Produktbild: Khabensky, V: Coolant Flow Instabilities in Power Equipment

Khabensky, V: Coolant Flow Instabilities in Power Equipment

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Beschreibung

Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

20.12.2012

Abbildungen

schwarz-weiss Illustrationen, Tabellen, schwarz-weiss

Verlag

Taylor and Francis

Seitenzahl

388

Maße (L/B/H)

23.5/15.6/2.5 cm

Gewicht

684 g

Sprache

Englisch

ISBN

978-1-4665-6704-7

Beschreibung

Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

20.12.2012

Abbildungen

schwarz-weiss Illustrationen, Tabellen, schwarz-weiss

Verlag

Taylor and Francis

Seitenzahl

388

Maße (L/B/H)

23.5/15.6/2.5 cm

Gewicht

684 g

Sprache

Englisch

ISBN

978-1-4665-6704-7

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  • Produktbild: Khabensky, V: Coolant Flow Instabilities in Power Equipment
  • Two-Phase Flow Oscillatory Thermal-Hydraulic Instability Classification of Types of Thermal-Hydraulic Instability and Typical Thermal and Hydrodynamic Boundary Conditions Two-Phase Flow Instability at Low Exit Qualities Two-Phase Flow Oscillatory Instability at High Exit Qualities (Density-Wave Instability) Simplifying Assumptions Underlying Mathematical Model and Their Effect on Accuracy of Thermal-Hydraulic Stability Boundary Prediction Oscillatory Stability Boundary in Hydrodynamic Interaction of Parallel Channels and Requirements to Simulate Unstable Processes on Test Facilities Qualitative Effect of Hydrodynamic Interaction of Parallel Channels on Oscillatory Stability Boundary Simulation of Thermal-Hydraulic Instability in Complex Systems Simplified Correlations for Determining the Two-Phase Flow Thermal-Hydraulic Oscillatory Stability Boundary Introduction The CKTI Method The Saha-Zuber Method The Method of the Institute for Physics and Energetics (IPE) Determination of Oscillatory Stability Boundary at Supercritical Pressures Some Notes on the Oscillatory Flow Stability Boundary Experimental Determination of the Stability Boundary Experimental Determination of Thermal-Hydraulic Stability Boundaries of a Flow Using Operating Parameter Noise The First Approximation Stability Investigation Stability Investigations Based on Direct Numerical Solution of the Unsteady System of Nonlinear Equations Static Instability Basic Definitions Ambiguity of Hydraulic Curve due to Appearance of a Boiling Section at the Heated Channel Exit Hydraulic Characteristic Ambiguity in the Presence of a Superheating Section Hydraulic Characteristic Ambiguity in Cases of Coolant Downflow and Upflow-Downflow Pressure Drop Oscillations Some Other Mechanisms Inducing Static Instability Thermal-Acoustic Oscillations in Heated Channels Thermal-Acoustic Oscillations at Subcritical Pressures TAOs at Supercritical Pressures Instability of Condensing Flows Introduction Instability of Condenser Tube and Hotwell System Interchannel Instability in System of Parallel-Connected Condensing Tubes Water Hammers in Horizontal and Almost Horizontal Steam and Subcooled Water Tubes Instability of Bubbling Condensers Some Cases of Flow Instability in Pipelines Self-Oscillations in Inlet Line-Pump System Instability of Condensate Line-Deaerator System Vibration of Pipelines with Two-Phase Adiabatic Flows Two-Phase Flow Instabilities and Bubbling References