Governing equations on differential form: Difference between revisions

Revision as of 17:38, 31 March 2026

The Differential Equations on Conservation Form

Conservation of Mass

The continuity equation on integral form reads

\frac{d}{d t} \underset{Ω}{∭} ρ d V + \iint_{\partial Ω} ρ 𝐯 \cdot 𝐧 d S = 0

Apply Gauss's divergence theorem on the surface integral gives

\iint_{\partial Ω} ρ 𝐯 \cdot 𝐧 d S = \underset{Ω}{∭} \nabla \cdot (ρ 𝐯) d V

(Eq. 2.32)

Also, if $Ω$ is a fixed control volume

\frac{d}{d t} \underset{Ω}{∭} ρ d V = \underset{Ω}{∭} \frac{\partial ρ}{\partial t} d V

(Eq. 2.33)

The continuity equation can now be written as a single volume integral.

\underset{Ω}{∭} [\frac{\partial ρ}{\partial t} + \nabla \cdot (ρ 𝐯)] d V = 0

(Eq. 2.34)

$Ω$ is an arbitrary control volume and thus

\frac{\partial ρ}{\partial t} + \nabla \cdot (ρ 𝐯) = 0

(Eq. 2.35)

which is the continuity equation on partial differential form.

Conservation of Momentum

The momentum equation on integral form reads

\frac{d}{d t} \underset{Ω}{∭} ρ 𝐯 d V + \iint_{\partial Ω} [(ρ 𝐯 \cdot 𝐧) 𝐯 + p 𝐧] d S = \underset{Ω}{∭} ρ 𝐟 d V

As for the continuity equation, the surface integral terms are rewritten as volume integrals using Gauss's divergence theorem.

\iint_{\partial Ω} (ρ 𝐯 \cdot 𝐧) 𝐯 d S = \underset{Ω}{∭} \nabla \cdot (ρ 𝐯 𝐯) d V

(Eq. 2.36)

\iint_{\partial Ω} p 𝐧 d S = \underset{Ω}{∭} \nabla p d V

(Eq. 2.37)

Also, if $Ω$ is a fixed control volume

\frac{d}{d t} \underset{Ω}{∭} ρ 𝐯 d V = \underset{Ω}{∭} \frac{\partial}{\partial t} (ρ 𝐯) d V

(Eq. 2.38)

The momentum equation can now be written as one single volume integral

\underset{Ω}{∭} [\frac{\partial}{\partial t} (ρ 𝐯) + \nabla \cdot (ρ 𝐯 𝐯) + \nabla p - ρ 𝐟] d V = 0

(Eq. 2.39)

$Ω$ is an arbitrary control volume and thus

\frac{\partial}{\partial t} (ρ 𝐯) + \nabla \cdot (ρ 𝐯 𝐯) + \nabla p = ρ 𝐟

(Eq. 2.40)

which is the momentum equation on partial differential form

Conservation of Energy

The energy equation on integral form reads

\frac{d}{d t} \underset{Ω}{∭} ρ e_{o} d V + \iint_{\partial Ω} ρ h_{o} (𝐯 \cdot 𝐧) d S =

\underset{Ω}{∭} ρ 𝐟 \cdot 𝐯 d V + \underset{Ω}{∭} \dot{q} ρ d V

Gauss's divergence theorem applied to the surface integral term in the energy equation gives

\iint_{\partial Ω} ρ h_{o} (𝐯 \cdot 𝐧) d S = \underset{Ω}{∭} \nabla \cdot (ρ h_{o} 𝐯) d V

(Eq. 2.41)

Fixed control volume

\frac{d}{d t} \underset{Ω}{∭} ρ e_{o} d V = \underset{Ω}{∭} \frac{\partial}{\partial t} (ρ e_{o}) d V

(Eq. 2.42)

The energy equation can now be written as

\underset{Ω}{∭} [\frac{\partial}{\partial t} (ρ e_{o}) + \nabla \cdot (ρ h_{o} 𝐯) - ρ 𝐟 \cdot 𝐯 - \dot{q} ρ] d V = 0

(Eq. 2.43)

$Ω$ is an arbitrary control volume and thus

\frac{\partial}{\partial t} (ρ e_{o}) + \nabla \cdot (ρ h_{o} 𝐯) = ρ 𝐟 \cdot 𝐯 + \dot{q} ρ

(Eq. 2.44)

which is the energy equation on partial differential form

Summary

The governing equations for compressible inviscid flow on partial differential form:

\frac{\partial ρ}{\partial t} + \nabla \cdot (ρ 𝐯) = 0

(Eq. 2.45)

\frac{\partial}{\partial t} (ρ 𝐯) + \nabla \cdot (ρ 𝐯 𝐯) + \nabla p = ρ 𝐟

(Eq. 2.46)

\frac{\partial}{\partial t} (ρ e_{o}) + \nabla \cdot (ρ h_{o} 𝐯) = ρ 𝐟 \cdot 𝐯 + \dot{q} ρ

(Eq. 2.47)

The Differential Equations on Non-Conservation Form

The Substantial Derivative

The substantial derivative operator is defined as

\frac{D}{D t} = \frac{\partial}{\partial t} + 𝐯 \cdot \nabla

(Eq. 2.48)

where the first term of the right hand side is the local derivative and the second term is the convective derivative.

Conservation of Mass

If we apply the substantial derivative operator to density we get

\frac{D ρ}{D t} = \frac{\partial ρ}{\partial t} + 𝐯 \cdot \nabla ρ

(Eq. 2.49)

From before we have the continuity equation on differential form as

\frac{\partial ρ}{\partial t} + \nabla \cdot (ρ 𝐯) = 0

(Eq. 2.50)

which can be rewritten as

\frac{\partial ρ}{\partial t} + ρ (\nabla \cdot 𝐯) + 𝐯 \cdot \nabla ρ = 0

(Eq. 2.51)

and thus

\frac{D ρ}{D t} + ρ (\nabla \cdot 𝐯) = 0

(Eq. 2.52)

Eq. 2.52 says that the mass of a fluid element with a fixed set of fluid particles is constant as the element moves in space.

Conservation of Momentum

We start from the momentum equation on differential form derived above

\frac{\partial}{\partial t} (ρ 𝐯) + \nabla \cdot (ρ 𝐯 𝐯) + \nabla p = ρ 𝐟

(Eq. 2.53)

Expanding the first and the second terms gives

ρ \frac{\partial 𝐯}{\partial t} + 𝐯 \frac{\partial ρ}{\partial t} + ρ 𝐯 \cdot \nabla 𝐯 + 𝐯 (\nabla \cdot ρ 𝐯) + \nabla p = ρ 𝐟

(Eq. 2.54)

Collecting terms, we can identify the substantial derivative operator applied to the velocity vector and the continuity equation.

ρ \underset{= \frac{D 𝐯}{D t}}{\underset{⏟}{[\frac{\partial 𝐯}{\partial t} + 𝐯 \cdot \nabla 𝐯]}} + 𝐯 \underset{= 0}{\underset{⏟}{[\frac{\partial ρ}{\partial t} + \nabla \cdot ρ 𝐯]}} + \nabla p = ρ 𝐟

(Eq. 2.55)

which gives us the non-conservation form of the momentum equation

\frac{D 𝐯}{D t} + \frac{1}{ρ} \nabla p = 𝐟

(Eq. 2.56)

Conservation of Energy

The last equation on non-conservation differential form is the energy equation. We start by rewriting the energy equation on differential form (Eqn. \ref{eq:governing:energy:pde}), repeated here for convenience

\frac{\partial}{\partial t} (ρ e_{o}) + \nabla \cdot (ρ h_{o} 𝐯) = ρ 𝐟 \cdot 𝐯 + \dot{q} ρ

(Eq. 2.57)

Total enthalpy, $h_{o}$ , is replaced with total energy, $e_{o}$

h_{o} = e_{o} + \frac{p}{ρ}

(Eq. 2.58)

which gives

\frac{\partial}{\partial t} (ρ e_{o}) + \nabla \cdot (ρ e_{o} 𝐯) + \nabla \cdot (p 𝐯) = ρ 𝐟 \cdot 𝐯 + \dot{q} ρ

(Eq. 2.59)

Expanding the two first terms as

ρ \frac{\partial e_{o}}{\partial t} + e_{o} \frac{\partial ρ}{\partial t} + ρ 𝐯 \cdot \nabla e_{o} + e_{o} \nabla \cdot (ρ 𝐯) + \nabla \cdot (p 𝐯) = ρ 𝐟 \cdot 𝐯 + \dot{q} ρ

(Eq. 2.60)

Collecting terms, we can identify the substantial derivative operator applied on total energy, $D e_{o} / D t$ and the continuity equation

ρ \underset{= \frac{D e_{o}}{D t}}{\underset{⏟}{[\frac{\partial e_{o}}{\partial t} + 𝐯 \cdot \nabla e_{o}]}} + e_{o} \underset{= 0}{\underset{⏟}{[\frac{\partial ρ}{\partial t} + \nabla \cdot (ρ 𝐯)]}} + \nabla \cdot (p 𝐯) = ρ 𝐟 \cdot 𝐯 + \dot{q} ρ

(Eq. 2.61)

and thus we end up with the energy equation on non-conservation differential form

ρ \frac{D e_{o}}{D t} + \nabla \cdot (p 𝐯) = ρ 𝐟 \cdot 𝐯 + \dot{q} ρ

(Eq. 2.62)

Summary

Continuity:

\frac{D ρ}{D t} + ρ (\nabla \cdot 𝐯) = 0

(Eq. 2.63)

Momentum:

\frac{D 𝐯}{D t} + \frac{1}{ρ} \nabla p = 𝐟

(Eq. 2.64)

Energy:

ρ \frac{D e_{o}}{D t} + \nabla \cdot (p 𝐯) = ρ 𝐟 \cdot 𝐯 + \dot{q} ρ

(Eq. 2.65)

Alternative Forms of the Energy Equation

Internal Energy Formulation

Total internal energy is defined as

e_{o} = e + \frac{1}{2} 𝐯 \cdot 𝐯

(Eq. 2.66)

Inserted in Eqn. \ref{eq:governing:energy:non}, this gives

ρ \frac{D e}{D t} + ρ 𝐯 \cdot \frac{D 𝐯}{D t} + \nabla \cdot (p 𝐯) = ρ 𝐟 \cdot 𝐯 + \dot{q} ρ

(Eq. 2.67)

Now, let's replace the substantial derivative $D 𝐯 / D t$ using the momentum equation on non-conservation form (Eqn. \ref{eq:governing:mom:non}).

ρ \frac{D e}{D t} - 𝐯 \cdot \nabla p + ρ 𝐟 \cdot 𝐯 + \nabla \cdot (p 𝐯) = ρ 𝐟 \cdot 𝐯 + \dot{q} ρ

(Eq. 2.68)

Now, expand the term $\nabla \cdot (p 𝐯)$ gives

ρ \frac{D e}{D t} - 𝐯 \cdot \nabla p + 𝐯 \cdot \nabla p + p (\nabla \cdot 𝐯) = \dot{q} ρ \Rightarrow ρ \frac{D e}{D t} + p (\nabla \cdot 𝐯) = \dot{q} ρ

(Eq. 2.69)

Divide by $ρ$

\frac{D e}{D t} + \frac{p}{ρ} (\nabla \cdot 𝐯) = \dot{q}

(Eq. 2.70)

Conservation of mass gives

\frac{D ρ}{D t} + ρ (\nabla \cdot 𝐯) = 0 \Rightarrow \nabla \cdot 𝐯 = - \frac{1}{ρ} \frac{D ρ}{D t}

(Eq. 2.71)

Insert in Eqn. \ref{eq:governing:energy:non:b}

\frac{D e}{D t} - \frac{p}{ρ^{2}} \frac{D ρ}{D t} = \dot{q} \Rightarrow \frac{D e}{D t} + p \frac{D}{D t} (\frac{1}{ρ}) = \dot{q}

(Eq. 2.72)

\frac{D e}{D t} + p \frac{D ν}{D t} = \dot{q}

(Eq. 2.73)

Compare with the first law of thermodynamics: $d e = δ q - δ w$

Enthalpy Formulation

h = e + \frac{p}{ρ} \Rightarrow \frac{D h}{D t} = \frac{D e}{D t} + \frac{1}{ρ} \frac{D p}{D t} + p \frac{D}{D t} (\frac{1}{ρ})

(Eq. 2.74)

with $D e / D t$ from Eqn. \ref{eq:governing:energy:non:b}

\frac{D h}{D t} = \dot{q} - p \frac{D}{D t} (\frac{1}{ρ}) + \frac{1}{ρ} \frac{D p}{D t} + p \frac{D}{D t} (\frac{1}{ρ})

(Eq. 2.75)

\frac{D h}{D t} = \dot{q} + \frac{1}{ρ} \frac{D p}{D t}

(Eq. 2.76)

Total Enthalpy Formulation

h_{o} = h + \frac{1}{2} 𝐯 𝐯 \Rightarrow \frac{D h_{o}}{D t} = \frac{D h}{D t} + 𝐯 \cdot \frac{D 𝐯}{D t}

(Eq. 2.77)

From the momentum equation (Eqn. \ref{eq:governing:mom:non})

\frac{D 𝐯}{D t} = 𝐟 - \frac{1}{ρ} \nabla p

(Eq. 2.78)

which gives

\frac{D h_{o}}{D t} = \frac{D h}{D t} + 𝐯 \cdot 𝐟 - \frac{1}{ρ} 𝐯 \cdot \nabla p

(Eq. 2.79)

Inserting $D h / D t$ from Eqn. \ref{eq:governing:energy:non:c} gives

\frac{D h_{o}}{D t} = \dot{q} + \frac{1}{ρ} \frac{D p}{D t} + 𝐯 \cdot 𝐟 - \frac{1}{ρ} 𝐯 \cdot \nabla p = \frac{1}{ρ} [\frac{D p}{D t} - 𝐯 \cdot \nabla p] + \dot{q} + 𝐯 \cdot 𝐟

(Eq. 2.80)

The substantial derivative operator applied to pressure

\frac{D p}{D t} = \frac{\partial p}{\partial t} + 𝐯 \cdot \nabla p

(Eq. 2.81)

and thus

\frac{D p}{D t} - 𝐯 \cdot \nabla p = \frac{\partial p}{\partial t}

(Eq. 2.82)

which gives

\frac{D h_{o}}{D t} = \frac{1}{ρ} \frac{\partial p}{\partial t} + \dot{q} + 𝐯 \cdot 𝐟

(Eq. 2.83)

If we assume adiabatic flow without body forces

\frac{D h_{o}}{D t} = \frac{1}{ρ} \frac{\partial p}{\partial t}

(Eq. 2.84)

If we further assume the flow to be steady state we get

\frac{D h_{o}}{D t} = 0

(Eq. 2.85)

This means that in a steady-state adiabatic flow without body forces, total enthalpy is constant along a streamline.

@@ Line 24: / Line 24: @@
 {{NumEqn|<math>
 \frac{d}{dt}\iiint_{\Omega} \rho dV+\iint_{\partial \Omega}\rho \mathbf{v}\cdot \mathbf{n} dS=0
-</math>|nonumber=1}}
+</math>|nonumber=1|border=1|background-color=whitesmoke|padding=2em}}
 Apply Gauss's divergence theorem on the surface integral gives
@@ Line 30: / Line 30: @@
 {{NumEqn|<math>
 \iint_{\partial \Omega}\rho \mathbf{v}\cdot \mathbf{n} dS=\iiint_{\Omega}\nabla\cdot(\rho\mathbf{v})dV
-</math>|number=5.34|spar=1|prefix=ekv.|border=1|padding=2em}}
+</math>}}
 Also, if <math>\Omega</math> is a fixed control volume
@@ Line 59: / Line 58: @@
 {{NumEqn|<math>
 \frac{d}{dt}\iiint_{\Omega} \rho \mathbf{v} dV+\iint_{\partial \Omega} \left[(\rho\mathbf{v}\cdot\mathbf{n})\mathbf{v}+p\mathbf{n}\right]dS=\iiint_{\Omega}\rho \mathbf{f}dV
-</math>|nonumber=1}}
+</math>|nonumber=1|border=1|background-color=whitesmoke|padding=2em}}
 As for the continuity equation, the surface integral terms are rewritten as volume integrals using Gauss's divergence theorem.
@@ Line 97: / Line 96: @@
 {{NumEqn|<math>
 \frac{d}{dt}\iiint_{\Omega}\rho e_o dV+\iint_{\partial \Omega}\rho h_o(\mathbf{v}\cdot\mathbf{n})dS=</math><br><br><math>\iiint_{\Omega}\rho\mathbf{f}\cdot\mathbf{v}dV+\iiint_{\Omega} \dot{q}\rho dV
-</math>|nonumber=1}}
+</math>|nonumber=1|border=1|background-color=whitesmoke|padding=2em}}
 Gauss's divergence theorem applied to the surface integral term in the energy equation gives

Governing equations on differential form: Difference between revisions

Revision as of 17:38, 31 March 2026

Contents

The Differential Equations on Conservation Form

Conservation of Mass

Conservation of Momentum

Conservation of Energy

Summary

The Differential Equations on Non-Conservation Form

The Substantial Derivative

Conservation of Mass

Conservation of Momentum

Conservation of Energy

Summary

Alternative Forms of the Energy Equation

Internal Energy Formulation

Enthalpy Formulation

Total Enthalpy Formulation

Navigation menu

Governing equations on differential form: Difference between revisions

Revision as of 17:38, 31 March 2026

The Differential Equations on Conservation Form

Conservation of Mass

Conservation of Momentum

Conservation of Energy

Summary

The Differential Equations on Non-Conservation Form

The Substantial Derivative

Conservation of Mass

Conservation of Momentum

Conservation of Energy

Summary

Alternative Forms of the Energy Equation

Internal Energy Formulation

Enthalpy Formulation

Total Enthalpy Formulation

Navigation menu

Search