Extreme and defensive driving. Dmitry Aleksandrovich LiskinЧитать онлайн книгу.
40 degrees), the front wheels slide. If you turn the front wheels at a smaller fixed angle (10—15 degrees), drift angle (steerability) will be higher, since load on the front tyres will be less.
With help of the controls, you can increase or decrease steerability. For example, if you press hard on the throttle pedal on rear wheel drive car while cornering, the rear axle can easily slides. That is pressing the throttle pedal on rear wheel drive car leads to acceleration not only, but also increases steerability. On front wheel drive car, on the contrary, pressing the throttle pedal causes car to straighten trajectory – this is effect of reducing of steerability. Oversteer (high steerability) may be created by using the handbrake: it is often possible to see drivers in rally races enter the hairpins with sliding of the rear axle, locking the rear wheels.
Steerability created with help of the controls will be “added” to the vehicle’s steerability. Let us say if car has very low steerability, it will be more difficult to send it into drift due to traction on the rear axle than car with high steerability.
Exercise. Try to determine steerability of your car. For this purpose you may place cones on ground that simulate a corner and do the test. Do not forget about safety: car can show very low steerability, or it can start slide and turn around, so there should be enough space on the ground.
Be careful! Incorrect “tuning” of car (it may be suspension parameters, track, ground clearance) can make your car unsafe. Manufacturers design passenger cars in such way that they are stable and do not roll over during sudden maneuvering. If there is a risk of overturning in a corner, turn the steering wheel against the direction of the corner to return vehicle to the four wheels.
It is worth noting that electronic drive control systems, electronic control of torque distribution on the wheels, dynamic electronic motion stabilization systems can distort perceived steerability of car.
Drift: causes of origin and methods of fighting
When the front axle slides, we lose control. Unlike understeer, drift – is a controlled sliding of car. There may be one or both axles in the slide. Tendency to drift and behavior of machine when drift are influenced by such parameters as the type of drive, steerability, the type of differential. During drift, the rear axle tends to bypass the front. For clearness, if longitudinal direction of the body deviates to the right from direction of movement, we will say that car drifts to the right (drift direction is to the right), and angle between direction of movement and longitudinal direction of the body will be called drift angle.
This rear-wheel-drive car is specially prepared for drifting. It is equipped with limited slip differential, high torque motor, negative camber of the wheels and an increased full lock angle of the front wheels. On a front-wheel-drive car it is may be easily get out of any angle of drift, if engine torque is sufficient to maintain skid of the front wheels. For example, on this car, we entered and exited drift several times one after another.
The sliding behavior of an all-wheel-drive car depends on distribution of the torque among the axles. If main part of the torque is applied to the front axle, behavior of car will be close to behavior of a front-wheel-drive car. This all-wheel-drive car feels like a front-wheel-drive car: when pressing the throttle pedal the car tends come out of drift.
But unlike front-wheel-drive, on all-wheel-drive car it is possible to maintain stable drift due to part of engine torque transmitted to the rear axle. In addition it is easier to maintain a slide on all-wheel-drive car than on rear-wheel-drive car (with an appropriate ratio of the torques transmitted by the engine to the front and rear axles), since traction on the front axle will not allow car to turn around.
It is worth noting, that when drive in reverse when turn the steering wheel the front axle can drifts. We accelerated in reverse and quickly turned the steering wheel, whereupon the car turned almost 180 degrees.
Inability to drive car in a drift often leads to accidents. Rear-wheel-drive car with usual differential (zero or low friction) is quite difficult to drive in a drift. Take for testing a rear-wheel-drive car with zero-friction differential (factory) on the rear axle. Let us look at what may be causes of occurrence and ways to provoke rear axle drift.
1. Braking by handbrake. It is the simplest and most understandable cause.
2. Aggressive throttling on a rear-wheel-drive car. Please note – with a standard differential the first starts to skid wheel from the inside of corner (the unloaded wheel).
3. Speeding of engine and depressing the clutch on a rear-wheel-drive car. If you push the clutch, gain engine speed and, without releasing the throttle, release the clutch, the rear wheels will skid.
We revved up the engine and casted off the clutch pedal. The both rear wheels began to skip, the rear axle began to drift.
4. Engine braking on a rear-wheel-drive car. When the throttle pedal is released, firstly, the front axle is loaded and the rear – is unloaded.
Because of this grip of the front tyres with the road increases, the rear – decreases. Secondly, there is a braking effort on the rear wheels caused by engine braking. These facts lead to increase of steerability and can cause drift when maneuvering on a rear-wheel-drive car, especially on a high steerability car. Soft braking with engine braking together can have the same effect. In addition, roughs on the road unload the rear axle awhile, which combined with engine braking increases risk of sliding on a rear-wheel-drive.
5. Downshift without throttle blip on a rear-wheel-drive car with a manual gearbox. After lowering the gear and releasing the clutch pedal the engine is forced to gain speed in a short time distance, which can be indicated by a jump of the tachometer needle. On rear-wheel-drive, this is equal to action of the handbrake.
6. Braking with a strong shift of brake balance to the rear axle. When balance of the braking system is shifted to the rear axle, steerability may increases during braking. It may happen that the rear wheels will be first to brake.
7. Rocking the center of mass. Rocking can cause drift when passing an S-like corner.
When direction of movement changes, the energy stored in the compressed suspension, is freed and pushes car in opposite direction, which can lead to drift.
8. Together pressing the throttle and brake pedals on a front-wheel-drive car. Moving along the ring on a front-wheel-drive car, let us press the throttle and brake pedals at one time.
There was drift of the rear axle, the car rushed inside the ring. That is, the pressed throttle and brake pedals on a front-wheel-drive car create oversteer. Since we pressed on the throttle when braking, there was traction from the engine on the front axle. The rear axle brakes more intensively than the front, not exclude the rear wheels may be locked. Braking by the rear wheels creates oversteer, which is similar to braking by the handbrake. To describe operation of the front axle we take into account the several factors:
• due to the roll in the corner the left wheels were loaded with mass of the car, and the right