Author: tsport100

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Aston Martin début all-electric all-wheel-drive DBX Concept

Aston Martin has surprise all at the 2015 Geneva Motor Show with the debut of an all electric DBX Concept.

Aston Martin is calling the DBX Concept a high luxury GT that fits the description of a crossover coupe. Far from a production ready vehicle, the concept is just a design study for the time being, but Aston does admit there is a market for such a vehicle.

The DBX Concept is an all-wheel drive crossover high luxury GT that uses in-board electric wheel motors at all four corners powered by lithium sulphur cells. Steering is a drive-by-wire system and both the driver and passenger have head-up displays surrounded by auto-dimming ‘smart glass’.

The DBX Concept can accommodate four adults and all the cargo they could ever want since there is a traditional rear cargo area as well as a front trunk occupying the place usually reserved for a ICE.

Souce: Autocar

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Lower cost carbon nanotube supercapacitors promise 10x higher energy density

Ultra- or supercapacitors are emerging as a key enabling energy storage technology for use in fuel-efficient transport as well as in renewable energy systems (for instance as power grid buffer). These devices combine the advantages of conventional capacitors, that can rapidly deliver high power densities on demand, and batteries, that can store a large amount of electrical energy.

"Among the various types of supercapacitors, carbon nanotube (CNT) based devices have shown an order of magnitude higher performance in terms of energy and power densities," says Ramakrishna Podila, an Assistant Professor in the Department of Physics and Astronomy at Clemson University. "The bottleneck for transferring this technology to the marketplace, however, is the lack of efficient and scalable manufacturing methods."

Podila's team at Clemson University have developed a new scalable method to directly spraycoat CNT-based supercapacitor electrodes. "Much like painting a car or a wall in your home, we can spray CNT solutions on flexible electrodes, porous aluminum foils in our case, to achieve high energy density supercapacitor electrodes without the need of any binder," explains Podila.

The resulting supercapacitors have a 10 times higher energy density compared to the state-of-the-art supercapacitors on the market.

Source: Nanowerk

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Researchers Develop More Efficient ‘Lithium-Air’ Battery

Massachusetts researchers using a fabricated form of carbon have developed battery technology that they hope will enable electric cars to travel far longer distances.

Chemists Dunwei Wang of Boston College and Wei Fan of the University of Massachusetts used an engineered form of the element — called 3DOm carbon — to enhance reactions between lithium and oxygen in batteries.

Researchers seeking a more efficient battery — one capable of allowing cars to travel hundreds of miles without recharging — have focused on the relationship between lithium and oxygen. They believe such "lithium-air" batteries would resolve size and cost constrains faced by current lithium ion batteries.

But the presence of carbon, an essential component in all batteries, previously proved too unstable to generate longer life cycles for the lithium-oxygen reaction.

3DOm carbon, which has a far more orderly molecular structure, apparently resolved those issues. In the German journal Angewandt Chemie, Wang and Fan reported the engineered carbon, along with the addition of molecular coatings, produced substantial improvements in the lithium-oxygen discharge cycle.

"We demonstrated that a particular form of carbon can be used to support a new type of chemistry that allows for energy storage with the promise of five to 10 times more energy density than state-of-the-art lithium-ion batteries we see today," Wang said.

The chemists hope the developments eventually lead to lithium-air batteries that can meet demand for energy, size and cost in the auto industry and other manufacturing sectors.

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Magna to Present Plug-In Hybrid Sports Car Concept at Geneva Motor Show

Magna International Inc. is set to debut MILA Plus, an innovative two-seat hybrid sports car at Geneva Motor Show 2015. The concept vehicle, which will be displayed at Magna's booth #6261 in Hall 6, combines a sophisticated, lightweight construction with an intelligent, alternative-drive solution to produce maximum performance as well as eco-friendliness. With an all-electric range of 75km and a vehicle weight of 1,520kg, MILA Plus achieves reduced CO2 emissions of 32g/km.

"Magna's broad range of services – from engineering to diverse product capabilities to full-vehicle contract manufacturing – helps support our customers as they continue to be challenged with the changing dynamics of the automotive industry. The MILA Plus vehicle concept illustrates our value proposition and advantage within the global supply base," emphasized Günther Apfalter, President Magna Europe and Magna Steyr.

As the latest vehicle concept in the MILA innovation family, MILA Plus features advanced technologies and flexible manufacturing processes with a focus on eco-friendliness.

Lightweight Construction
The structure of MILA Plus is based on an extruded aluminum space frame which has a number of advantages over a steel structure, including: lower weight; modular structural flexibility; and ability to accommodate different driveline configurations. The modular body-in-white (BIW) concept also allows the use of components and systems from large series production, thus enabling improved manufacturing efficiency and flexibility for global automakers.

MILA Plus offers additional benefits aimed at structural rigidity and weight reduction. For example, the concept integrates a high-voltage battery into the space frame, which increases structural rigidity. Lightweight plastic body panels are used due to their corrosion resistance and styling flexibility. A combination of manufacturing methods, sophisticated joining technologies and a multi-material external skin further contribute to a lightweight vehicle architecture that meets global safety standards.

Sophisticated Joining Technologies
Cold mechanical joining, a hybrid process in combination with bonding is used on the BIW. This reliable technology is more cost effective versus traditional welding solutions and is a joining process Magna has used on other vehicles including the Mercedes-Benz SLS AMG and Aston Martin Rapide.

Alternative Drive Solutions
MILA Plus plug-in hybrid system achieves a reduced emission of 32g/km CO2. The performance of the three-cylinder gasoline engine is enhanced by the addition of two electric motors - one between the internal combustion engine and transmission to drive the rear axle, and one on the electric front axle. This arrangement results in an electric all-wheel-drive system which transmits more torque to the road and results in improvement of vehicle maneuverability and dynamics.


Vehicle Dimensions:

Length:              
4403 mm
Width:                
1925 mm
Height:                
1250 mm
Wheelbase:         
2575 mm
Baggage compartment: 
360l (145l front; golf bag possible rear)
Acceleration:                   
0 to 100 km/h in 4.9s
Electric acceleration:       
0 to 80 km/h in 3.6s
Power output (kW/PS):     
200 / 272
Torque (Nm):                      
580 peak
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2015 Audi R8 e-tron confirmed with 450 km range

The 2015 Audi R8 e-tron electric supercar will have 340 kW of power and a remarkable 920 Nm of torque, sprint from 0-100 km/h in 3.9 seconds and offer a range in excess of 450 km.

The second-generation of Audi’s halo product will have more than doubles the range over the original small-batch model thanks to an increase in battery capacity from 49 kWh to approximately 92 kWh. Energy density has increased from 84 Wh/kg to 154 Wh/kg apparently without affecting packaging.

The battery powered R8 has a Combined Charging System (CCS) on board, which allows charging with direct and alternating current. Using this system, it is possible to fully charge the battery in significantly less than two hours.

The rear wheels are powered by two electric motors with specs uprated from 381 HP (280 kW) and 820 Nm (605 lb-ft) to 462 HP (340 kW) and 920 Nm (679 lb-ft). It's enough electric power to provide the Audi R8 e-tron 2.0 with a 0-62 mph (0-100 km/h) time of 3.9 seconds before hitting an electronically-capped top speed of 155 mph (250 km/h).

Audi says the new R8 e-tron serves "primarily as a mobile high-tech laboratory" that will eventually feed into technology used in a high-volume sedan — but in the meantime, if you've got the time and the money, the Germans are willing to build you one by hand. Hopefully we'll see the car on display in Geneva next week.

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Samsung SDI to Acquire Magna International’s Battery Pack Business

Samsung SDI has agreed to acquire the battery pack business of Magna International, a leading global automotive supplier.

The acquisition is expected to enhance Samsung SDI’s capabilities in batteries for electric vehicles by combining the company’s established leadership in battery cells and modules with Magna's expertise in battery packs.

Magna’s advanced technology and experience in providing global automakers with battery packs will also help Samsung SDI secure customers in the fast-growing automotive battery markets in Europe, North America and China.

"The acquisition is a key strategic step for Samsung SDI to strengthen the competitiveness of our automotive battery business,” said Namseong Cho, President and CEO of Samsung SDI. "It will provide new momentum to expand our business and customer base.”

Under the agreement, Samsung SDI will acquire the entire battery pack business from Magna Steyr, an Austria-based operating unit of Magna International, including all 264 employees, production and development sites and existing contracts of the business.

Financial terms of the deal will not be disclosed. The transaction is expected to be completed during the first half of 2015, pending regulatory approvals.

The global market for electric vehicles, including hybrid and plug-in hybrid models, is forecast to reach 7.7 million vehicles by 2020, compared with 2.1 million in 2014, according to research firms B3 and IHS.

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UK Government launch £10m prize for battery innovation

The British Government is launching a £10 million prize for innovation in battery design for the next generation of ultra-low emission vehicles.

The competition will open for bids in April with a winner announced in the summer.

Announcing the prize Chief Secretary to the Treasury Danny Alexander said: "The challenge is to draw on the UK's world-class scientific research and develop a battery which is at the cutting edge of innovation, commercially viable and ready to be put into production.

"The competition will be open to all UK research establishments, working together with vehicle manufacturers based over here in the UK."

Transport campaigner Quentin Willson, who has been involved in designing the prize, said: "The UK should lead the world in cutting-edge ULEV battery technology and this initiative will help create jobs, establish a whole new industry and boost GDP. I totally support this prize for the best in UK battery innovation."

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Carbon Fiber to Go Mainstream in Automobile by 2025

Driven by a faster-than-expected pace of technology development, carbon-fiber reinforced plastics (CFRPs) will be poised to gain widespread adoption for automotive lightweighting by 2025, according to Lux Research.

Already advances underway in fiber, resin and composite part production will lead to a $6 billion market for automotive CFRPs in 2020, more than double Lux's earlier projection. Even this figure is dwarfed by the full potential for CFRPs in automotive if they can become affordable enough for use in mainstream vehicles.

“Current trends strongly indicate significant mainstream automotive adoption of CFRPs in the mid-2020s, and companies throughout the value chain must position themselves to take advantage of the coming shifts. However, long-term megatrends towards urbanization, connectivity and automation suggest that there could be a limited time window beyond that for penetrating the automotive space,” said Anthony Vicari, Lux Research Associate and the lead author of the report titled, “Scaling Up Carbon Fiber: Roadmap to Automotive Adoption.”

“CFRP developers will have to continue the pace of innovation to overcome the high cost that has so far limited the material to less price-sensitive markets like aerospace and sporting goods,” he added.

Lux Research analysts reviewed the technology development in CFRPs, and evaluated its economics to consider its impact on the automotive sector. Among their findings:

  • Growing partnerships hasten development. The number of direct partnerships between carmakers or Tier-1 automotive suppliers and carbon fiber players has nearly doubled to 11 since 2012. Toray, with partnerships with Plasan Carbon Composites and Magna, has formed the most new relationships and is a major hub.

  • Patent uptick suggests mid-2020 adoption. Using a predictive tool, Lux Research identified a lag of about 18 years between uptick of patent activity and attainment of mainstream commercial adoption milestones. With another major upturn in CFRP patent activity occurring in 2007, large-scale mainstream automotive use is likely by the mid-2020s.

  • Other manufacturing costs need to be cut. Carbon fiber itself, at $28/kg for standard modulus fiber, represents just 22% of the cost of a final CFRP part. Additional advances are needed to reduce capital, labor, energy, resin and processing costs, which together make up the remaining 78%.

    Source: Lux Research

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    Electric Jaguar F-Pace crossover Due 2018

    Jaguar Land Rover is developing an electric drivetrain that will debut in a future variant of the upcoming Jaguar F-Pace SUV.

    Unnamed sources within the British automotive industry have told Autocar that Jaguar Land Rover is currently working on an electric vehicle with a range of around 480 kilometres.

    A key rival for the electric Jaguar F-Pace will be the upcoming Tesla Model X and one of the key reasons behind the development of the car is increasingly changing legislation. In the United States for example, eight states including California have adopted new Zero Emission Vehicle legislation which stipulate that between 2018 and 2025, sales of zero emission cars will reach 15.4 per cent from 5 per cent. All told, it is hoped that the effort will result in 3.3 million zero emission vehicles being on U.S. streets in the next 10 years

    With this in mind, it is speculated that the all-electric Jaguar could arrive for the 2018 model year. The British marque will apparently draw on its engineering experience from the hybrid Jaguar C-X75 supercar which was developed alongside Williams Advanced Engineering. The C-X75 combined a twin-charged (supercharged and turbocharged) 1.6-litre four-cylinder delivering 502 hp at 10,000 rpm and mated to four electric motors with one at each axle.

    Source: Autocar