Breaker Load Calculator

Breaker Load Calculator

Convert watts or VA into breaker amps, apply the 125% continuous-load rule, account for demand factor, select the next standard breaker, and compare the result against installed breaker headroom.

1Breaker load presets
2Load inputs
Breaker amps use VA / V for single phase or VA / (1.732 x V) for three phase.
Breaker or overcurrent device rating to compare against the calculated load.
Use real power watts when that is the best nameplate value available.
If VA is listed, the calculator uses the larger of entered VA and watts / PF.
Watts convert to apparent power as VA = W / power factor.
Loads expected for 3 hours or more are multiplied by 125%.
Use 100% unless a valid load method supports a lower demand factor.
Planning reserve kept unused on the installed breaker after adjusted load.
Check the inputs. Breaker rating must be positive, power factor must be 0.35 to 1.00, demand must be 25% to 100%, and at least one load value must be entered.
3Live load notes
Input statusEnter watts or VA to calculate apparent power, adjusted amps, breaker size, and spare capacity.
Breaker load estimate ready The adjusted load is checked against the entered breaker, the next standard breaker size, and the target spare headroom.
Adjusted load 0.0 A after 125% and demand factor
Demand VA 0.0 kVA apparent power basis
Breaker size 0 A next standard size
Headroom 0.0 A spare on installed breaker
4Breaker/load spec grid
5Breaker sizing reference tables
Standard breaker sizes used for rounding
RangeCommon standard sizesCalculator usePlanning note
Small branch circuits15, 20, 25, 30 ARounds up adjusted ampsUse the next size only when conductor and equipment ratings allow it
Appliance and feeder circuits35, 40, 45, 50, 60 AUsed for midrange loadsContinuous loads can push a circuit into the next breaker size quickly
Large residential loads70, 80, 90, 100, 110, 125 AUsed for EV, shop, and subfeed examplesCompare breaker rating against panel, disconnect, and feeder limits
Service and equipment feeders150, 175, 200, 225, 250 AUpper planning rangeDetailed code load calculations may supersede a simple load schedule
Voltage and amperage formulas
SystemFormulaTypical useExample result
120 V single phaseAmps = VA / 120Lighting, receptacles, controls, racks1,800 VA = 15.0 A
240 V single phaseAmps = VA / 240Heaters, EVSE, pumps, split systems9,600 VA = 40.0 A
208 V three phaseAmps = VA / (1.732 x 208)Balanced shop or commercial equipment12 kVA = 33.3 A
480 V three phaseAmps = VA / (1.732 x 480)Larger equipment feeders25 kVA = 30.1 A
Continuous and demand treatment
Load typeVA basisMultiplierCalculator treatment
Continuous lighting or rack loadWatts / PF or listed VA125%Continuous VA is multiplied by 1.25 before amp calculation
Noncontinuous appliance loadNameplate VADemand factorNoncontinuous VA is multiplied by the entered demand percent
Mixed branch circuitLargest of watts/PF and VASplit by shareContinuous share gets 125%, remaining VA gets demand factor
Planning reserveBreaker ratingReserve percentTarget capacity equals breaker amps x (1 - reserve percent)
Common breaker load scenarios
ScenarioInput loadAdjusted loadBreaker cue
Smart home rack1,250 W at 0.92 PF, 100% continuous1.70 kVA, 14.2 A at 120 V20 A breaker keeps about 5.8 A spare
EV charging load9,600 W at 1.00 PF, 100% continuous12.0 kVA, 50.0 A at 240 V50 A minimum, larger only if equipment allows
Workshop tools5,500 W at 0.88 PF, 20% continuous5.63 kVA, 23.5 A at 240 V30 A standard size before reserve check
Three phase shop12 kVA, 35% continuous, 75% demand10.95 kVA, 30.4 A at 208 V35 A standard size, compare to installed breaker
6Breaker load tips
Watts versus VA tip

Use listed VA when a load nameplate gives it. If only watts are available, the calculator divides watts by power factor so low-PF motors, drivers, or power supplies are not understated.

Continuous-load tip

Keep loads expected to run for three hours or longer in the continuous share. The calculator applies the 125% multiplier only to that portion, then adds demanded noncontinuous VA.

When determining the loads that a circuit can take, it is important to ensure that the circuit can handle the amount of electricity that will be used during actual use of the circuit. The number of devices that youre going to connect to the circuit are not necessarily a factor in determining the size of the breaker that is to be used on that circuit. The first step in determining the size of the breaker that are to be used on a circuit is to determine the difference between real power and an apparent power.

Real power, which are measured in watts, is the amount of power that the devices that are connected to the circuit actualy use. Apparent power, which is measured in volt-amps (VA), is the total amount of power that the circuit draws. Many devices, such as motors, electronics, and LED lights, do not have the same amount of real power then apparent power.

How to Size a Circuit Breaker

In these instances, the power factor is used to even out the differences between the two types of power. If the factor is low, more current will travel through the circuit to the devices, which could result in the circuit or breaker overheating. The second step in breaker sizing is to determine the difference between continuous and noncontinuous loads.

A continuous load are a load that is to be continuously operated for three hours or more. Continuous loads require the use of 125% multiplier to ensure that the heat building up from the continuous use of the load does not damage the wires leading to the devices or the breaker. Noncontinuous loads are those that do not continuously operate for three hours or more.

These types of loads do not need to use a 125% multiplier, since they do not build up as much heat before switching off to the devices. Using a 125% multiplier to continuous loads insures that the electrical components dont overheat. The third step in determining the size of the breaker for a circuit is to determine the demand factor.

The demand factor is a percentage that accounts for not all the devices drawing there full power at the same time. For instance, in a workshop, the saw, the dust collector, and the work lights may not all be running at the same time. If there is no demand factor applied to the circuit, the breaker will be sized for the electrical load that could theoretically exist on the circuit.

However, if the demand factor is too low, the breaker will continually trip due to the devices drawing the power that they requires to perform their jobs. To adjust the percentage according to the actual behavior of the electrical equipment
The fourth step involve choosing the size of the standard circuit breaker. The calculated value of the load in amps must be less than the standard value of the circuit breaker.

This is because manufacturers and inspectors of the electrical equipment make the standard circuit breakers. These manufacturers makes circuit breakers in specific amperage values. Furthermore, there must also be some spare capacity on the existing circuit breaker to allow for new electrical equipment to be added in the future.

Additionally, there should be some spare capacity for voltage drops on long wire runs. In selecting the size of the circuit breaker, there is also an 80 percent rule. This indicates that a 20 amp circuit breaker will only carry 16 amps of current.

The same 80 percent rule is applied to circuit breakers as the 125 percent rule for continuous loads. Operating a circuit breaker beyond this limit for many hours will reduce both the life of the circuit breaker and the electrical wires. The voltage of the system will also have an effect on the amperage calculation.

For three-phase power, the load is distributed among three separate circuits. Therefore, three-phase power will require fewer amps than single-phase power for the same value of volt amps. For instance, a value of volt amps at 208 volts for three-phase power will require fewer amps than the same value of volt amps at 120 volts for single-phase power.

The voltage of the circuit will determine the amperage that will flow through the wires. Finally, there are some common mistake when reading the data on the nameplate. For some electrical devices, only the wattage is listed.

For these devices, assuming a power factor of one will lead to incorrect calculations of the number of amps that will flow through the device. Additionally, for some devices the value of volt amps is listed, but the nameplate does not state if that value include the starting surge of the device. In this case, the higher of the two numbers should of been entered into the calculation.

Lastly, the continuous load multiplier and the demand factor should be applied separately. Multiplying these two factors together will lead to an incorrect result.

Breaker Load Calculator

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