Machine Design Models1. Create appropriate machine design models that represent real structures and components.
Free Body Diagrams2. Draw a free body diagram of a structure of machine component. Show the loads and calculate the reactions. Draw shear moment diagrams.
Stress from Combined Loadings3. Calculate stress in machine components due to combined loadings.
Deflection Estimates4. Estimate the deflection of structural members under combined loading.
Application of Static Failure Theories5. Select an appropriate static failure theory for a brittle or ductile material and apply it to predict failure loads and safety factors for various geometries and loading conditions.
Stress Analysis6. Analyze the stresses in pressure vessels, press fits, curved beams, bolts, and bolted joints.
Buckling Prediction7. Calculate buckling predictions for statically loaded compression members.
Cyclically Loaded Members8. Construct S-N and Goodman diagrams for cyclically loaded members, calculate mean and alternating stresses and predict safety factors for infinite or finite life.
Design to Prevent Failure9. Design machine members to prevent static, dynamic or fatigue failure. Integrate several components in a system to meet design requirements.
FEA Software10. Gain experience using commercial FEA software to create models of simple structures and machine components. Solve these models to determine deflections and stresses, and understand how to interpret the results for engineering application.
Structured Problem Solving11. Students will gain experience using a structured problem solving technique (e.g. SAFER) to solve machine design engineering problems.
ConVerSAnt Method12. Students will gain increased understanding of machine design problems by exploring solutions using the ConVerSAnt method.
Technical Report13. Students will apply machine design analysis concepts to a real-world problem and document their analysis through well designed figures and graphics as well as a technical report.