Problem with ideal gas law and a spring Help please

AI Thread Summary
The discussion revolves around solving a problem involving the ideal gas law and a spring system in equilibrium. The setup includes a piston separating an ideal gas and a spring, with the goal of finding the spring constant K based on the gas's temperature and other parameters. The key equations used include PV=nRT for the gas and F=-KX for the spring, with the equilibrium condition requiring that the force exerted by the gas equals that of the spring. The final expression derived for K is K=nRT/6L^2, with clarification on the relationship between the gas volume and the spring's natural length. The conversation highlights the importance of correctly linking the gas and spring systems to arrive at the solution.
ml_lulu
Messages
4
Reaction score
0
Problem with ideal gas law and a spring! Help please!

Homework Statement



We have a box divided in two parts by a piston without friction, and in one part there are n moles of an ideal gas and a Spring orf constant K and natural longitude L which keeps the piston in equilibrium. According to this, and knowing that the temperature of the gas is T0, find the amount for K.

Homework Equations



PV=nRT
F=-KX
E=(KX^2)/2

The Attempt at a Solution



I know its (nRTo)/6L^2 because the book has the answers, but I don't know where it came from! Please help!
 
Physics news on Phys.org
what do you know besides eqn. How do we link the two systems?

The common part to both is the piston, so Pressure of the gas multiplied by its area exerts a force on it.

This force must be the same as that exerted by the spring in order for system to be in equilibrium, that is piston is not moving.

Does this help?
 
I forgot to tell that the longitude of the spring in equilibrium is 3L (which means that x=2L, I think?) So, what I did is:

P= F/A
F=-kX
PV=nRT

kX/A=nRT/V

And volume is one, because its an ideal gas, so

K=nRTA/X

K=nRTA/2L

And that's all I know
 
Forget it! I did it :smile: :rolleyes: :-p

F/A*V=nRT
F*L=nRT
kX*L=nRT
K=nRT/X.L
K=nRT/2L*3L
K=nRT/6L^2

Thanks anyways! :)
 
Thanks, I was wondering where the 6 came from :confused:

Thats getting real close,

the importat links are being made:

There is nothing that says ideal gas has volume of 1,
in fact it is 22.4 L for n=1.

what we can say P=nRT/(A*L) where L here is the Length at equilibrium under final condition.

we know that force is P*A=nRT/L

we also know that F=K*L where L is above.

then k=nRT/L^2 now relate the L I used vs that you were given at equilibrium as I had some trouble understanding problem description.
 

Thread 'Errors and significant figures'

I multiplied the values first without the error limit. Got 19.38. rounded it off to 2 significant figures since the given data has 2 significant figures. So = 19. For error I used the above formula. It comes out about 1.48. Now my question is. Should I write the answer as 19±1.5 (rounding 1.48 to 2 significant figures) OR should I write it as 19±1. So in short, should the error have same number of significant figures as the mean value or should it have the same number of decimal places as...
View full post »
Thread 'Collision of a bullet on a rod-string system: query'

Thread 'Collision of a bullet on a rod-string system: query'

In this question, I have a question. I am NOT trying to solve it, but it is just a conceptual question. Consider the point on the rod, which connects the string and the rod. My question: just before and after the collision, is ANGULAR momentum CONSERVED about this point? Lets call the point which connects the string and rod as P. Why am I asking this? : it is clear from the scenario that the point of concern, which connects the string and the rod, moves in a circular path due to the string...
View full post »
Thread 'A cylinder connected to a hanging mass'

Thread 'A cylinder connected to a hanging mass'

Let's declare that for the cylinder, mass = M = 10 kg Radius = R = 4 m For the wall and the floor, Friction coeff = ##\mu## = 0.5 For the hanging mass, mass = m = 11 kg First, we divide the force according to their respective plane (x and y thing, correct me if I'm wrong) and according to which, cylinder or the hanging mass, they're working on. Force on the hanging mass $$mg - T = ma$$ Force(Cylinder) on y $$N_f + f_w - Mg = 0$$ Force(Cylinder) on x $$T + f_f - N_w = Ma$$ There's also...
View full post »

Similar threads

Proof question related to the Ideal Gas Law
Replies
8
Views
2K
Ideal Gas Law and Pressure at 80°C
Replies
2
Views
3K
What would be a real-life example of the ideal gas law?
Replies
3
Views
9K
Calculations using the Ideal Gas Law
Replies
2
Views
2K
Is the Ideal Gas Law Valid for Balloon Problems?
Replies
5
Views
2K
Ideal gas: Temperture at 1 atm
Replies
2
Views
2K
Finding both temperature and the amount of gas added
Replies
6
Views
1K
Closed cycle of an ideal gas
Replies
3
Views
1K
How Does the Ideal Gas Law Apply in Multi-Part Physics Problems?
Replies
14
Views
2K
Mixing two ideal gases with different V, T at constant pressure
Replies
16
Views
3K

Hot Threads

Recent Insights

Back
Top