Gain of output valves

[Mark]

Does your PT have a 220/230V primary tap?
If so and measured heater voltage is on the low side, you could use that to increase B+.

I measured the mains this morning and noticed that it was measuring 233vac, so I bumped the voltage selector to 230vac. The filament voltage was 6.5vac, so that was okay, the plate voltage was initially 468VDC, but the valves hadn’t fully warmed up, the B+ settled on 444VDC, at this point I was dubious about an increase in wattage. Sure enough, no increase in wattage.

I dare say this will lead into me make another thread on testing the power transformer for correct current capabilities.

Thank you everyone for your help, I really appreciate your support.

[R.G.]

Speaking of which, I have restrained myself from doing a series of posts on transformer modelling.

It's tricky to get the SPICE model just right, but doing power transformers really only needs ideal plus winding DC to do a pretty good job.

[martin manning]

Speaking of which, I have restrained myself from doing a series of posts on transformer modelling.

It's tricky to get the SPICE model just right, but doing power transformers really only needs ideal plus winding DC to do a pretty good job.

There are a number of tutorials on the web that address ideal/non-deal transformer modeling, but your instruction would be valuable, I'm sure!

The hard part as I see it is getting values to use in the non-ideal model. Some manufacturers provide some of it, for example Hammond includes DCR, primary inductance, and no-load voltages on their data sheets; capacitances and leakage inductance are most likely going to come from measurements. I don't think those details are critical unless one is trying to get an accurate frequency response.

For the OT model I used to produce the plot above, there is a coupling factor of 0.995, which I didn't mention. It's a guess, and probably on the low side. It might be as high as 0.999, but I don't have one to measure. Any idea of what that value might be for a typical good quality guitar amp OT? No capacitances were included, but I don't believe they are very important for estimating mid-band output power.

[edit] So some Hammond data sheets have leakage inductance listed, including the 1750W Twin Reverb (etc.) replacement with 4-ohm secondary. From that and the primary inductance I believe the coupling factor should be 0.9995 via Lpri-lk / Lpri-open = 1 - k pri-sec. An updated plot is posted above.

[Helmholtz]

Problem with calculating the coupling factor from leakage inductance and primary inductance is that, while the leakage inductance is fairly constant, the primary inductance varies considerably (often by a factor of 10 or more with PP OTs) depending on V/f (more exactly on the voltage-time area/integral of the AC voltage which determines the core flux density).
Also the 2 primary halves can have different leakage inductances depending on transformer construction.

Neither of the above is essential for mid band power calculation.

[R.G.]

The hard part as I see it is getting values to use in the non-ideal model. Some manufacturers provide some of it, for example Hammond includes DCR, primary inductance, and no-load voltages on their data sheets; capacitances and leakage inductance are most likely going to come from measurements. I don't think those details are critical unless one is trying to get an accurate frequency response.

Mostly frequency response, but the leakages come in really handy if you're messing with transients, such as a speaker lead going open.

For the OT model I used to produce the plot above, there is a coupling factor of 0.995, which I didn't mention. It's a guess, and probably on the low side. It might be as high as 0.999, but I don't have one to measure. Any idea of what that value might be for a typical good quality guitar amp OT? No capacitances were included, but I don't believe they are very important for estimating mid-band output power.

It varies hugely, primarily (?!) with the windings' layer interleaving. Leakage inductances can be used in calculating the coefficient "k". Here's a reasonable sendup on measuring the k and M factors: https://www.onallbands.com/audio-transf ... -modeling/
It's common for a guitar amp manufacturer to change the vendor and possibly interleaving on their OTs, so things change. Both leakage inductance and mutual coupling are slightly different views of the same thing - magnetic field leaking out of windings and not going through the coils of the other winding(s).
I think that leakage inductance may be something you need. Falling back on the ideal-transformer-plus-lumped-parts-model; the power through the transformer does not depend strongly on k being 0.95 or 0.99, exactly. My personal view of how a transformer works, and this is how I started the stuff I may post, is that the core has to be charged up with enough magnetic "zoots". A "zoot" is an imaginary unit of magnetic muchness. For a given voltage-frequency in the frequency domain and a given volt-time integral in the time domain, the core gets charged up to some level. This forms a "bridge" over which the secondaries can suck power from the core, but this is instantly replaced by power from the primary. The core is not really a player in power transfer, with only a couple of exceptions.
The exceptions are that the core sucks in magnetizing current to feed the field up to the desired level. Simple modelling says this is linear, more complex modelling says that magnetizing current is nonlinear, depending on the B-H curve it pumps. The area integral of the BH curve traversed is the energy lost to core loss, and it is nonlinear too, but modellable.
Hang on, I'm getting to it. Core losses are pretty much fixed at some level of volt-time or volt-frequency drive. This is easy to figure out for power transformers, harder for audio transformers. Leakage inductance limits power through the transformer by lowering the voltage drive to the ideal transformer inside, much like primary resistance does. This is probably the biggest contributor to power loss. Leakage inductance losses go up as frequency increases. Use of "mid band" means by definition that you're far away from where leakage losses are overwhelming other losses, so if you''re measuring at "mid band" you're probably in a region where the coupling coefficient k and its evil secret identity leakage are not big contributors.

Audio output transformers done for fidelity are usually wound to a much lower flux density than power transformers. This is to both get the primary inductance to be larger and more constant, without the fall off in incremental inductance as the BH curve starts its gradual rolloff. Guitar OTs??? Who knows?? Is there an MBA in the company? That will definitely make for smaller cores, higher Bmax, and higher losses.

There's another subtle effect getting you. Remember that volt-time and volt-frequency stuff? Bmax in a transformer is heavily, heavily dependent on frequency. It's the volt-second integral that drives Bmax; so a transformer driven with 200Hz has only half the Bmax it would if driven with the same voltage at 100Hz. Qualitatively, transformer power handling goes up with increasing frequency, until the frequency gets high enough that the losses in primary and secondary voltages due to leakage inductance start being significant. By saying "mid band" you have set the frequencies to where magnetizing losses are not severe, primary inductance losses are not big, and losses to k/leakage are not severe. I would expect not much change in power losses anywhere in the mid band that are not accounted for very closely by winding resistance.

To be fair, I'm typing this from general principles, so if you're trying to find sub-2% issues, things might be more critical.

[martin manning]

It varies hugely, primarily (?!) with the windings' layer interleaving. Leakage inductances can be used in calculating the coefficient "k". Here's a reasonable sendup on measuring the k and M factors: https://www.onallbands.com/audio-transf ... -modeling/

Problem with calculating the coupling factor from leakage inductance and primary inductance is that, while the leakage inductance is fairly constant, the primary inductance varies considerably (often by a factor of 10 or more with PP OTs) depending on V/f (more exactly on the voltage-time area/integral of the AC voltage which determines the core flux density).

Thanks for the responses. The write-up R.G. linked is a good one. In fact I have referenced that document previously, but at this location: http://www.tsf-radio.org/forum/im/25773 ... deling.pdf

Hammond specifies leakage inductance at 1 kHz, so I guess I can assume that a model that uses those values is only accurate at 1 kHz?
See: https://www.hammfg.com/files/parts/pdf/ ... 1697661946

[Helmholtz]

Hammond specifies leakage inductance at 1 kHz, so I guess I can assume that a model that uses those values is only accurate at 1 kHz?
See: https://www.hammfg.com/files/parts/pdf/ ... 1697661946

Hammond specifies full primary inductance at 1kHz/1V, which is about what many LCR meters use.
Inductance varies with frequency and voltage.
At full 100W power the voltage across a 2k primary is 447Vrms.
I measured a Fender Twin RI OT at 50Hz/460Vrms using the impedance method and got 172H.
At lower voltage (230Vrms) L increased to 260H.
My LCR meter gave me 11H@1kHz and 25H@100Hz.

Leakage inductance is quite constant because of the large "airgap" involved.
It might lower slightly at HF due to Eddy current effect, but that would be hard to measure because of the winding capacitance (several hundred pF to nF).

[martin manning]

Hammond specifies full primary inductance at 1kHz/1V, which is about what many LCR meters use.
Inductance varies with frequency and voltage.
At full 100W power the voltage across a 2k primary is 447Vrms.
I measured a Fender Twin RI OT at 50Hz/460Vrms using the impedance method and got 172H.
At lower voltage (230Vrms) L increased to 260H.
My LCR meter gave me 11H@1kHz and 25H@100Hz.
Leakage inductance is quite constant because of the large "airgap" involved.
It might lower slightly at HF due to Eddy current effect, but that would be hard to measure because of the winding capacitance (several hundred pF to nF).

Hmm. If I scale all of the inductances in my transformer model up uniformly to get into that range of Lpri, the resulting Ia vs. Va-k is nonsense.

[Helmholtz]

Hmm. If I scale all of the inductances in my transformer model up uniformly to get into that range of Lpri, the resulting Ia vs. Va-k is nonsense.

Not sure what you mean.
The relation between Ia and Vak is determined by the loadline.
As reflected load and Lpri are in parallel, the effect on the loadline will drecrease with higher Lpri.
If Lpri was infinite it would have no noticeable effect at all.
What do you mean with "all of the inductances"?
Leakage inductance of the Twin OT is 6.2mH.

[R.G.]

Hammond specifies leakage inductance at 1 kHz, so I guess I can assume that a model that uses those values is only accurate at 1 kHz?

As Helmholtz says, leakage inductance is very constant, because it's primarily magnetic field that goes through air, not core material. Primary inductance varies a lot because it's highly dependent on the B-H curve of the core material. Lp is so variable that it causes waveform distortion by varying as primary signal changes. Another issue is that in real-world practical transformers, there is a link between leakage and primary inductances. Leakage inductance is by definition the flux that's not sucked into the core's magnetic path by the core "shorting" the path through free space with a high permeability. As the core stack varies, more or less flux leaks off into the leakage inductances. This has some odd effects. The same bobbin and core stack will measure different leakage and primary inductances and hence bandwidth depending on how carefully the laminations are joggled into contact. A few thousandths of an inch of gap on E-I junctions can make noticeable differences.

If I were trying for more accurate V-I curves, I would assume that to a first order, constant Lp is the start. I would then make several runs to see how it varies with changing Lp, and after that try a number of varying-Lp models to see how much difference varying-Lp makes.

[Helmholtz]

Leakage flux runs partly through the core (mainly center leg) and partly through air.
So isn't totally constant.
I re-measured leakage L and got 6.3mH at 1kHz and 7.4mH at 100Hz.

[martin manning]

Here is what I have been doing, shown using the values from the Hammond Twin OT data sheet. This produces the expected voltage ratio, and reasonable results for the power amp simulation as seen above. If I scale all of the inductances up (preserving impedance ratio) to get Lpri a-a into the hundreds of Henries, the result does not look right.

[Helmholtz]

Here is what I have been doing, shown using the values from the Hammond Twin OT data sheet. This produces the expected voltage ratio, and reasonable results for the power amp simulation as seen above. If I scale all of the inductances up (preserving impedance ratio) to get Lpri a-a into the hundreds of Henries, the result does not look right.

The voltage ratio follows from the primary-to-secondary impedance ratio (in this case square root of 2k/4).
Secondary inductance is primary inductance divided by 500.
Absolute Lpri doesn't matter for these ratios.
As said, leakage inductance doesn't scale with primary inductance.
So the coupling factor can't be constant.

Please show your "scaled" results.

[martin manning]

Here you go... I find it hard to believe the amp would really be doing this at max power.

[Helmholtz]

Please show your "scaled" OT model. There must be an error.
What was the secondary load?
An ideal OT would have infinite primary (and secondary) inductance.