Industrial Robot Development: Difference between revisions
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Mechanical Design Illustrated | Mechanical Design Illustrated | ||
Denavit-Hartenberg Kinematic Parameters Completed | Denavit-Hartenberg Kinematic Parameters Completed for Sample Design | ||
Electrical Design Illustrated | Electrical Design Illustrated | ||
Hydraulic Design Illustrated | Hydraulic Design Illustrated | ||
Stepper Motor - Needle Valve Bracket Design Illustrated | |||
Systems Engineering Diagrams Added | Systems Engineering Diagrams Added | ||
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Research into microcontroller programming | Research into microcontroller programming | ||
Complete force analysis on different mechanical designs | Complete force analysis on different mechanical designs | ||
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Complete all CAD files of the industrial robot | Complete all CAD files of the industrial robot | ||
Complete fully detailed bill of materials | |||
Complete build instructions | Complete build instructions | ||
Revision as of 18:27, 2 June 2011
| Industrial Robot | ||
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| Home | Research & Development | Bill of Materials | Manufacturing Instructions | User's Manual | User Reviews | 
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Progress Report
General Developmental Bill of Materials Completed
Mechanical Design Illustrated
Denavit-Hartenberg Kinematic Parameters Completed for Sample Design
Electrical Design Illustrated
Hydraulic Design Illustrated
Stepper Motor - Needle Valve Bracket Design Illustrated
Systems Engineering Diagrams Added
Task List
Continue design optimization and understanding through research and collaboration
Research into design, construction, and mounting of shaft encoder
Research into design, construction, and mounting of gearbox
Research into microcontroller programming
Complete force analysis on different mechanical designs
Complete calculations for required specifications of various industrial robot components (eg. required pressure and flow from pump, required torque from motors)
Complete all CAD files of the industrial robot
Complete fully detailed bill of materials
Complete build instructions
Complete user's manual
Design Rationale
- Using hydraulic drive over electric drive: electric drive requires complicated electronic circuits, requires a high reduction gearbox (such as harmonic drive, which is complicated to design and fabricate), and is not as scalable as hydraulic drive (for very high loads).
- Needle valves and solenoid valves over proportional servovalves: proportional servovalves experience coil heat buildup that changes the resistance of the solenoid hence diminishes its accuracy of control; proportional servovalves also are more complicated to design and fabricate.
- Stepper motors to allow the electronic control of needle valves: eliminates need to have closed-loop system for needle valve control while maintaining high accuracy through stepping.
- Two plate, four pillar design for foundation: simple to design, fabricate, and assemble, does not require casting with molds while maintaining high degree of stability.
- Angles and bars frame design: simple to design, fabricate, and assemble, does not require casting with molds while maintaining high degree of stability akin to the designs of existing commercial industrial robots.
- Spur gearbox: High efficiency, minimal axial force transmitted onto shaft; simple to design, fabricate, and assemble relative to other gearbox types (such as planetary or harmonic).
- [Type of Encoder]