What IEEE 519 actually requires
IEEE 519 sets limits on harmonic current that a customer can inject into the utility's grid at the point of common coupling. The 2022 revision tightened a few definitions and introduced clearer enforcement language, but the structure is unchanged: pick a row in Table 2 by the short-circuit ratio Isc/IL, then compare your installation's total demand distortion (TDD) against the row's limit. The result is a pass/fail, and non-compliance gives the utility a basis to require filters or refuse interconnection.
UPS rectifiers as the dominant source
For a typical commercial install, the UPS rectifier is the single largest source of harmonic current — VFDs run a close second. A 6-pulse SCR rectifier with no filter is the worst case at ~30% THDi; a passive 5th/7th harmonic filter cuts that to ~10%; a 12-pulse rectifier holds the same ~10% without a filter. IGBT (AFE) rectifiers stay below 5% — usually under 3% in practice. The right architecture for the load is the cheapest way to comply.
Why this is a quick check, not a final report
A formal IEEE 519 study models the full upstream impedance, all non-linear loads on the same bus, and the cumulative effect across harmonic orders. This calculator approximates with a single-load assumption: the UPS dominates the PCC. That holds for small-to-medium commercial installs where the UPS is the largest non-linear load. For data centres with multiple UPS rectifiers, VFDs, or LED drivers contributing, commission a full study.
Strengthening a weak PCC
If the verdict is "Fail" and the rectifier upgrade isn't economical, the alternative is to strengthen the PCC: a larger transformer, a higher-voltage primary, or moving the PCC closer to the utility's strong bus. Each option drops the source impedance and increases Isc/IL, which both directly increases the TDD allowance and indirectly reduces the actual harmonic-current draw.