It has long been known that a decrease in tyre tread depth can lead to the deterioration of a tyre's performance during cornering, and straight line braking in the wet. A tyre is unable to deal with the same volume of water on the road at lower tread depths, which means that the tyre is unable to transmit traction and braking forces as effectively. Previous studies had confirmed this relationship, however there was a need for independent testing to quantify the effects on typical cars found on today's roads. In 2003, the British Rubber Manufacturers Association (BRMA) commissioned MIRA to study the effects of tread depth on stopping distances. The study was carried out on MIRA's test track in Nuneaton, and 5 different tread depths were tested - 6.7mm, 4.1mm, 2.6mm, 1.6mm (the legal minimum) and 0.9mm. Vehicles were mounted with equipment to record time, speed, and distance. The tests were carried out on two different surfaces at the testing track, hot rolled asphalt and smooth concrete. In order to ensure the accuracy of the results, the tests were repeated several times. The stopping distance was recorded at each of these tread depths and the points plotted on a graph of stopping distance versus tread depth. A line was drawn through the points to show the trend between stopping distance and tread depth, from which information could be taken.
Tyre surface: If the tyre is new, it will have surface with depressions which will offer more friction compared to old tyre whose surface-depressions are worn out and it is more flat, so it offers less friction. Therefore, new tyre will have less stopping distance, as force of friction is more. Thinking distance is affected neither by friction between tyre and road, nor by friction between brake and tyre. If road has a wet surface, it has less friction so the vehicle will skid farther, and vice versa. The braking force, i.e, friction between tyre and brake is unaffected by road condition or tyre surface. Hence the distance the vehicle travels WHILE retarding due to "braking force", is not same as stopping distance, because even when the wheels are stopped rotating due to braking force, the car will skid a little distance- this total distance is the stopping distance.
A distracted driver will have a greater reaction time than a non-distracted driver. A distraction to a driver will increase the drivers' reaction time and reduces the ability to respond to an emergency situation. The driver takes longer to react and more time passes between seeing the hazard and starting braking, so the car travels a greater distance before it comes to a stop. Two important factors to take into account for calculating stopping distances are reaction time and breaking distance. Reaction time For average drivers it takes 1.5 seconds to react to an emergency situation. For a distracted driver it may take as long as 3 seconds. A focused driver driving at 60km/hr will travel approximately 25m before they react, and a distracted driver driving at 60km/hr will travel approximately 33m before they react. Braking distance The breaking distance of a car depends on a number of variables. The slope of the roadway; a car will stop more quickly if it is traveling uphill because gravity will help slow the vehicle. The frictional resistance between the road and the tyres of the car is also important. A car with new tyres on a dry road will be less likely to skid and will stop more quickly than one with worn tyres on a wet road. If the slope and frictional resistance are equal, the factor that has most influence on braking distance is the initial speed. Formula used for calculating braking distance: d = V /(2g(f + G)) Where: d is the Braking Distance (m) g is the Acceleration due to gravity (9.8m/s^2) G is the Roadway grade V is the Initial vehicle speed (m/s) f is the Coefficient of friction between the tires and the roadway (u) A more simple formula used to calculate braking distance can be derived from a general equation of physics. Ignoring friction, and the roadway grade v = u - 2ad where: v is the final velocity (m/s) u is the initial velocity (m/s) a is the acceleration (m/s^2) d is the distance traveled during deceleration(m) Since we know that v will be zero when the car has stopped, the equation can be re-written as d = u/2a The total distance it takes for the car to come to a stop can be found by adding the reaction distance to the braking distance.
Depends on what you're thinking about. On a hard, even surface a tire w/o treads can generate more friction than a tire with treads, as it will have a bigger engaged surface area. OTOH a tire with little/no treads will be prone to hydroplaning, which is very low friction.Then if you're talking about a soft surface a smooth tire will have less friction than a treaded tire. On a soft surface the treads can bite in which offerc more engagement than a smooth tire that might just slide on the top.If you were to look at the rolling resistance of the wheel as a whole, then a worn out tire will roll lighter than a treaded tire. A big part of rolling resistance is the energy lost in deforming the tire as it rolls along. As there's less rubber in a worn tire it will deform more easily, offering lower rolling resistance.Depends on road conditions.On a firm, dry surface a smooth tire will have more friction than a treaded tire. That's why race cars tend to have smooth tires AKA slicks.The reason why treaded tires are generally required for road use is that slick tires do very poorly in rain. When you drive through a puddle, water gets squished between the contact patch and the road, and w/o the tread pattern allowing water to escape, the tire is lifted off the road and hydroplaning occurs.Slick tires also do very poorly on softer Surfaces where treads would have dug in and found grip.
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Friction in motion is important as it helps you get a grip on things, write on paper, walk on the ground, light a matchstick, etc................ It can also be troublesome in ways like : 1. Your shoes get worn out. 2. The engine of a car starts overheating after running for a long period of time. 3. Your pencil gets blunt on repeated usage. 4. Your car's tires are no more smooth.
On dry, level pavement, with decent tires? About 120 feet. Many things affect this calculation. With worn tires the distance can increase to 210 feet. Dirt roads require longer braking distances than pavement. Ice can increase the braking distance by hundreds of feet. Braking down a hill, depending upon the slope, can double the braking distance, whereas braking up hill can halve that distance. If you lock the tires, you typically increase the braking distance. You can reduce the distance by pumping the brakes. Anti-lock brakes allow the tires to slip, which decreases the braking distance. Extra weight in the vehicle increases the braking distance. Refer to the link below for calculating the braking distance at different speeds with different tire wear on dry, level pavement.
Smooth tyres have less frictional grip on the road surface, and will slide further that a deep tread tyre.
The distance needs to be further apart from the car in front
no If you've never rotated your tires and they're badly worn, or if they're unbalanced (wheel weight come off ) they can affect your steering somewhat
Worn out brakes.
the tyres could blow and you may lose controle of your car
Tires worn out? Tires mounted and tight ok? Good alignment? Good balance? you'll need to take it back and ask these things or get a second opinion.. d
If you are wondering how you can repair your worn out auto tires because your tires went flat, then you should check out Repair Your Own Tires Guide. It is online and free.
You tires are worn out because either the car needs an alignment, you are running them with either too low or too high air pressure, suspension parts are worn, steering parts are worn, or the tires were defective.
Too much camber and the tires aren't aligned right so the tires get worn easily
Tires are changed during an auto race because the tires get worn down by the track. It is safer to have good tires than to have tires that are worn down that could blow apart and cause accidents.
they are rethreaded