I guess you got carried away when you posted this. The skin depth in copper wire at 50 Hz is 9 mm, not 9 cm.
The paper is interesting and I don't dispute their data, but they only compare stranded vs solid wire, and don't make any comparison to actual litz wire. Which is an extremely bizarre omission, given their title suggesting that stranded wire is an alternative to litz wire. Makes it really hard to take the whole thing seriously.
Thanks for taking the time to do this experiment! I'm betting the difference is due to the strands being loosely packed. I'm betting if you were to gradually twist the ends more and more (while keeping the wire under tension in order to get the twisting distributed along the length) during the measurement, the AC resistance would rise until it's the same as solid wire. Though strands breaking might also confound the experiment...
AC resistance is a common term. Like you said, it's the real part of complex impedance at a given frequency, effectively the same as ESR. For analyzing the losses in inductors and transformers, this is usually considered separately from the imaginary impedance (which usually has a much simpler relationship to frequency).
on post #38
To me the very word "resistance" implies dissipation. However, students at an elementary level of study about AC circuits are sometimes told that the opposition to the flow of current exhibited by capacitors and inductors is a "resistance" even though it's not a dissipative property. The instructor (or elementary text) does this because the student is not ready for phasors and the accompanying complex arithmetic, but they want to call it something the student already knows about that is an opposition to current flow.
But the highest frequency I show in my images is 1 MHz, with a wavelength of about 300 meters, which is not at all comparable to the transverse section of the conductor, so we shouldn't expect the impedance to remain constant, should we?
Also note that the dependence of AC resistance due to skin effect is proportional to SQRT(f), as the slope of the yellow curve shows.
I suspect that his paper is aimed at people who have already noticed that true litz is expensive, and knew what the price was. He wanted to demonstrate an alternative; his readers could make their own comparison of prices of true litz compared to ordinary stranded wire.
The strands are in the shape of what the mathematicians would call a "right circular cylinder" (very long ones, to be sure). No matter how hard you squeeze them together, the contact patch between any pair of them is of very small area. This is the point of Sullivan's squeezing the bundle in a specially built anvil. The contact resistance between strands is rather high even when you squeeze hard. I suppose if you squeezed hard enough to cause the copper to flow one could achieve a very low contact resistance. Or, if the strands had a square cross section rather than circular, squeezing the flat sides of two strands together could achieve a very low contact resistance. Failing one of those two options, squeezing very hard won't cause the bundle resistance to rise until it's the same as solid wire; that is Sullivan's finding. The final conclusion is that stranded wire without individual strand insulation is, in fact, a poor man's litz.
To me the very word "resistance" implies dissipation. However, students at an elementary level of study about AC circuits are sometimes told that the opposition to the flow of current exhibited by capacitors and inductors is a "resistance" even though it's not a dissipative property. The instructor (or elementary text) does this because the student is not ready for phasors and the accompanying complex arithmetic, but they want to call it something the student already knows about that is an opposition to current flow.
People whose learning has progressed to a knowledge of complex impedance (that would be the participants of this thread) know to distinguish between "resistance" (real part of the impedance, the dissipative part) and "reactance" (imaginary part of the impedance, reactive part). Among such people the term "AC impedance" seems to be generally understood to be the real part of the impedance, which is what I mean by it, and apparently you do also.
But the highest frequency I show in my images is 1 MHz, with a wavelength of about 300 meters, which is not at all comparable to the transverse section of the conductor, so we shouldn't expect the impedance to remain constant, should we?
Also note that the dependence of AC resistance due to skin effect is proportional to SQRT(f), as the slope of the yellow curve shows.
I am unable to figure out how the experiment was carried out. The details you have provided appear to be correct.
What behavior do you mean by "strange behavior"?
The measurements reported in post #50 are intended to verify the statements made in points 1 and 6 here: