Consider a container of fluid at rest with a Cartesian coordinate defined as positive downward and the origin located at the surface of the fluid (Fig. 8.3). Find the hydrostatic pressure p at the depth h.
Question 8.2: Consider a container of fluid at rest with a Cartesian coord...
From Eqs. (8.36), (8.40), and (8.42), with g=+\rho g\hat{j}, given the downward oriented coordinate direction, we have
-\frac{\partial p}{\partial x}+\mu \triangledown ^{2}\nu _{x}+\rho g_{x}=\rho a_{x}. (8.36)
-\frac{\partial p}{\partial y}+\mu \triangledown ^{2}\nu _{y}+\rho g_{y}=\rho a_{y}. (8.40)
-\frac{\partial p}{\partial z}+\mu \triangledown ^{2}\nu _{z}+\rho g_{z}=\rho a_{z}. (8.42)
-\frac{\partial p}{\partial x}+0=0, -\frac{\partial p}{\partial y}+\rho g=0, -\frac{\partial p}{\partial z}+0=0.
From the first and third equations, p=p( y) at most, and the partial derivative becomes an ordinary derivative. Solving by integration,
\frac{dp}{dy}=\rho g\rightarrow \int{\frac{d}{dy} }(p)dy=\int{\rho g dy}and, consequently, we have FIGURE 8.3 Determination of the pressure as a function of depth in a static fluid. Fundamental Balance Relations
p(y)=\rho gy+c.The integration constant c is found from the boundary conditions. Here, note that the so-called gauge pressure is defined as the absolute pressure minus atmospheric pressure. If we assume an atmospheric pressure at the surface, then p(y=0)=0(gauge) and c=0. Thus, p(y)=\rho gy. At y=h, therefore, we obtain the well-known result that p=\rho gh at depth h (that pressure increases with depth is easily appreciated as we swim deeper in a pool). In a sense, then, this is a solution of the Navier–Stokes equation. Because of the importance and utility of the Navier–Stokes equation, much of Chap. 9 is devoted to its solution.
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