The page uses Browser Access Keys to help with keyboard navigation. Click to learn moreSkip to Navigation

Different browsers use different keystrokes to activate accesskey shortcuts. Please reference the following list to use access keys on your system.

Alt and the accesskey, for Internet Explorer on Windows
Shift and Alt and the accesskey, for Firefox on Windows
Shift and Esc and the accesskey, for Windows or Mac
Ctrl and the accesskey, for the following browsers on a Mac: Internet Explorer 5.2, Safari 1.2, Firefox, Mozilla, Netscape 6+.

We use the following access keys on our gateway

n Skip to Navigation
k Accesskeys description
h Help
Cornell University    
 
    
 
  Dec 11, 2017
 
Courses of Study 2017-2018
[Add to Favorites]

MAE 4701 - Finite Element Analysis for Mechanical and Aerospace Design


     
Fall. 4 credits. Letter grades only.

Prerequisite or corequisite: MAE 4300 , or permission of instructor. Enrollment limited to: senior standing or permission of instructor. Fulfills Senior Design requirement for M.E. majors. Co-meets with MAE 4700 /MAE 5700 .

H. Ritz.

Introduction to linear finite element static analysis for discrete and distributed mechanical and aerospace structures. Prediction of load, deflection, stress, strain, and temperature distributions. Major emphasis on underlying mechanics and mathematical formulation. Introduction to computational aspects via educational and commercial software (such as MATLAB and ANSYS). Selected mechanical and aerospace applications in the areas of trusses, beams, frames, heat transfer, and elasticity. A selection of advanced topics such as dynamic modal analysis, transient heat transfer, or design optimization techniques may also be covered, time permitting.

Outcome 1: Students will understand the mathematical and physical principles underlying the FEM as applied to solid mechanics, thermal analysis and select aspects of fluid mechanics.

Outcome 2: Be able to create his/her own FEM computer programs, for mathematically simple but physically challenging problems, in MATLAB.

Outcome 3: Be able to compare FEM results obtained with MATLAB with those obtained from ANSYS. Analyze more complex problems (in solid mechanics or thermal analysis) using the commercial FEM code ANSYS.

Outcome 4: Demonstrate the ability to design a component using FEM analysis (both MATLAB AND ANSYS).

Outcome 5: Make clear and effective technical presentations, both in terms of form as well as content, of his/her work and write clear technical reports describing his/her work.



[Add to Favorites]