An object at rest will stay at rest unless acted upon by an external force, according to Newton's first law of motion. Similarly, an object in motion will stay in motion with a constant velocity unless acted upon by an external force. These principles are fundamental to understanding the concept of inertia.
An object will stay at rest or keep moving at a constant velocity if the net force acting on it is zero, according to Newton's first law of motion. If there is no external force acting on the object, it will remain in its current state of motion.
An object will keep moving if no external force acts upon it to stop or change its motion. In the absence of friction or resistance, an object in motion will continue moving at a constant velocity due to its inertia.
It takes more force to get an object moving because you need to overcome its initial inertia, which is the resistance of the object to changes in its motion. Once the object is moving, it requires less force to keep it in motion because there is less resistance once it has overcome the inertia.
Yes, according to Newton's first law of motion, an object will remain in its state of motion (either at rest or moving at a constant velocity) unless acted upon by an external force. In order to keep an object moving, a force must be continuously applied to overcome any friction or resistance that might slow it down.
It is harder to get an object to start moving because overcoming static friction requires more force than maintaining its motion due to kinetic friction. Static friction is stronger initially but once the object is in motion, it requires less force to keep it moving due to kinetic friction being lower.
The condition for an object to stay at rest or if moving, moving at a constant velocity is that the sum of forces acting on the object be zero or that no force acts on the object.
The condition for an object to stay at rest or if moving, moving at a constant velocity is that the sum of forces acting on the object be zero or that no force acts on the object.
The condition for an object to stay at rest or if moving, moving at a constantvelocity is that the sum of forces acting on the object be zero or that no forceacts on the object.Read more: What_are_the_condition_for_an_object_to_stay_at_rest_to_keep_moving_at_constant_velocity
the heavier and the bigger the object the more force you need to use to keep it moving . the less weight and the smaller an object is the less force you need to use to keep it moving. it always depends on the weight of the object and the size of the object.
The best, purest answer is: Because no force at all is required to keep a moving object moving.
An object will stay at rest or keep moving at a constant velocity if the net force acting on it is zero, according to Newton's first law of motion. If there is no external force acting on the object, it will remain in its current state of motion.
Force is never needed to keep an object moving unless there is an opposite force trying to slow the object.
An object which is moving doesn't need a force to keep it moving.
to keep an object moving the way it is already moving .
That's true. Plus ... even if the forces on an object are BALANCED, it can keep moving forever.
The condition for an object to stay at rest or if moving, keep moving at a constantvelocity is that the sum of forces acting on the object be zero or that no force actson the object.For an object to increase its velocity, in other words to accelerate, there has to bea force acting on the object. The force is the one responsible for the accelerationof the object. Recall Newton's 2nd law of motion:F = m∙awhere 'F' is the force acting on the object with mass 'm', and 'a' is the acceleration the object experiences.Read more: What_are_the_conditions_for_an_object_to_stay_at_rest_to_keep_moving_at_constant_velocity_or_to_move_with_increasing_to_velocity
An object will keep moving if no external force acts upon it to stop or change its motion. In the absence of friction or resistance, an object in motion will continue moving at a constant velocity due to its inertia.