Explanation:
[tex]Given\\V=3ft^3\\T_{1} =300^oF\\T_{L} =400^oF\\P_{L} =200psia\\V_{f} =0.5V[/tex]
We assume kinetic and potential energy changes are negligible and there is no work interactions.
a) Taking tank as a system, The energy balance can be define as
[tex]E_{in}- E_{out}= E_{sys}[/tex]
[tex]m_{i} h_{L} -Q_{out}=m_{2} u_{2}-m_{1} u_{1}[/tex]
The mass balance could be written as
[tex]m_{in}- m_{out}= m_{sys} \\m_{i}= m_{2}- m_{1}[/tex]
The final pressure in the tank could be defined as following
[tex]P_{2} =P_{sat300^oF}[/tex]
from standard steam table we know at
[tex]T_{2}= T_{1}=300^oF\\ P_{2}=67.028psia[/tex]
b)
From steam table at
[tex]T_{1} =300^oF\\v_{1}= v_{g}=6.4663ft^3/lbm\\v_{1}= v_{g}=1099.8Btu/lbm\\ v_{f} =0.01745ft^3/lbm\\v_{f} =269.51Btu/lbm\\[/tex]
[tex]at\\P_{L} =200psia\\T_{L}=400^oF\\h_{L}=1210.9Btu/lbm[/tex]
initial mass in the tank could be define as
[tex]m_{1}=\frac{V}{v_{1} } \\m_{1} =\frac{3}{6.4663} =0.464lbm\\[/tex]
Final mass in the tank could be define as
[tex]m_{2}=\frac{V_{f} }{v_{f} }+\frac{V_{g} }{v_{g} } \\ m_{2} =\frac{1.5}{0.01745} +\frac{1.5}{6.4663} =86.2lbm[/tex]
The amount of steam that has entered the tank
[tex]m_{i}=m_{2}- m_{1}\\ m_{i}=86.2-0.464=85.74lbm[/tex]
c)
The internal energy in final state could be defined as following
[tex]U_{2}=m_{f} u_{f}+ m_{g} u_{g}\\ U_{2} =85.96*269.51+0.232*1099.8=23422Btu\\[/tex]
The heat transfer could be defined as following
[tex]Q_{out}=m_{i} h_{L}+m_{1} u_{1}-m_{2} u_{2}\\ Q_{out}=85.74*1210.9+0.464*1099.8-23422=80910Btu[/tex]
Answer:
A) 67.028 psia
B) 85.728 lbm
C) 80,910.64 Btu
Explanation:
Volume of tank (V) = 3 ft³
Temperature in tank (T1) = 300°F
Temperature in steam Line (TL) = 400°F
Steam pressure in line(PL) = 200 psia
Volume of liquid water (Vf) = 0.5V = 0.5 x 3 = 1.5 ft³
A) From the energy balance equation ;
ΔE(sys) = E(in) - E(out)
Thus, M(i)h(L) - Q(out) = m2u2 - m1u1
Also, the mass balance is given by;
M(in) - M(out) = ΔMsys
Thus the final pressure in the tank (P2) will be equal to the saturated pressure at 300°F temperature.
Thus,looking at the first table i attached,
It is seen that the Pressure P2 at 300°F = 67.028 psia
B) Looking at the first table, at T = 300°F, we have the following ;
v1 = vg = 6.4663 ft³/lbm
u1 = ug = 1099.8 Btu/lbm
vf = 0.01745 ft³/lbm
uf = 269.51 Btu/lbm
From second steam table attached, at P(L) = 200 psia and T(L) = 400 °F
We have; h(L) = 1210.9 Btu/lbm
Initial mass in the tank is gotten by;
m1 = V/v1
Thus, m1 = 3/6.4663 = 0.464 lbm
Ow, let's calculate final mass(m2) ;
m2 = Vf/vf + Vg/vg
Plugging in the relevant values to get ;
m2 = 1.5/0.01745 + 1.5/6.4663 = 85.96 + 0.232 = 86.192 lbm
Hence, the amount of steam that has entered the tank will be;
Mi = M2 - M1 = 86.192 lbm - 0.464 lbm = 85.728 lbm
C) The internal energy in the final state will be given as;
U2 = mfuf + mgug = (85.96 x 269.51) + (0.232 x 1099.8) = 23422.23 Btu
Now, the heat transfer is given as;
Q' = mihL + m1u1 - U2 = (85.74 x 1210.9) + (0.464 x 1099.8) - 23422.23 = 80,910.64 Btu
