Carbon dioxide (CO2) expands isothermally at steady state with no irreversibilities through a turbine from 10 bar, 500 K to 2 bar. Assuming the ideal gas model and neglecting kinetic and potential energy effects, determine the heat transfer and work, each in kJ per kg of carbon dioxide flowing.

Question

contestada

Respuesta :

potentialsamo potentialsamo · Answer 1 · 2020-05-05T07:21:12+02:00

Answer:

The answer to the question above is = 152.02 KJ/Kg

Explanation:

Given:

Temperature at first state, (T[tex]1[/tex])= 500k

Temperature at second state, (T[tex]2[/tex])= 500k

The above explains an isothermal process as a thermodynamic process,in which the temperature of the system remains constant

Pressure at first state, (p[tex]1[/tex]) = 10 bar

Pressure at second state, (p[tex]2[/tex]) = 2 bar

The heat transfer=

Qrev/m= T x [s(T[tex]2[/tex]) - s(T[tex]1[/tex]) - R ㏑ (p[tex]2[/tex] ÷ p[tex]1[/tex])]

Isothermal means the temperature does not change, while Expansion means the volume has increased.

For the internal isothermal process:

Qrev/m= T x [- R ㏑ (p[tex]2[/tex] ÷ p[tex]1[/tex])]

= 500 x - (8.314 ÷ 44.01) x In (2 ÷ 10) = 152.02 KJ/Kg

Energy equation at turbine is for the internally reversible isothermal process is:

Q-w = m [( (V[tex]2[/tex]²- V[tex]1[/tex]²) ÷ 2) + g ( Z[tex]2[/tex] - Z[tex]1[/tex])]

where w= the most efficient work possible in J

Neglecting the effect of both potential and kinetic energy

(w/ m) = Qrev/ m

= 152.02 KJ/Kg