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Audi has taken another big step in the development of new, CO2 neutral fuels: A pilot plant in Dresden has started production of the synthetic fuel Audi e diesel.
After a commissioning phase of just four months, the research facility in Dresden started producing its first batches of high‑quality diesel fuel a few days ago. To demonstrate its suitability for everyday use, Federal Minister of Education and Research Prof. Dr. Johanna Wanka put the first five liters into her official car, an Audi A8 3.0 TDI clean diesel quattro*, this Tuesday. “This synthetic diesel, made using CO2, is a huge success for our sustainability research. If we can make widespread use of CO2 as a raw material, we will make a crucial contribution to climate protection and the efficient use of resources, and put the fundamentals of the “green economy” in place,” declared Wanka.
The Dresden energy technology corporation sunfire is Audi’s project partner and the plant operator. It operates according to the power‑to‑liquid (PtL) principle and uses green power to produce a liquid fuel. The only raw materials needed are water and carbon dioxide. The CO2 used is currently supplied by a biogas facility. In addition, initially a portion of the CO2needed is extracted from the ambient air by means of direct air capturing, a technology of Audi’s Zurich‑based partner Climeworks.
Audi has taken another big step in the development of new, CO2 neutral fuels: A pilot plant in Dresden has started production of the synthetic fuel Audi e diesel.
Minister of Research, Prof. Dr. Johanna Wanka, and Reiner Mangold, Head of Sustainable Product Development at AUDI AG, refueled the Minister’s official car - a Audi A8 3.0 TDI clean diesel quattro - with the first five liters of Audi e-diesel.
Reiner Mangold, Head of Sustainable Product Development at Audi, sees Audi e‑diesel and Audi e‑fuels in general as an important component that complements electric mobility: “In developing Audi e-diesel we are promoting another fuel based on CO2 that will allow long‑distance mobility with virtually no impact on the climate. Using CO2 as a raw material represents an opportunity not just for the automotive industry in Germany, but also to transfer the principle to other sectors and countries.”
Production of Audi e‑diesel involves various steps: First, water heated up to form steam is broken down into hydrogen and oxygen by means of high-temperature electrolysis. This process, involving a temperature in excess of 800 degrees Celsius, is more efficient than conventional techniques because of heat recovery, for example. Another special feature of high-temperature electrolysis is that it can be used dynamically, to stabilize the grid when production of green power peaks.
In two further steps, the hydrogen reacts with the CO2 in synthesis reactors, again under pressure and at high temperature. The reaction product is a liquid made from long‑chain hydrocarbon compounds, known as blue crude. The efficiency of the overall process – from renewable power to liquid hydrocarbon – is very high at around 70 percent. Similarly to a fossil crude oil, blue crude can be refined to yield the end product Audi e‑diesel. This synthetic fuel is free from sulfur and aromatic hydrocarbons, and its high cetane number means it is readily ignitable. As lab tests conducted at Audi have shown, it is suitable for admixing with fossil diesel or, prospectively, for use as a fuel in its own right.
The Federal Ministry of Education and Research is supporting the sunfire project, which started in May 2012. Construction work on the facility in Dresden‑Reick kicked off in July 2013 and the plant was commissioned on November 14, 2014. The plant is set to produce over 3,000 liters (792.5 US gal) of Audi e‑diesel over the coming months. Audi is sunfire’s exclusive partner in the automotive sector.
Over and above the partnership with sunfire, Audi has been active in the development of CO2‑neutral fuels – Audi e‑fuels – since 2009. The Audi e‑gas plant in Werlte, Lower Saxony, already produces Audi e‑gas (synthetic methane) in a comparable manner; drivers of the Audi A3 Sportback g-tron* can fill up on it using a special fuel card. Audi is also conducting joint research into the synthetic manufacture of Audi e‑gasoline with Global Bioenergies, of France. In a further project, Audi has joined forces with the U.S. company Joule, which uses microorganisms to produce the synthetic fuels Audi e‑diesel and Audi e‑ethanol.
Fuel consumption of the models named above:
Audi A8:
Combined fuel consumption in l/100 km: 5.9 (39.9 US mpg)**;
Combined CO2 emissions in g/km: 155 (249.4 g/mi)**
Combined fuel consumption in l/100 km: 5.9 (39.9 US mpg)**;
Combined CO2 emissions in g/km: 155 (249.4 g/mi)**
Audi A3 Sportback g-tron:
CNG consumption in kg/100 kilometers: 3.3 – 3.2 (71.3 – 73.5 US mpg)**;
Combined fuel consumption in l/100 km: 5.2 – 5.0 (45.2 – 47.0 US mpg)**;
Combined CO2 emissions in g/km (CNG): 92 – 88 (148.1 – 141.6 g/mi)**;
Combined CO2 emissions in g/km (gasoline): 120 – 115 (193.1 – 185.1 g/mi)**
CNG consumption in kg/100 kilometers: 3.3 – 3.2 (71.3 – 73.5 US mpg)**;
Combined fuel consumption in l/100 km: 5.2 – 5.0 (45.2 – 47.0 US mpg)**;
Combined CO2 emissions in g/km (CNG): 92 – 88 (148.1 – 141.6 g/mi)**;
Combined CO2 emissions in g/km (gasoline): 120 – 115 (193.1 – 185.1 g/mi)**
**The fuel consumption and the CO2 emissions of a vehicle vary due to the choice of wheels and tires. They not only depend on the efficient utilization of the fuel by the vehicle, but are also influenced by driving behavior and other non-technical factors.
https://www.audi-mediacenter.com/en/press-releases/fuel-of-the-future-research-facility-in-dresden-produces-first-batch-of-audi-e-diesel-352
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TESLA’S MISSION IS TO ACCELERATE THE WORLD’S TRANSITION TO SUSTAINABLE ENERGY.
Tesla was founded in 2003 by a group of engineers in Silicon Valley who wanted to prove that electric cars could be better than gasoline-powered cars. With instant torque, incredible power, and zero emissions, Tesla’s products would be cars without compromise. Each new generation would be increasingly affordable, helping the company work towards its mission: to accelerate the world’s transition to sustainable energy.
Tesla’s engineers first designed a powertrain for a sports car built around an AC induction motor, patented in 1888 by Nikola Tesla, the inventor who inspired the company’s name. The resulting Tesla Roadster was launched in 2008. Accelerating from 0 to 60 mph in 3.7 seconds and achieving a range of 245 miles per charge of its lithium ion battery, the Roadster set a new standard for electric mobility. Tesla would sell more than 2,400 Roadsters, now on the road in more than 30 countries.
In 2012, Tesla launched Model S, the world’s first premium electric sedan. Built from the ground up to be 100 percent electric, Model S has redefined the very concept of a four-door car. With room for seven passengers and more than 64 cubic feet of storage, Model S provides the comfort and utility of a family sedan while achieving the acceleration of a sports car: 0 to 60 mph in about five seconds. Its flat battery pack is integrated into the chassis and sits below the occupant cabin, lending the car a low center of gravity that enables outstanding road holding and handling while driving 265 miles per charge. Model S was named Motor Trend’s 2013 Car of the Year and achieved a 5-star safety rating from the U.S. National Highway Traffic Safety Administration.
In late 2014, Tesla CEO Elon Musk unveiled two dual motor all-wheel drive configurations of Model S that further improve the vehicle’s handling and performance. The 85D features a high efficiency motor at the front and rear, giving the car unparalleled control of traction in all conditions. The P85D pairs a high efficiency front motor with a performance rear motor for supercar acceleration, achieving a 0 to 60 mph time of 3.2 seconds – the fastest four-door production car ever made.
Tesla owners enjoy the benefit of charging at home so they never have to visit a gas station or spend a cent on gasoline. For long distance journeys, Tesla’s Supercharger network provides convenient access to high speed charging, replenishing half a charge in as little as 20 minutes. Superchargers now connect popular routes in North America, Europe, and Asia Pacific.
Tesla’s vehicles are produced at its factory in Fremont, California, previously home to New United Motor Manufacturing Inc., a joint venture between Toyota and General Motors. The Tesla Factory has returned thousands of jobs to the area and is capable of producing 2,000 cars a week.
The company is expanding its manufacturing footprint into other areas, including in Tilburg, the Netherlands, where it has an assembly facility, and Lathrop, California, where it has a specialized production plant. To reduce the costs of lithium ion battery packs, Tesla and key strategic partners including Panasonic have begun construction of a gigafactory in Nevada that will facilitate the production of a mass-market affordable vehicle, Model 3. By 2018, the gigafactory will produce more lithium ion cells than all of the world’s combined output in 2013. The gigafactory will also produce battery packs intended for use in stationary storage, helping to improve robustness of the electrical grid, reduce energy costs for businesses and residences, and provide a backup supply of power.
Tesla is not just an automaker, but also a technology and design company with a focus on energy innovation.
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