Limited-slip differential
A limited-slip differential (LSD) is a type of differential that allows its two output
shafts to rotate at different speeds but limits the maximum difference between the
two shafts.
In an automobile, such limited-slip differentials are sometimes used in place of a
standard
differential, where they convey certain dynamic advantages, at the expense
of greater complexity.
Early history
In 1932, Ferdinand Porschedesigned a Grand Prix racing car for the Auto Union company. The high power of the design caused one
of the rear wheels to experience excessive wheel spin at any speed up to 160 km/h (100 mph). In 1935, Porsche commissioned the
engineering firm ZF to design a limited-slip differential to improve performance. The ZF "sliding pins and cams" became
available,[1] and one example was the Type B-70 used during the Second World War in the military VWs (Kübelwagen and
Schwimmwagen), although technically this was not a limited-slip differential, but a system composed of two freewheels, which sent
the whole of the engine power to the slower-turning
of the two wheels.[2]
Benefits
The main advantage of a limited-slip differential is demonstrated by considering the case of a
standard (or "open") differential in offroading or snow situations where one wheel begins to slip. In such a case with a standard differential, the slipping or non-contacting
wheel will receive the majority of the power (in the form of low-torque, high rpm rotation), while the contacting wheel will remain
Contents Cone-type LSD
Early history
Benefits
stationary with respect to the ground. The torque transmitted by an open differential will always be equal at both wheels; if one tire is
on a slippery surface, the supplied torque will easily overcome the available traction at a very low number. For example, the right tire
might begin to spin as soon as 70 N⋅m (50 lb⋅ft) of torque is placed on it, since it is on an icy surface. Since the same amount of
torque is always felt at both wheels, regardless of the speed at which they are turning, this means that the wheel with traction cannot
receive more than 70 Nm of torque either, which is far less than is required to move the vehicle. Meanwhile, the tire on the slippery
surface will simply spin, absorbing all of the actual power output (which is a function of torque provided over time), even though
both wheels are provided the same (very low) amount of torque. In this situation, a limited-slip differential prevents excessive power
from being allocated to one wheel, and so keeps both wheels in powered rotation, ensuring that the traction will not be limited to the
wheel which can handle the minimum amount of power.
The advantages of LSD in high-power, rear wheel drive automobiles were demonstrated during the United States "Muscle-Car" era
from the mid 1960s through the early 1970s. Cars of this era normally were rear wheel drive and did not feature independent
suspension for the rear tires (but instead used a live axle). With a live axle, when high torque is applied through the differential, the
traction on the right rear tire is lower as the axle naturally wants to turn with the torsion of the drive shaft (but is held stationary by
being mounted to the vehicle frame). This coined the terms "one wheel peel" or "one tire fire". As such, "Muscle-Cars" with LSD or
"posi" (posi-traction) were at a distinct advantage to their wheel-spinning counterparts.
Basic principle of operation
Automotive limited-slip differentials all contain a few basic elements. First, all have a gear train that, like an open differential, allows
the output shafts to spin at diferent speeds while holding the sum of their speeds proportional to that of the input shaft.
Second, all have some type of mechanism that applies a torque (internal to the differential) that resists the relative motion of the
output shafts. In simple terms, this means they have some mechanism which resists a speed difference between the outputs, by
creating a resisting torque between either the two outputs, or the outputs and the differential housing. There are many mechanisms
used to create this resisting torque. Types of limited-slip differential typically are named from the type of the resisting mechanism.
Examples include viscous and clutch-based LSDs. The amount of limiting torque provided by these mechanisms varies by design.
A limited-slip differential has a more complex torque-split and should be considered in the case when the outputs are spinning the
same speed and when spinning at different speeds. The torque difference between the two axles is called Trq d .
[3] (In this work it is
called Trq f for torque friction[4]). Trq d is the difference in torque delivered to the left and right wheel. The magnitude of Trq d comes
from the slip-limiting mechanism in the differential and may be a function of input torque (as in the case of a gear differential), or the
difference in the output speeds (as in the case of a viscous differential).
The torque delivered to the outputs is:
Trq 1 = ½ Trq in + ½ Trq d for the slower output
Trq 2 = ½ Trq in – ½ Trq d for the faster output
When traveling in a straight line, where one wheel starts to slip (and spin faster than the wheel with traction), torque is reduced to the
slipping wheel (Trq 2 ) and provided to the slower wheel (Trq 1 ).
In the case when the vehicle is turning and neither wheel is slipping, the inside wheel will be turning slower than the outside wheel.
In this case the inside wheel will receive more torque than the outside wheel, which can result in understeer .
[4]
When both wheels are spinning at the same speed, the torque distribution to each wheel is:
Trq (1 or 2) = ½ Trq in ±(½ Trq d ) while
Trq 1 +Trq 2 =Trq in .
This means the maximum torque to either wheel is statically indeterminate but is in the range of ½ Trq in ±( ½ Trq d ).
Types
Several types of LSD are commonly used in passenger cars.
Fixed value
Torque sensitive
Speed sensitive
Electronically controlled
Fixed value
In this differential the maximum torque difference between the two outputs, Trq d , is a fixed value at all times regardless of torque
input to the differential or speed difference between the two outputs. Typically this differential used spring-loaded clutch assemblies.
Torque sensitivity (HLSD
This type includes helical gear limited-slip differentials and clutch, cone (an alternative type of clutch) where the engagement force
of the clutch is a function of the input torque applied to the differential (as the engine applies more torque the clutches grip harder and
Trq d decreases).
Torque sensing LSDs respond to driveshaft torque, so that the more driveshaft input
torque present, the harder the clutches, cones or gears are pressed together, and thus
the more closely the drive wheels are coupled to each other. Some include spring
loading to provide some small torque so that with little or no input torque (trailing
throttle/gearbox in neutral/main clutch depressed) the drive wheels are minimally
coupled. The amount of preload (hence static coupling) on the clutches or cones is
affected by the general condition (wear) and by how tightly they are loaded.
Clutch, cone-type, or plate LSD
The clutch type has a stack of thin clutch-discs, half of which are coupled to one of
the drive shafts, the other half of which are coupled to the spider gear carrier. The
clutch stacks may be present on both drive shafts, or on only one. If on only one, the
remaining drive shaft is linked to the clutched drive shaft through the spider gears.
In a cone type the clutches are replaced by a pair of cones which are pressed together
achieving the same effect.
One method for creating the clamping force is the use of a cam-ramp assembly such
as used in a Salisbury/ramp style LSD. The spider gears mount on the pinion cross
shaft which rests in angled cutouts forming cammed ramps. The cammed ramps are
not necessarily symmetrical. If the ramps are symmetrical, the LSD is 2 way. If they
are saw toothed (i.e. one side of the ramp is vertical), the LSD is 1 way. If both sides
are sloped, but are asymmetric, the LSD is 1.5 way. (See the discussion of 2, 1.5 and
1 way below)
An alternative is to use the natural separation force of the gear teeth to load the clutch. An example is the center differential of the
2011 Audi Quattro RS 5.[5]
As the input torque of the driveshaft tries to turn the differential center, internal pressure rings (adjoining the clutch stack) are forced
sideways by the pinion cross shaft trying to climb the ramp, which compresses the clutch stack. The more the clutch stack is
compressed, the more coupled the wheels are. The mating of the vertical ramp (80–85° in practice to avoid chipping) surfaces in a
one-way LSD on overrun produces no cam effect or corresponding clutch stack compression.
Fixed value
Torque sensitivity (HLSD)
ZF LSD – clutch stack visible on left
ZF LSD – spider pinion shaft ramps
visible
Clutch, cone-type, or plate LSD
2-Way, 1-Way, 1.5-Way
Broadly speaking, there are three input torque states: load, no load, and over run. During load conditions, as previously stated, the
coupling is proportional to the input torque. With no load, the coupling is reduced to the static coupling. The behavior on over run
(particularly sudden throttle release) determines whether the LSD is 1 way, 1.5 way, or 2 way.
A 2-way differential will have the same limiting torque Trq d in both the forward and reverse directions. This means the differential
will provide some level of limiting under engine braking.
A 1-way differential will provide its limiting action in only one direction. When torque is applied in the opposite direction it behaves
like an open differential. In the case of a FWD car it is argued to be safer than a 2-way differential.[6] The argument is if there is no
additional coupling on over run, i.e. a 1-way LSD as soon as the driver lifts the throttle, the LSD unlocks and behaves somewhat like
a conventional open differential. This is also the best for FWD cars, as it allows the car to turn in on throttle release, instead of
ploughing forward.[6]
A 1.5-way differential refers to one where the forward and reverse limiting torques, Trq d_fwd, d_rev , are different but neither is zero
as in the case of the 1-way LSD. This type of differential is common in racing cars where a strong limiting torque can aid stability
under engine braking.
Geared LSD
Geared, torque-sensitive mechanical limited-slip differentials use worm gears and
spur gears to distribute and differentiate input power between two drive wheels or
front and back axles. This is a completely separate design from the most common
beveled spider gear designs seen in most automotive applications. As torque is
applied to the gears, they are pushed against the walls of the differential housing,
creating friction. The friction resists the relative movement of the outputs and
creates the limiting torque Trq d .
Unlike other friction-based LSD designs that combine a common spider gear "open"
differential in combination with friction materials that inhibit differentiation, the
torque sensing design is a unique type of differential, with torque bias inherent in its
design, not as an add-on. Torque bias is only applied when needed, and does not
inhibit differentiation. The result is a true differential that does not bind up like LSD
and locking types, but still gives increased power delivery under many road
conditions.
Examples include
Torsen T-1 is the brand name of the original Gleasman differential invented by Vernon Gleasmancirca 1949 (US
Patent 2,559,916 applied in 1949, granted 1951).[7] The original Gleasman design was sold to The Gleason Works
(later named Gleason Corporation), who started marketing it in 1982. The original T-1 model is incompatible with cclip drive axles, which limited its use with many cars and pick-up trucks of the time. However, the original Torsen
differential was used in racing by Mario Andretti and Paul Newman with great success.[8] All later worm gear LSD
designs were derived from the original Gleasman differential. The T-1 is original equipment in the Audi Quattro,
Subaru Impreza WRX STI, Toyota Mega Cruiser and AM General HMMWV "Humvee".[9]
Torsen T-2 was a new Gleasman design circa 1984 (US Patent application WO1984003745 A1)[10] that is
compatible with c-clip axles. The new design, along with a merger creating Zexel-Gleason U.S.A. increased Torsen
availability for OEM and aftermarket applications. Variants include the T-2R, which includes a Positraction style
clutch pack that gives preload for racing purposes; and the T-3, a dual differential intended for AWD applications.
The T-2 is original equipment in many high performance cars and pick-up trucks.[9]
Quaife differential, sold under the name Automatic Torque Biasing Differential (ATB), covered by European Patent
No. 130806A2. The Quaife version is most established in Europe and other markets other than the US, providing
extensive aftermarket support for European and Japanese brand cars, especially front wheel drive and all-wheel
drive applications. The Ford Focus RS uses the Quaife as original equipment.[11]
Eaton Corporation is the latest owner of the Truetrac differential, which has been in production for many years. Its
design is similar to the Torsen T-2 (slightly less torque bias), and is an aftermarket part for many popular US-made
solid axles for rear wheel drive and 4x4 pick-up trucks. The Truetrac is most often used in the front axle of 4x4 pickGeared LSD
Audi Quattro Torsen Differential
up trucks intended for of-road use, in combination with locking center and rear differentials. As is the case with all
geared LSD designs, the Truetrac does not have any negative impact on steering that most other LSD and "locker"
designs are prone to.
Speed sensitivity
Speed-sensitive differentials limit the torque difference between the outputs, Trq d , based on the difference in speed between the two
output shafts. Thus for small output speed differences the differential’s behavior may be very close to an open differential. As the
speed difference increase the limiting torque increases. This results in different dynamic behavior as compared to a torque sensitive
differential.
Viscous (VLSD
The viscous type is generally simpler because it relies on hydrodynamic friction
from fluids with high viscosity. Silicone-based oils are often used. Here, a
cylindrical chamber of fluid filled with a stack of perforated discs rotates with the
normal motion of the output shafts. The inside surface of the chamber is coupled to
one of the driveshafts, and the outside coupled to the differential carrier. Half of the
discs are connected to the inner, the other half to the outer, alternating inner/outer in
the stack. Differential motion forces the interleaved discs to move through the fluid
against each other. In some viscous couplings when speed is maintained the fluid
will accumulate heat due to friction. This heat will cause the fluid to expand, and
expand the coupler causing the discs to be pulled together resulting in a non-viscous
plate to plate friction and a dramatic drop in speed difference. This is known as the
hump phenomenon and it allows the side of the coupler to gently lock. In contrast to the mechanical type, the limiting action is much
softer and more proportional to the slip, and so is easier to cope with for the average driver. New Process Gear used a viscous
coupling of the Ferguson style in several of their transfer cases including those used in the AMC Eagle.
Viscous LSDs are less efficient than mechanical types, that is, they "lose" some power. In particular, any sustained load which
overheats the silicone results in sudden permanent loss of the differential effect.[12] They do have the virtue of failing gracefully,
reverting to semi-open differential behavior. Typically a visco-differential that has covered 60,000 miles (97,000 km) or more will be
functioning largely as an open differential. The silicone oil is factory sealed in a separate chamber from the gear oil surrounding the
rest of the differential. This is not serviceable; when the differential's behavior deteriorates, the VLSD center must be replaced.
Gerotor pump
This style limited-slip differential works by using a gerotor pump to hydraulically compress a clutch to transfer torque to the wheel
that is rotating slower. The gerotor pump uses the differential carrier or cage to drive the outer rotor of the pump and one axle shaft to
drive the inner rotor. When there is a difference between the left and right wheels' speed, the pump pressurizes the hydraulic fluid
causing the clutch to compress. thereby causing the torque to be transferred to the wheel that is rotating slower. These pump-based
systems have lower and upper limits on applied pressure which allows the differential to work like a conventional or open differential
until there is a significant speed difference between the right and left wheel, and internal damping to avoid hysteresis. The newest
gerotor pump based system has computer regulated output for more versatility and no oscillation.
Electronic
An electronic limited-slip differential will typically have a planetary or bevel gear set similar to that of an open differential and a
clutch pack similar to that in a torque sensitive or gerotor pump based differential. In the electronic unit the clamping force on the
clutch is controlled externally by a computer or other controller. This allows the control of the differential’s limiting torque, Trq d , to
be controlled as part of a total chassis management system. An example of this type of differential is Subaru’s DCCD used in the
2011 Subaru WRX STi.[13] Another example is the Porsche PSD system used on the Porsche 928. A third example is the SAAB
Speed sensitivity
Viscous (VLSD)
Nissan 240SX Viscous LSD
Gerotor pump
Electronic
XWD (Haldex Generation 4) with eLSD, it uses a common (electronically controlled via the vehicle computer network) hydraulic
power pack to control both the longitudinal and transversal torque transfer of the XWD system. The same Haldex system is used on
several other GM Epsilon based vehicles such as the Cadillac SRX etc.
Electronic systems: brake-based
These systems are alternatives to a traditional limited-slip differential. The systems harness various chassis sensors such as speed
sensors, anti-lock braking system (ABS) sensors, accelerometers, and microcomputers to electronically monitor wheel slip and
vehicle motion. When the chassis control system determines a wheel is slipping, the computer applies the brakes to that wheel. A
significant difference between the limited-slip differential systems listed above and this brake-based system, is that brake-based
systems do not inherently send the greater torque to the slower wheel, plus the added brake friction material wear that results from
the use of such a system if the vehicle is driven in an environment where the brake-based system will activate on a regular basis.
BMW's electronic limited-slip differential used on the F10 5 Series is an example of such a system. Another example began on the
first year (1992) production of the re-styled, and new 4.6L V-8 overhead cam Ford Crown Victoria model with its optional anti-lock
brakes. This option was available on the 1992 Crown Victoria, onward; on those cars equipped with anti-lock brakes.
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