After listening to some valuable advices, I have changed my design from a 3-stage C3g:GM70:GM70 to a simple 2-stage C3g:GM70.
All filaments are DC.
B+ for GM70 is set at 800V as I am using two RCA83 for rectification. The max plate voltage for 83 is only 400V.
Plate dissipation = 120W
HT = 800V
120W / 800V = 150mA
Anode current = 150mA
Bias voltage = 60V
60V / 150mA = 400ohm
Bias resistance = 400ohm
Is my biasing resistor value for GM70 correct? What wattage should I use? Will it be running very hot?
Will this schematic run in pure class A1?
Im not too sure how to calculate the IT ratio. If I want to load the C3g with around 10K, what will be the suggested ratio for the IT?
- Louis
An externally hosted image should be here but it was not working when we last tested it.
All filaments are DC.
B+ for GM70 is set at 800V as I am using two RCA83 for rectification. The max plate voltage for 83 is only 400V.
Plate dissipation = 120W
HT = 800V
120W / 800V = 150mA
Anode current = 150mA
Bias voltage = 60V
60V / 150mA = 400ohm
Bias resistance = 400ohm
An externally hosted image should be here but it was not working when we last tested it.
Is my biasing resistor value for GM70 correct? What wattage should I use? Will it be running very hot?
Will this schematic run in pure class A1?
Im not too sure how to calculate the IT ratio. If I want to load the C3g with around 10K, what will be the suggested ratio for the IT?
- Louis
Last edited:
Tell us, what voltage do rectifiers see if you want get 800V DC out ?
This is hardly the design that would be appropriate for somebody who doesn't understand the basics - on the other hand they say there is no education like life's experience, it's just that tuition gets expensive sometimes. This is going to be one of those occassions.
You should look up some elementary school physics book and focus on its electrics section. There you will find explained Ohm's law, Kirchoff's laws and the relation between voltage across a load & current through it and power dissipated on said load. Once you establish maximum dissipation, you should go for component that is rated higher than the projected maximum, including all the positive deviations (mains voltage variation). A factor of 2 is a good safety margin.
Transformer works as impedance converter with the ratio that is square of number of winding turns ratio ([Np / Ns]^2). Since you set up approximately infinite grid leak for the output tube whatever ratio you pick will result in approximately infinite load for the driver tube.
You really should look up tube basics first, then do a simple project where youll learn how things work and only then consider something like what you're attempting now. Failing that you're just going to spend alot of money for what could only avoid being a huge dissapointment by sheer coincidence. If you feel lucky play lottery instead, the relationship between investment and reward will be far more favorable to you.
Last edited:
sim with duncan psu designer and you will find that 83 can't go up to KV even with twin tubes voltage doubling.
thanks for you kind advice. Im not an electronics or electrical student but ohm's law and kirchoff's law are not too new to me. Based on my limited understanding, the bias resistor will end up being a huge heater and I can hardly find a precision (multi-turn) variable pot of that wattage to fit in! Knowing that 5W "might" not work for the bias resistor (more like a 50W), I still print it in my schematic because that is the "biggest" multi-turn pot that I can get my hands on. All I need is to have some experts like you to confirm my calculations or point out my newbie errors.
I do understand how a transformer work. Maybe I should re-phrase my question: Should I parallel a resistor with the IT as load for the driver stage and use a 1:1 ratio IT or the GM70 grid will have some loading that I can convert with a different ratio IT?
thanks for you suggestions. I believe I have did enough "clonings" of tested tube schematics and all I learnt so far is drilling, wiring, soldering, etc. Like you just said, "there is no education like life's experience". Maybe it's just the time to pay some tuition fees.
- Louis
But you've stated the maximum allowed anode voltage for each rectifier is 400V ? There is bound to be some drop across the rectifier to begin with. Now you're also mentioning voltage doubler (which imposes twice the voltage onto rectifier). Since you haven't posted schematic of your supply I can only guess as to what you're planning to do but things don't seem quite right.
As for wasted power for cathode biasing: why bother ? Set up a separate bias supply, it only takes a tiny current to bias the tube so it can be really cheap.
Grid of the output tube presents pretty much infinite load as long as it stays in class A1 (= Vg never comes close to 0V, let alone above 0V). Besides all tubes have suggested maximum grid leak resistance, usually in the area of 1M or more (depending on bias arrangement) so you should have included it there already. Lower resistance means heavier load for preceeding stage but if you want 10K load you can get 10K easily with suitable resistor once you know what the impedance transformation ratio of your transformer is (it's more difficult to find different ratio of transformer than it is to find a suitable resistor to get desired value).
Well, be careful along the way, 800V DC is no joke
Sorry for not attaching my PS schematic earlier.
An externally hosted image should be here but it was not working when we last tested it.
Increasing the 2uf capacitors might be able to further alter the output voltage for another 50~100V.
I am custom building all the irons. Given the choice, what ratio do you suggest?
Thanks for the reminder.Well, be careful along the way, 800V DC is no joke
Last edited:
Thanks for pointing that out!
In fact, I think it looks weird too. The initial schematic was like this:
An externally hosted image should be here but it was not working when we last tested it.
But I read somewhere that since Im using DC for filament, hum pot don't make much difference.
So I took it out and changed the schematic to this:
An externally hosted image should be here but it was not working when we last tested it.
Then I thought since Im going to share a common ground for the filament and B+, the other side will be grounded anyway.
Thats why I linked it down to ground.
So what is the correct way of connecting it?
- Louis
Frankly I would use a (couple of) 5U4GTB or even 5R4 to power this off of a single 600V winding using a hybrid (Graetz) bridge with solid state diodes on the negative half of the bridge.
I would also use fixed bias which would allow you to tune operating point over some range and eliminate a costly cathode bypass capacitor which could impart its own unnecessary flavor to the audio path.
I would also use fixed bias which would allow you to tune operating point over some range and eliminate a costly cathode bypass capacitor which could impart its own unnecessary flavor to the audio path.
Louis, few things:
1: Your rectifiers have their filament setup incorrectly (same problem Kavermei pointed out), you can't have cathode at same potential as anode
2: Your capacitors (the 2 uF ones) are a bit small. Are you sure your rectifiers can only handle 2 uF ? This totals 1 uF per supply, almost negligible value. You will probably want at least 10 uF (or 20-47 uF for quieter PSU) there.
3: Regarding IT ratio: this is something I haven't dealt with before so I'm sure others wuill be able to provide far more helpful tips than I can. However common sense dictates that you obey all the rules that pertain to transformers in general:
- wire must be thick enough to withstand DC current (quescent condition of driver stage)
- core must be airgapped or sufficiently large to withstand DC current without entering saturation
- inductance must be high enough not to cause LF rolloff
- leakage inductance must be low enough not to cause substantial loss
- parasite capacitance is usually low enough not to be worth the concern, but you can keep it in mind
You can read alot about these with regards to the output transformers (OPTs). Everything that applies to OPTs applies to these as well.
4: Regarding winding ratio: if your output tube never exits class 1 (= Vg is alwats negative enough for no grid current to flow) you can use your transformer as voltage step-up ("amplification") element, either getting some extra gain or getting rid of some gain without NFB. 1:1 is most straightforward as you only need one thickness of wire and everything is more straioghtforward but since you're winding your own you can tweak it to your specific goals.
5: Regarding cathode bias - it's so obvious but I haven't looked at your schematic long enough to notice it like Kavermei did: cathode resistor causes voltage drop. This drop is used to bias the tube, employing the self-adjusting relationship between grid voltage and cathode current (at some point the equilibrium is reached and if tube is stable there without melting down that's your operating point). So you obviously have to connect your bias to the correct side when using cathode bias with directly heated tubes (you can't make this mistake with indirectly heated ones because only one wire goes from the cathode). I still think you should be using fixed bias though.
1: Your rectifiers have their filament setup incorrectly (same problem Kavermei pointed out), you can't have cathode at same potential as anode
2: Your capacitors (the 2 uF ones) are a bit small. Are you sure your rectifiers can only handle 2 uF ? This totals 1 uF per supply, almost negligible value. You will probably want at least 10 uF (or 20-47 uF for quieter PSU) there.
3: Regarding IT ratio: this is something I haven't dealt with before so I'm sure others wuill be able to provide far more helpful tips than I can. However common sense dictates that you obey all the rules that pertain to transformers in general:
- wire must be thick enough to withstand DC current (quescent condition of driver stage)
- core must be airgapped or sufficiently large to withstand DC current without entering saturation
- inductance must be high enough not to cause LF rolloff
- leakage inductance must be low enough not to cause substantial loss
- parasite capacitance is usually low enough not to be worth the concern, but you can keep it in mind
You can read alot about these with regards to the output transformers (OPTs). Everything that applies to OPTs applies to these as well.
4: Regarding winding ratio: if your output tube never exits class 1 (= Vg is alwats negative enough for no grid current to flow) you can use your transformer as voltage step-up ("amplification") element, either getting some extra gain or getting rid of some gain without NFB. 1:1 is most straightforward as you only need one thickness of wire and everything is more straioghtforward but since you're winding your own you can tweak it to your specific goals.
5: Regarding cathode bias - it's so obvious but I haven't looked at your schematic long enough to notice it like Kavermei did: cathode resistor causes voltage drop. This drop is used to bias the tube, employing the self-adjusting relationship between grid voltage and cathode current (at some point the equilibrium is reached and if tube is stable there without melting down that's your operating point). So you obviously have to connect your bias to the correct side when using cathode bias with directly heated tubes (you can't make this mistake with indirectly heated ones because only one wire goes from the cathode). I still think you should be using fixed bias though.
..also to calculate the resonant frequency of that filter so that one makes sure it is as low as possible (this one clearly has a resonance in the bass region!) and with an appropriate merit factor.
Overall 800V at 150 mA for the GM70 is not a good choice for me because of very poor efficiency.....120W plate dissipation for few watts of Pout!!
For example, one could go for 800V/100 mA using a fixed bias at approx. -70V for 15-18W output with a 4-5K primary load. With 800V anode voltage and that driver I don't think one can get much more.
Cheers
45
Arnulf,
You are wrong.
Louis' HV power supply schematic is OK.
The 83 rectifier is direct heated; rectifier output (cathode) is at HV potential.
Actually the power supply is two stacked supplies.
Important is to use resistors over the 2 uF capacitors (all other capacitors should have bleeders).
Furthermore, Louis will use 10 Henry chokes instead of 1 Henry.
This will be a very quiet supply, Pi filter followed by extra LC.
The low capacitance of 2 uF (1 uF stacked) will be beneficial for regulation and rectifier behavior as it is approaching a choke input supply.
I simulated this supply in Duncan; with 425 volts at the anodes of the 83's the DC voltage at the output will be about 830 with a current draw of about 125 mA.
Kevin, I agree with the fixed bias thing. I advice Louis to read about biasing and many other tube related things; it is not a bad idea however to start with autobias. There is enough room in his project to introduce fixed bias later.
Pieter
You are wrong.
Louis' HV power supply schematic is OK.
The 83 rectifier is direct heated; rectifier output (cathode) is at HV potential.
Actually the power supply is two stacked supplies.
Important is to use resistors over the 2 uF capacitors (all other capacitors should have bleeders).
Furthermore, Louis will use 10 Henry chokes instead of 1 Henry.
This will be a very quiet supply, Pi filter followed by extra LC.
The low capacitance of 2 uF (1 uF stacked) will be beneficial for regulation and rectifier behavior as it is approaching a choke input supply.
I simulated this supply in Duncan; with 425 volts at the anodes of the 83's the DC voltage at the output will be about 830 with a current draw of about 125 mA.
Kevin, I agree with the fixed bias thing. I advice Louis to read about biasing and many other tube related things; it is not a bad idea however to start with autobias. There is enough room in his project to introduce fixed bias later.
Pieter
Both these are ok but the important thing when using cathode bias with directly heated tubes is that the filament supply must be floating, i.e. not grounded.
/Olof
Hi Pieter,
Thanks for your input.
You did enlighten me alot in my design and I really appreciate that!
Im trying to read more now to better understand the design.
Voltage = 830V
Current = 125mA
Bias voltage = 70V
70V / 125mA = 560ohm
Bias resistance = 560ohm
- Louis
Thanks for your input.
You did enlighten me alot in my design and I really appreciate that!
Im trying to read more now to better understand the design.
Is it necessary for all the caps in the PSU to have their own individual bleeder?
Thanks for pointing that out. It was a drawing error.
Does this chart looks right now?
An externally hosted image should be here but it was not working when we last tested it.
Voltage = 830V
Current = 125mA
Bias voltage = 70V
70V / 125mA = 560ohm
Bias resistance = 560ohm
- Louis
I think I just read something about a need for filament CT midpoint (grounded)
but maybe it was something different
Hi Kevin,
I was actually waiting for your suggestions and response!
Like Pieter said, I might change to fixed biasing in a later stage. Will keep that option open for now.
Im quite concern when you mention "bypass capacitor which could impart its own unnecessary flavor".
Does it means that I'll have to consider a better cap for better sonics?
I was planning to use some NOS russian electrolytic capacitors that I have previously collected for that bypass cap...
All the caps in the PS are NOS russian PIO too.
- Louis
I was actually waiting for your suggestions and response!
Like Pieter said, I might change to fixed biasing in a later stage. Will keep that option open for now.
Im quite concern when you mention "bypass capacitor which could impart its own unnecessary flavor".
Does it means that I'll have to consider a better cap for better sonics?
I was planning to use some NOS russian electrolytic capacitors that I have previously collected for that bypass cap...
All the caps in the PS are NOS russian PIO too.
- Louis
Now I got it! So I should totally isolate the filament circuits from HT too.
Is there any difference for connecting the bias resistor to the positive or negative side of the filament?
- Louis
hey, Im a complete noob with tubes
filament choke ?
it was omething about instability issues related to DHT tubes, with bias and heater being directly connected
edit, I seem to remember now, its something with small amounts of dc being transferred from heater supply to bias curcuit, and could upset the bias, or cause some kind of stability issues
something like that
filament choke ?
it was omething about instability issues related to DHT tubes, with bias and heater being directly connected
edit, I seem to remember now, its something with small amounts of dc being transferred from heater supply to bias curcuit, and could upset the bias, or cause some kind of stability issues
something like that
Please excuse this newbie, but I don't really understand "filament CT midpoint grounded".
A wild guess will be having filament power transformer with Center-Tap for grounding.
- Louis
- Status
- This old topic is closed. If you want to reopen this topic, contact a moderator using the "Report Post" button.