The magnitude of the resulting force is 10 N. Because the forces are perpendicular, we can use Pythagoras' theorem:
FT = SQRT ( F12 + F22 ) where:
If an object is moving at a constant speed, the forces acting on it are balanced. This means that the forces pushing in one direction are equal to the forces pushing in the opposite direction, resulting in no change in the object's speed or direction.
If two people on opposite sides are pushing on an object with equal force, the object will not move. The forces will cancel each other out, resulting in an equilibrium.
Forces are balanced when the net force acting on an object is zero. This means that the forces pushing or pulling in different directions cancel each other out, resulting in no acceleration of the object. When forces are balanced, an object will either remain at rest or move at a constant velocity.
The two forces acting on a sinking object are gravity, pulling the object downward, and buoyancy, pushing the object upward. Buoyancy force is caused by the displaced fluid pushing back against the object's weight, resulting in the object sinking, floating, or rising depending on the balance between these forces.
Two examples of pushing forces are a car's engine pushing the car forward, and a person pushing a heavy object across the floor.
10 newtons NE. a little more north than east
If an object is moving at a constant speed, the forces acting on it are balanced. This means that the forces pushing in one direction are equal to the forces pushing in the opposite direction, resulting in no change in the object's speed or direction.
An object at rest pulled in opposite directions by unequal forces will start to move in the direction of the net force. For example, if I have a chair, and I'm pushing with 10 newtons to the right, and my sister is pushing 5 newtons to the left, the net force is 5 newtons to the right. Therefore, I win, and the chair moves to the right, in the direction of the net force.
If two people on opposite sides are pushing on an object with equal force, the object will not move. The forces will cancel each other out, resulting in an equilibrium.
Forces are balanced when the net force acting on an object is zero. This means that the forces pushing or pulling in different directions cancel each other out, resulting in no acceleration of the object. When forces are balanced, an object will either remain at rest or move at a constant velocity.
The two forces acting on a sinking object are gravity, pulling the object downward, and buoyancy, pushing the object upward. Buoyancy force is caused by the displaced fluid pushing back against the object's weight, resulting in the object sinking, floating, or rising depending on the balance between these forces.
Two examples of pushing forces are a car's engine pushing the car forward, and a person pushing a heavy object across the floor.
Two forces that can make an object move are external forces, such as pushing or pulling it, and gravitational forces acting on the object.
Consider an object in empty space. There are two forces pushing from opposite sides, one force (force A) on the left pushing with 2 newtons of force, the other (force B) on the right pushing with 1 newton. Since force A is pushing with a greater force than force B, the result will be the object moving right. The object is also moving with a force of 1 newton, because force A is 1 newton greater than force B.
Two forces are balanced when they both have the same number of Newtons, eg. if a rock is placed on the ground, the rock will push down with a force of around 10 Newtons, say, and the ground will push back up with an equal force. this means that the rock will not sink into the floor, but it will also not start to rise off of the ground.
An example of unequal forces pushing in opposite directions is a tug-of-war game, where one team pulls harder than the other. The resulting force will cause the object (in this case, the rope) to move in the direction of the stronger force.
Pushing forces are forces that result from an object being moved away from you, while pulling forces are forces that result from an object being moved towards you. In pushing, the force is exerted in the direction opposite to the motion, while in pulling, the force is exerted in the direction of the motion.