Difference between revisions of "Bernoulli integral"
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''of the equations of hydrodynamics'' | ''of the equations of hydrodynamics'' | ||
− | An integral which determines the pressure | + | An integral which determines the pressure $p$ at each point of a stationary flow of an ideal homogeneous fluid or a barotropic gas $(p=F(\rho))$ in terms of the velocity $\mathbf v$ of the flow at that point and the body force function per unit mass $u(x,y,z)$: |
− | + | \begin{equation}\int\frac{dp}\rho=C-\frac12|\mathbf v|^2+u.\label{1}\end{equation} | |
− | The constant | + | The constant $C$ has a specific value for each flow line and varies from one flow line to another. If the motion is potential, the constant $C$ is the same for the entire flow. |
For a non-stationary flow, the Bernoulli integral (sometimes called the Cauchy–Lagrange integral) holds in the presence of a velocity potential: | For a non-stationary flow, the Bernoulli integral (sometimes called the Cauchy–Lagrange integral) holds in the presence of a velocity potential: | ||
− | + | \begin{equation}\int\frac{dp}\rho=\frac{\partial\phi}{\partial t}-\frac12|\mathbf v|^2+u+f(t),\label{2}\end{equation} | |
where | where | ||
− | + | $$\mathbf v=\grad\phi(x,y,z,t),$$ | |
− | and | + | and $f(t)$ is an arbitrary function of time. |
− | For an incompressible liquid the left-hand sides of equations | + | For an incompressible liquid the left-hand sides of equations \eqref{1} and \eqref{2} are converted to the $p/\rho$ form; for a barotropic gas $(p=F(\rho))$ to the form |
− | + | $$\int\frac{dp}\rho=\int F'(\rho)\frac{dp}\rho.$$ | |
The integral was presented by D. Bernoulli in 1738. | The integral was presented by D. Bernoulli in 1738. |
Latest revision as of 23:29, 24 November 2018
of the equations of hydrodynamics
An integral which determines the pressure $p$ at each point of a stationary flow of an ideal homogeneous fluid or a barotropic gas $(p=F(\rho))$ in terms of the velocity $\mathbf v$ of the flow at that point and the body force function per unit mass $u(x,y,z)$:
\begin{equation}\int\frac{dp}\rho=C-\frac12|\mathbf v|^2+u.\label{1}\end{equation}
The constant $C$ has a specific value for each flow line and varies from one flow line to another. If the motion is potential, the constant $C$ is the same for the entire flow.
For a non-stationary flow, the Bernoulli integral (sometimes called the Cauchy–Lagrange integral) holds in the presence of a velocity potential:
\begin{equation}\int\frac{dp}\rho=\frac{\partial\phi}{\partial t}-\frac12|\mathbf v|^2+u+f(t),\label{2}\end{equation}
where
$$\mathbf v=\grad\phi(x,y,z,t),$$
and $f(t)$ is an arbitrary function of time.
For an incompressible liquid the left-hand sides of equations \eqref{1} and \eqref{2} are converted to the $p/\rho$ form; for a barotropic gas $(p=F(\rho))$ to the form
$$\int\frac{dp}\rho=\int F'(\rho)\frac{dp}\rho.$$
The integral was presented by D. Bernoulli in 1738.
References
[1] | L.M. Milne-Thomson, "Theoretical hydrodynamics" , Macmillan (1950) |
Bernoulli integral. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Bernoulli_integral&oldid=18421