Ja, aber mit Einschränkungen:
Harmonische Minderung verbessert den Verzerrungsleistungfaktor (Dipf):
Durch die Beseitigung harmonischer Strömungen, AHFs reduzieren Verluste des Verzerrung Leistungsfaktor, Verbesserung des gesamten Leistungsfaktors (TPF).
Limited Reactive Power Compensation:
Some advanced AHFs can inject leading or lagging currents to correct displacement power factor (similar to capacitors or STATCOMs).
Jedoch, they are less cost-effective than capacitors for pure reactive power correction.
- Comparison with Traditional PFC Methods
- Practical Applications Where AHFs Improve Power Factor、
2.1 Industrial Plants with VFDs
Problem: Variable Frequenzantriebe (VFDs) generate harmonics and inductive reactive power.
Lösung: AHFs reduce harmonics, improving DiPF, while capacitors correct DPF.
2.2 Data Centers with SMPS Loads
Problem: Switch-mode power supplies (SMPS) cause harmonic distortion and poor power factor.
Lösung: AHFs clean harmonics, enhancing overall power factor without additional PFC units.
2.3 Renewable Energy Systems
Problem: Solar/wind inverters introduce harmonics and fluctuating reactive power.
Lösung: Hybrid systems (Ahf + Statcom) provide both harmonic filtering and dynamic PFC.
2.4. Limitations of AHFs in Power Factor Correction
Higher Cost: AHFs are more expensive than capacitor banks for pure PFC.
Limited kVAR Capacity: They are optimized for harmonics, not bulk reactive power.
Not Always Needed: If harmonics are low, capacitors or STATCOMs may be more efficient.
- Abschluss
Active Harmonic Filters do improve power factor, but primarily by reducing harmonic distortion (Dipf) rather than compensating for reactive power (DPF). For full PFC, a combination of AHFs and capacitors/STATCOMs is often the best solution.
In modern power systems with high harmonic pollution, AHFs offer a dual benefit: cleaner power and better power factor. Jedoch, engineers must evaluate whether harmonics or reactive power is the dominant issue before selecting the right solution.
