Top U.S. solar car team goes small in effort to win big in 2017 contest

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The sun-powered vehicle that the University of Michigan’s top-ranked Solar Car Team will race in a global contest this fall is the smallest and most aerodynamic that any U-M team has ever built.

The long, skinny, single-fairing car is named Novum — Latin for “new thing.”

For a week in October, a 17-member race crew will guide it across the Australian Outback in the Bridgestone World Solar Challenge. Top collegiate teams from around the globe compete in the 1,800-mile event, which takes place every other year.

The U-M team has been the reigning U.S. champion for more than a decade, having won the past six American Solar Challenges, including in 2016. The team has finished third in the world race five times in its 27-year history.

The students unveiled Novum Friday at Ann Arbor’s Michigan Theater. Measuring just more than one meter across, it’s roughly 40 percent narrower than the team’s last vehicle, Aurum. Simulations show that it’s around 20 percent more efficient. Beyond its design, the manufacturing process and solar technology behind this 14th-generation car are also unique compared with its predecessors.

A 3-D rendering of Novum, the U-M Solar Car Team’s 14th solar car and its entry into the 2017 Bridgestone World Solar Challenge. (Image by Steve Alvey)

“There are two ways to improve,” said Clayton Dailey, engineering director and a senior studying mechanical engineering. “You either refine an iteration of a previous design or you change something drastically. This year we’re going for a drastic change. We’re doing something that hasn’t been done before — going to the unknown.”

The team had considered building a small car in the past, but this time, other factors pushed the students to take the leap. First, race officials reduced the maximum size of a solar array area by roughly a third. Second, the team was able to secure high-tech, “multijunction” gallium arsenide solar cells. They’re roughly 35 percent efficient, compared to silicon cells’ 20 percent.

The last three U-M solar cars have been powered by silicon, but all previous vehicles used gallium-based arrays — ranging in junction variety and efficiency. In the eight years since the last gallium arrays, the technology has rapidly evolved, whereas silicon has plateaued. Novum’s will be the most advanced gallium cells the team has ever used.

“Flat-panel silicon is basically maxed out in terms of efficiency,” said Rachel S. Goldman, a professor of materials science and engineering, electrical engineering and computer science, and physics, who works on gallium arsenide cells and is not affiliated with the team.

Solar Car Team members Peter Rohrer, operations director, and Caroline Subramoney, micro systems engineer, clean the surface of Novum. Both undergraduates, Rohrer is studying naval architecture and marine engineering and Subramoney is studying computer engineering. (Photo by Evan Dougherty, Michigan Engineering)

Novum’s gallium array is less than half the size of the previous car’s silicon counterpart, yet the team expects it to generate enough energy to maintain average speeds of 50-55 mph in Australia — similar to Aurum’s.

“Going from silicon to multijunction is a big jump in efficiency,” said Eric Brown, race array engineer and a junior studying electrical engineering. “These types of cells are found in places where space is at a premium but you need a lot of energy. So, for example, satellites use them quite a bit. There are also different things you can do to mitigate losses from curvature and shading that you can’t do with silicon.”

The array’s smaller footprint allowed the design team more freedom.

“My teammates and I designed a lot of strange looking cars — all the crazy ideas we thought of trying in the past,” said Jiahong Min, aerodynamics leader and a graduate student studying mechanical engineering. He studied aerospace engineering as a U-M undergraduate. “There was a lot of trial and error, but experiments showed that making it narrower was more efficient than making it shorter.”

Andrew Dickinson, an undergraduate computer science engineering student on the Solar Car Team, places Novum’s canopy. (Photo by Evan Dougherty, Michigan Engineering)

The team’s two previous cars had a catamaran-style body with two parallel hulls. The students moved the hulls closer together as they designed narrower concepts, “until at one point we said, what if we just merge them?” Min recalled. “And then — bam — that’s how the shape came together.”

To ensure that this narrower car can handle the crosswinds of the Outback, the team conducted wind tunnel tests and simulations to examine every angle and wind speed it might encounter. They’ll also do road testing, including a mock race around Michigan’s Lower Peninsula this summer. The World Solar Challenge begins Oct. 8.

“I think this race will usher in the next era of solar cars,” Dailey said.

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Comments

  1. Jordan Billy
    on July 14, 2017 at 8:29 am

    hey how is it going?

  2. Jordan Randy
    on July 18, 2017 at 12:32 am

    best thing ive seen today. thank you!

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