Advantage The swing axle suspension has two advantages over the typical
live axle: • It reduced
unsprung weight since the differential is mounted to the
chassis • It eliminates sympathetic
camber changes on opposite wheels
Shortcomings • A great amount of single-wheel camber change is experienced relative to beam axle designs, since the radius of the jointed half-shaft is less than half that of the whole axle assembly. • "Jacking" on suspension unloading (or rebound) causes positive camber changes on both sides, which (In extreme cases) can overturn the car. • Change in camber due to
cornering forces can cause loss of rear-wheel adhesion leading to oversteer—a
dynamically unstable condition that can cause a vehicle to spin. This is an especially severe problem when a swing axle is used in a rear-engine design, because of the greater side-g forces on the rear wheels from the mass of the engine. Camber changes during deceleration can increase the severity of
lift-off oversteer.
Solutions Several engineering options can limit swing axle handling problems, with varying success: •
Anti-roll bar: As a design option, a front anti-roll bar which can ameliorate the swing axle car's handling—shifting
weight transfer to the front outboard tyre, considerably reducing rear
slip angles—thereby avoiding potential oversteer. • Single-pivot point: Mercedes-Benz addressed the handling issues by producing swing axles with a single-pivot point located under the differential, thus well below the axle. This configuration markedly reduced the tendency to "jack-up" and the later low pivot swing-axle equipped cars were praised in contemporary publications for their handling. The low-pivot swing-axle remained in production with
Mercedes-Benz W108/W109 280SE and 300SEL until 1972. It was fitted to the 300SEL 6.3, which was during the early 1970s the world's fastest production sedan. AMG-modified 6.3s were also raced with the stock swing axle. • Tyre pressure differential: The
Renault Dauphine,
Volkswagen Beetle and first generation
Chevrolet Corvair (1960–1964) used a
tyre pressure differential strategy to eliminate
oversteer characteristics of their swing axle suspensions—specifically low front and high rear tyre pressure—which induced
understeer. The
tyre pressure differential strategy offered a
significant disadvantage: owners and mechanics could inadvertently but easily re-introduce oversteer characteristics by over-inflating the front tyres (that is, to typical pressures for other cars with other suspension systems) or by inflating all four tyres to the same pressure. The effectiveness of this option was criticized in lawsuits in the US during the 1960s. •
Z-bar and
roll-inducing springs: Mercedes-Benz introduced, to help their low-pivot swing-axle, a coil spring mounted transversely above the differential, which would transfer load from one side to the other, so as to force down one wheel when the other side went up. This coil spring increases the load bearing capacity of the rear suspension, so a new lower pressure set of springs was substituted for the usual ones to maintain ride suppleness. A similar effect was achieved by VW's Z-bar, as opposed to anti-roll bar. Both devices distribute the response of the rear axles to input on one wheel, thus reducing the tendency for excessive camber to occur on one wheel. These solutions represent a compromise between swing axle and beam axle characteristics, at the cost of decreasing ride quality. •
Camber compensator: A transverse leaf spring is connected to the outer ends of the half-shafts and below the suspension assembly, resisting positive camber that could result from cornering forces or rebound. This was a successful solution introduced on the 1964 Corvair, and also factory-installed on Porsche 356 Super 90s and some later models. Aftermarket camber compensators are available for Porsche, VW and early Corvairs. ==Safety==