There's a lot of thorny questions - sorry for the rambling post
This amp (I built a little while back) is going through trem tubes at a fantastic rate of knots. I've been through 3 trem tubes in the last 3 months. Each time the symptoms are the same, it starts with a popping noise when I switch the trem (footswitch) off, and then eventually (quickly) builds up to a staticky thump that's in time with the speed control. And it is cured when I pop a new trem tube in, which lasts for okay about 20 hours, and then the same thing happens over again.
Rather than elevating the heaters some more and possibly risking endangering other tubes, I thought implementing the level-shift in the CF part of the LFO circuit would get the cathode voltage down to a 'safe' level. I have no idea how much you can level-shift a DC coupled LFO and CF and still have it working reasonably well, but I assume that as long as one engineers it to keep the CF voltage swing potentially bigger than what you need to affect the output tube grid bias voltage, it will work. Is that right?
I had a word with Simcha Delft (who lives locally here in Wellington), who recommended I try the level shift. But its a matter of trial and error a bit. I have some fundamental appreciation of concepts and Merlin's book is helpful.
At present I have the 6G9B bias-vary trem circuit - the CF is direct coupled to the LFO stage and the CF cathode is about idling at about 220VDC (with an HT of 426V and a cathode resistor of 470k), and the heaters are elevated to 43VDC.
By my reckoning with the existing DC coupled pair (using Merlin's cook book as a guide):
Quiescent plate current of LFO stage = (426-213)/470000 = .00045A (.45mA)
Current through LFO Rk = 2.03/4700 = .00043A (.43mA)
.02mA of current is 'missing', and the bias on CF stage is:
220-213 = -7V,
so the 'missing' .02mA of current (big deal) is being added to the current flowing through the (existing) 470k Rk of the CF.
No doubt this changes when you put a level shift voltage divider in between the two stages.
I was wondering what the whole effect would be on the characteristic form of the LFO wave compared to what you would get out of a 'normal' DC coupled pair. With the latter, you would get a more asymmetric wave - because the CF Rk steals current from the LFO plate one one side of the signal swing.
However with this level-shift idea, it is introducing another route for the current to take to get to the LFO plate.
I do wonder about how a level shift will affect the characteristic bias balancing act that otherwise takes place in a gain stage-CF DC-coupled pair. The introduction of a voltage divider in between the two stages has to have an effect on how much grid current will be 'stolen' from the first stage's plate resistor by the CF stage's cathode resistor (which takes place in a typical DC coupled pair), and it will no doubt affect the CF bias.
The components in particular I am thinking of changing/introducing are shaded in green and I have put questions marks after the component values and question marks after the prospective voltages.
I haven't done a proper analysis of the cathode resistor value required to get approx 85VDC. But my reckoning is that with the LFO plate at 213VDC, I need to knock the grid of the CF stage down to about 77VDC - which is 36.5% of 213 - and estimating that the cathode would need to be biased at about 8V above that, I reckon I'd need to aim for 85V on the cathode, but I didn't yet go to the step of calculating the cathode resistor needed to get that with an HT/CF plate of 426VDC, (I think that it should be around 180k to get 85V at the CF cathode to get a quiescent bias voltage of around -6, -7 v. with the grid voltage at 77V)
Also I'm not sure about the build-out resistor - so I tentatively put that at 100k. The slope/build-out resistor is currently 220k, and I'm guessing it may need to go down to 100k with the level shift implemented (because I'm anticipating there will be less signal swing)
The impedance bridging is probably inadequate? given there is 470k plate resistor on the LFO stage, and the ra there is about 62k(? - well I'm not sure about that ra value - since the stage is biased a little on the cool side and there is a 470k load line). (If I opted for an AC coupled CF stage instead, I suppose bootstrapping the CF stage's grid would increase the input impedance there, so that is always another resort).
The grid leak/lower part of the voltage divider in the DC coupled level shift in the schematic is 270k, because that works with the 470k upper resistor to give the CF grid about 36% of the voltage from what is at the LFO plate. (I think this gives a total of 740k - in parallel with the 470k plate resistor for the LFO stage - as far as AC is concerned. Somebody please correct me if I'm wrong - because I intuitively suspect the bypass cap in parallel with the 470k would alter this to some extent).
If this 270k needs to be something like 470k, then I would need to make the upper resistor 820k to get the same voltage division (which I think would then make 1.3M in parallel with the 470k LFO plate resistor - as far as AC is concerned - when I go to determine the output impedance of the LFO stage. Again somebody please correct me if I'm wrong). I guess that if the total resistance of the level-shift voltage divider is increased from 740k to 1290k, that would slightly affect/reduce(?) the overall output impedance of the LFO stage.
I guess I could use something like 4M7 and 2M7 in the interstage voltage divider to get the level shift mentioned in 1) above (i.e.; if the impedance bridging with 470k/270k divider isn't enough)? Please correct me if I'm wrong.
Also I haven't calculated the proper freq for the bypass cap in the voltage divider yet - .1uF is a stab in the dark. Any opinions welcomed.
I was thinking another option might be to take the HT for the whole LFO/CF circuit from a separate 10k supply resistor (that would be in parallel with the 10k supply resistor after the screen node) and use another 20uF to decouple that. That would at least lower the HT to around 360 for that circuit. Anything has got to be better than continually forking out for trem tubes
The attached schematic also shows a couple of AC coupled variants - fixed bias vs cathode biased. I was also wondering about the effect of using AC-coupled CF stages after the LFO.
Can anyone please comment on the the effect on the trem wave-form from using AC coupled CF (as opposed to DC coupled)?
Sorry if I've repeated myself several times in a rambling kind of way
Cheers
