Does the direction of friction change due to turning the tyres towards the direction of turn or is there any other reason? And, this video was very helpful, thank you so much.
to make things easier...we know friction pulls tyres back and we all remember when we rolled our toy car's tyres back...it actually went forward....hence conservation of momentum....but we all know toy cars don't run forever...for what, energy of us rolling the tyres back gets stored in that spring/elastic of that toy car....and that energy is not infinite, hence it finally stops.
thank you great work , i have one question the friction force direction should be opposes the direction of motion but in this example both in same direction ? ua-cam.com/video/IqmzNU11kv4/v-deo.html in this example for ABS the friction opposes direction of motion
@@FlippingPhysics i think some of kind applied force, because in begining the car it was at rest and this applied force used to change the tangential speed
The only part of the car touching the ground is the tires. The only horizontal force the ground can cause on the tires is the force of friction. It is the force of friction which moves the car. 😀
@@naderahmed78 The car pushes backward on the road via static friction (traction), attempting to do work on the road. Unbeknownst to the car, the road is attached to the Earth. The Earth will not accelerate significantly from this force, due to its enormous mass, that we might as well consider infinite at the scale of this problem. Per Newton's third law, the road simultaneously pushes forward on the car. Nearly all of the work that the car attempted to do on the road, the road will "reflect" back onto the car. The reaction force to the car pushing the road backward, will do work on the car, since the car is the object that has the most significant displacement in this interaction. Think of the road and Earth as a "work mirror". Push backwards on something with so much more mass than you, and it will reflect your work back to your body. Push on 5.98e24 kg of Earth, and you will get great traction. Push on 1 kg of loose mud, and you will get barely any traction on a 1000 kg car. The mud will move instead of your car.
great video .tnx
Lots of tough concepts illustrated here. It looks great!
Thanks. I am proud of this one. I do not know how I feel about the darker motif of this video though...
@@FlippingPhysics I didn't even notice that! I have dark mode enabled somewhat randomly across my devices, so maybe that's why it didn't stand out.
This is amazing, I love this
Looks great. Regarding the darker motif, I actually really liked it, if that makes a difference!
That's beautiful sentence sir that u said at last
Does the direction of friction change due to turning the tyres towards the direction of turn or is there any other reason? And, this video was very helpful, thank you so much.
thank you sir
to make things easier...we know friction pulls tyres back and we all remember when we rolled our toy car's tyres back...it actually went forward....hence conservation of momentum....but we all know toy cars don't run forever...for what, energy of us rolling the tyres back gets stored in that spring/elastic of that toy car....and that energy is not infinite, hence it finally stops.
why not Kinetic friction, Mr.P?
thank you great work , i have one question the friction force direction should be opposes the direction of motion but in this example both in same direction ?
ua-cam.com/video/IqmzNU11kv4/v-deo.html
in this example for ABS the friction opposes direction of motion
Good question. I will respond with a question.
In this example, what force is it that causes the car to move in the direction of motion?
@@FlippingPhysics i think some of kind applied force, because in begining the car it was at rest and this applied force used to change the tangential speed
The only part of the car touching the ground is the tires. The only horizontal force the ground can cause on the tires is the force of friction. It is the force of friction which moves the car. 😀
@@naderahmed78 The car pushes backward on the road via static friction (traction), attempting to do work on the road. Unbeknownst to the car, the road is attached to the Earth. The Earth will not accelerate significantly from this force, due to its enormous mass, that we might as well consider infinite at the scale of this problem. Per Newton's third law, the road simultaneously pushes forward on the car. Nearly all of the work that the car attempted to do on the road, the road will "reflect" back onto the car. The reaction force to the car pushing the road backward, will do work on the car, since the car is the object that has the most significant displacement in this interaction.
Think of the road and Earth as a "work mirror". Push backwards on something with so much more mass than you, and it will reflect your work back to your body. Push on 5.98e24 kg of Earth, and you will get great traction. Push on 1 kg of loose mud, and you will get barely any traction on a 1000 kg car. The mud will move instead of your car.
Nice dark theme
Glad you like it