Welcome to London's Audi Service.We have a team of Audi specialists who can sort out anything from basic Audi servicing to advanced technical Audi cars problems. One of the best Audi Master Technician on site offering knowledge and experience using the latest Audi Main Dealer compulsory diagnostics equipment.

The active sport differential distributes torque from the engine in continuously variable proportions between the rear wheels.

Targeted control of the power flow enables the car to steer even more spontaneously and directly into bends, and produces a far more robust directional stability.

Depending on the steering angle, lateral acceleration, yaw angle, road speed and other signals, the control unit calculates the most suitable distribution of torque to the wheels for every driving situation.

When the steering wheel is turned or the car is accelerated in a bend, power is redirected in a controlled manner to the outer rear wheel. This has the effect of “forcing” the car into the corner so that it accurately follows the angle of the front wheels.

The difference in tractive force between the left and right wheels exerts an additional steering effect, so that the usual corrections by the driver at the steering wheel are no longer needed. Understeer is completely eliminated. Active torque distribution is based on an entirely new design principle for the rear-axle differential.

So that the new high-tech unit can also divert torque to the outer wheel of the axle, which revolves faster than the inner wheel when cornering, the classic rear-axle differential has been equipped with superposition stages on the left and right, each with a multi-plate clutch running in an oil bath. The clutches are activated by an electro-hydraulic actuator. The superposition stage rotates ten percent faster than the half-shaft that normally drives the wheel; the two components can be coupled by the multi-plate clutch. If the clutch is engaged, the wheel is accelerated by the superposition stage, which is running at a higher speed, and thus receives an additional torque input.

The differential reduces the tractive force reaching the opposite wheel accordingly. In most driving situations, almost the complete input torque can be diverted to one rear wheel in this way. The maximum difference in torque between the wheels is 1,800 newton metres.

Article source: www.audi.co.uk

• Expertise in fuel cell technology – A7 Sportback h-tron quattro technology demonstrator ready for real-life traffic
• Long range – more than 300 miles
• Plug-in hybrid concept with electric quattro

Ingolstadt/Los Angeles, November 19, 2014 - It covers 310 miles on one tank of fuel – and its exhaust emits nothing more than a few drops of water: The A7 Sportback h tron quattro uses a powerful electric drive with a fuel cell as its energy source, in combination with a hybrid battery and an additional electric motor in the rear. Its drive configuration makes the emission-free Audi A7 Sportback h-tron quattro a quattro through and through, with 170 kilowatts of power at its disposal – a new departure in fuel cell cars. There is no mechanical connection between the front and rear axles. As an e quattro, the A7 Sportback h-tron quattro features fully electronic management of torque distribution.

“The A7 Sportback h‑tron quattro is a genuine Audi – at once sporty and efficient. Conceived as an e‑quattro, its two electric motors drive all four wheels,” explained Prof. Dr. Ulrich Hackenberg, Member of the Board of Management for Technical Development at Audi. “The h‑tron concept car shows that we have mastered fuel cell technology. We are in a position to launch the production process as soon as the market and infrastructure are ready.”

The “h” in the name h‑tron denotes the chemical element hydrogen. In visual terms the technology demonstrators that Audi has brought along to the Los Angeles Auto Show basically resemble the production models. As the label with the h‑tron signet reveals, this concept car now takes its place alongside the other Audi models with alternative drive principles, the e‑tron and g‑tron. Externally, there is no other evidence of the fuel cell that converts hydrogen into electrical power on board the vehicle.

The fuel cell

The crucial differences are beneath the bonnet of the A7 Sportback: The fuel cell in the Audi technology demonstrator is installed at the front, mirroring the conventional A7 Sportback with combustion engine. Because the exhaust system only has to handle water vapour, it is made of weight‑saving plastic.

The fuel cell itself comprises over 300 individual cells that together form a stack. The core of each of these individual cells is a polymer membrane. There is a platinum-based catalyst on both sides of the membrane.

This is how the fuel cell works: Hydrogen is supplied to the anode, where it is broken down into protons and electrons. The protons migrate through the membrane to the cathode, where they react with the oxygen present in air to form water vapour. Meanwhile, outside the stack the electrons supply the electrical power – depending on load point, the individual cell voltage is 0.6 to 0.8 volts.

The entire fuel cell operates in the voltage range of 230 to 360 volts.

The main auxiliary assemblies include

• a turbocharger that forces the air into the cells
• the so-called recirculation fan – it returns unused hydrogen to the anode, thus increasing efficiency, and
• a coolant pump.

These components have a high-voltage electric drive and are powered by the fuel cell.

There is a separate cooling circuit for the essential cooling of the fuel cell. A heat exchanger and a thermoelectric, self-regulating auxiliary heating element maintain pleasant temperatures in the cabin.

The fuel cell, which operates across a temperature range of 80 degrees Celsius, places higher demands on the vehicle cooling than an equivalent combustion engine but achieves superior efficiency of as high as 60 percent – almost double that of a conventional combustion engine. Its cold-starting performance is guaranteed down to -28 degrees Celsius.

Plug-in hybrid

A special feature of the A7 Sportback h‑tron quattro is its plug‑in hybrid concept – this represents a logical evolution from the Audi A2 H2 and Q5 HFC test cars. It has a lithium‑ion battery on board that can be recharged from the power socket by lead; with an 8.8 kWh energy capacity, it has been adopted from the A3 Sportback e‑tron*. It is located beneath the boot and has a separate cooling circuit for thermal management.

This high‑performance battery makes the ideal partner to the fuel cell. It can store energy recovered from brake applications and supply considerable power for full‑load boosting. This paves the way for impressive acceleration, making the A7 Sportback h‑tron quattro truly live up to quattro standards. Both the front and rear axles have no mechanical connections for the transmission of power. In the event of slip, the torque for both driven axles can be controlled electronically and adjusted continuously.

On battery power, the Audi A7 Sportback h‑tron quattro covers as much as 31 miles. The battery in the rear of the plug‑in hybrid can be recharged by lead. Depending on the voltage and current rating, a full recharge takes between two hours (industrial power socket/360 volts) and four hours (domestic power socket at 230 volts).

The battery operates at a different voltage level to the fuel cell. For that reason, there is a DC converter (DC/AC) between the two components. This tri‑port converter is located behind the stack. In many operating statuses it equalises the voltage, enabling the electric motors to operate at their maximum efficiency of 95 percent.

The power electronics in the front and rear of the vehicle convert the direct current from the fuel cell and battery into alternating current for the electric motors to drive the front and rear axles separately.

The two electric motors, which are cooled by a low-temperature circuit together with the voltage converters, are permanently excited synchronous machines. Each of them has an output of 85 kW, or even 114 kW if the voltage is temporarily raised. The peak torque is 270 Newtonmeters (199.1 lb‑ft) per electric motor.

The electric motors’ housings incorporate planetary gear trains with a single transmission ratio of 7.6:1. A mechanical parking lock and a differential function round off the system.

The appeal of e-quattro

Driving in the Audi A7 Sportback h‑tron quattro offers the full appeal of electric drive in conjunction with the new e‑quattro. The silent propulsion is fully available from the off, and the fuel cell reaches its maximum output within one second at full load – a more dynamic response than a combustion engine because the entire drive system involves only a few mechanical components.

With 540 Nm (398.3 lb‑ft) of propulsive power at its disposal the Audi A7 Sportback h‑tron quattro, which tips the scales at only around 1,950 kilograms, races from a standstill to 62 mph in 7.9 seconds. Its top speed is  111 mph – a top figure for its field of competitors. The e‑quattro concept requires precise coordination of the electric motors – the technology demonstrator offers a dynamic, stable and high-traction drive that is comparable to a production car with mechanical quattro drive.

A power meter – in the place of the revolution counter in the instrument cluster – informs the driver of the momentary power flow. The outer sections show the fuel level in the hydrogen tank and the level of battery charge. Graphics on the MMI monitor visualise the energy flow. When the driver presses the EV button, the technology demonstrator drives solely on battery power.

Switching from automatic transmission mode D to S increases the level of energy recovery when braking, so that the battery is charged up effectively during sporty driving. Brake applications, too, are almost always accomplished fully electrically: The electric motors then act as alternators and convert the car’s kinetic energy into electrical energy that is stored in the battery. The four disc brakes only become involved if more forceful or emergency braking is required.

The tank flap is in the right side section of the five-door coupé, concealing a filler connector for the hydrogen. Fully refueling with H₂takes around three minutes, roughly as the same as a conventional automobile. The tanks communicate with the refuelling system by infrared interface and equalise the pressure and temperature levels.

Zero emissions

The four hydrogen tanks of the Audi A7 Sportback h‑tron quattro are located beneath the base of the boot, in front of the rear axle, in the centre tunnel. An outer skin made from carbon fibre reinforced polymer (CFRP) encases the inner aluminium shell. The tanks can store around five kilograms of hydrogen at a pressure of 700 bar – enough to drive for around 310 miles. According to the NEDC cycle, fuel consumption is roughly one kilogram of hydrogen per 100 kilometers – an amount with an energy content equivalent to 76.4mpg combined.

It is already the case that the A7 Sportback h‑tron quattro always travels with zero local emissions. By using the renewable fuel hydrogen, it can also be used globally as a zero emissions vehicle: Since 2013 Audi has been operating a pilot plant in which renewable wind power is used to produce hydrogen by electrolysis. At present, this hydrogen is still used in an additional production process to obtain synthetic methane (Audi e‑gas). A future move to feed this hydrogen into a hydrogen supply and filling station network would make it available for refueling fuel-cell vehicles. This is a sound option for sustainable mobility with no emissions.

Article source: www.audi.co.uk

As a car manufacturer, we can never claim to have a truly positive impact on the environment – and nor should anyone else in the automotive industry. But what we can be certain about is that the billions of pounds we’re investing in responsible technologies over the next decade will place Audi at the forefront of efficient motoring and manufacture.

The principles of constant innovation at the heart of Vorsprung durch Technik already place Audi in a strong position. Technologies such as our lightweight space frames, efficient TDI engines and our waste-reducing manufacturing processes all serve to cut CO2 emissions. And we’ve been doing this for years – we’ve improved our cars’ efficiency by over a third during the last 20 years, and by 2012 we pledge to reduce the emissions of our vehicles by a further 20 per cent.

We’re continuing to work hard today to create a clean driving tomorrow and have a number of very exciting developments to offer our customers over the coming years. Read on to learn more about our commitment to reducing our, and your, impact on the environment.

In the UK

Whilst our colleagues in Germany are doing everything they can to make our cars more efficient, at Audi Head Office in Milton Keynes we are also committed to reducing waste.  A lot of what we do isn’t very innovative, you probably recycle paper and switch off unused appliances at home, but it does make a significant difference to our carbon footprint.  On top of this, by investing in technologies like intelligent lighting and video conferencing we are able to work efficiently without compromising our business standards.  And by joining forces with Audi UK’s franchise operation to minimise waste, we are generating tangible environmental benefits across the whole of the network.

Article source: www.audi.co.uk

Even the refuelling process has been inspired by the Audi R18. Open the classically TT-styled aluminium-look tank cap and the refuelling nozzle can be inserted straight into the filler neck. Just one of the ways the new generation TT has become a true sports car.

Article source: www.audi.co.uk