Answer:
Part a: The volume of vessel is 4.7680[tex]m^3[/tex] and total internal energy is 3680 kJ.
Part b: The quality of the mixture is 90.3% or 0.903, temperature is 120 °C and total internal energy is 4660 kJ.
Explanation:
Part a:
As per given data
m=2 kg
T=80 °C =80+273=353 K
Dryness=70% vapour =0.7
From the steam tables at 80 °C
Specific volume of saturated vapours=v_g=3.40527 [tex]m^3/kg[/tex]
Specific volume of saturated liquid=v_f=0.00102 [tex]m^3/kg[/tex]
Now the relation of total specific volume for a specific dryness value is given as
[tex]v=v_f+x(v_g-v_f)[/tex]
Substituting the values give
[tex]v=v_f+x(v_g-v_f)\\v=0.00102+0.7(3.40527-0.00102)\\v_f=2.38399 m^3/kg[/tex]
Now the volume of vessel is given as
[tex]v=\frac{V}{m}\\V=v \times m\\V=2.38399 \times 2\\V=4.7680 m^3[/tex]
So the volume of vessel is 4.7680[tex]m^3[/tex].
Similarly for T=80 and dryness ratio of 0.7 from the table of steam
Pressure=P=47.4 kPa
Specific internal energy is given as u=1840 kJ/kg
So the total internal energy is given as
[tex]u=\frac{U}{m}\\U=u \times m\\U=1840 \times 2\\U=3680 kJ[/tex]
The total internal energy is 3680 kJ.
So the volume of vessel is 4.7680[tex]m^3[/tex] and total internal energy is 3680 kJ.
Part b
Volume of vessel is given as 1.6
mass is given as 2 kg
Pressure is given as 0.2 MPa or 200 kPa
Now the specific volume is given as
[tex]v=\frac{V}{m}\\v=\frac{1.6}{2}\\v=0.8 m^3/kg[/tex]
So from steam tables for Pressure=200 kPa and specific volume as 0.8 gives
Temperature=T=120 °C
Quality=x=0.903 ≈ 90.3%
Specific internal energy =u=2330 kJ/kg
The total internal energy is given as
[tex]u=\frac{U}{m}\\U=u \times m\\U=2330 \times 2\\U=4660 kJ[/tex]
So the quality of the mixture is 90.3% or 0.903, temperature is 120 °C and total internal energy is 4660 kJ.
