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THE BIOMECHANICAL ENERGY HARVESTER: developed at Simon Fraser University includes an aluminum chassis and generator mounted on a customized orthopedic knee brace, weighing 3.5 pounds (1.6 kilograms).
Courtesy of Greg Ehlers, Simon Fraser University

Exercise may soon do more for you than tighten up your sagging muscles. Advances in biomechanical engineering could use energy generated while walking, hiking or running to power any device requiring portable power, including night-vision goggles and other battery-operated devices used by soldiers as well as robotic prosthetic limbs, cell phones and computers in remote locations where no other energy sources are available.

A team of researchers at the Simon Fraser University (S.F.U.) Locomotion Laboratory in Burnaby, British Columbia, are studying the amount of energy that can be generated by 3.5-pound (1.6-kilogram) aluminum and steel knee braces worn while walking or running. Volunteers, wearing a brace strapped on each leg, generated about five watts of electricity per person during a recent experiment, enough power, researchers say, to run 10 cell phones concurrently and twice that needed to keep a computer running (something useful in developing regions of Africa where electricity is scarce). They report that one brace-wearing subject generated 54 watts of power by running in place.

The best area to place a device for harnessing human energy is near a joint, because this is where the muscles—the body's power source—work hardest, says Max Donelan, Locomotion Lab director and an assistant professor at S.F.U.'s School of Kinesiology. "There's a long history of human power generation using hand cranks and bikes, but these require your dedicated attention, so you don't do it for very long." The key to energy harvesting is extracting the energy from the body's natural movement and, aside from breathing, very few unconscious muscle movements are more automatic than the action of walking.

Donelan and his team of researchers targeted a particular part of the stride, halfway through the swing of the lower leg after it has left the ground (when the hamstring comes to life to make sure you don't have uncontrolled extension) through the time the foot returns to the ground. The brace designed to capture this energy features gears, a clutch, a generator and a computerized control system that monitors the knee's angle to determine when to engage and disengage power generation.

The specific amount of energy generated from Donelan's device depends upon the weight of the wearer, the difficulty of the terrain, the speed of the person's gait and how long the device is used. In the prototype, energy generated is dissipated into resistors, although future models could include an onboard battery for energy storage. The researchers hope to be able to test their device within a year on Canadian soldiers at a field site.

Another effort underway to convert motion into energy relies on the Faraday law of induction, named after English chemist and physicist Michael Faraday, which holds that the movement of a conductor (such as a metal wire) through a magnetic field produces a voltage in that conductor proportional to the speed of movement. M2E Power, Inc., in Boise, Idaho, has developed a system of magnets and coils that, when moved, generates energy that can be used to power their host device. M2E's technology originated at the Idaho National Laboratory, a Department of Energy–funded research group.

A good example of this would be walking with a cell phone in your front pocket or attached to your belt. The phone's movement would cause the magnet and coil to generate energy that could be transferred to a bank of ultracapacitors that charge the phone's battery when a certain voltage level is reached. "Think of it as a minigenerator whose power comes from movement," says Regan Warner-Rowe, M2E's director of business development. "Because power management is such a critical issue for cell phones, we have been in discussions with handset companies." (Warner-Rowe declined to name them.)