Powered by the sun mit news electricity quotes by benjamin franklin

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For the team of 25 students on the MIT Solar Electric Vehicle Team (SEVT), the unveiling was as much a celebration of how far they’ve come and a send-off for how far they want to go. Seventeen hundred miles, to be exact, from Omaha, Nebraska to Bend, Oregon.

Professor J. Kim Vandiver, the Forbes Director of the Edgerton Center and dean for undergraduate research, spoke at the event, and referred to one of the first solar cars, Solectria 4, built by James Worden ’89 in 1988. In fact, about five years before the Edgerton Center was founded, Harold “Doc” Edgerton gave the team space in Building 20.

According to Worden, “unveilings” for solar cars were a little more off-the-cuff back then. Held at Worden’s house in Arlington, Massachusetts, the team performed midnight test runs on Massachusetts Avenue from one end of Arlington to the other on a stretch of flat and straight, car-free road.

This unveiling was more sedate. Junior Veronica LaBelle, team captain, remarked on the power behind a large group of students engaged in intensive collaboration, and her gratitude for the team’s commitment. Membership, she noted, has doubled in the past two years.

She also mentioned a road block in the summer of 2017. The team’s $10,000 entry fee for the Australian World Solar Challenge (WSC) had been paid, and Flux was ready to be shipped to Darwin, Australia for the race. But more road testing was needed, and the timeline was too tight to ensure that Flux was in competition shape. After hours of agonizing discussion, the team decided to forfeit their entry fee and use their time to prepare Flux for the ASC.

Flux stands apart from previous iterations of the solar car with its asymmetrical body. The driver sits on the same right-hand side as the wheel base, which means there’s less drag as it’s racing down the road. The car’s body is made from honeycomb wrapped in carbon fiber.

The 5-kilowatt battery primarily stores energy converted from the solar array – 260 silicon solar cells on the canopy of the car. While cruising, the solar array powers the car without much help from the battery. Acceleration, however, requires more than solar power, and some battery power is required to meet the motor’s demand. During the ASC, the team will have a charging period and can start each day with a full battery.

Talking about the team’s Independent Activities Period road trip to Georgia this January, sophomore Harith Morgan was visibly excited at the memory. “It’s an endurance race, so we’re not only racing, it’s how the car performs and how we perform as a team. If we get a flat, how quickly do we respond to that? Who takes off the wheel, who gets the next wheel, who is tightening the wheel, getting the new wheel secured properly? And we do it in two minutes or less.”

Morgan joined the team in his first-year. “When I got to MIT I knew I was interested in mechanical engineering, and I was thinking of a way I could apply mechanical engineering to solving world problems, and I thought energy was a world problem and solar car was the perfect marriage of the two,” Morgan added.

The team has a little more work ahead, including crush zone changes (bodywork that allows the car to absorb the impact of a crash) and new turning fairing. Plus some more hours of road training for the driver. And then, full sun-powered speed ahead, the ASC from Nebraska to Oregon.