OSU Solar Vehicle Team

1. SVT Oregon State University Solar Vehicle Team OSU Solar Vehicle Team

2. Background Information – Solar Cars • Solar panels directly on car • Completely enclosed system • No external energy input • Aux. battery pack to store excess energy for later usage • Solar cars mainly seen in two events • North American Solar Challenge (NASC) • World Solar Challenge (WSC)

3. Solar Car Races: NASC and WSC • World Solar Challenge • 3000 km race from Darwin to Adelaide • 10 day race • North American Solar Challenge • 2400 mile race from Dallas, TX to Calgary, Canada • Highway format • Highway speeds, traffic • Must be street legal (auto insurance, plates, VIN, etc) WSC

4. Solar Car Races: NASC and WSC • Fastest cars in World Solar Challenge can go faster than 142 kph • Top 2 to 3 vehicles can sustain posted speeds throughout race NASC 2008

5. Solar Array and Batteries • 6 m2 or 9 m2 solar array surface area allowed • Generates around 1800W (2.4 HP) peak with triple junction GaAs • Batteries only store 5 kWH (1.34 HP for 5 hrs) • How is propulsion possible? Triple junction GaAs cell [2]

6. Forces and Power Balance Pin = small, maximized Fdrag minimized Pout = small, maximized

7. Design Goals • Efficient power input • Efficient power usage • Low aerodynamic drag • Low mass

8. Efficient Power Input – Best Cars • > 26% efficient, triple junction GaAs array on fastest cars • > 98% efficiency electronics • High efficiency Li-Ion/LiFePO4 for charging and discharging. • Concentrators used on Univ. of Michigan car U of M solar car evening charging with concentrator sub-array

9. Lowering drag • Reduced weight • Carbon fiber • Aluminum/Titanium chassis • Most cars weigh 200 to 300kg • Better areo • Cd of .21 • .741 m2 cross sectional area • Cd * A = .156 • CFD/wind tunnel testing • Attention to detail – fillets, ridges 2010 OSU Solar Car in wind tunnel

10. OSU Solar Vehicle Team • OSU’s first solar vehicle • First car in Northwest • $50,000 budget vs. $2.4 million of U. of Mich. • 16.4% efficient cells • Brushed DC motor, 94% efficient peak (linearly decreasing to 0 as RPMs drop) • Fiberglass body • First titanium chassis in NASC history • LiFePO4 battery pack • 15th out of 24 entrants

11. OSU Solar Vehicle Team (cont’d) • 2010 OSU Solar Car: Odyssey • 17.4% minimum efficiency mono-crystalline SolarWorld solar array • Optimized prepreg carbon fiber body • Ti-425 titanium chassis and suspension • 95% efficient NGM PMAC wheel motor • 0.21 Cd drag, 0.74 m2 frontal area • Goal for top 5 cars in 2010 NASC • Anticipated speeds • 45-50 mph cruising • 85 mph top speed Odyssey Solidworks Schematics

12. Case Study: Body Design Process • Customer need: • Maximum solar surface area with minimum drag • Problem definition & specifications • Body must fit within a box that’s 1.8m x 1.6m x 5 meters and hold solar array

13. Body Design Continued • Data and information collection • Looked at over 30 vehicles from 1989 to now • Consulted books and experts • Evaluation of design and selection of optimal design • Ran computational fluid dynamics on more than 100 separate designs • Tested two best designs by 3D printing at EECS and using wind tunnel in Rogers

14. Body CFD

15. Body Wind Tunnel Testing

16. Implementation of Design • Implementation of design • Carbon fiber composite fabrication

17. Making the Car • Phase 1: Making the chassis, suspension, steering, body, wheels • Phase 2: Making the power electronics, attaching motor, batteries • Phase 3: Attach solar cells

18. How You Can Help • Help out with design and construction • Attend construction meetings • Meeting times will go out in emails, but will typically be Tuesday, Thursday, Friday and Saturdays. • Sign up by emailing osusvt@gmail.com • Visit our website at: http://oregonstate.edu/groups/solar