Speed of sound in material under tension

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A loading machine has been built to test material properties under tension, revealing that the pitch of sound emitted from the material changes with varying tension levels. The speed of sound in a material is defined by the formula C = (B/p), where B is the bulk modulus and p is the density, both of which are generally considered constant during loading. However, the discussion raises questions about whether the observed pitch changes are due to variations in frequency, wavelength, or other factors. It is noted that while pitch is related to mechanical vibrations, the relationship between speed of sound and pitch is complex and not fully understood in this context. Ultimately, the inquiry revolves around the underlying mechanics affecting sound pitch as tension is applied to the specimen.
jimmyct
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I have built a loading machine for testing material properties. It applies tension at slow rates (ie 1htz) under load control until the specimen fails. One thing I noticed is that if I tap the material as it is loaded, it seems to give off a different pitch noise when it is under higher tension vs. lower tension of the sinusoidal load.

I've been trying to figure out the theory behind this today for my own curiosity. The speed of sound (C) within a material is defined as C = (B/p) we B is the bulk modulus and p is density. I don't think either of those is changing as the load is applied. Bulk modulus is more of a constant determined from the slope of a stress strain curve while the density should not change as it is a material property. Any ideas what is being observed?
 
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the pitch was my first thought
but I'm not sure its entirely right.

the wiki page that was linked in says that the pitch is related to the primary frequency at which the mechanical vibrations are passing through the specimen in which we can hear.

But I am thinking that the frequency (f) itself is also proportional to speed of sound (SOS) and wavelength(w)
f = SOS/W

So which part is really changing? The wavelength or SOS?

To add more confusion, the link to the subsection of wikipedia page on "pitch" says that as the violin string gets longer, the pitch changes and says this length and pitch are proportional. Then it provides a formula that says the density is also changing. So that leads back to the other side of initial question i asked being that density is one of the parameters for Speed of sound. I just find it hard to believe the density of the steel plates are changing though as there is little strain/displacment on them.
 
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