not worth discussing here

Originally Posted by gmeast
Hi all,

I'm glad to see a recent (supportive) thread and post on this topic. For several months I have been trying to come up with methods for analyzing the performance of my Variant-Version of the MOSFET Heater experiment that do not require use of an expensive analyzer, scope or specialized equipment , though some sort of scope is helpful (cheap PC scope maybe just for general tuning).

I conclude partly that the circuit I'm using is what has been referred to as the 'corrected circuit' by others elsewhere. This is pertaining to the general circuit wherein a diode passes from FET Drain to B(+). I do not use the 555 Timer, I use my own digital PWM and a MOSFET Gate Driver chip instead.

Anyway, I have not come close to a COP>17, or 10, or 5, but I am seeing consistent results in the COP>1.2 to (almost) COP of 2.0.

In my tests, I run the circuit at a frequency exceeding 100KHz and around 25% Duty cycle. I run the circuit long enough to produce a stable Differential Temperature and then start recording that temperature. I use fairly small batteries (series 2 x 12V AGM x 7Ah = 24V) for which I have generated a Battery Calibration Discharge Curve using a 200-Ohm x 10W 1% resistor as the load. I record and manually plot the voltage drop of the battery bank (Circuit Discharge Curve), differential temperatures, 12V battery operating the PWM/Driver, etc. I do this for 6-1/2 hours on the hour + that last 1/2 hour. At the end of the 6-1/2 hours, I disconnect the circuit from the Inductive Resistor and calibrate the Inductive Resistor using a Precision DC Power Supply. I adjust the Power Supply levels to produce the same Temperature differential as maintained during the 6-1/2 hours of circuit running and record the Voltage and Current of the DC Power Supply (this can take hours to stabalize). I multiply the Supply's VA and that is the power the circuit was PRODUCING during the 'circuit run'. [AHEAD OF ALL OF THIS: it required that I perform many 'dry-runs' aimed at adjusting the PWM Frequency and Duty cycle to produce a Circuit Discharge Curve substantially parallel to the Battery Discharge Curve when plotted on the same graph]. You now have a clear picture of the Power Consumption of the Circuit (any voltage corresponding to a voltage on the Battery Calibration Curve V^2/200 Ohms ... because the slopes of the two curves are the same) vs. the Power Produced in heating the Inductive Resistor (because of the power value obtained from the Inductive Resistor's calibration using the DC Power Supply that immediately followed the Circuit test ). Using the same rationale (but reversed), plot the discharge of the 12V battery running the PWM/Driver, and create a Calibration Curve for that battery that produces the same slope as during the circuit test ... this means you need a variable resistor to do that. You also need to use a CSR to measure the quiescent current (thus power) of the PWM/Driver. You need to consider this quiescent power at some level. Via that CSR, I believe you can also measure the sourcing and sinking currents used by the PWM/ Driver ... that being the difference between (just) the PWM running and (both) PWM and FET firing. I'm not absolutely positive, but I think you must 'add' that difference in power to the power consumption value attained earlier. I 'add' this value ... just because.

Sorry that I was so 'long-winded' trying to explain this procedure, but it may better suit some of you experimenters and your gear, or it may be of no interest to you at all.

Thanks for listening. Regards