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Panasonic Says Tesla Investment Won’t Be a Risky Gamble

Panasonic executives sought to allay investor concerns about the firm taking part in Tesla Motors $5 billion battery plant, saying any investment decision will be made one step at a time.

Earlier this month, the Japanese tech giant said it signed a letter of intent to participate in the construction of what the Silicon Valley electric-car maker calls "gigafactory" for assembling vehicle batteries in the U.S. But Panasonic hasn't disclosed how much it plans to invest in the plant.

With Panasonic already expanding production of batteries at factories based in Japan, one key concern is whether it will face overcapacity if it invests in the U.S. plant.

Panasonic aims to double its sales from the automotive business to $20 billion by 2019. A third of these sales would come from car batteries and other parts for fuel-efficient vehicles.

In addition to Tesla, the company has also received interest from other auto makers both in and outside of Japan, while its batteries can also be used for power-storage systems, they said.

Source: WSJ

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Toyota Improve hybrid fuel efficiency by 10% with SiC Inverter

Toyota in collaboration with Denso has developed a silicon carbide (SiC) power semiconductor for use in automotive power control units. Toyota will begin test driving vehicles fitted with the new PCUs on public roads in Japan within a year.

Through use of SiC power semiconductors, Toyota aims to improve hybrid vehicle fuel efficiency by 10 percent under the Japanese Ministry of Land, Infrastructure, Transport and Tourism's JC08 test cycle and reduce PCU size by 80 percent compared to current PCUs with silicon-only power semiconductors. SiC power semiconductors have low power loss when switching on and off, allowing for efficient current flow even at higher frequencies. This enables the coil and capacitor, which account for approximately 40 percent of the size of the PCU, to be reduced in size.

PCUs play an important role in hybrids and other vehicles with an electrified powertrain: they supply electrical power from the battery to the motor to control vehicle speed, and also send electricity generated during deceleration to the battery for storage. However, PCUs account for approximately 25 percent of the total electrical power loss in HVs, with an estimated 20 percent of the total loss associated with the power semiconductors alone. Therefore, a key way to improve fuel efficiency is to improve power semiconductor efficiency, specifically by reducing resistance experienced by the passing current. Since launching the “Prius” gasoline-electric HV in 1997, Toyota has been working on in-house development of power semiconductors and on improving HV fuel efficiency.

As SiC enables higher efficiency than silicon alone, Toyota CRDL and Denso began basic research in the 1980s, with Toyota participating from 2007 to jointly develop SiC semiconductors for practical use. Toyota has installed the jointly developed SiC power semiconductors in PCUs for prototype HVs, and test driving on test courses has confirmed a fuel efficiency increase exceeding 5 percent under the JC08 test cycle.

In December last year, Toyota established a clean room for dedicated development of SiC semiconductors at its Hirose Plant, which is a facility for research, development and production of devices such as electronic controllers and semiconductors.

In addition to improved engine and aerodynamic performance, Toyota is positioning high efficiency power semiconductors as a key technology for improving fuel efficiency for HVs and other vehicles with electrified powertrains. Going forward, Toyota will continue to boost development activities aimed at early implementation of SiC power semiconductors.

Toyota will exhibit the technology at the 2014 Automotive Engineering Exposition, to be held from May 21 to May 23 at the Pacifico Yokohama convention center in Yokohama.

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ELMOFO Electric Radical First Race at Eastern Creek [VIDEO]

The Electric Radical SR8 built by Newcastle based ELMOFO had it's first race yesterday at Sydney Motorsport Park (Eastern Creek).

With Garth Walden at the wheel for the first official CAMS sanctioned race meeting for an Electric Vehicle. The instant torque can make this car a bit of a handful on tight track sections, particularly with cooler tyres.

The ELMOFO Radical, the current electric lap record holder, was the only electric powered vehicle in a field of petrol powered cars in Race 1 of Round 1 of the NSW SuperSports State Championships.

The car performed as expected during practice, qualified 3rd (of 7) in it's class and was positioned 5th (of 9) on the grid for the start. The 2 front runners are super-light and faster Stohr racers which are in a different class to the Radicals.

The 500 hp and 600 Nm of instant torque enabled Garth to wheel spin his way to the front of the Radical field which he led for the whole race until the last 150m where a technical issue caused a sudden power drop and let 2 cars pass just before the finish line.

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Flexible supercapacitor demonstrates ultrahigh energy-density

Scientists have taken a large step toward making a supercapacitor with energy density comparable to a Li-ion battery.

The supercapacitor packs an interconnected network of graphene and carbon nanotubes so tightly that it stores energy comparable to some thin-film lithium batteries—an area where batteries have traditionally held a large advantage.

The product's developers, engineers and scientists at Nanyang Technological University (NTU) in Singapore, Tsinghua University in China, and Case Western Reserve University in the United States, believe the storage capacity by volume (called volumetric energy density) is the highest reported for carbon-based microscale supercapacitors to date: 6.3 microwatt hours per cubic millimeter.

The device also maintains the advantage of charging and releasing energy much faster than a battery. The fiber-structured hybrid materials offer huge accessible surface areas and are highly conductive.

The researchers have developed a way to continuously produce the flexible fiber, enabling them to scale up production for a variety of uses. To date, they've made 50-meter long fibers, and see no limits on length.

They envision the fiber supercapacitor could be woven into clothing to power medical devices for people at home, or communications devices for soldiers in the field. Or, they say, the fiber could be a space-saving power source and serve as "energy-carrying wires" in medical implants.

Liming Dai, a professor of macromolecular science and engineering at Case Western Reserve and a co-author of the paper, explained that most supercapacitors have high power density but low energy density, which means they can charge quickly and give a boost of power, but don't last long. Conversely, batteries have high energy density and low power density, which means they can last a long time, but don't deliver a large amount of energy quickly.

Microelectronics to electric vehicles can benefit from energy storage devices that offer high power and high energy density. That's why researchers are working to develop a device that offers both.

To continue to miniaturize electronics, industry needs tiny energy storage devices with large volumetric energy densities.

By mass, supercapacitors might have comparable energy storage, or energy density, to batteries. But because they require large amounts of accessible surface area to store energy, they have always lagged badly in energy density by volume.

Their approach

To improve the energy density by volume, the researchers designed a hybrid fiber.

A solution containing acid-oxidized single-wall nanotubes, graphene oxide and ethylenediamine, which promotes synthesis and dopes graphene with nitrogen, is pumped through a flexible narrow reinforced tube called a capillary column and heated in an oven for six hours.

Sheets of graphene, one to a few atoms thick, and aligned, single-walled carbon nanotubes self-assemble into an interconnected prorous network that run the length of the fiber. The arrangement provides huge amounts of accessible surface area—396 square meters per gram of hybrid fiber—for the transport and storage of charges.

But the materials are tightly packed in the capillary column and remain so as they're pumped out, resulting in the high volumetric energy density. The process using multiple capillary columns will enable the engineers to make fibers continuously and maintain consistent quality, Chen said.

The findings

The researchers have made fibers as long as 50 meters and found they remain flexible with high capacity of 300 Farad per cubic centimeter. In testing, they found that three pairs of fibers arranged in series tripled the voltage while keeping the charging/discharging time the same.

Three pairs of fibers in parallel tripled the output current and tripled the charging/discharging time, compared to a single fiber operated at the same current density. When they integrate multiple pairs of fibers between two electrodes, the ability to store electricity, called capacitance, increased linearly according to the number of fibers used.

Using a polyvinyl alcohol /phosphoric acid gel as an electrolyte, a solid-state micro-supercapacitor made from a pair of fibers offered a volumetric density of 6.3 microwatt hours per cubic millimeter, which is comparable to that of a 4-volt-500-microampere-hour thin film lithium battery.

The fiber supercapacitor demonstrated ultrahigh energy-density value, while maintaining the high power density and cycle stability. "We have tested the fiber device for 10,000 charge/discharge cycles, and the device retains about 93 percent of its original performance," Yu said, " while conventional rechargeable batteries have a lifetime of less than 1000 cycles."

The team also tested the device for flexible energy storage. The device was subjected to constant mechanical stress and its performance was evaluated. "The fiber supercapacitor continues to work without performance loss, even after bending hundreds of times," Yu said. "Because they remain flexible and structurally consistent over their length, the fibers can also be woven into a crossing pattern into clothing for wearable devices in smart textiles." Chen said.

Such clothing could power biomedical monitoring devices a patient wears at home, providing information to a doctor at a hospital, Dai said. Woven into uniforms, the battery-like supercapacitors could power displays or transistors used for communication. The researchers are now expanding their efforts. They plan to scale up the technology for low-cost, mass production of the fibers aimed at commercializing high-performance micro-supercapacitors.

In addition, "The team is also interested in testing these fibers for multifunctional applications, including batteries, solar cells, biofuel cells, and sensors for flexible and wearable optoelectronic systems," Dai said. "Thus, we have opened up many possibilities and still have a lot to do."

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Airbus Electric Airplane Flies—For an Hour Per Charge [VIDEO]

The Airbus E-Fan, an all-electric trainer aircraft made of composite material, made its first flight last month–proving once again that it is possible to fly without jet fuel.

That’s with one caveat however: The plane can fly for about an hour on a single charge. But still, this seems like a big deal mainly because the largest aerospace and defense company in Europe and the world’s leading commercial aircraft manufacturer is backing it.

The successful first public flight of the electric E-Fan experimental aircraft was the highlight of Airbus Group’s E-Aircraft Day in Bordeaux, France on April 25. The electric E-Fan training aircraft is an experimental demonstrator based on an all-composite construction. Airbus Group and its partners intend to perform research and development to construct a series version of the E-Fan and propose an industrial plan for a production facility close to Bordeaux Airport. In addition, the group’s research efforts support the environmental protection goals of the European Commission, as outlined in its Flightpath 2050 program.

Built with an all-composite construction, the E-Fan is 22 feet long and has a wingspan of 31 feet. It looks like a toy version of a jet aircraft with a pair of nacelles that aren’t really jets, but two ducted, variable pitch fans spun by two electric motors with a combined power of 60 kW. The ducting increases the thrust while reducing noise, and by centrally mounting them, the fans provide better control. The E-Fan flies at only 114 miles per hour.

Powering the fans are a series of 250-volt, lithium-ion polymer batteries made by Kokam of South Korea. These batteries are mounted in the inboard section of the wings and carry enough charge for up to one hour of flight. They can be recharged in one hour. Worried about the “recharge” light coming on while up in the air? There’s a backup battery for emergency landings.

Another key technology on the E-Fan is its e-FADEC energy management system, which automatically handles the electrical systems. According to Airbus, this simplifies system controls and, since E-Fan is a trainer, eases the workload of instructors and students.

The E-Fan has zero carbon dioxide emissions in flight and should bring a significant reduction in noise around airfields, according to Airbus, “thus improving relations between local residents and flight schools with long-term prospects for the discreet and economical initial training of future professional pilots.”

“It will not only lead to a further reduction in aircraft emissions and noise to support our environmental goals but will also lead to more economic and efficient aircraft technology in the long run. Our focus is to develop innovations that will help define what tomorrow’s aerospace industry will look like,” said Airbus Group Chief Technical Officer Jean Botti.

So today the E-Fan is a learning platform, tomorrow a larger hybrid version that can fly 80 passengers on short regional trips. That’s apparently the plan. From small beginnings, a revolution in the air.