Pressure: pgh vs. pgy Please help me distinguish between the two.

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\rhogh represents gravitational potential energy at a specific point in a fluid column, where "h" indicates the height from the bottom to that point. In contrast, \rhogy measures pressure, accounting for the weight of the fluid above an arbitrary point, making it a true representation of pressure. The distinction is crucial, as \rhogh cannot be used to calculate pressure directly due to its focus on potential energy rather than the weight of the fluid. Bernoulli's equation illustrates how energy can transition between pressure, kinetic, and gravitational potential, maintaining a constant total. Understanding the difference between these two terms is essential for accurately analyzing fluid dynamics.
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Homework Statement



Please help me understand when I should use \rhogh vs. \rhogy.

Homework Equations



P = \rhogy
P =\rhogh

The Attempt at a Solution


(In a uniformly dense solution)

\rhogh is essentially the gravitational potential energy at a specified point in a fluid column. So "h" is taken from the bottom of the fluid to that specified point. It seems like this version of pressure isn't really pressure at all because pressure is dependent on the density (and thus mass) of a fluid.

\rhogy is an actual measure of pressure because it takes into account the mass (and thus the density) of all the fluid above some arbitrary point in the fluid.

Is my understanding correct?
...BTW I don't know calculus...
 
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What are 'y' and 'h' that supposedly make them different?
 
Last edited:
Pengwuino said:
What are 'y' and 'h' that supposedly make them different?

This is what I read about distinguishing the two:

"you definitely can't mix these up - one is gravitational potential energy, and the other is the potential energy due to pressure, which is a result of the weight of fluid, air, etc. pushing down from above.

imagine that you were a water molecule in a bucket, diffusing around. at the top of the bucket, you would have more gravitational potential energy (ρgh), and at the bottom of the bucket, you would have more potential energy from pressure (ρgy)

in bernoulli's equation:
pressure + ½ρv² + ρgh = constant, the point is that energy can be converted between pressure, kinetic, and gravitational potential, but stays the same everywhere.

ρgh by itself cannot be used to calculate pressure, since this is a measure of gravitational potential energy, as compared to some arbitrary reference point. For pressure, you need to know the weight of all of the matter above the point pushing down (think about this: what would the pressure be at the 1 ft dept of a swimming pool when it is filled to 10 ft vs when it is filled to 2 ft - it would be much higher, even though h at that point is the same)

remember that density = mass / volume (ρ = m / V)

ρgh is more-or-less the same thing as potential energy = mgh (that you use for problems on land), and as you should know in those problems, h could be the distance to the floor in the room, the ground outside, sea level, etc. h = 0 only because that it the height defined in the problem as being the bottom point."
 
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