A compact fluorescent lamp with an integrated electronic ballast
A fluorescent lamp is a type of lamp that uses electricity to excite mercury vapor in argon or neon gas, resulting in a plasma that produces short-wave ultraviolet light. This light then causes a phosphor to fluoresce, producing visible light.
Unlike incandescent lamps, fluorescent lamps always require a ballast to convert the mains power into power suitable for the lamp type. With fluorescent lamps designed to be compatible with standard light bulb sockets (named compact fluorescent light bulbs), the ballast is integrated with the lamp, usually inside the plastic housing between the socket connector and the glow tube.
Contents
- 1 History
- 2 Principles of operation
- 2.1 Mechanism of light production
- 2.2 Electrical aspects of operation
- 2.3 Method of 'starting' a fluorescent lamp
- 2.4 Phosphors and the spectrum of emitted light
- 3 Usage
- 4 Advantages over incandescent lamps
- 5 Disadvantages
- 6 Tube designations
- 7 Other fluorescent lamps
- 8 Fluorescent fun
- 9 External links
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History
The earliest ancestor of the fluorescent lamp is probably the device by Heinrich Geissler who obtained in 1856 a bluish glow from a gas sealed in a tube, excited with an induction coil. Though he is remembered as a physicist, Geissler was educated as a glassblower.
At the 1893 World's Fair, the World Columbian Exposition in Chicago, Illinois, Nikola Tesla's fluorescent lights were displayed.
In 1894, D. McFarlane Moore created the Moore lamp, a commercial gas discharge lamp meant to compete with the incandescent light bulb of his former boss Thomas Edison. The gases used were nitrogen and carbon dioxide emitting respectively pink and white light, and had moderate success.
In 1901, Peter Cooper Hewitt demonstrated the mercury-vapor lamp, which emitted light of a blue-green color, and thus was unfit for most practical purposes. It was, however, very close to the modern design. This lamp had some applications in photography where color was not yet an issue, thanks to its much higher efficiency than incandescent lamps.
Edmund Germer and coworkers proposed in 1926 to increase the operating pressure within the tube and to coat the tube with fluorescent powder which converts ultraviolet light emitted by a rare gas into more uniformly white-colored light. Germer is today recognized as the inventor of fluorescent lamp.
General Electric later bought Germer's patent and under the direction of George Inman brought the fluorescent lamp to wide commercial use in 1938.
In the 1970s and 80s Philips miniaturised the electronic ballasts to produce Compact Fluorescents.
Principles of operation
The main principle of fluorescent tube operation is based around inelastic scattering of electrons. An incident electron (emitted from the coils of wire forming the cathode electrode) collides with an atom in the gas (such as mercury, argon or krypton) used as the ultraviolet emitter. This causes an electron in the atom to temporarily jump up to a higher energy level to absorb some, or all, of the kinetic energy delivered by the colliding electron. This is why the collision is called 'inelastic' as some of the energy is absorbed. This higher energy state is unstable, and the atom will emit a photon (a "packet of light energy") to allow the atom's electron to revert to a lower, more stable, energy level. The photons that are released from the chosen gas mixtures tend to have a wavelength in the ultra-violet part of the spectrum. This is not visible to the human eye, so must be converted into visible light. This is done by making use of fluorescence. This fluorescent conversion occurs in the phosphor coating on the inner surface of the fluorescent tube, where the ultra-violet photons are absorbed by electrons in the phosphor's atoms, causing a similar energy jump, then drop, with emission of a further photon. The photon that is emitted from this, second, interaction has a lower energy then the one that caused it, and the chemicals that make up the phosphor are specially chosen so that these emitted photons are at wavelengths visible to the human eye. The difference in energy between the absorbed ultra-violet photon and the emitted visible light photon goes to heat up the phosphor coating.
Mechanism of light production
A fluorescent lamp bulb is filled with a gas containing low pressure argon (or more rarely argon-neon or sometimes even krypton) and mercury vapor.
The inner surface of the bulb is coated with a fluorescent paint made of varying blends of metallic and rare-earth phosphor salts. The bulb's cathode is typically made of coiled tungsten which is coated with a mixture of barium, strontium and calcium oxides (chosen to have a relatively low thermionic emission temperature).
When the light is turned on, the electric power heats up the cathode enough for it to emit electrons. The electrons convert the gases in the bulb to a plasma.
Electrons in the plasma bombard the noble gas atoms, ionizing the gas (see avalanche ionization) and causing its resistance to rapidly drop and consequently its conductivity to rise, allowing higher currents to flow through the lamp. The mercury, which exists at a stable vapour pressure equilibrium point of about one part per thousand in the inside of the tube (with the noble gas pressure typically being about 0.3% of atmospheric pressure (1 atm)), is then likewise ionized, causing it to emit light in the ultraviolet (UV) region of the spectrum predominately at wavelengths of 253.7 nm and 185 nm. The efficiency of fluorescent lighting owes much to the fact that low pressure mercury discharges emit about 65% of their total light at the 254 nm line (also about 10-20% of the light emitted in UV is at the 185 nm line). The UV light is absorbed by the bulb's fluorescent coating, which re-radiates the energy at lower frequencies (longer wavelengths) (see stokes shift) to emit visible light. The blend of phosphors controls the color of the light, and along with the bulb's glass prevents the harmful UV light from escaping.
Electrical aspects of operation
Fluorescent lamps are negative resistance devices. This means that as more current flows through them and more gas is ionized, the resistance of the fluorescent lamp drops and this would allow even more current to flow through them! Connected directly to a constant-voltage mains power line, a fluorescent lamp would rapidly self-destruct due to the unlimited current flow. Because of this, fluorescent lamps are always used with some sort of auxiliary electronics that regulates the current flow in the tube. This auxiliary device is commonly called a ballast.
While the ballast could be (and occasionally is) as simple as a resistor, substantial power is wasted in a resistive ballast so ballasts usually use a reactance (inductor or capacitor) instead. For operation from mains voltage, the use of simple inductor (a so-called "magnetic ballast") is common. In countries that use 120 V AC mains, the mains voltage is insufficient to light large fluorescent lamps so the ballast for these larger fluorescent lamps is often a step-up autotransformer with substantial leakage inductance (so as to limit the current flow). Either form of inductive ballast may also include a capacitor for power factor correction.
More sophisticated ballasts may employ transistors or other semiconductor components to convert mains voltage into high-frequency AC while also regulating the current flow in the lamp. These are referred to as "electronic ballasts".
Although most people cannot directly see 120 Hz flicker, some people [1][2] report that 120 Hz flicker causes eyestrain and headache. Dr. J. Veitch has found that people have better reading performance using high-frequency (20-60 kHz) electronic ballasts than magnetic ballasts (120 Hz)[3].
Method of 'starting' a fluorescent lamp
The mercury atoms in the fluorescent tube must be ionized before the arc can "strike" within the tube. For small lamps, it does not take much voltage to strike the arc and starting the lamp presents no problem, but larger tubes require a substantial voltage (in the range of a thousand volts). In some cases, that is exactly how it is done: "instant start" fluorescent tubes simply use a high enough voltage to break down the gas and mercury column and thereby start arc conduction. These tubes can be identified by the facts that
- they have a single pin at each end of the tube and
- the lampholders that they fit into have a "disconnect" socket at the low-voltage end to assure that the mains current is automatically removed so that a person replacing the lamp can not receive a high-voltage electric shock.
In other cases, a separate starting aid must be provided. Old fluorescent designs used a combination filament/cathode at each end of the lamp in conjunction with a mechanical or automatic switch that would initially connect the filaments in series and thereby "preheat" the filaments prior to striking the arc. Because of thermionic emission, the filaments would readily emit electrons into the gas column, creating a glow discharge near the filaments. Then, when the starting switch opened up, the inductive ballast would create a voltage surge which would (usually) strike the arc. If so, the impinging arc then kept the filament/cathode warm. If not, the starting sequence was repeated. If the starting aid was automatic, this often led to the situation where an old fluorescent lamp would flash time and time again as the starter repeatedly tried to start the worn-out lamp. More advanced starters would "trip out" in this situation and not attempt another start until manually reset.
Newer lamp and ballast designs (known as "rapid start" lamps) provide true filament windings within the ballast; these rapidly and continuously warm the filaments/cathodes using low-voltage AC. Unfortunately, there is no inductive voltage surge produced so the lamps must usually be mounted near a grounded (earthed) reflector to allow the glow discharge to propagate through the tube and initiate the arc discharge. Electronic ballasts often revert to a style in-between the preheat and rapid-start styles: a capacitor or other electronic circuit may join the two filaments, providing a conduction path that preheats the filaments but which is subsequently shorted out by the arc discharge.
Generally this capacitor also forms, together with the inductor that provides current limiting in normal operation, a resonant circuit, increasing the voltage across the lamp so that it can easily start. Some electronic ballasts use programmed start, the output AC frequency is started above the resonance frequency of the output circuit of the ballast, and after the filaments are heated the frequency is rapidly decreased. If the frequency approaches the resonant frequency of the ballast, the output voltage will increase so much that the lamp will ignite. If the lamp does not ignite an electronic circuit stops the operation of the ballast.
Phosphors and the spectrum of emitted light
Spectrum of a typical fluorescent light. For an explanation of the origin of the peaks click on the image. Note that several of the spectral peaks are directly generated from the mercury arc.
Many people find the color spectrum produced by some fluorescent lighting to be harsh and displeasing. It is common for a healthy person to appear with a sickly bluish skin tone under fluorescent lighting. This is due in part to the presence of prominent blue and green lines emitted directly by the mercury arc and in part to the type of phosphor used. Many pigments appear a slightly different color when viewed under fluorescent light versus incandescent. This is mainly the case with fluorescent lamps containing the older halophosphate type phosphors (chemical formula Ca5(PO4)3(F,Cl):Sb3+,Mn2+), usually labeled as "cool white". The bad color reproduction is due to the fact that this phosphor mainly emits yellow and blue light, and relatively little green and red. To the eye, this mixture looks white, but light reflected from surfaces has an incomplete spectrum. More expensive fluorescent lamps use a triphosphor mixture, based on europium and terbium ions, that have emission bands more evenly distributed over the spectrum of visible light. These phosphors give a more natural color reproduction to the human eye.
Usage
Fluorescent light bulbs come in many shapes and sizes. An increasingly popular one is the compact fluorescent light bulb (CF). Many compact fluorescent lamps integrate the auxiliary electronics into the base of the lamp, allowing them to screw into a regular light bulb socket.
In the US, residential use of fluorescent lighting remains low (generally limited to kitchens, basements, hallways and other areas), but schools and businesses find the cost savings of fluorescents to be significant and only rarely use incandescent lights. Typical lighting arrangements may include fluorescent tubes sending different tints of white, in order to provide good color reproduction. In other countries, residential use of fluorescent lighting varies depending on the price of energy and the environmental concerns of the local population as well as the acceptability of the light output.
Because they contain mercury, a toxic material, in many areas throughout the world, government regulations require that fluorescent bulbs must be properly disposed of.
(A typical 4 ft. T-12 fluorescent lamp contains about 12 milligrams of mercury[4]).
While this generally applies only to large commercial buildings which produce many waste bulbs, though restrictions vary widely, it is a good idea to find out if you can safely dispose of your waste bulbs in some manner.
Advantages over incandescent lamps
Fluorescent lamps are much more efficient than incandescent light bulbs of an equivalent brightness. This is because more of the consumed energy is converted to usable light and less is converted to heat, (allowing fluorescent lamps to run cooler). They also have a longer lamp life, which can be further lengthened by avoiding cramped enclosures, where heat build-ups that wear the lamp down may occur.
The seemingly cheap light bulbs could be replaced with seemingly more expensive fluorescent lamps, but due to electricity savings and the longer lifespan of the individual light source, money can be saved in the long term. Most incandescent light bulbs turn about 90% of the used power into heat. That is, they mainly produce and radiate heat instead of light. Whilst a typical light bulb might consume about 60 watts of power, a fluorescent lamp of approximately the same apparent "brightness" would take only 25% of this (about 15 watts).
Disadvantages
Fluorescent lamps do not give out a steady light, instead they flicker (fluctuate greatly in intensity) at a rate that depends on the frequency of the driving voltage. Whilst this is not easily discerned by the human eye, it can cause a strobe effect posing a safety hazard in a workshop for example, where something spinning at just the right speed may appear stationary if illuminated solely by a fluorescent lamp. It also causes problems for video recording as there can be a 'beat effect' between the periodic reading of a camera's sensor and the fluctuations in intensity of the fluorescent lamp. Incandescent lamps, due to the thermal inertia of their element, fluctuate less in their intensity, although the effect is measurable with instruments.
Fluorescent lights cannot be connected to a standard dimmer switch used for incandescent lamps. 4-pin fluorescent lamps and compatible controllers are required for successful fluorescent dimming.
Tube designations
Note: the information in this section might be unapplicable outside of North America.
Bulbs are typically identified by a code such as F##T##, where F is for fluorescent, the first number indicates the power in watts (or strangely, length in inches in very long bulbs), the T indicates that the shape of the lamp is tubular, and the last number is diameter in eighths of an inch. Typical diameters are T12 (1½" or 38 mm) for residential bulbs with old magnetic ballasts, T8 (1 in or 25 mm) for commercial energy-saving bulbs with electronic ballasts, and T5 (5⁄8" or 16 mm) for very small bulbs which may even operate from a battery-powered device.
High-output bulbs are brighter and draw more electrical current, have different ends on the pins so they cannot be used in the wrong fixture or with the wrong bulb, and are labeled F##T12HO, or F##T12VHO for very high output. Since about the early to mid 1950's to today, General Electric developed and improved the Power Groove(R) lamp with the label F##PG17. These lamps are recognisable by their large diameter, grooved tubes.
U-shaped tubes are FB##T##, with the B meaning "bent". Most commonly, these have the same designations as linear tubes. Circular bulbs are FC##T#, with the diameter of the circle (not circumference or watts) being the first number, and the second number usually being 9 (29mm) for standard fixtures.
Color is usually indicated by WW for warm white, EW for enhanced (neutral) white, CW for cool white (the most common), and DW for the bluish daylight white. BL is often used for blacklight (commonly used in bug zappers), and BLB for the common blacklight-blue bulbs which are dark purple. Other non-standard designations apply for plant lights or grow lights.
Philips uses numeric color codes for the colors:
- Low color rendition
- 33 the ubiquitous cool white (4000 K)
- 32 warm white (3000 K)
- 27 living room warm white (2700 K)
- High color rendition
- 840 cool white (4000 K)
- 830 warm white (3000 K)
- 827 warm white (2700 K)
- Other
- 09 Sun tanning lamps
- 08 Blacklight
- 05 Hard UV (no phosphors used at all)
Odd lengths are usually added after the color. One example is an F25T12/CW/33, meaning 25 watts, 1.5" diameter, cool white, 33" or 84 cm long. Without the 33, it would be assumed that an F25T12 is the more-common 30" long.
Compact fluorescents do not have such a designation system.
Other fluorescent lamps
Blacklights are a subset of fluorescent lamps that are used to provide long-wave ultraviolet light (at about 360nm wavelength). They are built in the same fashion as conventional fluorescent lamps but the glass tube is coated with a phosphor that converts the short-wave UV within the tube to long-wave UV rather than to visible light. They are used to provoke fluorescence (to provide dramatic effects using blacklight paint and to detect materials such as urine and certain dyes that would be invisible in visible light) as well as to attract insects to bug zappers.
Most blacklights (so-called "BLB" or "BlackLight-Blue" lamps) are also made from more expensive deep blue glass rather than clear glass. The deep blue glass filters out most of the visible colors of light directly emitted by the mercury vapor discharge, producing proportionally less visible light compared to UV light. This allows UV-induced fluorescence to be seen more easily (thereby allowing blacklight posters to seem much more dramatic). The blacklight lamps used in bug zappers do not require this refinement so it is usually omitted in the interest of low cost.
Sun lamps contain a different phosphor that emits more strongly in medium-wave UV, provoking a tanning response in human skin.
Germicidal lamps contain no phosphor at all (technically making them gas discharge lamps rather than fluorescent) and their tubes are made of fused quartz that is transparent to the short-wave UV directly emitted by the mercury discharge. The UV emitted by these tubes will kill germs, ionize oxygen to ozone, and cause eye and skin damage. Besides their uses to kill germs and create ozone, they are sometimes used by geologists to identify certain species of minerals by the color of their fluorescence. When used in this fashion, they are fitted with filters in the same way as blacklight-blue lamps are; the filter passes the short-wave UV and blocks the visible light produced by the mercury discharge. They are also used in EPROM erasers.
Electrodeless induction lamps are fluorescent lamps without internal electrodes. They have been commercially available since 1990. A current is induced into the gas column using electromagnetic induction. Because the electrodes are usually the life-limiting element of fluorescent lamps, such electrodeless lamps can have a very long service life, although they also have a higher purchase price.
Cold cathode fluorescent lamps (CCFL) are used as backlighting for LCD displays in laptop personal computers. They are also popular with case modders in recent years.
Fluorescent fun
If you live in a dry cold climate with lots of static electricity, try this: Put on your best static-gathering socks and take hold of a short fluorescent tube. Then shuffle about on the carpet to gather a robust static charge. Now discharge by gently touching the lamp electrodes to anything electrically grounded. Instead of the usual little spark the entire tube will flash as the electrons course (painlessly) out of your body. This also applies with Van de Graaff generators; simply touch the light to the sphere or touch the sphere while holding the light. Warning: This may produce a rather "jolty" shock.
Alternatively, if you happen to have a Tesla coil handy, you can fully illuminate the fluorescent lamp at quite a distance from the Tesla coil simply by holding the detached lamp in your hand and possibly touching one of its terminals. Do not touch the lamp to the coil, as this may result in injury and/or burning out the lamp (a hobbyist Tesla coil may operate at several kilowatts).
If you live near high-voltage power lines you might try standing underneath them at night while holding a fluorescent tube. The strong electric field created by power lines will cause a very small (harmless) current flow through the tube and it should give off at least a feeble glow.[5] Obviously you should never do this during stormy weather and no attempt should ever be made to get closer than average standing height to the lines using, for instance, a ladder, for that may get you killed.
External links
Wikimedia Commons has media related to:
- NASA: The Fluorescent Lamp: A plasma you can use
- How Stuff Works: Are fluorescent bulbs really more efficient than normal light bulbs?
- How Stuff Works: How Fluorescent Lamps Work
- The Lighting Design Lab: Should I Turn Off Fluorescent Lighting When Leaving A Room?
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