Is My Calculation for Cylinder and Piston Height Correct?

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The discussion centers on calculating the height of a cylinder with a piston under the influence of an ideal gas. Initial calculations yielded excessively high values for height, prompting concerns about the accuracy. Key errors included neglecting atmospheric pressure in the pressure calculations and miscalculating the volume of the gas. After correcting for atmospheric pressure, a more reasonable height of approximately 3.26 meters was determined, aligning with expected results. The conversation highlights the importance of considering all forces acting on the gas for accurate calculations.
S_fabris
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I think I might have this one right but my answer seems kinda high...can somebody help me out...just to confirm

A vertical cylinder of cross-sectional area 0.045m2 is fitted with a tight-fitting, frictionless piston of mass 6.5kg. The acceleration of gravity is 9.8 m/s2, andthe universal gas constant is 8.31451 J/Kmol.
If there are 4.4mol of an ideal gas in the cylinder at 412 K, determine the height h at which the position is in equilibrium under its own weight (in units of m).

The work I have so far is the following:
Pressure=f x area=(6.5kgx9.81)x(0.045m2)
=2.869N/m2

using PV=nRT I isolated my Volume
V = (4.4mol x 8.3145 x 412K) / 2.869N/m2
= 5253.58 m3

Using this volume inside the cylinder I want to find the height:
h = volume/area
= 5253.58m3 / 0.045m2
= 116 746.22m (this seems kind of high for a height, no?)

I also tried this
Area of cylinder = 2 x pie x r2
isolated my radius then plugged that into V = pie x r2 x h
the height I calculated was 334688.55m (once again pretty high)

I'm assuming my first calculation h= volume/area is a more reliable answer but I just need some assurance as to my answer...it seems pretty high for a cylinder/piston

Thanks
Sergio
 
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Good of you to be suspicious of this answer. Check your pressure calculation.
 
Ah yes Pressure = Force DEVIDED by area...
...long day :P

Thank you OlderDan
Sergio
 
I tried doing the same calculations using the corrected pressure equation and came to the answer of 236.38meters (using height = volume / area) and this isn't the correct answer on the homework service...again is it a formula problem i am having? (i tried the calcs a few times over to make sure)

Anybody? thanks...:)
 
S_fabris said:
I tried doing the same calculations using the corrected pressure equation and came to the answer of 236.38meters (using height = volume / area) and this isn't the correct answer on the homework service...again is it a formula problem i am having? (i tried the calcs a few times over to make sure)

Anybody? thanks...:)
You are ignoring atmospheric pressure. Total pressure on the gas is atmospheric pressure plus the piston pressure.

You can easily see that your volume cannot be right. 4.4 moles at STP would be 4.4 x 22.4 = 98.6 l = .0986 m^3. This is just a little more than atmospheric pressure (about 1.5 kPa above atmospheric pressure which is about 101 kPa).

I get a little more than 3 metres.

AM
 
Last edited:
Perfect, ur right i totally forgot about the atmospheric pressure exerted on the piston...I added 1.013x10^5N/m2 to my calculated pressure ...after all the calcs i got 3.26m which makes MUCH more sense and it is correct :D

thank you all for your patience...
Sergio
 

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