Transformer Sizing Calculator for Washington
NEC 2020 transformer sizing math for EV charger installers working in Washington.
DCFC and large workplace EV deployments in Washington typically need a dedicated 480 V three-phase service, which means sizing a pad-mount or dry-type transformer against the connected charger load plus the NEC 2020 continuous-load multiplier.
Worked example for Washington
A 350 kW DC fast charger draws roughly 421 A at 480 V three-phase. Applying the 125% continuous-load factor (350 × 1.25 ≈ 438 kVA), then rounding up to the next standard transformer rating gives a 450 kVA minimum. Washington's 87°F summer ambient does not directly derate the transformer, but it does push the secondary feeder ampacity down by 0.88× — so the secondary copper has to be sized accordingly.
Code & Utilities
The applicable code in Washington is the NEC 2020, which the state adopted in 2023. That includes Article 625 (Electric Vehicle Power Transfer System) requirements: 125% continuous-load sizing on EVSE branch circuits, GFCI protection at outdoor receptacles, and provisions for energy management systems on shared circuits.
Washington's primary EV-relevant utilities are Puget Sound Energy, Seattle City Light, Avista Utilities, Snohomish PUD. Always verify the applicable tariff and any utility-specific requirements (CT cabinets, metering enclosures, demand limiters) at design time.
Climate & Ampacity
Plan EV feeders against a 87°F ambient in Washington — the resulting NEC 310.15(B) correction of 0.88× is what trims a #6 THWN-2 down to its true continuous rating. Because the correction is below 0.9, conductors that "look fine" on a 30°C ampacity table will not carry their nameplate current here — always derate explicitly.
Washington takeaway
Coordinate primary-side voltage, impedance, and fault-current specs with Puget Sound Energy early — interconnection lead times for new pad-mounts in Washington can run 6-12 months on commercial DCFC sites.