If all forces in all direction on an object are equal then a box diagram would show that the forces (newtons, N) will cancel each other out, so it will stay fixed in it's position
If the forces are imbalanced then you can achieve acceleration. So for a car to move it must overcome tyre friction, so heat and noise wastage, air resistance, and all the smaller forces trying to stop the engine moving (mostly friction). Once it produces more force than those require it can move.
No. A balanced group of forces has the same effect on an object as no force at all.
Yes - if the sum of the forces is zero.Yes - if the sum of the forces is zero.Yes - if the sum of the forces is zero.Yes - if the sum of the forces is zero.
No. An object that has no net force on it will simply not be accelerating. It can be in motion, but it can not have any change in its velocity.
If the two forces acting on an object are not lined up, the object will experience a net force that is a combination of the two forces. This will result in the object accelerating in a direction that is a combination of the two forces, based on their magnitudes and directions.
When an object is at terminal velocity, the two forces due to gravity and drag are equal, so the object ceases accelerating. Its motion is constant and vertically downward.
If there are two or more unequal forces acting on an object then the object will be acting on the forces. ^_^
When an object is accelerating, the forces acting on it are unbalanced. This means that there is a net force acting on the object in the direction of its acceleration, causing a change in its velocity.
If you add up all the forces acting on an object, they are balanced if they equal zero. (They cancel each other out). If the forces acting on a object are balanced, then the acceleration of that object is zero. It may still be moving, but it is not accelerating. An object that is not accelerating, (the sum of the forces acting on it is zero), is in equilibrium.
Yes - if the sum of the forces is zero.Yes - if the sum of the forces is zero.Yes - if the sum of the forces is zero.Yes - if the sum of the forces is zero.
The object the forces are acting on will not move, or will be moving at a constant speed (e.g. not accelerating). This is called being in 'equilibrium'.
If the object is not moving, or is traveling at a constant velocity, all forces acting on the object are equal and opposite to each other. If the object is accelerating (speeding up, slowing down, or changing direction) the forces are not balanced.
If an object is not accelerating, it means that the sum of all forces acting on the object is equal to zero. This is in accordance with Newton's first law of motion, which states that an object will remain at rest or in constant motion unless acted upon by an external force.
No. An object that has no net force on it will simply not be accelerating. It can be in motion, but it can not have any change in its velocity.
If you are accelerating, there must be an unbalanced force acting on the object. The net force is what causes acceleration according to Newton's second law, F=ma. If the forces are balanced, then the object will either be at rest or moving at a constant velocity.
If the two forces acting on an object are not lined up, the object will experience a net force that is a combination of the two forces. This will result in the object accelerating in a direction that is a combination of the two forces, based on their magnitudes and directions.
You never know. The only thing you know about the forces on an object that's not accelerating is: They all add up to zero, and their effect on the object is the same as if no forces at all were acting on it. That's the same as saying that all the forces on the object are 'balanced'.
When an object stops accelerating, it either maintains a constant velocity or comes to a complete stop depending on the forces acting upon it. If the net force acting on the object is zero, it will move at a constant velocity. If there is a net force opposing its motion, the object will eventually come to a stop.
what is an essential characteristic of an object in equilibrium