Fluid Mechanics (I)

Lecturer: Ruey-Syan Shih (石瑞祥)

Phone: (02) 2462-2192 #6107

Webpage: hreweb.ntou.edu.tw/p/405-1059-47616,c8049.php?Lang=zh-tw

Course ID: B520293B

Credits: 3

Objective: This course is to provide the physical and mechanic concepts of fluids for students majored in engineering fields. The fluid properties and fluid motions and dynamics are also introduced in the course.

Course Prerequisites: None

Outline:

1. Introduction

2. Fluid Static

3. Fluid Kinematics

4. Fluid Dynamics

5. Finite Control Volume Analysis

6. Differential Analysis of Fluid Flow

7. Dimensional Analysis, and similitude

8. Viscous Pipe Flow

9. Open Channel Flow

Teaching Method: The lecture content and examples will be explained and discussed in class according to the established content of the course. There will be homework and discussion after each chapter.

Reference: "Fundamentals of Fluid Mechanics” By Bruce R. Munson, Donald F. Young, Theodore H. Okiishi, Wade W. Huebsch, 6th Edition, 2010, John Wiley & Sons

Course Schedule (subject to change):

According to the outline, basically, the class will be taught before the mid-term exam and the progress will be Chapter 5. The teaching content in the second half of the semester will be Chapters 6-9. However, the actual progress will be slightly adjusted depending on the students'' level and response.

Evaluation:

Midterm exam 30%

Final exam 30%

Five or more homework. 30%

Usual grades 10%

Lecturer: Wen-Yang Hsu (許文陽)

Email: wyhsu@mail.ntou.edu.tw

Phone: (02) 2462-2192 #6113

Webpage: https://hreweb.ntou.edu.tw/p/404-1059-103258.php?Lang=zh-tw

Course ID: B520293B

Credits: 3

Objective: Introduction to Fluid Characteristics and Fluid Motion Laws and Analysis. Additionally, an introduction to the dynamic characteristics of fluids and their phenomena and analysis.

Course Prerequisites: Calculus, General Physics.

Outline:

1. Introduction

2. Fluid Properties

3. Fluid Statics

4. The Bernoulli Equation and Pressure Variation

5. The Control Volume Approach and The Continuity Equation

6. The Momentum Equation

7. The Energy Equation

8. Dimensional Analysis and Similitude

Teaching Method: Textbooks and Supplementary Materials

Reference: "Engineering Fluid Mechanics" Donald F. Elger, Barbara A. LeBret, Clayton T. Crowe, John A. Roberson

Course Schedule (subject to change):

Week 1 2024-09-11(Wed.) CHAPTER 1 Introduction

Week 2 2024-09-18(Wed.) CHAPTER 2 Fluid Properties

Week 3 2024-09-25(Wed.) CHAPTER 3 Fluid Statics 4 2024-10-02(Wed.) CHAPTER

Week 4 The Bernoulli Equation and Pressure Variation

Week 5 2024-10-09(Wed.) CHAPTER 4 The Bernoulli Equation and Pressure Variation

Week 6 2024-10-16(Wed.) CHAPTER 5 The Control Volume Approach and The Continuity Equation

Week 7 2024-10-23(Wed.) Midterm Exam

Week 8 2024-10-30(Wed.) CHAPTER 5 The Control Volume Approach and The Continuity Equation

Week 9 2024-11-6(Wed.) CHAPTER 6 The Momentum Equation

Week 10 2024-11-13(Wed.) CHAPTER 6 The Momentum Equation

Week 11 2024-11-20(Wed.) CHAPTER 7 The Energy Equation

Week 12 2024-11-27(Wed.) CHAPTER 7 The Energy Equation

Week 13 2024-12-04(Wed.) CHAPTER 8 Dimensional Analysis and Similitude

Week 14 2024-12-11(Wed.) CHAPTER 8 Dimensional Analysis and Similitude

Week 15 2024-12-18(Wed.) （No Class）

Week 16 2024-12-25(Wed.) Final Examination

Evaluation:

Midterm exam 50%

Final exam 50%

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