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Hi,
These days I'm diving into some OT calculations and I have several questions.
Let's take a simplified formula for calculating the required OT inductance at certain low frequency at -3dB. It goes like L=Ra/2*pi*f where Ra is the primary reflected impedance and f the low cut off frequency. For example if we go for a 100 Watt OT with 2k primary impedance and cut at 50Hz below the required L will be 2000/6.28*50=6,4H.
Questions:
1/ At what signal level and what frequency can you measure that to make sure you hit the goal? I have a DMM with inductance measuring and all 100 Watt OTs I measured so far fall into the 3,5-4,5H range. The measuring signal of DMM is 1V at 100Hz. If we assume higher cutoff frequency the measurements will fall pretty much into that range.
However very often one can see inductance figures measured at 120 or 240V AC which are in the 20-70H range and higher.
2/ How do you get those figures and what can one make of them considering they vary for different 100W OTs. For example let's take 2 Hammond guitar OTs where those figures are provided:
Fender Twin/Showman replacement
http://www.hammondmfg.com/pdf/EDB1760W.pdf
Marshall JCM900 replacement
http://www.hammondmfg.com/pdf/EDB1750X.pdf
Both are specified at 70Hz-15kHz, however inductances are different. The first one is 21.22H the second 50.93H, both measured at 240V, 50Hz considering the second one has larger iron core. Also the primary DCRs are very low which either indicated lower number of turns or thick wire.
I did some calculation and simulations according to which the primary wire would be somewhere into the 0,35-0,45mm range (less the enamel), otherwise it's not possible to get the DCR so low.
It's well known that detailed data about well known guitar OTs like interleaving, wire size etc are very scarce. From what I could gather from the net it looks like there are 2 types of 100W OTs. Let's call them A/ Mesa type and B/ Marshall type.
A/ has around 1600 pri turns (0,25-0,3mm wire, less enamel) and 74 sec turns B/ has around 1200 pri (0,35-0,4mm, wire, less enamel) and 54-58 sec both for the 4 Ohm tap.
After some more calculations and simulations it turns out that no calculation ever would produce 1600 turns of primary at those low cutoff frequencies and iron sizes. Usually you get 1000-1200 turns. The only way you can get 1600 turns of primary is when you design a 50W HiFi specs transformer. Actually Mesa iron sizes and interleaving indicate just that. It's well known that both OT types will produce more than enough low frequency content so what's the deal here? The only advantage I see in using a 50W HiFi specs OT is Mesa likes "mismatched operation" by switching 2 tubes off for 50W where a higher inductance OT (which is in the 7-9H range for small signals) would provide adequate loading for two tubes.
Secondaries' wire thicknesses also vary between 0,6mm and 1,3mm (in parallel or single) so I'm somewhat confused about how manufacturers decide what type of OT to use or they're just using similar iron to what they had by hand when they first started building amps and it's well known that it wasn't always of good quality although (or because) it contributed to the tone they are known for.
These days I'm diving into some OT calculations and I have several questions.
Let's take a simplified formula for calculating the required OT inductance at certain low frequency at -3dB. It goes like L=Ra/2*pi*f where Ra is the primary reflected impedance and f the low cut off frequency. For example if we go for a 100 Watt OT with 2k primary impedance and cut at 50Hz below the required L will be 2000/6.28*50=6,4H.
Questions:
1/ At what signal level and what frequency can you measure that to make sure you hit the goal? I have a DMM with inductance measuring and all 100 Watt OTs I measured so far fall into the 3,5-4,5H range. The measuring signal of DMM is 1V at 100Hz. If we assume higher cutoff frequency the measurements will fall pretty much into that range.
However very often one can see inductance figures measured at 120 or 240V AC which are in the 20-70H range and higher.
2/ How do you get those figures and what can one make of them considering they vary for different 100W OTs. For example let's take 2 Hammond guitar OTs where those figures are provided:
Fender Twin/Showman replacement
http://www.hammondmfg.com/pdf/EDB1760W.pdf
Marshall JCM900 replacement
http://www.hammondmfg.com/pdf/EDB1750X.pdf
Both are specified at 70Hz-15kHz, however inductances are different. The first one is 21.22H the second 50.93H, both measured at 240V, 50Hz considering the second one has larger iron core. Also the primary DCRs are very low which either indicated lower number of turns or thick wire.
I did some calculation and simulations according to which the primary wire would be somewhere into the 0,35-0,45mm range (less the enamel), otherwise it's not possible to get the DCR so low.
It's well known that detailed data about well known guitar OTs like interleaving, wire size etc are very scarce. From what I could gather from the net it looks like there are 2 types of 100W OTs. Let's call them A/ Mesa type and B/ Marshall type.
A/ has around 1600 pri turns (0,25-0,3mm wire, less enamel) and 74 sec turns B/ has around 1200 pri (0,35-0,4mm, wire, less enamel) and 54-58 sec both for the 4 Ohm tap.
After some more calculations and simulations it turns out that no calculation ever would produce 1600 turns of primary at those low cutoff frequencies and iron sizes. Usually you get 1000-1200 turns. The only way you can get 1600 turns of primary is when you design a 50W HiFi specs transformer. Actually Mesa iron sizes and interleaving indicate just that. It's well known that both OT types will produce more than enough low frequency content so what's the deal here? The only advantage I see in using a 50W HiFi specs OT is Mesa likes "mismatched operation" by switching 2 tubes off for 50W where a higher inductance OT (which is in the 7-9H range for small signals) would provide adequate loading for two tubes.
Secondaries' wire thicknesses also vary between 0,6mm and 1,3mm (in parallel or single) so I'm somewhat confused about how manufacturers decide what type of OT to use or they're just using similar iron to what they had by hand when they first started building amps and it's well known that it wasn't always of good quality although (or because) it contributed to the tone they are known for.
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