Movement Assist System

2. Movement Assist System • Concept Validation and Feasibility • Analysis of chosen design • Integration with Other Systems • Results and Conclusion

3. Concept Validation and Feasibility 1 2 • 4 Main Concepts • Feasibility of Crank mechanism • Mechanical Advantage versus difficulty of integration • Chosen Concept 3 4

4. Comparison and Analysis of Designs • Evaluation of straight line crank mechanism • Showed that the device can provide a mechanical advantage due to crank arm • Main concerns and issues are due to actual construction  binding and sticking in joints of links and moving the crank around two end points of arc • Risk of trying to construct this crank versus the benefit resulted in going with regular crank arm • Gear Sets • Large mechanical advantage • Risks in cost and disengagement • Couldn’t find standard made planetary gear sets with the required footprint  too thick/large • Regular Crank directly coupled to shaft provides lowest risk and best design due to ease of integration and has the benefits of a good mechanical advantage

5. Analysis of Chosen Design • FBD of Model and EOM • Minimum Torque Required to move system uphill • Key Assumptions • Rolling without slip • Frictionless bearings • Lumped Masses • Torque input from user is constant through Φ • Required Torque to turn generator is lumped into 1 term, Tmotor, and is constant • Starts from Rest

6. Results With 1.5m Crank

7. Results with Hand on Wheel Rim

8. Conclusion of Movement Assist • Crank Design is feasible by itself and should be able to be achieved • Difficulty is in the user activation/disengagement and integration with other systems • Freewheel • Shaft attachment • Integration with braking and ratchet • Based on CR (component of lowest priority) we are putting this system on hold to focus on more critical systems = Hill holder, Gradual Aid, and Energy Recovery