### Theory and Technique of Engineering Structure Experiments

The course contents include: design theory test engineering structures, engineering structures load testing technology, engineering, structural testing measurement technology, engineering, structural testing of data acquisition and processing technology, and engineering structures on-site testing and evaluation technology. The goals of this course are to make engineering graduate grasp the basic theoretical knowledge and basic practical skills about structural testing. Moreover, they could carry out general engineering design and implementation of structural testing.

### Reinforced concrete: Mechanics and Design

1. Introduction (2学时)；

2. The design process (2学时)

3. Materials （4s\vl VEs\vl V4. Flexure: Basic concepts, rectangular beams (4学时)

5. Flexure: T beams, Beams with compression reinforcement, and special cases (4学时)

6. Shear in beams (4学时)

7. Torsion （4学时）

8. Development, anchorage, and splicing of reinforcement （4学时）

9. Serviceability (4学时)

10. Continuous beams and one-way slabs (4学时)

11. Columns: Combined axial load and bending （4学时）

12. Slender columns （4学时）

13. Two-way slabs: Behaviour, analysis, and direct design method （4学时）

14. Equivalent Frame method (4学时)

15. Two-way slabs: elastic, yield line, and strip method analysis （4学时）

16. Walls and shear walls （4学时）

17. Design of earthquake resistance （4学时）

### Computational Fluid Dynamics

This course introduces students to the fundamentals of numerical analysis and computational methods for solving engineering fluid dynamic problems. It enables students to using modern Computational Fluid Dynamics (CFD) packages.

Contents: Introduction, Governing equations of fluid dynamics, Partial Differential Equations (PDE): classification, characteristics and numerical methods, the basics of the Finite Difference Method (FDM) and the Finite Volume Method (FVM), initial conditions and boundary conditions, turbulence, introduction to turbulence modelling, Reynolds Averaged Navier-Stokes (RANS) equations, Large-Eddy Simulation (LES) and Direct Numerical Simulation (DNS), an introduction of Fluent®, applying Fluent® for solving engineering fluid dynamic problems.

### 水利工程实验技能

水流运动是一种非常复杂的自然现象，对各种作用力存在的情况和它们发展的规律，至今还没能很好地掌握。设计水利工程时通常采用用数学分析的方法，或经验公式。这两种方法都有一定的局限性。比如为了解决数学分析的困难，在推导理论方程之前需加上各种假设进行简化；在求解方程过程中，对高次项往往加以省略。因此，根据理论公式设计后，还要经过水工模型试验的验证再付诸实施，以保证工程的安全。其次，应用经验公式虽较可靠，但其系数仍有一定的使用条件和范围，不能任意推广。事实上，天然河道中的水工建筑物的边界条件各不相同，且非常复杂，须经水工模型试验的分析研究，方可切合实际，还可进一步提高理论，指导实践。因此，水工模型试验是流体力学理论和实际水利工程中间的媒介。

通过本课程学习，使水利学科的学生学会进行科学研究的方法和手段，掌握水工模型的制造与安装、各种试验数据的获得方法和仪器工作原理以及操作技巧、试验数据的分析方法、试验报告的编写等。