Electrical System Grounding EPSCO

Electrical System Grounding

Grounding plays a critical role in any electrical power system. The grounding system is a network that connects all components of an electrical power system to a line buried in the earth. The line carries excess fault current or unwanted electrical charge away from the equipment, structures, and personnel through a path of least resistance so that the current safely dissipates below ground. Proper grounding systems provide a reference point of zero volts on earth and reduce damage, outages, accidents, injuries, and casualties.

Grounding systems provide many benefits for any facility using electrical power systems. They allow for a common reference point in the power system, which makes it easy to detect ground fault locations, identify short circuits, and measure data or unexpected incidents in the power system.  Grounding systems form a defense against transient over-voltages caused by certain types of equipment and help protect equipment via ground fault interrupters, lightning protection, and surge protection. Grounding systems improve safety for workers and lower the odds of high energy electrostatic hazards that can pose extreme dangers to people.


Read this full article and others like it HERE in the Spring 2022 issue of Electrical Safety in the Workplace Magazine.


There are several types of grounding systems, each with a different function–

The following takes a brief overview of the systems that are frequently deployed:


  • System grounding is the most common. It is used in most three-phase power systems. Every piece of equipment in the power system is run into a grounding grid, with grounding rods buried in the earth at least 25 feet deep under the facility. Equipment grounding connects all non-current carrying metal parts to earth– This includes frames, enclosures, transformers, motors, conduits, boxes, cables, poles, and towers. Bonding is commonly used to merge electrically continuous materials. It utilizes infrastructure such as structural steel, plumbing, and other equipment to connect, lead, and feed unwanted electrical current into the grounding grid. These systems utilize green cables or solid, non-stranded uninsulated cables. All the equipment is interconnected and electrically continuous to produce stability and proper grounding. 


  • Neutral grounding systems are deployed for high-energy equipment that generates electromagnetic fields. Parts such as transformers, generators, and motors create transient disturbances and electrostatic hazards. Static often builds up in insulating materials and can become a fire hazard or cause the air to become flammable. Neutral grounding systems provide the means to control and mitigate those disturbances by dissipating high energy charges or electrical faults that could damage gear or cause injuries to workers.
  • Lightning protection uses a conductor network to prevent incidents in towers, buildings, and other tall structures. Lightning strikes cause thermal effects that can spark fire hazards and harm or kill people. Conductor networks re-direct lightning strikes to the ground, diverting harmful current away from buildings, equipment, and individuals.   

Lightning Protection Example Electrical System Grounding EPSCO


  • Surge protection provides transient overvoltage protection caused by drives and motors. Using drives to change motor speeds creates electrical instability and overvoltage conditions. If those overvoltages go undetected, they can cause equipment blowouts or arc flash events that cause injuries to people. Grounding re-stabilizes current levels when motors change speeds, helping to protect equipment and maintain production. Surge protection also mitigates the dangers of tall structures, which produce transient overvoltages as part of regular electrical power system function.

Surge protection Electrical System Grounding


  • Ground fault protection removes excess energy accumulated in structural hardware and takes it to the ground. Most large frames and enclosures are constructed of conductive material and can absorb voltages from energized parts– This creates a dangerous return path for fault current unless the current flow is diverted through a path of least resistance to ground.  Damp, wet, or dusty environments require special attention to the design and maintenance of ground fault protectors. Water is highly conductive, and moisture or particle debris can accelerate the breakdown of equipment. Ground fault protection is the most crucial safety mechanism to decrease shock hazards and prevent loss of life for workers or unqualified individuals who may inadvertently come into contact with equipment, frames, and enclosures. This vital protection is the only way to remove a ground fault from the system. It prevents a person from becoming part of the circuit and suffering an electrical shock.  


More detailed information about any codes and standards related to electrical grounding can be found in National Electrical Code Article 250. It provides guidance on system grounding, equipment grounding and bonding, and conductive material bonding to create an effective ground-fault current path to divert unwanted electrical hazards from equipment that should not be energized. Tables 250.66, 250.102C1, and 250.122 provide helpful grounding, bonding, and sizing references. 


Consulting the NFPA 70E is the best way to ensure your system follows proper grounding procedures that will offer protection to your facility, equipment, and personnel. 

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Author: Dave Hernandez, PE, CEM, GBE, CESCP Chief Operating Officer, EPSCO


Dave Hernandez, PE, CEM, GBE, CESCP is a distinguished Professional Engineer licensed in 52 U.S. jurisdictions and serves as the Chief Executive Officer at Electrical Power & Safety Co. (https://epsco. co), a world leader in electrical safety. He has overseen over 20,000 electrical projects, sits on various industry committees, and has published several white papers.