What are the equations for whistling in a convoluted tube?

  • Thread starter Thread starter manjagu
  • Start date Start date
  • Tags Tags
    Resonance Tube
AI Thread Summary
The discussion focuses on the equations governing whistling in convoluted tubes, commonly used in cable management and medical devices. It highlights the phenomenon of "impinging shear flow instability," which occurs when air flows over corrugated surfaces, creating vortices that produce sound. This effect is similar to how a tea kettle whistles, with the tube's ridges playing a crucial role in sound generation. The relationship between airflow speed and sound frequency is emphasized, noting that faster airflow results in higher pitch sounds. For precise numerical methods, participants are encouraged to research "impinging shear flow instability."
manjagu
Messages
3
Reaction score
1
Does anyone know what the equations governing the effects of whistling in a convoluted tube as air passes trough it are? I didn't know it was called this until today, but a convoluted tube is the real name for what many cable management tubes are. These tubes are also used in medicine for things like ventilators. You used to be able purchase large ones as a toys, which you could twirl around above your head. The faster you twirl them, the higher pitch whistle you could get out of it.

Thanks!
 
Physics news on Phys.org
manjagu, Welcome to Physics Forums!

The toy you mention can be purchased here:
Whirlies
An introduction to whirled music
http://www.exo.net/~pauld/summer_institute/summer_day13music/Whirly.html

The convoluted tube that produces sound is also used as a golf swing practice device described in this patent:
Golf swing practice system with convoluted tube
http://www.patentgenius.com/patent/6503149.html

For an excellent description of how it works see this from the Exploratoruim:
Aerodynamics researchers in Japan put a whirly in a wind tunnel and used very tiny hot wire anemometers to measure the airflow near the corrugations.
They discovered that air flowing over two successive corrugations in the wall of the whirly experienced "impinging shear flow instability."
This is the same effect that makes a tea kettle sing. If you look at the spout of a teakettle you will see that it has two disks separated by a short gap, each with a hole in its center. When the air, or steam, flows through the first hole and then flows through the second hole it exits in vortices which cause oscillating pressure in the air, heard by the human ear as a whistle. The ridges in the whirly tube play the same role. As the air flows first over one ridge then over a second it tumbles into a vortex. The faster the air flows through the tube the higher the frequency of the sound produced by the vortex. When the frequency of the vortex matches one of the natural resonant frequencies of the tube it is amplified.
http://isaac.exploratorium.edu/~pauld/activities/AAAS/aaas2001.html

If you still need the exact numerical methods to describe this you may search for
“Impinging shear flow instability”.

Cheers,
Bobbywhy
 
Thanks for the thorough response! Very helpful.
 

Thread 'The Effect of Linear and Rotational Motion on Measured Weight'

Consider an extremely long and perfectly calibrated scale. A car with a mass of 1000 kg is placed on it, and the scale registers this weight accurately. Now, suppose the car begins to move, reaching very high speeds. Neglecting air resistance and rolling friction, if the car attains, for example, a velocity of 500 km/h, will the scale still indicate a weight corresponding to 1000 kg, or will the measured value decrease as a result of the motion? In a second scenario, imagine a person with a...
View full post »

Thread 'Coulomb gauge implies instantaneous radial electric field?'

Scalar and vector potentials in Coulomb gauge Assume Coulomb gauge so that $$\nabla \cdot \mathbf{A}=0.\tag{1}$$ The scalar potential ##\phi## is described by Poisson's equation $$\nabla^2 \phi = -\frac{\rho}{\varepsilon_0}\tag{2}$$ which has the instantaneous general solution given by $$\phi(\mathbf{r},t)=\frac{1}{4\pi\varepsilon_0}\int \frac{\rho(\mathbf{r}',t)}{|\mathbf{r}-\mathbf{r}'|}d^3r'.\tag{3}$$ In Coulomb gauge the vector potential ##\mathbf{A}## is given by...
View full post »
Thread 'Griffith, Electrodynamics, 4th Edition, Example 4.8. (First part)'

Thread 'Griffith, Electrodynamics, 4th Edition, Example 4.8. (First part)'

I am reading the Griffith, Electrodynamics book, 4th edition, Example 4.8 and stuck at some statements. It's little bit confused. > Example 4.8. Suppose the entire region below the plane ##z=0## in Fig. 4.28 is filled with uniform linear dielectric material of susceptibility ##\chi_e##. Calculate the force on a point charge ##q## situated a distance ##d## above the origin. Solution : The surface bound charge on the ##xy## plane is of opposite sign to ##q##, so the force will be...
View full post »

Similar threads

Musical resonance of a cylinder/tube with a hole in the center
Replies
4
Views
2K
Creating turbulence in a small tube
Replies
4
Views
3K
Flow of air through an open tube with a balloon
Replies
9
Views
4K
Heat transfer in wing by anti-ice system using hot air in piccolo tube
Replies
6
Views
1K
Fluids (Through an IV) Question
2
Replies
77
Views
21K
What Is the Correct Water Level for the Third Resonance in a Closed-Open Tube?
Replies
3
Views
4K
What Happens When the Tension in a Musical Instrument String is Doubled?
Replies
1
Views
2K
Tutoring medical students for their physics exam
Replies
12
Views
4K
What determines a vacuum tube's perveance?
Replies
3
Views
5K
What is the resonant frequency of a plucked wire in a closed brass tube?
Replies
14
Views
4K

Hot Threads

Recent Insights

Back
Top