Calculating pressure within a system at a specific location?

AI Thread Summary
Pressure in a fluid system varies linearly with depth, and calculations for pressure at different points must consider the density of the fluid and the height difference. The pressure at point B was calculated correctly, but the attempt to calculate pressure at point C was flawed due to misunderstanding the influence of the fluid column above it. The pressure at point C should be lower than at point B because it is at a higher elevation, but confusion arose from the presence of air above the water surface at point C. Clarification on the relationship between the water surfaces at points B and C is essential for accurate pressure calculations. Understanding these principles is crucial for correctly determining pressure at various locations within the system.
russiansplash
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Homework Statement


4X2qAHf.png

Solution:
iA4yWXv.png

Homework Equations


dp/dz = -ρh

Pressure varies linearly with the depth.

The Attempt at a Solution



Firstly, I have calculated the pressure at point B.
PB = PA - (0.3m)*(1000kg/m^3)*(9.81m/s^2)
PB = 88057 Pa

Calculating the pressure at point C. However, my attempt is incorrect and I do not understand why I cannot use the pressure at point B to calculate the pressure at point C.

PC = PB - (0.6m)*(1.225kg/m^3)*(9.81m/s^2)
PC = 88049 Pa[/B]

I would appreciate any sort of assistance! Thank you in advance.
 

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I see two solutions, one called the "solution", and another called "The attempt at a solution". Is the first one a solution given to you, along with the problem, or is it a first attempt by you to get a solution?
Let us first state the principles: How did you translate the pressure from one column to the other? For example, in your calculation of pB, which is the same in both solutions, you used a principle, which allowed you to use the extra height of water in the middle column. What is that principle?
 
russiansplash said:
Calculating the pressure at point C. However, my attempt is incorrect and I do not understand why I cannot use the pressure at point B to calculate the pressure at point C.

PC = PB - (0.6m)*(1.225kg/m^3)*(9.81m/s^2)
PC = 88049 Pa

I would appreciate any sort of assistance! Thank you in advance.
You can indeed calculate the pressure at point C, given the pressure at point B. But you need to do it correctly. What was your rationale for writing the equation the way you did? From the diagram, do you expect the pressure at C to be higher than at B or lower than at B?
 
Chestermiller said:
You can indeed calculate the pressure at point C, given the pressure at point B. But you need to do it correctly. What was your rationale for writing the equation the way you did? From the diagram, do you expect the pressure at C to be higher than at B or lower than at B?
Thank you for the speedy response. The pressure at C should be lower as it is at a higher elevation. However, in the provided solution it quotes a value of pressure higher than that of point B. I am probably missing a point but I do not seem to understand how the pressure is higher at C.
 
Chandra Prayaga said:
I see two solutions, one called the "solution", and another called "The attempt at a solution". Is the first one a solution given to you, along with the problem, or is it a first attempt by you to get a solution?
Let us first state the principles: How did you translate the pressure from one column to the other? For example, in your calculation of pB, which is the same in both solutions, you used a principle, which allowed you to use the extra height of water in the middle column. What is that principle?
Sorry for not making it clear, the attached image is the solution to the problem and my attempt was a first attempt. Also, I translated the pressure from one column to the other because at the same elevations the pressure remains constant?
 
russiansplash said:
Thank you for the speedy response. The pressure at C should be lower as it is at a higher elevation. However, in the provided solution it quotes a value of pressure higher than that of point B. I am probably missing a point but I do not seem to understand how the pressure is higher at C.
The pressure at C is higher than at B because the column above the water surface is filled with (very low density) air. So the pressure at C is essentially the pressure at the water surface below C. Is that water surface above B or below B?
 
russiansplash said:
Sorry for not making it clear, the attached image is the solution to the problem and my attempt was a first attempt. Also, I translated the pressure from one column to the other because at the same elevations the pressure remains constant?
The pressure remains constant at a given elevation only if it is the same fluid.
 
Chestermiller said:
The pressure at C is higher than at B because the column above the water surface is filled with (very low density) air. So the pressure at C is essentially the pressure at the water surface below C. Is that water surface above B or below B?
Sorry, I do not understand what you mean by whether the water surface is above or below point B? I cannot get my head around this, could you perhaps provide more guidance? I'd really appreciate it.
 
russiansplash said:
Sorry, I do not understand what you mean by whether the water surface is above or below point B? I cannot get my head around this, could you perhaps provide more guidance? I'd really appreciate it.
Look in the right hand section where C is located. How far above the bottom of the tank is the water surface? How far above the bottom of the tank is the water surface located in the middle section, where point B is located? Is the water surface in the right hand section higher of lower than the water surface in the center section?
 

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