Mesoscale Analysis of Hydraulics.

Mesoscale Analysis of Hydraulics.

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Xu, Weilin.
Place / Publishing House:Singapore : : Springer Singapore Pte. Limited,, 2020.
©2021.
Year of Publication:2020
Edition:1st ed.
Language:English
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spelling Xu, Weilin.
Mesoscale Analysis of Hydraulics.
1st ed.
Singapore : Springer Singapore Pte. Limited, 2020.
©2021.
1 online resource (253 pages)
text txt rdacontent
computer c rdamedia
online resource cr rdacarrier
Intro -- Foreword I -- Foreword II -- Acknowledgments -- Contents -- About the Author -- List of Main Symbols -- List of Main Acronyms -- 1 Introduction -- 1.1 Definition of Mesoscale -- 1.2 Necessity of Mesoscale Research -- 1.3 Main Contents of Mesoscale Research -- References -- 2 Mesoscale Analysis of Cavitation and Cavitation Erosion -- 2.1 Background -- 2.2 Interactions Between Cavitation Bubbles and Rigid Boundaries -- 2.2.1 Shock Waves and Microjets Generated from the Collapse of CBs -- 2.2.2 Effects of the Geometric Shape of a Boundary on the Collapse Behavior of a CB -- 2.3 Interactions Between Cavitation Bubbles and Elastic Boundaries -- 2.3.1 Morphology of CBs Near Elastic Boundaries During the Collapsing Process -- 2.3.2 Shock Waves Generated by CBs Near Elastic Boundaries When Collapsing -- 2.3.3 Cavitation Erosion Resistance of Elastic Materials -- 2.4 Interactions Between Cavitation Bubbles -- 2.4.1 Interactions Between Two CBs -- 2.4.2 Interactions Between Multiple CBs -- 2.5 Interactions Between Cavitation Bubbles and Particles -- 2.5.1 Effects of Particles on the Collapse Directions of CBs -- 2.5.2 Effects of a Particle on the Shock Wave Generated by a CB When Collapsing -- 2.5.3 Effects of Particles on Cavitation Erosion -- 2.6 Collapse Locations of Cavitation Bubbles and Cavitation Erosion Control in Engineering Practice -- 2.6.1 Collapse Location Distribution Pattern of CBs in a Flow Past a Convex Body -- 2.6.2 Relationship of the Collapse Locations of CBs in a Flow Past a Convex Body with the Flow Field -- 2.6.3 Critical Conditions Required for Near-Boundary Collapse of CBs in a Flow Past a Convex Body -- 2.7 Conclusions -- References -- 3 Mesoscale Analysis of Aeration for Cavitation Erosion Protection -- 3.1 Background -- 3.2 Attenuation Effect of Air Bubbles on the Collapse Intensity of Cavitation Bubbles.
3.2.1 Intensity of the Collapse Noise of a Cavitation Bubble Interacting But Not Connected with Air Bubbles -- 3.2.2 Intensity of the Collapse Noise of a Cavitation Bubble Interacting and Connected with an Air Bubble -- 3.3 Direction-Changing Effect of an Air Bubble on the Collapse of a Cavitation Bubble -- 3.3.1 Direction-Changing Effect of an Air Bubble on the Collapse of a Cavitation Bubble -- 3.3.2 Direction-Changing Effect of an Air Bubble on a Cavitation Bubble Evolving Near a Wall -- 3.3.3 Combined Direction-Changing Effects of a Wall and an Air Bubble on the Collapse of a Cavitation Bubble -- 3.4 Retarding Effect of an Air Bubble on the Collapse Shock Wave of a Cavitation Bubble -- 3.4.1 Retarding Effect of an Air Bubble on the Collapse Shock Wave of a Cavitation Bubble -- 3.4.2 Impact Intensity of the Collapse Shock Wave of a Cavitation Bubble Interacting with an Air Bubble Near a Wall -- 3.5 Forced Aeration for Cavitation Erosion Protection of High-Head Dams -- 3.5.1 Mesoscale Mechanism of Forced Aeration -- 3.5.2 Design Principles of Forced-Aeration for Cavitation Erosion Protection Structures of High-Head Dams -- 3.6 Conclusions -- References -- 4 Mesoscale Analysis of Air-Water Two-Phase Flow -- 4.1 Background -- 4.2 Mesoscale Mechanism for Surface Aeration of High-Velocity Flows -- 4.2.1 Mesoscale Characteristics of the Free-Surface Shape of Flows -- 4.2.2 Mesoscale Free-Surface Aeration Process of Flows -- 4.2.3 Quantitative Analysis of the Free-Surface Aeration of Flows -- 4.3 Critical Condition for Surface Aeration of High-Velocity Flows -- 4.3.1 Critical Condition for Air Entrainment of Free-Surface Depressions in Flows -- 4.3.2 Air-Bubble Entrainment Characteristics of Free-Surface Depressions in Flows -- 4.3.3 Comparison of Calculated and Experimental Results.
4.4 Calculation of Concentration Distribution for Surface Aeration of High-Velocity Flows -- 4.4.1 Regional Characteristics of Surface Aeration in High-Velocity Flows -- 4.4.2 Comparison of the Calculated and Measured Values of the Ca Distribution in High-Velocity Aerated Flows -- 4.4.3 Diffusion Pattern of Ca Along the Course -- 4.5 Analysis of Depth and Concentration of Aerated Flows in Engineering Practice -- 4.5.1 Analysis of Self-Aerated Open-Channel Flows in Terms of Hm -- 4.5.2 Analysis of the Aerated Flow in the Spillway of the Jinping-I Hydropower Station -- 4.6 Conclusions -- References -- 5 Mesoscale Analysis of Flood Discharge and Energy Dissipation -- 5.1 Background -- 5.2 Vortex Structure of a Single Jet -- 5.2.1 Velocity Field Characteristics of a Single Jet -- 5.2.2 Vorticity Field Characteristics of a Single Jet -- 5.3 Vortex Structure with Multijets -- 5.3.1 Transverse Vortices -- 5.3.2 Vertical Vortices -- 5.4 Vortex Structure of a Pressure Flow with a Sudden Contraction -- 5.4.1 Flow Field Characteristics of a Pressure Flow with a Sudden Contraction -- 5.4.2 Vortex Blob Characteristics of a Pressure Flow with a Sudden Contraction -- 5.5 Application of Multihorizontal Submerged Jets in Engineering Project -- 5.5.1 Overview of the Project -- 5.5.2 Characteristics of the Flood Discharge and Energy Dissipation -- 5.6 Conclusions -- References -- 6 Mesoscale Analysis of Flood Discharge Atomization -- 6.1 Background -- 6.2 Jet Spallation in Air -- 6.2.1 Velocity Distribution of Jet-Spalled Water Droplets -- 6.2.2 Distribution of the Moving Directions of the Water Droplets Formed by Jet Spallation -- 6.3 Jet Collision in Air -- 6.3.1 Characteristics of the Water Droplets Formed by a Jet Collision in Air -- 6.3.2 Effects of the Flow-Rate Ratio on the Characteristics of the Water Droplets Formed by a Jet Collision.
6.3.3 Spallation Area of Jets After Collision in Air -- 6.4 Water Splash by Plunging Jets -- 6.4.1 Characteristics of the Water Droplets Splashed by a Jet -- 6.4.2 Motion Pattern of the Water Droplets Formed by the Splashing of Water with a High-Velocity Plunging Jet -- 6.5 Discussion of the Scale Effect in Flood Discharge Atomization Model Tests for High-Head Dams -- 6.5.1 Similarity Criterion for FDA Model Tests -- 6.5.2 Scale Effect in FDA Model Tests -- 6.6 Conclusions -- References -- 7 Mesoscale Analysis of Flash Flood and Sediment Disasters -- 7.1 Background -- 7.2 Sudden Stop and Accumulation of Sediment Particles After a Hydraulic Jump -- 7.3 Threshold Conditions for Combined Flash Flood and Sediment Disasters -- 7.4 Identification of Disaster-Prone Regions Based on the Threshold Conditions for Combined Flash Flood and Sediment Disasters -- 7.5 Analysis of Control Techniques Based on the Threshold Conditions for Combined Flash Flood and Sediment Disasters -- 7.6 Conclusions -- References.
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Print version: Xu, Weilin Mesoscale Analysis of Hydraulics Singapore : Springer Singapore Pte. Limited,c2020 9789811597848
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author Xu, Weilin.
spellingShingle Xu, Weilin.
Mesoscale Analysis of Hydraulics.
Intro -- Foreword I -- Foreword II -- Acknowledgments -- Contents -- About the Author -- List of Main Symbols -- List of Main Acronyms -- 1 Introduction -- 1.1 Definition of Mesoscale -- 1.2 Necessity of Mesoscale Research -- 1.3 Main Contents of Mesoscale Research -- References -- 2 Mesoscale Analysis of Cavitation and Cavitation Erosion -- 2.1 Background -- 2.2 Interactions Between Cavitation Bubbles and Rigid Boundaries -- 2.2.1 Shock Waves and Microjets Generated from the Collapse of CBs -- 2.2.2 Effects of the Geometric Shape of a Boundary on the Collapse Behavior of a CB -- 2.3 Interactions Between Cavitation Bubbles and Elastic Boundaries -- 2.3.1 Morphology of CBs Near Elastic Boundaries During the Collapsing Process -- 2.3.2 Shock Waves Generated by CBs Near Elastic Boundaries When Collapsing -- 2.3.3 Cavitation Erosion Resistance of Elastic Materials -- 2.4 Interactions Between Cavitation Bubbles -- 2.4.1 Interactions Between Two CBs -- 2.4.2 Interactions Between Multiple CBs -- 2.5 Interactions Between Cavitation Bubbles and Particles -- 2.5.1 Effects of Particles on the Collapse Directions of CBs -- 2.5.2 Effects of a Particle on the Shock Wave Generated by a CB When Collapsing -- 2.5.3 Effects of Particles on Cavitation Erosion -- 2.6 Collapse Locations of Cavitation Bubbles and Cavitation Erosion Control in Engineering Practice -- 2.6.1 Collapse Location Distribution Pattern of CBs in a Flow Past a Convex Body -- 2.6.2 Relationship of the Collapse Locations of CBs in a Flow Past a Convex Body with the Flow Field -- 2.6.3 Critical Conditions Required for Near-Boundary Collapse of CBs in a Flow Past a Convex Body -- 2.7 Conclusions -- References -- 3 Mesoscale Analysis of Aeration for Cavitation Erosion Protection -- 3.1 Background -- 3.2 Attenuation Effect of Air Bubbles on the Collapse Intensity of Cavitation Bubbles.
3.2.1 Intensity of the Collapse Noise of a Cavitation Bubble Interacting But Not Connected with Air Bubbles -- 3.2.2 Intensity of the Collapse Noise of a Cavitation Bubble Interacting and Connected with an Air Bubble -- 3.3 Direction-Changing Effect of an Air Bubble on the Collapse of a Cavitation Bubble -- 3.3.1 Direction-Changing Effect of an Air Bubble on the Collapse of a Cavitation Bubble -- 3.3.2 Direction-Changing Effect of an Air Bubble on a Cavitation Bubble Evolving Near a Wall -- 3.3.3 Combined Direction-Changing Effects of a Wall and an Air Bubble on the Collapse of a Cavitation Bubble -- 3.4 Retarding Effect of an Air Bubble on the Collapse Shock Wave of a Cavitation Bubble -- 3.4.1 Retarding Effect of an Air Bubble on the Collapse Shock Wave of a Cavitation Bubble -- 3.4.2 Impact Intensity of the Collapse Shock Wave of a Cavitation Bubble Interacting with an Air Bubble Near a Wall -- 3.5 Forced Aeration for Cavitation Erosion Protection of High-Head Dams -- 3.5.1 Mesoscale Mechanism of Forced Aeration -- 3.5.2 Design Principles of Forced-Aeration for Cavitation Erosion Protection Structures of High-Head Dams -- 3.6 Conclusions -- References -- 4 Mesoscale Analysis of Air-Water Two-Phase Flow -- 4.1 Background -- 4.2 Mesoscale Mechanism for Surface Aeration of High-Velocity Flows -- 4.2.1 Mesoscale Characteristics of the Free-Surface Shape of Flows -- 4.2.2 Mesoscale Free-Surface Aeration Process of Flows -- 4.2.3 Quantitative Analysis of the Free-Surface Aeration of Flows -- 4.3 Critical Condition for Surface Aeration of High-Velocity Flows -- 4.3.1 Critical Condition for Air Entrainment of Free-Surface Depressions in Flows -- 4.3.2 Air-Bubble Entrainment Characteristics of Free-Surface Depressions in Flows -- 4.3.3 Comparison of Calculated and Experimental Results.
4.4 Calculation of Concentration Distribution for Surface Aeration of High-Velocity Flows -- 4.4.1 Regional Characteristics of Surface Aeration in High-Velocity Flows -- 4.4.2 Comparison of the Calculated and Measured Values of the Ca Distribution in High-Velocity Aerated Flows -- 4.4.3 Diffusion Pattern of Ca Along the Course -- 4.5 Analysis of Depth and Concentration of Aerated Flows in Engineering Practice -- 4.5.1 Analysis of Self-Aerated Open-Channel Flows in Terms of Hm -- 4.5.2 Analysis of the Aerated Flow in the Spillway of the Jinping-I Hydropower Station -- 4.6 Conclusions -- References -- 5 Mesoscale Analysis of Flood Discharge and Energy Dissipation -- 5.1 Background -- 5.2 Vortex Structure of a Single Jet -- 5.2.1 Velocity Field Characteristics of a Single Jet -- 5.2.2 Vorticity Field Characteristics of a Single Jet -- 5.3 Vortex Structure with Multijets -- 5.3.1 Transverse Vortices -- 5.3.2 Vertical Vortices -- 5.4 Vortex Structure of a Pressure Flow with a Sudden Contraction -- 5.4.1 Flow Field Characteristics of a Pressure Flow with a Sudden Contraction -- 5.4.2 Vortex Blob Characteristics of a Pressure Flow with a Sudden Contraction -- 5.5 Application of Multihorizontal Submerged Jets in Engineering Project -- 5.5.1 Overview of the Project -- 5.5.2 Characteristics of the Flood Discharge and Energy Dissipation -- 5.6 Conclusions -- References -- 6 Mesoscale Analysis of Flood Discharge Atomization -- 6.1 Background -- 6.2 Jet Spallation in Air -- 6.2.1 Velocity Distribution of Jet-Spalled Water Droplets -- 6.2.2 Distribution of the Moving Directions of the Water Droplets Formed by Jet Spallation -- 6.3 Jet Collision in Air -- 6.3.1 Characteristics of the Water Droplets Formed by a Jet Collision in Air -- 6.3.2 Effects of the Flow-Rate Ratio on the Characteristics of the Water Droplets Formed by a Jet Collision.
6.3.3 Spallation Area of Jets After Collision in Air -- 6.4 Water Splash by Plunging Jets -- 6.4.1 Characteristics of the Water Droplets Splashed by a Jet -- 6.4.2 Motion Pattern of the Water Droplets Formed by the Splashing of Water with a High-Velocity Plunging Jet -- 6.5 Discussion of the Scale Effect in Flood Discharge Atomization Model Tests for High-Head Dams -- 6.5.1 Similarity Criterion for FDA Model Tests -- 6.5.2 Scale Effect in FDA Model Tests -- 6.6 Conclusions -- References -- 7 Mesoscale Analysis of Flash Flood and Sediment Disasters -- 7.1 Background -- 7.2 Sudden Stop and Accumulation of Sediment Particles After a Hydraulic Jump -- 7.3 Threshold Conditions for Combined Flash Flood and Sediment Disasters -- 7.4 Identification of Disaster-Prone Regions Based on the Threshold Conditions for Combined Flash Flood and Sediment Disasters -- 7.5 Analysis of Control Techniques Based on the Threshold Conditions for Combined Flash Flood and Sediment Disasters -- 7.6 Conclusions -- References.
author_facet Xu, Weilin.
author_variant w x wx
author_sort Xu, Weilin.
title Mesoscale Analysis of Hydraulics.
title_full Mesoscale Analysis of Hydraulics.
title_fullStr Mesoscale Analysis of Hydraulics.
title_full_unstemmed Mesoscale Analysis of Hydraulics.
title_auth Mesoscale Analysis of Hydraulics.
title_new Mesoscale Analysis of Hydraulics.
title_sort mesoscale analysis of hydraulics.
publisher Springer Singapore Pte. Limited,
publishDate 2020
physical 1 online resource (253 pages)
edition 1st ed.
contents Intro -- Foreword I -- Foreword II -- Acknowledgments -- Contents -- About the Author -- List of Main Symbols -- List of Main Acronyms -- 1 Introduction -- 1.1 Definition of Mesoscale -- 1.2 Necessity of Mesoscale Research -- 1.3 Main Contents of Mesoscale Research -- References -- 2 Mesoscale Analysis of Cavitation and Cavitation Erosion -- 2.1 Background -- 2.2 Interactions Between Cavitation Bubbles and Rigid Boundaries -- 2.2.1 Shock Waves and Microjets Generated from the Collapse of CBs -- 2.2.2 Effects of the Geometric Shape of a Boundary on the Collapse Behavior of a CB -- 2.3 Interactions Between Cavitation Bubbles and Elastic Boundaries -- 2.3.1 Morphology of CBs Near Elastic Boundaries During the Collapsing Process -- 2.3.2 Shock Waves Generated by CBs Near Elastic Boundaries When Collapsing -- 2.3.3 Cavitation Erosion Resistance of Elastic Materials -- 2.4 Interactions Between Cavitation Bubbles -- 2.4.1 Interactions Between Two CBs -- 2.4.2 Interactions Between Multiple CBs -- 2.5 Interactions Between Cavitation Bubbles and Particles -- 2.5.1 Effects of Particles on the Collapse Directions of CBs -- 2.5.2 Effects of a Particle on the Shock Wave Generated by a CB When Collapsing -- 2.5.3 Effects of Particles on Cavitation Erosion -- 2.6 Collapse Locations of Cavitation Bubbles and Cavitation Erosion Control in Engineering Practice -- 2.6.1 Collapse Location Distribution Pattern of CBs in a Flow Past a Convex Body -- 2.6.2 Relationship of the Collapse Locations of CBs in a Flow Past a Convex Body with the Flow Field -- 2.6.3 Critical Conditions Required for Near-Boundary Collapse of CBs in a Flow Past a Convex Body -- 2.7 Conclusions -- References -- 3 Mesoscale Analysis of Aeration for Cavitation Erosion Protection -- 3.1 Background -- 3.2 Attenuation Effect of Air Bubbles on the Collapse Intensity of Cavitation Bubbles.
3.2.1 Intensity of the Collapse Noise of a Cavitation Bubble Interacting But Not Connected with Air Bubbles -- 3.2.2 Intensity of the Collapse Noise of a Cavitation Bubble Interacting and Connected with an Air Bubble -- 3.3 Direction-Changing Effect of an Air Bubble on the Collapse of a Cavitation Bubble -- 3.3.1 Direction-Changing Effect of an Air Bubble on the Collapse of a Cavitation Bubble -- 3.3.2 Direction-Changing Effect of an Air Bubble on a Cavitation Bubble Evolving Near a Wall -- 3.3.3 Combined Direction-Changing Effects of a Wall and an Air Bubble on the Collapse of a Cavitation Bubble -- 3.4 Retarding Effect of an Air Bubble on the Collapse Shock Wave of a Cavitation Bubble -- 3.4.1 Retarding Effect of an Air Bubble on the Collapse Shock Wave of a Cavitation Bubble -- 3.4.2 Impact Intensity of the Collapse Shock Wave of a Cavitation Bubble Interacting with an Air Bubble Near a Wall -- 3.5 Forced Aeration for Cavitation Erosion Protection of High-Head Dams -- 3.5.1 Mesoscale Mechanism of Forced Aeration -- 3.5.2 Design Principles of Forced-Aeration for Cavitation Erosion Protection Structures of High-Head Dams -- 3.6 Conclusions -- References -- 4 Mesoscale Analysis of Air-Water Two-Phase Flow -- 4.1 Background -- 4.2 Mesoscale Mechanism for Surface Aeration of High-Velocity Flows -- 4.2.1 Mesoscale Characteristics of the Free-Surface Shape of Flows -- 4.2.2 Mesoscale Free-Surface Aeration Process of Flows -- 4.2.3 Quantitative Analysis of the Free-Surface Aeration of Flows -- 4.3 Critical Condition for Surface Aeration of High-Velocity Flows -- 4.3.1 Critical Condition for Air Entrainment of Free-Surface Depressions in Flows -- 4.3.2 Air-Bubble Entrainment Characteristics of Free-Surface Depressions in Flows -- 4.3.3 Comparison of Calculated and Experimental Results.
4.4 Calculation of Concentration Distribution for Surface Aeration of High-Velocity Flows -- 4.4.1 Regional Characteristics of Surface Aeration in High-Velocity Flows -- 4.4.2 Comparison of the Calculated and Measured Values of the Ca Distribution in High-Velocity Aerated Flows -- 4.4.3 Diffusion Pattern of Ca Along the Course -- 4.5 Analysis of Depth and Concentration of Aerated Flows in Engineering Practice -- 4.5.1 Analysis of Self-Aerated Open-Channel Flows in Terms of Hm -- 4.5.2 Analysis of the Aerated Flow in the Spillway of the Jinping-I Hydropower Station -- 4.6 Conclusions -- References -- 5 Mesoscale Analysis of Flood Discharge and Energy Dissipation -- 5.1 Background -- 5.2 Vortex Structure of a Single Jet -- 5.2.1 Velocity Field Characteristics of a Single Jet -- 5.2.2 Vorticity Field Characteristics of a Single Jet -- 5.3 Vortex Structure with Multijets -- 5.3.1 Transverse Vortices -- 5.3.2 Vertical Vortices -- 5.4 Vortex Structure of a Pressure Flow with a Sudden Contraction -- 5.4.1 Flow Field Characteristics of a Pressure Flow with a Sudden Contraction -- 5.4.2 Vortex Blob Characteristics of a Pressure Flow with a Sudden Contraction -- 5.5 Application of Multihorizontal Submerged Jets in Engineering Project -- 5.5.1 Overview of the Project -- 5.5.2 Characteristics of the Flood Discharge and Energy Dissipation -- 5.6 Conclusions -- References -- 6 Mesoscale Analysis of Flood Discharge Atomization -- 6.1 Background -- 6.2 Jet Spallation in Air -- 6.2.1 Velocity Distribution of Jet-Spalled Water Droplets -- 6.2.2 Distribution of the Moving Directions of the Water Droplets Formed by Jet Spallation -- 6.3 Jet Collision in Air -- 6.3.1 Characteristics of the Water Droplets Formed by a Jet Collision in Air -- 6.3.2 Effects of the Flow-Rate Ratio on the Characteristics of the Water Droplets Formed by a Jet Collision.
6.3.3 Spallation Area of Jets After Collision in Air -- 6.4 Water Splash by Plunging Jets -- 6.4.1 Characteristics of the Water Droplets Splashed by a Jet -- 6.4.2 Motion Pattern of the Water Droplets Formed by the Splashing of Water with a High-Velocity Plunging Jet -- 6.5 Discussion of the Scale Effect in Flood Discharge Atomization Model Tests for High-Head Dams -- 6.5.1 Similarity Criterion for FDA Model Tests -- 6.5.2 Scale Effect in FDA Model Tests -- 6.6 Conclusions -- References -- 7 Mesoscale Analysis of Flash Flood and Sediment Disasters -- 7.1 Background -- 7.2 Sudden Stop and Accumulation of Sediment Particles After a Hydraulic Jump -- 7.3 Threshold Conditions for Combined Flash Flood and Sediment Disasters -- 7.4 Identification of Disaster-Prone Regions Based on the Threshold Conditions for Combined Flash Flood and Sediment Disasters -- 7.5 Analysis of Control Techniques Based on the Threshold Conditions for Combined Flash Flood and Sediment Disasters -- 7.6 Conclusions -- References.
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fullrecord <?xml version="1.0" encoding="UTF-8"?><collection xmlns="http://www.loc.gov/MARC21/slim"><record><leader>09334nam a22004093i 4500</leader><controlfield tag="001">5006420716</controlfield><controlfield tag="003">MiAaPQ</controlfield><controlfield tag="005">20240229073836.0</controlfield><controlfield tag="006">m o d | </controlfield><controlfield tag="007">cr cnu||||||||</controlfield><controlfield tag="008">240229s2020 xx o ||||0 eng d</controlfield><datafield tag="020" ind1=" " ind2=" "><subfield code="a">9789811597855</subfield><subfield code="q">(electronic bk.)</subfield></datafield><datafield tag="020" ind1=" " ind2=" "><subfield code="z">9789811597848</subfield></datafield><datafield tag="035" ind1=" " ind2=" "><subfield code="a">(MiAaPQ)5006420716</subfield></datafield><datafield tag="035" ind1=" " ind2=" "><subfield code="a">(Au-PeEL)EBL6420716</subfield></datafield><datafield tag="035" ind1=" " ind2=" "><subfield code="a">(OCoLC)1231603708</subfield></datafield><datafield tag="040" ind1=" " ind2=" "><subfield code="a">MiAaPQ</subfield><subfield code="b">eng</subfield><subfield code="e">rda</subfield><subfield code="e">pn</subfield><subfield code="c">MiAaPQ</subfield><subfield code="d">MiAaPQ</subfield></datafield><datafield tag="050" ind1=" " ind2="4"><subfield code="a">TC1-1800</subfield></datafield><datafield tag="100" ind1="1" ind2=" "><subfield code="a">Xu, Weilin.</subfield></datafield><datafield tag="245" ind1="1" ind2="0"><subfield code="a">Mesoscale Analysis of Hydraulics.</subfield></datafield><datafield tag="250" ind1=" " ind2=" "><subfield code="a">1st ed.</subfield></datafield><datafield tag="264" ind1=" " ind2="1"><subfield code="a">Singapore :</subfield><subfield code="b">Springer Singapore Pte. Limited,</subfield><subfield code="c">2020.</subfield></datafield><datafield tag="264" ind1=" " ind2="4"><subfield code="c">©2021.</subfield></datafield><datafield tag="300" ind1=" " ind2=" "><subfield code="a">1 online resource (253 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="505" ind1="0" ind2=" "><subfield code="a">Intro -- Foreword I -- Foreword II -- Acknowledgments -- Contents -- About the Author -- List of Main Symbols -- List of Main Acronyms -- 1 Introduction -- 1.1 Definition of Mesoscale -- 1.2 Necessity of Mesoscale Research -- 1.3 Main Contents of Mesoscale Research -- References -- 2 Mesoscale Analysis of Cavitation and Cavitation Erosion -- 2.1 Background -- 2.2 Interactions Between Cavitation Bubbles and Rigid Boundaries -- 2.2.1 Shock Waves and Microjets Generated from the Collapse of CBs -- 2.2.2 Effects of the Geometric Shape of a Boundary on the Collapse Behavior of a CB -- 2.3 Interactions Between Cavitation Bubbles and Elastic Boundaries -- 2.3.1 Morphology of CBs Near Elastic Boundaries During the Collapsing Process -- 2.3.2 Shock Waves Generated by CBs Near Elastic Boundaries When Collapsing -- 2.3.3 Cavitation Erosion Resistance of Elastic Materials -- 2.4 Interactions Between Cavitation Bubbles -- 2.4.1 Interactions Between Two CBs -- 2.4.2 Interactions Between Multiple CBs -- 2.5 Interactions Between Cavitation Bubbles and Particles -- 2.5.1 Effects of Particles on the Collapse Directions of CBs -- 2.5.2 Effects of a Particle on the Shock Wave Generated by a CB When Collapsing -- 2.5.3 Effects of Particles on Cavitation Erosion -- 2.6 Collapse Locations of Cavitation Bubbles and Cavitation Erosion Control in Engineering Practice -- 2.6.1 Collapse Location Distribution Pattern of CBs in a Flow Past a Convex Body -- 2.6.2 Relationship of the Collapse Locations of CBs in a Flow Past a Convex Body with the Flow Field -- 2.6.3 Critical Conditions Required for Near-Boundary Collapse of CBs in a Flow Past a Convex Body -- 2.7 Conclusions -- References -- 3 Mesoscale Analysis of Aeration for Cavitation Erosion Protection -- 3.1 Background -- 3.2 Attenuation Effect of Air Bubbles on the Collapse Intensity of Cavitation Bubbles.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">3.2.1 Intensity of the Collapse Noise of a Cavitation Bubble Interacting But Not Connected with Air Bubbles -- 3.2.2 Intensity of the Collapse Noise of a Cavitation Bubble Interacting and Connected with an Air Bubble -- 3.3 Direction-Changing Effect of an Air Bubble on the Collapse of a Cavitation Bubble -- 3.3.1 Direction-Changing Effect of an Air Bubble on the Collapse of a Cavitation Bubble -- 3.3.2 Direction-Changing Effect of an Air Bubble on a Cavitation Bubble Evolving Near a Wall -- 3.3.3 Combined Direction-Changing Effects of a Wall and an Air Bubble on the Collapse of a Cavitation Bubble -- 3.4 Retarding Effect of an Air Bubble on the Collapse Shock Wave of a Cavitation Bubble -- 3.4.1 Retarding Effect of an Air Bubble on the Collapse Shock Wave of a Cavitation Bubble -- 3.4.2 Impact Intensity of the Collapse Shock Wave of a Cavitation Bubble Interacting with an Air Bubble Near a Wall -- 3.5 Forced Aeration for Cavitation Erosion Protection of High-Head Dams -- 3.5.1 Mesoscale Mechanism of Forced Aeration -- 3.5.2 Design Principles of Forced-Aeration for Cavitation Erosion Protection Structures of High-Head Dams -- 3.6 Conclusions -- References -- 4 Mesoscale Analysis of Air-Water Two-Phase Flow -- 4.1 Background -- 4.2 Mesoscale Mechanism for Surface Aeration of High-Velocity Flows -- 4.2.1 Mesoscale Characteristics of the Free-Surface Shape of Flows -- 4.2.2 Mesoscale Free-Surface Aeration Process of Flows -- 4.2.3 Quantitative Analysis of the Free-Surface Aeration of Flows -- 4.3 Critical Condition for Surface Aeration of High-Velocity Flows -- 4.3.1 Critical Condition for Air Entrainment of Free-Surface Depressions in Flows -- 4.3.2 Air-Bubble Entrainment Characteristics of Free-Surface Depressions in Flows -- 4.3.3 Comparison of Calculated and Experimental Results.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">4.4 Calculation of Concentration Distribution for Surface Aeration of High-Velocity Flows -- 4.4.1 Regional Characteristics of Surface Aeration in High-Velocity Flows -- 4.4.2 Comparison of the Calculated and Measured Values of the Ca Distribution in High-Velocity Aerated Flows -- 4.4.3 Diffusion Pattern of Ca Along the Course -- 4.5 Analysis of Depth and Concentration of Aerated Flows in Engineering Practice -- 4.5.1 Analysis of Self-Aerated Open-Channel Flows in Terms of Hm -- 4.5.2 Analysis of the Aerated Flow in the Spillway of the Jinping-I Hydropower Station -- 4.6 Conclusions -- References -- 5 Mesoscale Analysis of Flood Discharge and Energy Dissipation -- 5.1 Background -- 5.2 Vortex Structure of a Single Jet -- 5.2.1 Velocity Field Characteristics of a Single Jet -- 5.2.2 Vorticity Field Characteristics of a Single Jet -- 5.3 Vortex Structure with Multijets -- 5.3.1 Transverse Vortices -- 5.3.2 Vertical Vortices -- 5.4 Vortex Structure of a Pressure Flow with a Sudden Contraction -- 5.4.1 Flow Field Characteristics of a Pressure Flow with a Sudden Contraction -- 5.4.2 Vortex Blob Characteristics of a Pressure Flow with a Sudden Contraction -- 5.5 Application of Multihorizontal Submerged Jets in Engineering Project -- 5.5.1 Overview of the Project -- 5.5.2 Characteristics of the Flood Discharge and Energy Dissipation -- 5.6 Conclusions -- References -- 6 Mesoscale Analysis of Flood Discharge Atomization -- 6.1 Background -- 6.2 Jet Spallation in Air -- 6.2.1 Velocity Distribution of Jet-Spalled Water Droplets -- 6.2.2 Distribution of the Moving Directions of the Water Droplets Formed by Jet Spallation -- 6.3 Jet Collision in Air -- 6.3.1 Characteristics of the Water Droplets Formed by a Jet Collision in Air -- 6.3.2 Effects of the Flow-Rate Ratio on the Characteristics of the Water Droplets Formed by a Jet Collision.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">6.3.3 Spallation Area of Jets After Collision in Air -- 6.4 Water Splash by Plunging Jets -- 6.4.1 Characteristics of the Water Droplets Splashed by a Jet -- 6.4.2 Motion Pattern of the Water Droplets Formed by the Splashing of Water with a High-Velocity Plunging Jet -- 6.5 Discussion of the Scale Effect in Flood Discharge Atomization Model Tests for High-Head Dams -- 6.5.1 Similarity Criterion for FDA Model Tests -- 6.5.2 Scale Effect in FDA Model Tests -- 6.6 Conclusions -- References -- 7 Mesoscale Analysis of Flash Flood and Sediment Disasters -- 7.1 Background -- 7.2 Sudden Stop and Accumulation of Sediment Particles After a Hydraulic Jump -- 7.3 Threshold Conditions for Combined Flash Flood and Sediment Disasters -- 7.4 Identification of Disaster-Prone Regions Based on the Threshold Conditions for Combined Flash Flood and Sediment Disasters -- 7.5 Analysis of Control Techniques Based on the Threshold Conditions for Combined Flash Flood and Sediment Disasters -- 7.6 Conclusions -- References.</subfield></datafield><datafield tag="588" ind1=" " ind2=" "><subfield code="a">Description based on publisher supplied metadata and other sources.</subfield></datafield><datafield tag="590" ind1=" " ind2=" "><subfield code="a">Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2024. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries. </subfield></datafield><datafield tag="655" ind1=" " ind2="4"><subfield code="a">Electronic books.</subfield></datafield><datafield tag="776" ind1="0" ind2="8"><subfield code="i">Print version:</subfield><subfield code="a">Xu, Weilin</subfield><subfield code="t">Mesoscale Analysis of Hydraulics</subfield><subfield code="d">Singapore : Springer Singapore Pte. Limited,c2020</subfield><subfield code="z">9789811597848</subfield></datafield><datafield tag="797" ind1="2" ind2=" "><subfield code="a">ProQuest (Firm)</subfield></datafield><datafield tag="856" ind1="4" ind2="0"><subfield code="u">https://ebookcentral.proquest.com/lib/oeawat/detail.action?docID=6420716</subfield><subfield code="z">Click to View</subfield></datafield></record></collection>

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