Hi Bruce, all,
I've been thinking about what practical experiment could be performed to test out the hypothesis that using AC and switching, along with thermal blocking between the TE elements, will result in higher efficiency.
The first consideration is that standard modules have p and n junctions highly integrated. You can break the little bits of BiTe out of them, but then they are too small to work with. A reasonable sized ingot of BiTe costs about 300 dollars, and you would need one for p and one for n-- and they are almost impossible to work with, tending to fracture along the exact wrong directions. I worked up a couple of designs using metals rather than ceramic but the Seebeck coefficient is just too small.
However CuO is an interesting material for these uses. CuO produced by subjecting a Copper surface to an oxidizing flame has a Seebeck coefficient of 204 uV/K, while BiTe has a coefficient of 160-170 for p and n respectively. I got tipped to CuO from an interesting YouTube video by Nyle Steiner, which you can view by typing in his name and Copper Oxide.
A patent search for 'CuO thermoelectric generator' turned up a fascinating patent with somewhat anomalous characteristics. I've decided that if testing is done, this device should be tested first because it is a game changer, even without fancy electronics to boost voltage, or capacitive layers and such.
The patent is attached. Briefly, the device is a small can of Copper or Tungsten containing CuO created by subjecting Copper wire to a propane torch, with a lead put through the middle of the CuO, and a lead on the can itself. The inventor says that at cherry red temperature (815 C) the output was 4 mA at .2 V, or 80 mW. Now this doesn't seem too significant, but:
1) The can is very small, ideally a 1/4 in. long and 1/8 in. wide. If you do the power density calculations for a device that size and output, you get numbers for a m3 that are too astronomical to print, even if you allow half the space for leads and heat sinks.
2) The whole device can be subjected *to the same temperature*. There is no temperature differential or heat sink. This is thermodynamically suspect right from the start, and implies that something other than the Seebeck effect is operating.
If it is not a pipe dream. I would have left it behind at that point but for the discovery that CuO has such a high Seebeck coefficient. Also, CuO rectifiers are well known, and there are a class of devices that purport to rectify random thermal vibrations with diodes. So I wonder if it is possible that he has done this accidentally on a macro scale? (the other projects use nanodiodes). Even if the claims of the inventor are fallacious, given that CuO is an abundant, easy to make material, why hasn't more been done with it?
Fred
