One of the graphs shows clipping at about 1,300 C which suggests that the thermocouple is a type K which is good up to about 1,250 C.
NIST and Omega Engineering beg to differ.
http://www.omega.com/temperature/z/pdf/z204-206.pdf
And see my comments about clipping below.
These thermocouples only produce about 41 microvolts per degree Centigrade. This means that by the time you hit 1,250 C, you have less than 1/20th of a volt.
Slightly more, actually.
There are several problems with this. The first is that the voltage is very weak so it requires amplification. And, because of this, you need proper filtering to avoid picking up line noise or radio interference. The very first thing you do is twist the wires together to reduce AC noise. Notice that the wires coming from the thermocouple are not twisted. I would guess that there is inadequate filtering but this may not be much of a problem since the reading can be averaged with the computer.
All true but none obviously applicable. The "thermocouple amplifier" shown in the instrumentation photo (slide 8) is obviously home-built. As such, there is no way to determine what filtering is used, nor is there any description of the processing performed by the computer.
A type K is linear from about 0 C to 1,000 C. Above 1,000 C, the voltage increase drops. So, the temperature is likely correct up 1,000 and then low above that.
True enough, but the linearization coefficients are well known. Without description of the computer processing it is unknown if linearization occurs.
Since we see the graph hitting 1,300 C with clipping,
The behavior of the temperature near 1300 C may be clipping and it may not. The quality of the graph on slide 12 is simply not adequate to tell, one way or another.
I wouldn't be surprised if it is actually reaching 1,455 C which is the melting point of nickel.
Given that the melting point of nichrome is nominally 1400 C, with the highest reported version I can find at 1430 C, I would.
With that said, it seems clear that the data does not support the claim that
This shows that the reactor is producing heat during this time at the kilowatt level without any electric heater input.
First, and most obviously, the anomalous temperature (1250 C indicated) is comparable with the temperature produced with a heater power of 400 watts. This is hardly "kilowatt level".
More importantly, if the imputed reaction is producing 400 watts of heat, when combined with the 500 watts of heater power being provided this implies a total heat production of ~900 watts, and the temperature should have reached somewhere in the neighborhood of 1700 to 1800 degrees. Instead, the measured temperature never exceeds 1300 C, which is a reasonable value for the heater power alone.
Worse, the power levels shown in slide 18 are clearly synthetic, and the lack of real power data is extremely suspicious. Compare with slide 14.
The temperature fluctuations shown just before the "anomalous" section of slide 12 are, I believe, easily explained. The nichrome heater wire was beginning to fail. As a break occurred, the temperature would drop, the wires would contract and reestablish contact, which would cause the temperature to rise and break the wire again, etc. This is essentially a thermal relaxation oscillator. Again, the absence of real power data for this period should raise a large red flag. An uncharitable explanation is that the wild fluctuations in reported power data were considered evidence that the power measurement device had failed, and the data was discarded, to be replaced with computed values which seemed more appropriate.
