Verfügbarkeit: Adhesive particle flow :

Adhesive particle flow :: a discrete-element approach /

"A particulate flow is one in which a moving fluid interacts with a large number of discrete solid particles. The category is extraordinarily broad, encompassing everything from suspended dust carried by atmospheric winds to avalanches of debris or snow rolling down a hillside. Widely varying i...

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Bibliographische Detailangaben
Hauptverfasser:	Marshall, Jeffrey S. (Jeffrey Scott), 1961- (VerfasserIn), Li, Shuiqing Q., 1975- (VerfasserIn)
Format:	Elektronisch E-Book
Sprache:	English
Veröffentlicht:	New York : Cambridge University Press, 2014.
Schlagworte:	Granular flow. Adhesion. Discrete element method. Écoulement granulaire. Adhésion (Physique) Méthode des éléments discrets. adhesion. discrete element method. TECHNOLOGY & ENGINEERING > Engineering (General) TECHNOLOGY & ENGINEERING > Reference. Adhesion Discrete element method Granular flow
Online-Zugang:	Volltext
Zusammenfassung:	"A particulate flow is one in which a moving fluid interacts with a large number of discrete solid particles. The category is extraordinarily broad, encompassing everything from suspended dust carried by atmospheric winds to avalanches of debris or snow rolling down a hillside. Widely varying industrial, biological and environmental processes can be interpreted as particulate flows, encompassing areas of study such as sediment transport by stream and coastal flows, aerosol dynamics, colloidal suspensions, fluidized bed reactors, granular flows, slurries, nanoparticle dispersions, etc. There are also many situations where a suspension of biological cells can be interpreted as a particulate fluid, which extends the notion of particulate flow to problems such as blood flow and algal suspensions. Finally, there are many aspects of the methods used to analyze and model particulate flows that can be either directly applied or applied with small modifications to other types of multiphase flows, including droplet dispersions and bubbly flows, assuming that the deformation of the droplets and bubbles is minimal. Despite the many different forms in which we encounter them, there are a number of characteristics that are shared by most particulate flows. Some of these characteristics arise from the interaction of the individual particles with the surrounding fluid. For instance, a particulate flow past a blunt body tends to exert a higher drag force than the body would experience in the fluid with no particles"--
Beschreibung:	1 online resource (xvii, 342 pages)
Bibliographie:	Includes bibliographical references and index.
ISBN:	9781139957724 1139957724 9781139424547 1139424548 9781139958776 1139958771 1139950274 9781139950275 1139961942 9781139961943 1139949225 9781139949224 1139956655 9781139956659 1139959832 9781139959834

Internformat

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049			\|a MAIN
100	1		\|a Marshall, Jeffrey S. \|q (Jeffrey Scott), \|d 1961- \|e author. \|1 https://id.oclc.org/worldcat/entity/E39PCjD7wP8MFKPYcGCpd3mQtq \|0 http://id.loc.gov/authorities/names/n84137305
245	1	0	\|a Adhesive particle flow : \|b a discrete-element approach / \|c Jeffrey S. Marshall, Shuiqing Li.
264		1	\|a New York : \|b Cambridge University Press, \|c 2014.
300			\|a 1 online resource (xvii, 342 pages)
336			\|a text \|b txt \|2 rdacontent
337			\|a computer \|b c \|2 rdamedia
338			\|a online resource \|b cr \|2 rdacarrier
520			\|a "A particulate flow is one in which a moving fluid interacts with a large number of discrete solid particles. The category is extraordinarily broad, encompassing everything from suspended dust carried by atmospheric winds to avalanches of debris or snow rolling down a hillside. Widely varying industrial, biological and environmental processes can be interpreted as particulate flows, encompassing areas of study such as sediment transport by stream and coastal flows, aerosol dynamics, colloidal suspensions, fluidized bed reactors, granular flows, slurries, nanoparticle dispersions, etc. There are also many situations where a suspension of biological cells can be interpreted as a particulate fluid, which extends the notion of particulate flow to problems such as blood flow and algal suspensions. Finally, there are many aspects of the methods used to analyze and model particulate flows that can be either directly applied or applied with small modifications to other types of multiphase flows, including droplet dispersions and bubbly flows, assuming that the deformation of the droplets and bubbles is minimal. Despite the many different forms in which we encounter them, there are a number of characteristics that are shared by most particulate flows. Some of these characteristics arise from the interaction of the individual particles with the surrounding fluid. For instance, a particulate flow past a blunt body tends to exert a higher drag force than the body would experience in the fluid with no particles"-- \|c Provided by publisher
504			\|a Includes bibliographical references and index.
588	0		\|a Print version record.
505	0		\|a Cover; Half title; Title; Copyright; Dedication; Contents; Preface; Acknowledgments; 1 Introduction; 1.1. Adhesive Particle Flow; 1.2. Dimensionless Parameters and Related Simplifications; 1.2.1. Stokes Number; 1.2.2. Density Ratio; 1.2.3. Length Scale Ratios; 1.2.4. Particle Reynolds Number; 1.2.5. Particle Concentration and Mass Loading; 1.2.6. Bagnold Number; 1.2.7. Adhesion Parameter; 1.3. Applications; 1.3.1. Fibrous Filtration Processes; 1.3.2. Extraterrestrial Dust Fouling; 1.3.3. Wet Granular Material; 1.3.4. Blood Flow; 1.3.5. Aerosol Reaction Engineering; References
505	8		\|a 2 Modeling Viewpoints and Approaches2.1. A Question of Scale; 2.2. Macroscale Particle Methods; 2.2.1. Discrete Parcel Method; 2.2.2. Population Balance Method; 2.3. Mesoscale Particle Methods; 2.3.1. Molecular Dynamics; 2.3.2. Brownian Dynamics; 2.3.3. Dissipative Particle Dynamics; 2.3.4. Discrete Element Method; 2.4. Microscale Dynamics of Elastohydrodynamic Particle Collisions; 2.4.1. Microscale Simulations of Elastohydrodynamic Interactions; 2.4.2. Experimental Results for Two-Particle Collisions; 2.4.3. Simplified Models for Restitution Coefficient in a Viscous Fluid; References
505	8		\|a 3 Contact Mechanics without Adhesion3.1. Basic Concepts; 3.2. Hertz Theory: Normal Elastic Force; 3.2.1. Derivation; 3.2.2. Two-Particle Collision; 3.3. Normal Dissipation Force; 3.3.1. Physical Mechanisms; 3.3.2. Models for Solid-Phase Dissipation Force; 3.4. Hysteretic Models for Normal Contact with Plastic Deformation; 3.5. Sliding and Twisting Resistance; 3.5.1. Physical Mechanisms of Sliding and Twisting Resistance; 3.5.2. Sliding Resistance Model; 3.5.3. Twisting Resistance Model; 3.6. Rolling Resistance; 3.6.1. Rolling Velocity; 3.6.2. Physical Mechanism of Rolling Resistance
505	8		\|a 3.6.3. Model for Rolling ResistanceReferences; 4 Contact Mechanics with Adhesion Forces; 4.1. Basic Concepts and the Surface Energy Density; 4.2. Contact Mechanics with van der Waals Force; 4.2.1. Models for Normal Contact Force; DMT Model; JKR Model; M-D Model; 4.2.2 Normal Dissipation Force and Its Validation; 4.2.3. Effect of Adhesion on Sliding and Twisting Resistance; 4.2.4. Effect of Adhesion on Rolling Resistance; 4.3. Electrical Double-Layer Force; 4.3.1. Stern and Diffuse Layers; 4.3.2. Ionic Shielding of Charged Particles; 4.3.3. DLVO Theory; 4.4. Protein Binding
505	8		\|a 4.5. Liquid Bridging Adhesion4.5.1. Capillary Force; 4.5.2. Effect of Roughness on Capillary Cohesion; 4.5.3. Viscous Force; 4.5.4. Rupture Distance; 4.5.5. Capillary Torque on a Rolling Particle; 4.6. Sintering Force; 4.6.1. Sintering Regime Map; 4.6.2. Approximate Sintering Models; 4.6.3. Hysteretic Sintering Contact Model; References; 5 Fluid Forces on Particles; 5.1. Drag Force and Viscous Torque; 5.1.1. Effect of Flow Nonuniformity; 5.1.2. Effect of Fluid Inertia; 5.1.3. Effect of Surface Slip; 5.2. Lift Force; 5.2.1. Saffman Lift Force; 5.2.2. Magnus Lift Force
546			\|a English.
650		0	\|a Granular flow. \|0 http://id.loc.gov/authorities/subjects/sh2013003068
650		0	\|a Adhesion. \|0 http://id.loc.gov/authorities/subjects/sh85000861
650		0	\|a Discrete element method. \|0 http://id.loc.gov/authorities/subjects/sh2013003076
650		6	\|a Écoulement granulaire.
650		6	\|a Adhésion (Physique)
650		6	\|a Méthode des éléments discrets.
650		7	\|a adhesion. \|2 aat
650		7	\|a discrete element method. \|2 aat
650		7	\|a TECHNOLOGY & ENGINEERING \|x Engineering (General) \|2 bisacsh
650		7	\|a TECHNOLOGY & ENGINEERING \|x Reference. \|2 bisacsh
650		7	\|a Adhesion \|2 fast
650		7	\|a Discrete element method \|2 fast
650		7	\|a Granular flow \|2 fast
700	1		\|a Li, Shuiqing Q., \|d 1975- \|e author. \|1 https://id.oclc.org/worldcat/entity/E39PCjqvJTYrm6FrfJdVXtKvtq \|0 http://id.loc.gov/authorities/names/n2013063630
758			\|i has work: \|a Adhesive particle flow (Text) \|1 https://id.oclc.org/worldcat/entity/E39PCGmcfMyf8t7x49JYk9VX3P \|4 https://id.oclc.org/worldcat/ontology/hasWork
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Datensatz im Suchindex

DE-BY-FWS_katkey	ZDB-4-EBA-ocn879202701
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author	Marshall, Jeffrey S. (Jeffrey Scott), 1961- Li, Shuiqing Q., 1975-
author_GND	http://id.loc.gov/authorities/names/n84137305 http://id.loc.gov/authorities/names/n2013063630
author_facet	Marshall, Jeffrey S. (Jeffrey Scott), 1961- Li, Shuiqing Q., 1975-
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collection	ZDB-4-EBA
contents	Cover; Half title; Title; Copyright; Dedication; Contents; Preface; Acknowledgments; 1 Introduction; 1.1. Adhesive Particle Flow; 1.2. Dimensionless Parameters and Related Simplifications; 1.2.1. Stokes Number; 1.2.2. Density Ratio; 1.2.3. Length Scale Ratios; 1.2.4. Particle Reynolds Number; 1.2.5. Particle Concentration and Mass Loading; 1.2.6. Bagnold Number; 1.2.7. Adhesion Parameter; 1.3. Applications; 1.3.1. Fibrous Filtration Processes; 1.3.2. Extraterrestrial Dust Fouling; 1.3.3. Wet Granular Material; 1.3.4. Blood Flow; 1.3.5. Aerosol Reaction Engineering; References 2 Modeling Viewpoints and Approaches2.1. A Question of Scale; 2.2. Macroscale Particle Methods; 2.2.1. Discrete Parcel Method; 2.2.2. Population Balance Method; 2.3. Mesoscale Particle Methods; 2.3.1. Molecular Dynamics; 2.3.2. Brownian Dynamics; 2.3.3. Dissipative Particle Dynamics; 2.3.4. Discrete Element Method; 2.4. Microscale Dynamics of Elastohydrodynamic Particle Collisions; 2.4.1. Microscale Simulations of Elastohydrodynamic Interactions; 2.4.2. Experimental Results for Two-Particle Collisions; 2.4.3. Simplified Models for Restitution Coefficient in a Viscous Fluid; References 3 Contact Mechanics without Adhesion3.1. Basic Concepts; 3.2. Hertz Theory: Normal Elastic Force; 3.2.1. Derivation; 3.2.2. Two-Particle Collision; 3.3. Normal Dissipation Force; 3.3.1. Physical Mechanisms; 3.3.2. Models for Solid-Phase Dissipation Force; 3.4. Hysteretic Models for Normal Contact with Plastic Deformation; 3.5. Sliding and Twisting Resistance; 3.5.1. Physical Mechanisms of Sliding and Twisting Resistance; 3.5.2. Sliding Resistance Model; 3.5.3. Twisting Resistance Model; 3.6. Rolling Resistance; 3.6.1. Rolling Velocity; 3.6.2. Physical Mechanism of Rolling Resistance 3.6.3. Model for Rolling ResistanceReferences; 4 Contact Mechanics with Adhesion Forces; 4.1. Basic Concepts and the Surface Energy Density; 4.2. Contact Mechanics with van der Waals Force; 4.2.1. Models for Normal Contact Force; DMT Model; JKR Model; M-D Model; 4.2.2 Normal Dissipation Force and Its Validation; 4.2.3. Effect of Adhesion on Sliding and Twisting Resistance; 4.2.4. Effect of Adhesion on Rolling Resistance; 4.3. Electrical Double-Layer Force; 4.3.1. Stern and Diffuse Layers; 4.3.2. Ionic Shielding of Charged Particles; 4.3.3. DLVO Theory; 4.4. Protein Binding 4.5. Liquid Bridging Adhesion4.5.1. Capillary Force; 4.5.2. Effect of Roughness on Capillary Cohesion; 4.5.3. Viscous Force; 4.5.4. Rupture Distance; 4.5.5. Capillary Torque on a Rolling Particle; 4.6. Sintering Force; 4.6.1. Sintering Regime Map; 4.6.2. Approximate Sintering Models; 4.6.3. Hysteretic Sintering Contact Model; References; 5 Fluid Forces on Particles; 5.1. Drag Force and Viscous Torque; 5.1.1. Effect of Flow Nonuniformity; 5.1.2. Effect of Fluid Inertia; 5.1.3. Effect of Surface Slip; 5.2. Lift Force; 5.2.1. Saffman Lift Force; 5.2.2. Magnus Lift Force
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Marshall, Shuiqing Li.</subfield></datafield><datafield tag="264" ind1=" " ind2="1"><subfield code="a">New York :</subfield><subfield code="b">Cambridge University Press,</subfield><subfield code="c">2014.</subfield></datafield><datafield tag="300" ind1=" " ind2=" "><subfield code="a">1 online resource (xvii, 342 pages)</subfield></datafield><datafield tag="336" ind1=" " ind2=" "><subfield code="a">text</subfield><subfield code="b">txt</subfield><subfield code="2">rdacontent</subfield></datafield><datafield tag="337" ind1=" " ind2=" "><subfield code="a">computer</subfield><subfield code="b">c</subfield><subfield code="2">rdamedia</subfield></datafield><datafield tag="338" ind1=" " ind2=" "><subfield code="a">online resource</subfield><subfield code="b">cr</subfield><subfield code="2">rdacarrier</subfield></datafield><datafield tag="520" ind1=" " ind2=" "><subfield code="a">"A particulate flow is one in which a moving fluid interacts with a large number of discrete solid particles. 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Finally, there are many aspects of the methods used to analyze and model particulate flows that can be either directly applied or applied with small modifications to other types of multiphase flows, including droplet dispersions and bubbly flows, assuming that the deformation of the droplets and bubbles is minimal. Despite the many different forms in which we encounter them, there are a number of characteristics that are shared by most particulate flows. Some of these characteristics arise from the interaction of the individual particles with the surrounding fluid. For instance, a particulate flow past a blunt body tends to exert a higher drag force than the body would experience in the fluid with no particles"--</subfield><subfield code="c">Provided by publisher</subfield></datafield><datafield tag="504" ind1=" " ind2=" "><subfield code="a">Includes bibliographical references and index.</subfield></datafield><datafield tag="588" ind1="0" ind2=" "><subfield code="a">Print version record.</subfield></datafield><datafield tag="505" ind1="0" ind2=" "><subfield code="a">Cover; Half title; Title; Copyright; Dedication; Contents; Preface; Acknowledgments; 1 Introduction; 1.1. Adhesive Particle Flow; 1.2. Dimensionless Parameters and Related Simplifications; 1.2.1. Stokes Number; 1.2.2. Density Ratio; 1.2.3. Length Scale Ratios; 1.2.4. Particle Reynolds Number; 1.2.5. Particle Concentration and Mass Loading; 1.2.6. Bagnold Number; 1.2.7. Adhesion Parameter; 1.3. Applications; 1.3.1. Fibrous Filtration Processes; 1.3.2. Extraterrestrial Dust Fouling; 1.3.3. Wet Granular Material; 1.3.4. Blood Flow; 1.3.5. Aerosol Reaction Engineering; References</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">2 Modeling Viewpoints and Approaches2.1. A Question of Scale; 2.2. Macroscale Particle Methods; 2.2.1. Discrete Parcel Method; 2.2.2. Population Balance Method; 2.3. Mesoscale Particle Methods; 2.3.1. Molecular Dynamics; 2.3.2. Brownian Dynamics; 2.3.3. Dissipative Particle Dynamics; 2.3.4. Discrete Element Method; 2.4. Microscale Dynamics of Elastohydrodynamic Particle Collisions; 2.4.1. Microscale Simulations of Elastohydrodynamic Interactions; 2.4.2. Experimental Results for Two-Particle Collisions; 2.4.3. Simplified Models for Restitution Coefficient in a Viscous Fluid; References</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">3 Contact Mechanics without Adhesion3.1. Basic Concepts; 3.2. Hertz Theory: Normal Elastic Force; 3.2.1. Derivation; 3.2.2. Two-Particle Collision; 3.3. Normal Dissipation Force; 3.3.1. Physical Mechanisms; 3.3.2. Models for Solid-Phase Dissipation Force; 3.4. Hysteretic Models for Normal Contact with Plastic Deformation; 3.5. Sliding and Twisting Resistance; 3.5.1. Physical Mechanisms of Sliding and Twisting Resistance; 3.5.2. Sliding Resistance Model; 3.5.3. Twisting Resistance Model; 3.6. Rolling Resistance; 3.6.1. Rolling Velocity; 3.6.2. Physical Mechanism of Rolling Resistance</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">3.6.3. Model for Rolling ResistanceReferences; 4 Contact Mechanics with Adhesion Forces; 4.1. Basic Concepts and the Surface Energy Density; 4.2. Contact Mechanics with van der Waals Force; 4.2.1. Models for Normal Contact Force; DMT Model; JKR Model; M-D Model; 4.2.2 Normal Dissipation Force and Its Validation; 4.2.3. Effect of Adhesion on Sliding and Twisting Resistance; 4.2.4. Effect of Adhesion on Rolling Resistance; 4.3. Electrical Double-Layer Force; 4.3.1. Stern and Diffuse Layers; 4.3.2. Ionic Shielding of Charged Particles; 4.3.3. DLVO Theory; 4.4. Protein Binding</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">4.5. Liquid Bridging Adhesion4.5.1. Capillary Force; 4.5.2. Effect of Roughness on Capillary Cohesion; 4.5.3. Viscous Force; 4.5.4. Rupture Distance; 4.5.5. Capillary Torque on a Rolling Particle; 4.6. Sintering Force; 4.6.1. Sintering Regime Map; 4.6.2. Approximate Sintering Models; 4.6.3. Hysteretic Sintering Contact Model; References; 5 Fluid Forces on Particles; 5.1. Drag Force and Viscous Torque; 5.1.1. Effect of Flow Nonuniformity; 5.1.2. Effect of Fluid Inertia; 5.1.3. Effect of Surface Slip; 5.2. Lift Force; 5.2.1. Saffman Lift Force; 5.2.2. Magnus Lift Force</subfield></datafield><datafield tag="546" ind1=" " ind2=" "><subfield code="a">English.</subfield></datafield><datafield tag="650" ind1=" " ind2="0"><subfield code="a">Granular flow.</subfield><subfield code="0">http://id.loc.gov/authorities/subjects/sh2013003068</subfield></datafield><datafield tag="650" ind1=" " ind2="0"><subfield code="a">Adhesion.</subfield><subfield code="0">http://id.loc.gov/authorities/subjects/sh85000861</subfield></datafield><datafield tag="650" ind1=" " ind2="0"><subfield code="a">Discrete element method.</subfield><subfield code="0">http://id.loc.gov/authorities/subjects/sh2013003076</subfield></datafield><datafield tag="650" ind1=" " ind2="6"><subfield code="a">Écoulement granulaire.</subfield></datafield><datafield tag="650" ind1=" " ind2="6"><subfield code="a">Adhésion (Physique)</subfield></datafield><datafield tag="650" ind1=" " ind2="6"><subfield code="a">Méthode des éléments discrets.</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">adhesion.</subfield><subfield code="2">aat</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">discrete element method.</subfield><subfield code="2">aat</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">TECHNOLOGY & ENGINEERING</subfield><subfield code="x">Engineering (General)</subfield><subfield code="2">bisacsh</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">TECHNOLOGY & ENGINEERING</subfield><subfield code="x">Reference.</subfield><subfield code="2">bisacsh</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">Adhesion</subfield><subfield code="2">fast</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">Discrete element method</subfield><subfield code="2">fast</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">Granular flow</subfield><subfield code="2">fast</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Li, Shuiqing Q.,</subfield><subfield code="d">1975-</subfield><subfield code="e">author.</subfield><subfield code="1">https://id.oclc.org/worldcat/entity/E39PCjqvJTYrm6FrfJdVXtKvtq</subfield><subfield code="0">http://id.loc.gov/authorities/names/n2013063630</subfield></datafield><datafield tag="758" ind1=" " ind2=" "><subfield code="i">has work:</subfield><subfield code="a">Adhesive particle flow (Text)</subfield><subfield code="1">https://id.oclc.org/worldcat/entity/E39PCGmcfMyf8t7x49JYk9VX3P</subfield><subfield code="4">https://id.oclc.org/worldcat/ontology/hasWork</subfield></datafield><datafield tag="776" ind1="0" ind2="8"><subfield code="i">Print version:</subfield><subfield code="a">Marshall, Jeffrey S. 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id	ZDB-4-EBA-ocn879202701
illustrated	Illustrated
indexdate	2024-11-27T13:25:57Z
institution	BVB
isbn	9781139957724 1139957724 9781139424547 1139424548 9781139958776 1139958771 1139950274 9781139950275 1139961942 9781139961943 1139949225 9781139949224 1139956655 9781139956659 1139959832 9781139959834
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physical	1 online resource (xvii, 342 pages)
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publisher	Cambridge University Press,
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spelling	Marshall, Jeffrey S. (Jeffrey Scott), 1961- author. https://id.oclc.org/worldcat/entity/E39PCjD7wP8MFKPYcGCpd3mQtq http://id.loc.gov/authorities/names/n84137305 Adhesive particle flow : a discrete-element approach / Jeffrey S. Marshall, Shuiqing Li. New York : Cambridge University Press, 2014. 1 online resource (xvii, 342 pages) text txt rdacontent computer c rdamedia online resource cr rdacarrier "A particulate flow is one in which a moving fluid interacts with a large number of discrete solid particles. The category is extraordinarily broad, encompassing everything from suspended dust carried by atmospheric winds to avalanches of debris or snow rolling down a hillside. Widely varying industrial, biological and environmental processes can be interpreted as particulate flows, encompassing areas of study such as sediment transport by stream and coastal flows, aerosol dynamics, colloidal suspensions, fluidized bed reactors, granular flows, slurries, nanoparticle dispersions, etc. There are also many situations where a suspension of biological cells can be interpreted as a particulate fluid, which extends the notion of particulate flow to problems such as blood flow and algal suspensions. Finally, there are many aspects of the methods used to analyze and model particulate flows that can be either directly applied or applied with small modifications to other types of multiphase flows, including droplet dispersions and bubbly flows, assuming that the deformation of the droplets and bubbles is minimal. Despite the many different forms in which we encounter them, there are a number of characteristics that are shared by most particulate flows. Some of these characteristics arise from the interaction of the individual particles with the surrounding fluid. For instance, a particulate flow past a blunt body tends to exert a higher drag force than the body would experience in the fluid with no particles"-- Provided by publisher Includes bibliographical references and index. Print version record. Cover; Half title; Title; Copyright; Dedication; Contents; Preface; Acknowledgments; 1 Introduction; 1.1. Adhesive Particle Flow; 1.2. Dimensionless Parameters and Related Simplifications; 1.2.1. Stokes Number; 1.2.2. Density Ratio; 1.2.3. Length Scale Ratios; 1.2.4. Particle Reynolds Number; 1.2.5. Particle Concentration and Mass Loading; 1.2.6. Bagnold Number; 1.2.7. Adhesion Parameter; 1.3. Applications; 1.3.1. Fibrous Filtration Processes; 1.3.2. Extraterrestrial Dust Fouling; 1.3.3. Wet Granular Material; 1.3.4. Blood Flow; 1.3.5. Aerosol Reaction Engineering; References 2 Modeling Viewpoints and Approaches2.1. A Question of Scale; 2.2. Macroscale Particle Methods; 2.2.1. Discrete Parcel Method; 2.2.2. Population Balance Method; 2.3. Mesoscale Particle Methods; 2.3.1. Molecular Dynamics; 2.3.2. Brownian Dynamics; 2.3.3. Dissipative Particle Dynamics; 2.3.4. Discrete Element Method; 2.4. Microscale Dynamics of Elastohydrodynamic Particle Collisions; 2.4.1. Microscale Simulations of Elastohydrodynamic Interactions; 2.4.2. Experimental Results for Two-Particle Collisions; 2.4.3. Simplified Models for Restitution Coefficient in a Viscous Fluid; References 3 Contact Mechanics without Adhesion3.1. Basic Concepts; 3.2. Hertz Theory: Normal Elastic Force; 3.2.1. Derivation; 3.2.2. Two-Particle Collision; 3.3. Normal Dissipation Force; 3.3.1. Physical Mechanisms; 3.3.2. Models for Solid-Phase Dissipation Force; 3.4. Hysteretic Models for Normal Contact with Plastic Deformation; 3.5. Sliding and Twisting Resistance; 3.5.1. Physical Mechanisms of Sliding and Twisting Resistance; 3.5.2. Sliding Resistance Model; 3.5.3. Twisting Resistance Model; 3.6. Rolling Resistance; 3.6.1. Rolling Velocity; 3.6.2. Physical Mechanism of Rolling Resistance 3.6.3. Model for Rolling ResistanceReferences; 4 Contact Mechanics with Adhesion Forces; 4.1. Basic Concepts and the Surface Energy Density; 4.2. Contact Mechanics with van der Waals Force; 4.2.1. Models for Normal Contact Force; DMT Model; JKR Model; M-D Model; 4.2.2 Normal Dissipation Force and Its Validation; 4.2.3. Effect of Adhesion on Sliding and Twisting Resistance; 4.2.4. Effect of Adhesion on Rolling Resistance; 4.3. Electrical Double-Layer Force; 4.3.1. Stern and Diffuse Layers; 4.3.2. Ionic Shielding of Charged Particles; 4.3.3. DLVO Theory; 4.4. Protein Binding 4.5. Liquid Bridging Adhesion4.5.1. Capillary Force; 4.5.2. Effect of Roughness on Capillary Cohesion; 4.5.3. Viscous Force; 4.5.4. Rupture Distance; 4.5.5. Capillary Torque on a Rolling Particle; 4.6. Sintering Force; 4.6.1. Sintering Regime Map; 4.6.2. Approximate Sintering Models; 4.6.3. Hysteretic Sintering Contact Model; References; 5 Fluid Forces on Particles; 5.1. Drag Force and Viscous Torque; 5.1.1. Effect of Flow Nonuniformity; 5.1.2. Effect of Fluid Inertia; 5.1.3. Effect of Surface Slip; 5.2. Lift Force; 5.2.1. Saffman Lift Force; 5.2.2. Magnus Lift Force English. Granular flow. http://id.loc.gov/authorities/subjects/sh2013003068 Adhesion. http://id.loc.gov/authorities/subjects/sh85000861 Discrete element method. http://id.loc.gov/authorities/subjects/sh2013003076 Écoulement granulaire. Adhésion (Physique) Méthode des éléments discrets. adhesion. aat discrete element method. aat TECHNOLOGY & ENGINEERING Engineering (General) bisacsh TECHNOLOGY & ENGINEERING Reference. bisacsh Adhesion fast Discrete element method fast Granular flow fast Li, Shuiqing Q., 1975- author. https://id.oclc.org/worldcat/entity/E39PCjqvJTYrm6FrfJdVXtKvtq http://id.loc.gov/authorities/names/n2013063630 has work: Adhesive particle flow (Text) https://id.oclc.org/worldcat/entity/E39PCGmcfMyf8t7x49JYk9VX3P https://id.oclc.org/worldcat/ontology/hasWork Print version: Marshall, Jeffrey S. (Jeffrey Scott), 1961- Adhesive particle flow 9781107032071 (DLC) 2013040678 (OCoLC)863801613 FWS01 ZDB-4-EBA FWS_PDA_EBA https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=761484 Volltext
spellingShingle	Marshall, Jeffrey S. (Jeffrey Scott), 1961- Li, Shuiqing Q., 1975- Adhesive particle flow : a discrete-element approach / Cover; Half title; Title; Copyright; Dedication; Contents; Preface; Acknowledgments; 1 Introduction; 1.1. Adhesive Particle Flow; 1.2. Dimensionless Parameters and Related Simplifications; 1.2.1. Stokes Number; 1.2.2. Density Ratio; 1.2.3. Length Scale Ratios; 1.2.4. Particle Reynolds Number; 1.2.5. Particle Concentration and Mass Loading; 1.2.6. Bagnold Number; 1.2.7. Adhesion Parameter; 1.3. Applications; 1.3.1. Fibrous Filtration Processes; 1.3.2. Extraterrestrial Dust Fouling; 1.3.3. Wet Granular Material; 1.3.4. Blood Flow; 1.3.5. Aerosol Reaction Engineering; References 2 Modeling Viewpoints and Approaches2.1. A Question of Scale; 2.2. Macroscale Particle Methods; 2.2.1. Discrete Parcel Method; 2.2.2. Population Balance Method; 2.3. Mesoscale Particle Methods; 2.3.1. Molecular Dynamics; 2.3.2. Brownian Dynamics; 2.3.3. Dissipative Particle Dynamics; 2.3.4. Discrete Element Method; 2.4. Microscale Dynamics of Elastohydrodynamic Particle Collisions; 2.4.1. Microscale Simulations of Elastohydrodynamic Interactions; 2.4.2. Experimental Results for Two-Particle Collisions; 2.4.3. Simplified Models for Restitution Coefficient in a Viscous Fluid; References 3 Contact Mechanics without Adhesion3.1. Basic Concepts; 3.2. Hertz Theory: Normal Elastic Force; 3.2.1. Derivation; 3.2.2. Two-Particle Collision; 3.3. Normal Dissipation Force; 3.3.1. Physical Mechanisms; 3.3.2. Models for Solid-Phase Dissipation Force; 3.4. Hysteretic Models for Normal Contact with Plastic Deformation; 3.5. Sliding and Twisting Resistance; 3.5.1. Physical Mechanisms of Sliding and Twisting Resistance; 3.5.2. Sliding Resistance Model; 3.5.3. Twisting Resistance Model; 3.6. Rolling Resistance; 3.6.1. Rolling Velocity; 3.6.2. Physical Mechanism of Rolling Resistance 3.6.3. Model for Rolling ResistanceReferences; 4 Contact Mechanics with Adhesion Forces; 4.1. Basic Concepts and the Surface Energy Density; 4.2. Contact Mechanics with van der Waals Force; 4.2.1. Models for Normal Contact Force; DMT Model; JKR Model; M-D Model; 4.2.2 Normal Dissipation Force and Its Validation; 4.2.3. Effect of Adhesion on Sliding and Twisting Resistance; 4.2.4. Effect of Adhesion on Rolling Resistance; 4.3. Electrical Double-Layer Force; 4.3.1. Stern and Diffuse Layers; 4.3.2. Ionic Shielding of Charged Particles; 4.3.3. DLVO Theory; 4.4. Protein Binding 4.5. Liquid Bridging Adhesion4.5.1. Capillary Force; 4.5.2. Effect of Roughness on Capillary Cohesion; 4.5.3. Viscous Force; 4.5.4. Rupture Distance; 4.5.5. Capillary Torque on a Rolling Particle; 4.6. Sintering Force; 4.6.1. Sintering Regime Map; 4.6.2. Approximate Sintering Models; 4.6.3. Hysteretic Sintering Contact Model; References; 5 Fluid Forces on Particles; 5.1. Drag Force and Viscous Torque; 5.1.1. Effect of Flow Nonuniformity; 5.1.2. Effect of Fluid Inertia; 5.1.3. Effect of Surface Slip; 5.2. Lift Force; 5.2.1. Saffman Lift Force; 5.2.2. Magnus Lift Force Granular flow. http://id.loc.gov/authorities/subjects/sh2013003068 Adhesion. http://id.loc.gov/authorities/subjects/sh85000861 Discrete element method. http://id.loc.gov/authorities/subjects/sh2013003076 Écoulement granulaire. Adhésion (Physique) Méthode des éléments discrets. adhesion. aat discrete element method. aat TECHNOLOGY & ENGINEERING Engineering (General) bisacsh TECHNOLOGY & ENGINEERING Reference. bisacsh Adhesion fast Discrete element method fast Granular flow fast
subject_GND	http://id.loc.gov/authorities/subjects/sh2013003068 http://id.loc.gov/authorities/subjects/sh85000861 http://id.loc.gov/authorities/subjects/sh2013003076
title	Adhesive particle flow : a discrete-element approach /
title_auth	Adhesive particle flow : a discrete-element approach /
title_exact_search	Adhesive particle flow : a discrete-element approach /
title_full	Adhesive particle flow : a discrete-element approach / Jeffrey S. Marshall, Shuiqing Li.
title_fullStr	Adhesive particle flow : a discrete-element approach / Jeffrey S. Marshall, Shuiqing Li.
title_full_unstemmed	Adhesive particle flow : a discrete-element approach / Jeffrey S. Marshall, Shuiqing Li.
title_short	Adhesive particle flow :
title_sort	adhesive particle flow a discrete element approach
title_sub	a discrete-element approach /
topic	Granular flow. http://id.loc.gov/authorities/subjects/sh2013003068 Adhesion. http://id.loc.gov/authorities/subjects/sh85000861 Discrete element method. http://id.loc.gov/authorities/subjects/sh2013003076 Écoulement granulaire. Adhésion (Physique) Méthode des éléments discrets. adhesion. aat discrete element method. aat TECHNOLOGY & ENGINEERING Engineering (General) bisacsh TECHNOLOGY & ENGINEERING Reference. bisacsh Adhesion fast Discrete element method fast Granular flow fast
topic_facet	Granular flow. Adhesion. Discrete element method. Écoulement granulaire. Adhésion (Physique) Méthode des éléments discrets. adhesion. discrete element method. TECHNOLOGY & ENGINEERING Engineering (General) TECHNOLOGY & ENGINEERING Reference. Adhesion Discrete element method Granular flow
url	https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=761484
work_keys_str_mv	AT marshalljeffreys adhesiveparticleflowadiscreteelementapproach AT lishuiqingq adhesiveparticleflowadiscreteelementapproach

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