Convective heat and mass transfer in rotating disk systems
The book describes results of investigations of a series of convective heat-and-mass transfer problems in rotating-disk systems, namely, over free rotating disks, under conditions of transient heat transfer, solid-body rotation of fluid, orthogonal flow impingement onto a disk, swirl radial flow bet...
| Main Author: | Shevchuk, Igor V. |
|---|---|
| Other Authors: | SpringerLink (Online service) |
| Format: | eBook |
| Language: | English |
| Published: |
Heidelberg ; New York :
Springer,
©2009.
Heidelberg ; New York : [2009] |
| Physical Description: |
1 online resource (xxi, 239 pages) : illustrations. |
| Series: |
Lecture notes in applied and computational mechanics ;
v. 45. |
| Subjects: |
Heat
-- Convection.
|
Table of Contents:
- Cover
- Contents
- 1 General Characteristic of Rotating-Disk Systems
- 1.1 Industrial Applications of Rotating-Disk Systems
- 1.2 Acting Forces
- 1.3 Differential Equations of Continuity, Momentum and Heat Transfer
- 1.4 Differential Equation of Convective Diffusion
- 2 Modelling of Fluid Flow and Heat Transfer in Rotating-Disk Systems
- 2.1 Differential and Integral Equations
- 2.1.1 Differential NavierStokes and Energy Equations
- 2.1.2 Differential Boundary Layer Equations
- 2.1.3 Integral Boundary Layer Equations
- 2.2 Differential Methods of Solution
- 2.2.1 Self-Similar Solution
- 2.2.2 Approximate Analytical Methods for Laminar Flow Based on Approximations of Velocity Profiles
- 2.2.3 Numerical Methods
- 2.3 Integral Methods of Solution
- 2.3.1 Momentum Boundary Layer
- 2.3.2 Thermal Boundary Layer
- 2.4 Integral Method for Modelling Fluid Flow and Heat Transfer in Rotating-Disk Systems
- 2.4.1 Structure of the Method
- 2.4.2 Turbulent Flow: Improved Approximations of the Velocity and Temperature Profiles
- 2.4.3 Models of Surface Friction and Heat Transfer
- 2.4.4 Integral Equations with Account for the Models for the Velocity and Temperature Profiles
- 2.5 General Solution for the Cases of Disk Rotation in a Fluid Rotating as a Solid Body and Simultaneous Accelerating Imposed Radial Flow
- 3 Free Rotating Disk
- 3.1 Laminar Flow
- 3.2 Transition to Turbulent Flow and Effect of Surface Roughness
- 3.3 Turbulent Flow
- 3.3.1 Parameters of the Turbulent Boundary Layer
- 3.3.2 Surface Heat Transfer: Experimental and Theoretical Data of Different Authors
- 3.3.3 Effect of Approximation of the Radial Velocity Profile on Parameters of Momentum and Thermal Boundary Layers
- 3.3.4 Numerical Computation of Turbulent Flow and Heat Transfer for an Arbitrary Distribution of the Wall Temperature
- 3.4 Generalized Analytical Solution for Laminar and Turbulent Regimes Based on the Novel Model for the Enthalpy Thickness
- 3.5 Inverse Problem of Restoration of the Wall Temperature Distribution at a Specified Arbitrary Power Law for the Nusselt Number
- 3.5.1 Solution of the Problem
- 3.5.2 Limiting Case of the Solution
- 3.5.3 Properties of the Solution for Temperature Head
- 3.5.4 Analysis of the Solution
- 3.6 Theory of Local Modelling
- 3.6.1 Solution of the Problem
- 3.6.2 Other Interpretations
- 4 Unsteady Laminar Heat Transfer of a Free Rotating Disk
- 4.1 Transient Experimental Technique for Measuring Heat Transfer over Rotating Disks
- 4.2 Self-Similar NavierStokes and Energy Equations
- 4.3 Exact Solution for Surface Heat Transfer of an Isothermal Rotating Disk
- 4.4 Numerical Solution of an Unsteady Conjugate Problem of Hydrodynamics and Heat Transfer of an Initially Isothermal Disk
- 4.4.1 Computational Domain and Grid
- 4.4.2 Validation for Steady-State Fluid Flow and Heat Transfer
- 4.4.3 Unsteady Fluid Flow and Heat Transfer
- 4.5 Unsteady Conjugate Laminar Heat Transfer of a Rotating Non-uniformly Heated Disk
- 4.5.1 Problem Statement
- 4.5.2 Self-Similar Solution of the Transient Laminar Convective Heat Transfer Problem
- 4.5.3 Solution of the Unsteady Two-Dimensional Problem of Heat Conduction in a Disk
- 4.5.4 Analysis of the Solutions for Unsteady Heat Conduction in a Disk
- 5 External Flow Imposed over a Rotating Disk
- 5.1 Rotation of a Disk in a Fluid Rotating as a Solid Body Without Imposed Radial Flow
- 5.1.1 Turbulent Flow
- 5.1.2 Laminar Flow
- 5.2 Accelerating Ra.