Conductor clashing

Last updated September 17, 2024

In an overhead power line, conductor clashing occurs when energized wires accidentally come into contact with each other. Overhead transmission systems typically use un-insulated bare conductors for reasons of weight and economy. When bare conductors touch, the resulting momentary short circuit or electric arc can cause disturbances to the electric power system, damage to the conductors, or fire. Conductor clashing may be caused by wind, ice, excess sag due to creep or thermal expansion due to sustained heavy loading, or by contact with animals or objects. Conductor clash is prevented by proper design and installation to anticipate the likely conditions of weather and load. The effects of clashing conductors can be mitigated by fuses or protective relays and circuit breakers to de-energize the shorted conductors. For some types of transmission line, it may be possible to automatically reclose a circuit breaker in expectation that the clash was a momentary problem, thus minimizing interruption of service to grid customers.

Causes

Heavy winds or gusts can often result in the unintended contact of conductors, particularly where power lines exhibit excessive sag or other structural conditions that permit conductors to come into close proximity.^[1]^[2]

Trees near power lines may break and drop branches onto the wires, increasing the potential for conductors to clash by bringing them together.^[1]

Vehicles may hit transmission towers or poles, and aircraft may get entangled in wires. This may cause power lines to clash. This type of collision, often the result of accidents, can have a cascading effect on the power system, leading to conductor clashing.^[3]

Seismic activity may displace transmission line support structures, disturbing the planned spacing of conductors and possibly producing a clash.

Acts of vandalism targeted at power lines introduce another reason for conductor clashing. Deliberate acts of hurling objects at power lines can induce drooping and the subsequent collision of wires.^[4]

Process

When conductors clash, heat is produced, along with vaporization of conductor material, and the expulsion of metal particles. These ejected particles, often in the form of sparks, are then carried away by the wind.^[4]

The combustion aspect is driven by the release of energy in the form of an electrical arc (electrical breakdown of gas resulting in electrical discharge). Simultaneously, the conductor material erodes and vaporizes due to the intense heat generated by this arc. The process is significantly influenced by key parameters, including arc voltage, short-circuit current, and the duration of the arc. A higher arc voltage intensifies the energy of the electrical arc, while an increased short-circuit current leads to more substantial heat generation and vaporization of the conductor material. The duration of the arc plays a critical role, impacting the extent of material vaporization and potentially leading to molten or burning particles.^[2]

Contact between conductors may produce an electric arc with a bright flash, the emission of sparks, and a puff of white smoke. The intense heat of the arc causes the underlying metal to reach its boiling point and vaporize. When these vaporized metal particles come into contact with the air, they ignite and burn rapidly, forming ${\ce {Al2O3}}$ (aluminum oxide) as small aerosol particles. These aerosol particles can reach temperatures anywhere from 930 K (Kelvin) to 2730 K and create the characteristic puff of smoke. When the oxide is in a molten state, the oxidation process proceeds rapidly, with the heat generated by oxidation offsetting heat losses through convection and radiation. These droplets will continue to burn until all the metal is consumed or until they reach the ground.^[2]

Effects

Fire ignition resulting from conductor clashing has been a recurring issue worldwide, with numerous instances occurring in various countries. Such incidents can lead to significant environmental damage, such as forest fires, as well as substantial financial losses and, in some cases, pose potential threats to human lives.^[1]^[3]

An example of a conductor clashing catastrophe occurred in Western Australia on December 2, 2004. A 19.1 kV (kilovolt) conductor became dislodged from a pole-mounted insulator at the first pole and subsequently clashed with the underslung running earth conductor approximately 200 meters away. This collision led to a flashover (ignition of combustible material in an enclosed area), releasing hot metal particles (sparks) that ignited dry harvested stubble, which initiated the wildfire. Amid the fire, both conductors snapped, with the first conductor ultimately succumbing to structural wear and the influence of northerly winds. When both conductors fell and made contact with the dividing fence, the wildfire was ignited. It's worth noting that the property owner had previously reported a low-hanging power line conductor adjacent to the first pole. According to the property owner's estimate, roughly 468 hectares of land had been burned.^[5]

Related Research Articles

An electric current is a flow of charged particles, such as electrons or ions, moving through an electrical conductor or space. It is defined as the net rate of flow of electric charge through a surface. The moving particles are called charge carriers, which may be one of several types of particles, depending on the conductor. In electric circuits the charge carriers are often electrons moving through a wire. In semiconductors they can be electrons or holes. In an electrolyte the charge carriers are ions, while in plasma, an ionized gas, they are ions and electrons.

<span class="mw-page-title-main">Switch</span> Electrical component that can break an electrical circuit

In electrical engineering, a switch is an electrical component that can disconnect or connect the conducting path in an electrical circuit, interrupting the electric current or diverting it from one conductor to another. The most common type of switch is an electromechanical device consisting of one or more sets of movable electrical contacts connected to external circuits. When a pair of contacts is touching current can pass between them, while when the contacts are separated no current can flow.

A high-voltage direct current (HVDC) electric power transmission system uses direct current (DC) for electric power transmission, in contrast with the more common alternating current (AC) transmission systems. Most HVDC links use voltages between 100 kV and 800 kV.

An overhead line or overhead wire is an electrical cable that is used to transmit electrical energy to electric locomotives, electric multiple units, trolleybuses or trams. The generic term used by the International Union of Railways for the technology is overhead line. It is known variously as overhead catenary, overhead contact line (OCL), overhead contact system (OCS), overhead equipment (OHE), overhead line equipment, overhead lines (OHL), overhead wiring (OHW), traction wire, and trolley wire.

<span class="mw-page-title-main">Circuit breaker</span> Automatic circuit protection device

A circuit breaker is an electrical safety device designed to protect an electrical circuit from damage caused by current in excess of that which the equipment can safely carry (overcurrent). Its basic function is to interrupt current flow to protect equipment and to prevent fire. Unlike a fuse, which operates once and then must be replaced, a circuit breaker can be reset to resume normal operation.

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A transmission tower is a tall structure, usually a lattice tower made of steel that is used to support an overhead power line. In electrical grids, transmission towers carry high-voltage transmission lines that transport bulk electric power from generating stations to electrical substations, from which electricity is delivered to end consumers; moreover, utility poles are used to support lower-voltage sub-transmission and distribution lines that transport electricity from substations to electricity customers.

<span class="mw-page-title-main">Electrical breakdown</span> Conduction of electricity through an insulator under sufficiently high voltage

In electronics, electrical breakdown or dielectric breakdown is a process that occurs when an electrically insulating material, subjected to a high enough voltage, suddenly becomes a conductor and current flows through it. All insulating materials undergo breakdown when the electric field caused by an applied voltage exceeds the material's dielectric strength. The voltage at which a given insulating object becomes conductive is called its breakdown voltage and, in addition to its dielectric strength, depends on its size and shape, and the location on the object at which the voltage is applied. Under sufficient voltage, electrical breakdown can occur within solids, liquids, or gases. However, the specific breakdown mechanisms are different for each kind of dielectric medium.

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<span class="mw-page-title-main">Overhead power line</span> Above-ground structure for bulk transfer and distribution of electricity

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This glossary of electrical and electronics engineering is a list of definitions of terms and concepts related specifically to electrical engineering and electronics engineering. For terms related to engineering in general, see Glossary of engineering.

References

1 2 3 Ramljak, Ivan; Majstrovic, Matislav; Sutlovic, Elis (2014-05-05). "Statistical analysis of particles of conductor clashing". 2014 IEEE International Energy Conference (ENERGYCON). IEEE. pp. 638–643. doi:10.1109/ENERGYCON.2014.6850494. ISBN 978-1-4799-2449-3. S2CID 32761986.
1 2 3 Majstrović, Matislav; Sutlović, Elis; Ramljak, Ivan; Nižetić, Sandro (2018), Nižetić, Sandro; Papadopoulos, Agis (eds.), "Comparison of Aluminum and Copper Particle Critical Diameter Produced in Overhead Line Conductor Clashing", The Role of Exergy in Energy and the Environment, Green Energy and Technology, Cham: Springer International Publishing, pp. 13–25, doi:10.1007/978-3-319-89845-2_2, ISBN 978-3-319-89845-2 , retrieved 2023-11-06
1 2 Sutlovic, E.; Ramljak, I.; Majstrovic, M. (2019-06-12). "Analysis of conductor clashing experiments". Electrical Engineering. 101 (2): 467–476. doi:10.1007/s00202-019-00790-0. ISSN 0948-7921. S2CID 253711952.
1 2 Russell, B. Don; Benner, Carl L.; Wischkaemper, Jeffrey A. (2012-04-14). "Distribution feeder caused wildfires: Mechanisms and prevention". 2012 65th Annual Conference for Protective Relay Engineers. IEEE. pp. 43–51. doi:10.1109/cpre.2012.6201220. ISBN 978-1-4673-1842-6. S2CID 22707760.
↑ Department of Consumer and Employment Protection Government of Western Australia (2005-05-20). "ELECTRICAL INCIDENT REPORT" (PDF).

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[:0-1] 1 2 3 Ramljak, Ivan; Majstrovic, Matislav; Sutlovic, Elis (2014-05-05). "Statistical analysis of particles of conductor clashing". 2014 IEEE International Energy Conference (ENERGYCON). IEEE. pp. 638–643. doi:10.1109/ENERGYCON.2014.6850494. ISBN 978-1-4799-2449-3. S2CID 32761986.

[:5-2] 1 2 3 Majstrović, Matislav; Sutlović, Elis; Ramljak, Ivan; Nižetić, Sandro (2018), Nižetić, Sandro; Papadopoulos, Agis (eds.), "Comparison of Aluminum and Copper Particle Critical Diameter Produced in Overhead Line Conductor Clashing", The Role of Exergy in Energy and the Environment, Green Energy and Technology, Cham: Springer International Publishing, pp. 13–25, doi:10.1007/978-3-319-89845-2_2, ISBN 978-3-319-89845-2 , retrieved 2023-11-06

[:12-3] 1 2 Sutlovic, E.; Ramljak, I.; Majstrovic, M. (2019-06-12). "Analysis of conductor clashing experiments". Electrical Engineering. 101 (2): 467–476. doi:10.1007/s00202-019-00790-0. ISSN 0948-7921. S2CID 253711952.

[:52-4] 1 2 Russell, B. Don; Benner, Carl L.; Wischkaemper, Jeffrey A. (2012-04-14). "Distribution feeder caused wildfires: Mechanisms and prevention". 2012 65th Annual Conference for Protective Relay Engineers. IEEE. pp. 43–51. doi:10.1109/cpre.2012.6201220. ISBN 978-1-4673-1842-6. S2CID 22707760.

[:3-5] Department of Consumer and Employment Protection Government of Western Australia (2005-05-20). "ELECTRICAL INCIDENT REPORT" (PDF).

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