Vehicle Skid Control

VEHICLE SKIDDING

VEHICLE SKIDDING

SUBMITTED

SUBMITTED

BY:-UDAY VIR SINGH

UDAY VIR SINGH

RANA(80904114110)

RANA(80904114110)

SUPREET SINGH

SUPREET SINGH

RANA(80904114106)

RANA(80904114106)

SURYADEEP SINGH

SURYADEEP SINGH

VIRK(80904114107)

VIRK(80904114107)

AKSHAY

VEHICLE SKID

VEHICLE SKID

CONTROL

CONTROL

Vehicle skid can be defined as the loss of  Vehicle skid can be defined as the loss of  traction between a vehicle’s tyres and the traction between a vehicle’s tyres and the road surface due to the forces acting on the road surface due to the forces acting on the v

veehhiciclele. . MoMosst t sskkiidds s arare e ccauausseed d bby y ddrriiveverr error, although only about 15% of accidents error, although only about 15% of accidents are the direct result of a vehicle skidding. are the direct result of a vehicle skidding. S

Skkiidds s ooccccuurrrriinng g iin n ootthheer r aacccciiddeenntts s aarree usually the result of last minute action, by usually the result of last minute action, by the driver, when faced with a crisis ahead the driver, when faced with a crisis ahead ra

rathther er ththan an acactutualally ly cacaususining g an an acaccicidedentnt.. Skids can occur both in the dry and wet as Skids can occur both in the dry and wet as well as icy conditions, however, the chances well as icy conditions, however, the chances

VEHICLE SKID

VEHICLE SKID

CONTROL

CONTROL

Vehicle skid can be defined as the loss of  Vehicle skid can be defined as the loss of  traction between a vehicle’s tyres and the traction between a vehicle’s tyres and the road surface due to the forces acting on the road surface due to the forces acting on the v

veehhiciclele. . MoMosst t sskkiidds s arare e ccauausseed d bby y ddrriiveverr error, although only about 15% of accidents error, although only about 15% of accidents are the direct result of a vehicle skidding. are the direct result of a vehicle skidding. S

Skkiidds s ooccccuurrrriinng g iin n ootthheer r aacccciiddeenntts s aarree usually the result of last minute action, by usually the result of last minute action, by the driver, when faced with a crisis ahead the driver, when faced with a crisis ahead ra

rathther er ththan an acactutualally ly cacaususining g an an acaccicidedentnt.. Skids can occur both in the dry and wet as Skids can occur both in the dry and wet as well as icy conditions, however, the chances well as icy conditions, however, the chances o

iinnccrreeaassees s bby y 5500% % iin n tthhe e wweett. . TThhe e mmoosstt common type of skid we will be confronted common type of skid we will be confronted with is when the rear end of the car slides with is when the rear end of the car slides out, causing an oversteer or when the front out, causing an oversteer or when the front of the car plows toward the outside of a turn of the car plows toward the outside of a turn w

wiitthhoouut t ffoolllloowwiinng g tthhe e ccuurrvve e oof f tthhe e ttuurrnn cau

causising ng an an unundedersrsteteerer. . UsUsualuallyly, , oveoversrsteteerer occurs as a result of going into a corner too occurs as a result of going into a corner too ffaasst t oor r iinnccoorrrreeccttlly y hhiittttiinng g a a sslliicck k aarreeaa,, causing the rear wheels to oversteer. A third causing the rear wheels to oversteer. A third s

skkiid d ccaalllleed d tthhe e ffoouur r wwhheeeel l sskkiid d ccaan n aallssoo occur, where all the four wheels lock up and occur, where all the four wheels lock up and the vehicle slides in the direction where the the vehicle slides in the direction where the forward momentum is carrying it, with no forward momentum is carrying it, with no directional control.

directional control.

To counter these skids and to To counter these skids and to prevent accidents from happening, Vehicle prevent accidents from happening, Vehicle

Skid Control (VSC) is incorporated in the vehicle. Vehicle Skid Control (VSC) takes the safety aspects of the driver and the vehicle to the next level. It comes under the category of “Passive Technology”, which helps you to avoid a crash. Vehicle Skid Control (VSC) senses the onset of traction loss and helps the driver stay on track. This is achieved via the system's ability to reduce engine power and to control the brake actuator. VSC helps the driver maintain vehicle traction under demanding conditions by detecting and helping to correct the wheel spin. VSC uses a variety of sensor input to determine if the car is losing traction, then applies the brakes to individual wheels to help correct for

discrepancies. The system will also back off  the throttle to reduce power. VSC integrates traction control to limit rear wheelspin on

slippery surfaces. The VSC system

electronically monitors speed and direction, and compares the vehicle's direction of  travel with the driver's steering, acceleration and braking input. VSC can help the driver compensate for loss of lateral traction, which can cause skids and loss of vehicle control. 2. CAUSES

The main causes of skidding are as follows:

a) Harsh or sudden acceleration. b) Excessive or sudden braking.

d) Oversteer and understeer.

The effects of the above will be enhanced by speed. Combining these effects with non-recognition of adverse road and weather conditions will create problems for the driver.

3. TYPES OF SKID

The main types of skid that a driver could encounter on the public highway fall into three categories.

1) The front wheel skid. 2) The rear wheel skid. 3) The four wheel skid.

3.1. The Front Wheel Skid

3.1.1.Characteristics

The car tends to take a course outside of the expected course that the driver has steered (understeer). If the front tyre approaches the traction limit more rapidly, the effect is that the front of  the car takes a wider radius curve than the driver intended. The car is said to understeer.

3.1.2. Cause

Excess speed on entry to a hazard i.e. a corner or bend, or sudden braking to reduce the speed when negotiating the

hazard. Both of these actions will have the effect of destabilising the vehicle making it more vulnerable to a loss of control.

3.2. The Rear Wheel Skid

3.2.1. Characteristics

The rear of vehicle swings out of  line and gives the impression of trying to overtake the front (oversteer); see figure

2. If the rear tyres approach their traction limit more rapidly than the front, then the effect is for the rear of the car to steer a wider path than the front wheels. This rotates the car more than the driver

intended and, if nothing is done, leads to the car turning a smaller radius corner. When this occurs the car is said to

oversteer.

3.2.2. Cause

As with the front wheel skid, excessive speed into the hazard and sudden braking or acc-eleration with a

rear wheel drive vehicle, destabilising the vehicle, are the main causes of this skid.

3.3.1. Characteristics

All four wheels have locked up and the vehicle is sliding in the direction that the forward momentum is carrying it, with no directional control; see figure 3. Both front and rear wheel skids, if unchecked sufficiently early, can develop into four wheel skids.

3.3.2. Cause

Harsh or sudden braking has

caused the wheels to lock. A sensation of  increase in the vehicle’s speed often

occurs.

Figure 1

4. UNDERSTEER AND OVERSTEER 4.1. Understeer

As the name implies, understeer occurs when the front slip angle is greater than the rear and the car goes straighter rather than following the intended turn.  The slip angle, or yaw angle in technical terminology, is the angle between where the car is pointing and the intended path.  The yaw moment is the rate at which the yaw angle is changing. The higher the yaw moment, the more likely it is that the driver is losing control. At the same point, the front wheel may start to grip less even when the steering is turned sharply and as a result the car continues in more of a straight line than a sharp turn. Here in this case, the skid control system brakes the inside rear wheel, effectively tightening the car’s line. By applying the brakes, the

car slows down which further helps stabilise it.

4.2. Oversteer

Oversteer, on the other hand, occurs when the rear tyres have a greater slip angle than the front tyres and the back threatens to overtake the front, causing the vehicle to spin. In other words, if the rear tyres approach their traction limit more rapidly than the front, then the effect is for the rear of the car to steer a wider path than the front wheels. This rotates the car more than the driver intended and, if nothing is done, leads to the car turning a smaller radius corner. When this occurs the car is said to

oversteer. Here the skid control system brakes the outside front wheel to reduce oversteer, effectively pulling the tail back into line.

5. SKID CONTROL

Stability control systems or skid control systems with names like StabiliTrak,

Dynamic Stability Control, Stability

Management, and Vehicle Skid Control are the latest advancement in vehicle safety. Regardless of the different names, they all perform the same task – to sense the onset of traction loss and keep the driver on track. These systems are designed to

deliver transparent intervention the

moment the situation becomes unstable. A vehicle skid control system actually

detects when a driver has lost some degree of control. It then automatically stabilizes the vehicle to help the driver regain control. Vehicle Skid Control (VSC) takes the safety aspects of the driver and the vehicle to a completely new level. These skid control systems are often integrated with the engine management system to cut power in even more tricky situations. This scenario is a complex system of sensors and microprocessors that continually monitor the vehicle for any signs of instability. Once detected (usually in the form of a slide or skid), the system automatically applies selective

braking to specific wheels thereby

stabilizing the vehicle. This split-second intervention often happens so quickly that

it is over before drivers even realize they were in danger of losing control. By gently stabilizing the car at the critical moment, control is returned to the driver with minimal fuss and alarm. Luxury cars, such as the Mercedes Benzes, BMW, Lexus, etc. now sold in India, have stability systems installed that are designed to remove oversteer or understeer.

6. COMPONENTS

The Vehicle Skid Control (VSC) is made possible by the combination of different electronic and mechanical components. Some of the components are those used in Anti-lock Braking System (ABS), and an electronically controlled engine throttle, as well as a dedicated computer and sensors,

providing information to the VSC system.  These include:

Figure 2

•  Yaw rate sensor.

• G-sensor.

• Steering angle sensor.

• Electronic throttle control.

• Slip indicator.

• Computer.

•

 Yaw rate sensors detect changes in the car's rotation in a left or right direction. It

car is moving relative to which way the driver is

turning the steering wheel. When the sensors detect understeer or oversteer, a computer takes over and applies brakes or controls power to one or both the drive wheels, so that the car comes under control.

 The system is programmed to respond to a wide variety of scenarios and is so selective that it can apply only the brake on one specific wheel if that's what is needed to regain control. The G-sensor or gravity sensor determines if the car is accelerating or decelerating, cornering

and braking forces simultaneously while the car is on the move and accordingly controls the throttle. Steering angle sensor evaluates the direction and rate of change in steering wheel movement. Electronic throttle control reduces the throttle for

1/7th _{of a second, to control the wheel}

spin, when the front or rear wheels lose traction. Slip indicator alerts the driver that the tyres are about to exceed the grip limit. The central processing computer monitors the steering movement together with either taking over and applying brakes or controlling the power to one or both the drive wheels.

7. WORKING

from a number of sensors, and then determines whether the car is in a stable or unstable state. By combining the datas from ABS sensors (for wheel speed), steering angle sensors, yaw sensors (measuring the amount a car fishtails, or rotates around its vertical center axis), and lateral force sensors (measuring the amount of sideways g-force generated by the car), the central processing unit can actually detect when a vehicle is behaving in a way contrary to how the driver intends. VSC also includes a slip indicator with a warning sound and light to alert the driver that the tyres are about to exceed the grip limit.

If the processor does detect instability such as a slide produced by a sudden

swerve, it automatically applies light brake pressure to a select wheel (or wheels) to maintain or restore control. Here, the VSC computer uses engine throttle control and individual wheel braking to help counteract skidding and

spinning.The high-speed computer

constantly compares the driver's

intentions, as indicated by steering wheel, throttle and braking activity, with the car's actual motions measured by the various sensors. If they do not correlate, the VSC computer selectively applies individual wheel brakes and/or momentarily reduces engine power as necessary to help the driver regain the intended direction of 

travel. For example, if the car were

responding to the driver's right turn of the steering wheel, VSC would typically reduce engine power and would apply the right front brake momentarily to help the car follow the intended path. Once proper vehicle attitude is restored, VSC returns to a standby state. When VSC is active, a warning beep tone and instrument panel warning light indicate that the system is functioning. In many cases, VSC reacts well before the driver is aware of a loss of  lateral traction. A VSC shutoff button deactivates VSC and electronic traction control for use. At all other times,VSC remains on and functioning. VSC differs from Anti-lock Braking System (ABS) technology. ABS prevents vehicle wheels

from locking, decreases the distance required to stop and improves a driver's

control during emergency braking on wet and slippery roads whereas VSC is intended to help a driver maintain the intended direction of travel, even when the brakes are not applied. However, VSC and ABS compliment and work in close coordination with each other in stability control system, providing enhanced driver control in a broad range of situations.VSC can help provide a measure of control in real-world situations faced by even the most careful and experienced drivers. VSC senses the onset of traction loss and helps the driver stay on track. This is achieved

via the system's ability to reduce engine power and to control the brake actuator. 8. WHEN DOES IT HELP?

Like the safety systems that preceded it, Vehicle Skid Control is designed to step in when human input is incapable of  effectively controlling the vehicle. In most cases, critical situations are the result of  human error in the first place-driving too

quickly, inattention, misjudgment or

simply panicking in an emergency

situation. In these situations, everyone can benefit from a safety system that occasionally helps regain vehicle stability, while never taking full control out of the driver's hands.

After the introduction of  ABS, no safety advancement has added such a high level of driving security as VSC. When used with ABS and traction control, Vehicle Skid Control significantly increases a driver's chances of recovering from potentially dangerous situations. But no matter how advanced the safety aid, the ultimate fate of a vehicle and its occupants remains in the hands of the driver. No safety system should ever be expected to protect unconditionally. So while the latest generation of stability control systems offer drivers increased protection from both themselves and the unexpected, they can never overcome poor judgement or the laws of physics.

In each case, the cause can be removed by taking the foot off the accelerator or brake and depressing the clutch. The reasons are as

follows:-• By decelerating, the vehicle’s speed is

lowered, which in turn will start to reduce the magnitude of the skid.

• Relaxation of the pressure on the brake

pedal will unlock the wheels and allow the tyres to regain traction, enabling the vehicle to be steered.

• Depressing the clutch pedal has 3

beneficial effects:

(i) The engine will not stall, enabling

the vehicle to be moved quickly from the danger area.

(ii) The link between engine (providing power) and transmission is broken; there is no drive to any of the wheels, therefore the vehicle is no longer a front, rear or four wheel drive model. (iii) A very slippery surface can cause

the drive to lock up which in turn causes the wheels to lock, keeping the vehicle in a skid situation.

10. ADVANTAGES AND

DISADVANTAGES 10.1. Advantages

1) Monitors each wheel independently

maximizing the performance of the car.

2) Increases comfort, both physical and

psychological.

3) Improves safety aspects of the car and the

driver.

4) Helps save money long term.

5) Enhances the ability to dodge a

renegade object in its pathways. 10.2. Disadvantages

1) High initial costs.

2) Overdependence.

3) Not perfect.

4) Repairing cost may be high.

5) 11. CONCLUSION

Driving has become more and more dangerous with the ever increasing

population of man and vehicles. It is estimated that 25% of all accidents are caused by driver distractions. Automotive technology is being developed everyday to make our lives on the roads much safer. Vehicle Skid Control is one such instance. Safety is the principal benefit of this technology.

But no matter how advanced the safety aid, we should never forget that the ultimate fate of a vehicle and its occupants remains in the hands of the driver. No safety system should ever be expected to protect unconditionally. So while the latest generation of stability control systems offer drivers increased protection for both themselves and the