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Voltage sags & power-quality events — IEEE 1159, ITIC, SARFI

Sag = 0.1-0.9 pu for 0.5 cyc to 1 min (IEEE 1159) — 80-90% of PQ complaints. ITIC/CBEMA ride-through envelope: 0% @ 0.5 cyc → 70% @ 30 cyc → 90% steady. SARFI-X (IEEE 1564) counts events below threshold. Causes: remote faults (60-80%), motor start (5-7× FLC), transformer inrush (8-10×). Mitigation: equipment-RT → CVT → UPS → DVR → SSTS → active-front-end VFD. Flicker (IEEE 1453) Pst/Plt.

Senior ~13 min

Step 1 — Voltage sags: the #1 power-quality complaint

Animation speed 0.55×

event — V_remain — duration —

Reference notes

Voltage sags are the single most common power-quality disturbance in industrial and commercial plants — roughly 80-90% of all PQ complaints. IEEE 1159 defines the taxonomy of PQ events; the ITIC / CBEMA curve defines the equipment ride-through envelope; IEEE 1564 defines SARFI metrics for site sag-frequency characterization.

IEEE 1159 — power-quality event categories

Category	Duration	Magnitude / description
Transient — impulsive	µs	Lightning, ESD, switching surges. 10-20 pu peak.
Transient — oscillatory	µs - ms	Capacitor-bank energization, resonance.
Sag / dip	0.5 cyc - 1 min	0.1 - 0.9 pu — remote fault, motor start, transformer inrush.
Swell	0.5 cyc - 1 min	1.1 - 1.8 pu — LG fault elevates unfaulted phases.
Interruption	0.5 cyc - 1 min	< 0.1 pu — feeder lockout, breaker open.
Long-duration variation	> 1 min	Sustained over/undervoltage; outage > 1 min.
Voltage imbalance	steady	Asymmetric 3-phase voltage magnitudes.
Waveform distortion	steady	Harmonics, notching, DC offset — see IEEE 519.
Voltage fluctuation	sec	Flicker — IEEE 1453 Pst (10 min) and Plt (2 hr) indices.
Power-frequency variation	sec	Frequency deviation from 60 Hz.

Voltage sag definition (IEEE 1159)

RMS voltage 0.1 to 0.9 pu of nominal, duration 0.5 cycle to 1 minute.
Below 0.1 pu → INTERRUPTION (not a sag).
Above 0.9 pu → not classified as a PQ event.
Characterized by two parameters: magnitude (remaining V in pu) and duration (cycles / ms).
IEC term: voltage DIP (functionally identical to IEEE sag).

ITIC / CBEMA curve — equipment ride-through envelope

Plots magnitude (% of nominal, vertical) vs duration (log scale, 1 μs — microseconds, where μ is the Greek letter mu — to 10+ s, horizontal).
Successor of the CBEMA (Computer and Business Equipment Manufacturers Association) curve.
Maintained by ITI (Information Technology Industry Council).
Upper envelope (overvoltage tolerance): 200% at 1 µs → 140% at 3 ms → 120% steady.
Lower envelope (undervoltage tolerance): 0% at 0.5 cycle → 70% at 30 cycles (500 ms) → 80% at 10 s → 90% indefinitely.
Event INSIDE the envelope → expected to ride through. Event OUTSIDE → expected to trip.
Tighter variants:
- SEMI F47 — semiconductor fabs require ride-through ≤ 50% for 200 ms.
- IEEE 1668 — adjustable-speed drive ride-through.
Typical industrial site: 20-50 sags/year plot OUTSIDE the lower envelope.

Causes of voltage sags

Remote transmission/distribution faults — 60-80% of events. LG fault on a transmission line up to 100 miles away depresses voltage at your facility for the fault-clearing duration:
- Zone-1 distance protection clears in 1-3 cycles.
- Zone-2 backup in ~30 cycles (500 ms).
- Time-overcurrent backup in seconds.
Motor starting — large induction motors at start draw 5-7× FLC, depressing voltage at the motor bus and nearby loads during acceleration (seconds).
Transformer energization — inrush current 8-10× FLC for several cycles, especially severe for unloaded transformers.
Capacitor-bank switching — oscillatory transient (not a pure sag), may cause voltage notches and harm sensitive electronics.
Lightning — transients + may trigger faults that subsequently sag during clearing.

SARFI metrics (IEEE 1564) — site sag-frequency characterization

SARFI-X = System Average RMS Frequency Index = count of voltage events with remaining V < X% of nominal over a defined period (typically one year).
SARFI-90 counts all sags (broadest measure).
SARFI-70 counts moderately severe events.
SARFI-50 counts severe events likely to trip somewhat-tolerant equipment.
Typical industrial site benchmark:
- SARFI-90 ≈ 20-50 / year.
- SARFI-70 ≈ 5-15 / year.
- SARFI-50 ≈ 1-5 / year.
Utility tariffs sometimes guarantee SARFI levels contractually with rebates for exceedance.
Modern PQ monitors (Power Electronics, Schneider, Eaton, Schweitzer Engineering Laboratories) log every event and auto-compute monthly/annual SARFI indices.

Voltage swells, interruptions, transients

Swells: 1.1-1.8 pu overvoltage, 0.5 cycle to 1 min. Common cause: LG fault on one phase elevates the unfaulted phases (especially on Yo-grounded systems). Can damage MOVs and surge arresters.
Interruptions: < 0.1 pu, 0.5 cycle to 1 min. Caused by feeder lockout, breaker opening, brief loss of supply. Beyond 1 min → classified as outage (long-duration).
Impulsive transients: µs duration; lightning, ESD, switching surges. Peak magnitudes 10-20 pu. Mitigated by surge arresters (MOV / gapped) and BIL coordination (see L17 insulation-coordination-bil).
Oscillatory transients: µs-ms; capacitor-bank energization causing damped oscillation at the L-C resonance frequency. Can excite harmonic resonance (see L19 harmonics-ieee-519).

Flicker — IEEE 1453

Voltage fluctuations at 0.5-25 Hz cause perceptible variation in incandescent lamp brightness — annoying to occupants.
Pst (short-term flicker severity, 10-minute interval) — statistical perceptibility measure weighted by an eye-and-brain model. Pst = 1 is the threshold of irritation for a typical observer.
Plt (long-term, 2-hour interval) — cube-root of mean cube of twelve consecutive Pst values.
Typical utility limits at PCC: Pst ≤ 1, Plt ≤ 0.8.
Worst flicker sources: arc furnaces (modulating kV at ~1-25 Hz — peak human-perceptibility band). Modern variable-speed drives can also contribute.
Mitigation: SVC or STATCOM for reactive-power swing damping (see L18 facts-devices).

Mitigation hierarchy

Strategy	Cost	Coverage
Equipment ride-through retrofit (extended DC-link cap)	$	Affected equipment only
CVT (Constant-Voltage / Ferroresonant Transformer)	$	Small sensitive load — handles 50-130% input
Online (double-conversion) UPS	$$	Continuous, IT/critical electronics
DVR (Dynamic Voltage Restorer) — series VSC injection	$$$ ($100-300/kVA)	Whole feeder, 60-80% of sag events
SSTS (Static Source Transfer Switch)	$$$$	Whole bus — requires two independent feeders
Active-front-end VFD (PWM rectifier input)	$$ (30-50% drive cost premium)	Drive itself rides through to ~50% V
Utility coordination — faster fault clearing, single-pole tripping	variable	Reduces sag duration / depth

Economics

Single 30-cycle sag at a semiconductor fab: $100,000 - $1,000,000 in lost product / cycle time.
DVR for one critical feeder: ~$200,000 one-time.
Two avoided events per year typically pays back DVR investment.
Continuous-process plants (chemical, paper, glass) target SARFI-50 < 5 per year through combination of upstream coordination + on-site mitigation.

Take-away. Voltage sag = 0.1-0.9 pu remaining voltage for 0.5 cyc to 1 min (IEEE 1159); 80-90% of PQ complaints. Plot magnitude vs duration on the ITIC curve to assess ride-through. Lower envelope: 0% at 0.5 cyc → 70% at 30 cyc (500 ms) → 90% indefinitely. SARFI-X (IEEE 1564) counts events below threshold X; typical industrial SARFI-70 ≈ 5-15/yr. Primary causes: remote faults (60-80%), motor start (5-7×), transformer inrush (8-10×). Mitigation in cost order: equipment ride-through → CVT → UPS → DVR → SSTS → active-front-end VFD → utility coordination. Flicker (IEEE 1453) measured by Pst/Plt; arc furnaces are the worst source.