That depends on the specific situation. Note that by Newton's Third Law, the force exerted by a wall on a rope is the same as the force exerted by the rope on the wall.
When you pull a rope that is attached to a wall, you exert a force on the rope in one direction (action). In response, the wall exerts an equal and opposite force on the rope in the opposite direction (reaction), as described by Newton's third law of motion.
The force is typically due to the muscles in your fingers contracting and exerting a pushing force against the wall, resulting in your fingers bending. This force is a result of the interaction between your muscles and the wall, known as the normal force.
Yes, pushing against a brick wall would require force and displacement, which are the two components of work. You would be exerting energy to apply a force on the wall, but if the wall doesn't move, there would be no work done on the wall.
When someone pushes on a wall, the main forces involved are the normal force exerted by the wall on the person's hand (perpendicular to the wall) and the force exerted by the person's hand on the wall (opposite in direction to the normal force). Friction between the person's hand and the wall also plays a role in resisting the motion of the hand.
Three examples of action-reaction force pairs are: A person pushing against a wall (action) and the wall pushing back on the person (reaction). A rocket pushing exhaust gases downward (action) and the rocket being propelled upward (reaction). A book resting on a table (action) and the table exerting an upward force on the book (reaction).
For every actions there is an equal and opposite reaction. For example, if i punch a wall i am exerting a force on the wall, but at the same time the wall is exerting the same amount of force on my fist.
For every actions there is an equal and opposite reaction. For example, if i punch a wall i am exerting a force on the wall, but at the same time the wall is exerting the same amount of force on my fist.
When you pull a rope that is attached to a wall, you exert a force on the rope in one direction (action). In response, the wall exerts an equal and opposite force on the rope in the opposite direction (reaction), as described by Newton's third law of motion.
The force is typically due to the muscles in your fingers contracting and exerting a pushing force against the wall, resulting in your fingers bending. This force is a result of the interaction between your muscles and the wall, known as the normal force.
When you hammer a nail into a wall, you are applying pressure by exerting force on the hammer, which then transfers that force to the nail. The pressure created by the hammer forces the nail to penetrate the wall's surface, securing it in place.
Yes, pushing against a brick wall would require force and displacement, which are the two components of work. You would be exerting energy to apply a force on the wall, but if the wall doesn't move, there would be no work done on the wall.
In everyday popular usage, "work" means effort, sweat, things like that. But the formal scientific definition of work is: (Force) times (distance). You can push on a brick wall as hard as you want for as long as you want; no work has been done until the wall moves, because the force hasn't moved through a distance.
When someone pushes on a wall, the main forces involved are the normal force exerted by the wall on the person's hand (perpendicular to the wall) and the force exerted by the person's hand on the wall (opposite in direction to the normal force). Friction between the person's hand and the wall also plays a role in resisting the motion of the hand.
Three examples of action-reaction force pairs are: A person pushing against a wall (action) and the wall pushing back on the person (reaction). A rocket pushing exhaust gases downward (action) and the rocket being propelled upward (reaction). A book resting on a table (action) and the table exerting an upward force on the book (reaction).
Turgor pressure is the force of water pushing against the cell wall in plant cells. It helps maintain the shape and rigidity of the cell by exerting pressure against the cell wall. When there is sufficient turgor pressure, the plant cell is firm and rigid, which is important for supporting the plant structure.
No work is done on the brick wall by the force of 500N because the wall does not move in the direction of the force. Work is only done when a force causes a displacement in the direction of the force.
a person pushing the wall.here nothing will be displaced inspite of the force applied on it.this is because there is an greater force applied by wall with respect to the force applied by the person.