The two Femurs each of cross-sectional area `10 cm^(2)` support the upper part of a human body of mass 40 kg .The average pressure sustained by the femurs is (take g =`10 m s^(-2)`)

The two femurs each of cross-sectional area 10 cm^(2) support the upper part of a human body of mass 40 kg. the average pressure sustained by the femurs is (take g=10 ms^(-2))

The two thigh bones (femur bones) each of cross-sectional area 10 cm^(2) support the upper part of a human body of mass 40 kg . Estimate the average pressure sustained by the femurs. g=10m//s^(2)

The two thigh bones (femur bones) each of cross-sectional area 10 cm^(2) support the upper part of a human body of mass 40 kg . Estimate the average pressure sustained by the femurs. g=10m//s^(2)

The two thigh bones each of cross-sectional area 15 cm^(2) support the upper part of a person of mass 70 kg. The pressure sustained by these thigh bones is

A body falls freely for 10 s. Its average velocity during this journey is (Take g = 10 ms^(-2))

A steel rod of cross-sectional area 16 cm^(2) and two brass rods each of cross-sectional area 10 cm^(2) together support a load of 5000 kg as shown in the figure. ( Given, Y_(steel) = 2xx10^(6) kg cm^(-2) and Y_(brass) = 10 ^(6) kg cm^(-2)) . Choose the correct option(s).

Calculate the height through which a body of mass 0.5 kg is lifted if the energy spent in doing so is 10j . Take g = 10 m s^(-2)

What is the weight of a block of mass 10.5 kg ? Take g= 10 m s^(-2)

A crane lifts a mass of 100 kg to a height of 10 m in 20 s. The power of the crane is (Take g = 10 m s^(-2) )

A body of mass 5 kg is taken a height 5 m to 10 m .Find the increase in its potential energy (g=10 m s^(-2) )