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21 January, 04:40

Water flowing at the rate of 13.85 kg/s is to be heated from 54.5 to 87.8°C in a heat exchanger by 54 to 430 kg/h of hot gas flowing counterflow and entering at 427°C (cpm = 1.005 kJ/kg · K). The overall Uo = 69.1 W/m^2. K. Calculate the exit-gas temperature and the heat-transfer area.

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  1. 21 January, 04:44
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    => 572.83 K (299.83°C).

    => 95.86 m^2.

    Explanation:

    Parameters given are; Water flowing = 13.85 kg/s, temperature of water entering = 54.5°C and the temperature of water going out = 87.8°C, gas flow rate 54,430 kg/h (15.11 kg/s). Temperature of gas coming in = 427°C = 700K, specific heat capacity of hot gas and water = 1.005 kJ / kg. K and 4.187 KJ/kg. K, overall heat transfer coefficient = Uo = 69.1 W/m^2. K.

    Hence;

    Mass of hot gas * specific heat capacity of hot gas * change in temperature = mass of water * specific heat capacity of water * change in temperature.

    15.11 * 1.005 (700K - x) = 13.85 * 4.187 (33.3).

    If we solve for x, we will get the value of x to be;

    x = 572.83 K (2.99.83°C).

    x is the temperature of the exit gas that is 572.83 K (299.83°C).

    (b). ∆T = 339.2 - 245.33/ln (339.2/245.33).

    ∆T = 93.87/ln 1.38.

    ∆T = 291.521K.

    Heat transfer rate = 15.11 * 1.005 * 10^3 (700 - 572.83) = 1931146.394.

    heat-transfer area = 1931146.394/69.1 * 291.521.

    heat-transfer area = 95.86 m^2.
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