This article was posted 08/11/2005 and is most likely outdated.

Mike Holt Newsletter -
 

 
Topic - Grounding versus Bonding, Part 10 of 12
Subject - Piping Systems and Exposed Structural Metal

August 11, 2005 

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Grounding versus Bonding Part 10 of 12

Piping Systems and Exposed Structural Metal

Mike Holt for EC&M Magazine

Does the NEC require you to ground piping systems and structural steel? Be careful how you answer that.

You've probably seen project requirements that call for the grounding of piping systems and exposed structural steel. Those requirements, while well-intended, miss the mark.

The stated intention of such requirements is nearly always the removal of dangerous voltage on specific types of metal parts, in the event of a ground fault. These metal parts include exposed structural steel members, electrically conductive metal water piping systems, metal sprinkler piping, metal gas piping, and other metal piping systems.

But these requirements fail to make that intention a reality. That's because you remove dangerous voltage on metal parts through bonding , not through grounding.

So, while you don't need to ground piping systems and structural steel, you do need to bond them. And you need to bond them in a manner that establishes an effective ground-fault current path [250.4(A)(4)]

Metal water piping systems

You don't need to bond isolated sections of metal water piping connected to a nonmetallic water piping system. But where you have metal water piping systems (rather than just isolated sections that are metal), you must accomplish the bonding via one of three sets of requirements. Which set you conform to depends on whether your installation is a building supplied by a service, a building supplied by a feeder, or a multiple occupancy building.

Building supplied by a service . You must bond the metal water piping system to one of the following (Figure 250–149):

  • Service equipment enclosure
  • Grounded neutral service conductor
  • Grounding electrode conductor, if sized per Table 250.66
  • One of the electrodes of the grounding electrode system.

Size the metal water pipe bonding jumper per Table 250.66, based on the largest ungrounded service conductor. Here's an easy pop quiz for you. What size bonding jumper must you use for the metal water piping system, if the service conductors are 4/0 AWG (Figure 250–150)?

(a) 6 AWG (b) 4 AWG (c) 2 AWG (d) 1/0 AWG

The correct answer is (c) 2 AWG, Table 250.66. Was that your answer?

Where hot and cold water pipes are electrically connected, you need only one bonding jumper—to either the cold or hot water pipe. Otherwise, use a single bonding jumper sized per 250.104(A)(1) to bond the hot and cold water piping together.

Building or Structure Supplied by a Feeder . You must bond the metal water piping system of a building or structure supplied by a feeder to:

  • The equipment grounding terminal of the building disconnect enclosure,
  • The feeder equipment grounding (bonding) conductor, or
  • One of the electrodes of the grounding electrode system.

Size the metal water piping system bonding jumper per Table 250.66, based on the feeder circuit conductors that supply the building or structure. You don't need to make this bonding jumper larger than the ungrounded feeder conductors.

Multiple Occupancy Building . If the metal water piping systems in individual occupancies do not mechanically connect to each other, you can bond the metal water piping system (for each occupancy) to the equipment grounding terminal of the panelboard (Figure 250–151). Size this bonding jumper per Table 250.122, based on to the ampere rating of the occupancy feeder overcurrent protection device.

Other Metal Piping Systems

You must bond metal piping systems (such as gas or air) to an effective ground-fault current path, if they are likely to become energized. The equipment grounding (bonding) conductor for the circuit that may energize the piping can serve as the bonding means (source: NFPA 54, National Fuel Gas Code).

Because the equipment grounding (bonding) conductor for the circuit that may energize the piping can serve as the bonding means, the NEC doesn't require further bonding on the part of the electrical installer (Figure 250–152). Bonding of all metal piping and metal ducts within the building provides an additional degree of safety, but it isn't an NEC requirement.

Structural Metal

If exposed structural metal that forms a metal building frame is likely to become energized, you must bond it to (Figure 250–153) each of these:

  • Service equipment enclosure
  • Grounded neutral service conductor
  • Grounding electrode conductor, if sized per Table 250.66
  • One or more of the electrodes of the grounding electrode system.

This rule doesn't require you to bond sheet metal framing members (studs) or the metal skin of a wood frame building, but doing so is a good practice. Size the bonding jumper for the structural metal per Table 250.66, based on the feeder or service conductors that supply the building (or structure). This bonding jumper must be:

  • Copper where within 18 in. of earth [250.64(A)].
  • Securely fastened and adequately protected, if exposed to physical damage [250.64(B)].
  • Installed without a splice or joint, unless spliced by irreversible compression connectors listed for the purpose or by the exothermic welding process [250.64(C)].

Separately Derived Systems

In the area served by a separately derived system (SDS), you must bond the nearest available point of the metal water piping system to the grounded neutral terminal of the SDS. At the SDS end, you must make this bond at the same location where the grounding electrode conductor and system bonding jumper terminate [250.32(A)] (Figure 250–154).

Size this metal water piping bonding jumper per Table 250.66, based on the largest ungrounded conductor of the SDS. You don't need a water pipe bonding jumper, if you:

  • Use the water pipe as the grounding electrode for the SDS, or
  • Bond the metal water pipe to the structural metal building frame being used as the grounding electrode for the SDS (Figure 250–155).

Where exposed structural metal forms the building frame, you must bond it to the grounded neutral conductor of each SDS. At the SDS end, you must make this bond at the same location where the grounding electrode conductor and system bonding jumper terminate [250.32(A)]. Size each bonding jumper per 250.66, based on the largest ungrounded conductor of the SDS. You don't need a structural metal bonding jumper, if you:

  • Use the metal structural frame as the grounding electrode for the SDS, or
  • Bond the structural metal frame to metal water piping being used as the grounding electrode for the SDS.

Common Grounding Electrode Conductor

Where you have installed a common grounding electrode conductor for multiple SDSs—as permitted by 250.30(A)(4)—you must bond exposed structural metal and interior metal piping (in the area served by the SDS) to the common grounding electrode conductor. But, you don't have to install a separate bonding jumper from each derived system to metal water piping (and to structural metal members), if you have bonded the metal water piping and the structural metal members (in the area served by the SDS) to the common grounding electrode conductor.

Lightning Protection System

Does the facility have a lightning protection system? If yes, bond this system to the building (or structure) grounding electrode system [250.106] (Figure 250–156). Do not use the grounding electrode for a lightning protection system as the building (or structure) grounding electrode [250.60] (Figure 250–157). See NFPA 780, Standard for the Installation of Lightning Protection Systems for additional details on grounding and bonding requirements for lightning protection.

Metal raceways, enclosures, frames, and other metal parts of electrical equipment may require bonding or spacing from the lightning protection conductors (per NFPA 780). Separation from lightning protection conductors is typically 6 ft through air, or 3 ft through dense materials, such as concrete, brick, or wood (Figure 250–158).

People often talk about grounding metal piping systems and structural steel. The danger with such talk is it can mislead you into thinking you have met the requirements of Article 250 and several other standards, when in fact you haven't. Bonding deficiencies are notorious for permitting power quality problems to exist. But the worst part is they leave you with an unsafe facility. For safety and performance, bond .

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Comments
  • You most definitely do need to bond drain pipes and water supply pipes to each other and to the electrical service ground.

    I had an instance where a dying underground electrical line about 30 maybe 40 feet long was leaking 7 amps at 120 volts into the soil during a DROUGHT! The current flow energized the drain pipes and the basement floor causing nasty tingle voltages on properly grounded faucets and a washing machine.

    I also know of a mobile home park that has tree and grass roots that are penetrating the O-rings of gasketed PVC 3034 sanitary sewer pipes. This is in addition to handholes and manholes that are made of concrete which is electrically conductive.

    Interior plastic pipes are no protection. In his book Old Electrical Wiring David Eli Shapiro relates an instance where electricity was crawling up the slime inside of a plastic drain pipe for a shower. Really got the homeowner's attention! He never did find the source of the electricity.

    As electrical systems age these incidents will become more common. A good defense in the case of plastic pipe would be to insert a length of copper, brass, or stainless steel pipe and bond to that. A length at least 2 times the internal diameter but no less than 8 inches would seem to be my gut feel but I have no tests that say that would be effective. You can get schedule 40 copper or brass pipe and hook that in with hubless cast iron pipe couplings and addition to the more familiar type L copper tubing. ( Some places have banned the thinner type M copper tubing.

    Also, I have enough experience in a food plant to know that stainless steel that is in an oxygen deprived environment corrodes like @#!!. The environment can be as small and simple and a bolt in a threaded hole. Therefore, a length of stainless steel drain pipe would need to be between to vents so that there is oxygen circulation.

    Also, electric water heater elements can leak electricity without tripping a breaker. One of the things that I like about 277Y480 volts solidly grounded or resistance grounded is that I can use a Levition high current GFCI with a 120 volt control circuit to implement GFCI protection for vats into which workers pour chemicals and water. Last thing that you want is for a leaking 2 HP pump or a 480 volt heating element to knock the employee against the wall.


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