in the same condition what happens to the net force acting on the rope
In the same condition, the net force on the rope becomes zero when the pulls are equal in size and opposite in direction, so the rope does not accelerate and stays in balance.
Understanding the situation
When you see a question like
“ In the same condition, what happens to the net force acting on the rope? ”
it usually refers to a tug-of-war or a rope being pulled from both ends with
equal forces.
- If both sides pull with the same force in opposite directions , the forces cancel.
- Because they cancel, the net force on the rope is zero.
- With zero net force, the rope is either at rest or moves with constant velocity (no acceleration).
Balanced vs unbalanced forces (rope example)
- Balanced forces :
- Example: Two students pull a rope, 50 N left and 50 N right.
- Result: Net force = 50 N − 50 N = 0 N, so the rope does not speed up in either direction.
- Unbalanced forces :
- Example: One side pulls with 60 N, the other with 40 N.
- Result: Net force = 20 N toward the stronger side, so the rope accelerates that way.
Inside the rope, there is tension , but these internal forces are equal and opposite at each small segment, so they cancel when you talk about the net force on the whole rope.
Mini story illustration
Imagine a tug-of-war in school:
- Team A pulls the rope to the left with 300 N.
- Team B pulls to the right with 300 N.
Even though everyone feels the rope is tight and “the pull is strong,” the net force on the rope is still zero , because 300 N left and 300 N right cancel each other.
That is why the rope can stay almost motionless, even under heavy tension.
Short answer (TL;DR)
In the same condition (equal pulls on both ends of the rope), the net force on the rope is zero , so the rope is in equilibrium and does not accelerate.
Information gathered from public forums or data available on the internet and portrayed here.