146205 An ice cart of mass \(60 \mathrm{~kg}\) rests on a horizontal snow patch with coefficient of static friction \(\frac{1}{3}\). Assuming that there is no vertical acceleration, find the magnitude of the maximum horizontal force required to move the ice cart.
\(\left(\mathrm{g}=9.8 \mathrm{~ms}^{-2}\right)\)

146206 If a body have kinetic energy \(T\), moving on a rough horizontal surface stops at distance \(y\). The frictional force exerted on the body is

146207 If a ladder weighing \(250 \mathrm{~N}\) is placed against a smooth vertical wall having coefficient of friction between it and floor is 0.3 , then what is the maximum force of friction available at the point of contact between the ladder and the floor?

146208 A body of mass \(M\) is kept on a rough horizontal surface (friction coefficient \(\mu\) ). A person is trying to pull the body by applying a horizontal force but the body is not moving. The force by the horizontal surface on the surface of the body is \(F\), where

146205 An ice cart of mass \(60 \mathrm{~kg}\) rests on a horizontal snow patch with coefficient of static friction \(\frac{1}{3}\). Assuming that there is no vertical acceleration, find the magnitude of the maximum horizontal force required to move the ice cart.
\(\left(\mathrm{g}=9.8 \mathrm{~ms}^{-2}\right)\)

146206 If a body have kinetic energy \(T\), moving on a rough horizontal surface stops at distance \(y\). The frictional force exerted on the body is

146207 If a ladder weighing \(250 \mathrm{~N}\) is placed against a smooth vertical wall having coefficient of friction between it and floor is 0.3 , then what is the maximum force of friction available at the point of contact between the ladder and the floor?

146208 A body of mass \(M\) is kept on a rough horizontal surface (friction coefficient \(\mu\) ). A person is trying to pull the body by applying a horizontal force but the body is not moving. The force by the horizontal surface on the surface of the body is \(F\), where

146205 An ice cart of mass \(60 \mathrm{~kg}\) rests on a horizontal snow patch with coefficient of static friction \(\frac{1}{3}\). Assuming that there is no vertical acceleration, find the magnitude of the maximum horizontal force required to move the ice cart.
\(\left(\mathrm{g}=9.8 \mathrm{~ms}^{-2}\right)\)

146206 If a body have kinetic energy \(T\), moving on a rough horizontal surface stops at distance \(y\). The frictional force exerted on the body is

146207 If a ladder weighing \(250 \mathrm{~N}\) is placed against a smooth vertical wall having coefficient of friction between it and floor is 0.3 , then what is the maximum force of friction available at the point of contact between the ladder and the floor?

146208 A body of mass \(M\) is kept on a rough horizontal surface (friction coefficient \(\mu\) ). A person is trying to pull the body by applying a horizontal force but the body is not moving. The force by the horizontal surface on the surface of the body is \(F\), where

146205 An ice cart of mass \(60 \mathrm{~kg}\) rests on a horizontal snow patch with coefficient of static friction \(\frac{1}{3}\). Assuming that there is no vertical acceleration, find the magnitude of the maximum horizontal force required to move the ice cart.
\(\left(\mathrm{g}=9.8 \mathrm{~ms}^{-2}\right)\)

146206 If a body have kinetic energy \(T\), moving on a rough horizontal surface stops at distance \(y\). The frictional force exerted on the body is

146207 If a ladder weighing \(250 \mathrm{~N}\) is placed against a smooth vertical wall having coefficient of friction between it and floor is 0.3 , then what is the maximum force of friction available at the point of contact between the ladder and the floor?

146208 A body of mass \(M\) is kept on a rough horizontal surface (friction coefficient \(\mu\) ). A person is trying to pull the body by applying a horizontal force but the body is not moving. The force by the horizontal surface on the surface of the body is \(F\), where