Static VAR Generator (SVG) Working Principle: Dynamic Reactive Power Compensation

Static VAR Generator Working Principle is based on real-time reactive power compensation using advanced IGBT technology. 

What is the Static VAR Generator Working Principle?

A Static VAR Generator (SVG) continuously monitors load conditions and injects precise reactive current to improve power factor, stabilise voltage, and enhance overall power quality. A static VAR generator (SVG) is an IGBT-based device that injects precisely controlled reactive current in real time, correcting power factor and stabilising voltage far faster and more accurately than conventional capacitor banks.

Reactive power compensation shrinks the reactive component (Q) and lifts power factor toward unity, reducing apparent power (kVA) demand.

What is a static VAR generator?

Understanding the Static VAR Generator Working Principle helps industries improve power factor and voltage stability more effectively than conventional capacitor banks.

Inductive loads — motors, transformers, welding sets, drives — draw reactive power (kVAr) that does no useful work but loads up cables, transformers and the utility supply. Traditional automatic power-factor-correction (APFC) panels switch fixed capacitor steps in and out, which is slow, coarse and prone to switching surges and resonance.

A static VAR generator replaces those fixed steps with an electronics-based, stepless compensator. It senses the exact reactive demand of the load and generates an equal and opposite reactive current, so the supply only ever sees real, working power.

Static VAR generator working principle

The SVG continuously measures load current and voltage, calculates the reactive (and unbalanced) component, and commands an IGBT inverter to source or sink exactly that amount of reactive current. The result is a source current almost perfectly in phase with the voltage — unity power factor.

The SVG injects a leading reactive current that cancels the load’s lagging current, leaving the source current in phase with the voltage.

• • Stepless — compensates continuously, not in fixed capacitor steps.

• • Fast — responds within milliseconds to load swings, ideal for welding, cranes and drives.

• • Four-quadrant — supplies both inductive and capacitive VARs and can balance unbalanced phases.

• • No resonance — unlike capacitor banks, an SVG won’t resonate with system harmonics.

SVG vs. capacitor banks (APFC)

Criterion	Capacitor bank / APFC	Static VAR Generator
Compensation	Fixed steps	Stepless, exact
Response time	Seconds	Milliseconds
Unbalance correction	No	Yes
Resonance risk	High	None
Capacitive & inductive	Capacitive only	Both directions

Key benefits of an InPhase SVG

• • Maintains power factor close to unity at all load levels, cutting kVA demand and PF penalties

• • Stabilises voltage and reduces flicker for sensitive processes

• • Corrects load unbalance across phases

• • Stepless, surge-free operation with no capacitor switching transients

• • Real-time DSP control with remote monitoring

Applications

The Static VAR Generator Working Principle makes SVGs ideal for industries with rapidly changing inductive loads such as steel, cement, textile, automotive, and pharmaceutical plants.

SVGs are used across textile, cement, steel, metro, chemical, automotive and pharmaceutical plants — and in any facility with fluctuating inductive loads, renewable integration or strict utility power-factor requirements.

Standards & grid codes

Utilities worldwide enforce a minimum power factor — commonly 0.95 to 0.99 — and penalise low PF or excess reactive (kVAr / KVAH) demand. International standards such as IEC 61000-2-4 and EN 50160 also limit voltage variation and unbalance. An SVG helps facilities stay within these grid-code and utility requirements in any market.

Why choose InPhase

InPhase Power Technologies is a specialist power-quality manufacturer with R&D approved by DSIR (Government of India) and an installed base measured in kilo-amperes across 10+ countries and sectors such as steel, cement, metro, textile, oil & gas, data centres and green hydrogen.

• • 100% focused on power quality, with DSIR-approved R&D

• • Low-voltage SVG and medium-voltage VAJRA SVG (3.3–33 kV) from one manufacturer

• • Modular SVG options for easy scaling and servicing

Frequently asked questions

What is the working principle of a static VAR generator?

An SVG measures the reactive component of the load current and uses an IGBT inverter to inject an equal and opposite reactive current in real time, bringing the power factor close to unity and stabilising voltage.

What is the difference between an SVG and a capacitor bank?

A capacitor bank corrects power factor in fixed steps and reacts in seconds, whereas an SVG compensates steplessly within milliseconds, handles both inductive and capacitive demand, corrects unbalance, and carries no resonance risk.

Does an SVG reduce electricity bills?

Yes. By raising power factor and cutting reactive (kVAr) demand, an SVG lowers apparent power (kVA), helps avoid power-factor penalties and can reduce KVAH-based billing.

Can an SVG correct voltage and unbalance?

Yes. Besides power-factor correction, an SVG stabilises voltage and can balance unbalanced three-phase loads.

The Static VAR Generator Working Principle provides a future-ready solution for dynamic reactive power compensation, voltage stabilization, and improved power quality.

Improve power factor and stabilise voltage with an InPhase SVG. Visit inphase.in or email sales@inphase.in for a reactive-power study.

 

Learn more about power quality standards from IEC Standards and IEEE Standards Association.
Learn more about our Power Quality Solutions and Static VAR Generator Solutions.

Related: Modular SVG, VAJRA medium-voltage SVG, and Smart Hybrid Active Filter (SHAF).