Ride quality refers to a vehicle's effectiveness in insulating the occupants from undulations in the road surface such as bumps or corrugations. A vehicle with good ride quality provides comfort for the driver and the passengers.
Good ride quality provides comfort for the people inside the car, minimises damage to cargo and can reduce driver fatigue on long journeys in uncomfortable vehicles, and also because road disruption can impact the driver's ability to control the vehicle.
Suspension design is often a compromise between ride quality and car handling because cars with firm suspension can result in greater control of body movements and quicker reactions. Similarly, a lower center of gravity is more ideal for handling, but low ground clearance limits suspension travel and requires stiffer springs.
Ambulances have a special need for a high level of ride quality to avoid further injury to the already-ill passengers.
Early vehicles, like the Ford Model T, with its leaf spring, live axle suspension design, were both uncomfortable and handled poorly.
Historically, weight was key to allowing cars such as the Rolls-Royce Silver Cloud and the Cadillac in the 1950s and the 1960s to have a more comfortable ride quality. However, there are various drawbacks to heavier cars, including poor fuel efficiency, acceleration, braking, cornering and additional stresses on components.
Over time, technology has shifted the curve outward and so it is possible to offer vehicles that are extremely comfortable and still handle very well or vehicles with excellent handling that are also reasonably comfortable. One technical solution for offering both excellent comfort and reduced or eliminating body roll is by using computer-controlled suspensions, such as hydraulic active suspension system (like Active Body Control) or active anti-roll bars, but such systems are expensive because of their complexity.
The main factor affecting ride quality is the stiffness of suspension components (e.g. springs, shock absorbers, anti-roll bars and bushings).
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thumb|Ressort à lames utilisé pour la suspension automobile. vignette|Ressort à lames d'un wagon-torpille dans le parc paysager de Duisbourg Nord, Allemagne. Un ressort à lame est un type de ressort utilisant la flexibilité d'une ou plusieurs lames métalliques superposées. Leurs propriétés élastiques permettent d'absorber l'énergie mécanique, produire un mouvement, exerçant un effort ou un couple sur le système lié.
thumb|upright=1.2|Représentation schématique des masses suspendues et non suspendues. La masse non suspendue, parfois dénommée poids non suspendu, désigne dans le domaine des transports terrestres (routier et ferroviaire) la masse des éléments du véhicule suivant exactement les ondulations de la voie. Par opposition, la masse des autres éléments du véhicule liée aux roues par l'intermédiaire de la suspension est dite « masse suspendue ».
Automobile handling and vehicle handling are descriptions of the way a wheeled vehicle responds and reacts to the inputs of a driver, as well as how it moves along a track or road. It is commonly judged by how a vehicle performs particularly during cornering, acceleration, and braking as well as on the vehicle's directional stability when moving in steady state condition. In the automotive industry, handling and braking are the major components of a vehicle's "active" safety, as well as its ability to perform in auto racing.
Since sustainability and environmental issues rose lately, lightweighting has been the point of interest for automotive and aerospace sectors. Lightweighting reduces the fuel consumption of the vehicles and as a result of this reduces emissions. Aluminum, ...