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Lattice Boltzmann method and its applications in engineering /:

Lattice Boltzmann method (LBM) is a relatively new simulation technique for the modeling of complex fluid systems and has attracted interest from researchers in computational physics. Unlike the traditional CFD methods, which solve the conservation equations of macroscopic properties (i.e., mass, mo...

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1. Verfasser:	Guo, Zhaoli
Körperschaft:	World Scientific (Firm)
Weitere Verfasser:	Shu, Chang, 1962-
Format:	Elektronisch E-Book
Sprache:	English
Veröffentlicht:	Singapore ; Hackensack, N.J. : World Scientific Pub. Co., ©2013.
Schriftenreihe:	Advances in computational fluid dynamics ; v. 3.
Schlagworte:	Lattice Boltzmann methods. Méthodes de Boltzmann sur réseau. SCIENCE > Nanoscience. Lattice Boltzmann methods
Online-Zugang:	Volltext
Zusammenfassung:	Lattice Boltzmann method (LBM) is a relatively new simulation technique for the modeling of complex fluid systems and has attracted interest from researchers in computational physics. Unlike the traditional CFD methods, which solve the conservation equations of macroscopic properties (i.e., mass, momentum, and energy) numerically, LBM models the fluid consisting of fictive particles, and such particles perform consecutive propagation and collision processes over a discrete lattice mesh. This book will cover the fundamental and practical application of LBM. The first part of the book consists of three chapters starting form the theory of LBM, basic models, initial and boundary conditions, theoretical analysis, to improved models. The second part of the book consists of six chapters, address applications of LBM in various aspects of computational fluid dynamic engineering, covering areas, such as thermo-hydrodynamics, compressible flows, multicomponent/multiphase flows, microscale flows, flows in porous media, turbulent flows, and suspensions. With these coverage LBM, the book intended to promote its applications, instead of the traditional computational fluid dynamic method.
Beschreibung:	1 online resource (xiii, 404 pages) : illustrations (some color).
Bibliographie:	Includes bibliographical references (pages 373-396) and index.
ISBN:	9789814508308 9814508306 1299556507 9781299556508

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505	0		\|a Ch. 1. Introduction. 1.1. Description of fluid system at different scales. 1.2. Numerical methods for fluid flows. 1.3. History of LBE. 1.4. Basic models of LBE. 1.5. Summary -- ch. 2. Initial and boundary conditions for lattice Boltzmann method. 2.1. Initial conditions. 2.2. Boundary conditions for flat walls. 2.3. Boundary conditions for curved walls. 2.4. Pressure boundary conditions. 2.5. Summary -- ch. 3. Improved lattice Boltzmann models. 3.1. Incompressible models. 3.2. Forcing schemes with reduced discrete lattice effects. 3.3. LBE with nonuniform grids. 3.4. Accelerated LBE methods for steady flows. 3.5. Summary -- ch. 4. Sample applications of LBE for isothermal flows. 4.1. Algorithm structure of LBE. 4.2. Lid-driven cavity flow. 4.3. Flow around a fixed circular cylinder. 4.4. Flow around an oscillating circular cylinder with a fixed downstream one. 4.5. Summary -- ch. 5. LBE for low speed flows with heat transfer. 5.1. Multi-speed models. 5.2. MS-LBE models based on Boltzmann equation. 5.3. Off-lattice LBE models. 5.4. MS-LBE models with adjustable Prandtl number. 5.5. DDF-LBE models without viscous dissipation and compression work. 5.6. DDF-LBE with viscous dissipation and compression work -- internal energy formulation. 5.7. DDF-LBE with viscous dissipation and compression work -- total energy formulation. 5.8. Hybrid LBE models. 5.9. Summary -- ch. 6. LBE for compressible flows. 6.1. Limitation of conventional LBE models for compressible flows. 6.2. Conventional equilibrium function-based LBE models for compressible flows. 6.3. Circular function-based LBE models for compressible flows. 6.4. Delta function-based LBE models for compressible flows. 6.5. Direct derivation of equilibrium distribution functions from conservation of moments. 6.6. Solution of discrete velocity Boltzmann equation. 6.7. Lattice Boltzmann flux solver for solution of Euler equations. 6.8. Some sample applications. 6.9. Summary -- ch. 7. LBE for multiphase and multi-component flows. 7.1. Color models. 7.2. Pseudo-potential models. 7.3. Free energy models. 7.4. LBE models based on kinetic theories. 7.5. Summary -- ch. 8. LBE for microscale gas flows. 8.1. Introduction. 8.2. Fundamental issues in LBE for micro gaseous flows. 8.3. LBE for slip flows. 8.4. LBE for transition flows. 8.5. LBE for microscale binary mixture flows. 8.6. Summary -- ch. 9. Other applications of LBE. 9.1. Applications of LBE for particulate flows. 9.2. Applications of LBE for flows in porous media. 9.3. Applications of LBE for turbulent flows. 9.4. Immersed boundary-lattice Boltzmann method and its applications. 9.5. Summary.
520			\|a Lattice Boltzmann method (LBM) is a relatively new simulation technique for the modeling of complex fluid systems and has attracted interest from researchers in computational physics. Unlike the traditional CFD methods, which solve the conservation equations of macroscopic properties (i.e., mass, momentum, and energy) numerically, LBM models the fluid consisting of fictive particles, and such particles perform consecutive propagation and collision processes over a discrete lattice mesh. This book will cover the fundamental and practical application of LBM. The first part of the book consists of three chapters starting form the theory of LBM, basic models, initial and boundary conditions, theoretical analysis, to improved models. The second part of the book consists of six chapters, address applications of LBM in various aspects of computational fluid dynamic engineering, covering areas, such as thermo-hydrodynamics, compressible flows, multicomponent/multiphase flows, microscale flows, flows in porous media, turbulent flows, and suspensions. With these coverage LBM, the book intended to promote its applications, instead of the traditional computational fluid dynamic method.
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650		6	\|a Méthodes de Boltzmann sur réseau.
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contents	Ch. 1. Introduction. 1.1. Description of fluid system at different scales. 1.2. Numerical methods for fluid flows. 1.3. History of LBE. 1.4. Basic models of LBE. 1.5. Summary -- ch. 2. Initial and boundary conditions for lattice Boltzmann method. 2.1. Initial conditions. 2.2. Boundary conditions for flat walls. 2.3. Boundary conditions for curved walls. 2.4. Pressure boundary conditions. 2.5. Summary -- ch. 3. Improved lattice Boltzmann models. 3.1. Incompressible models. 3.2. Forcing schemes with reduced discrete lattice effects. 3.3. LBE with nonuniform grids. 3.4. Accelerated LBE methods for steady flows. 3.5. Summary -- ch. 4. Sample applications of LBE for isothermal flows. 4.1. Algorithm structure of LBE. 4.2. Lid-driven cavity flow. 4.3. Flow around a fixed circular cylinder. 4.4. Flow around an oscillating circular cylinder with a fixed downstream one. 4.5. Summary -- ch. 5. LBE for low speed flows with heat transfer. 5.1. Multi-speed models. 5.2. MS-LBE models based on Boltzmann equation. 5.3. Off-lattice LBE models. 5.4. MS-LBE models with adjustable Prandtl number. 5.5. DDF-LBE models without viscous dissipation and compression work. 5.6. DDF-LBE with viscous dissipation and compression work -- internal energy formulation. 5.7. DDF-LBE with viscous dissipation and compression work -- total energy formulation. 5.8. Hybrid LBE models. 5.9. Summary -- ch. 6. LBE for compressible flows. 6.1. Limitation of conventional LBE models for compressible flows. 6.2. Conventional equilibrium function-based LBE models for compressible flows. 6.3. Circular function-based LBE models for compressible flows. 6.4. Delta function-based LBE models for compressible flows. 6.5. Direct derivation of equilibrium distribution functions from conservation of moments. 6.6. Solution of discrete velocity Boltzmann equation. 6.7. Lattice Boltzmann flux solver for solution of Euler equations. 6.8. Some sample applications. 6.9. Summary -- ch. 7. LBE for multiphase and multi-component flows. 7.1. Color models. 7.2. Pseudo-potential models. 7.3. Free energy models. 7.4. LBE models based on kinetic theories. 7.5. Summary -- ch. 8. LBE for microscale gas flows. 8.1. Introduction. 8.2. Fundamental issues in LBE for micro gaseous flows. 8.3. LBE for slip flows. 8.4. LBE for transition flows. 8.5. LBE for microscale binary mixture flows. 8.6. Summary -- ch. 9. Other applications of LBE. 9.1. Applications of LBE for particulate flows. 9.2. Applications of LBE for flows in porous media. 9.3. Applications of LBE for turbulent flows. 9.4. Immersed boundary-lattice Boltzmann method and its applications. 9.5. Summary.
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Introduction. 1.1. Description of fluid system at different scales. 1.2. Numerical methods for fluid flows. 1.3. History of LBE. 1.4. Basic models of LBE. 1.5. Summary -- ch. 2. Initial and boundary conditions for lattice Boltzmann method. 2.1. Initial conditions. 2.2. Boundary conditions for flat walls. 2.3. Boundary conditions for curved walls. 2.4. Pressure boundary conditions. 2.5. Summary -- ch. 3. Improved lattice Boltzmann models. 3.1. Incompressible models. 3.2. Forcing schemes with reduced discrete lattice effects. 3.3. LBE with nonuniform grids. 3.4. Accelerated LBE methods for steady flows. 3.5. Summary -- ch. 4. Sample applications of LBE for isothermal flows. 4.1. Algorithm structure of LBE. 4.2. Lid-driven cavity flow. 4.3. Flow around a fixed circular cylinder. 4.4. Flow around an oscillating circular cylinder with a fixed downstream one. 4.5. Summary -- ch. 5. LBE for low speed flows with heat transfer. 5.1. Multi-speed models. 5.2. MS-LBE models based on Boltzmann equation. 5.3. Off-lattice LBE models. 5.4. MS-LBE models with adjustable Prandtl number. 5.5. DDF-LBE models without viscous dissipation and compression work. 5.6. DDF-LBE with viscous dissipation and compression work -- internal energy formulation. 5.7. DDF-LBE with viscous dissipation and compression work -- total energy formulation. 5.8. Hybrid LBE models. 5.9. Summary -- ch. 6. LBE for compressible flows. 6.1. Limitation of conventional LBE models for compressible flows. 6.2. Conventional equilibrium function-based LBE models for compressible flows. 6.3. Circular function-based LBE models for compressible flows. 6.4. Delta function-based LBE models for compressible flows. 6.5. Direct derivation of equilibrium distribution functions from conservation of moments. 6.6. Solution of discrete velocity Boltzmann equation. 6.7. Lattice Boltzmann flux solver for solution of Euler equations. 6.8. Some sample applications. 6.9. Summary -- ch. 7. LBE for multiphase and multi-component flows. 7.1. Color models. 7.2. Pseudo-potential models. 7.3. Free energy models. 7.4. LBE models based on kinetic theories. 7.5. Summary -- ch. 8. LBE for microscale gas flows. 8.1. Introduction. 8.2. Fundamental issues in LBE for micro gaseous flows. 8.3. LBE for slip flows. 8.4. LBE for transition flows. 8.5. LBE for microscale binary mixture flows. 8.6. Summary -- ch. 9. Other applications of LBE. 9.1. Applications of LBE for particulate flows. 9.2. Applications of LBE for flows in porous media. 9.3. Applications of LBE for turbulent flows. 9.4. Immersed boundary-lattice Boltzmann method and its applications. 9.5. Summary.</subfield></datafield><datafield tag="520" ind1=" " ind2=" "><subfield code="a">Lattice Boltzmann method (LBM) is a relatively new simulation technique for the modeling of complex fluid systems and has attracted interest from researchers in computational physics. 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indexdate	2024-11-27T13:25:21Z
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spelling	Guo, Zhaoli. https://id.oclc.org/worldcat/entity/E39PCjrYxVMBBm799rGygkC6Gb http://id.loc.gov/authorities/names/n2002056229 Lattice Boltzmann method and its applications in engineering / Zhaoli Guo, Chang Shu. Singapore ; Hackensack, N.J. : World Scientific Pub. Co., ©2013. 1 online resource (xiii, 404 pages) : illustrations (some color). text txt rdacontent computer c rdamedia online resource cr rdacarrier data file rda Advances in computational fluid dynamics ; v. 3 Includes bibliographical references (pages 373-396) and index. Ch. 1. Introduction. 1.1. Description of fluid system at different scales. 1.2. Numerical methods for fluid flows. 1.3. History of LBE. 1.4. Basic models of LBE. 1.5. Summary -- ch. 2. Initial and boundary conditions for lattice Boltzmann method. 2.1. Initial conditions. 2.2. Boundary conditions for flat walls. 2.3. Boundary conditions for curved walls. 2.4. Pressure boundary conditions. 2.5. Summary -- ch. 3. Improved lattice Boltzmann models. 3.1. Incompressible models. 3.2. Forcing schemes with reduced discrete lattice effects. 3.3. LBE with nonuniform grids. 3.4. Accelerated LBE methods for steady flows. 3.5. Summary -- ch. 4. Sample applications of LBE for isothermal flows. 4.1. Algorithm structure of LBE. 4.2. Lid-driven cavity flow. 4.3. Flow around a fixed circular cylinder. 4.4. Flow around an oscillating circular cylinder with a fixed downstream one. 4.5. Summary -- ch. 5. LBE for low speed flows with heat transfer. 5.1. Multi-speed models. 5.2. MS-LBE models based on Boltzmann equation. 5.3. Off-lattice LBE models. 5.4. MS-LBE models with adjustable Prandtl number. 5.5. DDF-LBE models without viscous dissipation and compression work. 5.6. DDF-LBE with viscous dissipation and compression work -- internal energy formulation. 5.7. DDF-LBE with viscous dissipation and compression work -- total energy formulation. 5.8. Hybrid LBE models. 5.9. Summary -- ch. 6. LBE for compressible flows. 6.1. Limitation of conventional LBE models for compressible flows. 6.2. Conventional equilibrium function-based LBE models for compressible flows. 6.3. Circular function-based LBE models for compressible flows. 6.4. Delta function-based LBE models for compressible flows. 6.5. Direct derivation of equilibrium distribution functions from conservation of moments. 6.6. Solution of discrete velocity Boltzmann equation. 6.7. Lattice Boltzmann flux solver for solution of Euler equations. 6.8. Some sample applications. 6.9. Summary -- ch. 7. LBE for multiphase and multi-component flows. 7.1. Color models. 7.2. Pseudo-potential models. 7.3. Free energy models. 7.4. LBE models based on kinetic theories. 7.5. Summary -- ch. 8. LBE for microscale gas flows. 8.1. Introduction. 8.2. Fundamental issues in LBE for micro gaseous flows. 8.3. LBE for slip flows. 8.4. LBE for transition flows. 8.5. LBE for microscale binary mixture flows. 8.6. Summary -- ch. 9. Other applications of LBE. 9.1. Applications of LBE for particulate flows. 9.2. Applications of LBE for flows in porous media. 9.3. Applications of LBE for turbulent flows. 9.4. Immersed boundary-lattice Boltzmann method and its applications. 9.5. Summary. Lattice Boltzmann method (LBM) is a relatively new simulation technique for the modeling of complex fluid systems and has attracted interest from researchers in computational physics. Unlike the traditional CFD methods, which solve the conservation equations of macroscopic properties (i.e., mass, momentum, and energy) numerically, LBM models the fluid consisting of fictive particles, and such particles perform consecutive propagation and collision processes over a discrete lattice mesh. This book will cover the fundamental and practical application of LBM. The first part of the book consists of three chapters starting form the theory of LBM, basic models, initial and boundary conditions, theoretical analysis, to improved models. The second part of the book consists of six chapters, address applications of LBM in various aspects of computational fluid dynamic engineering, covering areas, such as thermo-hydrodynamics, compressible flows, multicomponent/multiphase flows, microscale flows, flows in porous media, turbulent flows, and suspensions. With these coverage LBM, the book intended to promote its applications, instead of the traditional computational fluid dynamic method. Print version record. Lattice Boltzmann methods. http://id.loc.gov/authorities/subjects/sh2008008129 Méthodes de Boltzmann sur réseau. SCIENCE Nanoscience. bisacsh Lattice Boltzmann methods fast Shu, Chang, 1962- https://id.oclc.org/worldcat/entity/E39PCjGCvWVx8Jpc944TQXJppq http://id.loc.gov/authorities/names/n99255878 World Scientific (Firm) http://id.loc.gov/authorities/names/no2001005546 has work: Lattice Boltzmann method and its applications in engineering (Text) https://id.oclc.org/worldcat/entity/E39PCG6bB6XCqT4pgtR3vCKcRq https://id.oclc.org/worldcat/ontology/hasWork Print version: Guo, Zhaoli. Lattice Boltzmann method and its applications in engineering. Singapore ; Hackensack, N.J. : World Scientific Pub. Co., ©2013 9789814508292 Advances in computational fluid dynamics ; v. 3. http://id.loc.gov/authorities/names/no2011141214 FWS01 ZDB-4-EBA FWS_PDA_EBA https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=575395 Volltext
spellingShingle	Guo, Zhaoli Lattice Boltzmann method and its applications in engineering / Advances in computational fluid dynamics ; Ch. 1. Introduction. 1.1. Description of fluid system at different scales. 1.2. Numerical methods for fluid flows. 1.3. History of LBE. 1.4. Basic models of LBE. 1.5. Summary -- ch. 2. Initial and boundary conditions for lattice Boltzmann method. 2.1. Initial conditions. 2.2. Boundary conditions for flat walls. 2.3. Boundary conditions for curved walls. 2.4. Pressure boundary conditions. 2.5. Summary -- ch. 3. Improved lattice Boltzmann models. 3.1. Incompressible models. 3.2. Forcing schemes with reduced discrete lattice effects. 3.3. LBE with nonuniform grids. 3.4. Accelerated LBE methods for steady flows. 3.5. Summary -- ch. 4. Sample applications of LBE for isothermal flows. 4.1. Algorithm structure of LBE. 4.2. Lid-driven cavity flow. 4.3. Flow around a fixed circular cylinder. 4.4. Flow around an oscillating circular cylinder with a fixed downstream one. 4.5. Summary -- ch. 5. LBE for low speed flows with heat transfer. 5.1. Multi-speed models. 5.2. MS-LBE models based on Boltzmann equation. 5.3. Off-lattice LBE models. 5.4. MS-LBE models with adjustable Prandtl number. 5.5. DDF-LBE models without viscous dissipation and compression work. 5.6. DDF-LBE with viscous dissipation and compression work -- internal energy formulation. 5.7. DDF-LBE with viscous dissipation and compression work -- total energy formulation. 5.8. Hybrid LBE models. 5.9. Summary -- ch. 6. LBE for compressible flows. 6.1. Limitation of conventional LBE models for compressible flows. 6.2. Conventional equilibrium function-based LBE models for compressible flows. 6.3. Circular function-based LBE models for compressible flows. 6.4. Delta function-based LBE models for compressible flows. 6.5. Direct derivation of equilibrium distribution functions from conservation of moments. 6.6. Solution of discrete velocity Boltzmann equation. 6.7. Lattice Boltzmann flux solver for solution of Euler equations. 6.8. Some sample applications. 6.9. Summary -- ch. 7. LBE for multiphase and multi-component flows. 7.1. Color models. 7.2. Pseudo-potential models. 7.3. Free energy models. 7.4. LBE models based on kinetic theories. 7.5. Summary -- ch. 8. LBE for microscale gas flows. 8.1. Introduction. 8.2. Fundamental issues in LBE for micro gaseous flows. 8.3. LBE for slip flows. 8.4. LBE for transition flows. 8.5. LBE for microscale binary mixture flows. 8.6. Summary -- ch. 9. Other applications of LBE. 9.1. Applications of LBE for particulate flows. 9.2. Applications of LBE for flows in porous media. 9.3. Applications of LBE for turbulent flows. 9.4. Immersed boundary-lattice Boltzmann method and its applications. 9.5. Summary. Lattice Boltzmann methods. http://id.loc.gov/authorities/subjects/sh2008008129 Méthodes de Boltzmann sur réseau. SCIENCE Nanoscience. bisacsh Lattice Boltzmann methods fast
subject_GND	http://id.loc.gov/authorities/subjects/sh2008008129
title	Lattice Boltzmann method and its applications in engineering /
title_auth	Lattice Boltzmann method and its applications in engineering /
title_exact_search	Lattice Boltzmann method and its applications in engineering /
title_full	Lattice Boltzmann method and its applications in engineering / Zhaoli Guo, Chang Shu.
title_fullStr	Lattice Boltzmann method and its applications in engineering / Zhaoli Guo, Chang Shu.
title_full_unstemmed	Lattice Boltzmann method and its applications in engineering / Zhaoli Guo, Chang Shu.
title_short	Lattice Boltzmann method and its applications in engineering /
title_sort	lattice boltzmann method and its applications in engineering
topic	Lattice Boltzmann methods. http://id.loc.gov/authorities/subjects/sh2008008129 Méthodes de Boltzmann sur réseau. SCIENCE Nanoscience. bisacsh Lattice Boltzmann methods fast
topic_facet	Lattice Boltzmann methods. Méthodes de Boltzmann sur réseau. SCIENCE Nanoscience. Lattice Boltzmann methods
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