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T-368 Audio Modifications
Tim Smith, WA1HLR
Courtesy of WB3HUZ's AM Window
So anyway, what ya need to do......
Speech Amplifier
Modifications 
The 12AT7 (V12) is now a cascaded amplifier. Notice the microphonium
connector is floating from the front panel. The ground side of the jack is
bypassed to ground with a 0.1 uF, 5 VDC disc ceramic cap. This is done to avoid
ground loops that will occur between the modulator mainframe and the speech amp.
It is useful to have a microphone input for a ãjust plug it in and playä
capability. The usual D-104 or other high impedance type crystal or ceramic
microphone offers a good compromise between broadcast quality and good talk
power with the component values used.
There is no gain control pot used between the first and second stages. If
the gain is too high and overload occurs, a 12AU7 may substituted for the 12AT7
or pot could be incorporated into the circuit. An additional BNC connector is
used for a microphonium level input. This offers the use of a coax cable to the
front panel and a good positive electrical connection to the input circuit. An
RCA type connector may be used if this is the route you choose to go.
The audio bandpass filters and clipper stage (V14) have been removed. In
earlier experiments, the 6C4 driver stage was tested with a larger cathode
bypass cap (C21) and a larger negative feedback coupling cap (C40 changed from
2700 pF to 0.001 uF). This gave good low end response to about 80 Hz. Then the
low end response rolled off as evidenced by a decrease in modulator plate
current.
It was noticed, when a frequency response curve was performed using 400 Hz
as a reference point, that the response at 3 kHz was down 5 to 6 dB! As the
audio frequency was increased, the high end would continue to drop markedly
while the modulator tubes continued to pull more and more current, until about
12 kHz. (This is a sign that the frequency response of the modulation
transformer is okay but there is excessive amount of shunt capacity somewhere in
the circuit, Ed.,HUZ). The problem is in the RF deck. We will get to that later.
The 6C4 driver stage was changed to a triode connected 6AQ5 (low mu) and
the driver transformer was shunt fed. (This is also an excellent mod for Viking
Iâs and IIâs, Ed., HUZ). A 5k, 25 watt plate load resistor and a 4 uF oil
filled cap were installed under the chassis.
Notice that there is a 2 watt resistor across the secondary of T6, the
driver transformer. In any situation where the tube being driven are operated
predominately on Class AB1, it is very important to terminate the secondary of
the driver transformer with a resistor close to its design impedance. This
termination helps to reduce distortion caused by the transition from AB1 to AB2
(grid current on voice peaks). A type of clipping distortion can result. (The
effect is noticeable on many stock T-368s when the modulation exceeds about 90
percent, Ed., HUZ). Also, the load resistor serves to flatten out the frequency
response and rolls off the extreme highs. This latter is important when using
negative feedback. If enough phase shift occurs is very high frequencies,
ultrasonic oscillation will occur. (The effect on the life of the modulator is
left as an exercise for the reader, Ed., HUZ).
With the new driver stage, the low end response appeared to go down to 30
Hz. Not bad for military iron!
Now, back to the beginning again. We have dual inpoots, 1) microphonium
level, as previously described, and 2) line level. A 600 Ohm to grid transformer
is used for dealing with balanced lines and good RF isolation. However, a
typical medium impedance line level output, like that from your usual semi-pro
and home entertainment equipment, can be used by going directly to a 25 k line
inpoot pot. The two gain control pots (mic and line) are isolated from one
another by a 47 k resistor. This makes the gain setting of each independent from
the other.
Higher B+ was needed for proper operation of the speech amp. R12, a 10k
wirewound resistor that is in series from the low voltage B+ to the audio
section, has been jumpered out. Higher value dropping resistors are used for
decoupling the speech amp. Further, a 40 - 80 uF electrolytic and a 470 Ohm
resistor are used for decoupling.
Negative feedback is now introduced around the entire modulator in the
form of five 1 MegOhm, 2 watt resistors from one of the modulator plates (right
tube when view from the rear of the transmitter).
RF Deck Mods
It is imperative that these mods are performed or else the high end
response will always suffer. In the stock unit, there is about 6000 pF of
capacity to ground, not to mention the two vacuum variable for tuning and
loading. The circuit was converted to shunt fed by installing a single layer
type RF choke, a B&W 800. A National R175 will also work, but may compromise
performance on 160 meters due to lack of inductance.
The plate blocking and bypass caps used were 500 pF, 5kV CRL type 858
transmitting doorknobs. The end of L3 (1 mH) formerly connected to the B+ is now
grounded. This puts the plate tank components at ground potential. The original
blocking capacitors (C41, C42, C7) were left in place. It is a pain to remove
them. C10, a 200 pF mica (bypass) was removed.
In the T-368 I worked on, there was an additional pie-wound RF choke in
series with the plate current meter (M3). It was a convenient point to tie a
length of high voltage wire and connect to the final tube where the other
components are mounted (RF choke and 2 caps).
By removing the DC from the tank circuit, a possible source or arcing is
eliminated. Further, the total shunt capacity is now about 1000 pF compared to
6000 pF in the original circuit. (This improved to the frequency audio response
drastically, Ed., HUZ).
Final Thoughts
These changes allowed greater plate-to-plate swing of the modulator and
therefore better us of the impedance match of the stock mod transformer. The
transmitter at this point will do a bit better than 100% modulation in the
positive direction. An improvement can be made by substituting 4-250s or 4-400s
for the stock 4-125 modulators. The stock filament transformer will weather the
storm but it will run HOT. A larger transformer
should ultimately be used.
Air MUST be put on the tubes. A 4 inch muffin fan can be JS mounted to
blow air between the tubes. Better yet, metal work can be installed to enclose
the bottom portion of the chassis that contains the modulator tubes, thus
pressurizing that portion of the chassis and blowing air from the bottom of the
socket and over the tubes.
With the stock iron, there was a noticeable improvement in the low end
response. Further improvement can only be obtained by installing a different
modulation transformer. Space is limited. However, there is one type that
appears to be made to order, the famous RCA 5500-to 5500 Ohm (1:1 ratio) open
frame broadcast type. There is JUST enough space to install it. However, two
electrolytic caps (C17, C18) that were part of the carbonium microphonuim
voltage circuit must be removed. R19 is also jumpered out of the circuit. The
new mod transformer will drop right on the chassis like it was meant to be.
Now 4-250âs or 4-400âs are a must. The DC current rating of the RCA
transformer is 200 mA. Load the PA to only 200mA. DO NOT load the PA to the book
value. The power outpoot is a little low but no one will notice. The transmitter
will now easily modulate 150% positive. Al screen VR tubes are used (600 volts).
The RCA iron has good, clean low end response and the high end response is as
good as the stock iron.
There are possibly better alternatives for the speech amp mod shown here,
but the main limiting factor is the mod iron. There is no room for anything
larger. Also, 3-500Zs could be used for modulators with the proper audio driver
circuitry installed...............
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Amateur Radio Station W1UJR
