This article was posted 05/04/2006 and is most likely outdated.

Articles 701 and 702: Legally Required and Optional Standby Systems
 

 
Topic - NEC
Subject - Articles 701 and 702: Legally Required and Optional Standby Systems

May 4, 2006  

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Articles 701 and 702: Legally Required and Optional Standby Systems

 

By Mike Holt for EC&M Magazine

What are they and what are the rules?

Emergency Power Systems (Article 700) are at the top of the hierarchy of backup power systems. Legally required standby systems, which fall under Article 701, hold the number two spot. Optional standby systems (Article 702) are third in the pecking order. The level of importance is the order in which they appear in the NEC.

A system is legally required when any government agency having jurisdiction says it is. The rules that dictate what kinds of loads are legally required (or emergency) are found in the locally adopted building code, such as the International Building Code or NFPA 101 Life Safety Code. Unlike emergency systems, legally required systems do not directly protect the lives of the public at large. They prevent shutting down specific loads, the loss of which would create hazards or impede rescue operations. Hospital communications systems, for example, fall under Article 701 because evacuation instructions announced over the public address system are part of a rescue operation. Article 701 governs the installation, operation, and maintenance of such systems.

Legally required circuits and equipment supply illumination or power upon interruption of the normal electrical supply. They provide electric power to aid in firefighting, rescue operations, control of health hazards, and similar operations. They typically supply such loads as communications systems, ventilation and smoke removal systems, sewage disposal, lighting, and potentially dangerous industrial processes. Surprisingly enough, they might also include fire pumps and elevators, which many people automatically assume are emergency loads. The definition of “Legally Required Standby Systems” in 701.2 contains a Fine Print Note that lists some of the items that might be a legally standby system…but be careful—Fine Print Notes are informational only [90.5(C)]. Don’t depend on this Fine Print Note as a comprehensive list.  Always consult the AHJ and/or Fire Marshall to find out what is and what is not legally required…never just guess.

When it’s optional

A standby power system is optional when it’s not required by Article 700 or Article 701. These systems protect public or private facilities or property where life safety doesn’t depend on the performance of the system. These systems are not required for rescue operations.

They may supply on-site generated power to selected loads automatically or manually. These are typically installed to provide an alternate source of power. This can be for a variety of facilities, including industrial and commercial buildings, farms, and even residences. They serve such loads as heating and refrigeration systems, data-processing systems, communications systems, and industrial processes. They may also serve any load that the customer considers important enough to warrant a backup system, but not important enough for a building code to require it, such as break room refrigerator or that all important coffee maker.

These systems may be permanently installed, or they may be arranged for a connection to a premises wiring system from a portable alternate power supply (Figure 702-10). A portable generator doesn’t fall within the scope of Article 702 unless the generator is connected to the premises wiring (Figure 702-2).

It should come as no surprise that the AHJ must approve all equipment use in legally required systems [701.4]. What may surprise you is this same rule applies to optional systems [702.4].

Tests and Maintenance

While there are compelling operational and economic reasons to conduct testing and maintenance of optional systems, doing so is not an NEC requirement. But for legally required systems, it is [701.5].

Legally required standby system testing consists of acceptance testing and operational testing. You must maintain records of testing and maintenance [701.5(D)].

Conduct or Witness Test. The AHJ must conduct or witness an acceptance test of the emergency system upon completion of the installation, and periodically thereafter [701.5(D)].

Tested Periodically. Legally required standby systems must be periodically tested to ensure they are in proper operating condition. Running the system to power the loads of the facility is a generally accepted method of operational testing. In fact, you must provide a means to test these systems under the maximum anticipated load condition [701.5(E)].

Capacity and Rating

Legally required and optional standby systems must have adequate capacity to safely carry all loads that are expected to operate simultaneously [701.6 and 702.5]. Because optional standby systems are not critical, the user of the system can select which load(s) to connect to the system.

Additionally, both legally required standby system and optional standby system equipment must be suitable for the maximum available fault current at line terminals. The legally required standby alternate power source can supply legally required standby and optional standby system loads under either of these conditions [701.6]:

  • The alternate power source has adequate capacity to handle all connected loads.
  • Automatic selective load pickup and load shedding is provided to ensure that the legally required system takes priority over the optional system.

Power Sources

To protect utility workers, the backup system must have approved transfer equipment. Legally required standby systems and optional standby systems can be on the same transfer switch (emergency systems must have their own [700.6(D)]). On legally required systems, transfer equipment must be identified for standby use and be approved by the AHJ [701.7].

Where an outdoor generator has a readily accessible disconnecting means within sight (within 50 ft) of the structure, you don’t need an additional disconnecting means for the generator feeder conductors that serve or pass through the structure [701.11(5) and 702.1] (Figure 701-3).

 

Signage

To warn emergency response personnel of multiple electrical supply systems, both legally required and optional standby systems are required to have a sign indicating the presence of the system.  This signage must be placed at the service disconnecting means for the structure, and must indicate the physical location of the standby systems power source [701.9(A) and 702.8(A)].

The remaining Chapter 7 power source requirements apply to legally required systems [701.11], but not to optional power sources.

If the normal supply fails, legally required power must be available within 60 seconds (as opposed to 10 seconds for emergency systems). The supply system for the legally required standby power source must be one of these seven types:

  • Storage batteries [701.11(A)]. These must be of suitable rating and capacity to maintain the total load for 1.5 hours, without the voltage applied to the load falling below 87.5% percent of normal.
  • Generator Set [701.11(B)]. If prime mover-driven, a generator acceptable to the AHJ (and sized per 701.6) must have the means to automatically start the prime mover upon failure of the normal service. Where internal combustion engines are the prime movers, you need a two-hour on-site fuel supply (Figure 701-2).
  • Uninterruptible power supplies [701.11(C)]. A UPS must comply with the requirements for batteries and generators.
  • Separate Service [701.11(D)]. An additional service installed per Article 230 can serve as a legally required source of power, but only if it is acceptable to the AHJ (Figure 701-4). To minimize the possibility of simultaneous interruption of the legally required standby supply, a separate service drop or lateral must be electrically and physically separated from all other service conductors.
  • Connection Ahead of Service Disconnecting Means [701.11(E)]. Where acceptable to the AHJ, connection ahead of (not within) the same cabinet, enclosure, or vertical switchboard section as the service disconnecting means is permitted (Figure 701-5). To prevent simultaneous interruption of supply, the legally required standby service disconnect must be sufficiently separated from the normal service disconnection means. See 230.82 for equipment permitted on the supply side of a service disconnecting means. You cannot have more than six service disconnects, including the disconnecting means for the standby system [230.71(A)].
  • Fuel Cell Systems [701.11(F)]. A fuel cell system meeting the requirements of Article 692 can be used provided the system is capable of carrying the load for at least two hours of full demand operation.
  • Unit Equipment [701.11(G)]. Unit equipment consisting of a battery, a battery charging means and automatic actuation can serve to supply some legally required loads, such as lighting. Where unit equipment is used, the battery must maintain at least 87.5% of battery voltage for at least 90 minutes.

Wiring and Circuit Protection

The wiring for these systems can be in raceways, cables, boxes, and cabinets with other general wiring [701.10 and 702.9].

You don’t need to provide ground-fault protection of equipment on the alternate source of legally required standby power systems [701.17]. But you must ensure selective coordination [Article 100] of the Overcurrent Protection Devices (OCPDs) of legally required power systems with all supply-side OCPDs [701.18]. Selective coordination for optional standby systems is not a code requirement.

Grounding and bonding

If the system is separately derived, ground it per 250.30 [250.20(D)]. If it’s not separately derived, bond it to the system grounding electrode. Nothing in 701 explicitly states this, yet it’s explicitly stated in 702.10(B).

When you step back and take a look at what each kind of standby system is trying to accomplish, the requirements make sense.

Article 700 applies to systems or equipment required to protect people who are in an emergency and are trying to get out, while Article 701 applies to systems or equipment needed to aid the people responding to the emergency. Article 700 lighting provides an exit path, but Article 701 lighting illuminates fire hydrants and switchgear areas. Article 702 systems don’t protect people—they protect against financial loss.

During the mass power outage in Chicago a few years ago, food storage facilities and medical laboratories lost millions of dollars of inventory. Optional standby systems could have prevented those losses, which is one reason we see optional standby systems in facilities where loss of power causes business interruptions.

In an extended outage, the logistics of fuel delivery becomes a problem and this can force you to abandon your optional standby system. In 1994, for example, an ice storm shut down Kentucky interstate highways for three days. Companies that ran out of fuel for their optional standby systems were barred from “borrowing” the fuel from their legally required or emergency systems. If you can’t supply your legally required systems, you can’t legally operate. If you can’t supply your emergency systems, you typically can’t occupy the premises.

To ensure that you don’t confuse what’s optional with what’s legally required, walk down your systems and identify which non-emergency circuits and equipment prevent danger or aid in rescuing people. Review this list with the AHJ and/or Fire Marshall, making any necessary additions. Everything else is optional.

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Comments
  • There have been questions recently concerning the number of transfer switches required. Article 700.6(D) required a seperate transfer switch for emergency loads. This paragraph does not appear in Articles 701 and 702. some have asked if this means that one transfer switch can be used for 701 and 702 loads. Can anyone clairify in the NEC?

    Bob
    Reply to this comment

  • A newer technology that changes some parameters is that Advance now makes some Centium unversal voltage ballasts that are rated for use on both alternating current and direct current. An attractive option for night lighting in a large facility is to run night lighting fluorescent fixtures on 240Y416 volts AC for normal power and then switch the circuits ( using 4-pole power contactors ) to a 192 volt ( 4x48 volts ) or 240 volt bank. In a large facility incandescent battery packs do diddally squat.

    The transfer switch would need to one that has an adequate DC rating using 2 or 3 poles in series. Telemecanique\'s 4-pole F series contactors with 2 normally open poles and 2 normally closed poles would fit the bill using each pair of like poles in series to get a 300 volt DC rating. You would need to use the NO pole for AC power and the NC poles for the emergency battery bank. This would be electrically held in the normal power position and mechanically held in the emergency position.

    MIke Cole mc5w at earthlink dot net

    Michael R.Cole
    Reply to this comment

  • You're right, Mike. For many years I have been preaching about the different types of emergency loads addressed in these sections. 701 is for getting people out of the building safely. 702 is for the legally required standby. 703 is for the optional stuff. I am constantly defending my emergency lighting panel from people who want to add loads for their boiler controls, security cameras, even heat trace for cooling towers. Would you be happy if a generator stalled and killed the exit signs because the VP of the company wanted his air conditioning on the emergency panel?? That's why there are separate systems. They can share the same source, but they need to be divorced from one another at the earliest point in the system. I'll put away my soap box now...

    Leo
    Reply to this comment

  • Good article. I just want to add that for most states like here in NC what is permitted as emergency loads is determined by the building code not he NEC. In our case that is chapter 27 IBC i.e.NCBC. The NEC basically tells how it will be installed.

    Typical emergency loads are emergency egress lighting including exit lights, and fire alarm systems. These all have to do with life safety. You do not want anything that is not necessary to protect life that can generate enough energy during a fault to take out the emergency over-current device.

    Jim Yancey-NCDOI jyancey@ncdoi.net

    Jim Yancey
    Reply to this comment

  • Mike,

    Good newsletter on a subject that causes much confusion.

    I would have liked to see further commentary on GFP. Like the Code, you did not specifically state that GFP is required on optional standby systems. I find that many engineers overlook 702.3, which would inform them that 240.13 still applies for optional standby systems. Further, for a nonseparately derived system, 230.95(C) FPN No. 3 comes in to play. A typical 4-wire residual GF scheme on the generator breaker will see no ground fault current because the only path to return to the generator is on the grounded neutral conductor. A modified differential scheme is one way to resolve this problem.

    Blane Leuschner
    Reply to this comment


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