An electric arc, or arc discharge, is an electrical breakdown of a gas that produces a prolonged electrical discharge. The current through a normally nonconductive medium such as air produces a plasma; the plasma may produce visible light. An arc discharge is characterized by a lower voltage than a glow discharge and relies on thermionic emission of electrons from the electrodes supporting the arc. An archaic term is voltaic arc, as used in the phrase "voltaic arc lamp".
Techniques for arc suppression can be used to reduce the duration or likelihood of arc formation.
In the late 1800s, electric arc lighting was in wide use for public lighting. Some low-pressure electric arcs are used in many applications. For example, fluorescent tubes, mercury, sodium, and metal-halide lamps are used for lighting; xenon arc lamps have been used for movie projectors.
History
Natural lightning is now considered an electric spark, not an arc.
Sir Humphry Davy discovered the short-pulse electrical arc in 1800.[1] In 1801, he described the phenomenon in a paper published in William Nicholson's Journal of Natural Philosophy, Chemistry and the Arts.[2]According to modern science, Davy's description was a spark rather than an arc.[3] In the same year Davy publicly demonstrated the effect, before the Royal Society, by transmitting an electric current through two carbon rods that touched, and then pulling them a short distance apart. The demonstration produced a "feeble" arc, not readily distinguished from a sustained spark, between charcoal points. The Society subscribed for a more powerful battery of 1,000 plates, and in 1808 he demonstrated the large-scale arc.[4] He is credited with naming the arc.[5] He called it an arc because it assumes the shape of an upward bow when the distance between the electrodes is not small.[6] This is due to the buoyant force on the hot gas.
The first continuous arc was discovered independently in 1802 and described in 1803[7] as a "special fluid with electrical properties", by Vasily V. Petrov, a Russian scientist experimenting with a copper-zinc battery consisting of 4200 discs.[7][8]
In the late nineteenth century, electric arc lighting was in wide use for public lighting. The tendency of electric arcs to flicker and hiss was a major problem. In 1895, Hertha Marks Ayrton wrote a series of articles for the Electrician, explaining that these phenomena were the result of oxygen coming into contact with the carbon rods used to create the arc. In 1899, she was the first woman ever to read her own paper before the Institution of Electrical Engineers (IEE). Her paper was entitled "The Hissing of the Electric Arc". Shortly thereafter, Ayrton was elected the first female member of the IEE; the next woman to be admitted to the IEE was in 1958.[9] She petitioned to present a paper before the Royal Society, but she was not allowed because of her gender, and "The Mechanism of the Electric Arc" was read by John Perry in her stead in 1901.
Overview
File:ER2R with electric arcs after catenary icing.webmPlay media
Electric arcs between the power line and pantographs of an electric train after catenary icing
Electricity arcs between the power rail and electrical pickup "shoe" on a London Underground train
An electric arc is the form of electric discharge with the highest current density. The maximum current through an arc is limited only by the external circuit, not by the arc itself.
An arc between two electrodes can be initiated by ionization and glow discharge, when the current through the electrodes is increased. The breakdown voltage of the electrode gap is a combined function of the pressure, distance between electrodes and type of gas surrounding the electrodes. When an arc starts, its terminal voltage is much less than a glow discharge, and current is higher. An arc in gases near atmospheric pressure is characterized by visible light emission, high current density, and high temperature. An arc is distinguished from a glow discharge partly by the similar temperatures of the electrons and the positive ions; in a glow discharge, the ions are much colder than the electrons.
A drawn arc can be initiated by two electrodes initially in contact and drawn apart; this can initiate an arc without the high-voltage glow discharge. This is the way a welder starts to weld a joint, momentarily touching the welding electrode against the workpiece then withdrawing it until a stable arc is formed. Another example is separation of electrical contacts in switches, relays or circuit breakers; in high-energy circuits arc suppression may be required to prevent damage to contacts.[10]
Electrical resistance along the continuous electric arc creates heat, which ionizes more gas molecules (where the degree of ionization is determined by temperature), and as per this sequence: solid-liquid-gas-plasma; the gas is gradually turned into a thermal plasma. A thermal plasma is in thermal equilibrium; the temperature is relatively homogeneous throughout the atoms, molecules, ions, and electrons. The energy given to electrons is dispersed rapidly to the heavier particles by elastic collisions, due to their great mobility and large numbers.
Current in the arc is sustained by thermionic emission and field emission of electrons at the cathode. The current may be concentrated in a very small hot spot on the cathode; current densities on the order of one million amperes per square centimeter can be found. Unlike a glow discharge, an arc has little discernible structure, since the positive column is quite bright and extends nearly to the electrodes on both ends. The cathode fall and anode fall of a few volts occur within a fraction of a millimeter of each electrode. The positive column has a lower voltage gradient and may be absent in very short arcs.[10]
A low-frequency (less than 100 Hz) alternating current arc resembles a direct current arc; on each cycle, the arc is initiated by breakdown, and the electrodes interchange roles, as anode or cathode, when current reverses. As the frequency of the current increases, there is not enough time for all ionization to disperse on each half cycle, and the breakdown is no longer needed to sustain the arc; the voltage vs. current characteristic becomes more nearly ohmic.[10]
Electric arc between strands of wire.
The various shapes of electric arcs are emergent properties of non-linear patterns of current and electric field. The arc occurs in the gas-filled space between two conductive electrodes (often made of tungsten or carbon) and it results in a very high temperature, capable of melting or vaporizing most materials. An electric arc is a continuous discharge, while the similar electric spark discharge is momentary. An electric arc may occur either in direct current (DC) circuits or in alternating current (AC) circuits. In the latter case, the arc may re-strike on each half cycle of the current. An electric arc differs from a glow discharge in that the current density is quite high, and the voltage drop within the arc is low; at the cathode, the current density can be as high as one megaampere per square centimeter.[10]
An electric arc has a non-linear relationship between current and voltage. Once the arc is established (either by progression from a glow discharge[11] or by momentarily touching the electrodes then separating them), increased current results in a lower voltage between the arc terminals. This negative resistance effect requires that some positive form of impedance (as an electrical ballast) be placed in the circuit to maintain a stable arc. This property is the reason uncontrolled electrical arcs in apparatus become so destructive since once initiated, an arc will draw more and more current from a fixed-voltage supply until the apparatus is destroyed.
Uses
An electric arc can melt calcium oxide
Industrially, electric arcs are used for welding, plasma cutting, for electrical discharge machining, as an arc lamp in movie projectors, and followspots in stage lighting. Electric arc furnaces are used to produce steel and other substances. Calcium carbide is made in this way as it requires a large amount of energy to promote an endothermic reaction (at temperatures of 2500 °C).
Carbon arc lights were the first electric lights. They were used for street lights in the 19th century and for specialized applications such as searchlights until World War II. Today, low-pressure electric arcs are used in many applications. For example, fluorescent tubes, mercury, sodium, and metal halide lamps are used for lighting; xenon arc lamps are used for movie projectors.
Formation of an intense electric arc, similar to a small-scale arc flash, is the foundation of exploding-bridgewire detonators.
A major remaining application is in high voltage switchgear for high-voltage transmission networks. Modern devices use sulphur hexafluoride at high pressure in a nozzle flow between separated electrodes within a pressure vessel. The AC fault current is interrupted at current zero by the highly electronegative SF6 ions absorbing free electrons from the decaying plasma. A similar air-based technology has largely been replaced because many noisy units in series were required to prevent the current re-igniting under similar supergrid conditions.
Electric arcs have been studied for electric propulsion of spacecraft.
They are used in the laboratory for spectroscopy to create spectral emissions by intense heating of a sample of matter.
Guiding the arc
Scientists have discovered a method to control the path of an arc between two electrodes by firing laser beams at the gas between the electrodes. The gas becomes a plasma and guides the arc. By constructing the plasma path between the electrodes with different laser beams, the arc can be formed into curved and S-shaped paths. The arc could also hit an obstacle and reform on the other side of the obstacle. The laser-guided arc technology could be useful in applications to deliver a spark of electricity to a precise spot.[12][13]
Undesired arcing
Undesired or unintended electric arcing can have detrimental effects on electric power transmission, distribution systems and electronic equipment. Devices which may cause arcing include switches, circuit breakers, relay contacts, fuses and poor cable terminations. When an inductive circuit is switched off, the current cannot instantaneously jump to zero: a transient arc will be formed across the separating contacts. Switching devices susceptible to arcing are normally designed to contain and extinguish an arc, and snubber circuits can supply a path for transient currents, preventing arcing. If a circuit has enough current and voltage to sustain an arc formed outside of a switching device, the arc can cause damage to equipment such as melting of conductors, destruction of insulation, and fire. An arc flash describes an explosive electrical event that presents a hazard to people and equipment.
Undesired arcing in electrical contacts of contactors, relays and switches can be reduced by devices such as contact arc suppressors[14] and RC snubbers or through techniques including:
immersion in transformer oil, dielectric gas or vacuum
arc chutes
magnetic blowouts
pneumatic blowouts
sacrificial ("arcing") contacts
damping materials to absorb arc energy, either thermally or through chemical decomposition
Arcing can also occur when a low resistance channel (foreign object, conductive dust, moisture...) forms between places with different voltage. The conductive channel then can facilitate formation of an electric arc. The ionized air has high electrical conductivity approaching that of metals, and it can conduct extremely high currents, causing a short circuit and tripping protective devices (fuses and circuit breakers). A similar situation may occur when a lightbulb burns out and the fragments of the filament pull an electric arc between the leads inside the bulb, leading to overcurrent that trips the breakers.
An electric arc over the surface of plastics causes their degradation. A conductive carbon-rich track tends to form in the arc path, called "carbon tracking", negatively influencing their insulation properties. The arc susceptibility, or "track resistance", is tested according to ASTM D495, by point electrodes and continuous and intermittent arcs; it is measured in seconds required to form a track that is conductive under high-voltage low-current conditions.[15] Some materials are less susceptible to degradation than others. For example, polytetrafluoroethylene has arc resistance of about 200 seconds (3.3 minutes). From thermosetting plastics, alkyds and melamine resins are better than phenolic resins. Polyethylenes have arc resistance of about 150 seconds; polystyrenes and polyvinyl chlorides have relatively low resistance of about 70 seconds. Plastics can be formulated to emit gases with arc-extinguishing properties; these are known as arc-extinguishing plastics.[16]
Arcing over some types of printed circuit boards, possibly due to cracks of the traces or the failure of a solder, renders the affected insulating layer conductive as the dielectric is combusted due to the high temperatures involved. This conductivity prolongs the arcing due to cascading failure of the surface.
Arc suppression
Main article: Arc suppression
Arc suppression is a method of attempting to reduce or eliminate an electrical arc. There are several possible areas of use of arc suppression methods, among them metal film deposition and sputtering, arc flash protection, electrostatic processes where electrical arcs are not desired (such as powder painting, air purification, PVDF film poling) and contact current arc suppression. In industrial, military and consumer electronic design, the latter method generally applies to devices such as electromechanical power switches, relays and contactors. In this context, arc suppression uses contact protection.
Part of the energy of an electrical arc forms new chemical compounds from the air surrounding the arc: these include oxides of nitrogen and ozone, the second of which can be detected by its distinctive sharp smell. These chemicals can be produced by high-power contacts in relays and motor commutators, and they are corrosive to nearby metal surfaces. Arcing also erodes the surfaces of the contacts, wearing them down and creating high contact resistance when closed.[17]
See also
Arc transmitter
List of light sources
Marx generator
Spark gap
Vacuum arc
Paschen's law
References
A. Anders (2003). "Tracking down the origin of arc plasma science-II. early continuous discharges" (PDF). IEEE Transactions on Plasma Science. 31 (5): 1060–9. doi:10.1109/TPS.2003.815477.
Ayrton, Hertha (2015). Electric Arc (CLASSIC REPRINT). S.l: FORGOTTEN BOOKS. p. 94. ISBN 978-1330187593.
The Electric Arc, by Hertha Ayrton, page 20
Luckiesh, Matthew (1920). "Artificial light, its influence upon civilization". Nature. 107 (2694): 112. Bibcode:1921Natur.107..486.. doi:10.1038/107486b0. hdl:2027/chi.14153449. OCLC 1446711. S2CID 4135392.
"Arc". The Columbia Encyclopedia (3rd ed.). New York: Columbia University Press. 1963. LCCN 63020205.
Davy, Humphry (1812). Elements of Chemical Philosophy. p. 85. ISBN 978-0-217-88947-6. This is the likely origin of the term "arc".
"Tracking down the origin of arc plasma Science-II. Early continuous discharges". by André ANDERS. IEEE Xplore, ieee.org. IEEE Transactions on Plasma Science. Volume: 31, issue: 5, Oct 2003.
Kartsev, V.P. (1983). Shea, William R. (ed.). Nature Mathematized. Boston, MA: Kluwer Academic. p. 279. ISBN 978-90-277-1402-2.
Mason, Joan. "Sarah Ayrton". Oxford Dictionary of National Biography (online ed.). Oxford University Press. doi:10.1093/ref:odnb/37136. (Subscription or UK public library membership required.)
Howatson, A.M. (1965). "An Introduction to Gas Discharges". Plasma Sources Science and Technology. 9 (4): 47–101. Bibcode:2000PSST....9..517B. doi:10.1088/0963-0252/9/4/307. ISBN 978-0-08-020575-5. S2CID 37226480.
Mehta, V.K. (2005). Principles of Electronics: for Diploma, AMIE, Degree & Other Engineering Examinations (9th, multicolour illustrative ed.). New Delhi: S. Chand. pp. 101–107. ISBN 978-81-219-2450-4.
"Laser beams make lightning tunnels". Retrieved 2015-06-20.
Clerici, Matteo; Hu, Yi; Lassonde, Philippe; Milián, Carles; Couairon, Arnaud; Christodoulides, Demetrios N.; Chen, Zhigang; Razzari, Luca; Vidal, François (2015-06-01). "Laser-assisted guiding of electric discharges around objects". Science Advances. 1 (5): e1400111. Bibcode:2015SciA....1E0111C. doi:10.1126/sciadv.1400111. ISSN 2375-2548. PMC 4640611. PMID 26601188.
"Arc Suppression". Retrieved December 6, 2013.
Harper, Charles A.; Petrie, Edward M. (2003). Plastics Materials and Processes: A Concise Encyclopedia. John Wiley & Sons. p. 565. ISBN 9780471456032.
Harper & Petrie 2003, p. ???
"Lab Note #106 Environmental Impact of Arc Suppression". Arc Suppression Technologies. April 2011. Retrieved October 10, 2011.
External links
"High Voltage Arcs and Sparks" Videos of 230 kV 3-phase "Jacobs Ladder" and unintentional 500 kV power arc
High Voltage Arc Gap Calculator to calculate the length of an arc knowing the voltage or vice versa
Hellenica World - Scientific Library
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