History
My previous post outlined disassembly of the heater and my basic troubleshooting steps.
The Board
What follows is a look at the PC board.
So here's the PC board mounted at the top of the base in a plastic holder. Just bend one or both tabs on the ends to remove the board.
Here's the backside, image flipped BigClive style so that the tracks line up with the top side.
This is the schematic I created. But there is something wrong here. Design-wise it looks wrong. It simulates wrong. But I can't find the error. Resistance from the top of ZD1 to D5 is 10.2Ω, i.e., R3. Yet when tested live they are essentially identical at 11.9Vdc and maybe 0.25Vac. The cathode of D5 is connected to relay coil+. I should have measured at the top of D1,D3 - maybe next time
So here's what you've got: AC line voltage comes in on the blue connector CN1. L1 goes through the fuse to the full wave bridge (D1-D4) and the motor. The motor returns to the neutral lead.
The neutral flows through 10Ω power resistor R1 and the polystyrene capacitive dropper C1. There appears to be an integrated bleed-off resistor R2 soldered between the capacitor leads. The resistance value us estimated, the capacitance value is a guess from what I could sort-of read on the cap.
As mentioned, D1-D4 form a full-wave bridge, with reference ground at the bottom of D2,4, and DC+ at the top of D1.3. E1 is an electrolytic smoothing capacitor (41µF est). Expect this cap (E1) to dry out and lose capacitance or rupture over time. That will produce more AC ripple and the relay coil will suffer.
Now we take the DC voltage and regulate it to 12Vdc via ZD1. ZD1 was tested separately and passed current at 12V when reverse biased - I don't know the diode model. So D1,3,E1+ source voltage through R3, dropping the voltage to 12V at the cathode of ZD1. The anode is at reference ground.
That 12Vdc is connected to relay (REL1) coil+, coil- is at reference ground. D5 is the shunt or flyback diode that will pass the current sustained by the relay coil's magnetic field when the heater is unplugged and the DC voltage falls. Without the diode, the voltage would rise (back EMF) to a potentially destructive level as the the inductive coil does its best to sustain the current flow. Check out how ignition coils and spark plugs work.
So when the heater is plugged in, the blower is presumed to be running. If power fails or the fuse blows, the thermistor is still hot and generating voltage. The in-series over-temp safety switch hasn't opened yet. So the only thing to prevent the propane gas valve from staying open are the relay contacts which open when the DC voltage collapses. That's the singular purpose of this circuit. If the flame goes out, the thermistor voltage will drop and turn off the gas. If the fan stops or something impedes the flow of air, the over-temp switch will open.
Conclusion
I hope this helps you understand and troubleshoot your propane heater.
Warning: The content above is submitted in the context of a DIY repair. There are likely regulatory factors that affect the design and manufacture of these devices. I don't design or sell these contraptions, so I don't know. I just use them and try to fix them when they break.
If anyone has any insight as to where my original schematic went awry, I'd be interested to hear it.
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