Arc-Flash Knowledge Center
April 23, 2020
What is an arc flash?
While an arc flash is sometimes used interchangeably with “arc fault”, an arc flash is more accurately defined as the light produced during an arc fault. An arc fault is a type of electrical fault that results from the breakdown of an insulating medium between two conductors where the energy is enough to sustain an arc across the insulator (often air) and can cause extreme amounts of light (arc flash), immense heat upwards of 19,000 °C, and a resulting explosive pressure wave (arc blast). These forces combine to create a hazardous condition that can vaporize metal, destroy equipment, and pose a significant hazard to anyone in the vicinity.
What causes an arc flash?
An arc flash happens when electric current flows through an air gap between conductors. There are several ways this can happen but the most common occurrence is when conductor insulation is worm or broken down.
What is an arc-flash relay?
Arc-flash relays are microprocessor-based devices that use optical sensors to detect the onset of a flash. The sensors are strategically placed in various cubicles or drawers inside the switchboard. Installing an arc-flash relay to rapidly detect developing arc flashes greatly reduces the total clearing time and the amount of energy released through an arcing fault. In turn, there is less damage to equipment and fewer and less severe injuries to nearby personnel.
How Do Arc-Flash Relays Work?
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Video transcript:
There are many reasons an arc flash can occur and Littelfuse arc-flash relays can provide superior protection against its damaging results. Littelfuse market-leading arc-flash relay designs deliver reliable, easy-to-install protection. Littelfuse arc-flash relays and sensors are plug-and-play making them as easy to retrofit into existing switchgear as installing them into new equipment. No additional software is required.
Littelfuse arc-flash relays use light instead of current to detect an arc flash in under one millisecond. The fiber optic light sensor detects light throughout the entire length of the fiber. The sensor is ideal to protect buss bars, multiple compartment installations like motor control centers, or areas with many obstructions.
Littelfuse sensors are interchangeable. Giving the flexibility to adjust as needed during installation. The sensor’s red flashing light tells you the sensor is installed correctly and working. This visual indication serves as a warning to workers; if they open a cabinet and there’s no light they know to close it immediately. Littelfuse recommends mounting one or two sensors per cubicle to cover all horizontal and vertical buss bars, breaker compartments and anywhere there’s potential for an arc flash. Littelfuse arc-flash relays have backup trip paths, so if one fails the other is still protecting.
Arc flash relays improve sustainability and life of electrical equipment. They can also help lower the PPE category of protected equipment. An arc-flash relay is an integral part of an arc-flash protection system that can minimize damage, save money, time and lives.
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Why are arc-flash relays important?
Arc-flash relays are a necessary component in an electrical cabinet because they reduce the amount of incident energy in the system. While an arc-flash relay cannot prevent an arc flash from happening, it will protect critical assets and workers’ safety by reducing the severity of the flash. An arc-flash relay is an integral part of an arc-flash protection scheme that can minimize damage, and save money, time, and lives.
How much energy is in a typical arc-flash incident?
A phase-to-phase fault on a 480-volt system with 20,000 amperes of fault current provides 9,600,000 watts of power. If there is no arc protection and the fault lasts for 200 milliseconds before the overcurrent protection clears it, then nearly 2 megajoules of energy will be released, which corresponds roughly to a stick of dynamite.
The energy formula for an arc flash is:
Energy = voltage × current × time
480 V × 20,000 A × 0.2 s = 1,920,000 J
For a given system voltage, two factors can be adjusted to reduce arc-flash energy: time and current. Time can be reduced by using an arc-flash relay, such as the PGR-8800 or AF0500, to rapidly detect an electric arc flash. An arc-flash relay causes the connected circuit breaker to trip at its instantaneous speed, overriding any inverse-time delay. Current can be reduced by using current-limiting fuses or, in the case of phase-to-ground faults, by using high-resistance grounding.
What are the key considerations when choosing an arc-flash relay?
The most important aspects of arc-flash relays are:
- – reaction time,
- – trip reliability,
- – ease of installation,
- – sensor flexibility,
- – software,
- – sensor design,
- – avoidance of nuisance tripping, and
- – scalability.
Gain a deeper understanding of which features to consider when selecting an arc-flash relay with the white paper, Key Considerations to Selecting an Arc-Flash Relay.
What are the consequences of an arc flash?
Arcing and electric arc flashes are uncontrolled, intense, luminous discharges of electrical energy that occur when electric current flows across what is normally an insulating medium. The most common cause of arc faults is insulation failure. These failures may be caused by defective or aging insulation material, poor or incorrect maintenance, dust, moisture, vermin, and human error (such as touching a test probe to the wrong surface or a tool slipping and touching live conductors).
Arc-flash events are dangerous, and potentially fatal, to personnel. According to OSHA, industrial arc-flash events cause about 80% of electrically-related incidents and fatalities among qualified electrical workers. Even if personnel injuries are avoided, an arc flash can destroy equipment, resulting in costly replacement and downtime.