MCL311: Difference between revisions
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| credits = 4 | | credits = 4 | ||
| credit_structure = 3-0-2 | | credit_structure = 3-0-2 | ||
| pre_requisites = APL104, MCL211 | | pre_requisites = [[APL104]], [[MCL211]] | ||
| overlaps = AML705, 706, 710 (course should be mutually | | overlaps = [[AML705]], 706, 710 (course should be mutually | ||
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== MCL311 : CAD and Finite Element Analysis == | == MCL311 : CAD and Finite Element Analysis == | ||
exclusive w.r.t these courses) Introduction and overview. Need and Scope of Computer Aided Machine Design. Role of Geometric Modelling, FE and Optimization; 2D and 3D Geometric transformations and projections. The Viewing pipeline; Geometric modeling; Modelling of curves, cubics, splines, beziers and b-splines, NURBS; Modeling of surfaces; Modeling of solids–b-rep, CSG, octree, feature based modeling; Introduction to the Finite Element Method, principle of potential energy; 1D elements, Derivation of Stiffness and Mass matrices for a bar, a beam and a shaft, FEA using 2D and 3D elements; Plain strain and plain stress problems, plates / shell elements; Importance of Finite element mesh, Automatic meshing techniques; Interfacing with CAD software. Introduction to Thermal analysis, Dynamic analysis using eigen values, and Non linear analysis; Limitations of FEM. | exclusive w.r.t these courses) Introduction and overview. Need and Scope of Computer Aided Machine Design. Role of Geometric Modelling, FE and Optimization; 2D and 3D Geometric transformations and projections. The Viewing pipeline; Geometric modeling; Modelling of curves, cubics, splines, beziers and b-splines, NURBS; Modeling of surfaces; Modeling of solids–b-rep, CSG, octree, feature based modeling; Introduction to the Finite Element Method, principle of potential energy; 1D elements, Derivation of Stiffness and Mass matrices for a bar, a beam and a shaft, FEA using 2D and 3D elements; Plain strain and plain stress problems, plates / shell elements; Importance of Finite element mesh, Automatic meshing techniques; Interfacing with CAD software. Introduction to Thermal analysis, Dynamic analysis using eigen values, and Non linear analysis; Limitations of FEM. | ||
Latest revision as of 16:38, 14 April 2026
| MCL311 | |
|---|---|
| CAD and Finite Element Analysis | |
| Credits | 4 |
| Structure | 3-0-2 |
| Pre-requisites | APL104, MCL211 |
| Overlaps | AML705, 706, 710 (course should be mutually |
MCL311 : CAD and Finite Element Analysis
exclusive w.r.t these courses) Introduction and overview. Need and Scope of Computer Aided Machine Design. Role of Geometric Modelling, FE and Optimization; 2D and 3D Geometric transformations and projections. The Viewing pipeline; Geometric modeling; Modelling of curves, cubics, splines, beziers and b-splines, NURBS; Modeling of surfaces; Modeling of solids–b-rep, CSG, octree, feature based modeling; Introduction to the Finite Element Method, principle of potential energy; 1D elements, Derivation of Stiffness and Mass matrices for a bar, a beam and a shaft, FEA using 2D and 3D elements; Plain strain and plain stress problems, plates / shell elements; Importance of Finite element mesh, Automatic meshing techniques; Interfacing with CAD software. Introduction to Thermal analysis, Dynamic analysis using eigen values, and Non linear analysis; Limitations of FEM.