研究生课程开设申请表
开课院(系、所): 能源与环境学院
课程申请开设类型: 新开□ 重开√ 更名□(请在□内打勾,下同)
课程
名称
中文
高等流体力学
英文
Advanced Fluid Mechanics
待分配课程编号
S003106
课程适用学位级别
博士
硕士
√
总学时
54
课内学时
51
学分
3
实践环节
用机小时
3
课程类别
□ 公共基础 □ 专业基础 □√ 专业必修 □ 专业选修
开课院(系)
动力系
开课学期
春季
考核方式
A. □ 笔试( □开卷 □闭卷) B. □ 口试
C. □ 笔试与口试结合 D. √其他 笔试与上机结合
课程负责人
教师
姓名
归柯庭
职称
教授
e-mail
ktgui@seu.edu.cn
网页地址
授课语言
汉语
课件地址
适用学科范围
一级
所属一级学科名称
动力工程及工程热物理
实验(案例)个数
无
先修课程
工程流体力学(本科)
教学用书
教材名称
教材编者
出版社
出版年月
版次
主要教材
高等流体力学
归柯庭
讲义
主要参考书
流体力学
吴望一
北京大学出版社
1988.6
张量分析与流体力学
陈佐一、蒋滋康
科学出版社
1990.8
粘性流体力学
刘明杰等
高等教育出版社
1987.6
高等流体力学
刘应中等
上海交通大学出版社
2000.6
高等流体力学
周云龙等
中国电力出版社
2008.6
一、课程介绍(含教学目标、教学要求等)(300字以内)
流体力学是动力工程与工程热物理学科中的重要基础课程,是学习涡轮机械,传热,燃烧等课程的必要基础。要求学生掌握:流体运动的基本特性,基本方程;粘性流体绕流物体表面时的边界层微分方程及其相似性解、积分解;湍流运动方程及其基本解法;典型湍流流动及其边界层的基本特征;湍流模型及其工程适用;流体运动方程的数值求解。
二、教学
(含章节目录):(可附页)
第一章 流体运动的基本特性
概述;粘性流体与理想流体;可压缩流体与不可压缩流体;应力张量;张量知识简介;广义牛顿内摩擦定律
第二章 流体运动的基本方程
连续性方程;运动方程;能量方程;状态方程;方程组的封闭性和定解条件;粘性流体运动的几个基本特性
第三章 几种特殊条件下的流体运动方程解
流体运动方程解的讨论;充分发展的管内定常流流动;两平板间的定常流动;旋转圆筒间流体的定常流动;具有运动边界的非定常流动;流体绕圆球的缓慢运动
第四章 边界层微分方程及其相似性解
边界层的基本概念;二维层流边界层微分方程;三种边界层的厚度;边界层的分离现象;二维层流边界层方程的相似性解;绕契形体流动的佛克纳-斯肯解
第五章 二维层流边界层的积分解
边界层动量积分关系式;单参数速度剖面;卡门-波尔浩森单参数解法;霍斯汀改进解法;斯韦茨解法
第六章 湍流的基本理论
湍流的基本概念;湍流的基本方程(时均连续性方程、运动方程、雷诺应力、平均动能方程、湍动能方程);湍流统计理论(脉动量关联、能谱分析、能量级串与涡拉升、科尔莫高洛夫局部各向同性假设与湍能谱的-5/3幂次律);湍流统计方程的封闭性。
第七章 湍流模型
Spart-Alpla单方程模型、k-ε双方程模型(
k-ε模型、RNG k-ε模型和带旋流修正的k-ε模型)、雷诺应力模型、大涡模拟模型(标准 k-ω模型、剪切压力传输SST k-ω模型);不同湍流模型的工程适用范围。
第八章 典型的湍流流动
湍流边界层;自由剪切湍流;管内湍流。
第九章 两相流基础
两相流的定义及其分类、两相流动主要参数及其分类、两相流动基本方程、两相和多相流体力学的发展现状及其工程应用。
第十章 流体流动的数值模拟
数值模拟在流体流动中的应用实例;流体流动的数值模拟
;工程湍流模拟
三、教学周历
周次
教学内容
教学方式
1
本课程概况,粘性流体运动的基本特征,应力张量简介
讲授
2
广义牛顿内摩擦定律,流体运动的连续性方程,运动方程
讲授
3
能量方程,粘性流体运动的基本特性
讲授
4
流体运动方程解的讨论,流体绕圆球的斯托克斯运动
讲授、讨论
5
边界层微分方程,边界层的分离
讲授、讨论
6
二维层流边界层方程的相似性解
讲授
7
绕契形体流动的佛克纳-斯肯解
讲授
8
边界层动量积分关系式,单参数速度剖面
讲授
9
卡门-波尔浩森解,霍斯汀解,斯韦茨解
讲授
10
湍流运动的基本概念、基本方程
讲授、讨论
11
湍流统计理论; 湍流统计方程的封闭性
讲授
12
湍流模型及其工程适用范围
讲授
13
湍流边界层
讲授
14
自由剪切湍流和管内湍流
讲授
15
两相流基础
讲授、讨论
16
数值模拟在流体流动中的应用实例
讲授
17
流体流动的数值模拟方法、工程湍流模拟
讲授、上机实践
18
考试
上机实践、笔试
注:1.以上一、二、三项内容将作为中文教学大纲,在研究生院中文网页上公布,四、五内容将保存在研究生院。2.开课学期为:春季、秋季或春秋季。3.授课语言为:汉语、英语或双语教学。4.适用学科范围为:公共,一级,二级,三级。5.实践环节为:实验、调研、研究报告等。6.教学方式为:讲课、讨论、实验等。7.学位课程考试必须是笔试。8.课件地址指在网络上已经有的课程课件地址。9.主讲教师简介主要为基本信息(出生年月、性别、学历学位、专业职称等)、研究方向、教学与科研成果,以100至500字为宜。
四、主讲教师简介:
归柯庭,男,1957年2月出生,东南大学动力系教授,博士生导师。长期从事气固两相流动与大气污染控制方面的教学与科研工作。主持完成三项、参与完成多项国家自然科学基金资助项目的研究和多项部、省级科研课题的研究,发表
80多篇,出版译著一部,教材一部,主讲研究生课程两门和本科生课程十余门。获国家教委科技进步二等奖一项,专利两项。现正指导博士生、硕士生多名,主持一项国家自然科学基金资助项目的研究和参与两项国家重点基础研究发展
项目(973)的研究。
五、任课教师信息(包括主讲教师):A/B
任课
教师
学科
(专业)
办公
电话
住宅
电话
手机
通讯地址及电子邮件
邮政
编码
归柯庭
工程热物理
83792505
83791665
ktgui@seu.edu.cn
210096
钟文琪
热能工程
83794744
139********
wqzhong@seu.edu.cn
210096
Application Form for Opening Graduate Courses
School (Department/Institute):School of Energy and Environment
Course Type: New Open □ Reopen √ Rename □(Please tick in □, the same below)
Course Name
Chinese
高等流体力学
English
Advanced Fluid Mechanics
Course Number
S00302
Type of Degree
Ph. D
Master
√
Total Credit Hours
54
In Class Credit Hours
51
Credit
3
Practice
Computer-using Hours
3
Course Type
□Public Fundamental □Major Fundamental □Major Compulsory □Major Elective
School (Department)
Power Engineering
Term
Spring
Examination
A. □Paper(□ Open-book □ Closed-book) B. □Oral
C. □Paper-oral Combination D. √ Others Paper-computer Combination
Chief
Lecturer
Name
Guii Keting
Professional Title
Professor
E-mail
ktgui@seu.edu.cn
Website
Teaching Language used in Course
Chinese
Teaching Material Website
Applicable Range of Discipline
Name of First-Class Discipline
Power Engineering & Engineering Thermophysics
Number of Experiment
Preliminary Courses
Engineering Fluid Mechanics
Teaching Books
Textbook Title
Author
Publisher
Year of Publication
Edition Number
Main Textbook
Advanced Fluid Mechanics
Gui Keting
Main Reference Books
Fluid Mechanics
Wu Wangyi
Peking University Press
1988.6
Analysis of tension in fluid
Chen Zuoyi et. al
Science Press
1990.8
Viscous Fluid Mechanics
Liu Mingjie et. al
High Education Press
1987.6
Advanced Fluid Mechanics
Liu Yingzhong et.al
Shanghai Jiaotong University Press
2000.6
Advanced Fluid Mechanics
Zhou Yunlong et.al
Chinese Electric Powder Press
2008.6
I. Course Introduction (including teaching goals and requirements) within 300 words:
Fluid mechanics is a discipline within the broad field of applied mechanics concerned with the behavior of liquids and gases at rest or in motion. It is the base of the courses of Heat Transfer and Combustion. Through study the course of Advanced Fluid Mechanics; students should master the principle of fluid flow, the basic equations of fluid mechanics, boundary layer characteristics, special turbulent flow, turbulence model, numerical simulation of fluid flow etc.
II. Teaching Syllabus (including the content of chapters and sections. A sheet can be attached):
Ch.1 Fundamental properties of fluid flow
Introduction, viscous fluid and ideal fluid, compressible fluid and incompressible fluid, stress tensor, introduction to tensor, generalized Newton’s frictional law
Ch.2 Basic equations of fluid mechanics
Continual equation, momentum equation, energy equation, initial condition and boundary condition, some basic properties of viscous fluid flow
Ch3. Solutions of fluid equations under some special conditions
Discussion for the solutions of fluid equations, fully developed steady flow in pipes, steady flow in two plates, steady flow in rotative cylinders, unsteady flow with movement boundary
Ch.4 Boundary layer differential equation and its similar solution
Basic concepts of boundary layer, two dimensional boundary layer differential equation, thickness of three kinds boundaries, separation of boundary, similar solution of two dimensional boundary layer differential equation, Falkner-Skan solution of fluid flow
Ch.5 Two dimensional boundary layer equation and its integral solution
Momentum integral equation in boundary, velocity section with single parameter, Pohlhausen solving method with single parameter, Holstein method, Thwaites method
Ch.6 basic theory of turbulent flow
Basic concepts of turbulent flow, fundamental equation of turbulent flow (equation of continuity, equation of motion, Reynolds stress, equation of average kinetic energy, equation of turbulent kinetic energy), statistical theory of turbulent flow (scalar correlation-moment, energy spectrum analysis, energy cascade and vortex ascending, local isotropy hypothesis and -5/3 powder law of turbulent energy spectrum), closeness of turbulent statistic equation.
Ch.7 turbulence model
Spart-Alpla single equation model, k-ε two equations model (standard k-ε model, RNG k-ε model and k-ε model with swirl modified), Reynolds stress model, large eddy simulation model (standard k-ε model, shear stress transfer SST k-ε model), application range in engineering of different turbulent model.
Ch.8 the typical turbulent flow
Turbulent flow on flat wall, free shears turbulent flows, turbulent flow in pipe.
Ch.9 fundamental of two-phase flow
Definition and classify of two-phase flow, the main parameter and fundamental equation of two-phase flow, the developing situation and engineering application of two-phase and multi-phase flow.
Ch.10 Numerical simulation of fluid flow
Tpical applications of numerical simulation to fluid flow;Difference method, finite unit method, SIMPLEC method; simulation on engineering turbulence
III. Teaching Schedule:
Week
Course Contents
Teaching Method
1
Course introduction, fundamental properties of viscous fluid flow, stress tensor introduction
lecture
2
generalized Newton’s law, continual equation, momentum equation of fluid flow
lecture
3
energy equation, some basic properties of viscous fluid flow
lecture
4
discussion for the solutions of fluid equations, stokes motion of fluid flow bypass the ball
Lecture, discussion
5
boundary layer differential equation, separation of boundary
Lecture, discussion
6
similar solution of two dimensional boundary layer differential equation
lecture
7
Falkner-Skan solution of fluid flow
lecture
8
momentum integral equation in boundary, velocity section
lecture
9
Pohlhausen method, Holstein method, Thwaites method
discussion
10
basic concepts of turbulent flow, fundamental equation of turbulent flow
Lecture, discussion
11
statistical theory of turbulent flow, closeness of turbulent statistic equation
lecture
12
turbulent model and its application range in engineering
lecture
13
boundary layer of turbulent flow
lecture, discussion
14
free shears turbulent flows, turbulent flow in pipe
lecture
15
fundamental of two-phase flow
Lecture, discussion
16
tpical applications of numerical simulation to fluid flow
lecture
17
numerical simulation of fluid flow and simulation on engineering turbulence
lecture , practice in
computer
18
Examination
Practice in computer, examination
Note: 1.Above one, two, and three items are used as teaching Syllabus in Chinese and announced on the Chinese website of Graduate School. The four and five items are preserved in Graduate School.
2. Course terms: Spring, Autumn , and Spring-Autumn term.
3. The teaching languages for courses: Chinese, English or Chinese-English.
4. Applicable range of discipline: public, first-class discipline, second-class discipline, and third-class discipline.
5. Practice includes: experiment, investigation, research report, etc.
6. Teaching methods: lecture, seminar, practice, etc.
7. Examination for degree courses must be in paper.
8. Teaching material websites are those which have already been announced.
9. Brief introduction of chief lecturer should include: personal information (date of birth, gender, degree achieved, professional title), research direction, teaching and research achievements. (within 100-500 words)
IV. Brief Introduction of Chief lecturer:
Gui Keting received the Ph.D. degree in Thermal Engineering from Southeast University in 1998, the M. Sc. degree in Engineering Thermophysics from Southeast University in 1991 and B. Sc. degree in physics from Nanjing Institute of Technology in 1982. He is now a professor in Department of Power Engineering, Southeast University. His research areas are multiphase flow, control of air pollution and measurement in thermal engineering. He has published more than 80 papers in his research areas, and won some awards from State Education Commission of China.
V. Lecturer Information (include chief lecturer)
Lecturer
Discipline
(major)
Office phone number
Home Phone Number
Mobile Phone Number
Email
Postcode
Gui Keting
Engineering Thermophysics
83792505
83791665
ktgui@seu.edu.cn
210096
Zhong Wenqi
Thermal
Engineering
83794744
139********
wqzhong@seu.edu.cn
210096