The force of Gravity.
The normal force from the ground is pushing up on the car to support its weight, counteracting the force of gravity pulling the car downwards. If the car is on an incline, a component of the normal force would also act in the direction of the incline to prevent the car from rolling downhill.
The main forces acting on a car moving at a constant speed on a level highway in still air are the driving force from the engine propelling the car forward and the opposing forces such as friction between the tires and the road and air resistance. When these forces are balanced, the car will continue to move at a constant speed.
There are forces acting on the car. They are just equal to the force of the car acting on the force. In example, gravity is acting on the car, but the car is pushing back equally. Therefore, the car doesn't move.
Yes, even when a car is at rest, there are still forces acting on it. The two main forces are the force of gravity, pulling the car downward towards the ground, and the normal force exerted by the ground on the car to keep it stationary.
When a car is still, the main forces acting on it are the gravitational force pulling it downwards and the normal force from the ground pushing it upwards. These two forces are equal in magnitude and opposite in direction, resulting in a net force of zero.
The normal force from the ground is pushing up on the car to support its weight, counteracting the force of gravity pulling the car downwards. If the car is on an incline, a component of the normal force would also act in the direction of the incline to prevent the car from rolling downhill.
The main forces acting on a car moving at a constant speed on a level highway in still air are the driving force from the engine propelling the car forward and the opposing forces such as friction between the tires and the road and air resistance. When these forces are balanced, the car will continue to move at a constant speed.
There are forces acting on the car. They are just equal to the force of the car acting on the force. In example, gravity is acting on the car, but the car is pushing back equally. Therefore, the car doesn't move.
on a still car the weight force is down, and is balanced with the reaction force (working upwards). friction of forward and balanced with drag - backwards. ;)
Yes, even when a car is at rest, there are still forces acting on it. The two main forces are the force of gravity, pulling the car downward towards the ground, and the normal force exerted by the ground on the car to keep it stationary.
When a car is still, the main forces acting on it are the gravitational force pulling it downwards and the normal force from the ground pushing it upwards. These two forces are equal in magnitude and opposite in direction, resulting in a net force of zero.
None. It is at rest. No forces.
Of course. When your car is standing still, its velocity, acceleration, and momentum vectors, and the horizontal components of forces on it, are zero.
Not that i have found. i don't tell them I'm in the forces but rather the job i do in the forces (mechanic) this tends to lower it a bit. You are eligible for USAA insurance and that is usually significantly lower but you still need to shop around.
5 kg Car moving 10 m/s west+10 Newton force pushing car west-10 Newton force pushing car east Sum of the forces = Mass × acceleration Sum of the forces = (+10 Newton) + (-10 Newton) Sum of the forces = 0 Mass = 5 Kg Sum of the forces = 0 5 Kg × acceleration =0 acceleration =0 If acceleration = 0, the velocity is constant, not changing. If the car is sitting still, it will remain still. If the car is moving 10 m/s west, it will remain moving 10 m/s west. If 2 weight lifters of equal strength push with the same force on the front and back of the car, what will happen?
When two forces are applied to a car in an effort to move it, the car will move in the direction of the greater force. The car's motion is determined by the difference between the two forces acting on it.
Friction