Supplying power for electric fire pumps

Power is a key element in ensuring a fire pump works in an emergency situation. This article touches on relevant fire codes and offers best practices to illustrate proper design of power for fire pumps.


Learning Objectives

  1. Know which codes dictate how to specify power for fire pumps.
  2. Understand how to coordinate the numerous codes involved.

Figure 1: The fire pump connects to fire pump controller. The fire pump controller is connected to two power sources. All graphics courtesy: Jacobs EngineeringElectrically powered fire pumps are subject to many national and international codes such as the International Building Code (IBC), NFPA 5000: Building Construction and Safety Code, NFPA 101: Life Safety Code, NFPA 110: Standard for Emergency and Standby Systems, NFPA 20: Standard for Installation of Stationary Pumps for Fire Protection, and NFPA 70: National Electric Code (NEC). Because so many codes are involved, it is important to understand the scope of each code to ensure the correct code is used during the design process.

Fire pump codes

IBC 2009. IBC 2009, Section 403, which concerns high-rise buildings, classifies the fire pump as part of the emergency power system. Section 405, which deals with underground buildings (generally buildings that have a level occupied by humans more than 30 ft below the lowest level of exiting the premises), classifies fire pumps as part of the standby power system.

Section 913 of the IBC requires the installation of fire pumps in accordance with NFPA 20. In this case most fire pump rooms must be protected by 2-hour walls. But for non-high-rise buildings that are fully sprinkled, 1-hour walls are acceptable.

NFPA 5000, 2012 Edition. NFPA 5000 classifies fire pumps as part of the standby system (, High-rise buildings). Since no definition is provided for the standby system, this classification can be misconstrued. But requires compliance with NEC 701, which concerns the legally required standby system.

Another important requirement of NFPA 5000 is Annex F, In-Building Radio Systems. If the local jurisdiction has specifically adopted this annex, the fire pump room must have radio coverage.

NFPA 101, 2012 Edition. Just like NFPA 5000, NFPA 101 Chapter 11 (special structures and high-rise buildings) requires that fire pumps be part of the standby system and comply with NEC 701. Also, 11.8.6 requires that the emergency command center monitor the fire pump status.

NFPA 110, 2010 Edition. NFPA 110 classifies fire pumps as part of Level I systems, which are essential to the safety of human life (see A.4.4.1). This standard refers to NFPA 20 for the installation of fire pumps.

NFPA 20, 2013 Edition. NFPA 20 covers all stationary fire pumps, but Chapter 6 details electrical fire pumps.

Chapter 6 of NFPA 20 requires that the fire pump be powered by a reliable power source or by two or more independent sources. According to Annex A of NFPA 20, a reliable power source complies with 9.2.3 and has not:

  • Had any shutdowns for longer than 4 hours in the previous year
  • Experienced power outages that were not caused by natural disasters or grid management failure
  • Been supplied by overhead conductors.

Figure 2: The jockey pump is needed for the proper operation of the fire pump. The jockey pump is also powered by the generator.NFPA 20 Chapter 9 concerns the performance and testing of electrical equipment between the source and the pump. Even though the fire pumps run infrequently, Chapter 9 requires that all power supplies for the fire pumps be sized based on a continuous duty cycle. Chapter 9 also prohibits the use of phase converters as they are not considered reliable power sources. Thus, it’s necessary to use a single phase motor and fire pump controller if the source is single phase.

Chapter 9 of NFPA 20 describes in detail the overcurrent protection and means of disconnecting a fire pump service. 9.2.3, referenced above, requires the installation of a single disconnecting means and the associating overcurrent protection in the power supply of the fire pump controller. The disconnecting means must be lockable in place to avoid inadvertent power loss and remote from other building disconnecting means.

NFPA 20 also requires an alternate power source for the primary fire pump if the building’s height is beyond the reach of the fire department’s equipment. However, this requirement is waived if a backup pump is installed on the premises. If the alternate power source is a standby generator system, it must have enough capacity to carry the full load of the fire pump and other emergency loads. The generator must also be able to support the fire pump auxiliary system, such as a jockey pump, and have a fuel supply that can provide 8 hours of fire pump continuous operation.

NEC 2011. The proper installation of electrical fire pumps and associating equipment is the scope of the NEC. NEC 2011 dedicates Article 695 to fire pumps. Article 695 was first introduced in NEC 1996. Article 695 of NEC also covers the electrical power sources, interconnecting circuits, and switching and control equipment that are dedicated to the fire pump. Jockey (or makeup) pumps are not covered by Article 695.

Although the scope of Article 695 has not changed, important revisions have been made through the years. One of the most important revisions is the requirement of reliable power for electric fire pumps installed in a campus-style arrangement. This arrangement includes multiple buildings often powered by a medium-voltage distribution system.

In case of a campus-style building complex, such as a university, the fire pump can be fed from more than one power source if there are two (or more) feeders derived from two separate utility services. However, this arrangement has to be approved by the authority having jurisdiction before implementation.

NEC 695.3 requires that a reliable power source supply power for an electric fire pump. While NEC does not define a reliable power source, the definition in NFPA 20, described above, can apply. The reliable power source must also be able to carry the locked rotor current of the fire pump motor and the full load current of the accessory equipment if the accessory equipment is connected to the same power source. This reliable power source could be an individual source that in turn could be one of the following:

  • Separate utility connection.
  • On-site power production facility (that produces power constantly).
  • Dedicated feeder.

If the utility power source is not reliable, multiple sources can be used. Alternate sources could be another separate utility feed or a standby generator or both. The generator does not need to be sized for the locked rotor current of the fire pump—only for the full load current of the fire pump(s) and the associating loads. Remember that NFPA 20 Chapter 9 requires the power source to be sized for the continuous duty of the fire pump.

Figure 3: Feeds from two single-ended substations connect to the fire pump through an automatic transfer switch (ATS). The generator connects to the fire pump through an integrated ATS in the fire pump controller.Best practices

Ensure continuity of power. It is very important that the fire pump is powered continuously and inadvertent power disconnection is averted. To this end, it is preferable that the fire pump controller connects directly to the power supply. However, this connection is not always possible, so 695.4(B) permits the installation of a single disconnecting means and overcurrent protection between the source and the fire pump controller.

NEC 695.6(G) does not permit ground fault protection of the fire pump. Again, this is done to allow continuity of power to the fire pump circuit.

Lock the disconnecting means. Make sure that the disconnecting means is not accidentally exercised, interrupting the power to the fire pump. One way to handle this problem is to lock the disconnecting means in the closed position. Because the disconnecting means might need to be accessed (exercised) during emergency situations, the personnel must know its location. NEC requires a sign placed near the fire pump controller indicating the location of the disconnecting means.

Allow the locked-rotor current. The overcurrent device should be set to allow locked rotor current to flow without tripping. On the other hand, the conductors are sized to no less than 125% of the full load current of the fire pump motor and 100% of the auxiliary loads that the circuit supplies. This standard is different from other NEC requirements in that the rest of NEC requires that the conductors and equipment be protected. In the case of the fire pump circuit, the priority is to keep the pump running no matter what. If a fault occurs, the overcurrent device will trip (which seems to be contrary to what was just stated), but the pump would not work on a short anyway.

Carry only the full load current. The overcurrent protection device between the generator and the fire pump controller is not required to carry the locked rotor load of the fire pump motor. Rather, the overcurrent protection device should be set to carry the full load of the fire pump and the entire auxiliary load fed through the fire pump circuit. The disconnecting means supplied by the emergency generator must also be lockable in the closed position, just like the disconnecting means fed from normal (utility) power.

Design feeding through a transformer. There are cases when a transformer is needed to feed the fire pump circuit. After all, that is why NEC 695.5 exists. The transformer is required to be rated at least 125% of the fire pump and jockey pump loads, plus 100% of auxiliary loads. The primary overcurrent protection device has to be set to allow the locked rotor current of the fire pump and the full load of the associating loads. The secondary overcurrent protection is not allowed.

Account for voltage drop. Another hard requirement of NEC (and also NFPA 20) is that the voltage drop at the fire pump controller be 15% or less. There are several ways to deal with this requirement. Depending on the type of pump, using variable speed drive (don’t forget, the inverter-duty type) eliminates the voltage drop. Another way to mitigate the voltage drop is to size the conductors appropriately.

Protect conductors. The conductors supplying the fire pump need to be protected from physical damage. The conductors should be routed outside the building if feasible. If routed inside the building, the conductors have to be encased in 2 in. of concrete. While in the electrical room and in the fire pump room, conductors are not required to have the minimum 2-hour rating, but if the building is a high-rise, consult NEC 700.10(D).

Work with the fire marshal. When designing power for an electrical fire pump, make sure you talk to the fire marshal about the fire pump room location. In the case of a fire, the fire department will enter the pump room to monitor the pump activity, so the pump room needs to be accessible, preferably from the outside.

Eduard Pacuku is electrical project engineer at Jacobs Engineering, where the majority of his time is spent designing electrical distribution systems for universities (including laboratories), health care facilities, and data centers. He has extensive experience with fire pump installations.

SIVA , AL, India, 04/13/14 03:45 AM:

All points are important which i follow in my project . good information
John , AR, United States, 04/17/14 08:50 AM:

Other codes that may impact design approaches involve arc flash labeling, since such requirements will change how maintenance is allowed to be done; NEC, NFPA 70E, NESC, OSHA. Consider past approaches of tying the fire pump feeder direct to a service transformer; then consider that where "dangerous" arc flash conditions result, that electrical service to the building may have to be turned off in order to service the fire pump equipment. Consequently, new design trends are likely to occur; such as a broader application of arc flash reduction breakers, where no breakers may have been used before.
Anonymous , 04/17/14 09:13 AM:

If arc flash (AF) maintenance switches are employed; shouldn’t there be a warning level for each level of arc flash depending upon the position of the AF Maintenance Switch? Now consider two power sources, each with an AF Maintenance Switch; now there are potentially 4 different levels of arc flash hazard. At a minimum the labeling needs to elaborate the worst case hazard (non-maintenance) condition, and a worst case “maintenance condition.” For service to be performed appropriately (i.e.; safely), further instructions would have to accompany the arc flash label to make clear any expectation for a standard operating procedure. Such as a diagram showing the AF maintenance switch names, locations, lock-out tag-out applications (where appropriate), etc.
John , AR, United States, 04/17/14 09:51 AM:

For those who would restrict arc flash label requirements to the short equipment list in NEC 110.16, I suggest they read it again carefully; Electrical equipment… likely to require examination… while energized, shall be… marked to warn…of… electric arc flash hazards.
Add to this the reference to the NEC 90 intro and NEC 90.1(A) notation to apply professional discretion beyond the “letter of the code”; which is to say to start with the intent (e.g. “safeguarding persons and property”) and apply this arc flash NEC article to each application (e.g. other equipment may also be appropriate for arc flash labeling).
Anonymous , 04/19/14 12:47 PM:

First of all I see on attached photos very bad installation matter. Feeders to fire pumps are not supported by steel construction, just waiving free in the air. Longer discussion is on concrete. First men. fix cabels use B-lines structures. and fire rated steel supports even you said that Fire pumping room has 2 hours fire protection walls. I see very bad electrical works done by PE Engineers. When you attach photos as training course, even on site you work bad make false support just for case presentation. Here in CSE the author and magazine checker forgot the proper rules. May be they are new on a market and fresh authors for magazines articles, but more technical view shall be provided because young electrician will read and then repeat on site "the Burdello". Second
All Fire installation Panels (panelboards) shall be red color. Here on the foto feeder to fire pump is taken from grey color panel, That is not correct to NFPA Standard. The cable shall be laid on cable tray or ladder. Not in US now, but with US training. No more comments.
PE, M.Sc.,EE
RICK , NV, United States, 04/23/14 10:34 AM:

The writer states the installation of standby power to serve a fire pump in the event of a normal supply being lost is to be in compliance with NEC 701. This installation is troublesome to me since 701 systems are standard wiring methods and would not require any special fire protection. Since the 700 systems are permitted to be installed in separate standard wiring methods "when sprinklered", I believe you are jeapordizing the entire 700 system by not installing the fire pump standby wiring per 700 and not 701.
RICK , NV, United States, 04/23/14 10:36 AM:

The writer doesn't address the installation of fire pumps when installed in facilities that are served at medium voltage with multiple paralleled generators serving as standby backup all at medium voltage.
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