Device Lets You Share Wireless Power
About 12 seconds of charging would support 1 minute of additional talk time.
It's any phone-obsessed person's nightmare: you're out, your phone's battery is depleted down into the red zone, and there's not an electrical plug in sight. But one day, mobile and wearable devices could engage in "power-sharing," by wirelessly charging each other on the go, researchers say.
This innovative solution could help people easily recharge mobile or wearable gadgets, particularly for tasks such as emergency phone calls, the scientists added.
Mobile and wearable devices are now virtually everywhere, but their battery lives remain limited, with many lasting for less than a day.
A number of devices now exist to provide extra power to mobiles and wearables, such as power packs, mobile hand generators and solar cells. But although external power packs have become popular, they add size and weight, and mobile hand generators and solar cells produce only limited amounts of power.
Instead, an invention called PowerShake allows mobile and wearable devices to wirelessly charge other mobile and wearable devices on the go, even when those devices are being held or worn. Wireless-charging technologies are becoming more prevalent, but many of these stations are fixed, and do not account for devices near or in contact with skin.
"When mobile phones first came out, people really found them liberating because they didn't have to be attached to a wire, but they actually still do have to be attached to a wire when they recharge," said study co-author Mike Fraser, a computer scientist at the University of Bristol in England. "So now we're seeking to liberate mobile phones again, to help them manage power without plugging in."
Wireless charging involves at least two coils - one in the power transmitter, and one in the power receiver. When an electric current passes through the power transmitter coil, it creates an electromagnetic field that can transfer charge to another coil. Power transmission is best at close distances, the scientists said.
The researchers experimented with a variety of power transmitter and receiver coils. They also devised electromagnetic shielding made of ferrite plates and copper tape on the back of coils in order to prevent any transmitted energy from reaching human tissue. They noted flexible coils were also possible, and potentially embeddable in watch straps.
In experiments, PowerShake fit into small devices, met wireless power transfer safety guidelines, and performed about as well at power transmission as commercial alternatives, such as the Qi wireless charging pad, transferring about 3.1 watts of power, the researchers said. They estimated that about 12 seconds of charging would support 1 minute of additional talk time, while 2 minutes of charging would support about 4 minutes of video watching.
One drawback of PowerShake is that twice as much energy needs to be transmitted as is received.
"The power transfer is not ever going to be cost-free," Fraser told Live Science. "That's just the intrinsic power cost of wireless charging in general - wireless charging is always going to consume more power than wired charging."
In workshops, the researchers found that volunteers exploring the potential usefulness of PowerShake liked the idea of sharing power with their friends or family. However, due to the power costs of PowerShake, volunteers noted that if they needed to make an emergency call, they would probably just ask to borrow a phone instead of asking for power. Still, "if one needs to complete something on a particular device, and have already started but are running out of power halfway through and can't switch devices, this could help people," Fraser said.
The researchers now seek to have volunteers test PowerShake in real environments, "to see if it actually works, and if people do find it useful," Fraser said.
The scientists detailed their findings at the annual CHI conference on human-computer interactions in San Jose, California.
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PowerShake allows mobile and wearable devices to wirelessly charge other mobile and wearable devices on the go.
Most people would agree that fossil fuels simply need to go. They’re the cause of pollution, wars and climate change. Scientists have been researching alternative energy solutions like wind and solar power, and hydrogen fuel for cars, for years. But while some automakers -- like Toyota and Honda -- are bringing hydrogen-fueled cars to market, wind and solar are still more expensive than oil and coal and may not be the best solution for all places or uses. For example, some medical devices that are implanted in a human body could benefit from super tiny batteries that last decades.
So scientists continue the quest for abundant, cheap and efficient energy by investigating lesser-known sources, ones that may seem a little unusual, even ridiculous, unrealistic and, in some cases, morbid. “I think in order to solve the impending energy needs we might have to go a bit beyond,” said Bobby Sumpter, a senior research scientist of computational theoretical chemistry at Oak Ridge National Laboratory. Here are 11 of the more unusual sources that go above and beyond the norm. Who knows -- one day, you may use sugar to power your laptop, bacteria to run your car or dead bodies to heat a building.
Stretching the imagination when it comes to energy could get us closer to generating energy the way nature does: free and efficient. In London, Mayor Boris Johnson announced that excess heat from the subway tunnels and an electric substation would be funneled into British homes.
Traditionally, putting sugar into a gas tank is a prank that can ruin a car’s engine. But someday, it could be a great way to fuel a vehicle. “We should not dismiss ideas, we should let people pursue ideas of unusual things,” Diego del Castillo Negrete, a senior research scientist in the Fusion Energy Division at the Oak Ridge National Laboratory said. Researchers and chemists at Virginia Tech are developing a way to convert sugar into hydrogen, which can be used in a fuel cell, providing a cheaper, cleaner, pollutant-free and odorless drive. The scientists combine plant sugars, water and 13 powerful enzymes in a reactor, converting the concoction into hydrogen and trace amounts of carbon dioxide.
The hydrogen could be captured and pumped through a fuel cell to produce energy. Their process delivers three times more hydrogen than traditional methods, which translates into cost savings. Unfortunately, it might be another decade before consumers can actually dump sugar into their gas tanks. What seems more realistic in the short term is using the same technology to create long-lasting sugar-based batteries for laptops, cell phones and other electronics.
One hundred billion times more power than humanity currently needs is available right now, out in space. It comes through solar wind, a stream of energized, charged particles flowing outward from the sun. Brooks Harrop, a physicist at Washington State University in Pullman and Dirk Schulze-Makuch of Washington State’s School of Earth and Environmental Science, think they can capture these particles with a satellite that orbits the sun the same distance Earth does.
Their so-called Dyson-Harrop satellite would have a long copper wire charged by onboard batteries in order to produce a magnetic field perfect for snagging the electrons in the solar wind. The energy from the electrons would be beamed from the satellite via a infrared laser to Earth, since the infrared spectrum would not be affected by the planet’s atmosphere. This Dyson-Harrop satellite holds a few technical problems that researchers are currently trying to fix. It has no protection from space debris, and some of the power could be lost as it’s beamed through Earth’s atmosphere. Plus, finding a way to aim the laser beam across millions of miles of space is no small task. What seems more realistic is to use this satellite in order to power nearby space missions.
Feces and Urine
Most people think that feces and urine should be disposed of immediately. But feces contains methane, a colorless, odorless gas that could be used in the same way as natural gas. At least two solutions -- one in Cambridge, Mass., called Park Spark and one in San Francisco run by Norcal Waste -- is focused on converting dog poo into methane.
In both solutions, dog walkers are provided biodegradable bags, which after they’re filled, are placed into a large container called a digester. Inside, microorganisms process the poo, giving off methane as a byproduct. The methane can be used to power lights In Pennsylvania, a dairy farm is looking to cow manure for energy. Six hundred cows that produce 18,000 gallons of manure daily are helping the farm save $60,000 a year. The waste is used to produce electricity, bedding, fertilizer and heating fuel. And Hewlett-Packard recently released a study explaining how a dairy farmer could make money by leasing land to Internet server companies, who could power computers with the methane. Human waste is just as good. In Bristol, Australia a VW Beetle car is powered by methane captured from a raw sewage treatment plant. Engineers from Wessex Water estimate the waste from 70 homes can generate enough gas to make the car run for 10,000 miles. And let’s not forget urine. At the Heriot-Watt University's School of Engineering and Physical Sciences in Edinburgh, scientists are looking for a way to make world's first urine-powered fuel cells. It could be a viable way for astronauts or military personnel, for instance, to produce power on the go. Urea is an accessible, non-toxic, organic chemical compound rich in nitrogen. So yes, humans are constantly carrying around a chemical compound that can produce electricity.
People: Dead or Alive
The next time you’re standing in a crowded subway in the middle of summer, don’t sweat it. The heat your body produces can warm an entire building, complete with offices, apartments and shops. At least that’s what's happening in Stockholm and Paris. Jernhuset, a state owned property administration company is putting together a plan to capture body heat from train commuters traveling through Stockholm’s Central Station. The heat will warm water running through pipes, which will then be pumped through the building’s ventilation system.
Paris Habitat, owner of a low-income housing project in Paris, will also use body heat to warm 17 apartments in a building, which is directly above a metro station near Pompidou Center. On a more morbid and less sweaty note, a crematorium in the United Kingdom is using gasses released from the cremation process to heat a crematorium. The energy in cremated bodies is already being captured when it has to pass through filters to remove the mercury in the deceased’s fillings. Instead of letting the energy escape, pipes are used to pump it through the building.
Go out and party; it may help the environment. Club Watt in Rotterdam, Netherlands is using floor vibrations from people walking and dancing to power its light show. The vibrations are captured by “piezoelectric” materials that produce an electric change when put under stress. The U.S. Army is also looking at piezoelectric technology for energy. They put the material in soldier’s boots in order to charge radios and other portable devices. Although this is an interesting renewable energy with great potential, it’s not cheap. Club Watt spent $257,000 on this first generation 270-square-foot floor, more money than it can recoup. But the floor will be reprogrammed to improve output in the future. Your dance moves really can be electric.
California municipalities alone produce 700,000 metric tons of dried sludge annually, which has the potential to generate 10 million kilowatt-hours of electricity per day. The University of Nevada, Reno, is drying sludge to make it burnable for a gasification process, which turns it into electricity. A team of researchers at the university built the processing machine as a way of producing low cost and energy efficient technology. The machine turns gooey sludge into powder by using relatively low temperatures in a fluidized bed of sand and salts to produce the biomass fuel.
The waste-to-energy technology is designed to be on site which means companies can save on trucking costs, disposal fees, and electricity. Although the research is still ongoing, estimates show that a full-scale system can potentially generate 25,000 kilowatt-hours per day to help power reclamation facilities.
Jellyfish that glow in the dark contain the raw ingredients for a new kind of fuel cell. Their glow is produced by green fluorescent protein, referred to as GFP. A team at The Chalmers University of Technology in Gothenburg, Sweden, placed a drop of GFP onto aluminum electrodes and then exposed that to ultraviolet light. The protein released electrons, which travel a circuit to produce electricity. The same proteins have been used to make a biological fuel cell, which makes electricity without an external light source. Instead of an external light source, a mixture of chemicals such as magnesium and luciferase enzymes, which are found in fireflies, were used to produce electricity from the device. These fuel cells can be used on small, nano devices such as those that could be implanted in a person to diagnose or treat disease.
There are three known "exploding lakes," in the world, so called because they contain huge reservoirs of methane and carbon dioxide trapped in the depths by differences in water temperature and density. If temperatures should change and the lake turns, these gases would immediately fizz to the surface like a shaken bottle of soda, killing the millions of people and animals living nearby. In fact, such an event happened on Aug. 15, 1984, when Cameroon's Lake Nyos unleashed a huge cloud of concentrated carbon dioxide, instantly suffocating hundreds of people and animals. In Rwanda, Lake Kivu is such a place. But the government has built a power plant that sucks up the noxious gases from the lake to power three large generators, which produce 3.6 megawatts of electricity. The government hopes that in the next couple of years, the plant could be producing enough power for one-third of the country.
Billions of bacteria live out in the wild, and like any living organism, they have a survival strategy for when there is a limited food supply. E. coli bacteria store fuel in the form of fatty acids that resembles polyester. That same fatty acid is needed for the production of biodiesel fuel. So, researchers are looking to genetically modify E. coli microorganisms to overproduce those polyester-like acids. The scientists removed enzymes from the bacteria to boost fatty acid production, and then dehydrated the fatty acid to get rid of the oxygen, which made turned it into a type of diesel fuel. The same bacteria that can make us sick can also help save people money and the environment, by providing fuel for transportation.
Carbon nanotubes are hollow tubes of carbon atoms that have a range of potential uses, from armor-like fabrics to elevators that could lift cargo between Earth and the moon. Recently, scientists from MIT have a found a way to use carbon nanotubes to collect 100 times more solar energy than a regular photovoltaic cell. The nanotubes could work as antenna to capture and funnel sunlight onto solar arrays. This means that instead of having an entire rooftop covered in solar panels, a person may need just a small space.