Some steam at `100^(@)C` is passed into `1.1` kg of water constained in a calorimeter of water equivalent 20 gm at `15^(@)C` so that the temperature of the calorimeter and its contained rises to `80^(@)C` What is the mass of steam condensing (in kg).

Steam at 100^(@)C is passed into 1.1 kg of water contained in a calorimeter of water equivalent 0.02kg at 15^(@)C till the temperature of the calorimeter and its content rises to 80^(@)C . What is the mass of steam condensed? Latent heat of steam = 536 cal//g .

Steam at 100^@C is passed into 1.1 kg of water contained in a calorimeter of water equivalent 0.02 kg at 15^@C till the temperature of the calorimeter and its contents rises to 80^@C . The mass of the steam condensed in kilogram is

Steam at 100^@C is passed into 1.1 kg of water contained in a calorimeter of water equivalent 0.02 kg at 15^@C till the temperature of the calorimeter and its contents rises to 80^@C . The mass of the steam condensed in kilogram is

A steam at 100^@C is passed into 1 kg of water contained in a calorimeter of water equivalent 0.2 kg at 9^@C till the temperature of the calorimeter and water in it is increased to 90^@C . Find the mass of steam condensed in kg(S_(w) = 1 cal//g^@C, & L_("steam") = 540 cal//g) .

Steam at 100^@C is passed into a calorimeter of water equivalent 10 g containing 74 cc of water and 10 g of ice at 0^@C . If the temperature of the calorimeter and its contents rises to 5^@C , calculate the amount of steam passed. Latent heat of steam =540 kcal//kg , latent heat of fusion =80 kcal//kg .

In a calorimeter of water equivalent 20 g, water of mass 1.1 kg is taken at 288 K temperature. If steam at temperature 373 K is passed through it and temperature of water increases by 6.5^(@)C then the mass of steam condensed is

2gm of steam condenses when passed through 40 gm of water initially at 25^(@)C . The condensation of steam raises the temperature of water to 54.3^(@)C . What is the latent heat of steam

Steam at 100^(@)C is added slowly to 1400 gm of water at 16^(@)C until the temperature of water is raised to 80^(@)C . The mass of steam required to do this is ( L_(V) = 540 cal/g)

A sphere of alumininum of mass 0.047 kg placed for sufficient time in a vessel containing boling water, so that the sphere is at 100^(@)C . It is then immediately transferred to 0.14 kg copper calorimeter containing 0.25 kg of water at 20^(@) C . The temperature of water rises and attains a steady state at 23^(@)C . calculate the specific heat capacity of aluminum. Specific heat capacity of copper = 0.386 xx 10^(3) J kg^(-1) K^(-1) . Specific heat capacity of water = 4.18 xx 10^(-3) J kg^(-1) K^(-1)

A sphere of aluminium of 0.047 kg is placed for sufficient time in a vessel containing boiling water, so that the sphere is at 100^(@) C. It is then immediately transferred to 0.14 kg copper calorimeter containing 0.25 kg of water at 20^(@) C. The temperature of water rises and attains a steady state at 23^(@) Calculate the specific heat capacity of aluminium. (Give specific heat of copper =0.386xx10^(3)Jkg^(-1)K^(-1)) .