Approximately 90 million lightning bolts strike the United States each year and cause approximately 30,000 building fires, over 400 personal injuries and 30% of all power outages.
Lightning is estimated to produce in excess of $2 billion in property damage annually. Lightning is also responsible for more deaths and property losses than tornados and hurricanes.
According to Ernest Freeman and Matthew Glennon, P.E., from the Hartford Steam Boiler Inspection and Insurance Company, the purpose of a lightning protection system is to protect a building and its occupants and contents from the thermal, mechanical and electrical effects of lightning.
This is achieved when a lightning discharge can be safely diverted to the earth without causing damage to the equipment or property.
To do this successfully, the system must intercept the lightning flash before it strikes the structure, lead the current safely downward, prevent the occurrence of side flashes and conduct the current to a ground system which is able to instantly accept the heavy flow of current and dissipate it harmlessly.
When properly located and installed, lightning protection systems consist of three basic components that provide a low impedance metal path to assure that a lightning discharge will be conducted harmlessly between air terminals and the ground.
Air Terminals—Also known as lightning rods, lightning air terminals are pointed metal rods or tubes made of copper, bronze or aluminum which are installed at the high points of a building. Their function is to intercept any lightning in the immediate area.
In some cases, the metal building structure may be used as part of the lightning protection system if the structural metal framing has sufficient cross-sectional area to equal the conductivity of the main lightning conductor and the framing is electrically continuous.
Conductors—Lightning conductors are cables made of copper or aluminum that connect lightning air terminals to one another and to the ground, forming a conductor network. The metal path must be continuous from the ground terminal to the air terminal. The conductor network consists of three parts: the perimeter roof conductor, cross-run conductors and down conductors.
When selecting metal conductors, assure the integrity of the lightning conductor for an extended period. Lightning down conductors should not be painted since this will increase impedance. Gradual bends (minimum 8-inch radius) should be included to avoid flashover problems.
Grounding—Grounding is the key to any lightning protection system. Galvanized steel and copper are suitable ground rod material; aluminum should not be used. Each down conductor should terminate at a ground terminal dedicated to the lightning protection system. Welded connectors are highly recommended in all circumstances.
Ground rods should be at least 1/2 inch in diameter, 8 feet long and should be vertically driven at least 10 feet deep. If the soil is sandy or rocky, additional ground rods may be required to improve the ground resistance. These additional rods should be spaced horizontally at least 10 feet from each other.
After grounding rods have been bonded to the rest of the system, the electrical ground resistance should be checked to see if it meets the National Electric Code© requirement of 25 ohms. Ensure that the lightning ground system is connected to all other grounding systems associated with the structure being protected.
This means interconnecting the lightning protection system with the electrical system ground, as well as telephone, cable TV, antennas or any underground metallic piping system. If the electric, telephone or other systems are bonded to a metallic water pipe, only one connection from the lightning protection system to the water pipe system is required.
The inclusion of electrical Surge Protection Devices (SPDs) should be considered in any comprehensive lightning protection plan if a building contains important electrical or electronic systems or equipment. Proper selection and installation of SPDs can protect electrical and electronic equipment from lightning and other surges that can enter a building through the electric, telephone, data or other wires that enter the building from the outside.
Frequency of inspections varies. Systems should be inspected following installation. Existing systems should receive inspections at intervals determined by such factors as:
In addition, a lightning protection system should be inspected whenever alterations or repairs are made to a protected structure, as well as after any known lightning discharge to the system.
Visual inspections of components should determine the following:
Testing is needed to verify the continuity of the system and the proper operation of components not possible through visual inspection. Perform resistance tests of the ground termination system and compare the results with previous or initial results. Investigate all results with significant differences.
Records should be kept for:
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