Somebody pushing the car; friction slowing down the car; gravity acting on the car (this is especially relevant if the car is going up or down a slope); the engine pushing the car forwards.
Yes, a force is acting on the car when it turns to the left. This force is known as centripetal force, which is directed towards the center of the circular path the car is traveling along. It is required to keep the car moving in a curved path instead of continuing in a straight line.
Yes, if a car is moving at a constant speed, balanced forces must be acting on it. This means that the force pushing the car forward is equal to the resistive forces acting against it (like friction and air resistance), resulting in zero net force and a constant velocity.
When a car is in motion, the main forces acting on it are: Thrust force from the engine propelling the car forward. Frictional force between the tires and the road resisting the car's motion. Air resistance acting opposite to the direction of motion, which increases with speed. Gravitational force pulling the car downward.
Yes, frictional forces such as air, tires against the ground, gravity pulling the car down, force of engine moving car forward. The positive force of the engine turning the drive train and the wheels is equaled by the frictional forces; so overall forces balance out.
When a car is moving at a steady speed of 50 mph, the main forces acting on it are the force of friction between the tires and the road (rolling resistance), air resistance, and the force from the engine propelling the car forward. Additionally, there may be gravitational forces acting on the car depending on the incline or decline of the road.
Yes, a force is acting on the car when it turns to the left. This force is known as centripetal force, which is directed towards the center of the circular path the car is traveling along. It is required to keep the car moving in a curved path instead of continuing in a straight line.
Yes, if a car is moving at a constant speed, balanced forces must be acting on it. This means that the force pushing the car forward is equal to the resistive forces acting against it (like friction and air resistance), resulting in zero net force and a constant velocity.
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.
When a car is in motion, the main forces acting on it are: Thrust force from the engine propelling the car forward. Frictional force between the tires and the road resisting the car's motion. Air resistance acting opposite to the direction of motion, which increases with speed. Gravitational force pulling the car downward.
Yes, frictional forces such as air, tires against the ground, gravity pulling the car down, force of engine moving car forward. The positive force of the engine turning the drive train and the wheels is equaled by the frictional forces; so overall forces balance out.
When a force is acting on an object, there is always another equal and opposite force acting upon it. For example; a car that is travelling forward has a force of 'Thrust' which is pulling the car forward, as this occurs, 'Drag' or 'Air resistance' is also acting upon the car.
When a car is moving at a steady speed of 50 mph, the main forces acting on it are the force of friction between the tires and the road (rolling resistance), air resistance, and the force from the engine propelling the car forward. Additionally, there may be gravitational forces acting on the car depending on the incline or decline of the road.
An example of a net force is when a car is accelerating. The net force on the car is the combined effect of all forces acting on it, such as the force produced by the engine and the force of friction. This net force causes the car to change its speed or direction.
When a car is not moving, the main forces acting on it are gravity pulling it downward and the normal force from the ground pushing upward to support the car's weight. There may also be frictional forces between the tires and the road, as well as air resistance acting on the car.
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.
The reaction force to the friction acting on the car is the friction force acting on the road. It acts on the car in the opposite direction to the friction force acting on the car.
No,because if the car is moving at a constant velocity that means the acceleration is zero. So the net force is zero and there may be some forces acting on it. Only gravity, downward.