Powder processing—Models and simulations

A. B. Yu

doi:10.1016/B978-0-323-90800-9.00118-9

Powder processing—Models and simulations

A. B. Yu

Chemical & Biological Engineering

Research output: Chapter in Book/Report/Conference proceeding › Chapter (Book) › Other › peer-review

1 Citation (Scopus)

Abstract

Particle science and technology is a rapidly developing interdisciplinary research area with its core being the understanding of the relationships between micro- and macro-scopic properties of granular matter—a state of matter that is widely encountered but poorly understood. The macroscopic behavior of particulate matter is controlled by the interactions between individual particles as well as interactions with surrounding gas, liquid and/or wall. Understanding the microscopic mechanisms in terms of these interaction forces is therefore key to leading to truly interdisciplinary research into particulate matter and producing results that can be generally used. This aim can be effectively achieved via particle scale research based on detailed microdynamic information such as the forces acting on and trajectories of individual particles in a considered system. In recent years, such research has been rapidly developed worldwide, mainly as a result of the rapid development of discrete particle simulation technique and computer technology. This chapter presents an overview of the work in this direction. It is demonstrated that simulation and modeling has emerged to be a powerful tool not only for fundamental research but also for engineering application.

Original language	English
Title of host publication	Encyclopedia of Condensed Matter Physics
Editors	Tapash Chakraborty
Place of Publication	Amsterdam Netherlands
Publisher	Elsevier - Mosby
Pages	679-693
Number of pages	15
Edition	2nd
ISBN (Electronic)	9780323908009
ISBN (Print)	9780323914086
DOIs	https://doi.org/10.1016/B978-0-323-90800-9.00118-9
Publication status	Published - 2024

Keywords

Agglomeration
Computational fluid dynamics
Computer simulation
Discrete element method
Discrete particle simulation
Fluidization
Gas-solid flow
Granular dynamics
Granular materials
Interparticle interaction
Mathematical modeling
Modelling and simulation
Particle packing
Particle-fluid interaction
Porous media
Powder processing

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10.1016/B978-0-323-90800-9.00118-9

Cite this

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title = "Powder processing—Models and simulations",

abstract = "Particle science and technology is a rapidly developing interdisciplinary research area with its core being the understanding of the relationships between micro- and macro-scopic properties of granular matter—a state of matter that is widely encountered but poorly understood. The macroscopic behavior of particulate matter is controlled by the interactions between individual particles as well as interactions with surrounding gas, liquid and/or wall. Understanding the microscopic mechanisms in terms of these interaction forces is therefore key to leading to truly interdisciplinary research into particulate matter and producing results that can be generally used. This aim can be effectively achieved via particle scale research based on detailed microdynamic information such as the forces acting on and trajectories of individual particles in a considered system. In recent years, such research has been rapidly developed worldwide, mainly as a result of the rapid development of discrete particle simulation technique and computer technology. This chapter presents an overview of the work in this direction. It is demonstrated that simulation and modeling has emerged to be a powerful tool not only for fundamental research but also for engineering application.",

keywords = "Agglomeration, Computational fluid dynamics, Computer simulation, Discrete element method, Discrete particle simulation, Fluidization, Gas-solid flow, Granular dynamics, Granular materials, Interparticle interaction, Mathematical modeling, Modelling and simulation, Particle packing, Particle-fluid interaction, Porous media, Powder processing",

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year = "2024",

doi = "10.1016/B978-0-323-90800-9.00118-9",

language = "English",

isbn = "9780323914086",

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editor = "Tapash Chakraborty",

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edition = "2nd",

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T1 - Powder processing—Models and simulations

AU - Yu, A. B.

PY - 2024

Y1 - 2024

N2 - Particle science and technology is a rapidly developing interdisciplinary research area with its core being the understanding of the relationships between micro- and macro-scopic properties of granular matter—a state of matter that is widely encountered but poorly understood. The macroscopic behavior of particulate matter is controlled by the interactions between individual particles as well as interactions with surrounding gas, liquid and/or wall. Understanding the microscopic mechanisms in terms of these interaction forces is therefore key to leading to truly interdisciplinary research into particulate matter and producing results that can be generally used. This aim can be effectively achieved via particle scale research based on detailed microdynamic information such as the forces acting on and trajectories of individual particles in a considered system. In recent years, such research has been rapidly developed worldwide, mainly as a result of the rapid development of discrete particle simulation technique and computer technology. This chapter presents an overview of the work in this direction. It is demonstrated that simulation and modeling has emerged to be a powerful tool not only for fundamental research but also for engineering application.

AB - Particle science and technology is a rapidly developing interdisciplinary research area with its core being the understanding of the relationships between micro- and macro-scopic properties of granular matter—a state of matter that is widely encountered but poorly understood. The macroscopic behavior of particulate matter is controlled by the interactions between individual particles as well as interactions with surrounding gas, liquid and/or wall. Understanding the microscopic mechanisms in terms of these interaction forces is therefore key to leading to truly interdisciplinary research into particulate matter and producing results that can be generally used. This aim can be effectively achieved via particle scale research based on detailed microdynamic information such as the forces acting on and trajectories of individual particles in a considered system. In recent years, such research has been rapidly developed worldwide, mainly as a result of the rapid development of discrete particle simulation technique and computer technology. This chapter presents an overview of the work in this direction. It is demonstrated that simulation and modeling has emerged to be a powerful tool not only for fundamental research but also for engineering application.

KW - Agglomeration

KW - Computational fluid dynamics

KW - Computer simulation

KW - Discrete element method

KW - Discrete particle simulation

KW - Fluidization

KW - Gas-solid flow

KW - Granular dynamics

KW - Granular materials

KW - Interparticle interaction

KW - Mathematical modeling

KW - Modelling and simulation

KW - Particle packing

KW - Particle-fluid interaction

KW - Porous media

KW - Powder processing

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U2 - 10.1016/B978-0-323-90800-9.00118-9

DO - 10.1016/B978-0-323-90800-9.00118-9

M3 - Chapter (Book)

AN - SCOPUS:85212805416

SN - 9780323914086

SP - 679

EP - 693

BT - Encyclopedia of Condensed Matter Physics

A2 - Chakraborty, Tapash

PB - Elsevier - Mosby

CY - Amsterdam Netherlands

ER -

Powder processing—Models and simulations

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Keywords

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ARC Research Hub for Computational Particle Technology

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Powder processing—Models and simulations

Abstract

Keywords

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ARC Research Hub for Computational Particle Technology

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