SAE AIR 1168/1 : 1990
SAE AIR 1168/1 : 1990
THERMODYNAMICS OF INCOMPRESSIBLE AND COMPRESSIBLE FLUID FLOW
SAE International
THERMODYNAMICS OF INCOMPRESSIBLE AND COMPRESSIBLE FLUID FLOW
SAE International
SECTION 1A - INCOMPRESSIBLE FLUID FLOW
1 INTRODUCTION
1.1 Scope
1.2 Nomenclature
2 BASIC FLUID MECHANICS
2.1 Continuity Equation
2.2 Momentum Equation
2.3 Energy Equation
2.4 Viscosity Concepts
2.5 Boundary Layer Flow
2.6 Total Pressure Loss Due to Change of Fluid
Velocity Profile
3 SPECIFIC PRESSURE LOSS DATA
3.1 Pressure Losses, Straight Ducts
3.2 Pressure Losses, Elbows
3.3 Pressure Losses, Duct Area Changes
3.4 Pressure Losses, Duct Branches
3.5 Pressure Losses, Internal Installations
3.6 Pressure Losses, Exits To Compartments
3.7 Example of Pressure Loss Calculations
4 REFERENCES
SECTION 1B - THERMODYNAMICS AND COMPRESSIBLE FLOW
1 INTRODUCTION
1.1 Definition and Scope
1.2 Nomenclature
2 FIRST LAW OF THERMODYNAMICS
3 IDEAL OR PERFECT GASES AS WORKING FLUIDS
3.1 Equation of State
3.2 Energy Equations of a Ideal Gas
3.3 Equations for Mixtures of Ideal Gases
4 THE SECOND LAW OF THERMODYNAMICS
4.1 Carnot Cycle and Available Energy
4.2 Methods of Graphical Representations
5 REAL GAS CHARACTERISTICS
5.1 Van der Waals Equation
5.2 Beattie-Bridgeman
5.3 Generalized Reduced Coordinate System
5.4 Change of Phase
5.5 Triple Point and Triple Line
5.6 Latent Heat
5.7 Critical Point
6 THERMODYNAMICS OF HIGH-VELOCITY GAS FLOWS
6.1 Introduction
6.2 Steady-Flow Energy Equation
6.3 Sonic Velocity and Mach number
6.4 One-Dimensional Energy Equation for Steady Flow
Without Heat Transfer
6.5 Total Temperature, Static Temperature, Velocity,
and Mach Number Relations
6.6 Pressure Ration, Density Ration, and Mach Number
Relations
6.7 Continuity Relations
6.8 Illustrative Examples
6.9 Forces on Internal Flow Passages
6.10 General Duct Flow
6.11 Constant Area Duct Flow With Heat Transfer And
No Friction
6.12 Constant Area Duct Flow With Friction and No
Heat Transfer
6.13 Constant Area Duct Flow With Heat Transfer And
Friction
6.14 Mach Waves and Prandtl-Meyer Flow
6.15 Normal, Oblique, and Conical Shock Waves
6.16 Subsonic Diffusers
6.17 Auxiliary Inlets and Diffusers
6.18 Auxiliary Outlets
6.19 Supersonic Nozzles and Sonic Venturis
6.20 Duct Component Losses in Compressible Flow
6.21 Real Gas Effects
7 REFERENCES
Contains fluid flow which can be treated as isothermal, subsonic and incompressible.
Document Type | Standard |
Status | Current |
Publisher | SAE International |
Committee | AC 9B |