Harmonic Suppression Furnace Transformer Solution

​Problem Analysis​
Modern electric furnaces (especially arc furnaces, medium-frequency furnaces, and power-frequency induction furnaces) generate substantial higher-order harmonic currents that inject into the grid during operation due to their nonlinear load characteristics (e.g., violent fluctuations of electric arcs, rectification/inversion processes). These harmonics cause:

1. ​Grid Pollution: Distorted grid voltage waveforms (increased THD), affecting the normal operation of other sensitive equipment on the same grid.
2. ​Equipment Damage: Overheating, intensified vibration, accelerated insulation aging, and even failure of transformers, cables, compensation capacitors, etc.
3. ​Increased Power Loss: Additional thermal losses from harmonic currents flowing through grid impedance.
4. ​Reduced Power Factor: Despite installed compensation capacitors, harmonics may render reactive power compensation devices ineffective or amplify resonances.
5. ​Measurement Errors: Compromised accuracy in energy metering and monitoring instruments.

​Solution Core: Harmonic Suppression Furnace Transformer​
To address these challenges, ROCKWILL offers an advanced harmonic suppression furnace transformer solution. It effectively mitigates harmonics at the source, ensuring safe, stable, and efficient operation of furnace systems and the grid.

​Core Technologies & Measures​

1. ​Built-in High-Efficiency Harmonic Filter:
   • The core of this solution integrates an optimally designed harmonic filter targeting characteristic harmonics (e.g., 5ᵗʰ, 7ᵗʰ, 11ᵗʰ, 13ᵗʰ) generated by furnace loads.
   • The compact, space-saving filter is integrated directly into the transformer for easy installation.
   • Utilizing LC resonance, it provides a low-impedance path to absorb and filter specific harmonics near the source, significantly reducing grid-injected harmonic currents (THD reduction complies with GB/T 14549, IEEE 519, etc.).
2. ​Optimized Transformer Design:
   • Low-Harmonic Magnetic Circuit: High-permeability silicon steel sheets and optimized core structures minimize core saturation tendency and self-generated harmonics.
   • Low-Harmonic Winding: Advanced winding techniques (e.g., foil winding) and materials reduce eddy current losses, leakage flux, copper losses, and additional harmonics.
   • Enhanced Insulation & Cooling: Reinforced insulation and optimized cooling systems (e.g., forced-oil air cooling) ensure long-term reliability and extended service life under harmonic-induced thermal stress.
   • Improved Short-Circuit Resistance: Enhanced resilience to abnormal operating conditions caused by harmonics.
3. ​Coordinated Optimization & Smart Monitoring (Optional)​:
   • Synchronize with furnace control systems or external active power filters (APF) and static var generators (SVG) for holistic power quality management.
   • Optional smart monitoring systems track key parameters (harmonics, temperature, load rate) in real time for predictive maintenance and remote oversight.

​Advantages​
• ​Efficient Harmonic Mitigation: Filters key characteristic harmonics at the source, significantly reducing grid THD and protecting grid/equipment.
• ​Source-Level Mitigation: Directly addresses harmonics at the transformer, ensuring thorough suppression.
• ​Improved Power Quality: Stabilizes voltage waveforms for reliable operation of furnaces and sensitive equipment.
• ​Extended Equipment Lifespan: Prevents harmonic-induced overheating and damage to transformers, cables, and capacitors, lowering maintenance costs.
• ​Optimized Reactive Compensation: Minimizes harmonic interference with compensation devices, enhances power factor correction, and reduces line losses.
• ​Standards Compliance: Ensures harmonics meet GB/T 14549, IEEE 519, and other global power quality standards.
• ​Compact & Reliable: Integrated design saves space and simplifies system architecture.
• ​Enhanced System Efficiency: Reduces harmonic-related losses and boosts overall energy efficiency.

​Application Scenarios​
Ideal for harmonic-intensive applications demanding high power quality:
• Electric arc steelmaking furnaces
• Medium-frequency/power-frequency induction melting furnaces
• Submerged arc furnaces
• Power supply systems for other large-scale nonlinear furnace loads