Formula for Work to create a vacuum.

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    Formula Vacuum Work
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Discussion Overview

The discussion revolves around calculating the work or energy required to create a vacuum, specifically aiming for a 2.5 psi vacuum in a tube using a pneumatic cylinder. Participants explore the theoretical and practical aspects of this calculation, including the necessary formulas and unit conversions.

Discussion Character

  • Technical explanation
  • Mathematical reasoning
  • Debate/contested

Main Points Raised

  • One participant seeks guidance on calculating the energy required to create a vacuum and the power of an electric motor needed for the task.
  • Another participant provides a formula for work as W = dP*V*t, where dP is the pressure difference, V is the volume, and t is time, but later questions the inclusion of time.
  • A participant corrects the formula to W = dP*V, stating that time is not necessary for calculating work.
  • Discussion includes unit conversions, with a participant calculating the volume of a cylinder and applying the pressure difference to derive work in Joules.
  • One participant introduces a more complex model involving the ideal gas law, suggesting that work must account for both the pressure difference and the expansion of gas, leading to a derived formula: W = V * (Pamb - Pnew) + V * Pnew * ln(Pnew/Pamb).
  • Another participant confirms the calculations and clarifies the meaning of the natural logarithm in the context of the work done by expanding gas.
  • Participants discuss the derivation of the equations used, with references to first principles and integrals related to gas expansion.

Areas of Agreement / Disagreement

Participants present varying approaches to calculating work, with some agreeing on the simplified formula while others introduce more complex models involving gas behavior. The discussion remains unresolved regarding the best method to calculate the work required for creating a vacuum.

Contextual Notes

Limitations include assumptions about ideal gas behavior and the need for unit conversions between different measurement systems. The discussion does not resolve the complexities involved in the calculations.

Arnak
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Hi,

Can someone give me some guidance on how to calculate the work or energy required to create a vacuum.

For example, I would like to create a 2.5psi vacuum in a tube of a specific length and diameter using a pneumatic cylinder to remove the air.

How would I go about calculating the energy required to do that please?

From that answer I want to calculate the power of an electric motor required to perform that task.

Thanks,

Arnak
 
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Arnak said:
Hi,

Can someone give me some guidance on how to calculate the work or energy required to create a vacuum.

For example, I would like to create a 2.5psi vacuum in a tube of a specific length and diameter using a pneumatic cylinder to remove the air.

How would I go about calculating the energy required to do that please?

From that answer I want to calculate the power of an electric motor required to perform that task.

Thanks,

Arnak

The work to create difference in pressure is

W = dP*V*t

dP is the pressure difference
V is the volume of the air container
t is the time for what you have achieved the pressure difference

Here the heat transfer is not taken in account.
 
Malverin said:
The work to create difference in pressure is

W = dP*V*t

dP is the pressure difference
V is the volume of the air container
t is the time for what you have achieved the pressure difference

Here the heat transfer is not taken in account.

Why do you need time here ?
 
Hi,

Thanks for that formula.9-))

What units would the work be in please?

Am I right in saying then that with a cylinder of 200 x 50mm V= 10000 mm3

Pressure difference = 2.5psi

So 10000 x 2.5 = 25000 units?Arnak
 
regor60 said:
Why do you need time here ?

I have confused work with power here.

The power is

Power = dP*V / t

so work is only

W = dP*V

My mistake. Sorry
 
Arnak said:
Hi,

Thanks for that formula.9-))

What units would the work be in please?

Am I right in saying then that with a cylinder of 200 x 50mm V= 10000 mm3

Pressure difference = 2.5psi

So 10000 x 2.5 = 25000 units?


Arnak

The formula has to be

W = dP*V

t has no place there. My mistake

in SI system, units are

W => Joules
dP => Pascals
V => m3
 
Malverin said:
The work to create difference in pressure is

W = dP*V*t

dP is the pressure difference
V is the volume of the air container
t is the time for what you have achieved the pressure difference

Not quite.

Consider the ideal case of a cylinder and a piston. You have a volume V of an ideal gas at ambient pressure Pamb and you want to exhaust enough gas to end up with the same volume V at reduced pressure Pnew.

That means that you need to push the piston to exhaust a volume V * (1 - Pnew/Pamb) of gas at ambient pressure. Pushing against atmospheric pressure takes work equal to Pamb * V * (1 - Pnew/Pamb) = V * (Pamb - Pnew)

But this leaves you with a volume V * Pnew/Pamb of gas at ambient pressure with a total volume V available to expand into. That represents work that can be reclaimed. The formula for the work gained with the isothermal expansion of an ideal gas is Vinitial * Pinitial * ln(Pinitial/pfinal). The formula also works if you swap "initial" with "final" and negate the sign.

Putting that together gives you a required work of:

W = V * ( Pamb - Pnew ) + V * Pnew * ln(Pnew/Pamb)

As long as Pnew is lower than Pamb, the second term will be negative, so it subtracts from the work required.

If you are using a coherent system of units such as SI with volume in cubic meters, pressure in Pascals and work in Joules then the formula will work as is. If you are using pounds per square inch and cubic millimeters then some unit conversion factors will be required.
 
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Hi Jbriggs,

Thanks for the input.8-))

So by my calculations :-

W = 0.00001*(101325 - 84088) + 0.00001 * 84088 * ln(84088/101325)

W = 0.87020288682 Joules.

Please excuse my lack of knowledge of algebra but is the component ln the designation for the result of (Pnew/Pamb)?

I have converted the units to Pascals and M3.

V= 0.00001 m3, Pamb = air pressure 101325 Pascals, Reduction of 2.5psi in Pascals =17237

So Pamb(101325) - Reduction of 17237 = Pnew = 84088

Have I got that right so far please?

Can you also advise me where I can find a link to these equations so I can attempt to learn more?

Martin
 
Last edited:
Arnak said:
So by my calculations :-

W = 0.00001*(101325 - 84088) + 0.00001 * 84088 * ln(84088/101325)

W = 0.87020288682 Joules.

Please excuse my lack of knowledge of algebra but is the component ln the designation for the result of (Pnew/Pamb)?

"ln" is natural logarithm. The natural log of 84088/101325 is approximately -0.19

I have converted the units to Pascals and M3.

V= 0.00001 m3, Pamb = air pressure 101325 Pascals, Reduction of 2.5psi in Pascals =17237

So Pamb(101325) - Reduction of 17237 = Pnew = 84088

Have I got that right so far please?
Looks good.

Can you also advise me where I can find a link to these equations so I can attempt to learn more?
The equation for the work done by the (hypothetical) piston pushing out against the ambient atmosphere was trivial. It comes from first principles. You multiply atmospheric pressure by area to get the force on the piston. You multiply force by distance the piston moved to get work done. Work is the product of force (area x pressure) and distance. This can also be expressed as (area x distance) times pressure. Since area x distance = change in volume, it follows that work done is atmospheric pressure times delta V

The equation for the work done by the expanding gas inside the cylinder came from a Google search and is derived in the same way. But the pressure of the expanding gas in the cylinder declines as it expands. So instead of a straight multiple you need an integral. The pressure of the gas decreases as the inverse of the volume, so one is integrating [some multiple of] 1/V and the resulting integral is some multiple of ln(Vfinal) - ln(Vinitial). Equivalently, this is ln(Vfinal/Vinitial)

Google "work done by expanding gas at constant temperature". e.g. http://hyperphysics.phy-astr.gsu.edu/hbase/thermo/isoth.html You'll find any number of derivations. Most of them express the multiplier in terms of moles and Boltzmann's constant, but one can substitute that out with the equation: pV=nRt.

I fiddled with the sign conventions to make sure that the contributions from the two terms were correct.
 
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Hi Jbriggs,

Excellent info, thanks very much.

A bit complex for me but I am getting the hang of it.8-))

Arnak
 

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