Water Pressure in One Pipe Flowing to Another

AI Thread Summary
The discussion revolves around calculating water pressure and velocity changes in a tapered pipe using Bernoulli's equation. The initial conditions include a larger pipe radius of 0.22 m, a smaller radius of 0.08 m, an initial water velocity of 0.85 m/s, and a pressure of 283,640 Pa. The user attempts to derive the final velocity and pressure using the conservation of energy principle but encounters numerical inaccuracies. A suggestion is made to correctly apply Bernoulli's equation to find the pressure at the smaller pipe section. This approach emphasizes the importance of accurately using fluid dynamics principles in solving such problems.
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Homework Statement



A water pipe tapers down from an initial radius of R1 = 0.22 m1 to a final radius of R2 = 0.08 m1. The water flows at a velocity v1 = 0.85 m1s-1 in the larger section of pipe. The water pressure in the center of the larger section of the pipe is P1 = 283640 Pa. Assume the density of water is 1000 kg1m-3.

Homework Equations



(1) A ∝ r2
(2) p + ½·ρ·v2 + p·g·h = C
(3) A1·v1 = A2·v2

The Attempt at a Solution



I assumed that since the water remains at roughly the same height, and that the only thing changing is the velocity, and that pressure in Bernoulli's equation is conserved, that one should try to compute the velocity from this.

½·ρ·v2 = P1
ρ·v2 = 2·P1
v2 = 2·P1
v = √(2·P1/ρ)

Using Equation 3 in conjunction with the fact that A ∝ r2, I concluded that the final velocity must be (R1)2·√(2·P1/ρ)/(R2)2, however this isn't giving the correct numerical answer. Any thoughts?
 
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You are using Bernoulli's equation incorrectly. Write the equation as

P1 + .5*rho*(V1)^2 = P2 + .5*rho*(V2)^2

and evaluate for P2.
 

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