Rich’s article will be especially helpful to radio restoration newcomers, but even our old-timers will find points of interest in this thorough discussion of how to handle an obsolete rectifying device commonly found in vintage electronic equipment—mfe. Selenium rectifiers are often found in TVs, amplifiers, and test equipment dating from the late 1940s to late 1960s. If the equipment is to be renovated, the selenium units should be replaced. This article will discuss some background on selenium devices, their benefits and drawbacks, why they need to be replaced, and how to do the replacement correctly.
Background
Selenium is a shiny gray metallic element discovered
by Swedish chemist Jöns Jakob
Berzelius in 1817. In the 1920s, German scientists
discovered that a “sandwich” of a selenium
layer against another metal layer would pass current
in only one direction. That meant it could be
made to rectify alternating current (AC), changing
it to DC for use in electronic apparatus. After
World War II, both European and American
companies began to make commercial rectifiers
by evaporating selenium onto small plates of
steel or aluminum.
These rectifiers were a real break-through in
improving the efficiency of electronic equipment. Two small selenium “stacks” could easily
replace a type 80 or 5Y3 vacuum tube rectifier in
many circuits. Since each plate of the selenium
stack could support about 30 volts, you will typically
find 5 or 6 plates in a 120 Vrms rectifier.
Tube rectifiers need filament power to thermally
stimulate electron flow. The 5Y3, for example,
requires 5 volts at 2 amperes to heat its filament.
That means that 10 watts must be furnished
and dissipated as heat in order to rectify enough
DC to supply a 10 or 20 watt amplifier. With selenium
rectifiers no filament power is required.
Other Benefits
Besides the obvious efficiency advantage of
selenium over vacuum tubes, there were other
benefits to consider:
• Selenium rectifiers were typically smaller
than the tubes they replaced.
• No sockets were required, since selenium typically
had a long life (10+ years).
• Selenium is “self-healing.” A short-term voltage
spike might “zap” the selenium film, but
it soon heals itself and functions again.
• When used in 120 Vrms rectifier circuits, the
selenium unit had a drop or loss of only about
5 to 10 volts while the tube rectifier drop was
10 to 25 volts. This lower drop meant that DC
voltages were higher when selenium replaced
a tube.
Disadvantages
With so much going for it, why did selenium disappear from most designs by the late 1960s?
• Small silicon diodes became available. Silicon diodes could easily handle 10 times more current than selenium with only 1 volt of drop, compared to 5 or 10 volts for selenium.
• Selenium is an essential trace element (you’ll even find it in dandruff shampoo), but in larger quantities it is dangerous and toxic. The US EPA regulates the use and disposal of selenium. See reference (3).
• Selenium rectifiers “age.” That is, as they get
older both their forward voltage drop and reverse
leakage current increase, making them
less effective. The DC voltages supplied to the
associated electronic equipment gradually decrease
causing poor performance.
As selenium units get older and run hotter,
they are more prone to catching fire, causing
a foul-smelling, pungent smoke. Some oldtimers
compare this to burning garlic.
• By 1970, silicon diodes cost only pennies and
were 10 times smaller than the selenium units
they replaced.
Some manufacturers’ data indicate that selenium
rectifiers could handle as much as 250 milliamperes
per square inch of plate area. From the
table above, you can see that 100 milliamps is
more typical. This isn’t a problem, as a replacement
silicon diode will easily handle almost half
an ampere.
Replacement a Must
Even if your equipment seems to be working
well, you should replace the selenium rectifier
unit. It is only a question of time before it will
fail. If you are lucky, it will fail gracefully, blowing
a fuse or showing an “open” circuit. Unfortunately,
if your rectifier overheats, you could
have lots of nasty, toxic smoke.
Replacement is easy and silicon diodes are
cheap, so there is no reason not to do the replacement.
New selenium rectifiers are difficult to find,, though they are still made in India.
Don’t bother buying a new old stock (NOS) selenium
unit. It will be at least 50 years old and already
well-aged toward failure.
Silicon Diode Specs
Most parts distributors, including Radio
Shack, carry one- ampere silicon diodes. The
most popular are the 1N400x series. If you are
replacing a typical 130 Volt selenium, choose at
least a 1N4004. This is a 400-volt rated part.
Seems like over-kill? Not really. Unlike selenium,
silicon is not “self-healing.” Even a few
microseconds of a voltage spike can zap a silicon
diode. My personal preference is to use a
1N4007 (rated at 1000 volts). It costs only a few
pennies more and provides a lot of extra margin.
If you are really conservative, the 1N5408 diode
will handle 1000 volts and almost 3 amps!
Silicon diodes are packaged as small cylinders
with a wire lead emerging from
each end. one end of the cylinder will
have a band marked on it. This is the
cathode. Some diodes will have a
taper or chamfer to mark the cathode
end. Be sure to observe the proper polarity
when connecting a silicon diode
in place of a selenium rectifier! My illustration
of a 1N4004 diode shows a
(+) indication for the cathode—which
was the convention used on selenium
rectifiers.
Adding Resistance
The typical US power line is rated
at 120 Vrms. This means that the peak
voltage is 1.414 x 120 or roughly 170
volts. When you rectify the 120 Vrms
line and used it to charge a filter capacitor,
you might get as much as 170
VDC on the capacitor. In practice, the
voltage is a bit lower due to losses in
the rectifier and the wiring.
xxWhen you exchange a selenium
rectifier for a silicon diode you will
find that the DC output voltage to your
equipment has increased by 5 to 15
volts. In order to maintain the originally
specified output voltage, you
will want to add a series resistor between the diode’s cathode and the first filter capacitor.
Sometimes the increase in output voltage
is not a particular problem, but a resistor
should be added in all cases to reduce the available
surge current.
When a filter capacitor first charges up, it appears
to be a momentary short circuit, drawing a
huge current through the diode. Selenium rectifiers
have a naturally higher internal resistance,
so they “self-limit” the surge current. Silicon
diodes have a lower forward resistance, so you
need a resistor in series just to reduce the surge.
My rule-of-thumb is to size the resistor to
drop about 10 volts, simulating the drop of the
old selenium rectifier. If the equipment requires
50 milliamperes, we can use Ohm’s Law to
calculate:
R = Vdrop/IDC = 10 V/0.050 A = 200 ohms
This is only a rule-of-thumb. If you want to
duplicate the exact original output voltage, start
with a resistor of about 100 ohms and measure
the output voltage with the equipment operating.
Adjust the resistor value up or down until you
achieve the voltage specified by the manufacturer
of the equipment. Typical values will be
from 20 to 200 ohms. The resistor has to dissipate
some power, which means it will generate
heat, so be sure to use a resistor rated for the
power. In the example above, the approximate
power required will be:
P = V2/R = 102/200 = 0.5 watts
Don’t use a half-watt resistor! A half-watt resistor
gets very hot when dissipating a half-watt.
I would recommend at least 100% to 200%
safety factor. In fact, 5 watt resistors are probably
easier to find than 2 watt types. If your current
calculation is different, use a resistor rated
for at least twice the power calculated. Resistors
are cheap, so don’t cut corners.
You’ll undoubtedly also be replacing the filter
capacitors—standard practice in most restorations. In AC-DC power supplies, make
sure that your new filter capacitors are rated for
at least 170 Volts. Old equipment might have
150 V caps, but use the higher voltage rated capacitors
when renovating.
Replacement Considerations
You may decide to remove the old selenium
unit or merely disconnect it. It’s usually best to remove
the unit and mount a multi-terminal connection
strip in its place. Connect each wire of the
new silicon diode to one lug of the terminal strip.
Connect the resistor (calculated above) between
the cathode lug and one of the free lugs of the terminal
strip. It goes without saying that you should
not use any lugs that are grounded to the chassis.
The AC wire is the one that had been connected
to the unmarked or minus (-) terminal of
the selenium device. Now connect it to the unmarked
side of the silicon diode. Connect the (+)
terminal of the first filter capacitor to the free
end of the resistor. Make sure that the banded
end of the diode is the one that is connected to
the resistor and through the resistor to the (+)
terminal of the first filter capacitor. If you get
the polarity wrong, you can short or destroy
the filter capacitors, blow a fuse, and blow the
new diode. Be careful. Be certain you know
which end of the diode connects to the DC.
Possible Configurations
You will typically find selenium rectifiers used in audio amplifiers, test equipment, and “3- Way” portable radios. Selenium was not used in the popular “All American Five” radios, because the rectifier tube was necessary to complete the heater series string for 120 VAC operation. In most equipment, there will be one selenium rectifier connected as a half-wave circuit. This was the lowest cost rectifier configuration. Ripple voltage is higher at the output, but that wasn’t a problem in most equipment. More sophisticated equipment might use two selenium rectifiers in a full-wave configuration. That means you need two silicon diodes and associated resistors. Likewise, TVs from the 1950s often used a voltage doubler circuit. Two selenium rectifiers were used in a circuit that boosted the DC output to twice the AC input voltage. Use particular caution in this case as the “boosted” DC can reach up to 400 V! Be careful in replacing selenium units in socalled “battery eliminators” or “3-way” portable radios. This equipment usually uses low voltage tubes in configurations involving the tube filaments in the DC power circuit. These kinds of circuits have too many variations to cover here. A typical example is the Zenith Trans-Oceanic, one of the most popular of the 3-way portables. See the references (6) through (9) for more help.
REFERENCES
1. ARRL Handbook 1959. American Radio Relay League.
2. Allied Radio Catalog 1970
3. “Selenium Compounds; Hazards.” http:// www.epa.gov/ttn/atw/hlthef/selenium.html
4. “Insel Rectifiers.” http://www.rectifierindia. com/product/seleniumrectifiers/index.html
5. “Metallic Rectifier Design & Application.” http://www.pmillett.com/file%20downloadss/selenium.pdf
6. “Zenith Trans-Oceanic.” http://oak.cats. ohiou.edu/~postr/bapix/H500_2.htm
7. “Power Supply Rebuilding.” http:// trans-oceanic.fortunecity.net/te01015.htm
8. “Motorola VT-73.” “Replacing Selenium.” http://antiqueradio.org/motvt73.htm
9. “Powering your Antique Portable Radio.” http://antiqueradio.org/bsupply.htm
10. Radio Shack 1959 Guide to Electronic Buying
Replacing Selenium Rectifiers Further Thoughts Six Years Later
Since the Antique Wireless Association published my article in January of 2007, I've received numerous comments, mostly good, about the article. I think it's a good place to start for someone who is dealing with a selenium rectifier for the first time. Certainly, not all situations are covered, but the basics are still useful today. Here are some corrections and additions:
1. The comment about using selenium to replace a type 80 or 5Y3 vacuum tube rectifier is not really appropriate. These tubes have a reverse voltage rating exceeding 500 V. To replace them with selenium would require a very long stack of plates, certainly a dozen or more in series. But this fact highlights the really dramatic advantage of silicon rectifiers. In many circuits, one 1N4007 can be used to replace each plate of a dual rectifier tube. This saves more than 10 Watts of heat and allows nearby components to run cooler.
2. AT&T Bell Labs reported on selenium rectifier performance in an extensive report in the 1950s. J. Gramels explains in detail how selenium rectifiers are made and how they age with time. From the beginning of their use, it was understood that the rectifier characteristics would change with age. www3.alcatel-lucent.com/bstj/vol32-1953/articles/bstj32-6-1469.pdf
3. The 1N4007 diode is the best all-around choice for replacement of selenium rectifiers found in radios, test equipment, and TV sets. The price is so low, under 10 cents, that it doesn't pay to use anything less. The 1N5408 is another choice, though really overkill in most cases.
4. I continue to recommend a "cut and try" approach on the series resistor. The current waveform is not a nice sinusoid, as the rectifier supplies current only during the middle of an AC cycle when the filter capacitor needs additional charge. Peak currents can be 5 or 10 times higher than the measured DC average value.
5. Don't save money by using 150 V electrolytic capacitors. Yes, the old radios used them, but line voltages are higher today and capacitors are cheaper. I wouldn't use anything less than 200V for typical 120V (rms) line voltages. If the equipment you are repairing has a transformer, then use capacitors that are rated for at least the peak output voltage plus a 10 or 20% safety factor.
6. European radios favored a 4-diode full-wave bridge. These can be replaced with four 1N4007s or a commercial bridge rated for at least 600V. With 220V input, the peak diode voltage is in excess of √2 x 240 or 340V.
7. Automotive battery chargers and "eliminators" (like those sold by HeathKit
and EICO) used large single- or double- plate selenium rectifiers. The circuit is
usually a full-wave center-tap. For higher current levels you will need to
choose a larger rectifier that bolts down to a heatsink. You must electrically
isolate the rectifier if you choose to use the metal chassis or cabinet as a
heatsink.
Some helpful reading materials:
• "Metallic Rectifiers," Theodore Conti. http://www.vacuumtubeera.net/MetRect-CrysDiodes.pdf
• "Design Guide for Rectifier Use," Hammond Transformer. http://www.hammondmfg.com/pdf/5c007.pdf
• AN 1040 "Mounting Considerations for Power Semiconductors, " on Semiconductor. http://www.onsemi.com/pub/Collateral/AN1040-D.PDF
• Data Sheet 1N4001-07 rectifier. on Semiconductor. http://www.onsemi.com/pub/Collateral/1N4001-D.PDF
출처
REPLACING SELENIUM RECTIFIERS - W3HWJ
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