Wednesday, November 20, 2013

HAVE YOU EVER WONDERED?

Whither the teakettle whistle

With the winter weather comes the  flu and cold season, which means this device will be getting alot more attention.

Did you know...






Despite decades of brewing tea in a whistling kettle, the source and mechanism of this siren sound of comfort has never been fully described scientifically. Acknowledging the vibrations made by the build-up of steam escaping through two metal spout plates is about as far as the explanation went -- and was good enough for most people.

But not for a team of engineering investigators, who have at last illuminated the mystery. Through a series of experiments, the team has produced a breakthrough in breakfast musings with the world's first accurate model of the whistling mechanism inside the classic stovetop kettle.

They have located the physical source of the teakettle whistle at the spout as steam flows up it, and identified a two-mechanism process of whistle production. Their results show that as the kettle starts to boil, the whistle behaves like a Helmholtz resonator -- the same mechanism that causes an empty bottle to hum when you blow over the neck.

However, above a particular flow speed, the sound is instead produced by small vortices -- regions of swirling flow -- which, at certain frequencies, can produce noise.

The findings are potentially able to explain familiar problems of other wayward whistles, such as the annoying plumbing noises caused by air trapped in pipes or damaged car exhausts.

To interrogate kettle whistles, the team tested a series of simplified kettle whistles in an apparatus by forcing air through them at various speeds.
They then recorded the resulting sounds produced by rushing air, plotted the frequency and amplitude data of the sound, then analyzed it to identify trends in the data. They also used a two-microphone technique to determine frequency inside the spout.

Vortex production starts as steam comes up the kettle's spout and meets a hole at the start of the whistle, which is much narrower than the spout itself. This contracts the flow of steam as it enters the whistle and creates a jet of steam passing through it.

The steam jet is naturally unstable, like the jet of water from a garden hose that starts to break into droplets after it has traveled a certain distance. As a result, by the time it reaches the end of the whistle, the jet of steam is no longer a pure column, but slightly disturbed.

These instabilities cannot escape perfectly from the whistle. As they hit the second whistle wall, they form a small pressure pulse. This pulse causes the steam to form vortices as it exits the whistle, and it is these vortices that produce the siren sound that has conditioned millions of people to anticipate the coming of the tea.


No comments:

Post a Comment