Bernoulli's Equation (Solved for p_1, Any Gravity)

$P_1 = P_2 + rho*g*y_2 + 1/2*rho*V_2^2 - rho*g*y_1 - 1/2*rho*V_1^2$

$(rho)"Density"$

$(V_1)"Initial Velocity"$

$(V_2)"Final Velocity"$

$(y_1)"Initial Height"$

$(y_2)"Final Height"$

$(P_2)"Final Pressure"$

$(g)"Acceleration due to Gravity"$

Bernoulli Equation Calculators

The Math / Science

Bernoulli's equation is one of the most important/useful equations in fluid mechanics. Many problems relating to real fluid are analyzed with a form of the Bernoulli equation.

Each of the terms in the equation is expressed with units of energy per unit mass. Note that energy per unit mass is unit equivalent to pressure. In fluid flow, energy per unit mass is known as head. In general, Bernoulli stated that:

1) $P + 1/2 rho * V^2 + rho *g*h = C$ where: C is a constant.

In a combined system with two separate elevations, pressures and velocities as in the diagram above, one can make the following association:

2) $P_1 + 1/2 rho * V_1^2 + rho *g*h_1 = P_2 + 1/2 rho * V_2^2 + rho *g*h_2$

Based on this, the pressure at an elevation can be computed using Bernoulli's formula for pressure (P₁) and re-ordering the terms of equation 2 :

3) $P_1 = 1/2 rho * (V_2^2 -V_1^2) + rho *g* (h_2-h_1) + P_2$

or you can divide both sides of equation 3 by $rho *g$ to get an equivalent expression for $P_1$ , shown as equation 4:

4) $P_1 = ρ*g [(V_2^2 -V_1^2)/(2*g) + (h_2-h_1) + P_2/(ρ*g)]$

where:

P₁ is the pressure at elevation 1 based on Bernoulli's Equation
V₁ is the velocity at elevation 1
h₁ is the height of elevation 1
P₂ is the pressure at elevation 2
V₂ is the velocity at elevation 2
h₂ is the height of elevation 2
ρ is the density of the fluid
g is the acceleration due to gravity

Reference

Young, Hugh and Freeman, Roger. University Physics With Modern Physics. Addison-Wesley, 2008. 12th Edition, (ISBN-13: 978-0321500625 ISBN-10: 0321500628 ) Pg 468, eq 14.17