AC/DC receiver design: Difference between revisions

Browse history interactively ← Previous editContent deleted Content addedVisual WikitextInline

Revision as of 22:00, 20 July 2012 editWtshymanski (talk \| contribs)Extended confirmed users76,122 edits rewrite out of point form← Previous edit		Latest revision as of 02:02, 15 June 2024 edit undoGreenC bot (talk \| contribs)Bots2,548,646 edits Move 1 url. Wayback Medic 2.5 per WP:URLREQ#angelfire.com
(246 intermediate revisions by 62 users not shown)
Line 1:		Line 1:
			{{Short description\|Type of power supply}}
	{{Refimprove\|date=February 2010}}
	]		]
	The description '''AC/DC''' refers to equipment designed to operate on either ] (AC) or ] (DC). This term typically describes certain types of ] ] or ] receivers. AC/DC equipment was necessary because in the early days of vacuum tubes, some regions were supplied with AC power, others with DC. Equipment which is able by its nature to use either AC or DC, e.g., heating devices and ]s, is not usually described as “AC/DC”.

			An '''AC/DC receiver design''' is a style of ] of ] radio or ]s that eliminated the bulky and expensive mains transformer. A side-effect of the design was that the receiver could in principle operate from a DC supply as well as an AC supply. Consequently, they were known as "AC/DC receivers".
	== Alternative and direct current ==
	] flows only in one direction. This is the type of current that is supplied by batteries, and was used in early central station generators for electric lights. ] regularly reverses direction, and is used in modern distribution systems since it can readily be changed in voltage with ]s. Electronic devices such as ]s and ]s are usually operated on direct current. One form of electric power can be converted to the other,using a motor-generator system or ] devices such as rectifiers and inverters. Some types of electric motor operate only on direct current, others can only operate on alternating current. Heating elements, and incandescent lamps, can operate on either direct current or alternating current of the same ] value.

	== Applicability to early radio and television ==		== Applicability to early radio and television ==
			In the early days of radio, ] was supplied at different voltages in different places, and either direct current (DC) or alternating current (AC) was supplied. There are three ways of powering electronic equipment. AC-only equipment would rely on a transformer to provide the voltages for heater and plate circuits. AC/DC equipment would connect all the tube heaters in series to match the supply voltage; a ] would convert AC to the direct current required for operation. When connected to a DC supply, the rectifier stage of the power supply performed no active function. DC-only equipment would only run from a DC supply and included no rectifier stage. DC is almost never used in mains power distribution anymore.

			Different radio set models were required for AC, DC mains, and ] operation. For example, a 1933 ] with essentially the same circuit had different models for AC supply, DC supply, and battery operation.<ref> {{Webarchive\|url=https://web.archive.org/web/20200217040016/http://www.classicwireless.co.uk/Murphy_A4.htm \|date=2020-02-17 }}. Classicwireless.co.uk. Anonymous. Retrieved June 21, 2013.</ref> The introduction of AC/DC circuitry allowed a single model to be used on either AC or DC mains as a selling point,<ref> {{Webarchive\|url=https://web.archive.org/web/20200217213434/http://www.classicwireless.co.uk/sunbeama.htm \|date=2020-02-17 }} Classicwireless.co.uk. Anonymous. Retrieved June 21, 2013. (Offers AC/DC operation as a selling point).</ref> and some such models added "Universal" to their name<ref> {{Webarchive\|url=https://web.archive.org/web/20160303230301/http://www.classicwireless.co.uk/deccaa.htm \|date=2016-03-03 }}. Classicwireless.co.uk. Anonymous. Retrieved June 21, 2013.</ref> (such sets usually had user-settable voltage tapping arrangements to cater for the wide range of voltages).<ref> (PDF). ] Pty, Ltd. February 22, 1952. Via KevinChant.com. Retrieved June 21, 2013. (Manual of 1952 Astor with instructions on use with AC and DC mains of different voltages)</ref>
	Vacuum tube equipment used a number of tubes, each with a heater requiring a certain amount of electrical power. Tubes require relatively high voltages on some of their ]s; these voltages can conveniently be derived directly from ]. There are three ways of ] such equipment:
	# AC equipment: a ] converts mains electricity into both a low-voltage (typically 6.3V) supply connected to the ]-connected heaters of all the tubes in the equipment, and one or more high-voltage supplies which are ] and filtered to give high DC voltages required by the equipment. Transformers operate on AC only, so that this type of equipment is AC-only.
	# AC/DC equipment: the heaters of all the tubes are connected in ]. All the tubes are rated at the same current (typically 100, 150, 300, or 450mA) but at different voltages. If necessary, ] (which can be a ] (barretter), power ] or resistive cable are added so that, when the mains voltage is applied across the chain, the required current flows.<ref></ref> With mains voltages of around 220V, the power dissipated by the additional resistance and the voltage drop across it could be quite high, and it was common to use a resistive power cable (mains cord) of defined resistance, running warm, rather than putting a hot resistor inside the case. A rectifier and a ] are connected directly to the mains. If the mains power is AC, the rectifier converts it to DC. If it's DC, the rectifier effectively acts as a conductor. In both cases DC at about the same voltage as the mains is available to drive the circuitry. The tube heaters do just as their name describes and heat the ]s, whether AC or DC power is applied. There is no transformer to isolate AC/DC equipment from the mains. Much equipment was built on a metal ] which had to be connected to one side of the mains.<ref></ref> A typical low-cost radio would have 5 tubes, plus a ballast built into an envelope like a tube that was easily replaceable.<ref></ref>
	# DC-only from DC mains (no longer applicable: ''see ]'').
	The operation of the power supply is further described in ].

			The first ever AC/DC design of radio was the ]. The sole aim of the design was to eliminate the mains transformer.<ref>. ''Fun with Tubes.'' Max Robinson. Angelfire.com. Retrieved June 21, 2013. (Third sentence.)</ref><!-- Even some of the other references in this article say the same thing ---><ref> {{Webarchive\|url=https://web.archive.org/web/20170424082127/http://home.netcom.com/~wa2ise/radios/aa5h.html \|date=2017-04-24 }}. WA2ISE personal webpage. Netcom.com. Retrieved June 21, 2013.</ref> The lower cost of transformerless designs remained popular with manufacturers long after DC power distribution had disappeared. Several models were produced which dispensed with the power transformer, but had circuit features which only allowed operation from AC.<ref name=super8/><ref name=B18T/> Some early models were available in both AC-only and AC/DC versions, with the AC/DC versions sometimes slightly more expensive.<ref>. ] Co. Retrieved June 21, 2013. (Showing AC/DC models {{GBP}}0.5.0 (about 2%) more expensive than AC only.)</ref>
	AC/DC equipment was suitable for use on either AC or DC, an important consideration when DC distribution was still used. Manufacturers were able to produce a single range of equipment for all power, and users did not have problems when moving house. Because no power transformer was used, so-called "hot chassis" construction was required and the equipment power supply was conductively connected to the input power source. Any exposed metal on the device connected to the circuit common was also connected to the power supply. For safety, no exposed metal could be connected to the circuit common. Service personnel working on energized equipment had to be mindful that the chassis could be at line potential with respect to earth ground.

			Television receivers were first commercially sold in England in 1936 for the new 'Television Service' broadcast by the ]. All pre World War II sets used mains transformers and consequently were AC only. In 1948 Pye released the first television receiver, the B18T, to employ the AC/DC design<ref>{{cite web \|url=http://www.scienceandsociety.co.uk/results.asp?image=10251132 \|title=Image of pye television receiver, type b18t, 1948. by Science & Society Picture Library (of Science Museum Group)\|website=Scienceandsociety.co.uk \|date= \|author= \|accessdate= 19 July 2016}}</ref> to eliminate the mains transformer when operated off 240 V mains.<ref name=ef50>{{cite web \|url=http://www.r-type.org/timeline/time-028.htm \|title=Pye B18T AC/DC Television Chassis \|newspaper=Wireless World\|date=September 1948\|author= \|accessdate= 17 July 2016}} "The set is the first on the market in which this technique has been applied to television."</ref> While sufficient for radio, the voltage was not high enough to power some television circuits, so energy was recovered during the flyback period from the primary of the ] to provide a boosted HT supply;<ref>PAL Receiver servicing, D.J.Seal, 8, 175, pub. Foulsham & Co Ltd. 1971, {{ISBN\|0-572-00790-6}}</ref> this was not possible with a lower mains supply voltage—even 220 V was insufficient. Pye's marketing material did not mention the set's ability to operate from a DC supply, possibly because there were no DC supplies within the reception range of ], then Britain's only operating transmitter. Other manufacturers adopted the design; they, and later also Pye, sold them as AC/DC sets; the technique was used for many decades.
⚫	~~If a resistive power cable was used, an inexpert repairer might replace it by a standard cable, or use the wrong length, damaging equipment and risking fire.~~ AC/DC equipment did not require a transformer, and was consequently cheaper, lighter, and smaller than comparable AC equipment. This type of equipment continued to be produced long after AC became the universal standard due to its cost advantage over AC-only, and was only discontinued when vacuum tubes were replaced by low-voltage solid-state electronics.
	* Older AC-only equipment uses a bulky, heavy, and expensive 50- or 60-Hz transformer, but the chassis is never live and can be earthed, making for safer operation. Additionally, the use of a transformer allowed higher voltages to be generated (e.g., for high-powered ]s), and allowed multiple independent power supplies from separate transformer windings for different stages.
	* DC-only equipment was a little cheaper than AC/DC, but became obsolete as AC power became dominant.

	===~~Regional~~ ~~variations~~===		===Series tube heaters===
			Vacuum tube equipment used a number of tubes, each with a heater requiring a certain amount of electrical power. In AC/DC equipment, the heaters of all the tubes are connected in ]. All the tubes are rated at the same current (typically 100, 150, 300, or 450 ]) but at different voltages, according to their heating power requirements. If necessary, ] (which can be a ] (]), a power ] or a resistive mains lead are added so that, when the mains voltage is applied across the chain, the specified heating current flows.<ref> {{webarchive \|url=https://web.archive.org/web/20140316144326/http://www.antiqueradios.com/features/ballast.shtml \|date=March 16, 2014 }}. ''Radio Craft'' (from National Union Radio Corp), January 1939. Via Antiqueradios.com.</ref> Some types of ballast resistors were built into an envelope like a tube that was easily replaceable.<ref> {{webarchive \|url=https://web.archive.org/web/20110629192342/http://www.scottbecker.net/tube/sheets/046/suppinfo/03a/254-258.pdf \|date=June 29, 2011 }} (PDF). '' {{webarchive \|url=https://web.archive.org/web/20110629153652/http://scottbecker.net/tube/sheets/046/suppinfo/03a.html \|date=June 29, 2011 }}''. Philips Technical Library. p. 254-258. Ed. N.S. Markus & J. Otte. Elsevier Press. 1952 (English edition). (With ballast (barretter), detailed description and circuit diagram. Retrieved June 21, 2013.</ref> With mains voltages of around 220 V, the power dissipated by the additional resistance and the voltage drop across it could be quite high, and it was common to use a resistive power cable (mains cord) of defined resistance, running warm, rather than putting a hot resistor inside the case. If a resistive power cable was used, an inexperienced repairer might replace it with a standard cable, or use the wrong length, damaging the equipment and risking a fire.
⚫	In the past, ~~110-120V~~ was not high enough for ~~high~~-power audio and television applications~~. Therefore~~, it ~~was~~ ~~used~~ to operate low-power audio equipment such as radio receivers. Higher-powered ~~110-120V~~ ~~tube~~ audio or television equipment needed higher voltages which ~~had~~ to be ~~stepped~~ up ~~by a~~ transformer power supply, or sometimes a ], therefore operating off AC only.

			===Transformer===
	Some AC/DC equipment was designed to be switchable to be able to operate off either 110 V AC (possibly with a voltage doubler) or 220-240V AC or DC.<ref></ref> Television receivers were produced to run off 240V AC or DC.<ref></ref> The voltage was not high enough to power some of the circuits, so it was boosted with energy recovered from the deflection coils during ]. Some details of the way the voltage was boosted are to be found in a technical description of the 1951 Bush TV22.<ref></ref> AC/DC televisions were produced well into the color and semiconductor era (sets were tube/semiconductor hybrids).
		⚫	AC/DC equipment did not require a transformer, and was consequently cheaper, lighter, and smaller than comparable AC equipment. This type of equipment continued to be produced long after AC became the universal standard due to its cost advantage over AC-only, and was only discontinued when vacuum tubes were replaced by low-voltage solid-state electronics.

			A ] and a filter capacitor were connected directly to the mains. If the mains power was AC, the rectifier converted it to DC. If it was DC, the rectifier effectively acted as a conductor. When operating on DC, the voltage available was reduced by the voltage drop across the rectifier. Because an AC waveform has a voltage peak that is higher than the average value produced by the rectifier, the same set operating on the same ] AC supply voltage would have a higher effective voltage after the rectifier stage. In areas using 110–120 volt AC, a simple half-wave rectifier limited the maximum plate voltage that could be developed; this was adequate for relatively low-power audio equipment, but television receivers or higher-powered amplifiers required either a more complex ] rectifier or warranted the use of a power transformer with a conveniently high secondary voltage. Areas with 220–240 volt AC supplies could develop higher plate voltage with a simple rectifier. Transformerless power supplies were feasible for television receivers in 220–240 volt areas. Additionally, the use of a ] allowed multiple independent power supplies from ] for different stages.
	==Motorized tools and appliances==
	Many hand-held power tools or small kitchen appliances use ]s. When DC distribution was still used, some motorized appliances were name-plated for operation both on DC and AC systems. The universal motor connects its field in series with the armature. The motor is small enough that the reversal of magnetic fields in both the armature and field occur at almost the same time, meaning the motor can run equally well on both types of current. Although modern tools and appliances often still use lightweight and powerful universal motors, they are no longer rated for operation on DC systems, usually because the switch is only suitable for AC. Safety standards no longer test for DC operation, switching devices in AC-only appliances are smaller and unsuitable for DC circuits of the same current, and many modern power tools and appliances incorporate AC-only speed control based on ]s that will not work on direct current supplies.

			In an AC/DC design there was no transformer to isolate the equipment from the mains. Much equipment was built on a metal ] which was connected to one side of the mains.<ref>. ''CHRS Journal''. California Historical Radio Society. Via Antiqueradios.com.</ref> Because no power transformer was used, "hot chassis" construction was required: one of the mains power lines became the negative side of the power supply, connected to the chassis, and all metal parts in metallic contact with it, as common "ground". With AC power, the neutral, rather than live, line should be connected to the chassis; touching it, while highly undesirable, is usually relatively safe—the neutral conductor is normally at or near earth potential. But if used with a two-pin power plug (or an incorrectly wired three-pin one), any metal that the user could touch was an electrocution hazard, connected to mains live. Consequently equipment was made with no metal connected to the chassis exposed even in predictable abnormal situations, such as when a plastic knob came off a metal shaft, or small fingers poked through ventilation holes. Service personnel working on energized equipment had to use an isolation transformer for safety, or be mindful that the chassis could be live. AC-only vacuum tube equipment used a bulky, heavy, and expensive transformer, but the chassis was not connected to the supply conductors and could be earthed, making for safe operation.
	==Modern equipment==

	Since ] displaced vacuum tubes, circuits required high currents at relatively low voltages, and the use of transformers has become almost universal. The decreasing cost of complex electronics, with massive functionality available in a single, cheap, ] has made it feasible to power equipment safely from either AC or DC mains without a conventional mains transformer. The supply is rectified and filtered if AC, and ] whose output is connected to the primary winding of a small, cheap, high-frequency transformer (which is often part of the tuned circuit used by the oscillator) which isolates the circuitry of the equipment from the mains electricity. In principle, modern AC/DC equipment would be no more complex or costly than AC-only. In practice, DC mains electricity is no longer used, and DC operation direct from the mains is irrelevant.
			Transformerless "hot chassis" televisions continued to be commonly manufactured long after transistorisation rendered live-chassis design obsolete in radios. By the 1990s, inclusion of ] input jacks required elimination of the ] as TVs needed to be interconnectable with VCRs, game consoles and video disc players. The widespread replacement of ]s with ]s after the turn of the millennium resulted in televisions using primarily low voltages, obtained from ]. The potentially-hazardous "floating chassis" was no more.
	Although unrelated to AC/DC as used in the past, modern equipment is often powered from low-voltage DC, typically a 12V battery in a ]. Much equipment operates from 12V or less, but an ] can be used to provide AC output or a ] based on a ] (SMPS) for higher DC output. Modern SMPSes can accept a DC input without any problem, though the DC voltage does need to be around 25% higher than the rated RMS AC voltage{{Citation needed\|date=September 2008}}.

			===Regional variations===
		⚫	In the past, 110–120 V was not high enough for higher-power tube audio and television applications, and only suitable to operate low-power radio and audio equipment such as radio receivers. Higher-powered 110–120 V audio or television equipment needed higher voltages, which were obtained using a step-up transformer based power supply, or sometimes an AC ], therefore operating off AC only.

			Some AC/DC equipment was designed to be switchable to be able to operate off either 110 V AC (possibly with a voltage doubler) or 220–240 V AC or DC.<ref name=super8> {{webarchive \|url=https://web.archive.org/web/20110629190705/http://www.scottbecker.net/tube/sheets/046/suppinfo/03a/264-269.pdf \|date=June 29, 2011 }} '' {{webarchive \|url=https://web.archive.org/web/20110629153652/http://scottbecker.net/tube/sheets/046/suppinfo/03a.html \|date=June 29, 2011 }}''. Philips Technical Library. p. 264-269. Ed. N.S. Markus & J. Otte. Elsevier Press. 1952 (English edition).(Detailed description and circuit diagram)</ref> Television receivers were produced which could run off 240 V AC or DC.<ref name=B18T>{{Cite web \|title=Pye B18T AC/DC Television Chassis \|author= \|website=The National Valve Museum \|publisher=] \|date=December 1948 \|access-date=21 April 2021 \|url= http://www.r-type.org/timeline/time-028.htm }} True AC/DC 240V monochrome TV. For 190–220 V AC operation needed an additional autotransformer. DC operation was possible, but was not an advertised feature; the transformerless design was to save size and weight.</ref> The voltage was not high enough to power some circuits, so energy was recovered during the flyback period from the primary of the ] to provide a boosted ] (high tension) supply.<ref>Seal, D.J. (1971). . Foulsham Technical Books / Thorn Radio Valves & Tubes Ltd. 1971. pp. 173–174. Via Archive.org.</ref> In a typical vacuum tube colour TV set, the line output stage had to boost its own HT supply to between 900 and 1200 volts (depending on screen size and design).<ref>Seal, 1971, p. 173.</ref> Transistor line output stages, although not requiring supply voltages above the rectified mains voltage, nevertheless still developed extra voltage over the normal supply rail to avoid complicating the power supply circuitry. A typical transistor stage would produce between 20 and 50 'extra' volts.<ref>This is the range from a large collection of TV servicing data. 20 volts is the ITT FS12 (12″ B&W), and 50 volts is the BRC2000 chassis used in a fair number of early transistorised 25″ colour TV sets.</ref><!-- Extend the range if you can find data to support it ---> Some details of the way in which the nominally 190 volts HT supply was boosted to nearly 500 volts in the 1951 Bush TV22 are described in a technical publication.<ref name=TV22>{{cite web\|url=http://www.domino405.co.uk/documents/TV22_TV1979.pdf \|title=Vintage TV: The Bush Model TV22 \|first=Malcolm \|last=Burrell \|work=Television \|location=UK \|date=December 1979 \|pages=88–89 \|format=PDF \|archiveurl=https://web.archive.org/web/20120323074902/http://www.domino405.co.uk/documents/TV22_TV1979.pdf \|archivedate=2012-03-23 \|url-status=dead \|via=domino405.co.uk <!-- "Reproduced with the author's permission": see http://web.archive.org/web/20080417082010/http://www.domino405.co.uk/technical.html --> \|accessdate=2013-06-21}}</ref> AC/DC televisions were produced well into the color and semiconductor era (some sets were tube/semiconductor hybrids).

			==Transistor radios==
			With widespread adoption of solid-state design in the 1970s, voltage and power requirements for tabletop portable radio receivers dropped significantly. One common approach was to design a battery-powered radio (typically 6 volts DC from four ]s) but include a small built-in ] and ] to allow ] (120 V or 240 V AC, depending on region) as an alternative to battery-powered operation.

	==See also==		==See also==
	{{Portal\|Electronics~~\|Energy~~}}		{{Portal\|Electronics}}
	* ]
	* ]
	* ]
	* ]

	==Notes and references==		==Notes and references==
			{{reflist\|33em}}
	<references/>

	{{DEFAULTSORT:Ac/Dc ~~(Electricity)~~}}		{{DEFAULTSORT:Ac Dc Receiver Design}}
⚫	]
	]		]
		⚫	]

			]
	]

Latest revision as of 02:02, 15 June 2024

Type of power supply

So-called "All American Five" vacuum tube radio receivers used a power supply that could work on either AC or DC

An AC/DC receiver design is a style of power supply of vacuum tube radio or television receivers that eliminated the bulky and expensive mains transformer. A side-effect of the design was that the receiver could in principle operate from a DC supply as well as an AC supply. Consequently, they were known as "AC/DC receivers".

Applicability to early radio and television

In the early days of radio, mains electricity was supplied at different voltages in different places, and either direct current (DC) or alternating current (AC) was supplied. There are three ways of powering electronic equipment. AC-only equipment would rely on a transformer to provide the voltages for heater and plate circuits. AC/DC equipment would connect all the tube heaters in series to match the supply voltage; a rectifier would convert AC to the direct current required for operation. When connected to a DC supply, the rectifier stage of the power supply performed no active function. DC-only equipment would only run from a DC supply and included no rectifier stage. DC is almost never used in mains power distribution anymore.

Different radio set models were required for AC, DC mains, and battery operation. For example, a 1933 Murphy radio with essentially the same circuit had different models for AC supply, DC supply, and battery operation. The introduction of AC/DC circuitry allowed a single model to be used on either AC or DC mains as a selling point, and some such models added "Universal" to their name (such sets usually had user-settable voltage tapping arrangements to cater for the wide range of voltages).

The first ever AC/DC design of radio was the All American Five. The sole aim of the design was to eliminate the mains transformer. The lower cost of transformerless designs remained popular with manufacturers long after DC power distribution had disappeared. Several models were produced which dispensed with the power transformer, but had circuit features which only allowed operation from AC. Some early models were available in both AC-only and AC/DC versions, with the AC/DC versions sometimes slightly more expensive.

Television receivers were first commercially sold in England in 1936 for the new 'Television Service' broadcast by the British Broadcasting Corporation. All pre World War II sets used mains transformers and consequently were AC only. In 1948 Pye released the first television receiver, the B18T, to employ the AC/DC design to eliminate the mains transformer when operated off 240 V mains. While sufficient for radio, the voltage was not high enough to power some television circuits, so energy was recovered during the flyback period from the primary of the line output transformer to provide a boosted HT supply; this was not possible with a lower mains supply voltage—even 220 V was insufficient. Pye's marketing material did not mention the set's ability to operate from a DC supply, possibly because there were no DC supplies within the reception range of Alexandra Palace television station, then Britain's only operating transmitter. Other manufacturers adopted the design; they, and later also Pye, sold them as AC/DC sets; the technique was used for many decades.

Series tube heaters

Vacuum tube equipment used a number of tubes, each with a heater requiring a certain amount of electrical power. In AC/DC equipment, the heaters of all the tubes are connected in series. All the tubes are rated at the same current (typically 100, 150, 300, or 450 mA) but at different voltages, according to their heating power requirements. If necessary, resistance (which can be a ballast tube (barretter), a power resistor or a resistive mains lead are added so that, when the mains voltage is applied across the chain, the specified heating current flows. Some types of ballast resistors were built into an envelope like a tube that was easily replaceable. With mains voltages of around 220 V, the power dissipated by the additional resistance and the voltage drop across it could be quite high, and it was common to use a resistive power cable (mains cord) of defined resistance, running warm, rather than putting a hot resistor inside the case. If a resistive power cable was used, an inexperienced repairer might replace it with a standard cable, or use the wrong length, damaging the equipment and risking a fire.

Transformer

AC/DC equipment did not require a transformer, and was consequently cheaper, lighter, and smaller than comparable AC equipment. This type of equipment continued to be produced long after AC became the universal standard due to its cost advantage over AC-only, and was only discontinued when vacuum tubes were replaced by low-voltage solid-state electronics.

A rectifier and a filter capacitor were connected directly to the mains. If the mains power was AC, the rectifier converted it to DC. If it was DC, the rectifier effectively acted as a conductor. When operating on DC, the voltage available was reduced by the voltage drop across the rectifier. Because an AC waveform has a voltage peak that is higher than the average value produced by the rectifier, the same set operating on the same root mean square AC supply voltage would have a higher effective voltage after the rectifier stage. In areas using 110–120 volt AC, a simple half-wave rectifier limited the maximum plate voltage that could be developed; this was adequate for relatively low-power audio equipment, but television receivers or higher-powered amplifiers required either a more complex voltage doubler rectifier or warranted the use of a power transformer with a conveniently high secondary voltage. Areas with 220–240 volt AC supplies could develop higher plate voltage with a simple rectifier. Transformerless power supplies were feasible for television receivers in 220–240 volt areas. Additionally, the use of a transformer allowed multiple independent power supplies from separate transformer windings for different stages.

In an AC/DC design there was no transformer to isolate the equipment from the mains. Much equipment was built on a metal chassis which was connected to one side of the mains. Because no power transformer was used, "hot chassis" construction was required: one of the mains power lines became the negative side of the power supply, connected to the chassis, and all metal parts in metallic contact with it, as common "ground". With AC power, the neutral, rather than live, line should be connected to the chassis; touching it, while highly undesirable, is usually relatively safe—the neutral conductor is normally at or near earth potential. But if used with a two-pin power plug (or an incorrectly wired three-pin one), any metal that the user could touch was an electrocution hazard, connected to mains live. Consequently equipment was made with no metal connected to the chassis exposed even in predictable abnormal situations, such as when a plastic knob came off a metal shaft, or small fingers poked through ventilation holes. Service personnel working on energized equipment had to use an isolation transformer for safety, or be mindful that the chassis could be live. AC-only vacuum tube equipment used a bulky, heavy, and expensive transformer, but the chassis was not connected to the supply conductors and could be earthed, making for safe operation.

Transformerless "hot chassis" televisions continued to be commonly manufactured long after transistorisation rendered live-chassis design obsolete in radios. By the 1990s, inclusion of audio-video input jacks required elimination of the floating ground as TVs needed to be interconnectable with VCRs, game consoles and video disc players. The widespread replacement of cathode ray tubes with liquid crystal displays after the turn of the millennium resulted in televisions using primarily low voltages, obtained from switching power supplies. The potentially-hazardous "floating chassis" was no more.

Regional variations

In the past, 110–120 V was not high enough for higher-power tube audio and television applications, and only suitable to operate low-power radio and audio equipment such as radio receivers. Higher-powered 110–120 V audio or television equipment needed higher voltages, which were obtained using a step-up transformer based power supply, or sometimes an AC voltage doubler, therefore operating off AC only.

Some AC/DC equipment was designed to be switchable to be able to operate off either 110 V AC (possibly with a voltage doubler) or 220–240 V AC or DC. Television receivers were produced which could run off 240 V AC or DC. The voltage was not high enough to power some circuits, so energy was recovered during the flyback period from the primary of the line output transformer to provide a boosted HT (vacuum tube) (high tension) supply. In a typical vacuum tube colour TV set, the line output stage had to boost its own HT supply to between 900 and 1200 volts (depending on screen size and design). Transistor line output stages, although not requiring supply voltages above the rectified mains voltage, nevertheless still developed extra voltage over the normal supply rail to avoid complicating the power supply circuitry. A typical transistor stage would produce between 20 and 50 'extra' volts. Some details of the way in which the nominally 190 volts HT supply was boosted to nearly 500 volts in the 1951 Bush TV22 are described in a technical publication. AC/DC televisions were produced well into the color and semiconductor era (some sets were tube/semiconductor hybrids).

Transistor radios

With widespread adoption of solid-state design in the 1970s, voltage and power requirements for tabletop portable radio receivers dropped significantly. One common approach was to design a battery-powered radio (typically 6 volts DC from four dry cells) but include a small built-in step down transformer and rectifier to allow mains electricity (120 V or 240 V AC, depending on region) as an alternative to battery-powered operation.

Notes and references

"Murphy Radio Model A4 From 1933" Archived 2020-02-17 at the Wayback Machine. Classicwireless.co.uk. Anonymous. Retrieved June 21, 2013.
"Sunbeam radio" Archived 2020-02-17 at the Wayback Machine Classicwireless.co.uk. Anonymous. Retrieved June 21, 2013. (Offers AC/DC operation as a selling point).
"Decca 'Universal 55' radio" Archived 2016-03-03 at the Wayback Machine. Classicwireless.co.uk. Anonymous. Retrieved June 21, 2013.
"Technical Bulletin: Model 'PS'" (PDF). Astor Radio Corporation Pty, Ltd. February 22, 1952. Via KevinChant.com. Retrieved June 21, 2013. (Manual of 1952 Astor with instructions on use with AC and DC mains of different voltages)
"The All American Five". Fun with Tubes. Max Robinson. Angelfire.com. Retrieved June 21, 2013. (Third sentence.)
"History of the AA5 (All American 5ive) AM tube radio" Archived 2017-04-24 at the Wayback Machine. WA2ISE personal webpage. Netcom.com. Retrieved June 21, 2013.
^ "An eight-valve 110 V AC or 220 V AC/DC superheterodyne receiver with push-pull output stage" Archived June 29, 2011, at the Wayback Machine Data and Circuits of Radio Receiver and Amplifier Valves IIIa Archived June 29, 2011, at the Wayback Machine. Philips Technical Library. p. 264-269. Ed. N.S. Markus & J. Otte. Elsevier Press. 1952 (English edition).(Detailed description and circuit diagram)
^ "Pye B18T AC/DC Television Chassis". The National Valve Museum. Wireless World. December 1948. Retrieved 21 April 2021. True AC/DC 240V monochrome TV. For 190–220 V AC operation needed an additional autotransformer. DC operation was possible, but was not an advertised feature; the transformerless design was to save size and weight.
"1935 catalogue". Murphy Radio Co. Retrieved June 21, 2013. (Showing AC/DC models £0.5.0 (about 2%) more expensive than AC only.)
"Image of pye television receiver, type b18t, 1948. by Science & Society Picture Library (of Science Museum Group)". Scienceandsociety.co.uk. Retrieved 19 July 2016.
"Pye B18T AC/DC Television Chassis". Wireless World. September 1948. Retrieved 17 July 2016. "The set is the first on the market in which this technique has been applied to television."
PAL Receiver servicing, D.J.Seal, 8, 175, pub. Foulsham & Co Ltd. 1971, ISBN 0-572-00790-6
"All About Ballast and Resistor Tubes" Archived March 16, 2014, at the Wayback Machine. Radio Craft (from National Union Radio Corp), January 1939. Via Antiqueradios.com.
"VII. A five-valve receiver for AC/DC mains" Archived June 29, 2011, at the Wayback Machine (PDF). Data and Circuits of Radio Receiver and Amplifier Valves IIIa Archived June 29, 2011, at the Wayback Machine. Philips Technical Library. p. 254-258. Ed. N.S. Markus & J. Otte. Elsevier Press. 1952 (English edition). (With ballast (barretter), detailed description and circuit diagram. Retrieved June 21, 2013.
"Resistive Line Cords And Ballast Tubes". CHRS Journal. California Historical Radio Society. Via Antiqueradios.com.
Seal, D.J. (1971). The MAZDA Book of PAL Receiver Servicing. Foulsham Technical Books / Thorn Radio Valves & Tubes Ltd. 1971. pp. 173–174. Via Archive.org.
Seal, 1971, p. 173.
This is the range from a large collection of TV servicing data. 20 volts is the ITT FS12 (12″ B&W), and 50 volts is the BRC2000 chassis used in a fair number of early transistorised 25″ colour TV sets.
Burrell, Malcolm (December 1979). "Vintage TV: The Bush Model TV22" (PDF). Television. UK. pp. 88–89. Archived from the original (PDF) on 2012-03-23. Retrieved 2013-06-21 – via domino405.co.uk.

Categories: