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Beam axle

Diagonal Panhard rod bolted to a black rectangular profile beam axle on a front-wheel-drive 2002 Mazda MPV. This is an example of a "dead axle". A "live axle" not only connects two wheels, but also drives them.

A beam axle, rigid axle, or solid axle is a dependent suspension design in which a set of wheels is connected laterally by a single beam or shaft. Beam axles were once commonly used at the rear wheels of a vehicle, but historically, they have also been used as front axles in four-wheel-drive vehicles. In most automobiles, beam axles have been replaced with front (IFS) and rear independent suspensions (IRS).

Implementation

Solid axle suspension characteristics: Camber change on bumps, none on rebound, large unsprung weight

With a beam axle, the camber angle between the wheels is the same regardless of its location in the travel of the suspension.

A beam axle's location in the fore and aft directions is constrained by one of several suspension components, including trailing arms, semi-trailing arms, radius rods, and leaf springs. The lateral location can be constrained by a Panhard rod, a Scott Russell linkage, a Watt's linkage, or some other arrangement, most commonly by the leaf springs. Shock absorbers and either leaf springs, coil springs, or air bags are used to control vertical movement.

Live axle vs dead axle

A live axle in a Jeep. This is the front suspension, using coil springs.

A live axle is a type of beam axle in which the shaft (or, commonly, shafts connected to move as a single unit) also transmits power to the wheels; a beam axle that does not also transmit power is sometimes called a dead axle. While typically used in vehicles with Hotchkiss drive, this suspension system can also be used with other types of power transmission.

Advantages

  • A beam axle is typically simple in design, rugged, and inexpensive to manufacture.
    • Only one universal joint or constant-velocity joint (CV) is needed at each steered and driven wheel and none are needed at non-steered wheels; this reduces maintenance requirements and manufacturing costs compared to independent suspensions, which typically require two such joints at each driven wheel.
    • The CVs are located in metal enclosures attached to the axle housings; there are no rubber CV boots that may be cut or punctured when off-roading.
  • A beam axle is space-efficient, an important advantage for off-road applications, as it provides better vehicle articulation and durability in a high-load environment.
  • Camber angle is rigidly fixed by axle geometry; for a live axle, toe is typically fixed as well.
    • As the vehicle's body rolls during hard cornering, the unchanging camber yields predictable handling—at least on smooth surfaces.
    • Wheel alignment is simplified.
    • Traction, braking and tire wear characteristics do not change as the suspension is compressed. These are great benefits in a vehicle that carries heavy loads, and together with the beam axle's characteristic strength, this has resulted in front and rear beam axles being nearly universal in buses and heavy-duty trucks. Most light- and medium-duty pickup trucks, SUVs, and vans also use a beam axle, at least in the rear.
  • A beam axle is easier and less expensive to modify than other axles. This is because it has fewer parts, less mechanical complexity, and more empty space between suspension components, axles, and the vehicle's frame or body. This makes it easier to work with when making modifications such as adding lift kits to increase body or running clearance, or installing larger diameter tires to increase ground/axle clearance.[1]

Disadvantages

  • A beam axle does not allow each wheel to move independently in response to uneven surfaces, and handling is typically worse than more sophisticated suspension designs.
    • In turns, the outside wheel is often subjected to adverse camber angles when the inside wheel hits a bump, which can suddenly reduce cornering grip and destabilize the vehicle.
    • If one wheel on a beam axle slips off a steep incline or is knocked to one side by a rock at high speed, the other wheel will also follow because of the physical connection of the two wheels on an axle. If this happens on the front axle, the entire vehicle may suddenly jump toward that side. If the steering damper is inadequate, the driver may suffer dislocated fingers or a dislocated shoulder due to the sudden feedback from the steering wheel.[2]
    • Camber angle cannot change during body roll. Furthermore, the roll center moves in reaction to road irregularities.
    • Toe is typically fixed at zero for a live axle, and dynamic toe control is difficult to implement.
  • The mass of the beam is part of the unsprung weight of the vehicle, hurting ride quality.
    • The need for lateral location devices such as a Panhard rod or Watt's linkage adds more unsprung weight and partially offsets the beam axle's advantages in terms of simplicity, space efficiency, and cost.
  • In a vehicle with conventional Hotchkiss drive, the entire axle may twist in its mounts in reaction to torque loads; during hard acceleration, this may reduce traction and induce wheel hop or sudden adverse toe changes.
  • The bulky differential housing of a Hotchkiss live axle reduces ground clearance, hindering the vehicle's ability to ford deep mud, clear obstacles and negotiate deeply rutted roads.
    • The differential housing can only be raised by using larger wheels and tires, typically with a penalty in unsprung weight, braking effectiveness and acquisition costs; furthermore, vehicle modifications may be necessary for adequate fender or frame clearance.
  • Front beam axle suspension is unusually sensitive to any lack of concentricity in the hub and wheel assembly which can cause a side-to-side oscillation ("shimmy") of the steering at certain speeds (typically 60–80 km/h; 40–50 mph), commonly referred to as "death wobble" within the 4×4 community.[3] This is addressed on some vehicles with steering dampers, although removal and careful refitting of the front wheels often resolves the problem.

Axle truss

An axle truss is typically a six-millimeter thick steel plate bent into a "Π"-shaped beam and welded with the open side facing the top of the differential or axle housing. It reinforces a solid axle so that it does not bend or break when the axle's load rating is exceeded.[4] A larger/thicker axle is stronger, but also comes with increased cost, unsprung weight, and more compatibility issues (drivetrain, suspension, steering geometries, body mount locations, clearances) on smaller vehicles.[5]

eAxle

eAxle or E-axle is a solid axle with electric motors attached to the differential, either end, or elsewhere. Inverters, power electronics, gearboxes, transfer cases (including low-range gearing), and transmissions may also be attached to the motors and/or axle. All components move with the axle as unsprung weight.[6][7][8][9]

Examples

Modern production vehicles with solid front axle

Unibody modern production vehicles with solid axle

See also

Notes

  1. ^ THE COST OF CHOOSING BIGGER 4x4 TYRES. Retrieved 2024-04-12 – via www.youtube.com.
  2. ^ "10 Off Road tips for inside the cab". 4 Wheeling Australia. Retrieved 2024-04-12.
  3. ^ Lingeman, Jake. "Autoweek explains: What is the 'death wobble'?". Autoweek. Retrieved 2 October 2021.
  4. ^ "Axle Truss Truths".
  5. ^ "What Are the Differences Between Sprung and Unsprung Weight?". Machine Design. 2016-05-17. Retrieved 2024-08-02.
  6. ^ "Everything you need to know about electric axles | Accelera". www.accelerazero.com. 2023-09-27. Retrieved 2024-08-02.
  7. ^ "The eAxle, a core component of electric vehicles".
  8. ^ "eAxle: Electric Drive for Cars". Bosch Global. Retrieved 2024-08-02.
  9. ^ "3-in-1 E-Axle for Electric Vehicles".
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