Centripital force.
The centripetal force is the force that holds an object in a circular motion. It acts towards the center of the circle and keeps the object moving in a curved path. Without this force, the object would move in a straight line.
Centripetal force is the force that holds objects in a circular motion. It acts towards the center of the circle and keeps an object moving in a circular path rather than flying off in a straight line.
A force that holds a moving object in a circular path is a "centripetal force". In the case of an orbiting planet, moon, artificial satellite etc., the mutual force of gravitation between the orbiting body and the central body is the centripetal force.
centripetal- Dashun Walden
Friction is the force that holds back the movement of an object. It occurs when two surfaces are in contact and opposes the direction of motion, making it more difficult for the object to move.
The centripetal force is the force that holds an object in a circular motion. It acts towards the center of the circle and keeps the object moving in a curved path. Without this force, the object would move in a straight line.
Centripetal force is the force that holds objects in a circular motion. It acts towards the center of the circle and keeps an object moving in a circular path rather than flying off in a straight line.
A force that holds a moving object in a circular path is a "centripetal force". In the case of an orbiting planet, moon, artificial satellite etc., the mutual force of gravitation between the orbiting body and the central body is the centripetal force.
centripetal- Dashun Walden
Friction is the force that holds back the movement of an object. It occurs when two surfaces are in contact and opposes the direction of motion, making it more difficult for the object to move.
The force that keeps an object in orbit around another object is gravity. Specifically, it is the gravitational pull between the two objects that keeps them moving in a curved path instead of flying off into space. This balance between the object's inertia and the gravitational force keeps it in orbit.
Its changing direction ;)
Yes, the Archimedes principle applies in a satellite moving in a circular orbit. The principle states that the buoyant force acting on an object is equal to the weight of the fluid displaced by the object. In the case of a satellite in orbit, the principle still holds as the satellite is displacing the atmosphere and experiences a reduced weight due to its orbital motion.
The force that holds the planets in orbit is gravity, although inertia( the resistance of any physical object to a change in its state of motion or rest, or the tendency of an object to resist any change in its motion.) help to hold it in place as well, because the two forces balance each other out.
The force that holds back a sliding object is friction. Friction is the resistance that occurs when two surfaces rub against each other, causing the object to slow down or stop.
No, an unbalanced force will cause an object to accelerate, not move at a constant velocity. The object will continue to accelerate in the direction of the unbalanced force until a balanced force is applied.
Archimedes' principle refers to an object floating in a liquid. In this case, there is the downward force of gravity on the object, and the "buoyant force" as upward force. This is quite unrelated to "free fall", which means that no other forces than gravity act on an object.