Flow Past a Cylinder as the...Fig. 3-11 Two-Phase Flow Patterns in Vertically Upwards and Horizontal Cross...Fig. 3-12 Flow Pattern Map for Two-Phase Flow Across Cylinder Arrays Using F...Fig. 3-13 Flow Regime Map for Vertical Two-Phase Flow Using McQuillan and Wh...Fig. 3-14 Ulbrich and Mewes Flow Regime Map (Solid Line) for Vertically Upwa...Fig. 3-15 Flow Patterns in Vertical Two-Phase Cross Flow from Kanizawa and R...Fig. 3-16 Flow Regime Map Comparison Between Vertically Upward Air-Water Flo...Fig. 3-17 Sketch of Axial-Flow Heated-Cylinder Test Section (Pettigrew and G...Fig. 3-18 Effect of Nucleate Boiling on Cylinder Vibration (Pettigrew and Go...Fig. 3-19 Cross-Flow Tube Bundle Test Section with Heated Tubes (M and T) in...Fig. 3-20 Example 3-3 - Cross-Section of Heat Exchanger Showing Flow Paths 1...Fig. 3-21 Predicted Velocity Vectors (Left), Steam Quality (Second from the ...Fig. 3-22 Vector Fluid Velocity for a Maximum-Radius Tube Shown by Thick-Lin...Fig. 3-23 Gap Cross-Flow Velocity for the Maximum-Radius Tube.Fig. 3-24 Predicted (a) Velocity and (b) Air Concentration Distributions in ...Fig. 3-25 Process Heat Exchanger Predictions of Velocity Distribution for (a...Fig. 3-26 CFD Predictions of Path Lines in a Shell-and-Tube Heat Exchanger w...
4 Chapter 4Fig. 4-1 Effect of Void Fraction and Mass Flux on Hydrodynamic Mass Ratio (P...Fig. 4-2 Effect of P/D and Bundle Geometry on Hydrodynamic Mass Ratio (Petti...Fig. 4-3 Effect of Slip Ratio and Fluid Mixture on Hydrodynamic Mass Ratio C...Fig. 4-4 Straight Tube with Simple Support at Each End.Fig. 4-5 Two‐Span Beam with Outer Ends Clamped.Fig. 4-6 Multi‐Span Beam with Outer Ends Clamped.Fig. 4-7 View of Typical Steam Generator U‐Tube with Support Points Located ...Fig. 4-8 Nomenclature Utilized in Representing Lateral and Rotational Displa...Fig. 4-9 View of Half of Steam Generator U‐Tube, Referred to as a Half‐Tube,...Fig. 4-10 Schematic Representation of Boundary and Continuity Conditions to ...Fig. 4-11 Schematic Representation of Boundary and Continuity Conditions to ...Fig. 4-12 Schematic Representation of First and Second Free Vibration In‐Pla...Fig. 4-13 Schematic Representation of First and Second Free Vibration Out‐of...Fig. 4-14 Schematic Representation of Boundary and Continuity Conditions to ...Fig. 4-15 Schematic Representation of Boundary and Continuity Conditions to ...Fig. 4-16 Schematic Representation of Boundary and Continuity Conditions to ...Fig. 4-17 Schematic Representation of Boundary and Continuity Conditions to ...
5 Chapter 5Fig. 5-1 Types of Tube Motion at Support Location.Fig. 5-2 Types of Dynamic Interaction between Tube and Tube Support.Fig. 5-3 Damping of Heat Exchanger Tubes in Air.Fig. 5-4 Effect of Tube Support Thickness on Damping in Gases (Air).Fig. 5-5 Effect of Tube Support Thickness on Normalized Damping Ratio in Gas...Fig. 5-6 Effect of Support Thickness on a) Sliding Interaction, and b) Impac...Fig. 5-7 Effect of Dimensionless Support Thickness (L / ℓm) on Normali...Fig. 5-8 Design Recommendation for Damping in Gases.Fig. 5-9 Damping Data for Multi‐Span Heat Exchanger Tubes in Water.Fig. 5-10 Viscous Damping Data for a Cylinder in Confined (Chen et al, 1976)...Fig. 5-11 Viscous Damping of Cylinders in Liquids Versus Stokes Number.Fig. 5-12 Damping Due to Tube Supports in Multi‐Span Heat Exchanger Tubes.Fig. 5-13 Heat Exchanger Tube with N Spans and (N‐1) Intermediate Supports....Fig. 5-14 Linearization of Three‐Dimensional Factor K.Fig. 5-15 Damping and Hydrodynamic Mass Functions, Im(h) and Re(h), (Mulcahy...Fig. 5-16 Squeeze‐Film Damping of a Multi‐Span Heat Exchanger Tube in Water....Fig. 5-17 Effect of Support Thickness Parameter L/ℓm on Damping due to...Fig. 5-18 Comparison between Tube Support Damping Parameter and Experimental...Fig. 5-19 Type of Contact Between Tube and Support.Fig. 5-20 Comparison between Tube Support Damping Model (Squeeze‐Film and Fr...
6 Chapter 6Fig. 6-1 Flow Regime Map for Tube Bundles in Vertical Cross Flow: Symbols Sh...Fig. 6-2 Damping of a Cylinder in Confined Air‐Water Axial Flow; Mass Flux: ...Fig. 6-3 Effect of Mass Flux on Two‐Phase Damping Ratio in Annular Flow (Car...Fig. 6-4 Effect of Mass Flux on Tube Damping in Two‐Phase Cross Flow (Pettig...Fig. 6-5 Effect of Mass Flux on Damping in Lift and Drag Directions for a No...Fig. 6-6 Damping of Tube Bundles of P/D = 1.47 in Two‐Phase Cross Flow Showi...Fig. 6-7 Damping of Tube Bundles in Two‐Phase Cross Flow: Comparison of Air‐...Fig. 6-8 Damping of a Rotated‐Triangular Tube Bundle in Freon‐22 Two‐Phase C...Fig. 6-9 Effect of Void Fraction on Two‐Phase Damping in Cross Flow: Propose...Fig. 6-10 Damping of Tube Rows in Air-Water Cross Flows; ▴ Taylor et al (198...Fig. 6-11 Total Damping for Tube Bundles of P/D = 1.22 in Air‐Water Cross Fl...Fig. 6-12 Damping Behavior: Comparison Between All Flexible Tube Bundle and ...Fig. 6-13 Effect of Surface Tension on Two‐Phase Damping for Tube Frequencie...Fig. 6-14 Damping of Rotated Triangular Tube Bundles: Comparison Between Air...Fig. 6-15 Comparison Between Proposed Design Guideline and Available Damping...
7 Chapter 7Fig. 7-1 Typical Vibration Response versus Flow Velocity Relationship for Tu...Fig. 7-2 Vibration Response of a Normal‐Triangular Tube Bundle of P/D = 1.33...Fig. 7-3 Fluidelastic Instability Data and Design Recommendations for Variou...Fig. 7-4 Fluidelastic Instability Diagrams: a) Normal Square, b) Rotated Squ...Fig. 7-5 Principal Tube Bundle Configurations.Fig. 7-6 Well-Defined Fluidelastic ThresholdFig. 7-7 Less Well-Defined Fluidelastic ThresholdFig. 7-8 Vibration Response of One Flexible Tube versus Seven Flexible Tubes...Fig. 7-9 Outline of Fluidelastic Instability Data for All‐Flexible Tube Bund...Fig. 7-10 Fluidelastic Instability of a Single Flexible Tube in Rigid Arrays...Fig. 7-11 Fluidelastic Instability of a Single Flexible Tube in a Normal‐Squ...Fig. 7-12 Comparison of Fluidelastic Instability Results with Only Structura...Fig. 7-13 Fluidelastic Instability Data for Flexible Tube Bundles: Compariso...Fig. 7-14 Effect of Pitch‐to‐Diameter Ratio on Fluidelastic Instability Cons...Fig. 7-15 Fluidelastic Instability Data Presented in Terms of Modified Mass‐...Fig. 7-16 Fluidelastic Instability Data for Different Tube Bundle Configurat...Fig. 7-17 Summary of Fluidelastic Instability Data for All‐Flexible Tube Bun...Fig. 7-18 Fluidelastic Instability Analysis of Real Heat Exchangers: Compari...Fig. 7-19 Multi‐Span Heat Exchanger Tube Schematic with Cross‐Flow Pattern....Fig. 7-20 Wind‐Tunnel, Rotated‐Triangular Test Array.Fig. 7-21 Response Spectra Variation with Flow Velocity for Tube 2 in a Full...Fig. 7-22 Vibration Response for the Flexible Bundle within Wind Tunnel: ♦, ...Fig. 7-23 Response Frequency versus Flow Velocity for the Flexible Bundle wi...Fig. 7-24 Clamped‐Free Cylinder Experiencing 4th‐Mode Buckling In Confined L...Fig. 7-25 Selected Frequency Spectra for Fluidelastic Instability of Clamped...
8 Chapter 8Fig. 8-1 Typical Tube Response Spectra for Increasing Mass Fluxes at Constan...Fig. 8-2 Typical Vibration Response: Comparison Between Flexible Tube Bundle...Fig. 8-3 Vibration Response: Comparison Between Flexible Tube Bundle and One...Fig. 8-4 Schematic of Air‐Water Test Section and Tube Bundle.Fig. 8-5 Photograph of Air‐Water Test Section and Part of Air‐Water Loop.Fig. 8-6 Photograph of Cantilever Tube Bundle with Normal‐Triangular Configu...Fig. 8-7 Fluidelastic Instability Results in Air‐Water Cross Flow.Fig. 8-8 Flow Regime Maps for Air‐Water Cross Flow Showing Flow Conditions a...Fig. 8-9 Effect of P/D on Fluidelastic Instability Constant in Air‐Water Cro...Fig. 8-10 Two‐Phase Flow Structure in a Rotated‐Triangular Tube Bundle: a) S...Fig. 8-11 Two‐Phase Flow Paths in a Normal‐Triangular Tube Bundle.Fig. 8-12 Hydrodynamic Coupling Coherence as a Function of Mass Flux Ratio....Fig. 8-13 Air‐Water and Steam‐Water Fluidelastic Instability Results Plotted...Fig. 8-14 Air‐Water and Steam‐Water Fluidelastic Instability Results Plotted...Fig. 8-15 Photograph of Freon Pressure Vessel Test Section Showing Instrumen...Fig. 8-16 Schematic of Freon Test Section.Fig. 8-17 Photograph of Rotated‐Triangular Tube Bundle Instrumented with Str...Fig. 8-18 Typical Vibration Response Spectra for Two‐Phase Freon Cross Flow....Fig. 8-19 Typical Vibration Response Curves for Two‐Phase Freon Cross Flow: ...Fig. 8-20 Vibration Response: Freon versus Air‐Water.Fig. 8-21 Vibration Response In Freon at 80% Void