"Normal" forces push up on a still car. In this case, normal forces are equal in magnitude but opposite in direction to the gravitational forces pushing down on the still 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.
When a helicopter is hovering (aka "still") it has the force of gravity pushing "down" toward the Earth and the force of "lift" of the spinning rotor blade(s) pushing against the surrounding air. When the gravitational force is equal to the force of lift the helicopter hovers on the vertical axis.
When a car is stationary, the main forces acting on it are the force of gravity pulling it down, the normal force from the ground pushing it up, and potentially frictional forces on the tires and air resistance. In this situation, the net force on the car is typically zero, resulting in the car remaining stationary.
Why not ? Take four big guys shaped like barrels, who can push a car uphill with one hand. Now put the car on a flat parking lot and spread the four guys around it, with one guy in the back pushing forward, one in the front pushing backward, one on the left pushing right, and one guy on the right pushing left. Where will the car go ? Nowhere. Even in neutral with the parking brake off. If you remember to include the directionof each force, then all the forces on the car add up to zero.
A book resting on a table with the force of gravity pulling it down balanced by the normal force from the table pushing it up. A person standing still on the ground with the force of gravity pulling them down balanced by the normal force from the ground pushing them up. A car traveling at a constant speed on a flat road with the driving force from the engine balanced by the frictional force and air resistance.
The chair in pushing you up and the gravity pushing you down
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 balance between the forces pushing the crust down (like gravity) and the forces pushing it up (like buoyancy from the mantle) is called isostasy. This concept helps to explain how the Earth's lithosphere floats on the semi-fluid asthenosphere below.
There's no such thing as one single balanced force. A group of two or more forces are balanced if they all add up to zero. Like if two people are pushing on the same shopping cart ... one in the back pushing it forward, and one on the front pushing it backward. They add up to zero, and the cart acts exactly as if there are no forces on it at all ... it stands still. Those two forces are balanced.
When a helicopter is hovering (aka "still") it has the force of gravity pushing "down" toward the Earth and the force of "lift" of the spinning rotor blade(s) pushing against the surrounding air. When the gravitational force is equal to the force of lift the helicopter hovers on the vertical axis.
When a car is stationary, the main forces acting on it are the force of gravity pulling it down, the normal force from the ground pushing it up, and potentially frictional forces on the tires and air resistance. In this situation, the net force on the car is typically zero, resulting in the car remaining stationary.
Why not ? Take four big guys shaped like barrels, who can push a car uphill with one hand. Now put the car on a flat parking lot and spread the four guys around it, with one guy in the back pushing forward, one in the front pushing backward, one on the left pushing right, and one guy on the right pushing left. Where will the car go ? Nowhere. Even in neutral with the parking brake off. If you remember to include the directionof each force, then all the forces on the car add up to zero.
A book resting on a table with the force of gravity pulling it down balanced by the normal force from the table pushing it up. A person standing still on the ground with the force of gravity pulling them down balanced by the normal force from the ground pushing them up. A car traveling at a constant speed on a flat road with the driving force from the engine balanced by the frictional force and air resistance.
Mountains and plateaus are landforms that are typically formed by the forces of tectonic plates pushing against each other, causing the Earth's crust to uplift. This process is known as crustal deformation and results in the creation of large elevated landmasses.
because when you drive theair is pushing on your car and goes inside the car and goes warm and heats up as you go
The forces pushing the ball uphill are the external force or the force applied to the ball, which imparts energy to move it up, and the force of friction acting against the ball's motion. The forces pulling the ball downhill include gravity, which pulls the ball downwards, and potentially air resistance if applicable.
A person pushing a car to start it. A weightlifter pushing up on a barbell during a bench press. Wind pushing against a sail on a boat.