45mA with 500v on the anode is 20W dissipation. A full class A on the outer pair V8 & V11, due to the pair of pull up resistors on the grids. V9 & V10 will probably sit around 75% dissipation and around 40mA.
A tad on the hot side for my liking.

I just checked, and the way I have it set, V8 and V11 are pulling 40mA each, and V9 and V10 are pulling 23mA each.
Is that reasonable?

Edit: I mean, is what I'm trying to do here bias 1 pair not TOOO hot, and the other not TOO cold?

That looks about right.

The 2.2M resistors between the outer tube grids and ground constitute voltage dividers together with the 440k series resistance, thus lowering the grid bias value by 10% compared to the inner pair.

It is hard to tell (without measuring) f the outer pair could run in full class A without knowing the plate impedance.
It's possible with high idle current but would require a large load impedance at that high plate voltage.

Thanks guys! Just to add, the high gain channel sounds really bad and fizzy on these amps. A 1n across the Rp of V2a R8, and a 1n across 470K R9 really woke it up and made it sing.

If you get chance, it would be interesting to know what the OT primary impedances, or winding ratios, of the inner and outer pairs were

Indirectly answering you: that can be easily calculated using the datasheet curves.

Solve separate for each "Class" section to have plate swing as much as possible, from +V idle to plate saturation, which will NOT be zero but around 60-80V .

Each section will have an optimum load impedance coming from peak to Peak voltage swing and related peak to peak current swing, that will define both optimum load and peak power output.

You also want to make lowest saturation tubes the "outer" ones, the inner ones by definition will stop further away from ground.

In my view, a useless design, nothing to be gained from it, but of course it´s "unique" and so "patentable", an important consideration for MB.

It also includes the magical "Class A" buzzword.

It’s just that I recall a report that when investigated, the leads to the inner and outer anode came from the same point, the start or end of the winding. Rather than the inner leads being taken from taps along the primary winding.
ie thereby making the whole simul class thing something of a nonsense, which existed only as a patent rather than being implemented in real world amps.

For full class A operation with an idle current of 45mA to 50mA, plate load per tube should be at least 8k. Meaning Zaa = 16k for the pair.

A simple method to find out if it's actually full class A would be measuring the supply current for the pair in "class A" mode.
If the supply current at full output is significantly higher than at idle, it's not (full) class A.

That would be VERY funny.

And of course entirely possible.

If not mistaken, guess they even patented fixed bias or something.

And a host other "discoveries"

I recall that as well. I think it was for early simul-class. And thus invalidated the whoe patent thing.
I believe someone on one of the other forums had done an autopsy on the OT.

Just did a Simu Class Satellite Same set up with an ultra linear output trans.

If I remember right, it's so you can run 6L6's in the hot sockets and EL34's in the cold.

Simu Class!
Get it?
Ha, ha.

But most just run all 6L6's.

Below is the original simul class OT data (part # 562003). Later the stack thickness was reduced and later (mark IV B for example, part # 562004R-1) they made it without the additional taps.
The simul class schematic is usually wrong because the 6L6 pair connects to the outer OT taps.

Iron EI96x47mm, laminations 0,35мм, 2 laminations per row

Winding №1- 2 layers (37 + 37 turns), wire thickness, 1mm
Winding №2 2 layers (94 + 110 turns), wire thickness, 0,3mm
Winding №3 7 layers (118 turns), wire thickness, 0,3mm
Winding №4 1 layer (43 turns), wire thickness, 0,9mm
Winding №5 7 layers (118 turns), wire thickness , 0,3mm
Winding №6 2 layers (94 + 110 turns), wire thickness, 0,3mm
Winding №7- 2 layers (37 + 37 turns), wire thickness, 1mm

Total – Primary turns 1652-2060 / Sec 4 Ohm – 74 turns, 8 Ohm – 117 turns
All wires’ diameters include the wire enamel ( insulation).
For a single layer insulation the copper only diameter will be as follows:
0,28mm/0,85mm/0,95mm
For a double layer insulation the copper only diameter will be as follows:
0,25mm/0,8mm/0,9mm
Turns ratio for the 4 Ohm secondary 1652/74=22,3 2060/74=27,8
Reflected primary impedance: 22,3^2=1989, assuming COP of 90% ~2210 Ohms
27,8^2=3091 Ohms, assuming COP of 90% ~3435 Ohms

Part #562004

Primary:
A1 6L6 Blue
A1 EL34 Blue/White
B+ Red
A2 EL34 Brown/White
A2 6L6 Brown

Secondary:
0 Ohm Black
4 Ohms Green
8 Ohms Yellow

Sorry, what is COP?