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I must admit I've tended to take the line that you won't usually see saturation of the output transformer in the typical guitar amp. Looks like I may be wrong.
Case in point is a super simple Fender Custom Shop '57 Champ 5F1, SE 6V6 class A. By the by, the biggest shock to me was the list price at some $1,200 or so. Ouch! While checking the power out which I usually do at 1Khz but I also tested at 100Hz (as the owner said it distorted on low notes) into a resistive 4 ohms. The power out dropped to a rather feeble 1 watts clean(-ish) at 100Hz. I if turned the signal up the waveform got really ugly, not what I'd expect to see at all.
I subbed in a new output transformer, just in case, and got the same result. So, I hooked up a probes for the output waveform and the plate current and this is what I saw at a lowish 0.6W output.
Turn it up a bit to a nominal 2.5W and the plate current shoots up with an ugly output waveform, indicating saturation:
The manufacturer quotes -1dB @ 70Hz with 187Vrms into 7k ohms (== 5 watts out) so this was rather surprising to me.
I think there might be two things going on. One is that as the primary drive hits the limits and the voltage is no longer a sine wave so the primary volt-seconds goes up so increasing the flux in the core. Once the core starts to saturate things get rapidly worse and with the feedback not helping the situation at all. The other thing is that the transformer spec is exactly as written i.e. with no DC current present. That in effect roughly halves the SE voltage swing limit and means 1/4 of the output power. Putting it another way, below 140Hz you can expect this particular transformer to saturate.
I guess that is the secret, for good or bad, of the '57 Champ.
Possible solutions?
1) a bigger OPT
2) lower the idle current so you get a better LF response at the expense of less 1KHz output power
3) increase the corner freq of the drive to the output tube grid to make it harder to get the nastiness on lows during real world playing
4) removing the feedback should make things drop off in a more progressive way.
Case in point is a super simple Fender Custom Shop '57 Champ 5F1, SE 6V6 class A. By the by, the biggest shock to me was the list price at some $1,200 or so. Ouch! While checking the power out which I usually do at 1Khz but I also tested at 100Hz (as the owner said it distorted on low notes) into a resistive 4 ohms. The power out dropped to a rather feeble 1 watts clean(-ish) at 100Hz. I if turned the signal up the waveform got really ugly, not what I'd expect to see at all.
I subbed in a new output transformer, just in case, and got the same result. So, I hooked up a probes for the output waveform and the plate current and this is what I saw at a lowish 0.6W output.
Turn it up a bit to a nominal 2.5W and the plate current shoots up with an ugly output waveform, indicating saturation:
The manufacturer quotes -1dB @ 70Hz with 187Vrms into 7k ohms (== 5 watts out) so this was rather surprising to me.
I think there might be two things going on. One is that as the primary drive hits the limits and the voltage is no longer a sine wave so the primary volt-seconds goes up so increasing the flux in the core. Once the core starts to saturate things get rapidly worse and with the feedback not helping the situation at all. The other thing is that the transformer spec is exactly as written i.e. with no DC current present. That in effect roughly halves the SE voltage swing limit and means 1/4 of the output power. Putting it another way, below 140Hz you can expect this particular transformer to saturate.
I guess that is the secret, for good or bad, of the '57 Champ.
Possible solutions?
1) a bigger OPT
2) lower the idle current so you get a better LF response at the expense of less 1KHz output power
3) increase the corner freq of the drive to the output tube grid to make it harder to get the nastiness on lows during real world playing
4) removing the feedback should make things drop off in a more progressive way.
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