Numerical Simulation of Internal Flow in Screw-Conveyor Atomizer from a Spraying Dust Suppression Device

Eduardo Ayala; Diego Rivera; Julio Ronceros; Leonardo Vinces

doi:10.1007/978-3-031-66961-3_17

Numerical Simulation of Internal Flow in Screw-Conveyor Atomizer from a Spraying Dust Suppression Device

Eduardo Ayala, Diego Rivera, Julio Ronceros, Leonardo Vinces

Facultad de Ingeniería

Universidad Peruana de Ciencias Aplicadas

Producción científica: Capítulo del libro/informe/acta de congreso › Contribución a la conferencia › revisión exhaustiva

Resumen

This article presents a proposition to delve into the intricate internal flow dynamics of a screw-conveyor pressure-swirl atomizer. The objective of the study is to use a comprehensive mathematical model, which will serve as a tool for determining the core dimensions of the atomizer. To verify the accuracy and reliability of the model, rigorous numerical simulations will be conducted. The computational tools employed for the following purpose encompass the utilization of Ansys ICEM CFD software for the creation of a meticulously crafted three-dimensional hexahedral mesh. Subsequently, the Ansys Fluent CFD software is going to be harnessed to execute the simulation of the atomizer’s internal flow behavior. By undertaking the comprehensive analysis, the article aims to shed light on the various merits and demerits inherent in the utilization of such atomizers, particularly concerning their impact on fuel consumption and the intricate sizing aspects. These facets hold paramount significance in the broader realm of mechanical design, specifically in the context of devising efficient dust suppression devices. The numerical simulation of the internal flow is going to be executed employing the RNG k-ε turbulence model, a robust choice to capture the complexities of turbulence. Furthermore, the VOF multiphase model is going to be employed to accurately determine the interface location between the air and liquid phases, enhancing the fidelity of the simulations. In essence, the study strives to provide a comprehensive understanding of the internal flow dynamics of screw-conveyor pressure-swirl atomizers through a combination of advanced mathematical modeling and precise numerical simulations.

Idioma original	Inglés
Título de la publicación alojada	Proceedings of the 9th Brazilian Technology Symposium (BTSym’23) - Emerging Trends and Challenges in Technology
Editores	Yuzo Iano, Rangel Arthur, Osamu Saotome, Guillermo Leopoldo Kemper Vásquez, Maria Thereza de Moraes Gomes Rosa, Gabriel Gomes de Oliveira
Editorial	Springer Science and Business Media Deutschland GmbH
Páginas	184-194
Número de páginas	11
ISBN (versión impresa)	9783031669606
DOI	https://doi.org/10.1007/978-3-031-66961-3_17
Estado	Publicada - 2024
Evento	9th Brazilian Technology Symposium on Emerging Trends and Challenges in Technology, BTSym 2023 - Campinas, Brasil Duración: 24 oct. 2023 → 26 oct. 2023

Serie de la publicación

Nombre	Smart Innovation, Systems and Technologies
Volumen	402 SIST
ISSN (versión impresa)	2190-3018
ISSN (versión digital)	2190-3026

Conferencia

Conferencia	9th Brazilian Technology Symposium on Emerging Trends and Challenges in Technology, BTSym 2023
País/Territorio	Brasil
Ciudad	Campinas
Período	24/10/23 → 26/10/23

Acceder al documento

10.1007/978-3-031-66961-3_17

Otros archivos y enlaces

Enlace a la publicación en Scopus

Citar esto

Ayala, E., Rivera, D., Ronceros, J., & Vinces, L. (2024). Numerical Simulation of Internal Flow in Screw-Conveyor Atomizer from a Spraying Dust Suppression Device. En Y. Iano, R. Arthur, O. Saotome, G. L. Kemper Vásquez, M. T. de Moraes Gomes Rosa, & G. Gomes de Oliveira (Eds.), Proceedings of the 9th Brazilian Technology Symposium (BTSym’23) - Emerging Trends and Challenges in Technology (pp. 184-194). (Smart Innovation, Systems and Technologies; Vol. 402 SIST). Springer Science and Business Media Deutschland GmbH. https://doi.org/10.1007/978-3-031-66961-3_17

Ayala, Eduardo ; Rivera, Diego ; Ronceros, Julio et al. / Numerical Simulation of Internal Flow in Screw-Conveyor Atomizer from a Spraying Dust Suppression Device. Proceedings of the 9th Brazilian Technology Symposium (BTSym’23) - Emerging Trends and Challenges in Technology. editor / Yuzo Iano ; Rangel Arthur ; Osamu Saotome ; Guillermo Leopoldo Kemper Vásquez ; Maria Thereza de Moraes Gomes Rosa ; Gabriel Gomes de Oliveira. Springer Science and Business Media Deutschland GmbH, 2024. pp. 184-194 (Smart Innovation, Systems and Technologies).

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title = "Numerical Simulation of Internal Flow in Screw-Conveyor Atomizer from a Spraying Dust Suppression Device",

abstract = "This article presents a proposition to delve into the intricate internal flow dynamics of a screw-conveyor pressure-swirl atomizer. The objective of the study is to use a comprehensive mathematical model, which will serve as a tool for determining the core dimensions of the atomizer. To verify the accuracy and reliability of the model, rigorous numerical simulations will be conducted. The computational tools employed for the following purpose encompass the utilization of Ansys ICEM CFD software for the creation of a meticulously crafted three-dimensional hexahedral mesh. Subsequently, the Ansys Fluent CFD software is going to be harnessed to execute the simulation of the atomizer{\textquoteright}s internal flow behavior. By undertaking the comprehensive analysis, the article aims to shed light on the various merits and demerits inherent in the utilization of such atomizers, particularly concerning their impact on fuel consumption and the intricate sizing aspects. These facets hold paramount significance in the broader realm of mechanical design, specifically in the context of devising efficient dust suppression devices. The numerical simulation of the internal flow is going to be executed employing the RNG k-ε turbulence model, a robust choice to capture the complexities of turbulence. Furthermore, the VOF multiphase model is going to be employed to accurately determine the interface location between the air and liquid phases, enhancing the fidelity of the simulations. In essence, the study strives to provide a comprehensive understanding of the internal flow dynamics of screw-conveyor pressure-swirl atomizers through a combination of advanced mathematical modeling and precise numerical simulations.",

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Ayala, E, Rivera, D, Ronceros, J & Vinces, L 2024, Numerical Simulation of Internal Flow in Screw-Conveyor Atomizer from a Spraying Dust Suppression Device. En Y Iano, R Arthur, O Saotome, GL Kemper Vásquez, MT de Moraes Gomes Rosa & G Gomes de Oliveira (eds.), Proceedings of the 9th Brazilian Technology Symposium (BTSym’23) - Emerging Trends and Challenges in Technology. Smart Innovation, Systems and Technologies, vol. 402 SIST, Springer Science and Business Media Deutschland GmbH, pp. 184-194, 9th Brazilian Technology Symposium on Emerging Trends and Challenges in Technology, BTSym 2023, Campinas, Brasil, 24/10/23. https://doi.org/10.1007/978-3-031-66961-3_17

Numerical Simulation of Internal Flow in Screw-Conveyor Atomizer from a Spraying Dust Suppression Device. / Ayala, Eduardo; Rivera, Diego; Ronceros, Julio et al.
Proceedings of the 9th Brazilian Technology Symposium (BTSym’23) - Emerging Trends and Challenges in Technology. ed. / Yuzo Iano; Rangel Arthur; Osamu Saotome; Guillermo Leopoldo Kemper Vásquez; Maria Thereza de Moraes Gomes Rosa; Gabriel Gomes de Oliveira. Springer Science and Business Media Deutschland GmbH, 2024. p. 184-194 (Smart Innovation, Systems and Technologies; Vol. 402 SIST).

Producción científica: Capítulo del libro/informe/acta de congreso › Contribución a la conferencia › revisión exhaustiva

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T1 - Numerical Simulation of Internal Flow in Screw-Conveyor Atomizer from a Spraying Dust Suppression Device

AU - Ayala, Eduardo

AU - Rivera, Diego

AU - Ronceros, Julio

AU - Vinces, Leonardo

N1 - Publisher Copyright: © The Author(s), under exclusive license to Springer Nature Switzerland AG 2024.

PY - 2024

Y1 - 2024

N2 - This article presents a proposition to delve into the intricate internal flow dynamics of a screw-conveyor pressure-swirl atomizer. The objective of the study is to use a comprehensive mathematical model, which will serve as a tool for determining the core dimensions of the atomizer. To verify the accuracy and reliability of the model, rigorous numerical simulations will be conducted. The computational tools employed for the following purpose encompass the utilization of Ansys ICEM CFD software for the creation of a meticulously crafted three-dimensional hexahedral mesh. Subsequently, the Ansys Fluent CFD software is going to be harnessed to execute the simulation of the atomizer’s internal flow behavior. By undertaking the comprehensive analysis, the article aims to shed light on the various merits and demerits inherent in the utilization of such atomizers, particularly concerning their impact on fuel consumption and the intricate sizing aspects. These facets hold paramount significance in the broader realm of mechanical design, specifically in the context of devising efficient dust suppression devices. The numerical simulation of the internal flow is going to be executed employing the RNG k-ε turbulence model, a robust choice to capture the complexities of turbulence. Furthermore, the VOF multiphase model is going to be employed to accurately determine the interface location between the air and liquid phases, enhancing the fidelity of the simulations. In essence, the study strives to provide a comprehensive understanding of the internal flow dynamics of screw-conveyor pressure-swirl atomizers through a combination of advanced mathematical modeling and precise numerical simulations.

AB - This article presents a proposition to delve into the intricate internal flow dynamics of a screw-conveyor pressure-swirl atomizer. The objective of the study is to use a comprehensive mathematical model, which will serve as a tool for determining the core dimensions of the atomizer. To verify the accuracy and reliability of the model, rigorous numerical simulations will be conducted. The computational tools employed for the following purpose encompass the utilization of Ansys ICEM CFD software for the creation of a meticulously crafted three-dimensional hexahedral mesh. Subsequently, the Ansys Fluent CFD software is going to be harnessed to execute the simulation of the atomizer’s internal flow behavior. By undertaking the comprehensive analysis, the article aims to shed light on the various merits and demerits inherent in the utilization of such atomizers, particularly concerning their impact on fuel consumption and the intricate sizing aspects. These facets hold paramount significance in the broader realm of mechanical design, specifically in the context of devising efficient dust suppression devices. The numerical simulation of the internal flow is going to be executed employing the RNG k-ε turbulence model, a robust choice to capture the complexities of turbulence. Furthermore, the VOF multiphase model is going to be employed to accurately determine the interface location between the air and liquid phases, enhancing the fidelity of the simulations. In essence, the study strives to provide a comprehensive understanding of the internal flow dynamics of screw-conveyor pressure-swirl atomizers through a combination of advanced mathematical modeling and precise numerical simulations.

KW - ANSYS Fluent

KW - ANSYS ICEM

KW - Mechanical design

KW - Numerical simulation CFD

KW - Screw-conveyor atomizer

KW - Spraying dust suppression device

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M3 - Contribución a la conferencia

AN - SCOPUS:85202601837

SN - 9783031669606

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BT - Proceedings of the 9th Brazilian Technology Symposium (BTSym’23) - Emerging Trends and Challenges in Technology

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A2 - Kemper Vásquez, Guillermo Leopoldo

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Ayala E, Rivera D, Ronceros J, Vinces L. Numerical Simulation of Internal Flow in Screw-Conveyor Atomizer from a Spraying Dust Suppression Device. En Iano Y, Arthur R, Saotome O, Kemper Vásquez GL, de Moraes Gomes Rosa MT, Gomes de Oliveira G, editores, Proceedings of the 9th Brazilian Technology Symposium (BTSym’23) - Emerging Trends and Challenges in Technology. Springer Science and Business Media Deutschland GmbH. 2024. p. 184-194. (Smart Innovation, Systems and Technologies). doi: 10.1007/978-3-031-66961-3_17