Can Gibbs law (& combined first and second law of thermodynamics) be used only for a system (and not a control volume ie flow process)?

Question

I was going through a problem related to flow through isentropic nozzle and I realized that the $v\mathrm{d}p$ term in the Gibbs laws, when applied to a nozzle, doesn't turn zero.

$\mathrm{d}h=T\mathrm{d}s+V\mathrm{d}p$ (note: h,T,V,and P are all static quantity)

$V\mathrm{d}p$ is usually called isentropic shaft work, and there is no isentropic shaft work when considering a flow through a nozzle. But if we are considering static quantities (static pressure, temperature etc) then there is a static pressure drop between the inlet and outlet of the nozzle and so the $V\mathrm{d}P$ term cannot be zero, (and so this would mean there is shaft work in nozzle). So I am wondering if the Gibbs law & combined first and second law of thermodynamics can be used only for a system and not to a flow process (and also what the $V\mathrm{d}P$ work mean in the closed syste & in the equation $\mathrm{d}h=T\mathrm{d}s+V\mathrm{d}p$).

[I have applied the SFEE to the nozzle where I have taken the work ,W, (and heat) to be zero and that the total enthalpy remains constant throughout an isentropic nozzle, (given no change in potential energy).]

Answer 1

First of all, the differential of h is Tds+Vdp, not Tds-Vdp.

Secondly, the term Vdp only sometimes represents shaft work, not always.

Thirdly, for a nozzle, one must include not only the change in enthalpy but also the change in kinetic energy of the flowing stream. So, for an isentropic nozzle (involving no shaft work), the SFEE reduces to:$$\Delta(h+\frac{1}{2}u^2)=0$$or $$dh+udu=Vdp+udu=0$$ I hope this answers your questions.

Answer 2

Local equilibrium

If the assumption of local equilibrium (usually exploited to use thermodynamics in fluid mechanics), you can use thermodynamic relations for every fluid particle.

Solution of the problem

It seems to me that you did it right. Let's revisit the problem using integral equations for a fluid in a control volume:

• mass: $\dfrac{d}{dt}\displaystyle \int_V \rho + \oint_S \rho \mathbf{u} \cdot \mathbf{\hat{n}} = 0$
• momentum (not needed here): ...
• total energy: $\dfrac{d}{dt}\displaystyle \int_V \rho e^t + \oint_S \rho e^t \mathbf{u} \cdot \mathbf{\hat{n}} = \int_V \rho \mathbf{g} \cdot \mathbf{u} + \int_V (-p\mathbf{\hat{n}} + \mathbf{s}_n) \cdot \mathbf{u} - \oint_S \mathbf{q} \cdot \mathbf{\hat{n}}$

to be simplified using some assumptions, basically

• steady flow $\frac{d}{dt} \equiv 0$;
• no volume force $\mathbf{g} = \mathbf{0}$;
• negligible viscous stress $\mathbf{s}_n = 0$, negligible heat transfer $\mathbf{q} = 0$, without shock waves and thus isentropic conditions (don't make me prove it here. If needed, look for balance equation for entropy, or Clausius-Duhem condition);
• perfect gas law $P = \rho R T$; for isentropic conditions you get $\dfrac{P}{\rho^\gamma} = const$;
• uniform properties on each section of the nozzle.

The simplified equations read

• mass:

  $\oint_S \rho \mathbf{u} \cdot \mathbf{\hat{n}} = 0 \qquad \rightarrow \qquad \rho_1 A_1 V_1 = \rho_2 A_2 V_2$

• total energy, introducing the definition of total enthalpy $h^t = e^t + \frac{P}{\rho} =\dfrac{1}{2}|\mathbf{u}^2| + e + \frac{P}{\rho}$:

  $\oint_S \rho h^t \mathbf{u} \cdot \mathbf{\hat{n}} = 0 \qquad \rightarrow \qquad \rho_1 A_1 V_1 h^t_1 = \rho_2 A_2 V_2 h^t_2 \qquad \rightarrow \qquad h^t_1 = h^t_2$

and you can use them along with the condition for isentropic transformations $P_1/\rho_1^\gamma = P_2/\rho_2^\gamma$ and the constitutive equation for perfect gases.

Differential form of quasi-1D isentropic equations

Since mass flux is constant through the sections of the nozzle, you can write

$0 = d \dot{m} := \rho A V + \rho dA V + \rho A dV$.

Since $h^t$ is constant, you can use one of the equivalent forms of the following equation

$0 = d h^t = V dV + dh = V dV + de + d\left(\dfrac{P}{\rho}\right) = V dV + \underbrace{de - \left(\dfrac{P}{\rho^2}\right)d\rho}_{= de + P dv = Tds \quad (1^{st} Pr.)} + \dfrac{dP}{\rho} = VdV + Tds + v dP$.

For isentropic flows, where $ds=0$, you get

$VdV + v dP = 0$.