| 課程大綱 Syllabus |
學生學習目標
Learning Objectives |
單元學習活動
Learning Activities |
學習成效評量
Evaluation |
備註
Notes |
序
No. | 單元主題
Unit topic |
內容綱要
Content summary |
| 1 | Introduction to Momentum Transfer |
1. FLUIDS AND THE CONTINUUM
2. PROPERTIES AT A POINT
3. POINT-TO-POINT VARIATION OF PROPERTIES IN A FLUID
4. COMPRESSIBILITY
5. SURFACE TENSION |
1. To understand what is transport phenomena and unit operation
2. To know some fluid properties |
講授
|
|
|
| 2 | Fluid Statics |
1. PRESSURE VARIATION IN A STATIC FLUID
2. UNIFORM RECTILINEAR ACCELERATION
3. FORCES ON SUBMERGED SURFACES |
To understand the application of fluid statics |
講授
|
作業
|
|
| 3 | Fluid Statics and Fluid in motion |
1. BUOYANCY
2. FUNDAMENTAL PHYSICAL LAWS
3. FLUID-FLOW FIELDS: LAGRANGIAN AND EULERIAN REPRESENTATIONS
4. STEADY AND UNSTEADY FLOWS
5. STREAMLINES
6. SYSTEMS AND CONTROL VOLUMES |
To learn the transition from flow statics to fluid flow. |
講授
|
作業
|
|
| 4 | Conservation of mass |
1. INTEGRAL RELATION
2. SPECIFIC FORMS OF THE INTEGRAL EXPRESSION |
To learn how to establish the mass balance balance and solve it. |
講授
|
作業
平時考
|
|
| 5 | Newton's 2nd law of motion |
1. INTEGRAL RELATION FOR LINEAR MOMENTUM
2. APPLICATIONS OF THE INTEGRAL EXPRESSION
FOR LINEAR MOMENTUM
3. INTEGRAL RELATION FOR MOMENT OF MOMENTUM |
To learn how to establish the momentum balance and solve it. |
講授
|
|
|
| 6 | Newton's 2nd law of motion |
1. APPLICATIONS TO PUMPS AND TURBINES |
To learn momentum balance. |
講授
|
作業
|
|
| 7 | Conservation of energy |
1. INTEGRAL RELATION FOR THE CONSERVATION OF ENERGY
2. APPLICATIONS OF THE INTEGRAL EXPRESSION |
Use energy balance to solve transport phenomena problems. |
講授
|
|
|
| 8 | Conservation of energy |
1. THE BERNOULLI EQUATION |
Use BERNOULLI EQUATION to solve fluid mechanics problems. |
講授
|
作業
|
|
| 9 | 期中考 |
期中考 |
期中考 |
|
期中考
|
|
| 10 | Shear stress in laminar flow |
1. NEWTON’S VISCOSITY RELATION
2. NON-NEWTONIAN FLUIDS
3. VISCOSITY
4. SHEAR STRESS IN MULTIDIMENSIONAL LAMINAR FLOWS OF A NEWTONIAN FLUID |
To learn shear stress for newtionian fluids |
講授
|
|
|
| 11 | Shear stress in laminar flow |
1. NEWTON’S VISCOSITY RELATION
2. NON-NEWTONIAN FLUIDS
3. VISCOSITY
4. SHEAR STRESS IN MULTIDIMENSIONAL LAMINAR FLOWS OF A NEWTONIAN FLUID |
To learn shear stress for newtionian fluids |
講授
|
作業
|
|
| 12 | Analysis of differential fluid element in laminar flow |
1. FULLY DEVELOPED LAMINAR FLOW IN A CIRCULAR
CONDUIT OF CONSTANT CROSS SECTION
2. LAMINAR FLOW OF A NEWTONIAN FLUID DOWN AN INCLINED-PLANE SURFACE |
To learn how to analyze fluid flow |
講授
|
作業
|
|
| 13 | Differential equations of fluid flow |
1. THE DIFFERENTIAL CONTINUITY EQUATION
2. NAVIER–STOKES EQUATIONS
3. BERNOULLI’S EQUATION |
To learn how to solve fluid flow problems with Navier-Stokes equation. |
講授
|
作業
|
|
| 14 | Inviscid fluid flow |
1. FLUID ROTATION AT A POINT
2. THE STREAM FUNCTION
3. INVISCID, IRROTATIONAL FLOWABOUT AN INFINITE CYLINDER
4. IRROTATIONAL FLOW, THE VELOCITY POTENTIAL |
To learn fluid flow with negligible viscosity |
講授
|
|
|
| 15 | Inviscid fluid flow |
1. UTILIZATION OF POTENTIAL FLOW
2. POTENTIAL FLOWANALYSIS—SIMPLE PLANE FLOW CASES
3. POTENTIAL FLOWANALYSIS—SUPERPOSITION |
To learn fluid flow with negligible viscosity |
講授
|
作業
平時考
|
|
| 16 | Dimensional analysis |
1. DIMENSIONS
2. DIMENSIONAL ANALYSIS OF GOVERNING DIFFERENTIAL EQUATIONS
3. THE BUCKINGHAM METHOD
4. GEOMETRIC, KINEMATIC, AND DYNAMIC SIMILARITY
5. MODEL THEORY |
To learn how to use dimensional analysis to develop engineering correlation |
講授
|
|
|
| 17 | Flow in closed conduits |
1. DIMENSIONAL ANALYSIS OF CONDUIT FLOW
2. FRICTION FACTORS FOR FULLY DEVELOPED LAMINAR, TURBULENT, AND TRANSITION FLOW IN CIRCULAR CONDUITS
3. FRICTION FACTOR AND HEAD-LOSS DETERMINATION FOR PIPE FLOW
4. PIPE-FLOW ANALYSIS
5. FRICTION FACTORS FOR FLOW IN THE ENTRANCE TO A CIRCULAR CONDUIT |
To learn how to calculate flow friction. |
講授
|
作業
|
|
| 18 | 期末考 |
期末考 |
期末考 |
|
期末考
|
|