It may get crushed, but its center of mass will not accelerate.
Then the objects will move in the direction of the resultant force.
If all forces of an object are balanced, then the motion of the object will remain the same. For instance, if all forces are balanced and if the object is moving, then it will continue to move. If it's still, it will remain still.
If the object accelerates, that means the forces are NOT balanced.
Balanced forces do not bring about any change in motion. If forces are balanced, an object is either at rest, or moving in a straight line at constant velocity.
balanced
The object remain stable in situ
Assuming this is a physics question, when all the forces acting on an object are balanced, the object is in equilibrium. For example, when a car is at a constant velocity, with no acceleration, all the forces are equal.
Balanced forces acting on an object do not change the object's position.
Then the objects will move in the direction of the resultant force.
If the object doesn't move, the forces HAVE TO be balanced. There is no other way.
In that case, the object will accelerate.
balanced forces don't move an object, but unbalanced forces on an object do move
* Balanced: The vector sum of all forces on an object is zero. The object does not accelerate.* Unbalanced: The vector sum of all forces on an object is NOT zero, the object DOES accelerate.
Not at all. The object is at rest only because the forces are balanced.
If all forces of an object are balanced, then the motion of the object will remain the same. For instance, if all forces are balanced and if the object is moving, then it will continue to move. If it's still, it will remain still.
If the forces are balanced they will have no action or the object, if not they will accelerate the object in the resultant direction of the two forces..
An object with balanced forces acting on it is still. An object with unbalanced forces acting on them moves at an non constant velocity. It is possible for an object to have balanced forces acting on it and yet move in a vacuum.