Closed ended tube resonance problem

[AbsoluteZer0]

Homework Statement

In class a 3 m long aluminum bar was made to resonate by clamping it at a node in the centre of the bar. The frequency heard was 1200Hz.

Homework Equations

L = \frac{n}{4}\lambda

v = f\lambda

The Attempt at a Solution

Knowing that L is 3, we can substitute this into the formula and solve accordingly in order to find wavelength:

3 = \frac{1}{4}\lambda
(4)(3) = \lambda

Which gives us 12m. We can then use the wave equation, substituting 12 and 1200

v = f\lambda
v =(1200)(12)

to arrive at 14400 m s^-1

However, I am lead to believe that I am possibly wrong due to the relatively high value of velocity that I found. Am I wrong? If so, where is my mistake?

Thanks

 

[TSny]

What must be at each end of the rod - a node or an antinode? Rethink the expression for $L$ in terms of $\lambda$.

 

[AbsoluteZer0]

What must be at each end of the rod - a node or an antinode? Rethink the expression for $L$ in terms of $\lambda$.

I believe an antinode at each end, making it an open ended tube.

L = \frac{n}{2}\lambda

L is therefore 6 m, and velocity is therefore 7200 m s^-1

Is this correct?

Thanks,

 

[TSny]

Yes, that looks right to me. (According to a quick check on the internet, 7200 m/s is somewhat high for aluminum. But that's what your data gives.)

 

[AbsoluteZer0]

Thanks