All American Five

The term All American Five is a colloquial name for mass-produced, superheterodyne radio receivers that used five vacuum tubes in their design. These radio sets were designed to receive amplitude modulation (AM) broadcasts in the medium wave band, and were manufactured in the United States from the mid-1930s until the early 1960s[1] By eliminating a power transformer, cost of the units was kept low; the same principle was later applied to television receivers. Variations in the design for lower cost, shortwave bands, better performance or special power supplies existed, although many sets used an identical set of vacuum tubes.

The Philco PT-44 is an example of the All American Five radio set. This set deviates from the more usual AA5 in that it features an Octode mixer rather than a pentagrid
Placard showing the tube placement. This set would have required an additional series resistor in the heater chain as the tube heater voltages do not sum to 115 volts.
Back view of the chassis. The compact design is aided by putting both IF transformers in a single can.

Philosophy

The radio was called the "All American Five" because the design represented the majority of radios manufactured for home use in the USA and Canada in the tube era. They were manufactured in the millions by hundreds of manufacturers from the 1930s onward, with the last examples being made in Japan. The heaters of the tubes were connected in series, all consequently drawing the same current, but with different voltages across them. The standard line up of tubes were designed so that the total rated voltage of the five tubes was 121 volts, slightly more than the electricity supply voltage of 110-117V. An extra dropper resistor was therefore not required. Transformerless designs had a metal chassis connected to one side of the power line, which was a dangerous electric shock hazard and required a thoroughly insulated cabinet. Transformerless radios could be powered by either AC or DC (consequently called AC/DC receivers)—DC supplies were still not uncommon. When operated on DC, they would only work if the plug was inserted with the correct polarity. Also, if run from a DC supply the radio had a reduced performance because the B+ voltage would only be 120 volts compared with 160-170 volts when operated from AC.[2]

The philosophy of the design was simple: it had to be as cheap to make as possible. The design was optimized to provide good performance for the price. At least one radio manufacturer, Arthur Atwater Kent, preferred to go out of business rather than attempt to compete with 'midget' or low-cost AA5 designs.[3]

Many design tricks were used to reduce production costs of the five-tube radio. The heaters of all the vacuum tubes had to be rated to use the same current, so they could be operated in series from line voltage. The rectifier and audio output tube required more heater power, so dropped a larger voltage than the other tubes. In many designs the rectifier tube had a tap on the heater to power a dial light. The plate current was routed through that portion of the rectifier heater, in order to make up for the current diverted to the dial lamp. If the dial lamp failed, that part of the rectifier heater would have a larger current which could burn out the tube in a few months. Early radios had a resistor network to minimize the problem but this was soon eliminated as the cost of replacing the tube was not the manufacturer's problem. As with Christmas tree lights, if one tube heater failed, none of the tube heaters would operate.

The radio used a half wave rectifier to produce a plate voltage of 160 to 170 volts directly from the AC power line; the rectifier, while not needed with a strictly DC supply, did not cause a problem.

The frequency mixer was of the pentagrid converter design to save the cost of a separate oscillator tube. The detector and first audio stage were provided by a dual diode/triode combination tube. When the detector/first audio tube contained a second diode, it could be used to provide automatic gain control (AGC), or AGC bias could be derived from the audio detector diode.[4]

Potential hazards of the design

Many early examples of the 'All-American Five' posed a shock hazard to users. Lacking a mains transformer, the chassis of the AA5 radio was directly connected to one side of the mains electric supply. The hazard was made worse because the on/off switch was often in the wire of the mains supply which was connected to the chassis, meaning that the chassis could be "hot" when the set was either 'on' or 'off', depending on which way the plug was inserted in the power outlet. Many power plugs had two identical pins, and could be plugged in either way round. The metal chassis securing screws were sometimes accessible from the outside of the Bakelite or wood case, and there were many examples of owners receiving a shock by making contact with these screws while handling a set. Ventilation holes could be large enough to allow children to poke their fingers, or metal objects, through. The same type of hazard was present in European AC/DC sets, at twice the voltage.

The hazard was eliminated from later sets by the use of an internal ground bus connected to the chassis by an isolation network. Underwriters Laboratories required the adoption of the floating chassis, as isolation from the mains (the exact circuit and component values were not specified although the leakage current allowed was specified) to limit the shock to a "safe" current level. The chassis was maintained at RF ground (for shielding) by a bypass capacitor (typically 0.05 µF to 0.2 µF) usually with a resistor connected across it (typically 220 kΩ to 470 kΩ, although values as small as 22 kΩ were sometimes used or the resistor was simply omitted).[5] In older schematics, "M" was used to indicate "thousand" and not "megohm". Later on, "K" for "kilo" or "thousand", and "Meg" for "mega" or "million" became the standard, with "M" deleted to avoid confusion. Today, the symbols are kΩ and MΩ.

Over the years, these paper capacitors often become leaky, and could allow sufficient current flow to give the user a shock.

Variations on the theme

Although four-, six-, and even a few rare eight-tube radios were produced, they were not common. The four-tube version with vacuum tube rectifier was of inferior performance, as they typically had no IF amplifier tube, although some four-tube designs with a selenium rectifier in place of the rectifier tube avoided this problem. The six-tube versions added either a RF amplifier tube, a push-pull audio power amplifier tube, or a beat frequency oscillator tube (to listen to Morse code or single-sideband modulation transmissions). However, these radios cost significantly more and sold in smaller quantities. The eight-tube versions cost even more, adding two or more of the features of the six-tube versions and sometimes an extra IF amplifier tube.

# Tubes RF Amp BFO Converter IF Amp Det/Pre-amp Audio Amp Rectifier
4 X X X X
4 X X X X (selenium)
5 (standard) X X X X X
6 X X X X X X
6 X X X X X (push-pull) X
6 X X X X X X
8 X X X X X (push-pull) X X (push-pull) X
8 X X X X X X X (push-pull) X
8 X X X X X (push-pull) X X (push-pull) X
8 X X X X X X X (push-pull) X

Specific implementations

The basic design of the 'All-American Five' had its origins in low-cost sets produced in the early days of radio.

Early attempts

Radio manufacturers attempted to deviate from traditional heater voltages of 2.5, 5 and 6.3 volts to try and use a 5 tube heater scheme to get as close to 110-120 VAC line voltage. For the 1935 model year, designers were able to get a 5-tube heater string to total up to 78 volts. This meant that a dropping resistor or line ballast tube was needed to drop the remaining 35-42 volts. If a ballast tube was used, the radio would be marketed as a "6-tube" radio even though one was just a voltage dropping ballast. Other manufacturers used a "line cord resistor", a special AC cord made with resistance wire which replaced a power resistor in the radio chassis. These line cords tend to get warm to the touch after the radio was in use for a while.

During the 1935-36 model years examples of 5 tube (pre-octal base or prong tubes) series strings using 300 mA heaters were:

Later when newer tubes came out another variant was:

[6]

True 5-tube transformerless version

The very first set of metal tubes produced included 6-volt heater tubes that could be used to make a transformer-powered 6-tube radio. RCA released their first set of these metal octal tubes for this design in 1939, using 12.6-volt 150 mA heaters instead. The original design used the following tubes:

This series had the grids brought out as top caps on the signal tubes, and the 35Z4 did not have a provision for a dial light.

Single ended tube variant

AC/DC designs for 110-117V usually used 150mA heater current.

The tube array in the early days of single ended octal tubes was:

These sets were first marketed in late 1939. Canadian sets would sometimes use a 35L6 in place of the 50L6, as parts of Canada used 110 volts as a design standard. Because areas near Niagara Falls had 25 Hz power, some Canadian sets had slightly larger filter capacitors.

The "Loctal" variant

The tube line up of the Loctal tubes was:

Miniature tubes

After the Second World War the set was redesigned to use miniature 7-pin tubes and the line up became:

The 50C5, introduced in 1948, is electrically identical to the 50B5, but has a revised pinout to address concerns that high peak voltage between 4 (heater) and 5 (anode) would promote socket breakdown.[7]

In the postwar period, some makers built sets with a mixture of miniature, octal, and loctal types.

"Power-Saver" version

Another low-power variation changed the tube heaters to run on 100 milliamperes rather than 150 milliamperes. These tubes took a little longer to warm up:

The voltage distribution has changed around the tube heaters but the total is still a little more than the 120 volt mains supply. This line-up is for an Admiral radio.

Farm radio

A "farm radio" modification (usually done at the point of sale) allowed an AA5 to run off 32 volt DC, commonly generated by farm windmills. With a relatively simple rewiring, the tube heaters could be put in series-parallel to run off 32 volts, with the three twelve-volt heaters in series and a 25L6, 35L6 or 43 in parallel; the tubes would still function with the heater voltage somewhat out of specification. If run from a 32-volt supply the radio had a substantially reduced performance because the B+ voltage would only be 32 volts compared with 160-170 volts when operated from AC. With 32 volts on the plate, the radio tended to be insensitive.[8] Sometimes only the tube heater power was derived from a windmill, and dry batteries were retained for the plate voltage supply. The advantage was that the heaters were a high and continuous load on the battery, whereas the plate voltage battery drain was smaller and intermittent. Often a wet-cell rechargeable battery was used for tube heaters, recharged by a local garage or by exchanging with a vehicle battery.

Many 32-volt farm radios were factory-built for the purpose. They usually had two type 48 power tetrodes that could operate with B+ voltages as low as 28 volts. The type 48 pairs were parallel connected, or connected in push-pull. Some factory 32-volt radios used an electromechanical vibrator power supply to provide increased voltage. Vibrator power supplies could also be made to work from a 6 volt supply from a dedicated wind-charger or from a car battery borrowed from a farm vehicle.

Battery operated variants

A number of other versions of the set appeared, including some that did have a transformer, a version that operated in a motor vehicle off a 6-volt supply, using a vibrator to convert the 6V DC supply to AC which could feed a transformer with higher voltage output, and a version that operated from either dry batteries or the mains supply. The battery version commonly used tubes where the filament was heated by a single 1.5-volt dry cell and plate voltage was supplied by a (nominally) 90-volt battery.

One version, called a Three-way portable because it could be operated any of three ways: batteries, the AC line, or the DC line; typically had the following tube array:

This version used a 7.5 V A battery and a 90 V B battery. Note that the A battery did not need to heat the rectifier tube because, when operating from the batteries, the rectifier was not needed.

When operating on batteries, this version had almost instant warmup because of the tubes used their filaments as cathodes. This setup was common on Motorola portable radios commonly resembling metal "lunch boxes".

Variations

Since the AA5 was a minimalist design, there was plenty of room for enhanced versions, resulting in an "AA6":

There were even a few "AA4" designs, usually midget sets, only usable in strong-signal metropolitan areas, because most had no IF amplifier (although some replaced the rectifier tube with a selenium rectifier).

Series string order

According to various editions of the RCA Receiving Tube Manual, the heater string of an AC/DC radio should be arranged in a particular order to minimize hum. Assuming that all functions are performed by separate tubes, the heaters in the string should be arranged as follows:

  1. Input stage
  2. Ballast tube or resistor
  3. Rectifier
  4. Audio power output amplifier
  5. RF and IF amplifiers
  6. Converter
  7. First AF amplifier
  8. Detector
  9. Ground/B-minus line

Not all manufacturers followed this recommendation.

Effect on television design

Many black-and-white and color television receivers were built using All American Five principles, including a hot chassis and series-wired heaters. The designs were found primarily in portable or inexpensive sets ranging from the 1950s to even as late as the GE Portacolor series which was finally discontinued in the 1980s. Early sets tended to use selenium rectifiers in place of a tube; later sets used silicon diodes. Some of these sets were hybrid, using transistors for small signal applications and vacuum tubes in place of then-expensive power transistors. Some also included a rectifier diode in series with the tube filaments; when the set was off, the rectifier kept the filaments partially heated, a technique given a variety of names such as "Instant On".

Servicing precautions

Since the chassis of the set may be connected directly to the live side of the power line, service shops used an isolation transformer to protect technicians from a shock hazard. Some restorers will rewire the hot chassis set to put the chassis at neutral at all times. Some designs only require polarizing the plug, while others require rewiring the power supply to remove the switch from chassis ground. Power outlets must be wired properly for this modification to be protective.

See also

External links

Notes

  1. History of the AA5 (All American 5ive) AM tube radio This looks suspiciously like an enthusiasts web site (WP:ELNO).
  2. From a 120 volt DC supply, the highest voltage available to the radio's circuits is 120 volts DC. However, with a 120 volt AC supply, the alternating current reaches a peak value of 170 volts each cycle, so the radio's rectifier and filter capacitor can supply as much as 170 volts DC in with a 120 volt supply.
  3. Douglas, Alan, Radio Manufacturers of the 1920s (Vol. 1) Vestal, New York: Vestal Press, Ltd. (1988); Schiffer, Michael, The Portable Radio In American Life, Tucson: Univ. of Ariz. Press (1991)
  4. F. Langford Smith, The Radiotron Designer's Handbook, Third Edition, (1940), The Wireless Press, Sydney, Australia, no ISBN, no Library of Congress card , Chapter 19
  5. Typical schematic of a 1948 model AC/DC radio with a 220K isolation resistor.
  6. "Mallory Radio Service Encyclopedia- 6 Ed 1948, By P.R. Mallory & Co Inc"
  7. History of the AA5 (All American 5ive) AM tube radio This looks suspiciously like an enthusiasts web site (WP:ELNO).
  8. Lewis Coe, Wireless radio: a brief history, Mcfarland 1996 ISBN 0-7864-0259-8, page 39
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