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In electronics, a vacuum tube, electron tube (in North America), or thermionic valve (elsewhere, especially in Britain) is a device that relies on the flow of electric current through a vacuum. Vacuum tubes may be used for rectification, amplification, switching, or similar processing or creation of electrical signals. Vacuum tubes rely on thermionic emission of electrons from a hot filament or cathode, that then travel through a vacuum toward a positively-charged anode or plate. Additional electrodes interposed between the cathode and anode can alter the current flow, making the device an amplifier.

Vacuum tubes were critical to the development of electronic technology, which drove the expansion and commercialization of radio communication and broadcasting, television, radar, sound reproduction, large telephone networks, analog and digital computers, and industrial process control. Although some of these applications had counterparts using earlier technologies, such as the spark gap transmitter or mechanical computers, it was the invention of the triode vacuum tube and its capability of electronic amplification that made these technologies widespread and practical.

For the most part vacuum tubes have been replaced by solid-state devices such as transistors and other semiconductor devices. Solid-state devices last much longer, are smaller, more efficient, more reliable, and cheaper than equivalent vacuum tube devices. However, tubes still find particular uses where solid state devices have not been developed or are not practical. Tubes are still produced for such applications and to replace those used in existing equipment such as high-power radio transmitters.

Classification

Vacuum tubes with two active elements ("diodes") are used for rectification. Ones with 3 or more elements ("triodes", "tetrodes", etc.) are used for amplification or functions which rely on amplification such as oscillators. Tubes used in consumer electronic equipment are often classified as "receiving tubes," as opposed to the much larger "transmitting tubes" used to generate high power radio signals for transmission. This article covers these components which are used as elements of electronic circuits.

On the other hand there are vacuum tubes used in different manners, such as cathode ray tubes which create a beam of electrons for display purposes (such as the television picture tube) in addition to more specialized functions such as electron microscopy and electron beam lithography. X-ray tubes are also vacuum tubes. Phototubes and photomultipliers also rely on electron flow through a vacuum, though in this case the emission of electrons from the cathode depends on energy from photons rather than thermionic emission. Since these sorts of "vacuum tubes" have functions other than electronic amplification and rectification they are described in their own articles.

Modern applications

Specialized applications for amplifying vacuum tubes continue to this day, such as the magnetron which is used to generate microwave energy in the household microwave oven and some radar systems. The klystron is commonly deployed by broadcasters as a high-power UHF television transmitting tube. Hi-fi equipment using tubes is still popular among certain audiophiles for its distinct sound signature and other tube equipment is maintained for its aesthetic appeal.

Gas-filled tubes

There are also varieties of current-conducting tubes filled with one or another gas at a higher or lower pressure; the common fluorescent bulb is a familiar example. Such discharge tubes and cold cathode tubes are not vacuum tubes and are not the subject of this article. However certain types such as the voltage regulator tube and thyristor physically resemble commercial vacuum tubes and fit in sockets designed for vacuum tubes. Their distinctive orange, red, or purple glow during operation betrays the presence of gas; electrons flowing in a vacuum do not produce light within that region. Although not properly termed vacuum tubes, they may still be referred to as "electron tubes" as they do perform electronic functions, and are briefly discussed below under "Special-purpose tubes."

Description

A vacuum tube consists of two or more electrodes in a vacuum inside an airtight enclosure. Most tubes have glass envelopes, though ceramic and metal envelopes (atop insulating bases) have also been used. The electrodes are attached to leads which pass through the envelope via an airtight seal. On most tubes, the leads, in the form of pins, plug into a tube socket for easy replacement of the tube. (Tubes were by far the most common cause of failure in electronic equipment, and consumers were expected to be able to replace tubes themselves).

Vacuum tube diode: electrons from the hot cathode flow towards positive anode, but not visa versa.

The earliest vacuum tubes resembled, and in fact evolved from incandescent light bulbs, containing a filament sealed in an evacuated glass envelope. When hot, the filament releases electrons into the vacuum, a process called thermionic emission. These electrons will be drawn to a more positive electrode, the anode or plate. The result is a net flow of electrons from filament to plate. However current cannot flow in the reverse direction because the plate is not heated and does not emit electrons. Such a tube with only two electrodes is termed a diode, and is used for rectification. Since current can only pass in one direction, such a diode (or rectifier) will convert AC to DC. This is therefore used in a DC power supply, but is also used as a demodulator of amplitude modulated (AM) radio signals, and similar functions.

While early tubes used the directly-heated filament as the cathode, most (but not all) more modern tubes employed indirect heating. A separate element was used for the cathode. Inside the cathode, and insulated from it, was the filament or heater. The heater warmed the cathode sufficiently to undergo thermionic emission, but avoided any electrical connection. This allowed the tubes in a radio set to be heated through a common circuit, while allowing each cathode to arrive at a voltage independly of the others, removing an unwelcome constraint on circuit design.

During operation vacuum tubes require constant heating of the filament, so that they require considerable power even when amplifying signals at the microwatt level. In most amplifiers further power is consumed due to the quiescent current between the cathode and the plate (anode), resulting in heating of the plate. In a power amplifier heating of the plate can be quite considerable, and has a potential for self-destruction if the tube is driven beyond its safe limits. Since the tube requires a vacuum to operate, convection cooling of the plate is not generally possible (except in special applications where the anode forms a part of the vacuum envelope; this is avoided in consumer products due to the shock hazard it entails). Thus anode cooling occurs mainly through black-body radiation.

Vacuum tube triode: voltage applied to the grid controls plate current.

With the exception of diode tubes, another electrode, called a control grid, is placed between the cathode and the plate. The vacuum tube is then known as a "triode." With additional grids they are called tetrode, pentode, etc. These intervening electrodes are all called grids as they are not solid electrodes but sparse elements through which electrons can pass on their way to the plate. The control grid (and sometimes other grids) turn the diode into a voltage-controlled device, that is, the voltage that is applied to the control grid will affect the current flow between the cathode and the plate. A negative electrostatic field from the control grid repels electrons emitted by the cathode, rather than allowing them to continue toward the plate, thus reducing or even completely stopping the current flow. As long as the control grid stays more negative than the cathode, essentially no current flows into it, yet a change of several volts on the control grid is sufficient to make a large difference in the plate current, possibly changing the output by hundreds of volts (depending on the load of the circuit). The solid-state device most closely resembling the pentode tube is the JFET, although vacuum tubes typically operate at over a hundred volts, unlike most semiconductors in most applications.

History and development

Early RCA triode vacuum tube, type 808

The 19th century saw increasing research with evacuated tubes, such as the Geissler and Crookes tubes. Famous scientists who experimented with such tubes included Thomas Edison, Eugen Goldstein, Nikola Tesla, and Johann Wilhelm Hittorf among many others. With the exception of early light bulbs, such tubes were only used in scientific research or as novelties. The groundwork laid by these scientists and inventors, however, was critical to the development of subsequent vacuum tube technology.

Although thermionic emission was originally reported in 1873 by Frederick Guthrie, it was Thomas Edison's 1884 investigation that spurred future research, the phenomenon thus becoming known as the "Edison Effect." Edison patented what he found, but he did not understand the underlying physics, nor did he have an inkling of the potential value of the discovery. It wasn't until the early 20th century that the rectifying property of such a device was utilized, most notably by John Ambrose Fleming who used the diode tube to detect (demodulate) radio signals. Lee De Forest's 1906 "audion" was also developed as a radio detector, and soon led to the developement of the triode tube. This was essentially the first electronic amplifier, leading to great improvements in telephony (such as the first coast-to-coast telephone line in the US) and revolutionizing the technology used in radio transmitters and receivers. The electronics revolution of the 20th century arguably began with the invention of the triode vacuum tube.

Diodes

The English physicist John Ambrose Fleming worked as an engineering consultant for firms including Edison Telephone and the Marconi Company. In 1904, as a result of experiments conducted on Edison effect bulbs imported from the USA, he developed a device he called an "oscillation valve" (because it passes current in only one direction). The heated filament, or cathode, was capable of thermionic emission of electrons that would flow to the plate (or anode) when it was at a higher voltage. Electrons, however, could not pass in the reverse direction because the plate was not heated and thus not capable of thermionic emission of electrons.

Later known as the Fleming valve, it could be used as a rectifier of alternating current and as a radio wave detector. This greatly improved the crystal set which rectified the radio signal using an early solid-state diode based on a crystal and a so-called cat's whisker. Unlike modern semiconductors, such a diode required painstaking adjustment of the contact to the crystal in order for it to rectify. The diode tube was a reliable alternative for rectifying radio signals. Higher power diode tubes or power rectifiers found their way into power supply applications until they were eventually replaced by silicon rectifiers in the 1960's.

Triodes

Vacuum tube with plate cut open revealing grid.
Triodes as they evolved over 40 years of tube manufacture, from the RE16 in 1918 to a 1960's era miniature tube.
Triode symbol. From top to bottom: plate (anode), control grid, cathode, heater (filament)

Originally, the only use for tubes in radio circuits was for rectification, not amplification. In 1906 Robert von Lieben filed for a patent for a cathode ray tube which included magnetic deflection. This could be used for amplifying audio signals and was intended for use in telephony equipment. He would later go on to help refine the triode vacuum tube.

However it was Lee De Forest who in 1907 is credited with inventing the triode tube while continuing experiments to improve his original Audion tube, a crude forerunner of the triode. By placing an additional electrode in between the filament (cathode) and plate, he discovered the ability of the resulting device to amplify signals of all frequencies. As the voltage applied to the so-called control grid (or simply "grid") was lowered from the cathode's voltage to somewhat more negative voltages, the amount of current flowing from the filament to the plate would be reduced. The negative electrostatic field created by the grid in the vicinity of the cathode would inhibit thermionic emission and reduce the current to the plate. Thus a few volts difference at the grid would make a large change in the plate current and could lead to a much larger voltage change at the plate, resulting in voltage and power amplification. In 1907, De Forest filed for a patent for such a three-electrode version of his original Audion tube for use as an electronic amplifier in radio communications. This eventually became known as the triode.

De Forest's device was not strictly a vacuum tube, as he erroneously believed that it depended on the presence of residual gas remaining after evacuation. The De Forest company, in its Audion leaflets, even warned against operation which might lead to too high a vacuum! The Finnish inventor Eric Tigerstedt significantly improved on the original triode design in 1914, while working on his sound-on-film process in Berlin, Germany. The first true vacuum triodes in production were the Pliotrons developed by Irving Langmuir at the General Electric research laboratory (Schenectady, New York) in 1915. Langmuir was one of the first scientists to realize that a harder vacuum would improve the amplifying behaviour of the triode. Pliotrons were closely followed by the French 'R' Type which was in widespread use by the allied military by 1916. These two types were the first true vacuum tubes; early diodes and triodes performed as such despite a rather high residual gas pressure. Techniques to produce and maintain better vacuums in tubes were then developed. Historically, vacuum levels in production vacuum tubes typically ranged from 10 µPa down to 10 nPa.

The non-linear operating characteristic of the triode caused early tube audio amplifiers to exhibit harmonic distortions at low volumes. This is not to be confused with the so-called overdrive distortion that tube amplifiers exhibit when driven beyond their linear region (known as the tube sound). To remedy the triode's nonlinear characteristics, engineers plotted curves of the applied grid voltage and resulting plate currents, and discovered that there was a range of grid voltages allowing for relatively linear operation. In order to use this range, a negative voltage had to be applied to the grid to place the tube in the "middle" of the linear area with no signal applied. This was called the idle condition, and the plate current at this point the "idle current". Today this current would be called the quiescent or bias current. The controlling voltage was superimposed onto this fixed "bias" voltage, resulting in a linear variation of plate current in response to both positive and negative variation of the input voltage around that point. This concept is called grid bias. Many early radio sets had a third battery called the "C battery" (not to be confused with the modern C cell) whose positive terminal was connected to the cathode of the tubes (or "ground" in most circuits) and whose negative terminal supplied this bias voltage to the grids of the tubes. More modern circuits used cathode biasing in lieu of a separate negative power supply.

When triodes were first used in radio transmitters and receivers, it was found that tuned amplification stages had a tendency to oscillate unless their gain was very limited. This was due to the parasitic capacitance between the plate (the amplifier's output) and the control grid (the amplifier's input), known as the Miller capacitance. Eventually the technique of neutralization was developed whereby the RF transformer connected to the plate would include an additional winding in the opposite phase. This winding would be connected back to the grid through a small capacitor, and when properly adjusted would cancel the Miller capacitance. This technique was employed and led to the success of the Neutrodyne radio during the 1920's. However neutralization required careful adjustment and proved unsatisfactory when used over a wide ranges of frequencies.

Tetrodes and pentodes

Tetrode symbol. From top to bottom: plate (anode), screen grid, conrol grid, cathode, heater (filament)

In order to combat the stability problems and limited voltage gain due to the Miller effect, the noted physicist Walter H. Schottky invented the tetrode tube in 1919. He showed that the addition of a second grid, located between the control grid and the plate, known as the screen grid, could solve these problems. ("Screen" in this case refers to electrical "screening" or shielding, not physical construction: all "grid" electrodes in between the cathode and plate are "screens" of some sort rather than solid electrodes since they must allow for the passage of electrons directly from the cathode to the plate). A positive voltage slightly lower than the plate voltage was applied to it, and was bypassed (for high frequencies) to ground with a capacitor. This arrangement decoupled the anode and the control grid, essentially eliminating the Miller capacitance and its associated problems. Consequently higher voltage gains from a single tube became possible, reducing the number of tubes required in many circuits. This two-grid tube is called a tetrode, meaning four active electrodes, and was common by 1926.

However, the tetrode has one new problem. In any tube, electrons strike the anode with sufficient energy to cause the emission of electrons from its surface. In a triode this so-called secondary emission of electrons is not important since they are simply re-captured by the more positive anode. But in a tetrode they can be captured by the screen grid since it is at also at a high voltage, thus robbing them from the plate current and reducing the amplification of the device. Since secondary electrons can outnumber the primary electrons, in the worst case, particularly as the plate voltage dips below the screen voltage, the plate current can actually go down with increasing plate voltage. This is termed negative resistance and can itself cause instability. This is the so-called "tetrode kink" (see the reference for a plot of this effect in the RCA-235 tetrode). Another consequence of secondary emission is that in extreme cases the current reaching the screen grid can cause it to overheat to the point of destroying the tube.

Vacuum tubes in an Australian radio of the late 1930s

The solution was to add one more grid in between the screen grid and the plate, called the suppressor grid (since it supressed secondary emission current toward the screen grid). This grid was held at the cathode (or "ground") voltage and its negative voltage (relative to the anode) electrostatically repelled secondary electrons so that they would be collected by the anode after all. This three-grid tube is called a pentode, meaning five electrodes. The pentode was invented in 1928 by Bernard D. H. Tellegen and became generally favoured over the simple tetrode. A refinement of the tetrode or pentode for power applications is the beam tetrode or "beam power tube", discussed berlow.

Multifunction configurations

The pentagrid converter contained no less than 5 grids in between the cathode and the plate.

Superheterodyne receivers require a local oscillator and mixer, which required two tubes. With the development of the pentagrid converter, these functions were combined inside a single tube which applied the RF signal to the control grid, but also implemented the local oscillator using additional grids. Various alternatives such as using a combination of a triode with a hexode and even an octode have been used for this purpose. The additional grids include both control grids (at a low potential) and screen grids (at a high voltage). Many designs used such a screen grid as a second 'leaky' plate to provide feedback for the oscillator oscillator function, whose current was added to that of the incoming radio frequency signal. Due to the large oscillating signal nonlinearity of the tube response caused frequency mixing, seen on the plate current (output) of such a "converter" circuit. The difference frequency between that of the incoming signal and that of the oscillator was selected by a tuned transformer, becoming the input to the receivers's intermediate frequency (IF) amplifier.

The pentagrid converter such as the 12BE6 thus became widely used in AM receivers including the minature tube version of the "All American Five". Octodes such as the 7A8 were rarely used in the US, but much more common in Europe particularly in battery operated radios where the lower power consumption was an advantage.

To further reduce the cost and complexity of radio equipment, two separate vacuum tubes could be combined in the bulb of a single tube, a so-called multisection tube. An early example was the Loewe 3NF. This 1920s device had 3 triodes in a single glass envelope together with all the fixed capacitors and resistors required to make a complete radio receiver. As the Loewe set had only one tube socket, it was able to substantially undercut the competition since, in Germany, state tax was levied by the number of sockets. However, reliability was compromised, and production costs for the tube were much greater. In a sense, these were akin to integrated circuits. In the US, Cleartron briefly produced the "Multivalve" triple triode for use in the Emerson Baby Grand receiver. This Emerson set also had a single tube socket, but because it used a four-pin base, the additional element connections were made on a "mezzanine" platform at the top of the tube base.

Popular 12AX7 dual triode
Compactron tube: 12AE10, dual pentode

By 1940 multisection tubes had become commonplace. There were constraints, however, due to patents and other licencing considerations (see British Valve Association). Constraints due to the number of external pins (leads) often forced the functions to share some of those external connections such as their cathode connections (in addition to the heater connection). The RCA Type 55 was a double diode triode used as a detector, automatic gain control rectifier and audio preamp in early AC powered radios. These sets often included the 53 Dual Triode Audio Output. Another early type of multi-section tube, the 6SN7, is a "dual triode" which, for most purposes, can perform the functions of two triode tubes, while taking up half as much space and costing less. The 12AX7 is a dual high voltage gain (or high mu) triode in a minature enclosure, and became widely used in audio signal amplifiers, instruments, and.guitar amplifiers.

The introduction of the miniature tube base (see below) which could have 9 pins, also allowed many other multi-section tubes, such as the 6GH8 triode + pentode. Along with a host of similar tubes, the 6GH8 was quite popular in television receivers. Some color TV sets used exotic types like the 6JH8 which had two plates and beam deflection electrodes (it was known as the 'sheet beam' tube). Vacuum tubes used like this were designed for demodulation of synchronous signals, an example of which is color demodulation for television receivers. The desire to include additional functions in one envelope resulted in the General Electric Compactron which had 12 pins (minature tubes had only 7 or 9 pins). A typical example, the 6AG11, contained two triodes and two diodes.

Beam power tubes

Beam power tube symbol and pinout for 6L6

The beam power tube is usually a tetrode with the addition of beam-forming electrodes, which take the place of the suppressor grid. These angled plates focus the electron stream onto certain spots on the anode which can withstand the heat generated by the impact of massive numbers of electrons, while also providing pentode behavior. The positioning of the elements in a beam power tube uses a design called "critical-distance geometry", which minimizes the "tetrode kink", plate-grid capacitance, screen-grid current, and secondary emission effects from the anode, thus increasing power conversion efficiency. The control grid and screen grid are also wound with the same pitch, or number of wires per inch.

6L6 tubes in glass envelopes

Aligning the grid wires also helps to reduce screen current, which represents wasted energy. This design helps to overcome some of the practical barriers to designing high-power, high-efficiency power tubes. 6L6 was the first popular beam power tube, introduced by RCA in 1936. Corresponding tubes in Europe were the KT66, KT77 and KT88 by GEC (the KT standing for "Kinkless Tetrode").

Variations of the 6L6 design are still widely used in tube guitar amplifiers, making it one of the longest lived electronic device families in history. Similar design strategies are used in the construction of large ceramic power tetrodes used in radio transmitters.

Miniature tubes

Miniature tube, alongside euro coin
Subminiature CV4501 tube, 35 mm long x 10 mm diameter (excluding leads).
RCA 6DS4 "Nuvistor" triode, ca. 20 mm high by 11 mm diameter.

Early tubes used a metal or glass envelope atop an insulating bakelite base. In 1938 a technique was developed to instead use an all glass construction with the pins fused in the glass base of the envelope. This was used in the design of a much smaller tube outline, known as the miniature tube, having 7 or 9 pins. Making tubes smaller reduced the voltage that they could work at, and also the power of the filament. Miniature tubes became predominant in consumer applications such as radio receivers and hi-fi amplifiers. However the larger older styles continued to be used especially as higher power rectifiers, in higher power audio output stages and as transmitting tubes.

Subminiature tubes with a size roughly that of half a cigarette were used in hearing-aid amplifiers. These tubes did not have pins plugging into a socket but were soldered in place. The "acorn" valve (named due to its shape) was another such example. Another very small tube style was called the nuvistor. About the size of a thimble, these metal cased tubes were made small not mainly for compactness, but for use at very high frequencies, notably in UHF television tuners.

Improvements in construction and performance

The very earliest vacuum tubes strongly resembled incandescent light bulbs and were made by lamp manufacturers, who had the equipment for manufacture of glass envelopes and the powerful vacuum pumps required to evacuate the enclosures. After World War I, specialized manufacturers using more economical construction methods were set up to fill the growing demand for broadcast receivers. Bare tungsten filaments operated at a temperature of around 2200 °C. The development of oxide-coated filaments in the mid 1920s reduced filament operating temperature to a dull red heat (around 700 °C), which in turn reduced thermal distortion of the tube structure and allowed closer spacing of tube elements. This in turn improved tube gain, since the gain of a triode is inversely proportional to the spacing between grid and cathode.

Indirectly heated cathodes

The desire to power electronic equipment using AC mains power faced a difficulty with respect to the powering of the tubes' filaments, as these were also the cathode of each tube. Powering the filaments directly from a power transformer would introduce 50 or 60 Hz hum into audio stages using tubes whose filaments were powered in such a manner. The invention of the "equi-potential cathode" reduced this problem, with the filaments being powered by a balanced AC power transformer winding having a grounded center tap.

A superior solution, and one which allowed each cathode to "float" at a different voltage, was that of the indirectly-heated cathode. Now, a filament inside a cylinder of oxide-coated nickel, provided for a cathode electrically isolated from the filament which could then just as well be powered by AC. In such tubes, the filament is frequently referred to as a heater to distinguish it as an inactive element. In the 1930's indirectly heated cathode tubes became widespread in equipment using AC power. However directly heated filament tubes continued to prevail in battery operated equipment, as the power requirements for these filaments were substantially lower than required by the heaters used to heat cathodes indirectly.

World War II

Near the end of World War II, to make radios more rugged, some aircraft and army radios began to integrate the tube envelopes into the radio's cast aluminium or zinc chassis. The radio became just a printed circuit with non-tube components, soldered to the chassis that contained all the tubes. During WWII in 1942, rugged metal vacuum tubes were mounted in anti-aircraft shells. These proximity fuzes made anti-aircraft shells 6 times more effective. In the fall of 1944, artillery shells with proximity fuses were used. The tiny tubes were later known as "subminiature" types. They were widely used in 1950s military and aviation electronics.

Use in early electronic computers

See also: List of vacuum tube computers
Tubes in a 1950s computer.

While the development of vacuum tubes made electronic computing possible for the first time, the cost and reliability of early tubes made such developments rather impractical. It was only the pressure of World War II that led to the development of Colossus and early electronic computers using tubes. The general practicality of electronic computers was only realized with the development of transistors over a decade later.

Colossus

Colossus (and its successor Colossus Mk2) was built by the British during World War II to substantially speed up the task of breaking the German high level Lorenz encryption. Based on 1500 vacuum tubes, Colossus replaced an earlier machine based on relay and switch logic (the Heath Robinson). Colossus was able to break in a matter of hours messages that had previously taken several weeks. Colossus Mk2 used a total of around 2000 vacuum tubes. Colossus was the first ever use of vacuum tubes on such a large scale for a single machine. The largest project previously had used just 150 tubes and had proven to be extremely unreliable. The main design problem at Colossus's inception was how to make vacuum tube based equipment reliable when the tubes were used in large numbers.

The Colossus computer's designer, Dr. Tommy Flowers, had a theory that most of the unreliability was caused during power down and (mainly) power up. Once Colossus was built and installed, it was switched on and left switched on running from dual redundant diesel generators (the wartime mains supply being considered too unreliable). The only time it was switched off was for conversion to the Colossus Mk2 and the addition of another 500 or so tubes. Another 9 Colossus Mk2s were built, and all 10 machines ran with a surprising degree of reliability. The 10 Colossi consumed 15 kilowatts of power each, 24 hours a day, 365 days a year—nearly all of it for the tube heaters.

Whirlwind

To meet the reliability requirements of the early digital computer Whirlwind, it was necessary to build special "computer vacuum tubes" with extended cathode life. The problem of short lifetime was traced to evaporation of silicon, used in the tungsten alloy to make the heater wire easier to draw. Elimination of the silicon from the heater wire alloy (and paying extra for more frequent replacement of the wire drawing dies) allowed production of tubes that were reliable enough for the Whirlwind project. The tubes developed for Whirlwind later found their way into the giant SAGE air-defense computer system. High-purity nickel tubing and cathode coatings free of materials that can poison emission (such as silicates and aluminium) also contribute to long cathode life. The first such "computer tube" was Sylvania's 7AK7 of 1948. By the late 1950s it was routine for special-quality small-signal tubes to last for hundreds of thousands of hours, if operated conservatively. This increased reliability also made mid-cable amplifiers in submarine cables possible.

Heat generation and transfer

The anode of this transmitting triode has been designed to dissipate up to 500W of heat

A considerable amount of heat is produced when tubes operate, both from the filament (heater) but also from the stream of electrons bombarding the plate. The requirements for heat removal can significantly change the appearance of high-power vacuum tubes. Although the miniature tube style became predominant in consumer equipment, high power audio amplifiers and rectifiers would still require the larger "octal" style of enclosure. Transmitting tubes could be much larger still.

Most tubes produce heat from two sources during operation. The first source is the filament or heater. Some tubes contain a directly heated cathode. This is a filament similar to an incandescent electric lamp; some types glow brightly like a lamp, but most glow a dim orange-red. The "bright emitter" types possess a tungsten filament alloyed with 1-3 % thorium which reduces the work function of the metal, giving it the ability to emit sufficient electrons at about 2000 degrees Celsius. The "dull emitter" types also possess a tungsten filament but it is coated in a mixture of calcium, strontium and barium oxides, which emit electrons easily at much lower temperatures due to a monolayer of mixed alkali earth metals coating the tungsten; these only reach 800-1000 degrees Celsius.

The second form of cathode is the indirectly heated form which usually consists of a nickel cylinder, coated on the outside with the same strontium, calcium, barium oxide mix used in the "dull emitter" directly heated types. Inside the cylinder is a tungsten filament to heat it. This filament is usually uncoiled and coated in a layer of alumina (aluminium oxide) in order to insulate it electrically from the actual cathode. This form of construction allows for a much greater electron emitting area and allows the cathode to be held at a potential difference, typically 150 volts more positive than the heater or 50 volts more negative than the heater. For small-signal tubes such as used in radio receivers, heaters consume between 50 mW and 5 watts, (directly heated), or between 500 mW and 8 watts for indirectly heated types. Thus even a small signal amplifier might consume a watt of power just to warm its heater, compared to the milliwatts (or less) that a modern semiconductor amplifier would require for the same function. Even in power amplifiers the filament power may be responsible for an appreciable reduction in efficiency.

The second source of heat is generated at the plate, as electrons accelerated by the anode voltage strike the plate, depositing their kinetic energy on it and raising its temperature. In tubes used in power amplifiers or transmitter output stages, this source of heat will far exceed the power due to the cathode heater. The plates of improperly operated or overloaded beam power tubes can sometimes become visibly red hot; this should never occur under normal operation of consumer electronics and is a precursor to tube failure.

Heat escapes the device by black body radiation from the anode/plate as infrared radiation. Convection is not possible in most tubes since the anode is surrounded by vacuum. Considerations of heat removal can affect the overall appearance of some tubes. The anode or plate is often treated to make its surface less shiny and darker in the infrared (see black body radiator). The screen grid may also generate considerable heat, which is radiated toward the plate which must reradiate that additional heat along with the heat it generates itself. Limits to screen grid dissipation, in addition to plate dissipation, are listed for power devices. If these are exceeded then tube failure is likely.

Tubes used as power amplifier stages for radio transmitters may have additional heat exchangers, cooling fans, radiator fins, or other measures to improve heat transfer at the anode. High power transmitting tubes may have the surface of their anodes external to the tube, allowing for water cooling or evaporative cooling. Such a water cooling system must be electrically isolated to withstand the high voltage present on the anode.

Tubes which generate rather little heat, such as the 1.4 volt filament directly heated tubes designed for use in battery powered equipment, often have shiny metal anodes. 1T4, 1R5 and 1A7 are examples. Gas filled tubes such as thyratrons may also use a shiny metal anode since the gas present inside the tube allows for convection of heat from the anode to the glass enclosure.

The outer electrode in most tubes is the anode. Some small signal types, such as sharp and remote cut-off R.F. and A.F. pentodes and some pentagrid converters have a shield fitted around all the electrodes enclosing the anode. This shield is sometimes a solid metal sheet, treated to make it dull and gray so that it can itself reradiate heat generated from within. Sometimes it is fabricated from expanded metal mesh, acting as a Faraday cage but allowing sufficient infrared radiation from the anode to escape. Types 6BX6/EF80 and 6BK8/EF86 are typical examples of this shielded type using expanded mesh. Types 6AU6/EF94 and 6BE6/EK90 are examples which use a gray sheet metal cylindrical shield.

Tube packaging

Metal cased tubes with "octal" bases
High power GS-9B triode transmitting tube with heat sink at bottom.

Most modern tubes have glass envelopes, but metal, fused quartz (silica), and ceramic have also been used. The first version of the 6L6 used a metal envelope sealed with glass beads, while a glass disk fused to the metal was used in later versions. Metal and ceramic are used almost exclusively for power tubes above 2 kW dissipation. The nuvistor was a modern receiving tube using a very small metal and ceramic package.

Tubes have always had their internal elements connected to external circuitry using pins at their base which plug into a socket. After all, tubes needed to be replaced rather frequently unlike modern semiconductor devices which are mostly soldered in place. Subminiature tubes were produced using wire leads rather than sockets, however these were restricted to rather specialized applications. In addition to the connections at the base of the tube, many early triodes connected the grid using a metal cap at the top of the tube; this was done in order to reduce stray capacitance between the grid and the plate leads. Tube caps were also used for the plate (anode) connection, particularly in transmitting tubes and tubes using a very high plate voltage.

High power tubes such as transmitting tubes have packages designed more to enhance heat transfer. In some tubes, the metal envelope is also the anode. The 4CX1000A is an external anode tube of this sort. Air is blown through an array of fins attached to the anode, thus cooling it. Power tubes using this cooling scheme are available up to 150 kW dissipation. Above that level, water or water-vapor cooling are used. The highest-power tube currently available is the Eimac 4CM2500KG, a forced water-cooled power tetrode capable of dissipating 2.5 megawatts. (By comparison, the largest power transistor can only dissipate about 1 kilowatt.)

Special-purpose tubes

Some special-purpose tubes are constructed with particular gases in the envelope. For instance, voltage regulator tubes contain various inert gases such as argon, helium or neon, and take advantage of the fact that these gases will ionize at predictable voltages. The thyratron is a special-purpose tube filled with low-pressure gas or mercury, some of which vaporizes. Like other tubes, it contains a hot cathode and an anode, but also a control electrode, which behaves somewhat like the grid of a triode. When the control electrode starts conduction, the gas ionizes, and the control electrode no longer can stop the current; the tube "latches" into conduction. Removing plate (anode) voltage lets the gas de-ionize, restoring its non-conductive state. Some thyratrons can carry large currents for their physical size. One example is the miniature type 2D21, often seen in 1950s jukeboxes as control switches for relays. A cold-cathode version of the thyratron, which uses a pool of mercury for its cathode, is called an Ignitron (tm). It can switch thousands of amperes in its largest versions. Thyratrons containing hydrogen have a very consistent time delay between their turn-on pulse and full conduction, and have long been used in radar transmitters. Thyratrons behave much like silicon-controlled rectifiers, or to be more chronologically precise, silicon controlled rectifiers mimic some of the behaviours of Thyratrons.

An extremely specialized tube is the Krytron, which is used for extremely precise, rapid high-voltage switching. Due to their intended purpose, the initiation of the precise sequence of detonations used to set off a nuclear weapon, they are heavily controlled at an international level.

X-ray tubes are used in medical imaging among other uses. X-ray tubes used for continuous duty operation in fluoroscopy and imaging equipment may use a rotating anode to dissipate the large amounts of heat thus generated, and a focused cathode. They are housed in an aluminum housing which is filled with a dielectric oil for cooling. Nuclear medicine imaging equipment and liquid scintillation counters require photomultiplier tube arrays to detect scintillation due to ionizing radiation.

Powering the tube

Batteries

Batteries provided the voltages required by tubes in early radio sets. Three different voltages were generally required, using three different batteries designated as the A', B, and C battery. The "A" batteries or LT (low-tension) battery provided the filament voltage. Tube heaters were designed for single, double or triple-cell lead-acid batteries, giving nominal heater voltages of 2 V, 4 V or 6 V. In portable radios, dry batteries were sometimes used with 1.5 or 1 V heaters. Reducing filament consumption improved the life span of batteries. By 1955 towards the end of the tube era, tubes using only 50 mA down to as little as 10 mA for the heaters had been developed.

The plate voltage was provided by the "B" batter or the HT (high-tension) supply or battery. These were generally of dry cell construction and typically came in 22.5, 45, 67.5, 90 or 135 volt versions.

Batteries for a vacuum tube circuit. The C battery is highlighted.

Early sets used a grid bias battery or "C" batteries which was connected to provide a negative voltage. Since virtually no current flows through a tube's grid connection, these batteries had very low drain and lasted the longest. Even after AC power supplies became commonplace, some radio sets continued to be built with C batteries, as they would almost never need replacing. However more modern circuits were designed using cathode biasing, eliminating the need for a third power supply voltage; this became practical with tubes using indirect heating of the cathode.

Note that the "C battery" is a designation having no relation to the 1.5 volt "C cell" (nor for the A and B batteries, discussed above).

AC power

"Cheater cord" redirects here. For the three-prong to two-prong mains plug adapter, see Cheater plug.

Replacement of batteries was a major cost of operation for early radio receiver users. The development of the battery eliminator, and, in 1925, batteryless receivers operated by household power, reduced operating costs and contributed to the growing popularity of radio. A power supply using a transformer with several windings, one or more rectifiers (which may themselves be vacuum tubes), and large filter capacitors provided the required direct current voltages from the alternating current source.

As a cost reduction measure, especially in high-volume consumer receivers, all the tube heaters could be connected in series across the AC supply, and the plate voltage derived from a half-wave rectifier directly connected to the AC input, eliminating the need for a heavy power transformer. As an additional feature, these radios could be operated on AC or DC mains. This arrangement resulted in a limited plate voltage, however with advances in tube technology tubes could run reasonably effectively with only 150 volts on their plates. A filament tap on the rectifier tube provided the 6 volt, low current supply needed for a dial light.

Rectifying the AC mains directly did have one safety issue: the chassis of the receiver was connected to one side of the mains, presenting a shock hazard. This hazard was reduced by enclosing the chassis in an insulated case and running the AC power through a so-called interlock connection at the removable back side of the receiver. This would come disconnected whenever the radio was opened (for instance, to test and replace the tubes) preventing such a shock hazard. (Technicians and tinkerers routinely bypassed this by using a separate cord, known colloquially as a "cheater cord" or "widowmaker.") Many consumer AM radio manufacturers of the era used a virtually identical circuit with the tube complement of 12BA6, 12BE6, 12AV6, 35W4, and 50C5, giving these radios the nickname All American Five or simply "Five Tube Radio." Although millions of such receivers were produced, they have now become collector's items.

Reliability

Tube tester manufactured in 1930

One reliability problem of tubes with oxide cathodes is the possibility that the cathode may slowly become "poisoned" by gas molecules from other elements in the tube, which reduce its ability to emit electrons. Trapped gases or slow gas leaks can also damage the cathode or cause plate-current run away due to ionization of free gas molecules. Vacuum hardness and proper selection of construction materials are the major influences on tube lifetime. Depending on the material, temperature and construction, the surface material of the cathode may also diffuse onto other elements. The resistive heaters that heat the cathodes may break in a manner similar to incandescent lamp filaments, but rarely do, since they operate at much lower temperatures than lamps.

The heater's failure mode is typically a stress-related fracture of the tungsten wire or at a weld point and generally occurs after accruing many thermal (power on-off) cycles. Tungsten wire has a very low resistance when at room temperature. A negative temperature coefficient device, such as a thermistor, may be incorporated in the equipment's heater supply or a ramp-up circuit may be employed to allow the heater or filaments to reach operating temperature more gradually than if powered-up in a step-function. Low-cost radios had tubes with heaters connected in series, with a total voltage equal to that of the line (mains). Following World War II, tubes intended to be used in series heater strings were redesigned to all have the same ("controlled") warm-up time. Earlier designs had quite-different thermal time constants. The audio output stage, for instance, had a larger cathode, and warmed up more slowly than lower-powered tubes. The result was that heaters that warmed up faster also temporarily had higher resistance, because of their positive temperature coefficient. This disproportionate resistance caused them to temporarily operate with heater voltages well above their ratings, and shortened their life.

Another important reliability problem is caused by air leakage into the tube. Usually oxygen in the air reacts chemically with the hot filament or cathode, quickly ruining it. Designers developed tube designs that sealed reliably. This was why most tubes were constructed of glass. Metal alloys (such as Cunife and Fernico) and glasses had been developed for light bulbs that expanded and contracted in similar amounts, as temperature changed. These made it easy to construct an insulating envelope of glass, while passing connection wires through the glass to the electrodes.

When a vacuum tube is overloaded or operated past its design dissipation, its anode (plate) may glow red. In consumer equipment, a glowing plate is universally a sign of an overloaded tube. However, some large transmitting tubes are designed to operate with their anodes at red, orange, or in rare cases, white heat.

Vacuum

Getter in opened tube; silvery deposit from getter

The highest possible vacuum is desired in a tube. Remaining gas atoms will ionize and conduct electricity between the elements in an undesired manner. In a defective tube residual air pressure will lead to ionization, becoming visible as a pink-purple glow discharge between the tube elements.

To prevent gases from compromising the tube's vacuum, modern tubes are constructed with "getters", which are usually small, circular troughs filled with metals that oxidize quickly, barium being the most common. While the tube envelope is being evacuated, the internal parts except the getter are heated by RF induction heating to help free any remaining gases from the metal parts. The tube is then sealed and the getter is heated to a high temperature, again by radio frequency induction heating. This causes some material from the getter to evaporate, reacting with any residual gases and usually leaving a silver-colored metallic deposit on the inside of the envelope of the tube. The getter continues to absorb small amounts of gas that may leak into the tube during its working life. If a tube develops a serious leak in the envelope, this deposit turns a white color as it reacts with atmospheric oxygen. Large transmitting and specialized tubes often use more exotic getter materials, such as zirconium. Early gettered tubes used phosphorus based getters and these tubes are easily identifiable, as the phosphorus leaves a characteristic orange or rainbow deposit on the glass. The use of phosphorus was short-lived and was quickly replaced by the superior barium getters. Unlike the barium getters, the phosphorus did not absorb any further gases once it had fired.

Transmitting tubes

Large transmitting tubes have carbonized tungsten filaments containing a small trace (1% to 2%) of thorium. An extremely thin (molecular) layer of thorium atoms forms on the outside of the wire's carbonized layer and, when heated, serve as an efficient source of electrons. The thorium slowly evaporates from the wire surface, while new thorium atoms diffuse to the surface to replace them. Such thoriated tungsten cathodes usually deliver lifetimes in the tens of thousands of hours. The end-of-life scenario for a thoriated-tungsten filament is when the carbonized layer has mostly been converted back into another form of tungsten carbide and emission begins to drop off rapidly; a complete loss of Thorium has never been found to be a factor in the end-of-life in a tube with this type of emitter. The highest reported tube life is held by an Eimac power tetrode used in a Los Angeles radio station's transmitter, which was removed from service after 80,000 hours (~9 years) of operation. It has been said that transmitters with vacuum tubes are better able to survive lightning strikes than transistor transmitters do. While it was commonly believed that at rf power levels above approx. 20 kilowatts, vacuum tubes were more efficient than solid state circuits, this is no longer the case especially in medium wave (AM broadcast) service where solid state transmitters at nearly all power levels have measurably higher efficiency. FM broadcast transmitters with solid state power amplifiers up to approx. 15 kW also show better overall mains-power efficiency than tube-based power amplifiers.

Receiving tubes

Cathodes in small "receiving" tubes are coated with a mixture of barium oxide and strontium oxide, sometimes with addition of calcium oxide or aluminium oxide. An electric heater is inserted into the cathode sleeve, and insulated from it electrically by a coating of aluminium oxide. This complex construction causes barium and strontium atoms to diffuse to the surface of the cathode when heated to about 780 degrees Celsius, thus emitting electrons.

Failure modes

Catastrophic failures

A catastrophic failure is one which suddenly makes the vacuum tube unusable. A crack in the glass envelope will allow air into the tube and destroy it. Cracks may result from stress in the glass, bent pins or impacts; tube sockets must allow for thermal expansion, to prevent stress in the glass at the pins. Stress may accumulate if a metal shield or other object presses on the tube envelope and causes differential heating of the glass. Glass may also be damaged by high-voltage arcing.

Tube heaters may also fail without warning, especially if exposed to over voltage or as a result of manufacturing defects. Tube heaters do not normally fail by evaporation like lamp filaments, since they operate at much lower temperature. The surge of inrush current when the heater is first energized causes stress in the heater, and can be avoided by slowly warming the heaters, gradually increasing current. Some tubes intended for series string operation of the heaters across the supply will have a definite controlled warm-up time to avoid excess voltage on some heaters as others warm up. Directly-heated filament-type cathodes as used in battery-operated tubes or some rectifiers may fail if the filament sags, causing internal arcing. Excess heater-to-cathode voltage in indirectly heated cathodes can break down the insulation between elements and destroy the heater.

Arcing between tube elements can destroy the tube. An arc can be caused by applying plate potential before the cathode has come up to operating temperature, or by drawing excess current through a rectifier which damages the emission coating. Arcs can also be initiated by any loose material inside the tube, or by excess screen voltage. An arc inside the tube allows gas to evolve from the tube materials, and may deposit conductive material on internal insulating spacers.

Degenerative failures

Degenerative failures cause the performance of the tube to slowly deteriorate with time.

Overheating of internal parts, such as control grids or mica spacer insulators, can result in trapped gas escaping into the tube; this can reduce performance. A getter is used to absorb gases evolved during tube operation, but has only a limited ability to combine with gas. Control of the envelope temperature prevents some types of gassing. A tube with very bad internal gas may have a visible blue glow when plate voltage is applied.

Gas and ions within the tube contribute to grid current which can disturb operation of a vacuum tube circuit. Another effect of overheating is the slow deposit of metallic vapors on internal spacers, resulting in inter-element leakage.

Tubes on standby for long periods, with heater voltage applied, may develop high cathode interface resistance and display poor emission characteristics. This effect occurred especially in pulse and digital circuits, where tubes had no plate current flowing for extended times.

Cathode depletion describes the loss of emission after thousands of hours of normal use. Sometimes emission can be restored for a time by raising heater voltage either for a short time or a permanent increase of a few percent. Cathode depletion was uncommon in signal tubes but was a frequent cause of failures of monochrome television cathode-ray tubes.

Other failures

Vacuum tubes may have or develop defects in operation that makes an individual tube useless in one device, but which may not prevent its satisfactory operation in another system. Microphonics refers to internal vibration of tube elements, which modulates the signal from the tube in an undesirable way; sound or vibration pick-up may affect the signals, or even cause uncontrolled howling if a feedback path develops between a microphonic tube and, for example, a loudspeaker. Leakage current between AC heaters and the cathode may couple into the circuit, or electrons emitted directly from the ends of the heater may also inject hum into the signal. Leakage current due to internal contamination may also inject noise.

Cooling

A 12AX7 preamp tube, EL84 power tube (with dampener rings) and a GZ34 rectifier tube in a guitar amplifier.

Like any electronic device, vacuum tubes produce heat while operating. This waste heat is one of the principal factors that affect tube life . The majority of this waste heat originates in the anode though some grids may also require cooling to remove excess heat. For example, the cooling of the screen grid in an EL34 is facilitated by the addition of two small radiators or "wings," located near the top of the tube. The heater also contributes to the total waste heat. A tube's data sheet will normally identify the maximum amount of heat each element may dissipate.

The method of anode cooling is dependent on the construction of the tube itself. For tubes with internal anodes such as the 12AX7 or EL34, the cooling occurs by radiating the heat by black body radiation from the anode to the glass envelope . Natural air circulation, convection, then removes the heat from the envelope. Tube shields that aided heat dispersal could be retrofitted on certain select types of tubes. These shields act by improving heat conduction from the surface of the tube to the shield itself by means of tens of copper tongues in contact with the glass tube, and have an opaque, black outside finish for improved heat radiation. The ability to remove heat may be further increased by implementing forced air cooling, adding fins to the anode, and operating the anode at red hot temperatures. All of these measures are implemented in the 4-1000A transmitting tube.

The amount of heat that may be removed from a tube with an internal anode is limited . Tubes with external anodes may be cooled using forced air, water, vapor, and multiphase. The 3CX10,000A7 is an example of a tube with an external anode cooled by forced air. The water, vapor, and multiphase cooling techniques all depend on the high specific heat and latent heat of water. The 8974 is an example of a water cooled tube and is among the largest commercial tube available today.

In a water cooled tube, the anode voltage appears directly on the cooling water surface, thus requiring the water to be an electrical insulator. Otherwise the high voltage can be conducted through the cooling water to the radiator system; hence the need for deionized water. Such systems usually have a built-in water-conductance monitor which will shut down the high-tension supply (often tens of kilovolts) if the conductance becomes too high.

Other vacuum tube devices

Many devices were built during the 1920–1960 period using vacuum-tube techniques. Most such tubes were rendered obsolete by semiconductors; some techniques for integrating multiple devices in a single module, sharing the same glass envelope have been discussed above, such as the Loewe 3NF. Vacuum-tube electronic devices still in common use include the magnetron, klystron, photomultiplier, x-ray tube, traveling-wave tube and cathode ray tube. The magnetron is the type of tube used in all microwave ovens. In spite of the advancing state of the art in power semiconductor technology, the vacuum tube still has reliability and cost advantages for high-frequency RF power generation. Photomultipliers are still the most sensitive detectors of light.

The cathode ray tube (CRT) is a vacuum tube used particularly for display purposes. Many televisions, oscilloscopes and computer monitors still use cathode ray tubes, though flat panel displays are becoming more predominant as prices drop. At one time many radios used "magic eye" tubes, a specialized sort of CRT used in place of a meter movement to indicate signal strength, or input level in a tape recorder. A modern indicator device, the vacuum fluorescent display (VFD) is also a sort of cathode ray tube.

Secondary emission is the term for what happens when electrons in a vacuum strike certain materials, and the impacts cause electrons to be emitted. For some materials, more electrons are emitted than originally hit the surface. Such devices, called electron multipliers, amplify the current represented by the incoming electrons. Several stages (as many as 15 or so) can be cascaded for high gain, and are essential parts of very sensitive phototubes, usually called photomultipliers or multiplier photoubes. The image orthicon TV studio camera tubes also used multistage photomultipliers.

For decades, electron-tube designers tried to use secondary emission to obtain more amplification in vacuum tubes with hot cathodes, but they suffered from short life because the material used for the secondary-emission electrode (called a dynode) "poisoned" the tube's hot cathode. (For instance, the interesting RCA 1630 secondary-emission tube was marketed, but did not last.) However, eventually, Philips of The Netherlands developed the EFP60 tube that had a satisfactory lifetime, and was used in at least one product, a laboratory pulse generator. However, transistors were rapidly improving, and eclipsed tubes in general.

A variant, called a channel electron multiplier, is a curved tube, such as a helix, coated on the inside with material with good secondary emission. One type had a little funnel to capture incoming electrons. The tube was resistive, and its ends were connected to enough voltage to create repeated cascades of electrons.

Tektronix made a high-performance wideband oscilloscope CRT with a channel electron multiplier plate behind the phosphor layer. This plate was a bundled array of a huge number of short individual c.e.m. tubes that accepted a low-current beam and intensified it to provide a display of practical brightness. (The electron optics of the wideband electron gun could not provide enough current to directly excite the phosphor.)

Some tubes, such as magnetrons, traveling-wave tubes, carcinotrons, and klystrons, combine magnetic and electrostatic effects. These are efficient (usually narrow-band) RF producers and still find use in radar, microwave ovens and industrial heating. Traveling-wave tubes (TWTs) are very good amplifiers; they are used in some communications satellites. High-powered klystron amplifier tubes can provide hundreds of kilowatts in the UHF range.

Gyrotrons or vacuum masers, used to generate high-power millimetre band waves, are magnetic vacuum tubes in which a small relativistic effect, due to the high voltage, is used for bunching the electrons. Gyrotrons can generate very high powers (hundreds of kilowatts). Free electron lasers, used to generate high-power coherent light and perhaps even X rays, are highly relativistic vacuum tubes driven by high-energy particle accelerators.

Particle accelerators can be considered vacuum tubes that work backward, the electric fields driving the electrons, or other charged particles. In this respect, a cathode ray tube is a particle accelerator.

A tube in which electrons move through a vacuum (or gaseous medium) within a gas-tight envelope is generically called an electron tube.

Some condenser microphone designs use built-in vacuum tube preamplifiers.

Vacuum tubes in the 21st century

Niche applications

Aothough vacuum tubes have been largely replaced by solid-state devices in most amplifying applications, there are certain exceptions. In addition to the special functions noted above, tubes have some niche applications even in the current age.

Vacuum tubes are much less susceptible than corresponding solid-state components to the electromagnetic pulse effect of nuclear explosions. This property kept them in use for certain military applications long after transistors had replaced them elsewhere. Vacuum tubes are still used for very high-powered applications such as industrial radio-frequency heating, generating large amounts of RF energy for particle accelerators, and power amplification for broadcasting. Several sorts of tubes are used in microwave applications, such as the household microwave oven in which the magnetron is used to efficiently generate microwave powers of several hundred watts.

70 watt tube audio amplifier currently selling for $2,680. Certain audiophiles happily pay ten times more for the perceived "tube sound."

Many audiophiles, professional audio engineers, and musicians prefer the tube sound of audio equipment based on vacuum tubes over electronics based on transistors. There are companies which still make specialized audio hardware featuring tube technology. A common usage is in the high-end microphone preamplifiers preferred by professional music recording studios, and in electric guitar amplification. The sound produced by a tube based amplifier with the tubes overloaded (overdriven) has defined the texture of some genres of music such as classic rock and blues. Guitarists often prefer tube amplifiers for the warmth of their tone and the natural compression effect they can apply to an input signal.

In 2002, computer motherboard maker AOpen brought back the vacuum tube for modern computer use by releasing the AX4GE Tube-G motherboard. This motherboard uses a Sovtek 6922 vacuum tube (a version of the 6DJ8) as part of AOpen’s TubeSound Technology. AOpen claims that the vacuum tube brings superior sound.

Vacuum fluorescent display

A modern display technology using a sort of cathode ray tube is freqeuntly used in videocassette recorders, microwave oven control panels, and automotive dashboards. Rather than raster scanning these vacuum fluorescent displays (VFD) switch control grids and plate voltages on and off to display discrete characters, for instance. This term should not be confused with fluorescent light technology which uses fluorescence from ultraviolet radiation produced using a discharge tube. Rather the VFD uses phosphor-coated anodes as in other display cathode ray tube. Because the filaments are in view, they must be operated at temperatures where the filament does not glow visibly. This is possible using more recent cathode technology, and these tubes also operate with quite low anode voltages (often less than 50 volts) contrary to classical cathode ray tubes. Often found in automotive applications, their high brightness allows reading the display in daylight. VFD tubes are flat and rectangular, as well as relatively thin. Typical VFD phosphors emit a broad-spectrum greenish-white light, permitting use of color filters. This type of phosphor provides a bright glow despite the low energy of the incident electrons.

Vacuum tubes using field electron emitters

In the early years of the 21st century there has been renewed interest in vacuum tubes, this time with the electron emitter formed on a flat silicon substrate, as in integrated circuit technology. This subject is now called vacuum nanoelectronics. The most common design uses a cold cathode in the form of a large-area field electron source (for example a field emitter array). With these devices, electrons are field-emitted from a large number of closely spaced individual emission sites.

Their claimed advantages include greatly enhanced robustness combined with the ability to provide high power outputs at low power consumptions. Operating on the same principles as traditional tubes, prototype device cathodes have been fabricated in several different ways. Although a common approach is to use a field emitter array, one interesting idea is to etch electrodes to form hinged flaps – similar to the technology used to create the microscopic mirrors used in Digital Light Processing) that are stood upright by an electrostatic charge.

Such integrated microtubes may find application in microwave devices including mobile phones, for Bluetooth and Wi-Fi transmission, in radar and for satellite communication. Presently they are being studied for possible applications in field emission display technology, but significant production problems seem to exist.

Modern manufacturers

Vacuum tubes are still being manufactured in the following countries:

China

Manufacturer Area of expertise
Shuguang Electron Group Co. Tubes primarily for audio applications.
Tianjin Quanerzhen Electron Tube Technology Co. Direct heated tubes for audio applications.
Nanjing Sanle Electronic Information Industry Group Co. Transmitting and industrial tubes. (Including Chinese 3-500C & 4-400C)
JiangXi Jingguang Electronics Co. Transmitting and industrial tubes.
Huaguang Electric Power & Electronics Co. Transmitting and industrial tubes
Chengdu Xuguang Electronics Co. Transmitting and industrial tubes

Russia

Manufacturer Area of expertise
Ekspopul JSC Audio tube factory of New Sensor Inc. Known formerly as tube factory of Reflektor JSC.
"Ryazan" Vacuum Components LLC Direct heated tubes. SV811 and SV572 series for audio, 811A and 572B for RF applications.
"SED-SPb" Svetlana Electron Devices - St. Petersburg. Svetlana JSC Primarily transmitting and industrial tubes. Manufactures also few models for audio applications.
Voskhod KRLZ JSC Tubes for small signal RF and audio applications
NEVZ-Soyuz HC JSC Transmitting and industrial tubes, known formerly as Novosibirsk electron tube plant.

United States

Manufacturer Area of expertise
Communications & Power Industries Inc. Transmitting and industrial tubes, formerly known as Eitel-McCullough Inc.
Burle Industries Inc. Transmitting and industrial tubes, formerly factory of RCA
MPD Components Inc. Planar triodes and magnetrons, formerly Ken-Rad and later GE tube factory
MU Incorporated Contract manufacturer.
LND Inc. Geiger-Mueller tubes
Western Electric Export Corporation 300B Tubes Former Factory of AT&T's Western Electric moved equipment from Missouri to Tennessee in 2002

United Kingdom

Manufacturer Area of expertise
e2v Technologies Ltd. Transmitting and industrial tubes, formerly known as English Electric Valve Co. Ltd.
Centronic Ltd. Geiger-Mueller tubes, formerly Philips GM-tubes
TMD Technologies Ltd. Transmitting and industrial tubes. Formerly THORN Microwave Devices Ltd.

Germany

Manufacturer Area of expertise
Vacutec GmbH. Geiger-Mueller tubes

France

Manufacturer Area of expertise
Covimag SA Transmitting and industrial tubes. Products marketed by Richardson Electronics.

Formerly Philips transmitting tube factory.

Thales Electron Devices SA Transmitting and industrial tubes. Formerly known as Thomson-CSF.

Czech Republic

Manufacturer Area of expertise
Emission Labs Direct heated tubes for audio applications
KR Audio Electronics s.r.o. Direct heated tubes for audio applications
Tesla Electrontubes s.r.o Transmitting and industrial tubes

Slovakia

Manufacturer Area of expertise
JJ-Electronic Tubes primarily for audio applications, factory was formerly part of Tesla Electrontubes
Euro Audio Team Tubes for high-end audio.

See also

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Patents

References

  1. U.S. patent 307,031
  2. "Robert von Lieben — Patent Nr 179807 Dated November 19, 1906" (PDF). Kaiserliches Patentamt. November 19, 1906. Retrieved March 30, 2008.
  3. U.S. patent 879,532
  4. Introduction to Thermionic Valves (Vacuum Tubes), Colin J. Seymour
  5. http://www.r-type.org/static/story.htm particularly the section entitled "Glass Base Construction".
  6. L.W. Turner,(ed), Electronics Engineer's Reference Book, 4th ed. Newnes-Butterworth, London 1976 ISBN 0 408 00168 pages 7-2 through 7-6
  7. Sōgo Okamura , History of electron tubes ,IOS Press, 1994, ISBN 90-5199-145-2, page 133
  8. Robert B. Tomer, Getting the most out of vacuum tubes, Howard W. Sams, Indianapolis, USA 1960, Library of Congress card no. 60-13843, available on the Internet Archive. Chapter 1
  9. Tomer 60, chaper 2
  10. Tomer 60, chapter 3
  11. Eimac “Care and Feeding of Power Grid Tubes” 1967, p. 108
  12. ^ RCA "Transmitting Tubes Manual" TT-5 1962, p. 10
  • Spangenberg, Karl R. (1948). Vacuum Tubes. McGraw-Hill. LCC TK7872.V3 OCLC 567981.
  • Millman, J. & Seely, S. Electronics, 2nd ed. McGraw-Hill, 1951.
  • Shiers, George, "The First Electron Tube", Scientific American, March 1969, p. 104.
  • Tyne, Gerald, Saga of The Vacuum Tube, Ziff Publishing, 1943, (reprint 1994 Prompt Publications), pp. 30–83.
  • Stokes, John, 70 Years of Radio Tubes and Valves, Vestal Press, NY, 1982, pp. 3–9.
  • Thrower, Keith, History of The British Radio Valve to 1940, MMA International, 1982, pp 9–13.
  • Eastman, Austin V., Fundamentals of Vacuum Tubes, McGraw-Hill, 1949
  • Philips Technical Library. Books published in the UK in the 1940s and 1950s by Cleaver Hume Press on design and application of vacuum tubes.
  • RCA "Radiotron Designer's Handbook" 1953(4th Edition) Contains chapters on the design and application of receiving tubes.
  • Wireless World. "Radio Designer's Handbook". UK reprint of the above.
  • RCA "Receiving Tube Manual" RC15, RC26 (1947, 1968) Issued every two years, contains details of the technical specs of the tubes that RCA sold.


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