No, why do you say that?housemartin said:so you suggest that at the bottom the tension would be less than at the top?
At the top of the circle, yes, that is correct. Now draw a free body diagram of the obect at the bottom of the circle. You should find that the tension in the string is greater at the bottom.And the fact that both weight and tension acts in same direction doesn't just mean that required centripetal acceleration is gain from both of these forces? So mac=T+mg and T = mv2/r-mg
Tension force in circular motion refers to the force that is exerted on an object as it moves in a circular path. It is a reactive force that is caused by a centripetal force, which is directed towards the center of the circular path.
Tension force in circular motion can be calculated using the formula T = mv²/r, where T is the tension force, m is the mass of the object, v is the speed of the object, and r is the radius of the circular path.
Tension force and centripetal force have an inverse relationship. This means that as the tension force increases, the centripetal force decreases, and vice versa. The centripetal force is the force that causes the object to move in a circular path, while the tension force is a reactive force that balances the centripetal force.
No, tension force in circular motion can never be greater than centripetal force. This is because the tension force is always equal and opposite to the centripetal force, and the centripetal force is required to keep the object moving in a circular path.
Increasing the speed or decreasing the radius will result in an increase in tension force in circular motion. This is because the formula for tension force includes both the speed and radius variables, meaning that any changes in these values will directly affect the tension force.