How does this calculator convert from kVA to kW?

The calculator uses the standard relationship between apparent power S in kVA and active power P in kW: P (kW) = S (kVA) × power factor (cos φ). You enter the apparent power and a power factor (either a preset or a custom value), and the tool multiplies them to obtain the active power in kilowatts.

Can this calculator also convert from kW to kVA?

Yes. In the Advanced options panel you can change the conversion direction to kW → kVA. In that mode, you enter the active power in kW and the power factor. The calculator applies the inverse formula S (kVA) = P (kW) / cos φ to obtain the apparent power.

What power factor should I select if I do not know the exact value?

If the power factor is not indicated on the equipment nameplate, a common engineering approximation for induction motor and mixed industrial loads is 0.8. For installations with power factor correction capacitors, values around 0.9 to 0.95 are typical. Always prefer measured or specified power factor values whenever they are available.

Why does the calculator ask for phase type and voltage if they are not for kVA to kW conversion?

Phase type (single-phase or three-phase) and line voltage are not needed to convert between kVA and kW, but they are used to estimate the line current drawn by the load. Once the apparent power in kVA is known, the calculator can estimate current using I = S × 1000 / (√3 × U) for three-phase systems or I = S × 1000 / U for single-phase systems, which is useful for cable sizing and protection coordination.

Convert kVA to kW (with Power Factor) — Free Instant Calculator & Examples

This technical article explains converting kVA to kW accurately with power factor considerations and examples.

Includes instant calculator logic, formulas, normative references, practical cases, and step-by-step engineering calculations for industry.

kVA to kW Conversion with Power Factor – Professional Instant Calculator

Apparent power (kVA)

Power factor (cos φ)

Custom power factor (cos φ, 0–1)

Advanced options

Conversion direction

System phase type

Line voltage (V)

Upload a nameplate or single-line diagram photo to suggest reasonable input values.

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Enter apparent power and power factor to obtain active power in kW.

Formulas used (SI units):

Active power in kilowatts: P (kW) = S (kVA) × cos φ
Apparent power in kilovolt-amperes: S (kVA) = P (kW) / cos φ
Three-phase line current (if voltage is provided): I (A) ≈ S (kVA) × 1000 / (√3 × U_L-L (V))
Single-phase current (if voltage is provided): I (A) ≈ S (kVA) × 1000 / U (V)

Quick reference – typical power factors:

Power factor (cos φ)	Typical load example	Comment
1.00	Pure resistive heaters, incandescent lamps	No reactive power, S ≈ P
0.95–0.98	Well-corrected industrial installations	High power factor with capacitor banks
0.85–0.90	Modern motors with partial correction	Common design target for plants
0.75–0.80	Older induction motors, mixed loads	Typical default for many nameplate calculations
0.6–0.7	Lightly loaded motors, fluorescent lighting without correction	Poor power factor, higher current for same kW

Technical FAQ – kVA to kW with power factor

Why do I need the power factor to convert from kVA to kW?: Apparent power (kVA) represents the vector sum of active and reactive power. Only active power (kW) performs useful work. The ratio P/S is the power factor (cos φ). Without cos φ, the relationship between kVA and kW is unknown.
What power factor should I use if I only have the kVA rating?: When the exact power factor is not specified, 0.8 is a common assumption for general industrial induction motor loads. For well-corrected systems, 0.9 or higher may be appropriate. Always prefer the actual nameplate or measurement when available.
Does this calculator distinguish between lagging and leading power factor?: The magnitude of the power factor (absolute value of cos φ) is sufficient for kVA to kW conversion, because the sign (lagging or leading) affects reactive power direction but not the active power magnitude.
Why does the estimated current depend on phase type and voltage?: For a given apparent power, the current is inversely proportional to the system voltage and depends on whether the system is single-phase or three-phase. Three-phase systems share power across three conductors, which reduces the current per phase for the same kVA compared with a single-phase system.

Fundamental definitions and power relationships

Understanding apparent, real, and reactive power is essential before converting kVA to kW.

Use consistent SI units: kW (kilowatts) for real power, kVA (kilovolt-amperes) for apparent power.

Convert Kva To Kw With Power Factor Free Instant Calculator Examples guide

Core power quantities and relationships

Real power (P), apparent power (S), and reactive power (Q) are related by the power triangle. Key formulas:

S = √(P² + Q²)

P = S × PF

Q = √(S² − P²)

Explain variables and typical values:

P (real power): measured in kW. Typical values: 1 kW (small motor), 100 kW (commercial loads), 1000 kW+ (large plants).
S (apparent power): measured in kVA. Typical values: generator and transformer ratings: 10 kVA, 50 kVA, 250 kVA, 1000 kVA.
Q (reactive power): measured in kVAR. Typical values: depends on inductive/capacitive loads; large motors can be tens to hundreds of kVAR.
PF (power factor): dimensionless (cos φ). Typical industrial values: 0.6 to 0.95, target near 0.95–1.0 after correction.

Mathematical conversion: kVA to kW with power factor

The direct conversion is trivial when PF is known: multiply apparent power by PF.

Primary conversion formula:

kW = kVA × PF

Alternate notation using uppercase P and S:

P (kW) = S (kVA) × PF

Variable explanations with typical example values:

S (kVA): e.g., 100 kVA, 250 kVA, 500 kVA.
PF: e.g., 0.8 (uncompensated industrial), 0.9 (improved), 1.0 (purely resistive).
P (kW): result, e.g., for S = 100 kVA and PF = 0.85 → P = 85 kW.

Practical notes on units and conversion

Ensure kVA and kW use the same base (kilo). If power is in VA or W, convert by dividing/multiplying by 1000.
Power factor must be the decimal fraction (0–1). Do not input percentage without conversion (e.g., 90% → 0.9).
For three-phase systems, the kVA rating is already system apparent power. Use the same conversion formula.

kVA	PF 0.60	PF 0.70	PF 0.80	PF 0.85	PF 0.90	PF 0.95	PF 1.00
10	6.0 kW	7.0 kW	8.0 kW	8.5 kW	9.0 kW	9.5 kW	10.0 kW
25	15.0 kW	17.5 kW	20.0 kW	21.25 kW	22.5 kW	23.75 kW	25.0 kW
50	30.0 kW	35.0 kW	40.0 kW	42.5 kW	45.0 kW	47.5 kW	50.0 kW
100	60.0 kW	70.0 kW	80.0 kW	85.0 kW	90.0 kW	95.0 kW	100.0 kW
250	150.0 kW	175.0 kW	200.0 kW	212.5 kW	225.0 kW	237.5 kW	250.0 kW
500	300.0 kW	350.0 kW	400.0 kW	425.0 kW	450.0 kW	475.0 kW	500.0 kW
1000	600.0 kW	700.0 kW	800.0 kW	850.0 kW	900.0 kW	950.0 kW	1000.0 kW

Single-phase and three-phase current relationships

When designing systems, convert kVA (or kW) into line current for conductor selection and protection.

Formulas for current

Single-phase current (I1):

I1 = (kVA × 1000) / V

Three-phase line current (I3):

I3 = (kVA × 1000) / (√3 × V)

Where variables mean:

I1, I3: current in amperes (A).
kVA: apparent power in kilovolt-amperes.
V: line-to-line voltage for three-phase or line voltage for single-phase (volts).
√3: approximate 1.732, accounts for three-phase system geometry.

kVA	230 V single-phase I (A)	400 V three-phase I (A)	480 V three-phase I (A)	600 V three-phase I (A)
10	43.5 A	14.4 A	12.0 A	9.6 A
25	108.7 A	36.0 A	30.3 A	24.0 A
50	217.4 A	72.1 A	60.6 A	48.1 A
100	434.8 A	144.3 A	121.2 A	96.2 A
250	1086.9 A	360.8 A	303.0 A	240.4 A
500	2173.9 A	721.7 A	606.1 A	480.8 A

Instant calculator logic and implementation notes

An instant conversion calculator must validate inputs and handle edge cases to be reliable for engineers.

Required input validation and handling

Accept numerical kVA value > 0. Reject or flag zero/negative entries.
Accept PF values in range 0.0–1.0 (or 0–100% and convert to decimal).
Deal with missing PF: provide defaults (e.g., 0.8 industrial, 1.0 resistive) and warn user.
Allow selection of system voltage and phase type to compute currents.
Provide rounding options (significant figures) and unit conversion toggles.

Algorithmic steps for a robust calculator

Read kVA input; convert to numeric kVA_value.
Read PF input; if PF is given as percentage, convert PF = percentage / 100.
Compute kW_value = kVA_value × PF.
If current requested: compute I_single = (kVA_value × 1000) / V for single-phase; compute I_three = (kVA_value × 1000) / (√3 × V) for three-phase.
Apply correction factors: generator efficiency, transformer losses, ambient derating if selected.
Return results with traceable units and formula references to the user.

Practical engineering considerations and corrections

Real installations require more than a simple multiplication; consider power factor correction, harmonics, and derating.

Power factor correction

Correcting PF increases usable kW without changing apparent capacity. Capacitor banks supply leading reactive current, reducing Q.

Before correction: P = S × PF_old.
After correction: P = S × PF_new. If PF improves, P increases for same S.
Sizing capacitors: required kVAR to move PF from PF_old to PF_new:

kVAR_required = kVA × (tan(arccos(PF_old)) − tan(arccos(PF_new)))

Variables and typical values:

PF_old: e.g., 0.75; PF_new target: e.g., 0.95.
kVAR_required: sized per bank, often installed at distribution panels.

Generator and transformer sizing

Manufacturers rate equipment in kVA, not kW, so converting informs usable real load and sizing margins.

Generators: specify both kVA and PF (commonly 0.8). A 500 kVA generator at PF 0.8 provides 400 kW continuous.
Transformers: rated in kVA; ensure kW load at target PF is ≤ transformer kVA rating.
Apply derating: altitude, temperature, harmonics, parallel operation change rated capability.

Real-world example 1: Industrial motor bank load—convert kVA to kW and size generator

Problem statement: An industrial facility has a total apparent load of 750 kVA with measured PF of 0.78. Engineer must determine usable kW and recommend generator size with 20% spare capacity.

Step-by-step solution:

Compute real power: kW = kVA × PF
Substitute values: kW = 750 × 0.78
Calculate: kW = 585.0 kW
Apply spare capacity (20%): Required generator kW = 585.0 × 1.20 = 702.0 kW
Convert required kVA at standard generator PF (typically 0.8): Required kVA = Required generator kW / PF_generator
Assume generator PF = 0.8: Required kVA = 702.0 / 0.8 = 877.5 kVA
Choose next standard generator size: 900 kVA or 1000 kVA depending on manufacturer availability and derating conditions.

Notes and verification:

If using a 900 kVA generator at PF 0.8, available kW = 900 × 0.8 = 720 kW, which exceeds the required 702 kW but has limited margin.
Consider derating for altitude/temperature and harmonics. If derating reduces kVA by 10%, choose 1000 kVA to maintain margin.

Real-world example 2: Data center UPS load conversion and current sizing

Problem statement: A UPS is rated 250 kVA and supplies critical servers. The load power factor is 0.9. Calculate kW supplied, three-phase current at 400 V, and recommend conductor current rating with 125% design margin.