Power Factor Calculator

Calculate power factor from real, reactive, and apparent power measurements. Size capacitor banks for power factor correction to avoid utility penalties (typically required to maintain PF > 0.9). Outputs required kVAR compensation and capacitor sizing. Essential for industrial facilities with large inductive loads (motors, transformers).

IEEE Std 141-1993IEC 61000-4-7IEEE Std 18-2012
Calculator Input
Enter your power system parameters to calculate power factor and get correction recommendations.
kW

Active power consumed by the load (0.1 - 100,000 kW)

kVAr

Reactive power (optional if S is provided)

kVA

Apparent power (optional if Q is provided)

System voltage level (for capacitor sizing)

System frequency (defaults to 60 Hz)

PF

Desired power factor for correction calculations (0.8 - 1.0)

Engineering Theory & Fundamentals
Understanding the engineering principles and standards behind this calculator

Power factor (PF) measures the efficiency of electrical power usage in AC systems—the ratio of real power (kW) that performs useful work to apparent power (kVA) supplied by the source. Understanding power factor is critical for reducing energy costs, sizing equipment correctly, and optimizing electrical system performance.

Key Concept: Power factor ranges from 0 to 1.0, where 1.0 (unity) means all supplied power performs useful work. Most industrial facilities operate at 0.70-0.90 PF, wasting 10-30% of electrical capacity. Improving PF from 0.80 to 0.95 typically reduces apparent power demand by 15-20%, directly impacting utility bills and system capacity.

Why Power Factor Matters: Utilities penalize PF below 0.90-0.95 through demand charges based on kVA rather than kW. Low PF increases current for the same real power, causing higher I²R losses, voltage drop, and requiring oversized equipment. A 500kW facility at 0.70 PF requires 714kVA capacity versus only 526kVA at 0.95 PF—a 36% infrastructure reduction.

Common Causes: Induction motors (PF 0.65-0.85), transformers at light load (PF 0.10-0.30), fluorescent lighting with magnetic ballasts (PF 0.50-0.70), welding equipment (PF 0.50-0.70), and VFDs without correction (PF 0.75-0.85) all contribute to poor power factor.

Correction Methods: Capacitor banks provide the most cost-effective solution, supplying reactive power locally to achieve target PF of 0.95-0.98. Automatic power factor controllers switch capacitor stages based on load. Active PFC in modern equipment shapes input current for near-unity PF.

Industry Standards: IEEE Std 141-1993 and IEC 61921 specify power factor requirements and correction methods for industrial facilities.

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Mathematical Formulas
Engineering equations with detailed explanations and unit references
13 formulas

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Referenced Standards & Guidelines

Calculations comply with the following authoritative sources

3 References

Usage Examples

Real-world scenarios showing how to use this calculator effectively