The direction of tension in a rope always runs both ways and parallel to the rope.
The reaction force to you pulling on a rope is the tension force exerted by the rope in the opposite direction. This tension force is equal in magnitude and opposite in direction to the force you apply to the rope.
The force acting at arrow a is the tension force in the rope. It is responsible for pulling the object in the direction of the rope.
The tension on a rope can be calculated using Newton's second law, which states that the sum of the forces acting on an object is equal to the mass of the object multiplied by its acceleration. By setting up equations for forces in each direction, one can solve for the tension in the rope.
The force exerted by the wall on the rope depends on the tension in the rope. This tension is equal in magnitude but opposite in direction to the force the rope exerts on the wall according to Newton's Third Law.
When people are pulling on a rope, the primary forces acting on them are tension in the rope (the force exerted by the rope on each person pulling) and friction between their feet and the ground (to prevent slipping). Additionally, each person must exert a force in the direction of the pull, counteracting the tension in the rope to move the object.
The reaction force to you pulling on a rope is the tension force exerted by the rope in the opposite direction. This tension force is equal in magnitude and opposite in direction to the force you apply to the rope.
The force acting at arrow a is the tension force in the rope. It is responsible for pulling the object in the direction of the rope.
The tension on a rope can be calculated using Newton's second law, which states that the sum of the forces acting on an object is equal to the mass of the object multiplied by its acceleration. By setting up equations for forces in each direction, one can solve for the tension in the rope.
tension
The force exerted by the wall on the rope depends on the tension in the rope. This tension is equal in magnitude but opposite in direction to the force the rope exerts on the wall according to Newton's Third Law.
When people are pulling on a rope, the primary forces acting on them are tension in the rope (the force exerted by the rope on each person pulling) and friction between their feet and the ground (to prevent slipping). Additionally, each person must exert a force in the direction of the pull, counteracting the tension in the rope to move the object.
A pulling force in a rope is called tension. Tension is the force exerted by a rope when it is pulled taut by two opposing forces.
The tension in the rope at that point is the force pulling in opposite directions at the point where the rope is being held or attached.
In that case (ignoring the weight of the rope, for simplicity), the tension at any point of the rope will also be 100 N.
If both dogs pull the rope with a force of 85N each in opposite directions, the rope will experience a tension of 85N as well. Since the forces are equal and opposite, the rope will not move in either direction.
The tension in the rope will be 100 N, as both forces are pulling on the rope with equal magnitude but in opposite directions. This results in no net force being applied to the rope, maintaining the tension at 100 N.
Assuming you meant two forces, the tension will be 200N.