6H100 Build Issues

[pdf64]

Yey, that’s good
But why such a high idle cathode current?
My guess is that it won’t need anywhere near that much to sound good.
The 35w KT88 anode limit is under the design max system.
Design max limits are not intended to be used directly, rather they put the onus on the equipment designer (in this case, you) to derate them as appropriate.
Whereas design centre limits are intended to be used without further derating.
35W design max typically equates to about 30W design centre. Hence 21W may be regarded as the max idle anode dissipation in fixed bias AB for KT88.

I suggest that you sound test the amp at lower and lower idle cathode currents. Gain will reduce with cathode current, so adjust the amp volume to compensate, rather you should be focusing on the sound quality.
At some point the sound quality will become noticeably ragged and degraded. It may need to get down to 10mA before that happens (your bias supply may not put out enough voltage to get down there).
When that happens, adjust cathode current back up a bit so that sound quality cleans up.
Any idle point between there and 21W may be regarded as being valid, so play around with it, experiment.

[csjoyner]

I based the number off of the bias calculator. I went with the average.

[Stevem]

Are you running 6550s or KT88s?
A 6550 is a35 watt tube and the 88 is a 42 watt tube.

With a 6550 and 425 volts on the plate 58 MV would be 70% dissipation, 49mv is 60%.

With a KT88 and 425 volts 65 MV is 70% and 60.8 MV would be 60%.

[pdf64]

Such calculators make no distinction between design centre and design max limits. As such, they’re fatally flawed.
I thought you were using KT88?

[pompeiisneaks]

Such calculators make no distinction between design centre and design max limits. As such, they’re fatally flawed.
I thought you were using KT88?

I'd like to understand this better. Are you saying that because the calculator just calculates and doesn't give datasheet level detail for every tube it's flawed? Robs calculator shows for Class A Fixed 70% is cool, 80% is average and 90% dissipation is maximum safe. What does that miss? Then for Class AB Fixed 50% is cool, 60% average, and 70% is max safe dissipation. Finally for Cathode Biasing, 85% is cool, 95% is average and 100% is Max Safe.

I've reviewed some of the common tubes myself and they also seem to concur with this, are you saying that some tubes do not fit these definitions? Are they common tubes or esoteric rare ones etc... Do the tubes on his bias calculator not fit these justifications? They specifically call out min, max and a middle reading allowing the user to decide where they want to fit the bias without exceeding maximums... isn't that design centered AND max? fitting both your designations? Or am I misunderstanding the terminology and the bias percentages the datasheets recommend are not related to design centered and max limits?

Just not sure I understand why the bias calculators everyone uses all the time are fatally flawed (In my mind, fatally flawed means they're guaranteed to cause a significant amount of really bad decisions, what that means is open to interpretation, but I'd think 'horrible sounding amps' or 'burning up tubes' in the fatally flawed range, or maybe even 'drastically shortening the tubes life'

I've yet to hear someone say that using one of these calculators led to any of the above, but your experience is way deeper than mine, or I wouldn't be asking the question.

Edit: just to be clear, nothing is meant in a negative tone, wrote this quickly, didn't read, and had to jump on a meeting, but wanted to quickly add this if the above seems harsh or negative.

~Phil

[pdf64]

Can you get your head around RCA AN174?
http://www.one-electron.com/Archives/RC ... 0Tubes.pdf

[martin manning]

Pete is trying to put a finer point on it. He's talking about the assumptions under which the max dissipation is specified on the data sheet. A design center value is what an average tube in an average installation with average component variation on an average temperature day with the moon at an average phase can tolerate. The tube manufacturer has to make assumptions to get to that value. A design max value is more like a not to exceed, ever, so the designer of the equipment has to work backward from the not to exceed dissipation considering any other relavent variables. We are not dealing with spacecraft going to Mars here, so making an estimate using the data sheet value, whatever its pedigree, is a good start. If the plates turn red in your useage case, maybe lowering the bias current a bit will fix it.

[pompeiisneaks]

Can you get your head around RCA AN174?
http://www.one-electron.com/Archives/RC ... 0Tubes.pdf

I was asking honest questions, but I fail to see how "read a 34 page document to understand why I'm right" helps. I was asking if you could clarify your statement with some backup information, not send me off without any actual answer, but if you don't want to answer, I'll get to reading that document at some point? I just feel that's a super facile way out of answering the actual question. If you didn't want to support your statement with detail, why did you offer it? I find this all to often in online discussions. People posit something really significant, but when doing so, it's should be on the person making a claim that eliminates the way MANY others view things with the proof of said claims. Instead, because I question them, it's now on ME to do deep research to understand it better? I can find tons of proof that they work and work well without major detriment due to the many times I and others use them to positive results. I don't know of negative ones and was asking to understand them.

But to each his or her own I guess.

Pete is trying to put a finer point on it. He's talking about the assumptions under which the max dissipation is specified on the data sheet. A design center value is what an average tube in an average installation with average component variation on an average temperature day with the moon at an average phase can tolerate. The tube manufacturer has to make assumptions to get to that value. A design max value is more like a not to exceed, ever, so the designer of the equipment has to work backward from the not to exceed dissipation considering any other relavent variables. We are not dealing with spacecraft going to Mars here, so making an estimate using the data sheet value, whatever its pedigree, is a good start. If the plates turn red in your useage case, maybe lowering the bias current a bit will fix it.

All of that, I think I understand pretty fully, BUT I don't see how it relates to using bias calculators. That refers to 'design' not 'implementation of known well used pardigms in the real world'

I don't think too many 'novel tube amp designs' are still happening today either, just retread of already known stuff that had been forgotten due to oversimplifications of some previous work. or other such types of things. I'm not trying to discredit the understanding of design of tube amps, but I did spend a significant portion over a few years devouring all kinds of data about tubes and tube amp design, and realized pretty quickly that I didn't have the stomach to get the super deep understanding of all the complex design mojo. I realized that for two reasons 1. I don't see myself or really many other people creating a new 'major breakthrough' in tube guitar amplifier design by doing so. (I'd be super happy to be wrong though) At that point I've relegated myself to the fact that I will slowly over time learn small nuggets of things that will help me understand how tube amps work most specifically in the guitar amp realm, and be happy with that. 2. there are way too many designers out there now that are not really designers that just copy/paste, slightly edit an amp and act like it's a new marvel, and I realized quickly I didn't want to be that either. I would consider you to be a super talented design minded person pdf64, and was hoping to learn from the source, but I appear to be pushing my luck. I started looking into solid state stuff to learn more about electronics as well and see it gets really gnarly really fast, and it's not something to tread lightly upon, there be dragons here

Not trying to start some kind of argument or heated debate, just really not understanding how biasing an existing tube amp, and designing new tube amps are directly linked in this scenario? i.e. how does knowing better how to design tube amplifiers help me understand how to bias a tube amp I already have, and that has documented data on how to bias it, that is readily available?

Edit: somehow missed the second reason in my writing up the first at the end there... added

~Phil

[martin manning]

I'd like to understand this better. Are you saying that because the calculator just calculates and doesn't give datasheet level detail for every tube it's flawed? Robs calculator shows for Class A Fixed 70% is cool, 80% is average and 90% dissipation is maximum safe. What does that miss? Then for Class AB Fixed 50% is cool, 60% average, and 70% is max safe dissipation. Finally for Cathode Biasing, 85% is cool, 95% is average and 100% is Max Safe.

The bias calculator is fine, it's just doing some simple math to find current given a voltage and a power dissipation, P/E=I. Note that it ignores screen current, though. But is 70% of the data sheet number for p-p and 100% for cathode bias really "max safe?" That depends on the amp's design and construction, the basis if the data sheet max, and the environment in which it's being played.

[pdf64]

Apologies for brevity, I'm tied up with other stuff, and I thought it was polite to provide you with some sort of response in a timely manner.
No need to read all 54 pages.
The first couple of pages serve to introduce and explain the concepts, which I got the impression you weren't familiar with?

[pompeiisneaks]

Apologies for brevity, I'm tied up with other stuff, and I thought it was polite to provide you with some sort of response in a timely manner.
No need to read all 54 pages.
The first couple of pages serve to introduce and explain the concepts, which I got the impression you weren't familiar with?

I too am working thus why I did try to add edits that I wans't trying to be snarky or rude, literally j ust asking questions. I've had some time to start reading the doc, and I think already I get the idea you're maybe pointing to, but am not sure...
The document defines there are three types of ratings systems. Rob Robinettes calculator clearly denotes his is for max design dissipation, not the other two. also the design maximum (max design? Same thing? not sure) is defined in this older document as the newest and latest design methodology decided on by a large group (JETEC) who were asked to provide this standard as the latest and greatest means of providing the right data for designers.

Is your implication that maybe this latest design maximum methodology is flawed and that the design centered system is more optimal?

Again, trying to understand it. I'd not known there were these separate well defined datasheet methodologies, I'd literally assumed they meant a designer themselves could choose to start at the center, or start at the max and derate as they built the new circuit, just up to their design choices/needs. is the JETEC finding that design max was the most valid one a bad decision then?

~Phil

[pompeiisneaks]

I'd like to understand this better. Are you saying that because the calculator just calculates and doesn't give datasheet level detail for every tube it's flawed? Robs calculator shows for Class A Fixed 70% is cool, 80% is average and 90% dissipation is maximum safe. What does that miss? Then for Class AB Fixed 50% is cool, 60% average, and 70% is max safe dissipation. Finally for Cathode Biasing, 85% is cool, 95% is average and 100% is Max Safe.

The bias calculator is fine, it's just doing some simple math to find current given a voltage and a power dissipation, P/E=I. Note that it ignores screen current, though. But is 70% of the data sheet number for p-p and 100% for cathode bias really "max safe?" That depends on the amp's design and construction, the basis if the data sheet max, and the environment in which it's being played.

well per what pdf64 said, if correct, this is a fatally flawed tool. To me, if true, this means it should not be 'fine' and we should stop using them and educate accordingly. Fatally flawed is pretty significant. Fatal means causing death (of a person or product?) or leading to failure/disaster, flawed means fundamentally not right... maybe the term was exaggerated or I'm taking something that was tongue in cheek too literally? Either way, I'm just trying to learn as I go

~Phil

[csjoyner]

We are using Tung-Sol 6550 which according to the calculator and data sheet are 42 watt. I’ve been calling them KT88s mainly because I forgot we went with the 6550 at the beginning and only realized it when I went to bias it. Also, I kinda thought 6550 was another name for KT88.

[Stevem]

Also according to the 6550 tube data your amps 430 volts on pin 4 is too high for that tube!

Even the tube data on the JJ site list there 6550 as being a 35 watt tube and there KT88 as being a 42 watt tube , theGenlex ones rated at 45 watts where killer tough!

[pdf64]

I withdraw the 'fatally flawed' comment and request that it be read as 'somewhat flawed'
Perhaps even as far as 'significantly flawed', in view of the impression of technical validity and accuracy the user might take from the calculators.
Ideally I would have reviewed and amended that before it got picked up on.
I have no reason to believe that such calculators do not work as expected from the data fed into them. The flaw I refer to is that different valve types / manufacturers / regions / time periods used different rating systems, so the published info should not be assumed to be directly comparable, from one valve type / manufacture / date to the next, and so should not be taken at face value, but rather should be interpreted from their particular context.

...The document defines there are three types of ratings systems. Rob Robinettes calculator clearly denotes his is for max design dissipation, not the other two. also the design maximum (max design? Same thing?

I don't think so, ie the 'max design' dissipation noted on the calculator does not seem to correspond to a specific rating system.
For convenience and so we're all on the same page, here's Rob's calculator https://robrobinette.com/Tube_Bias_Calculator.htm
There's a 'valve type' selection menu that provides anode dissipation ratings taken from manufacturer's info. For this calculator, that's where the user might be expected to get that data, though helpfully all integer values over the relevant range are also provided as an option.
I think the menu has examples of valve anode ratings from all 3 systems, eg 6L6WGB 26W - abs max, 6V6GTA 14W - design max, 6V6 12W - design centre.
It might be a useful improvement if the rating system used by the menu was made clear, as it tends to be noted on the published info, particularly for design max.
https://tubedata.altanatubes.com.br/she ... 6L6WGB.pdf
https://tubedata.altanatubes.com.br/she ... 6V6GTA.pdf
https://tubedata.altanatubes.com.br/she ... /6/6V6.pdf

...Is your implication that maybe this latest design maximum methodology is flawed and that the design centered system is more optimal?

All the systems are fine in and of themselves, what's non optimal is it isn't a level playing field for valve anode dissipation ratings, so in my view that acts to further erode the conceptual validity of idling all power valves in fixed bias to a specific, generic, target anode dissipation.
That being something that some people seem to fixate on.

My view is that for general use, as with such calculators, it would be best if design centre ratings, either published or estimated, were used, because they include an additional safety factor for component and supply variations. That being something non EEs may not consider when using ratings that were derived under the design max or abs max systems.
From the few published examples available, design centre ratings tend to be about 15 - 20% lower than design max.

...is the JETEC finding that design max was the most valid one a bad decision then?

Very clever engineers put forward a compelling technical rationale for it. But then there may be a more cynical commercial motivation, as valve types rated under the design max system get an apparent 20% boost in their anode ratings, compared to equivalents rated under the design centre system. Which gave the new 6L6GC a marketing advantage over the (European) EL34 it wouldn’t otherwise have had. However the Philips organisation seemed content and did fine staying with the design centre system. So on balance, given the confusion it causes, my view is that it would have been better for the whole global industry to do so too.

It’s unfortunate that the ‘big guns’ such as Merlin and Aiken, whilst providing guidance on max idle anode dissipation % in fixed bias AB, don’t qualify it by providing any indication about how the rating system used to derive the anode dissipation limit might affect that (if at all?). However the context to both examples seems to be EL34, a design centre type. We might take from that design max rated types should be idled a bit cooler than the 85 and 70% points they suggest.

The semiconductor industry uses only abs max ratings, perhaps they learned as lesson from this mess.

...theGenlex ones rated at 45 watts where killer tough!

See https://tubedata.altanatubes.com.br/she ... k/KT88.pdf
Design max - 35W, abs max - 42W.
From the typical max/centre ratios available for other valve types, I think its design centre rating would be about 30W.
It should be noted that abs max ratings do not include the allowance for valve variation, whereas the design max rating does. So from that, we may take it that many, perhaps up to half, KT88 would be excessively stressed as their average anode dissipation was increased above 35W, up to 42W.
The inclusion of the normally withheld abs max rating for the KT88 in that info may have been a desperate, cynical ploy by the GEC marketing dept to make it look competitive with GE’s 6550A. The 6550A had a 42W design max rating.

It would be interesting to know what rating systems are used by modern manufacturers.