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Gleason Works Chamfering and Deburring Project

This critical design review focuses on improving the chamfering and deburring processes at Gleason Works, a leading supplier of gear cutting technology. The project team aims to address issues with sharp edges, burrs, and efficiency in the current processes. The design proposal includes a smaller footprint, more tilt capabilities, and a lower cost solution. The review also covers topics such as chip removal, automation, enclosure, and stress analysis.

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Gleason Works Chamfering and Deburring Project

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  1. Critical Design Review Senior Design Team 05: Gleason Works – Chamfering and Deburring Project

  2. Team Introduction • Project Manager: Vincenzo Mansueto -ME • Lead Engineer: Matthew Liddick -ME • Team Member: Brian Banazwski -ME • Team Member: Mark Trotta -ME • Team Member: Julie Wilcox -ME • Team Member: Phil Raduns -EE • Team Member: Greg Baesl -ISE • Faculty Advisor: Bill Scarbrough • Gleasons Representative: Eric Mundt

  3. Company Background • Leading world-wide supplier of gear cutting technology • Subdivision of Gleason Corporation • Primary Market • Automobile and truck industries • Secondary Market • Aerospace, Farm, Construction, Marine

  4. Defining the Need • Cutting process for creating gears leaves behind sharp edges and burrs • Danger to workers • Gear strength • Contamination • Aesthetic • Two current processes need improvement or modification

  5. On Machine Apparatus • Not capable of tilt in both directions • Has no scrapper • Burrs still exist after chamfer

  6. GTR 250 • Too slow • 30 rpm max on work spindle • Too expensive • Accuracy of machine is excessive for process • Large footprint

  7. Design Requirements and Deliverables • Requirements • Chamfer and deburr in same cycle • Capable of machining various sizes of gear sets • Price below $130k • Cycle time under 1 minute • As many commercial parts as possible • Decrease footprint • Deliverables • Top level ProE drawings • Market assessment

  8. Design Proposal • ~70% smaller foot-print than GTR • More tilt capabilities than both existing • Lower cost

  9. Process Demonstration

  10. How we arrived at our design • Work Break-down Structure • Cutting Tool Apparatus • Work Piece Apparatus • Stock Divider • Electronics • Enclosure • Customer Interactions • Current process investigations

  11. Tilt Structure

  12. Stock Divider

  13. Time Study

  14. Max Torque Curve

  15. Electrical Components • Servo/Spindle Motors • Drives • CNC Controller

  16. Cost Analysis

  17. Cost Analysis Continued

  18. Future Topics • Chip removal • Automation • Enclosure • More in depth stress analysis • Further VNC analysis to ensure adequate part range and cycle time

  19. Questions? Contact Info: vrm0298@rit.edu

  20. Time Study Breakdown • Test Conditions - Trial #2 • 1,500 RPM – Chamfer Motor • 41 Teeth – Bevel Ring Gear • 4 Revolution & 4-Start Cutter • 0.75mm • Total Cycle Time = 129 sec • Total Chamfering Time = 13.4 sec • Actual Chamfering Time = ~3 sec • Tooth Cutting Time = 109 sec

  21. Max Torque Breakdown • Test Conditions • 1,500 RPM – Chamfer Motor • 41 Teeth – Bevel Ring Gear • 4 Revolution & 4-Start Cutter • 0.75mm and 1.25mm Chamfer Depth • Trial #1 = 41.0 in-lbf  0.75mm • Trial #4 = 92.5 in-lbf  1.25mm • Trial #5 = 95.6 in-lbf  1.25mm • Trial #3 = Off Chart  1.25mm

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