NCHU Course Outline
Course Name (中) 流體力學導論(6731)
(Eng.) Fundamentals of Fluid Mechanics
Offering Dept Department of Mechanical Engineering
Course Type Elective Credits 3 Teacher Keng-Lin Lee
Department Department of Mechanical Engineering/Graduate Language 中/英文 Semester 2026-FALL
Course Description 本研究所課程涵蓋流體力學的核心理論與分析方法,由流體的基本性質與流體運動學出發,逐步建立流體統御方程式的理論基礎,並介紹流體力學的重要進階主題,包括層流、無黏性流、邊界層流與紊流等。本課程透過循序漸進的理論建構與物理觀念分析,學生將具備深入理解流體流動現象、分析複雜流場及解決流體力學問題的能力,並為後續高階研究與工程實務應用奠定扎實基礎。
Prerequisites
self-directed learning in the course Y
Relevance of Course Objectives and Core Learning Outcomes(%) Teaching and Assessment Methods for Course Objectives
Course Objectives Competency Indicators Ratio(%) Teaching Methods Assessment Methods
1.探討基本的流體力學現象與原理。
2.連結流體力學數學模式與物理現象之關係。
1.The ability to solve engineering problems independently with professional knowledge in mechanical engineering.
2.The ability to think innovatively, plan and conduct research projects and to present research outcome in a professional format.
3.The ability to manage multi-disciplinary teams and to integrate cross-field technologies..
6.The knowledge of professional ethics and social responsibilities of a mechanical engineer.
50
15
15
20
Lecturing
Assignment
Quiz
Course Content and Homework/Schedule/Tests Schedule
Week Course Content
Week 1 1. 基本概念(Fundamental Concepts)
Week 2 2. 流體運動學(Fluid Kinematics)
Week 3 2. 流體運動學(Fluid Kinematics)
Week 4 3. 統御方程式(Governing Equations)
Week 5 3. 統御方程式(Governing Equations)
Week 6 4. 層流(Laminar Flow)
Week 7 4. 層流(Laminar Flow)
Week 8 4. 層流(Laminar Flow)
Week 9 Midterm Exam
Week 10 5. 無黏性流(Inviscid Flow)
Week 11 5. 無黏性流(Inviscid Flow)
Week 12 5. 無黏性流(Inviscid Flow)
Week 13 6. 邊界層與紊流(Boundary Layer and Turbulent Flow)
Week 14 6. 邊界層與紊流(Boundary Layer and Turbulent Flow)
Week 15 6. 邊界層與紊流(Boundary Layer and Turbulent Flow)
Week 16 Final Exam
self-directed
learning
   02.Viewing multimedia materials related to industry and academia.

Evaluation
Homework 30%, Midterm exam 30%, Final exam 40%
Textbook & other References
Main Textbooks
- Kundu, P. K., Cohen, I. M., & Dowling, D. R. Fluid Mechanics. 6th ed., Academic Press, Elsevier, 2015.
- Munson, B. R., Young, D. F., Okiishi, T. H., & Huebsch, W. W. Fundamentals of Fluid Mechanics. 9th ed.
- Çengel, Y. A., Cimbala, J. M., & Turner, R. H. Fluid Mechanics: Fundamentals and Applications. 4th ed.

Additional References
- Currie, I. G. Fundamental Mechanics of Fluids. McGraw-Hill.
- Panton, R. L. Incompressible Flow. John Wiley & Sons.
- Batchelor, G. K. An Introduction to Fluid Dynamics. Cambridge University Press.
- Anderson, J. D. Fundamentals of Aerodynamics. McGraw-Hill.

Fluid Flow Visualization
- Van Dyke, M. An Album of Fluid Motion. The Parabolic Press, Stanford, California.
Teaching Aids & Teacher's Website
自編筆記、iLearning 數位教學平台
Office Hours
星期三-下午15:00-17:00
Sustainable Development Goals, SDGs(Link URL)
include experience courses:N
Please respect the intellectual property rights and use the materials legally.Please respect gender equality.
Update Date, year/month/day:2026/07/08 21:22:34 Printed Date, year/month/day:2026 / 7 / 09
The second-hand book website:http://www.myub.com.tw/