This article was posted 02/14/2006 and is most likely outdated.

Article 695: Fire Pumps
 

 
Topic - NEC
Subject - Article 695: Fire Pumps

February 14, 2006 

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Article 695: Fire Pumps

 

By Mike Holt for EC&M Magazine

Why some fire pump requirements are “backwards”

One of the principle NEC requirements for circuit protection is that you shut down the equipment rather than let supply conductors melt from overload. But Article 695 seems to require just the opposite.

A fire pump supplies water to a facility’s fire protection piping, which in turn supplies water to the sprinkler system and fire hoses. It’s vital to keep that supply of water flowing. The core principle of Article 695 is the fire pump motor must run no matter what—because it exists to protect the facility and the people who work there.

So you will keep that fire pump running, regardless of the consequences to the pump or its circuits. Saving the fire pump or its conductors is a hollow victory if you lose the facility—or people.

Article 695 is “backwards” from the rest of the NEC because it won’t shut down equipment in the event of an overload. Yet, many of its requirements are obvious—for example, you have to install the fire pump wiring in a location that minimizes its exposure to fire. As you read through Article 695, several requirements will jump out as being common sense. In addition to these NEC requirements, you will also find many requirements in other NFPA standards, such as NFPA 20 Standard for the Installation of Stationary Pumps for Fire Protection. These rules include the physical location of the fire pump, which must also be in a location that minimizes its exposure to fire.

But some requirements will initially seem wrong—until you go back to that core principle of “run no matter what.” For example, the disconnect must be lockable in the closed position [695.4(b)(2)(2)]. You would expect a normal disconnect to be lockable in the open position—so you can de-energize the circuit and keep it de-energized. But fire pump disconnects are not normal. You lock them closed to prevent de-energization of the circuit.

Power Sources [695.3]

You must supply power to fire pump motors from a reliable source that has the capacity to carry the locked-rotor current of the fire pump motor(s) and pressure maintenance pump motors. This source must also be capable of supplying the full-load current of any associated fire pump equipment . Reliable sources of power include single sources such as:

  • A separate electric utility service from a connection located ahead of (but not within) the service disconnecting means.
  • An on-site power supply, such as a generator. This can supply a fire pump only if it’s located (and protected) to minimize damage by fire.

If a single source isn’t adequate, you can use a combination of sources. The Authority Having Jurisdiction (AHJ) has final say as to what constitutes a reliable source of power.

You must also ensure power continuity, by protecting supply circuits from inadvertent disconnection [695.4]. To do this, you can use a direct connection or a supervised connection.

Direct Connection. The supply conductors must directly connect the power source either to a listed fire pump controller or to a listed combination fire pump controller and power transfer switch [NFPA 20:9.3.2.2.2].

Supervised Connection. You can install a single disconnecting means and associated overcurrent protective device(s) (OCPD) between a remote power source and one of the following:

  • A listed fire pump controller
  • A listed fire pump power transfer switch
  • A listed combination fire pump controller and power transfer switch

Size the supply transformer for no less than 125 percent of the sum of the fire pump and pressure maintenance pump(s) motor loads, and 100 percent of the ampere rating of the accessory equipment [695.5].

Disconnects [695.4(B)]

The disconnecting means must:

  • Be identified as suitable for use as service equipment.
  • Be lockable in the closed position.
  • Not be located within equipment that feeds loads other than the fire pump.
  • Be located sufficiently remote from other building or other fire pump source disconnecting means.
  • Be marked “Fire Pump Disconnecting Means.” The letters must be at least 1 in. in height and be visible without opening enclosure doors or covers.

Power Wiring [695.6]

You must route the supply conductors outside buildings, where possible. Where it’s not possible to route the supply conductors outside buildings, encase them in 2 in. of concrete or brick [230.6(2)]. In either case, install these conductors as service entrance conductors per Article 230 [695.6].

Fire pump supply conductors on the load side of the final disconnect [695.6(B)] must be independent of all other wiring. You can route them through a building only if using one of the methods specified in 695.6(B).

If conductors supply fire pump motors or accessory equipment, size them no less than 125 percent of the sum of the motor full-load current as listed in Table 430.248 (or 430.250) plus 100 percent of the ampere rating of the accessory equipment [695.6(C)].

Conductors supplying a single fire pump motor must be sized per 430.22: This means the branch-circuit conductors to a single fire pump motor must have an ampere rating of not less than 125 percent of the fire pump motor full-load current (FLC)—as listed in Table 430.248 or 430.250.

And:

  • You can run wiring from the fire pump controller to the fire pump motor only in raceway listed in 695.6(E).
  • You cannot use ground-fault protection for fire pumps [695.6(H)].

Overcurrent protection [695.6(D)]

Overcurrent protection devices (OCPDs) must be sized to carry indefinitely the sum of the locked-rotor current of the fire pump and pressure maintenance pump motor(s), and 100 percent of the ampere rating of the fire pump’s accessory equipment.

Why such big OCPDs? To protect fire pump branch-circuit and feeder conductors against short circuits—not overloads. Again, the fire pump must run no matter what—so, Article 695 expressly forbids automatic overload protection. But isn’t this risky? Not really. By design, you have overload prevention built in—these circuits have a dedicated load and supply, with installation requirements that greatly minimize the chance of overload.

But wouldn’t short circuit protection shut the pump down and thus violate the “run no matter what” rule? Yes and no. A short circuit would shut down the pump anyhow. Short circuit protection makes it possible to fix the short circuit and then run the pump.

The requirement to carry the locked- rotor currents indefinitely applies to OCPDs in the fire pump circuit(s), not to other conductors or devices.

Voltage Drop [695.7]

The voltage at the line terminals of the controller, when the motor starts (locked-rotor current), must not drop more than 15 percent below the controller’s rated voltage. Also, the voltage at the motor terminals must not drop more than 5 percent below the voltage rating of the motor when the motor operates at 115 percent of the fire pump full-load current rating.

Test your knowledge with this problem. A 25 hp, 208V three-phase fire pump motor is 175 ft from the service. The fire pump motor controller is 150 ft from the service. What size conductor must you install to the fire pump motor controller? Equipment terminals are rated 75ºC (Figure 695-2).

(a) 4 THHN     (b) 3 THHN    (c) 2 THHN    (d) 1 THHN

Answer: (b) 3 THHN

Answer: Cmil = [(1.732 x K x I x D)/VD]

K = 12.9 ohms, copper

I = 404A (locked-rotor, Table 430.251B)

D = 150 ft

VD = 31.2V (208V x 15%)

Cmil = (1.732 x 12.9 ohms x 404A x 150 ft)/31.2V

Cmil = 43,397, Chapter 9, Table 8 = 3 AWG

Where you increase the size of ungrounded conductors, you must proportionately increase equipment grounding (bonding) conductors (where installed)—according to the circular mil area of the ungrounded conductors [250.122(B)].

Now, for the same pump, what size conductor must you install to the fire pump motor? Remember, it’s 25 ft from the controller (Figure 695-3).

(a) 4 THHN     (b) 3 THHN    (c) 2 THHN    (d) 1 THHN

Answer: (b) 3 THHN

The operating voltage at the terminals of the motor must not drop more than 5 percent below the voltage rating of the motor while the motor is operating at 115 percent of the full-load current rating of the motor.

Cmil = [(1.732 x K x I x D)/VD]

K = 12.9 ohms, copper

I = 86A (74.8A at 115%), Table 430.250

D = 175 ft

VD 5 % = 10.4V (208V x 5%)

Cmil = (1.732 x 12.9 ohms x 86A x 175 ft)/10.4V

Cmil = 32,332

Chapter 9, Table 8 = 4 AWG

For voltage drop, the 4 AWG wire is OK from the controller to the motor, but 695.6(C)(2) requires the branch-circuit conductors to be sized not smaller than 3 AWG (Figure 695-4).

Applying Article 695 means you will sometimes have to “think backwards.” Normally, protecting conductors from overload is a key part of protecting people and property. But shutting down a fire pump during a fire is not a good idea.

A review of NFPA 20: Standard for the Installation of Stationary Fire Pumps will help you apply Article 695. The easiest way to avoid confusion is to remember why that fire pump motor is there. And when you do that, you’ll remember it needs to run no matter what.

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Comments
  • Mike,

    You forgot to include the impedance of the supply transformer in your voltage drop calculations. If a supply transformer is 5.4% impedance ( typical for a dry transformer and silicone filled indoor industrial substation transformers ) the transformer needs to be sized at at least 200% of the sum of the fire pump and accessories plus additional capacity for any other loads.

    Most of the impedance of a transformer is inductive which means that the voltage drop across the transformer is very high when motors are starting because during the starting period the power factor of the motor is very low. For high power factor loads a 5.4% impedance transformer would be very small around 1.25% to 2%. In this case the inductive portion of the impedance produces a phase shift in the voltage rather than a drop in voltage magnitude. The resistive voltage drop of a transformer needs to be more like 1% in order for the transformer to be efficient.

    Also be careful of older water mains that have iron bacteria clumps inside. Most iron ore deposits were laid down by giant iron bacteria colonies. This means that the fire pump could be called upon to act as a grinder necessitating 200% conductors in accordance with table 430.22(E). Under these circumstances an oversize motor would not be a bad idea much like how with rock crushers the average load on a 60 HP motor is more like 30 HP.

    Mike Cole, mc5w at earthlink dot net

    Michael R. Cole
    Reply to this comment

  • The theory of "continue to run when everything else fails" makes sense to me in this instance. But I wonder why most UL listed fire control cabinets that I have installed are constructed like a normal motor control cabinet with fuses sized per article 430.

    We obviously perform our installation per 695 but it seems to defeat the purpose to have a 200 amp OCPD (for example) feed a controller with a 30 amp fuse.

    Rich Bardwell
    Reply to this comment

  • Hai how are you teams members I need some electrical book how i am bring( i am studied (ele-ITI) I need some extra nalage please give me ideas thank you by james(india)

    james
    Reply to this comment
  • Reply from: axionnaitaste   
    Nedujieod. http://cieodjuf.he
    Reply to axionnaitaste


  • Mike, I have a request to change the designed MI cable fire pump feeders, which run from the service (with overcurrent protection) through the building to the fire pump controller/room, to RHH conductors installed in EMT. The cut sheet shows the RHH with conduit as a UL Classified two-hour rated cable when used in conduit. Has anyone run across this and does this meet the requirement of NEC 695-6 (b)? Lynn Palmer

    Lynn Palmer
    Reply to this comment

  • I was told by a pump service person that any equipment inside the starter cabinet that was not part of the original build would be cause for the insurance company not to pay out if a fire occurred and the fire pumps did not come on.... In my case I have power factor correction capacitors inside the control cabinet.....is this a problem? I might add that this person did not know what a capacitor was.

    Gary Burton
    Reply to this comment

  • Mike, I would like to address the comment you made that the conductors be required to carry locked rotor current of the fire pump motor (in your test question). In the answer you used 404 amps (locked rotor current per table 430.251(B)). For sizing conductors per 695.6(C)(1), the conductors shall have a rating not less than 125% of the sum of the fire pump motors....... and 100% of associated equipment. The way I am reading this code section, I should be able to use table 430.250 which gives me a current of 74.8 amnps for a 25hp, 208v motor. If I multiply this by the 125% as required by 695.6(C)(2) for a single motor, wouldn't I use 93.5 amps in the VD equation? The way I am reading this article, the OCPD is required to carry the locked rotor current, but the conductors are required to carry 125% of full load current. Am I reading this article wrong???? Thanks for straightening me out if I am, Mike.

    Respectfully, Gary Lile, Chief Electrical Inspector, City of Gresham, OR

    Gary Lile
    Reply to this comment


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