Ford’s First Factory Fully Electric Dragster – Mustang Cobra Jet 1400


It won’t hurt your ears and doesn’t use a drop of fuel, but it’s projected to crush the quarter-mile in the low-8-second range at more than 170 mph. For the first time ever, Ford Performance introduces a one-off Mustang Cobra Jet factory drag racer with all-electric propulsion.

The battery-powered Mustang Cobra Jet 1400 prototype is purpose-built and projected to deliver over 1,400 horsepower and over 1,100 ft.-lbs. of instant torque to demonstrate the capabilities of an electric powertrain in one of the most demanding race environments.

“Ford has always used motorsport to demonstrate innovation,” said Dave Pericak, Global Director, Ford Icons. “Electric powertrains give us a completely new kind of performance and the all-electric Cobra Jet 1400 is one example of pushing new technology to the absolute limit. We’re excited to showcase what’s possible in an exciting year when we also have the all-electric Mustang Mach-E joining the Mustang family.”

Following the debut of the all-electric Ford Mustang Mach-E SUV – the first-ever, all-electric Mustang, the Mustang Cobra Jet 1400 prototype represents another opportunity to advance Mustang heritage and performance while simultaneously incorporating some of the most advanced technology coming to Ford’s future powertrains.

Mustang Cobra Jet 1400 also honors the original Cobra Jet that first dominated drag strips in the late 1960s and still is a major force in sportsman drag racing today.

"This project was a challenge for all of us at Ford Performance, but a challenge we loved jumping into,” said Mark Rushbrook, Global Director, Ford Performance Motorsports. “We saw the Cobra Jet 1400 project as an opportunity to start developing electric powertrains in a race car package that we already had a lot of experience with, so we had performance benchmarks we wanted to match and beat right now. This has been a fantastic project to work on, and we hope the first of many coming from our team at Ford Performance Motorsports."

Ford have yet to reveal any technical information about the electric Cobra Jet’s motors, batteries etc but we can have a few educated guesses:

  • Motors: 2x AM Racing Dual Stack 250 Motors. Most likely 2x of these motors are stacked vertically for a grand total of 4x HVH Remy 250 cores.
  • Inverters: 4x RMS PM250 DZ - 450Arms continuous, 600Arms peak, 300-800v
  • Transmission: The video sounds like a 2 speed Powerglide.
  • Rear-end: Most likely shortened Ford 9 inch diff - typical drag racing equipment.
*Note: RMS & AM Racing are now owned by Borg Warner under the new name Cascadia Motion. Remy is also owned by Borg Warner.

Ford Performance continues to test Cobra Jet 1400 ahead of its world debut later this year at a drag racing event where fans, media and competitors alike will get to meet the race car, as well as see exactly what it’s capable of up on the asphalt.

Before that, catch a sneak peek starting this Sunday, April 26 by watching MotorTrend On Demand’s “Hard Cell”, a showcase of electric vehicles pushing innovation boundaries.

To maximize the efficiency and effectiveness of the project, Ford Performance has teamed up with several capable and specialized suppliers:
  • MLe Racecars – Vehicle builder, designer, integrator and tuner
  • Watson Engineering – Chassis support and development, roll cage builder
  • AEM EV – Software and motor calibration and controls
  • Cascadia – Inverter and Motor supplier












German OEMs Plan 350 kW Fast Charging Network Across Europe

BMW Group, Daimler AG, Ford Motor Company and Volkswagen Group with Audi and Porsche have signed a Memorandum of Understanding to create the highest-powered charging network in Europe. The goal is the quick build-up of a sizable number of stations in order to enable long-range travel for battery electric vehicle drivers. This will be an important step towards facilitating mass-market BEV adoption.

The projected ultra-fast high-powered charging network with power levels up to 350 kW will be significantly faster than the most powerful charging system deployed today. The build-up is planned to start in 2017. An initial target of about 400 sites in Europe is planned. By 2020 the customers should have access to thousands of high-powered charging points. The goal is to enable long-distance travel through open-network charging stations along highways and major thoroughfares, which has not been feasible for most BEV drivers to date. The charging experience is expected to evolve to be as convenient as refueling at conventional gas stations.

The network will be based on Combined Charging System (CCS) standard technology. The planned charging infrastructure expands the existing technical standard for AC- and DC charging of electric vehicles to the next level of capacity for DC fast charging with up to 350 kW. BEVs that are engineered to accept this full power of the charge stations can recharge brand-independently in a fraction of the time of today’s BEVs. The network is intended to serve all CCS equipped vehicles to facilitate the BEV adoption in Europe.

Ford CEO confirms plans for long-range electric car

Ford CEO Mark Fields said the Dearborn automaker will not be left behind in the race to develop long-range electric vehicles like the Tesla Model 3 and Chevrolet Bolt that can go 320 km (200 miles) or more on a single charge.

“We want to make sure that we’re either among the leaders or in a leadership position,” Fields said during a conference call Thursday with analysts. “When you look at some of the competitors and what they’ve announced, clearly, that’s something we’re developing for.”

The Chevrolet Bolt will have a range of at least 320 km and a starting price of about $27,000 when it goes on sale later this year.

Tesla CEO Elon Musk generated global buzz when he unveiled the Tesla Model 3 earlier this month. That car is expected to have 345 km (215 miles) of range and will go on sale in late 2017 at a starting price of $35,000.

Earlier this month, Automotive News reported that the automaker was satisfied with its 2017 Focus Electric that will get 160 km (100 miles) on a full charge, saying that vehicle will satisfy a large chunk of consumers.

Fields didn’t say when Ford plans to launch a vehicle to match Tesla's Model 3 or the Chevrolet Bolt, but made it clear Ford is pressing forward.

He did reiterate Ford's plans to spend $4.5 billion over the next four years to develop 13 new hybrid or electric vehicles.

"Our approach, very simply, is to make sure we are among the leaders or in a leadership position in the product segments that we are in," Fields said.

Ford Motor Company are collaborating with Xerox PARC and Oak Ridge National Laboratory to develop pouch cells with a 20% improvement in gravimetric energy density (Wh/kg), and a 30% reduction in $/kWh costs for electric vehciles.

Ford, Xerox PARC & Oak Ridge Labs Team up to Develop EV Battery

Xerox PARC today announced its ‘Co-Extrusion (CoEx) for Cost Reduction of Advanced High-Energy-and-Power Battery Electrode Manufacturing’ project funded by the U.S. Department of Energy’s (DOE) Office of Energy Efficiency and Renewable Energy (EERE). In collaboration with Oak Ridge National Laboratory (ORNL) and Ford Motor Company, the project will use PARC’s novel CoEx printing technology to fabricate thick higher energy and higher power battery electrodes with the end goal of enabling longer range and low cost electric vehicles.

The project goal is to demonstrate pilot-scale, electric vehicle (EV) pouch cells with a 20% improvement in gravimetric energy density (Wh/kg), and a 30% reduction in $/kWh costs. CoEx allows fine structures to be printed at high speed, and when applied to thick battery electrodes, it adds a new design dimension that can be used to enhance energy and power performance. This innovative approach has the potential to help make high performance and affordable electric vehicles (EVs) a reality.

PARC will develop the inks and CoEx hardware required to fabricate a thick high energy and high power CoEx cathode electrodes. ORNL will assist PARC with the matching anode development, anode and CoEx cathode coating at pilot scale, and electrochemical performance optimization in automotive-relevant lithium-ion pouch cells. The bulk of this research will occur at the DOE Battery Manufacturing R&D Facility (BMF) at ORNL, which was designed in 2011 with these types of projects in mind. PARC will design a custom CoEx apparatus that will be integrated into one of the research coating lines at the BMF.

“The PARC team is excited to start this collaboration with ORNL and Ford. CoEx has the potential to make higher capacity EV batteries possible through the creation of two and three dimensional structures which can enhance lithium-ion pathways in ultra-thick battery electrodes. Our goal is to fabricate EV pouch cells that are higher in energy and power than conventional, with a path towards a reduction in $/kWh costs for EVs”said project principal investigator and PARC CoEx technical lead Dr. Corie Cobb.

“PARC and ORNL have a track record of working successfully together, and their collaboration on this project will transform the way lithium-ion electrode coatings are made and perform under high discharge rates,” said ORNL project lead David Wood.

PARC’s CoEx project is part of a portfolio of research within the PARC Energy Technology Program aimed at developing practical solutions to make clean and abundant energy available across a wide range of applications. This includes a focus on improving energy storage for EVs, consumer electronics, and electric grid support through better ways to make, monitor, and manage batteries.

“By leveraging our deep background in printing, PARC has developed the CoEx printing process to enable higher performance solar cells, fuel cells and batteries.,” said Scott Elrod, Vice President of PARC’s Hardware Systems Lab. “By applying CoEx to printed batteries, we can create optimal structures that boost power performance without compromising energy storage. It’s an efficient and a lower-cost approach that can be applied to the mass manufacturing of batteries.”

Ford C-MAX Solar Energi Hybrid Concept Goes Off the Grid

Ford Motor Company announced today the C-MAX Solar Energi Concept, a first-of-its-kind sun-powered vehicle with the potential to deliver the best of what a plug-in hybrid offers – without depending on the electric grid for fuel.

Instead of powering its battery from an electrical outlet, Ford C-MAX Solar Energi Concept harnesses the power of the sun by using a special concentrator that acts like a magnifying glass, directing intense rays to solar panels on the vehicle roof.

The result is a concept vehicle that takes a day's worth of sunlight to deliver the same performance as the conventional C-MAX Energi plug-in hybrid, which draws its power from the electric grid. Ford C-MAX Energi gets a combined best miles per gallon equivalent in its class, with EPA-estimated 108 MPGe city and 92 MPGe highway, for a combined 100 MPGe. By using renewable power, Ford C-MAX Solar Energi Concept is estimated to reduce the annual greenhouse gas emissions a typical owner would produce by four metric tons.

"Ford C-MAX Solar Energi Concept shines a new light on electric transportation and renewable energy," said Mike Tinskey, Ford global director of vehicle electrification and infrastructure. "As an innovation leader, we want to further the public dialog about the art of the possible in moving the world toward a cleaner future."

C-MAX Solar Energi Concept, which will be shown at the 2014 International CES in Las Vegas, is a collaborative project of Ford, San Jose, Calif.-based SunPower Corp. and Atlanta-based Georgia Institute of Technology.

Strong electrified vehicle sales

The C-MAX Solar Energi Concept debuts as Ford caps a record year of electrified vehicle sales.

Ford expects to sell 85,000 hybrids, plug-in hybrids and all-electric vehicles for 2013 – the first full year its six new electrified vehicles were available in dealer showrooms.

C-MAX Energi is Ford's plug-in sales leader, with sales of more than 6,300 through November. Ford sold more plug-in vehicles in October and November than both Toyota and Tesla, and it outsold Toyota through the first 11 months of 2013. Plug-in hybrids continue to grow in sales as more customers discover the benefits of using electricity to extend their driving range.

C-MAX Hybrid over the last year has been a key driver in helping Ford sell more hybrids than any other automaker in the United States, second only to Toyota. C-MAX Hybrid continues to bring new customers to the Ford brand, with a conquest rate of 64 percent and drawing nearly half of its sales from import brands. Conquest rates are even higher in key hybrid growth markets like San Francisco, Los Angeles and Washington, D.C.

Breakthrough clean technology

SunPower, which has been Ford's solar technology partner since 2011, is providing high-efficiency solar cells for the roof of Ford C-MAX Solar Energi Concept. Because of the extended time it takes to absorb enough energy to fully charge the vehicle, Ford turned to Georgia Institute of Technology for a way to amplify the sunlight in order to make a solar-powered hybrid feasible for daily use.

Researchers developed an off-vehicle solar concentrator that uses a special Fresnel lens to direct sunlight to the solar cells while boosting the impact of the sunlight by a factor of eight. Fresnel is a compact lens originally developed for use in lighthouses. Similar in concept to a magnifying glass, the patent-pending system tracks the sun as it moves from east to west, drawing enough power from the sun through the concentrator each day to equal a four-hour battery charge (8 kilowatts).

With a full charge, Ford C-MAX Solar Energi Concept is estimated to have the same total range as a conventional C-MAX Energi of up to 620 miles, including up to 21 electric-only miles. Additionally, the vehicle still has a charge port, and can be charged by connecting to a charging station via cord and plug so that drivers retain the option to power up via the grid, if desired.

After C-MAX Solar Energi Concept is shown at CES, Ford and Georgia Tech will begin testing the vehicle in numerous real-world scenarios. The outcome of those tests will help to determine if the concept is feasible as a production car.

Off-the-grid car

By tapping renewable solar energy with a rooftop solar panel system, C-MAX Solar Energi Concept is not dependent on the traditional electric grid for its battery power. Internal Ford data suggest the sun could power up to 75 percent of all trips made by an average driver in a solar hybrid vehicle. This could be especially important in places where the electric grid is underdeveloped, unreliable or expensive to use.

The vehicle also reinforces MyEnergi Lifestyle, a concept revealed by Ford and several partners at 2013 CES. MyEnergi Lifestyle uses math, science and computer modeling to help homeowners understand how they can take advantage of energy-efficient home appliances, solar power systems and plug-in hybrid vehicles to significantly reduce monthly expenses while also reducing their overall carbon footprint.

The positive environmental impact from Ford C-MAX Solar Energi could be significant. It would reduce yearly CO2 and other greenhouse gas emissions from the average U.S. car owner by as much as four metric tons – the equivalent of what a U.S. house produces in four months.

If all light-duty vehicles in the United States were to adopt Ford C-MAX Solar Energi Concept technology, annual greenhouse gas emissions could be reduced by approximately 1 billion metric tons.

Ford Reveals Automated Fusion Hybrid Research Vehicle

Taking the next step in its Blueprint for Mobility, Ford today – in conjunction with the University of Michigan and State Farm® – revealed a Ford Fusion Hybrid automated research vehicle that will be used to make progress on future automated driving and other advanced technologies.

The result of an ongoing project that builds on more than a decade of Ford's automated driving research, the Fusion Hybrid automated vehicle will test current and future sensing systems and driver-assist technologies. Ford's goal is to advance development of new technologies with its supplier partners so these features can be applied to the company's next generation of vehicles.

"The Ford Fusion Hybrid automated vehicle represents a vital step toward our vision for the future of mobility," said Ford Executive Chairman Bill Ford. "We see a future of connected cars that communicate with each other and the world around them to make driving safer, ease traffic congestion and sustain the environment. By doing this, Ford is set to have an even greater impact in our next 100 years than we did in our first 100."

Today's Ford vehicles already have technology that enables them to park themselves, understand a driver's voice commands, detect dangerous driving situations and assist with emergency braking. With these technologies and others that one day could allow a person to be driven to a destination, the driver always will need to be in control of the wheel if necessary.

"In the future, automated driving may well help us improve driver safety and manage issues such as traffic congestion and global gridlock, yet there are still many questions that need to be answered and explored to make it a long-term reality," said Raj Nair, group vice president, Ford global product development. "With the automated Ford Fusion Hybrid research project, our goal is to test the limits of full automation and determine the appropriate levels for near- and mid-term deployment."

The automated Fusion Hybrid will serve as the research platform to develop potential solutions for these longer-term societal, legislative and technological issues raised by a future of fully automated vehicles.

The Fusion Hybrid research vehicle builds on driver-in-control studies conducted in Ford's VIRTTEX driving simulator. Using VIRTTEX, Ford researchers study how to merge the capabilities of human and automated drivers to create a seamless, integrated experience.

Ford's Blueprint for Mobility
Last year at the Mobile World Congress in Barcelona, Bill Ford outlined Ford Motor Company's Blueprint for Mobility – a plan that describes what the automaker believes transportation will look like in 2025 and beyond, and the technologies, business models and partnerships needed to get there.

Today, Ford is working on improving technology already used in vehicles on the road. This includes functions that alert drivers to traffic jams and accidents, and technologies for parking and for driving in slow-moving traffic.

In the mid-term, vehicle-to-vehicle communications will begin to enter into the mainstream. This will include some autopilot capabilities, such as vehicle "platooning," where vehicles traveling in the same direction sync up their movements to create denser driving patterns.

In the longer-term, vehicles will have fully autonomous navigation and parking. They will communicate with each other and the world around them, and become one element of a fully integrated transportation ecosystem. Personal vehicle ownership also will change as new business models develop. The benefits include improved safety, reduced traffic congestion and the ability to achieve major environmental improvements.

Tomorrow's technology, today
The Ford Fusion Hybrid was chosen as the test platform for the new research effort because it is among the leaders in offering the most advanced driver-assist technologies in its class.

These technologies include Blind Spot Information System, active park assist, lane-departure warning, and adaptive cruise control and collision warning with brake support. These vehicle sensing systems, offered on many Ford vehicles today, are the building blocks for the future of fully automated driving.

In North America, these technologies can be found on Ford Focus, C-MAX hybrids, Fusion, Taurus, Escape, Explorer and Flex. In Europe, these technologies are available on Ford C-MAX, Mondeo, S-MAX and Galaxy.

"Products such as Ford Fusion Hybrid give us a head start in the development of automated features," said Paul Mascarenas, chief technical officer and vice president, Ford research and innovation. "Our Blueprint for Mobility aligns the desired outcomes of our work in automated functionality with the democratization of driver-assist technology found on today's lineup of Ford products."

Ford's Fusion Hybrid research vehicle is unique in that it first uses the same technology found in Ford vehicles in dealer showrooms today, then adds four scanning infrared light sensors – named LiDAR (for Light Detection And Ranging) – that scan the road at 2.5 million times per second. LiDAR uses light in the same way a bat or dolphin uses sound waves, and can bounce infrared light off everything within 200 feet to generate a real-time 3D map of the surrounding environment.

The sensors can track anything dense enough to redirect light – whether stationary objects, or moving objects such as vehicles, pedestrians and bicyclists. The sensors are so sensitive they can sense the difference between a paper bag and a small animal at nearly a football field away.

Working together
Developing the necessary infrastructure to support a sustainable transportation ecosystem will require the collaboration of many partners across multiple industries. State Farm and the University of Michigan's robotics and automation research team are critical to creating the visionary research project.

Ford's work with others on the future of mobility is longstanding. Ford was an active participant in the Defense Advanced Research Projects Agency (DARPA)-controlled autonomous vehicle challenges in 2004, 2005 and 2007, the year Ford extended its efforts to include the University of Michigan.

While Ford is responsible for developing unique components allowing for the vehicle to function at high levels of automation, the University of Michigan – under the direction of faculty members Ryan Eustice and Edwin Olson – is leading in development of sensor-based technologies. The sensors aid in the logic and virtual decision making necessary to help the vehicle understand its physical surroundings on the road.

The university's researchers are processing the trillions of bytes of data collected by the vehicle's sensors, from which they can build a 3D model of the environment around the vehicle. The goal is to help the vehicle – and the driver – make appropriate and safe driving decisions.

"This research builds on the University of Michigan's long history of pioneering automotive research with Ford," said Alec Gallimore, associate dean of research and graduate education at the school's College of Engineering. "The unique collaboration will enable Ford to benefit from the university's deep knowledge of robotics and automation, and it will allow University of Michigan faculty and students to work side-by-side with some of the best auto engineers in the world."

Meanwhile, State Farm has been working with Ford to assess the impact of driver-assist technologies to determine if the technologies can lower the rate of rear collisions.

Last year there were nearly 34,000 fatalities due to traffic accidents in the United States. By developing more intelligent vehicles, Ford helps create smarter drivers.

"By teaming up with Ford and the University of Michigan in this research, we are continuing our decades-long commitment to making vehicles, roadways and drivers safer," said State Farm Chairman and CEO Edward Rust. "The changes new technologies bring to our lives are exciting, and we are always looking at how technology can better meet the ever-changing needs of our customers."

Setting the stage for mobility in Michigan
Today's Ford Fusion Hybrid research vehicle announcement follows an aggressive plan released this week by Business Leaders for Michigan to position the state as the global center for mobility and grow up to 100,000 new jobs in its auto sector by becoming a hub for excellence in advanced powertrain, lightweight and smart/connected transportation technologies.

With Bill Ford as champion of Business Leaders for Michigan's mobility initiative, the plan has been developed with a coalition of top industry experts, the Center for Automotive Research and McKinsey & Company. The plan identifies growth strategies for the auto sector as it transitions to an increasingly advanced technology-based sector.

Ford outsells plug-in rivals for first time in October

Ford said Monday it sold 2,179 of its Fusion and C-Max plug-in hybrids last month, topping the totals of plug-in competitors Toyota Motor Corp. and General Motors Corp. for the first time.

Toyota sold 2,095 of its Prius plug-in cars and GM sold 2,022 of its Volt range-extended plug-in hybrid sedans.

Sales of plug-in vehicles — excluding full battery-electric cars — total 39,083 through October, up from the 29,075 sold during the same period in 2012, according to data from automakers and the Electric Drive Transportation Association.

But plug-in vehicles still represent less than 1 percent of new-vehicle sales.

Ford sales of the Fusion and C-Max Energi cars helped the Dearborn automaker to its best plug-in hybrid vehicle sales month ever.

Plug-In EVs report strong June sales month in US

Electric vehicles had their strongest month in June this year as major automakers cut prices and added hefty incentives to boost sales.

General Motors reported sales jumped by 53 percent to 2,698 in June, up over the 1,760 in June 2012 after it offered incentives worth as much as $5,000 off 2012 models and $4,000 off 2013 models. For the first half of 2013, sales are up 11.8 percent.

Nissan said sales of its all-electric Leaf were up 315 percent over June 2012 to 2,225, for its second-best ever month. Nissan has now sold 9,849 in the first half of 2013, more than the 9,819 it sold in all of 2012. In January, Nissan said it was cutting the price of the entry-level Leaf 18 percent to $28,800 for the 2013 model as it launched U.S. production.

Honda had its best-ever month in June with 208 Fit EVs sold, after selling 83 in the first five months of the year. Honda announced in May that it has cut the monthly lease payment on its Fit EV from $389 to $259 and also is cutting the payment for those who already had leased the vehicle. Honda sold just 93 last year.

Honda started sales in July 2012 of the Fit EV and said it plans to sell just 1,100 over two years, citing capacity constraints. The company has 200 dealers selling the Fit EV and said it plans steadier availability. Honda spokeswoman Jessica Fini said after the lease price was cut, “basically everything on the ground sold,” but she emphasized that the company still has inventory to sell.

GM plans to keep the same incentives in place for at least another month. GM is offering $5,000 off the 2012, and $4,000 off the 2013, and a $269 lease for 36 months with $2,399 due at signing. More than 40 percent of Volts are sold in California, followed by Michigan in second.

Malcho said GM has increased its incentives to stay competitive in the electric vehicle market. The company also wants to clear out some inventory before it begins building 2014 Volts later this summer.

In January, Ford Motor Co. dropped the price of the lease for a Focus EV from about $350 a month to $285, plus $930 due at signing. Ford reduced the base price of the EV Focus by $2,000 to $37,995. But Ford EV sales have remained very modest. Ford sold 157 Focus EVs in May to 723 for the first five months of the year. By contrast Ford has sold 8,177 hybrids in the first five months of the year.

Ford Focus Electric Production Begins in Europe

Ford Motor Company today began a new chapter in its vehicle manufacturing history with the start of production of the all-new Focus Electric – the first full-electric vehicle to be built by Ford in...

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