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Modeling the shock interaction of a mud particle with a filter element at ultrasonic cavitation filtering

descriptionPublicationkeyboard_double_arrow_right Article 18 Apr 2020Publisher:Kyiv Politechnic InstituteJournal:Mechanics and Advanced Technologies, volume 88, pages 58-65 (issn: 2521-1943, eissn: 2522-4255, Copyright policy )
Authors: Zilinskyi, A.; Luhovskyi, А.; Kryshchuk, M.; Gryshko, I.; Shulha, A.;

doi: 10.20535/2521-1943.2020.88.201335

Modeling the shock interaction of a mud particle with a filter element at ultrasonic cavitation filtering

Abstract

The simulation of impact interaction of the contaminant particle with the solid surface of the filter element, which is placed in the cavitation medium by ultrasonic filtration of contaminated liquids, is carried out in the work. An expression of the law of energy conservation is presented, which takes into account the dominant factors acting in the process of interaction of the pollutant with the surface of the filter element. The constituent sources of energy sources that act on the pollutant in contact with the stationary surface of the filter are justified and described. The results of the comparative analysis of mathematical modeling data in ANSYS® Academic Research Mechanical, Release 2019R3 shock interaction of dirt particles with a diameter of 10 μm and 100 μm with two types of filter elements made of AISI321 steel and TEFLON 7 are presented.

В работе проведен имитационное моделирование ударного взаимодействия частицы загрязнителя с твердой поверхностью фильтроэлемента, который расположен в кавитационном среде при ультразвуковом фильтровании загрязненных жидкостей. Представлены выражение закона сохранения энергии, который учитывает доминирующие факторы, действующие в процессе взаимодействия загрязнителя с поверхностью фильтроэлемента. Обоснованные и расписаны составляющие источников энергии, которые действуют на загрязнитель при контакте с неподвижной поверхностью фильтра. Приведены результаты сравнительного анализа данных математического моделирования в программной среде ANSYS® Academic Research Mechanical, Release 2019R3 ударного взаимодействия частиц грязи диаметром 10 мкм и 100 мкм с двумя типами фильтроэлементов, изготовленным из стали 12Х18Н10Т и фторопласта Ф4.

В роботі проведено імітаційне моделювання ударної взаємодії частинки забруднювача з твердою поверхнею фільтроелементу, який розміщений в кавітаційному середовищі при ультразвуковому фільтруванні забруднених рідин. Представлено вираз закону збереження енергії, який враховує домінуючі фактори, що діють у процесі взаємодії забруднювача з поверхнею фільтроелементу. Обґрунтовані та розписані складові джерел енергії, які діють на забруднювач при контакті з нерухомою поверхнею фільтру. Наведено результати порівняльного аналізу даних математичного моделювання в програмному середовищі ANSYS® Academic Research Mechanical, Release 2019R3 ударної взаємодії частинок бруду діаметром 10мкм та 100мкм з двома типами фільтроелементів, виготовленим зі сталі 12Х18Н10Т та фторопласту Ф4.

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Keywords

filtering; ultrasonic cavitation processing; ultrasonic field; ultrasonic cavitation, shock, simulation, defomation, stress, фільтрування; ультразвукова кавітаційна обробка; ультразвукове поле; ультразвукова кавітація, удар, імітаційне моделювання, дефомації, напруження, фильтрование; ультразвуковая кавитационная обработка; ультразвуковое поле; ультразвуковая кавитация, удар, имитационное моделирование, дефомации, напряжение

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selected citations
These citations are derived from selected sources.
This is an alternative to the "Influence" indicator, which also reflects the overall/total impact of an article in the research community at large, based on the underlying citation network (diachronically).
BIP!Citations provided by BIP!
popularity
This indicator reflects the "current" impact/attention (the "hype") of an article in the research community at large, based on the underlying citation network.
BIP!Popularity provided by BIP!
influence
This indicator reflects the overall/total impact of an article in the research community at large, based on the underlying citation network (diachronically).
BIP!Influence provided by BIP!
impulse
This indicator reflects the initial momentum of an article directly after its publication, based on the underlying citation network.
BIP!Impulse provided by BIP!
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