The following analysis holds while I am sitting in/on the chair:
Gravitational force -- downward
Resistance force of the chair -- upward
Sum of the forces on the seat of my pants -- Zero
Therefore neither I nor the seat of my pants is accelerated.
The frictional force between the chair and the floor is less than 15 newtons, as it was overcome by the applied force for the chair to start moving. The frictional force opposes the motion of the chair until it reaches an equilibrium. This scenario suggests that the static friction force between the chair and the floor is less than 15 newtons.
from Newton's third law of motion, the action reaction pair is adapted to your question, thus f=f following that the force exeterd buy the chair on the person is equall to the force at gravity by the person.
When you pull a chair across a room, you are exerting a force known as kinetic friction. This force opposes the direction of motion and arises between the chair's legs and the floor surface due to their contact.
An unbalanced force acting on the chair could overcome the static friction between the chair and the floor, causing the chair to start moving. Once the force is stronger than the static friction, the chair will slide across the room due to the unbalanced force propelling it forward.
The action force when you sit down on a chair is the force exerted by you on the chair. This force is equal in magnitude and opposite in direction to the reaction force exerted by the chair on you, which supports your weight and keeps you from falling through the chair.
The frictional force between the chair and the floor is less than 15 newtons, as it was overcome by the applied force for the chair to start moving. The frictional force opposes the motion of the chair until it reaches an equilibrium. This scenario suggests that the static friction force between the chair and the floor is less than 15 newtons.
from Newton's third law of motion, the action reaction pair is adapted to your question, thus f=f following that the force exeterd buy the chair on the person is equall to the force at gravity by the person.
When you pull a chair across a room, you are exerting a force known as kinetic friction. This force opposes the direction of motion and arises between the chair's legs and the floor surface due to their contact.
An unbalanced force acting on the chair could overcome the static friction between the chair and the floor, causing the chair to start moving. Once the force is stronger than the static friction, the chair will slide across the room due to the unbalanced force propelling it forward.
The action force when you sit down on a chair is the force exerted by you on the chair. This force is equal in magnitude and opposite in direction to the reaction force exerted by the chair on you, which supports your weight and keeps you from falling through the chair.
If it starts moving, that implies that the frictional force is less than 15 N.
When someone pushes a chair across the floor, the force applied in the pushing direction causes the chair to move. Friction between the chair legs and the floor resists the motion, which can create a sound as the chair moves. If the force is strong enough, the chair will accelerate and continue moving until the force is removed or balanced by other forces.
When you sit in a chair, the action force is the downward force you exert on the chair due to your weight. The reaction force is the upward force exerted by the chair on you, supporting your weight and keeping you from falling to the ground.
If the chair is moving at a constant velocity, the force of friction is equal and opposite to the force you are exerting on the chair. This is to maintain the equilibrium of forces acting on the chair.
because the floor exerts the same amount of force which means the net force is balanced causing it not to move
The upward force exerted by a chair when you sit on it depends on your weight and the design of the chair. The force is equal to the force of gravity acting on you, to keep you balanced and prevent you from falling.
You are demonstrating the force of friction when you pull a chair across a room. Friction is the resistance that opposes relative motion between two surfaces in contact.