Formula relating thickness of pipe to fundamental frequency

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Homework Help Overview

The discussion revolves around the relationship between the thickness of a closed pipe and its fundamental frequency. The original poster seeks a formula that incorporates wall thickness along with other factors like length, temperature, and speed of sound to determine the resonant frequency of a closed pipe.

Discussion Character

  • Exploratory, Conceptual clarification, Problem interpretation

Approaches and Questions Raised

  • Participants discuss the effects of wall thickness on the fundamental frequency and explore whether it influences the resonant frequencies of both the air column and the pipe walls. There are inquiries about the nature of vibrations being considered and the methods used to measure frequencies.

Discussion Status

The conversation is ongoing, with participants sharing insights about the interaction between air column vibrations and wall vibrations. Some have provided clarifications on measurement techniques and the nature of overblowing, while others question the assumptions regarding the fundamental frequency and its relationship to wall thickness.

Contextual Notes

Participants are navigating the complexities of how different modes of vibration interact and the implications of varying wall thicknesses on resonant frequencies. There is an acknowledgment of the need for further investigation into these interactions.

Zoro
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Homework Statement


I understand how to find the resonant frequency of a closed pipe but when the thickness of the walls varies, the resonant frequency varies. Is there a formula that i can use to find the resonant frequency of a closed pipe given the length, temperature, speed of sound and THICKNESS. Thank you for any help :)

Homework Equations

The Attempt at a Solution


I attempted a few experiments in which i used a technique called over blowing but i also want to calculate it mathematically if possible.
 
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I was not aware that the wall thickness does affect the fundamental frequency of the notes produced by the column of air. I can understand how it alters any notes generated by vibration of the pipe walls, and how it may attenuate different harmonics from the air column differently. Both of those will make the note sound different, but the fundamental frequency should be the same.
Maybe someone else knows some subtleties I'm missing.
 
Yes, are talking about modes of the air in the tube or about the flexural modes of the pipe?
 
i mean the resonant frequency. Basically i was trying to determine the resonant frequency of a closed pipe (measuring cylinder) and looked at different cylinders with different thicknesses of the walls. I used a technique called over blowing
 
Both types of vibrations (air vibration and wall vibration) have resonant frequencies.
How did you measure the frequency?
By over blowing you mean a technique of exciting higher modes of a wind instrument?
 
By overblowing, i mean i hit the glass measuring cylinder twice with my finger and then blew air over the opening. The sound that was made was recorded and the natural / resonant frequency was calculated using f = waves/ time
 
The cylinder itself has natural frequencies of vibration - these are what you excite when you tap the cylinder . During vibration the cylinder flexes in the same way as a bell does - hence this type of vibration is commonly called bell mode vibration .

The air column in the cylinder has a different set of natural frequencies - these are what you excite when you blow over the cylinder .

The level of interaction between bell mode vibration and air column vibration has to be investigated case by case but very often the interaction is so weak that the two can be looked at individually .

If you tap the cylinder quite sharply with a metal spoon or similar you will clearly hear the bell mode vibrations . Usually quite a clear musical note is produced .

The material and geometry of the cylinder determine its natural frequencies .
 
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Zoro said:
By overblowing, i mean i hit the glass measuring cylinder twice with my finger and then blew air over the opening. The sound that was made was recorded and the natural / resonant frequency was calculated using f = waves/ time
Over-blowing generally produces some harmonic, not the fundamental frequency.

Were the various resonant frequencies you obtained approximately a multiple of the fundamental frequency?
 

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