodzki
Izabela Kruszelnicka
Dobrochna Ginter-Kramarczyk
Radosław Olszewski
Bernard Michałek
author_sort Ivan Pavlenko
title The Mathematical Model for the Secondary Breakup of Dropping Liquid
title_short The Mathematical Model for the Secondary Breakup of Dropping Liquid
title_full The Mathematical Model for the Secondary Breakup of Dropping Liquid
title_fullStr The Mathematical Model for the Secondary Breakup of Dropping Liquid
title_full_unstemmed The Mathematical Model for the Secondary Breakup of Dropping Liquid
title_sort mathematical model for the secondary breakup of dropping liquid
publisher MDPI AG
series Energies
issn 1996-1073
publishDate 2020-11-01
description Investigating characteristics for the secondary breakup of dropping liquid is a fundamental scientific and practical problem in multiphase flow. For its solving, it is necessary to consider the features of both the main hydrodynamic and secondary processes during spray granulation and vibration separation of heterogeneous systems. A significant difficulty in modeling the secondary breakup process is that in most technological processes, the breakup of droplets and bubbles occurs through the simultaneous action of several dispersion mechanisms. In this case, the existing mathematical models based on criterion equations do not allow establishing the change over time of the process’s main characteristics. Therefore, the present article aims to solve an urgent scientific and practical problem of studying the nonstationary process of the secondary breakup of liquid droplets under the condition of the vibrational impact of oscillatory elements. Methods of mathematical modeling were used to achieve this goal. This modeling allows obtaining analytical expressions to describe the breakup characteristics. As a result of modeling, the droplet size’s critical value was evaluated depending on the oscillation frequency. Additionally, the analytical expression for the critical frequency was obtained. The proposed methodology was derived for a range of droplet diameters of 1.6–2.6 mm. The critical value of the diameter for unstable droplets was also determined, and the dependence for breakup time was established. Notably, for the critical diameter in a range of 1.90–2.05 mm, the breakup time was about 0.017 s. The reliability of the proposed methodology was confirmed experimentally by the dependencies between the Ohnesorge and Reynolds numbers for different prilling process modes.
topic oscillatory wall
vibrational impact
Weber number
critical value
nonstable droplet
url https://www.mdpi.com/1996-1073/13/22/6078
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