Express-O Commuter Trike DESIGN PROJECT PRESENTATION Department of Mechanical Engineering Dalhousie University Halifax, Nova Scotia
Team 4 – Express-O Clients Supervisor Dr. A. Warkentin Dept. of Mechanical Eng. Dalhousie University Matthew Rockwell Matthias Eisengruber Jayme Whalen Patricia Gillis Ahad Ahmed
Problem Definition PROBLEM SOLUTION Congested Highways Increase in Commuter traffic in HRM Congested Highways Environmental Pollution Parking space shortages SOLUTION Environmentally Friendly Reduce traffic congestion Average business person
Express-O Design Drive Train Frame Braking Banking Steering
Rear Triangle from Bicycle Frame and Seat Re-use rear triangle Adjustable seat 60o from Horizontal 1 3/8” Chromoly Steel Tubing Rear Triangle from Bicycle
Drivetrain 80 rpm [ Comfortable, Efficient pedal cadence Gearing 3 X 7 Rear drive train Fixed ratio Front drive train
Drivetrain High Gear 1 : 3.5 Gear Ratio Max Speed @ 80rpm input: 35 km/h Low Gear 1 : 0.69 Gear Ratio Max Speed @ 80rpm input = 6.8 km/h Front Middle Rear
Chain Routing
Braking Dual Front Disc Brakes Radical© Brand Mechanical Disc Brakes
Tilting: Theory Shifts Center of Gravity Normal Force on inside wheel is increased Tipping occurs when Normal force = 0 D F mg FF A y x a b FN y y H H
Tilting: Theory Turning Velocity h Stability in Turns h
Tilting: Links Thickness of Link – 1” thick x 1.5” high Holes for bushing and spring housing Bushing Horizontal Tilt Link Diamond Plate
Steering: Theory Ackerman Steering Centre Point Steering Caster Effect Wheel Camber
Steering: Rider Input Vertical Steering Arms Located at both sides of the rider Can move forward and backward Connected to L-bracket on bottom of the stub axle
Manufacturing Parts needed for Assembly : Qty 88 Parts Tasks: Acquisition of Material Off the Shelf – 44 parts Student built – 32 parts Technician Built – 12 parts Dimensioning Machining Welding Assembly
Major Design Changes Tilting System Materials Brakes Drive train
Changes to Tilting System Replaced bearings with bushings Closer fit More contact surface Added springs Static stability Return from banking position
Changes to Materials Most parts originally designed to be fabricated from steel To reduce weight, cost some parts were fabricated from aluminum These include: Horizontal tilt links Steering L-brackets Steering arms
Changes to Brakes Omitted rear V-brake Vehicle now has dual front disc brakes only Disc brakes provide sufficient braking power Simplified the braking system
Changes to Drive Train Originally designed to have three derailleurs Now has two derailleurs Lower gear ratio
Analysis Finite Element Analysis Design Requirements: Horizontal Tilt Links Stub Axles Design Requirements: Survive: 5Km/H impact with curb 0.16 m drop off curb Safety Factor: 3
FEM RESULTS Max Force: Max Stress: Al 6061 T6 Yield Strength: 1800 N 90 MPa Al 6061 T6 Yield Strength: 276 MPa
Stub Axles Max Force: 1020 Steel Yield Strength: 1800 N Max Stress: 200 MPA 1020 Steel Yield Strength: 346 MPa
Future Improvements Horizontal Tilt Link Mounts Chain Pulley Brackets Spherical Ball Ends Spring and Damper Set Up Seat
Horizontal Tilt Link Mounts Problem: Cantilevered Bolt acts a Pivot Bolt bends when forces act on Links Fix: Second Diamond Plate
Chain Pulley Brackets Problem: Fix: Cantilevered Bolt Bolt bends when Chain is under tension Regular Idler Gear not designed to run on an angle Fix: Second Adjustable Plate
Spherical Ball Ends Problem: Fix: Inexpensive Rod Ends with unknown load rating Not quite enough freedom to move Premature Failure Fix: Higher Budget to buy specked out Rod Ends
Spring and Damper Set Up Problem: Springs need to be adjusted according to rider weight for smooth banking Banking motion is not continuous Fix: Adjustable Spring Mounts Light Damper to “smooth out” banking motion
Seat Problem: Fix: Not enough side support Makes leaning into corners harder Fix: Deeper Sling Seat Design
Accessories Lexan/Plexiglas Enclosure Lights Flag More Storage Compartments Toolkit Cup holder
Original Scope Ergonomics Safety Durability Materials Costs Complexity Physical Specs Ergonomics Materials Costs
Safety Safe to operate Visible in traffic Stable Durable Protection of rider from moving parts
Durability Withstand environmental conditions This has not been fully tested Withstand road conditions (i.e. potholes) Seems to ride well on road surfaces Survived speed bumps!
Complexity Simple & Functional Easy to Manufacture & Repair Standard “off-the-shelf” Parts Brakes Wheels Chaining Rear Triangle
Physical Specs Original Dimensions Actual Dimensions Width: 1.5m Length: 3m Height: 2m Weight: 50kg Actual Dimensions Width: 1.12m Length: 2.15m Height: 0.82m Weight: 29kg
Ergonomics Sized comfortably for one adult Adjustable seat to pedal distance Seat at a comfortable height Simple to operate Intuitive steering Learning curve to mastering tilting Easy to Mount/Dismount Relatively easy – except position of tilt links
Ergonomics (continued) Reduced physical power input Relatively easy to pedal Protection from weather Not included due to time and money Options for future adaptations Cargo Space to fit backpack/briefcase Rack over rear wheel Extra space behind seat
Materials Minimize costs and meet design requirements Recycled Parts Donated Material Light, durable, easily machined Changed some parts to aluminum Durability issues with the chaining Stub axles were the most complicated part
Cost Ceiling price of $2000 Total estimated cost $1221.96 ($785.95 with donations) Actual cost $825.15 Keep cost to a minimum Donated Material Recycled Parts Money Donations Necessary but expensive parts Additional costs for bolts, springs, etc.
Criteria Table Criteria Satisfied Room for Improvements Safety Durability Complexity Physical Specs Ergonomics Materials Costs
Testing Performance Goals Turning Radius Cruising Speed Maximum Speed Stability Stopping Distance Reliability
Cornering / Turning Radius Goal Capable of maneuvering on city streets Test Result Acceptable turning radius of 6m @ 15km/h
Cruising / Max Speed Goal Test Result Comfortable cruising speed of 15km/h Maximum speed of approximately 50km/h Test Result 15km/h is easily attainable Maximum Speed obtained of 45km/h
Stability Goal Test Result Stable when stationary (i.e. Stoplight) Stable at high speed Stable while cornering Test Result Stable with the aid of front brakes and practice Low speed stability is slightly less than desired High speed stability is as expected Performs very well at high speeds “Hugs” tight corners at high speeds
Stopping Distance Goal Test Result Maximum stopping distance of 6m At cruising speeds (~15km/h) : <2m At max speed (45km/h): 7m
Reliability Goal Test Result 1350km/year with minimal maintenance Chain tension system on the prototype is not very reliable Tilting linkage would require frequent adjustment
Conclusion Performance Size and Weight Cost Safe FUN
Thank You Angus & Albert Paddy Wong & Zack Gus Reed Sportwheels & Bike Doctor Dr. Warkentin
QUESTIONS?