Driveshaft

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A driveshaft, driving shaft, or Cardan shaft is a mechanical device for transferring power from the engine or motor to the point where useful work is applied.

Most engines or motors deliver power as torque through rotary motion: this is extracted from the linear motion of pistons in a reciprocating engine; water driving a water wheel; or forced gas or water in a turbine. From the point of delivery, the components of power transmission form the drive train.

Driveshafts are carriers of torque: they are subject to torsion and shear stress, which represents the difference between the input force and the load. They thus need to be strong enough to bear the stress, without imposing too great an additional inertia by virtue of the weight of the shaft.

Contents 1 Automotive driveshafts 1.1 Vehicles 1.2 Driveshaft for Research and Development (R&D) 2 Motorcycle driveshafts 3 Marine driveshafts 4 Driveshafts in Bicycles 4.1 Advantages 4.2 Disadvantages

[edit] Automotive driveshafts

[edit] Vehicles

Most automobiles today use rigid driveshafts to deliver power from a transmission to the wheels. A pair of short driveshafts is commonly used to send power from a central differential, transmission, or transaxle to the wheels.

In front-engined, rear-drive vehicles, a longer driveshaft is also required to send power the length of the vehicle. Two forms dominate: The torque tube with a single universal joint and the Hotchkiss drive with two or more joints. This system became known as Système Panhard after the automobile company, Panhard et Levassor patented it.

Early automobiles often used chain drive or belt drive mechanisms rather than a driveshaft. Some even used electrical generators and motors to transmit power to the wheels.

In British English, the term "driveshaft" is restricted to a transverse shaft which transmits power to the wheels, especially the front wheels. A driveshaft connecting the gearbox to a rear differential is called a propeller shaft (or more commonly a "prop-shaft") and a driveshaft connecting a rear differential to a rear wheel is usually called a halfshaft. The name derives from the fact that two such shafts are required to form one rear axle.

There are different types of driveshafts in Automotive Industry:

• 1 piece driveshaft
• 2 piece driveshaft
• Slip in Tube driveshaft

The Slip in Tube Driveshaft is the new type which also helps in Crash Energy Management. It can be compressed in case of crash. It is also known as a collapsible driveshaft.

[edit] Driveshaft for Research and Development (R&D)

The automotive industry also uses driveshafts at testing plants. At an engine test stand a drive shaft is used to transfer a certain speed / torque from the combustion engine to a dynamometer. A "shaft guard" is used at a shaft connection to protect against contact with the drive shaft and for detection of a shaft failure. At a transmission test stand a drive shaft connects the prime mover with the transmission.

[edit] Motorcycle driveshafts

Driveshafts have been used on motorcycles almost as soon as there were motorcycles. As an alternative to chain and belt drives, driveshafts offer relatively maintance-free operation and long life. A disadvantage of shaft drive on a motorcycle is that gearing is needed to turn the power 90° from the shaft to the rear wheel, losing some power in the process.

The best known motorcycle manufacturer to use shaft drive for a long time — since 1923 — is BMW. Among contemporary manufacturers, Moto Guzzi is also well know for its shaft drive motorcycles. The British company, Triumph and all four Japanese brands, Honda, Suzuki, Kawasaki and Yamaha, have produced shaft drive motorcycles.

Motorcycle engines positioned such that the crankshaft is longitudinal and parallel to the frame are often used for shaft driven motorcycles. The requires only one 90° turn in power transmission, rather than two. Moto Guzzi, BMW, Triumph, and Honda use this apporoach to engine layout.

[edit] Marine driveshafts

On a power-driven ship, the driveshaft, or propeller shaft, usually connects the transmission inside the vessel directly to the propeller, passing through a stuffing box or other seal at the point it exits the hull.

As the rotating propeller pushes the vessel forward, the marine driveshaft is also subject to compression, and when going reverse, to tension.

[edit] Driveshafts in Bicycles

The driveshaft has served as an alternative to a chain-drive in bicycles for the past century, although never becoming very popular. A shaft-driven bicycle is described as "acatane". When used on a bicycle, a driveshaft has several advantages and disadvantages:

[edit] Advantages

• Drive system is less likely to become jammed or broken, a common problem with chain-driven bicycles
• The use of a gear system creates a smoother and more consistent pedalling motion
• The rider cannot become dirtied from chain grease or injured by the chain from "Chain bite", which occurs when clothing or even a body part catches between the chain and a sprocket
• Lower maintenance than a chain system when the driveshaft is enclosed in a tube, the common convention
• More consistent performance. Dynamic Bicycles claims that a driveshaft bicycle consistently delivers 94% efficiency, whereas a chain-driven bike can deliver anywhere from 75-97% efficiency based on condition.
• Greater clearance: with the absence of a derailleur or other low-hanging machinery, the bicycle has nearly twice the ground clearance

[edit] Disadvantages

• A driveshaft system weighs more than a chain system, usually 1-2 pounds heavier
• At optimum upkeep, a chain delivers greater efficiency
• Many of the advantages claimed by driveshaft's proponents can be achieved on a chain-driven bicycle, such as covering the chain and gears with a metal or plastic cover
• Use of lightweight derailleur gears with a high number of ratios is impossible, although hub gears can be used
• Wheel removal can be complicated in some designs (as it is for some chain-driven bicycles with hub gears).
• Loss of power