This is the second part of a two-part series on the methodologies used to find the short circuit current duties of circuit breakers and fuses. The first part, Short Circuit Current Duties of Circuit Breakers and Fuses — Part 1,which ran last month in the July issue of EC&M, provided the necessary background and illustrated the ANSI methodologies to determine the short circuit current duties of ANSI-rated medium-voltage circuit breakers and fuses. This part follows the same process steps but focuses on low-voltage circuit breakers and fuses. It should be noted that other ratings and application considerations beyond the scope of this article must be considered for the proper selection of low-voltage circuit breakers and fuses. Specifically, the reader is directed to the IEEE Blue Book (IEEE Std 1015-2006), Chapters 5 and 7 of the IEEE Buff Book (IEEE Std 242-2001), and the latest edition of the National Electrical Code (NFPA 70) for comprehensive coverage of this topic.

As discussed in Part 1, the interrupting ratings of low-voltage circuit breakers and fuses are classified on a symmetrical-current-rated basis. In this context, “symmetrical-current-rated” implies that a multiplying factor (MF) to account for the DC component of the short circuit current waveform is unnecessary to adjust the calculated first-cycle symmetrical RMS short circuit current whenever the short circuit X/R ratio is less than or equal to some limit, because a certain degree of asymmetry is built into the rating structure. However, if the short circuit X/R ratio exceeds the limit, a larger than tested DC component may exceed the built-in asymmetry allowance; and the first-cycle symmetrical RMS current must be multiplied by an appropriate MF before comparison with the interrupting ratings (i.e., 3-phase short circuit current ratings) in a manufacturer’s table. Listed below are the short circuit X/R ratio limit and the formula to calculate the MF (in the event that the short circuit X/R ratio exceeds the limit) for several categories of low-voltage circuit breakers and fuses.

## Unfused Low-Voltage Power Circuit Breakers

First-cycle duty of unfused low-voltage power circuit breaker = MF × first-cycle symmetrical RMS current

MF = 1.0 is applicable whenever the first-cycle short-circuit X/R ratio at the fault point (i.e., source side of breaker) is 6.6 or less. If the first-cycle short-circuit X/R ratio is greater than 6.6, the following formula from IEEE Std C37.13-2008 can be used to find the MF.

The 3-phase rated short circuit current in RMS kA must exceed the first-cycle duty in asymmetrical RMS kA.

*Note***:** On 3-phase systems where the voltage across a single pole under a fault condition may exceed 58% of the rated maximum voltage (e.g., corner-grounded delta under single line to ground fault), the single-pole interrupting capability shall be 87% of the 3-phase rated short circuit current.

## Fused Low-Voltage Power Circuit Breakers

First-cycle duty of fused low-voltage power circuit breaker = MF × first-cycle symmetrical RMS current

MF = 1.0 is applicable whenever the first-cycle short circuit X/R ratio at the fault point (i.e., source side of breaker) is 4.9 or less. If the first-cycle short circuit X/R ratio is greater than 4.9, the following formula from IEEE Std C37.13-2008 can be used to find the MF.

The 3-phase rated short circuit current in RMS kA must exceed the first-cycle duty in asymmetrical RMS kA.

*Note***:** On 3-phase systems where the voltage across a single pole under a fault condition may exceed 58% of the rated maximum voltage (e.g., corner-grounded delta under single line to ground fault), the single-pole interrupting capability shall be 87% of the 3-phase rated short circuit current.

## Molded- and Insulated-Case Circuit Breakers

First-cycle duty of molded- or insulated-case breaker = MF × first-cycle symmetrical RMS current

**Interrupting ratings 10,000A symmetrical or less:**

MF = 1.0 is applicable whenever the first-cycle short circuit X/R ratio at the fault point (i.e., source side of breaker) is less than 1.7. If the first-cycle short circuit X/R ratio is greater than 1.7, the following formula can be used to find the MF.

**Interrupting Ratings between 10,001A and 20,000A symmetrical:**

MF = 1.0 is applicable whenever the first-cycle short circuit X/R ratio at the fault point (i.e., source side of breaker) is less than 3.2. If the first-cycle short circuit X/R ratio is greater than 3.2, the following formula can be used to find the MF.

**Interrupting ratings exceeding 20,000A symmetrical:**

MF = 1.0 is applicable whenever the first-cycle short circuit X/R ratio at the fault point (i.e. source side of breaker) is less than 4.9. If the first-cycle short circuit X/R ratio is greater than 4.9, the following formula can be used to find the MF.

The 3-phase rated short circuit current in RMS kA must exceed the first-cycle duty in asymmetrical RMS kA.

*Note***: **On 3-phase systems where the voltage across a single pole under a fault condition may exceed 58% of the rated maximum voltage (e.g., corner-grounded delta under single line to ground fault), the single-pole interrupting capability shall be 87% of the 3-phase rated short circuit current.

## Low-Voltage Fuses

First-cycle duty of low-voltage fuse = MF × first-cycle symmetrical RMS current

MF = 1.0 is applicable whenever the first-cycle short circuit X/R ratio at the fault point (i.e., source side of breaker) is 4.9 or less. If the first-cycle short circuit X/R ratio is greater than 4.9, the following formula from IEEE Std C37.13-2008 can be used to find the MF.

The interrupting rating in RMS kA must exceed the first-cycle duty in asymmetrical RMS kA.

*Note***:** The marked interrupting rating of a fuse is the tested single-pole interrupting rating, so derating to assess single-pole interrupting capability does not apply to fuses.

**Example:**

Let’s put numbers to the formulas above by considering the example from Part 1 of this series for which the first-cycle symmetrical RMS current and short circuit X/R ratio for a 3-phase fault at low-voltage Bus 3 are 23.910kA and 7.0, respectively.

First-cycle duty of Bus 3 unfused low-voltage power circuit breaker = MF × Bus 3 first-cycle (momentary) symmetrical RMS current = 1.012 × 23.910kA = 24.197kA (asymmetrical RMS)

First-cycle duty of Bus 3 molded- or insulated-case breaker = MF × Bus 3 first-cycle (momentary) symmetrical RMS current = 1.073 × 23.910kA = 25.655kA (asymmetrical RMS)

First-cycle duty of Bus 3 low-voltage fuse = MF × Bus 3 first-cycle (momentary) symmetrical RMS current = 1.078 × 23.910kA = 25.775kA (asymmetrical RMS)

*Mercede, P.E., is principal of Mercede Engineering LLC, based in Bryn Mawr, Pa. He can be reached at fmercede@mercedeengineering.com.*