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  • Nowadays an anti-lock braking system is used in almost all modern vehicles.

  • This system prevents accidents like this,

  • where you lose control of the steering as you apply the brakes.

  • With ABS, you will be able to steer the vehicle properly

  • and it also reduces the braking distance.

  • What is ABS?

  • How is it able to prevent accidents due to the braking?

  • We will explore these questions in this video.

  • To properly understand ABS,

  • we first need to understand the principles of steering and braking.

  • When you press the brake pedal,

  • the brake pads on the wheel disks will be activated and press against the disks,

  • and this will stop the rotation of the wheels.

  • As the wheels stop,

  • this causes slippage between the road and wheels,

  • and the vehicle stops due to this friction.

  • Now let's understand the steering mechanism.

  • The whole steering mechanism is dependent on

  • the simple principle of the wheels rolling.

  • The wheels will always try to avoid slipping on the road.

  • So this means that the velocity of the wheel at the contact point

  • will always be zero.

  • The wheels have two kinds of motion.

  • They rotate on their axis and also they move along the direction of the car.

  • Due to these two kinds of motion, they have two kinds of velocity:

  • translational and rotational.

  • For non-slip rolling conditions,

  • the sum of the translational and rotational velocities

  • at the contact point should be zero.

  • Just keep this simple principle in mind,

  • and you will very easily be able to understand the steering mechanism.

  • In an automobile,

  • all four wheels should be rolling at all times to avoid the vehicle slipping.

  • In fact, this simple rolling principle is the reason why

  • your car turns when you turn the front wheels.

  • Let's examine this.

  • Assume a hypothetical condition in which,

  • even after turning the wheels, the car carries straight on.

  • In this case, the rolling velocity will be inclined as shown,

  • and the translation velocity remains straight.

  • Therefore, if you add up these two velocities,

  • the resultant velocity will not be zero.

  • This will cause the car to slip.

  • The only way to avoid this is by making the translation velocity also inclined.

  • This is possible only when the whole car makes a turn as shown.

  • When the car makes a turn at the instantaneous center shown,

  • all four wheels can satisfy the condition of rolling.

  • From this snapshot, you can clearly see how the velocity

  • at the contact point of all four wheels becomes zero.

  • Now, let's analyze the steering mechanism at the time of braking.

  • Due to the brake pads being activated, the wheels stop spinning.

  • Even though the wheels are turned, since they are not rotating,

  • there will be no rotational velocity at all.

  • In this case, the vehicle does not need to turn

  • as this has become like a normal case of braking.

  • The vehicle will no longer react to the driver's changes to the steering

  • and will slide in a straight line which can cause an accident.

  • Apart from losing control of the steering,

  • cars without ABS face another big issue,

  • braking on surfaces with different levels of traction.

  • When the left and right wheels are on different traction surfaces,

  • applying the brakes will generate different frictional forces on the wheels.

  • This will produce torque, and the car will go into an uncontrollable spin.

  • Let's see how ABS solves these issues.

  • An anti-lock braking system is very simple.

  • What ABS does is to prevent the wheels from completely locking up.

  • The ABS system includes speed sensors attached to all of the wheels.

  • When the sensors detect that a wheel is about to lock up,

  • a modulator unit partially releases the brake pad on that wheel.

  • This way, the wheels will be allowed to spin intermittently during braking.

  • You can immediately see the effect of

  • this intermittent wheel rotation on steering.

  • Here, the wheels will have a rotational velocity component.

  • This will definitely allow the steering to function,

  • and driver will be able to steer the vehicle even during the braking.

  • But the big question here is:

  • How does the action of intermittently releasing the brakes

  • reduce the braking distance?

  • To get an answer to this question,

  • we first need to understand how the coefficient of friction

  • between the tire and the road varies with respect to slip.

  • In perfect rolling conditions,

  • the value of the frictional coefficient is nearly zero.

  • However, when the wheel is 100% slipping, sliding friction comes into play.

  • You can expect the frictional values for other levels of slippage to vary like this.

  • But since rubber is a complex material

  • which has strange behaviors during braking,

  • the frictional coefficient between the tire and the road varies as shown

  • with respect to slippage.

  • It has a peak value at around 12% of slip ratio.

  • And below and above this, the frictional coefficient reduces.

  • During breaking without ABS,

  • the frictional coefficient which comes into effect

  • is predominantly sliding friction.

  • However in ABS braking,

  • the clever algorithm adjusts the break pressure

  • to keep the slip ratio near to 12%,

  • where the frictional value is at the maximum.

  • This significantly reduces the braking distance.

  • Now back to the huge instability issue of the cars.

  • By intelligent electronic braking distribution,

  • which is a subsystem of modern ABS,

  • one can overcome this issue very easily.

  • An EBD yaw rate of the car

  • and the relative slip of each wheel is measured.

  • Just by reducing the brake pressure on the wheels with higher grip,

  • we will be able to reduce the frictional force produced by these wheels.

  • This will keep the yaw torque and the whole car under control.

  • We hope this video gave you a clear conceptual overview of the workings of ABS.

  • And please, don't forget to support our educational activities on patreon.

  • Thank you!

Nowadays an anti-lock braking system is used in almost all modern vehicles.

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