Aneon lamp (alsoneon glow lamp) is a miniaturegas-discharge lamp. The lamp typically consists of a small glass capsule that contains a mixture ofneon andother gases at a low pressure and twoelectrodes (ananode and acathode). When sufficient voltage is applied and sufficient current is supplied between the electrodes, the lamp produces an orangeglow discharge. The glowing portion in the lamp is a thin region near the cathode; the larger and much longerneon signs are also glow discharges, but they use thepositive column which is not present in the ordinary neon lamp. Neon glow lamps were widely used asindicator lamps in the displays of electronic instruments and appliances. They are still sometimes used for their electrical simplicity in high-voltage circuits.
Neon was discovered in 1898 byWilliam Ramsay andMorris Travers. The characteristic, brilliant red color that is emitted by gaseous neon when excited electrically was noted immediately; Travers later wrote, "the blaze of crimson light from the tube told its own story and was a sight to dwell upon and never forget."[1]
Neon's scarcity precluded its prompt application for electrical lighting along the lines ofMoore tubes, which used electric discharges in nitrogen. Moore tubes were commercialized by their inventor,Daniel McFarlan Moore, in the early 1900s. After 1902,Georges Claude's company,Air Liquide, was producing industrial quantities of neon as a byproduct of his air liquefaction business, and in December 1910 Claude demonstrated modernneon lighting based on a sealed tube of neon. In 1915 a U.S. patent was issued to Claude covering the design of the electrodes for neon tube lights;[2] this patent became the basis for the monopoly held in the U.S. by his company, Claude Neon Lights, through the early 1930s.[3]
Around 1917, Daniel Moore developed the neon lamp while working at theGeneral Electric Company. The lamp has a very different design from the much larger neon tubes used forneon lighting. The difference in design was sufficient that a U.S. patent was issued for the lamp in 1919.[4] A Smithsonian Institution website notes, "These small, low power devices use a physical principle calledcoronal discharge. Moore mounted two electrodes close together in a bulb and added neon or argon gas. The electrodes would glow brightly in red or blue, depending on the gas, and the lamps lasted for years. Since the electrodes could take almost any shape imaginable, a popular application has been fanciful decorative lamps.[5]
Glow lamps found practical use as indicators in instrument panels and in many home appliances until the widespread commercialization oflight-emitting diodes (LEDs) in the 1970s.[5]
A smallelectric current (for a 5 mm bulb diameter NE-2 lamp, thequiescent current is about 400 μA), which may beAC orDC, is allowed through the tube, causing it to glow orange-red. The gas is typically aPenning mixture, 99.5%neon and 0.5%argon, which has lowerstriking voltage than pure neon, at a pressure of 1–20 torrs (0.13–2.67 kPa).
The lampglow discharge lights at its striking voltage.[6] The striking voltage is reduced by ambient light or radioactivity. To reduce the "dark effect", some lamps were made with a small amount of radioactive material, typicallyKrypton-85, added to the envelope to provide ionization in darkness.[6]
The voltage required to sustain the discharge is significantly (up to 30%) lower than the striking voltage. This is due to the organization of positive ions near the cathode. Neon lamps operate using a low currentglow discharge.
Higher power devices, such asmercury-vapor lamps ormetal halide lamps use a higher currentarc discharge. Low pressuresodium-vapor lamps use a neon Penning mixture for warm up and can be operated as giant neon lamps if operated in a low power mode.
Once the neon lamp has reached breakdown, it can support a large current flow. Because of this characteristic, electrical circuitry external to the neon lamp must limit the current through the circuit or else the current will rapidly increase until the lamp is destroyed.
For indicator-sized lamps, aresistor typically limits the current. In contrast, larger sized lamps often use a specially constructed high voltagetransformer with highleakage inductance or otherelectrical ballast to limit the available current (seeneon sign).
When the current through the lamp is lower than the current for the highest-current discharge path, theglow discharge may become unstable and not cover the entire surface of the electrodes.[7] This may be a sign of aging of the indicator lamp, and is exploited in the decorative "flicker flame" neon lamps. However, while too low a current causes flickering, too high a current increases the wear of the electrodes by stimulatingsputtering, which coats the internal surface of the lamp with metal and causes it to darken.
The potential needed to strike the discharge is higher than what is needed to sustain the discharge. When there is not enough current, the glow forms around only part of the electrode surface. Convective currents make the glowing areas flow upwards, not unlike the discharge in aJacob's ladder. Aphotoionization effect can also be observed here, as the electrode area covered by the glow discharge can be increased by shining light at the lamp.
In comparison withincandescent lamps, neon lamps have much higherluminous efficacy.Incandescence is heat-driven light emission, so a large portion of the electric energy put into an incandescent lamp is converted into heat. Non-incandescent light sources such as neon lamps,fluorescent lamps, andlight-emitting diodes are therefore much more energy efficient than normal incandescent lamps. LEDs are the highest efficiency.
Green neon lamps[8] can produce up to 65 lumens per watt of power input, while white neon lamps have an efficacy of around 50 lumens per watt. In contrast, a standard incandescent lamp only produces around 13.5 lumens per watt.[9]
The precise values of starting and maintaining voltages of neon lamps is subject to change due to several effects. External light falling on the electrodes provides a source of ionization to start the lamp; in total darkness, lamps may reach a high and erratic starting voltage. One measure to mitigate for this effect is to include a pilot lamp within the enclosure to provide an initial source of light. Lamps are also somewhat sensitive to external electrostatic fields, temperature, and aging. Lamps intended for use as circuit components may be specially processed to eliminate most of the initial aging effects.[10]
Even after the widespread availability of cheapLEDs, small neon lamps are still widely used as visual indicators in electronic equipment and appliances, due to their low power consumption, long life, and ability to operate on mains power.
Neon lamps are commonly used as low-voltagesurge protectors, but they are generally inferior togas discharge tube (GDT) surge protectors (which can be designed for higher voltage applications). Neon lamps have been used as an inexpensive method to protect RF receivers from voltage spikes (lamp connected to RF input and chassis ground), but they are not suitable for higher-power RF transmitters.[11]
Most small neon (indicator-sized) lamps, such as the commonNE-2, have abreak-down voltage of around 90 volts. When driven from a DC source, only the negatively charged electrode (cathode) will glow. When driven from an AC source, both electrodes will glow (each during alternate half cycles). These attributes make neon lamps (with series resistors) a convenient low-costvoltage tester. By examining which electrode is glowing they can reveal whether a given voltage source is AC or DC, and if DC, the polarity of the points being tested.
The breakdown characteristic of glow-discharge lamps allows them to be used asvoltage regulators orovervoltage protection devices.[12] Starting around the 1930s,General Electric (GE), Signalite, and other firms made voltage regulator tubes.
Like othergas discharge lamps,[13] the neon lamp hasnegative resistance; its voltage falls with increasing current after the lamp reaches its breakdown voltage.[10][14][15][16] Therefore, the lamp hashysteresis; its turn-off (extinction) voltage is lower than its turn-on (breakdown) voltage.[17]
This allows it to be used as an active switching element. Neon lamps were used to makerelaxation oscillator circuits, using this mechanism, sometimes referred to as thePearson–Anson effect[15][17][18] for low frequency applications such as flashing warning lights,stroboscopes[19] tone generators in electronic organs,[15] and as time bases and deflection oscillators in earlycathode ray oscilloscopes.[20]
Neon lamps can also bebistable, and were even used to builddigital logic circuits such aslogic gates,flip-flop,binarymemories, anddigital counters.[21][22][23] These applications were sufficiently common that manufacturers made neon lamps specifically for this use, sometimes called "circuit-component" lamps. At least some of these lamps have a glow concentrated into a small spot on the cathode, which made them unsuited to use as indicators. To provide more repeatable lamp characteristics and reduce "dark effect" ( a rise in starting voltage observed in lamps kept in total darkness), some types of lamp such as NE83 (5AH) include a small amount of a radioisotope to provide initial ionization.[10]
A variant of the NE-2 type lamp for circuit applications, the NE-77, have three wire electrodes in the lamp (in a plane) instead of the usual two, the third for use as a control electrode.
Neon lamps have been historically used as microwave and millimeter-wave detectors ("plasma diodes" or glow discharge detectors (GDDs)) up to about 100 GHz or so and in such service were said to exhibit comparable sensitivity (of the order of a few 10s to perhaps 100 microvolts) to the familiar 1N23-type catwhisker-contacted silicon diodes[citation needed] once ubiquitous in microwave equipment. More recently it has been found that these lamps work well as detectors even at sub-millimeter ("terahertz") frequencies and they have been successfully used as pixels in several experimental imaging arrays at these wavelengths.
In these applications the lamps are operated either in "starvation" mode (to reduce lamp-current noise) or in normal glow discharge mode; some literature references their use as detectors of radiation up into the optical regime when operated in abnormal glow mode. Coupling of microwaves into the plasma may be in free space, in waveguide, by means of a parabolic concentrator (e.g.,Winston cone), or via capacitive means via a loop or dipole antenna mounted directly to the lamp.
Although most of these applications use ordinary off-the-shelf dual-electrode lamps, in one case it was found that special three (or more) electrode lamps, with the extra electrode acting as the coupling antenna, provided even better results (lower noise and higher sensitivity). This discovery received a US patent.[24]
Neon lamps with several shaped electrodes were used as alphanumerical displays known asNixie tubes. These have since been replaced by other display devices such aslight emitting diodes,vacuum fluorescent displays, andliquid crystal displays.
Since at least the 1940s, argon, neon, andphosphoredglowthyratronlatching indicators (which would light up upon an impulse on their starter electrode and extinguish only after their anode voltage was cut) were available for example as self-displayingshift registers in large-format, crawling-textdot-matrix displays,[25] or, combined in a 4×4, four-color phosphored-thyratron matrix, as a stackable 625-color RGBA pixel for large video graphics arrays.[26]Multiple-cathode and/or anodeglow thyratrons calledDekatrons could count forwards and backwards while their count state was visible as a glow on one of the numbered cathodes.[27] These were used as self-displayingdivide-by-n counter/timer/prescalers in counting instruments, or asadder/subtracters incalculators.
In 1930s radio sets, neon lamps were used as tuning indicators, called "tuneons" and would give a brighter glow as the station was tuned in correctly.[28][29]
Because of their comparatively short response time, in the early development oftelevision neon lamps were used as the light source in manymechanical-scan TV displays.
Novelty glow lamps with shaped electrodes (such as flowers and leaves), often coated with phosphors, have been made for artistic purposes. In some of these, the glow that surrounds an electrode is part of the design.
Neon indicator lamps are normally orange, and are frequently used with a colored filter over them to improve contrast and change their color to red or a redder orange.
They can also be filled withargon,krypton, orxenon rather than neon, or mixed with it. While the electrical operating characteristics remain similar, these lamps light with a bluish glow (including someultraviolet) rather than neon's characteristic reddish-orange glow. Ultraviolet radiation then can be used to excite aphosphor coating inside of the bulb and provide a wide range of various colors, including white.[30] A mixture of 95% neon, 2.5%krypton, and 2.5% argon can be used for a green glow,[31] but nevertheless "green neon" lamps are more commonly phosphor-based.
{{cite book}}: CS1 maint: url-status (link)
| International | |
|---|---|
| Other | |
