Constant-velocity joints (aka homokinetic or CV joints) allow a rotating shaft to transmit power through a variable angle, at constant rotational speed, without an appreciable increase in friction or play. They are mainly used in front wheel drive and all wheel drive cars. Rear wheel drive cars with independent rear suspensions typically use CV joints at the ends of the rear axle halfshafts, and increasingly use them on the propshafts.
Audi Quattros use them for all four half-axles and on the front-to-rear driveshaft (propeller shaft) as well, for a total of ten CV joints.
These joints are very strong, and are usually highly overspecified for a given application. Maintenance is usually limited to checking that the rubber gaiter (dust/weather boot) that covers them is secure and not split. If the gaiter is damaged, the molybdenum disulfide grease with which the joint is packed will be thrown out. The joint will then pick up dirt, water, and road deicing salt and cause the joint to overheat and wear. The grease can also contaminate the brakes. In worst case, the CV joint may disjoin causing the vehicle to stop moving or lock up, rendering the car incapable of steering. Damaged CV joint gaiters will usually cause a car to fail a vehicle inspection.
Before the CV joint
Early front wheel drive systems such as those used on the Citroën Traction Avant and the front axles of
Land Rover and similar four wheel drive vehicles used Hookes (universal) joints, where a cross-shaped metal pivot sits between two forked carriers. These are not CV joints as, except for specific configurations, they result in a variation of the transmitted speed. They are simple to make and can be tremendously strong, and are still used to provide a flexible coupling in some propshafts, where there is not very much movement. However, they become "notchy" and difficult to turn when operated at extreme angles, and need regular maintenance. They also need more complicated support bearings when used in drive axles, and could only be used in rigid axle designs.
Rzeppa joints
A Rzeppa joint consist of a spherical inner with 6 grooves in it, and a similar enveloping outer shell. Each groove guides one ball. The input shaft fits in the center of a large, steel, star-shaped "gear" that nests inside a circular cage. The cage is spherical but with ends open, and it typically has six openings around the perimeter. This cage and gear fit into a grooved cup that has a splined and threaded shaft attached to it. Six large steel balls sit inside the cup grooves and fit into the cage openings, nestled in the grooves of the star gear. The output shaft on the cup then runs through the wheel bearing and is secured by the axle nut. This joint is extremely flexible and can accommodate the large changes of angle when the front wheels are turned by the steering system; typical Rzeppa joints allow 45-48 degrees of articulation, while some can give 52 degrees.At the "outboard" end of the driveshaft a slightly different unit is used. The end of the driveshaft is splined and fits into the outer "joint". It is typically held in place by a circlip.
Tripod joints
These joints are used at the inboard end of car driveshafts. This joint has a three-pointed yoke attached to the shaft, which has barrel-shaped roller bearings on the ends. These fit into a cup with three matching grooves, attached to the differential. Since there is only significant movement in one axis, this simple arrangement works well. These also allow an axial 'plunge' movement of the shaft, so that engine rocking and other effects do not preload the bearings. A typical Tripod joint has up to 50 mm of plunge travel, and 26 degrees of angular articulation.
Double cardan
Double Cardan joints are similar to double Cardan shafts, except that the length of the intermediate shaft is shortened as much as is practical, effectively allowing the two Hooke's joints to be mounted back to back. This provides true constant velocity operation at low speeds, but the torque required to accelerate the internals of the joint does provide some additional vibration at higher speeds. DCJs are typically used in steering columns, as they eliminate the need to correctly phase the universal joints at the ends of the intermediate shaft (IS), which eases packaging of the IS around the other components in the engine bay of the car. They are also used to replace Rzeppa style constant-velocity joints in applications where high articulation angles, or impulsive torque loads are common, such as the driveshafts and halfshafts of rugged four wheel drive vehicles. Double Cardan joints have been developed utilizing a floating centering element to maintain equal angles between the driven and driving shafts.
Thompson coupling
The Thompson constant velocity joint (TCVJ), also known as a Thompson coupling, is a constant velocity universal joint that can be loaded axially and continue to maintain constant velocity over a range of input and output shaft angles with low friction and vibration. It consists of two cardan joints assembled within each other, thus eliminating the intermediate shaft, along with a control yoke that geometrically constrains their alignment. The control yoke maintains equal joint angles and a relative phase angle of zero to insure constant angular velocity at all input and output shaft angles. The geometric configuration also maintains constant velocity of the control yoke, or intermediate coupling, that aligns the pair of cardan joints and thus eliminates the induced shear stresses and vibration inherent in traditional double cardan shafts.
The use of cardan joints within the Thompson Coupling reduces the wear, heat and friction when compared with Rzeppa type constant velocity joints. Cardan joints, including Thompson couplings, utilise roller bearings running circumferentially, whereas Rzeppa constant velocity joints use balls which roll and slide axially along grooves.
The novel feature of the coupling is the method to geometrically constrain the pair of cardan joints within the assembly by using, for example, a spherical four bar scissors linkage and it is the first coupling to have this combination of properties.
The coupling earned its inventor, Glenn Thompson, the Australian Society for Engineering in Agriculture Engineering Award.