How Many Amps Is 2.2 kVA at 240V?
A 2.2 kVA single-phase load at 240V draws 9.17 amps. Three-phase configurations are not typical at this voltage. At a load power factor of 0.8 the load's real-power draw is 1.76 kW (a generator or UPS feeding this load has a separate kW rating set by the manufacturer which must be checked independently against the kVA rating).
Use this citation when referencing this page.
Assumes a single-phase AC circuit at the input voltage. kVA is apparent power, so no power factor term is involved.
Formulas
Single Phase
I(A) = (kVA × 1000) ÷ V
Three Phase (240V Line-to-Line)
I(A) = (kVA × 1000) ÷ (VL-L × √3)
Applies to 240V delta (uncommon, high-leg delta) systems where 240V is the line-to-line voltage.
Generator & UPS Sizing
Load-Side Real Power by Power Factor
A load with an apparent power of 2.2 kVA draws different amounts of real power depending on the load's own power factor. The table below is a load-side conversion, not a forecast of what a generator or UPS will output for that load: generators and UPS units publish their own independent kW rating set by the engine or inverter design, and that rating is often lower than kVA × the load's PF.
| Load Type | Load PF | Load Real Power (kW) | Current at 240V |
|---|---|---|---|
| Resistive (heaters, lights) | 1.0 | 2.2 kW | 9.17 A |
| Mixed typical | 0.85 | 1.87 kW | 9.17 A |
| Motors/HVAC | 0.80 | 1.76 kW | 9.17 A |
| Computers/servers (no PFC) | 0.65 | 1.43 kW | 9.17 A |
Note: current draw stays the same across the rows because kVA sets the current, not the load's power factor. PF only affects how much real work (kW) the load does per amp drawn.
Sizing a load against a source. If you are feeding this load from a UPS, generator, or transformer, check the load against both the source's kVA rating AND the source's kW rating. Those are two independent numbers published by the manufacturer. A 10 kVA / 8 kW generator, for example, can supply up to 10 kVA of apparent power AND up to 8 kW of real power, whichever limit is reached first. Do not use the kW figures above as a substitute for the source's published kW rating.
Circuit Sizing: Starting Points
The numbers below are rough order-of-magnitude starting points under typical assumptions (copper conductors, 75°C terminations, short run, no ambient or bundling derates, non-continuous duty). They are not install specs. Actual breaker and wire selection depends on the equipment nameplate, conductor and termination temperature ratings, cable type, run length and voltage-drop target, ambient and bundling conditions, whether the load is continuous, any NEC 430/440 motor or HVAC provisions, and local code.
| Single Phase | Three Phase | |
|---|---|---|
| Current draw (at full kVA) | 9.17 A | 5.29 A |
| Ballpark branch OCP | ~15A | ~15A |
For a real install, run the full wire-size calculator with your actual run length, voltage, and drop target, and verify breaker selection against the equipment nameplate and local code.
Energy Cost at Full Load
A load with an apparent power of 2.2 kVA at load PF 0.85 draws 1.87 kW of real power. Running cost at that draw: $0.32/hour at $0.17/kWh (rates last reviewed April 2026), or $76.30/month (8h/day). Full breakdown.
kW Equivalent
2.2 kVA at PF 0.85 = 1.87 kW. See 1.87 kW to amps at 240V.
Other kVA Ratings at 240V
| kVA | Single Phase Amps | Three Phase Amps (L-L, per line) | Real Power (PF 0.8) |
|---|---|---|---|
| 1 kVA | 4.17 A | 2.41 A | 0.8 kW |
| 2 kVA | 8.33 A | 4.81 A | 1.6 kW |
| 3 kVA | 12.5 A | 7.22 A | 2.4 kW |
| 5 kVA | 20.83 A | 12.03 A | 4 kW |
| 7.5 kVA | 31.25 A | 18.04 A | 6 kW |
| 10 kVA | 41.67 A | 24.06 A | 8 kW |
| 15 kVA | 62.5 A | 36.08 A | 12 kW |
| 20 kVA | 83.33 A | 48.11 A | 16 kW |
| 25 kVA | 104.17 A | 60.14 A | 20 kW |
| 30 kVA | 125 A | 72.17 A | 24 kW |
| 40 kVA | 166.67 A | 96.23 A | 32 kW |
| 50 kVA | 208.33 A | 120.28 A | 40 kW |