Inherit the Wind

for Discover

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kite1
JoeBen Bevirt and his team test a prototype of a flying wind turbine on the cliffs north of Santa Cruz.
photography by Sean Fenn

Bonny Doon is hardly the place one thinks of visiting for high-tech thrills. Once an old logging camp, the tiny hamlet northwest of Santa Cruz, California, sits at the end of a country road, past miles of empty beaches and strawberry farms. Hang a left before you reach the vineyard and you find a short dirt track leading to a barn. And then, amid hundreds of acres of redwoods out back, you encounter an avatar of the future—a whirring black gizmo, about the size of a bread box, zipping around overhead. The strange flying object is controlled remotely by a cluster of giggling engineers. Their leader, a tall man with the build of a gazelle, windswept blond hair, and a permanent grin, starts extolling the possibilities of his device before he remembers to introduce himself.

To inventor JoeBen Bevirt, the flying black box holds our clean-energy future, a world in which wind turbines lift off the ground and fly among the clouds. His company, Joby Energy, designs these turbines from scratch. “In order to have truly sustainable energy, we’ve got to beat coal,” he says. “We are going to need game-changing technology. I believe that technology is high-altitude wind.”

In concept his idea makes sense: Wind power from the sky would strip turbines of their expensive, heavy towers and oversize blades, allowing them to collect energy unobtrusively from the richest lode of wind in the world. Winds at an altitude of 30,000 feet carry 20 times as much energy as those near the ground, representing a source of power that could be a fraction of the cost of coal. The challenge, observers say, is keeping such turbines aloft.

“Finding a resource so large is like finding an oil field in your garden,” says Cristina Archer, an environmental engineer at the University of California, Chico, and lead author of a global survey on high-altitude winds. “Plus, you’re saving on material costs by using 100-pound devices floating on air rather than 200 tons of cement for a traditional wind turbine.”

Friends of JoeBen Bevirt say that within 15 minutes of meeting the man, you either love him or hate him. His focused energy, coupled with unusually wide, unblinking blue eyes, can be unnerving. He is friendly but talks at a brisk clip, punching out rapid-fire syllables without breaking eye contact. When seated, he twitches a leg. “You would think he’d had five cups of coffee,” says David Craig, one of Joby Energy’s earliest employees. “He’s pretty intense. But the enthusiasm is contagious.”

Bevirt (who, for the record, is anticaffeine) was a passionate engineer even before he knew what the word meant. “From the time I was a little kid, I wanted to do renewable energy because I grew up without electricity,” he says. Living with his parents in a back-to-the-land community in the Santa Cruz Mountains near where Joby Energy stands today, he recalls “kerosene lamps, no TV, and cooking with propane.”

Bevirt’s lofty aspirations came from his father, Ron (a.k.a. “Hassler”) Bevirt, an early member of the Merry Pranksters, the counterculture pioneers who launched their brand with an epic, acid-fueled bus trip across America in 1964. Hassler was the one who recorded the famous passage in photographs. Generally in charge of equipment, “he was the guy making sure that the sound system worked,” JoeBen Bevirt explains. “They called him Hassler because if there was a hassle, he was on it.” The younger Bevirt’s strange name has a Prankster past too: Joe Ben (“Joby”) Stamper was the angel-faced, transcendent optimist in Sometimes a Great Notion, Prankster Ken Kesey’s novel about loggers in the Oregon woods.

Bevirt took after his father, a master house builder, though the son had a penchant not for dwellings but for smaller, higher kinds of tech. He tinkered with a neighbor’s solar panels, set up mini wind turbines, and adapted generators to run his precious Apple computer. Bevirt spent hundreds of hours cleaning up nails and performing other odd jobs at construction sites to earn enough for the costly mountain bikes and computers that would feed his technology habit as the years went by. By the time he was a freshman in high school, in 1987, he was building those bikes from the ground up.

It was at the University of California, Davis, that Bevirt found his calling, in one of the most peculiar laboratories in the state. “Paul Moller is this totally crazy inventor in Davis who has been working for the past 40 or 50 years to build a flying car,” Bevirt says, smiling broadly at the memory of his mentor. “It was an amazing experience.” From his sophomore through his senior years, Bevirt worked all hours alongside Moller and a few other engineers trying to figure out a controlled way to lift a vehicle and its driver off the ground. Much of the time was spent on basic questions, such as how to generate enough thrust without massive engines. It never really worked, but Bevirt became infected with a love of “big idea” engineering.

Thirteen years after graduating, Bevirt had the opportunity to embark on his own big idea, backed with his own funds. The tech devotee had invested his meager savings in Apple, Intel, and other booming names during the 1990s while in graduate school at Stanford and sold his shares in 1999, just before the tech bubble burst. He used nearly $500,000 of profit to start Velocity11, a company that designed robotics for the genomics industry. As the company’s CEO and then president, Bevirt not only designed the machines that prepped endless lines of gene specimens for analysis but also headed up customer service and sales for the company. Eight years later he sold Velocity11 to biotech giant Agilent Technologies for more than $100 million.

By then Bevirt had created a second successful company, called Joby, that built gadgets like bendable tripods—dubbedGorillapods—for outdoor photographers. But after his design for a wireless headset flopped, he decided it was time to stop wasting his efforts on small ideas and go after the sort of big dream that had captured his imagination in college. Recalling the solar panels of his childhood, he turned to renewable energy and began pursuing every hip new energy source he could find. “At one point JoeBen got all excited about algae,” his friend and former colleague David Scheinman says. “We went to algae conferences. All we talked about was algae, algae, algae. Then he kind of decided: nope.”

Algae did not have enough concentrated energy to be cost-effective, Bevirt concluded. In 2007 he was still casting about for a novel resource—one that contained so much power it would cost less than coal—when he had an epiphany in midair. “I was on a flight back from China, and the air quality over there had been just absolutely atrocious,” he says. “And I realized that we had 200-mile-an-hour tailwinds. So I started doing calculations on exactly how much power was in 200-mile-an-hour winds. By the time I landed, I was all fired up.”

Bevirt, who has always loved aviation and is an avid kite surfer, started modeling jet stream winds. Over several sleepless nights he calculated how much power a wind turbine at altitude could gather. He knew wind power is related to the cube of wind speed, so faster winds create exponentially more power than slower ones. But the actual numbers staggered him. In the jet stream above New York City, one square meter of wind routinely carries eight kilowatts of power (enough for six or seven American homes), whereas the same area near the ground could not even power a toaster oven. What’s more, high-altitude winds are more consistent, so those kilowatts would be generated virtually all the time. Produced by such constant, ferocious air currents, wind power could finally be cheaper than coal. As a bonus, elevated turbines would not mar the landscape, neutralizing one of the big political objections to wind.

“I spent several days completely focused on it, to the point where it was the only thing I could think about,” Bevirt says. He imagined a device that could fly in the relentless punishment of the jet stream: a giant wing, fitted with multiple turbines, that would take off and land like a helicopter. He created an animation of such a craft and showed it to colleagues. “Are you out of your mind?” they asked him. How would he build it or get it aloft?

Bevirt had no idea what he was getting into when he launched Joby Energy in February 2008. Sure, other companies were tinkering with high-altitude wind (see “High Fliers,” next page), but he had an advantage in his solid source of funding: his own fortune. By the end of the year, he had bought a 40-acre plot of redwood forest in the Santa Cruz Mountains to fly models around and outfitted it with workshops for metal, wood, fiberglass, and carbon fiber. He converted an old barn into a lofty research lab and bought a small house next door where he could sleep in between relentless 18-hour days.

The first thing he and his team had to decide was the type of design to pursue. Did they want something like a kite, which would generate small amounts of energy by pulling a tether and spinning a turbine on the ground? Or should they develop generators that would be affixed to a craft and sent into the sky? Bevirt was interested not in generating a few kilowatts of electricity for a single house but in making great quantities of power; for this the latter idea seemed best. He wanted a device that could be scaled to an industrial size, on par with a coal-fired plant. (Most modern wind turbines generate anywhere from 700 kilowatts to 2.5 megawatts each—enough for 200 to 750 typical homes.) Attaching turbines directly to the craft would mean more generators and therefore more power.

But what should the device look like? The team began with off-the-shelf model airplanes, attached by tether to the ground and flown in circles. This led to a bizarre early design called the Whirly, which had two rotors on opposite sides of a long wing; as the wing sliced the air, the rotors circled each other much like two animals chasing each other’s tails. The spinning generated lots of wind, but the construct was too heavy and costly to scale to industrial size.

In their steamroller style of engineering, where every path was tested and only the best was followed, the team scrapped that idea and went on to the next, a device that looked a little like an old World War I biplane without a cockpit. They mounted rotors at the joints where the vertical struts met the horizontal wings. This arrangement allowed more attached rotors, yet there were problems here as well. For one thing, the rotors were right in front of the wings, impeding airflow and causing a reduction in lift. And then another issue surfaced. Numerous trips to Washington, D.C., convinced Bevirt that the Federal Aviation Administration was not going to allow him to fly permanent commercial devices at 30,000 feet anytime soon. This meant that the craft would have to fly at a lower elevation—much lower.

Ironically, this brought Bevirt back to the original idea that he had sketched three years earlier on his flight back from China: a single wing facing into the wind with turbines mounted on it, gently tracing a large circle through the air. Only this time, the rotors would be mounted on posts above and below the wings, a configuration that would prevent them from stealing the air needed to keep the machine aloft. To take off and land, the whole thing would swivel vertically 90 degrees, with the rotors facing upward and acting like helicopter blades.

Bevirt was disappointed to leave behind his dream of taking wind power from the jet stream, tens of thousands of feet up, but it turns out that even at just a few thousand feet, the device could collect tremendous amounts of energy, thanks to its solid structure and constant swing. For a standard wind turbine, the amount of energy available is related to the speed of the wind and the size of the area swept by the blades. Bevirt’s prototype maximizes both these variables. The single-wing design exploits the wind to create lift, a force that sends the craft hurtling through the air at many times the speed of the wind. Even in a 20-mile-an-hour wind, the turbines can move through the air in excess of 100 miles an hour. And even though the blades are much shorter than those on ground-based wind turbines,they cut through more wind because the craft flies in a giant circle.

Bevirt says the design was less a sudden inspiration than a slow, forceful evolution. “Innovation is messy,” he states, noting the Stanford engineering mantra of FFF, or Fail Forward Fast. “You have to be tolerant of failure and learn from it as aggressively as you can. The faster you can try out ideas and learn from them, the better—and that’s especially important when exploring a new space.”

Joby energy now employs 20 engineers—mostly young men who do not mind Bevirt’s brutal 60- to 80-hour workweeks—and is trying to scale up to a prototype that is the length of a pool table and has four spinning turbines. The team has produced a few kilowatts of electricity with initial models and is designing turbines that could generate 250 kilowatts each (similar to some of the early, land-based turbines).

Although Bevirt still insists that wind turbines can fly in the jet stream, he accepts that the first units will probably have to operate at just a few thousand feet to prove they can be trusted by utility companies and big-time energy spenders. The government would probably need even more convincing. “It’s a meaty regulatory challenge,” says Bevirt, who estimates it would take $100 million and three to five years of lobbying to open up the jet stream for energy use. Energy insiders like Lukas Gresnigt, head of business development at the Norwegian energy giant Statkraft (one of the few companies following the technology), says trust will start to come only if someone can fly a half-megawatt device for at least six months without incident.

This brings up what Bevirt calls his biggest engineering hurdle. In order for high-altitude turbines to work, they must have automated control systems that can guarantee the device won’t crash in a dramatic and expensive accident. “That’s the crux of this problem,” he says. “If there’s going to be something that makes or breaks an airborne wind turbine effort, it’s going to be in controls.”

A device the size of a bread box is actually more difficult to control than one the size of a pool table, like what Joby Energy is now working on. But the consequences of a crash for the latter are obviously worse. For a device the size of a semi truck, the risk is greater still. Each device will have an onboard computer (similar to the kind used by a Predator drone) that will detect small changes in the wind and automatically adjust to them. And this is the task facing most of Bevirt’s employees today: writing code and creating control software. The crew is currently working on 3- and 10-meter-long prototypes, although the goal is a 60-meter [200-foot] commercial machine. A pilot project comprising multiple 20-meter craft flying in unison is planned for 2012.

Among the companies that are competing to tap high-altitude winds, Joby Energy stands out for its business savvy and stable funding. Even so, few players in the energy world are ready to bet on flying turbines. But you would never know about all that skepticism from walking around Bevirt’s busy compound in the woods. “JoeBen lives for those days when he goes kite-surfing and it’s blowing really big and the waves are really big,” Scheinman says. “And everyone looks at him like, ‘Is this guy really going to do it?’ And he does it. That’s a pretty decent analogy for JoeBen’s life. He looks for the biggest days and takes out the biggest kite.”


High Fliers

Joby Energy is not the only company trying to tap high-altitude wind. Several competitors are working on related designs that could start feeding the grid within the next couple of years. Like Joby, these companies are exploiting new strong, cheap materials, advanced control electronics, and an improved understanding of upper-level wind patterns. They are also seeking a way around the resistance to land-based and near-shore wind farms, like the finally approved Cape Wind project off Cape Cod.

Makani Power employs a tethered single-wing planefitted with six small rotors, that sweeps out a circular path at 1,200 feet and generates up to 1 megawatt of power. The California-based company received $15 million from Google’s philanthropic arm (the tech giant’s largest clean-energy investment) and just secured a $3 million grant from the U.S. Department of Energy.

Magenn Power has developed a helium-filled blimp that rotates around an axle 1,000 feet in the air. Generators on both ends send electricity down tethers to the ground. Starting next summer, the company plans to take orders for a $500,000 model that produces up to 100 kilowatts.

Ampyx Power combines a glider and a ground-based generator to make its PowerPlane. As the glider darts through the air, it unwinds a long tether, creating mechanical energy that a generator on the ground converts into electricity. The Dutch firm plans to sell a 1-megawatt model by 2013. Italian start-up Kite gen employs the same concept but uses a giant kite rather than a glider to uncoil the tether.