Answer:
[tex]Q_{in}=146.22kW[/tex]
Explanation:
Hello,
In this case, the energy balance for the given uninsulated diffuser is:
[tex]m_{in}h_{in}+m_{in}\frac{v_{in}^2}{2}+Q_{in} =m_{out}h_{out}+m_{out}\frac{v_{out}^2}{2}[/tex]
Thus, we shall remember that the inlet mass equals the outlet mass and the outlet velocity is negligible, for that reason we obtain:
[tex]mh_{in}+m\frac{v_{in}^2}{2}+Q_{in} =mh_{out}[/tex]
Hence, solving for the heat, we need the enthalpy at the inlet, which at 120°C for a liquid-vapor mixture results:
[tex]h_{in}=503.81\frac{kJ}{kg} +0.55*2202.1\frac{kJ}{kg}=1714.965\frac{kJ}{kg}[/tex]
Moreover, at 120 °C the outlet enthlapy as saturated steam is:
[tex]2706.0\frac{kJ}{kg}[/tex]
(Values extracted from Cengel, Thermodynamics 7th edition). In such a way, the required heat inlet is:
[tex]Q_{in}=m(h_{out}-h_{in}-\frac{v_{in}^2}{2})=0.15\frac{kg}{s}(2706.0\frac{kJ}{kg}-1714.965\frac{kJ}{kg}-\frac{(180m/s)^2}{2*1000})[/tex]
[tex]Q_{in}=146.22kW[/tex]
Notice that the term having the velocity should be divided by 1000 to obtain it in kJ/kg.
Best regards.
