Dual Clutch Gearbox

Most of the present cars come with two basic transmission types: manuals, which require that the driver change gears by depressing a clutch pedal and using a stick shift, and automatics, which do all of the shifting work for drivers using clutches, a torque converter and sets of planetary gears. But there's also something in between that offers the best of both worlds -- the dual-clutch transmission, also called the semi-automatic transmission, the "clutchless" manual transmission and the automated manual transmission.
In the world of racecars, semi-automatic transmissions, such as the sequential manual gearbox (or SMG), have been a staple for years. But in the world of production vehicles, it's a relatively new technology, one that is being defined by a very specific design known as the dual-clutch, or direct-shift gearbox.

Comparison between the working mechanisms of A conventional manual transmission and DCT:

A dual-clutch transmission offers the function of two manual gearboxes in one. To understand what this means, it's helpful to review how a conventional manual gearbox works. When a driver wants to change from one gear to another in a standard stick-shift car, he first presses down the clutch pedal. This operates a single clutch, which disconnects the engine from the gearbox and interrupts power flow to the transmission. Then the driver uses the stick shift to select a new gear, a process that involves moving a toothed collar from one gear wheel to another gear wheel of a different size. Devices called synchronizers match the gears before they are engaged to prevent grinding. Once the new gear is engaged, the driver releases the clutch pedal, which re-connects the engine to the gearbox and transmits power to the wheels.
So, in a conventional manual transmission, there is not a continuous flow of power from the engine to the wheels. Instead, power delivery changes from on to off to on during gearshift, causing a phenomenon known as "shift shock" or "torque interrupt." For an unskilled driver, this can result in passengers being thrown forward and back again as gears are changed. The graphical layout of the DCT is shown below.

Layout of a DCT:

(from above figure)A dual-clutch gearbox, by contrast, uses two clutches, but has no clutch pedal. Sophisticated electronics and hydraulics control the clutches, just as they do in a standard automatic transmission. In a DCT, however, the clutches operate independently. One clutch controls the odd gears (first, third, fifth and reverse), while the other controls the even gears (second, fourth and sixth). Using this arrangement, gears can be changed without interrupting the power flow from the engine to the transmission.

Sequentially, it works like this:

A two-part transmission shaft is at the heart of a DCT. Unlike a conventional manual gearbox, which houses all of its gears on a single input shaft, the DCT splits up odd and even gears on two input shafts. The outer shaft is hollowed out, making room for an inner shaft, which is nested inside. The outer hollow shaft feeds second and fourth gears, while the inner shaft feeds first, third and fifth. The diagram below shows this arrangement for a typical five-speed DCT. Notice that one clutch controls second and fourth gears, while another, independent clutch controls first, third and fifth gears. That's the trick that allows lightning-fast gear changes and keeps power delivery constant. A standard manual transmission can't do this because it must use one clutchfor all odd and even gears.

Torque converter or Multiplate clutch:

Because a dual-clutch transmission is similar to an automatic, you might think that it requires a torque converter, which is how an automatic transfers engine torque from the engine to the transmission. DCTs, however, don't require torque converters. Instead, DCTs currently on the market use wet multi-plate clutches. A "wet" clutch is one that bathes the clutch components in lubricating fluid to reduce friction and limit the production of heat. Several manufacturers are developing DCTs that use dry clutches, like those usually associated with manual transmissions, but all production vehicles equipped with DCTs today use the wet version.

Exploded view of multiplate clutch used in DCT:

Like torque converters, wet multi-plate clutches use hydraulic pressure to drive the gears. The fluid does its work inside the clutch piston, seen in the diagram above. When the clutch is engaged, hydraulic pressure inside the piston forces a set of coil springs part, which pushes a series of stacked clutch plates and friction discs against a fixed pressure plate. The friction discs have internal teeth that are sized and shaped to mesh with splines on the clutch drum. In turn, the drum is connected to the gearset that will receive the transfer force. Audi's dual-clutch transmission has both a small coil spring and a large diaphragm spring in its wet multi-plate clutches.

Engagement mechanisms for odd and even gears:

To disengage the clutch, fluid pressure inside the piston is reduced. This allows the piston springs to relax, which eases pressure on the clutch pack and pressure plate.

HEMI

The HEMI engine as the name indicates has a hemispherical Combustion chamber which provides an excellent way of better induction of the air-fuel mixture from the inlet and to provide larger valves. HEMI engines are provided in the popularly known American Muscle cars which follows a tradition of Big , Loud and Powerful! The first HEMI engine ways back to 1951 which was produced Chrysler it was a v8 producing 180 bhp at 2500 rpm. In the initial stages it was marketed as Fire Power untill when it it was revived in the year 1964 when it was designated as HEMI. The present day HEMI how ever does not hav a hemispherical combestion chamber it is relatively flatter and used an advanced technology such as coil over plug distributorless ignition system, dual Spark plug per cylinder, Variable valve timing technology and Variable displacement technology. The distributorless ignition system was used to achieve a better spark tining capability replacing the conventional distributor and contact breaker arrangement. The dual spark plug was introduces to hav a consistent flame growth and ensure complete combustion. Variable valve time timing ensured that a proper combination of the inlet and outlet timing according to the various driving styles to provide maximum efficiency and reduce emissions. in the Earlier models all the 8 cylinders would remain active at all conditions leading to loss of efficiency and fuel economy, but in the modern HEMI it features Multiple Displacement System(MDS) or Variable Displacement Technology which activates the required number of cylinders out of the 8 according to power requirements this lead to and increase in efficiency by 4% and greatly reducing emissions. The present HEMI engines are available as 6.1L, 425hp and 6.4L. these engines are featured in select models.


Dodge Challenger SRT-8:



Crysler 300c SRT-8:



Jeep Grand Cherokee SRT-8:



6.4L HEMI in Grand Cherokee:



Dodge Charger SRT-8:



Dodge Magnum SRT-8:



HEMI engines are Adored for their growl which is one of its kind!!

Early Impact from Automobiles

At the age of 4, "The School Van" is the earliest of the automobile that i can hunt down in my memory. It was a boxy van called as Standard(An early Indian company which no longer exists) which seats 15 but the one i went to School carried about 40. It had a diesel engine which sounded as if a cow or a horse was tortured brutally and and gave out so much of smoke as if a forest had been burnt down to ashes. And in same era, the common Autorickshaws powered by a two stroke engine. Had fun traveling in it except while cornering which gave me a feeling that it would topple since it has only three wheels. And then a steep transition after about two years at the age of 6(In Oman)... Glittering cars... Air Conditioned interiors.. cruising speeds of about 100 to 120Km/hr... exhaust pipes with visually no smoke from it.. I wondered if i was a dream! But I realised it was Quality. Twelve years of exotic cars, buses and trucks. Then voila! I was back to Chennai, the Detroit of India! Amazed at the cars. The quality was instilled in them which lacked at the earlier stages. During the young years of my life, curiosity about the World of Automobile Engineering continuously urged me to focus my career in that field... how does the engine roar?? How does the wheel turn when the steering is rotated?? What is the long shaft spinning under the truck??.... and yes i did with a big smile and a high enthusiasm Venture to do Bachelor's in Automotive Engineering. To learn the evolution and wonders and the depth of the Ocean of this Wonderful Machine on Earth!