A liquid of denisty ` 850kgm^(-3)` flows through a calorimeter at the rate of `8xx10^(-6)` cubic metre per second. Heat is supplied by mean of a 250- watts electric heating coil and a temperature difference of `15^(@)C` is established in steady state conditioins betweenthe inflow adn outflow. Find the specific heat capacity of the liquid.

A "flow calorimeter" is used to measure the specific heat of a liquid. Heat is added at a known rate to a stream of the liquid as it passes through the calorimeter at known rate, then a measurement of the resulting temperature difference between the in flow and the out flow points of the liquid stream enables us to compute the specific heat of the liquid. A liquid of density 0.85 g//cm^(3) flows through a calorimeter at the rate of 8.0 cm^(3)//s . heat is added by means of a 250 watt electric heating coil, and a temperature difference of 15^(@)C is established in steady state conditions between the in flow and out flow points. Q. Rate of heat absorption per unit specific heat capacity is

A "flow calorimeter" is used to measure the specific heat of a liquid. Heat is added at a known rate to a stream of the liquid as it passes through the calorimeter at known rate, then a measurement of the resulting temperature difference between the in flow and the out flow points of the liquid stream enables us to compute the specific heat of the liquid. A liquid of density 0.85 g//cm^(3) flows through a calorimeter at the rate of 8.0 cm^(3)//s . heat is added by means of a 250 watt electric heating coil, and a temperature difference of 15^(@)C is established in steady state conditions between the in flow and out flow points. Q. Specific heat of the liquid is

A liquid of density 0.85 g//cm^(3) flows through a calorimeter at the rate of 8.0 cm^(2)//s . Heat is added by means of a 250 W electric heating coil and a temperature difference of 15^@C is established in steady state conditions between the inflow and the outflow points of the liquid. The specific heat for the liquid will be

A "flow calorimeter" is used to measure the specific heat of a liquid. Heat is added at a known rate to a stream of the liquid as it passes through the calorimeter at known rate, then a measurement of the resulting temperature difference between the in flow and the out flow points of the liquid stream enables us to compute the specific heat of the liquid. A liquid of density 0.85 g//cm^(3) flows through a calorimeter at the rate of 8.0 cm^(3)//s . heat is added by means of a 250 watt electric heating coil, and a temperature difference of 15^(@)C is established in steady state conditions between the in flow and out flow points. Q. Rate of heat added per second is

The volume of a mixture of ice and water is found to decrease by 0.125xx10^(-6)m^(3) without change in temperature when 10xx10^(-3)kg of a metal at 100^(@)C is immersed into it. The relative density of ice is 0.917 . Find the specific heat capacity of the metal.

A liquid having mass m = 250 g is kept warm in a vessel by use of an electric heater. The liquid is maintained at 50^(@)C when the power supplied by heater is 30 watt and surrounding temperature is 20^(@)C . As the heater is switched off, the liquid starts cooling and it was observed that it took 10 second for temperature to fall down from 40^(@)C to 39.9^(@)C . Calculate the specific heat capacity of the liquid. Assume Newton’s law of cooling to be applicable.

Water flows at the rate of 0.1500 kg//min through a tube and is heated by a heater dissipating 25.2W . The inflow and outflow water temperatures are 15.2^@C and 17.4^@C , respectively. When the rate of flow is increased to 0.2318 kg//min and the rate of heating to 37.8W , the inflow and outflow temperature are unaltered. Find i. the specific heat capacity of water ii. the rate of loss of heat from the tube.