What Is Arc Flash?

An arc flash is a sudden release of electrical energy caused by an arc fault — an unintended electrical discharge through air between energized conductors or between a conductor and ground. Arc temperatures can reach 35,000°F (nearly four times the surface temperature of the sun), vaporizing copper conductors and creating a pressure wave, intense ultraviolet light, and molten metal spatter. Arc flash incidents cause severe burns, hearing loss, vision damage, and fatalities — making arc flash hazard analysis a critical part of any commercial or industrial electrical project.

Governing Standards

NFPA 70E — Standard for Electrical Safety in the Workplace — requires employers to perform arc flash hazard assessments and label electrical equipment with incident energy levels or arc flash boundaries. Compliance is enforced by OSHA under 29 CFR 1910.132.

IEEE 1584 — Guide for Performing Arc Flash Hazard Calculations — provides the technical methodology for calculating incident energy. The 2018 edition significantly updated the empirical equations based on extensive laboratory testing and is now the industry standard.

Key Terms

  • Incident energy (IE) — the amount of thermal energy at a working distance, measured in cal/cm². Human skin begins to sustain a second-degree burn at 1.2 cal/cm².
  • Arc flash boundary (AFB) — the distance from the arc point at which IE equals 1.2 cal/cm². Workers inside the AFB must wear appropriate PPE.
  • Limited approach boundary — distance within which an unqualified person may not cross without an escort
  • Restricted approach boundary — distance within which only qualified electrical workers may approach
  • Working distance — typically 18 inches for 480V equipment, 24 inches for medium-voltage switchgear

The IEEE 1584 Calculation Method

An arc flash study requires a power system model — typically built in software like SKM PowerTools, EasyPower, or ETAP. The analysis process:

  • Collect system data: utility fault current, transformer impedances, cable sizes and lengths, overcurrent device trip times
  • Build the system model and run a bolted fault current study
  • Calculate arcing fault current at each bus using IEEE 1584 equations
  • Determine the arc duration based on the upstream protective device clearing time
  • Calculate incident energy at each bus at the applicable working distance
  • Determine the arc flash boundary

The arcing fault current is approximately 38–85% of the bolted fault current — IEEE 1584 provides empirical equations that account for system voltage, gap between conductors, and enclosure type (open air, box, switchgear).

PPE Requirements

NFPA 70E Table 130.5(G) defines PPE categories based on incident energy:

  • Category 1 (1.2–4 cal/cm²): arc-rated shirt and pants (4 cal/cm² rating), safety glasses, hearing protection, leather gloves
  • Category 2 (4–8 cal/cm²): arc flash suit with hood, arc-rated gloves
  • Category 3 (8–25 cal/cm²): arc flash suit with hood and face shield, arc-rated gloves, leather footwear
  • Category 4 (25–40 cal/cm²): heavy arc flash suit (40 cal/cm²), face shield

Equipment with incident energy above 40 cal/cm² is considered too hazardous for energized work and must be de-energized before any work is performed.

Reducing Arc Flash Hazard

The most effective ways to reduce incident energy are: reducing clearing time of upstream protective devices (bus differential protection, zone-selective interlocking), installing arc flash detection relays, using current-limiting fuses on feeders, and designing systems with lower available fault current. Engineering controls are always preferred over PPE.

Arc Flash Labels

NFPA 70E requires that electrical equipment be labeled with the incident energy level, arc flash boundary, and required PPE. Labels must be updated whenever the system changes (new transformers, added loads, modified protective device settings). Most firms update their arc flash study every 5 years or after any significant system modification.