Ferrovanadium DC Furnace: Equipment and Technical Parameters
1. Equipment Overview
The ferrovanadium DC furnace adopts a single top cathode + furnace bottom anode DC arc furnace structure, suitable for producing FeV40, FeV50 and FeV60 ferrovanadium via silicothermic or aluminothermic reduction processes. Compared with traditional three-phase AC ferrovanadium furnaces, it delivers prominent advantages: concentrated and stable electric arc, 40%~50% lower graphite electrode consumption, low grid harmonic distortion, natural power factor of 0.90~0.96, high molten pool thermal efficiency, longer refractory service life and over 20 dB noise reduction.
Standard single furnace output capacities: 1.5t, 3t and 5t finished ferrovanadium furnaces, fully equipped with rectified power supply, water cooling, hydraulic tilting and full-automatic PLC control systems.
2. Complete Equipment System Composition
2.1 Power Supply & Rectification System (Core Power Unit)
- High-voltage Power Distribution Unit
10kV incoming cabinet, isolating switch, vacuum circuit breaker, SVG reactive power filter compensation device; suppresses grid flicker to only 50%~70% of that of AC furnaces.
- On-load Tap-changing Rectifier Transformer
Mainstream capacities: 1800kVA / 2500kVA / 3200kVA
Primary side: 10kV; secondary AC output adjustable from 90~220V with multiple tap positions
- Three-phase Full-controlled Bridge Rectifier
High-power thyristor rectifier with closed-circuit water cooling; outputs stable direct current with reversible positive/negative polarity switching; integrated multi-interlock protection against overcurrent, overvoltage, high water temperature and water leakage.
- Short Network Conductive System
- Upper cathode: water-cooled conductive cross arm, copper contact shoe, single graphite cathode electrode
- Furnace bottom anode: copper conductive base plate, water-cooled conductive support, furnace bottom conductive steel bundles
- Large cross-section internal water-cooled flexible cables with current density ≤3A/mm² to minimize conductive loss
2.2 Furnace Body System
- Furnace Shell
Cylindrical steel plate shell with double-layer circulating water jackets on upper section and thickened water cooling at slag line to reduce erosion from high-temperature radiation; equipped with temperature measuring and water leakage detection sensors.
- Special Alkaline Refractory Lining for Ferrovanadium Smelting
- Furnace bottom & molten pool: fused magnesia brick, magnesia-carbon brick (withstanding high reduction temperature of 1800~2100℃)
- Slag line furnace wall: chrome-magnesia brick; conductive steel plate laid on furnace bottom as anode
- Tubular fully water-cooled furnace cover reserved with feeding port, flue gas duct and central electrode hole
- Furnace Tilting Mechanism
Full hydraulic bilateral tilting, tilting angle 0~110°, tilting speed 0.5~2°/min; three positioning modes: smelting horizontal position, slag tapping position and metal tapping position, with mechanical locking device.
- Furnace Cover Lifting & Rotating Device
Hydraulic lifting + rotary structure; the cover can rotate away after lifting for furnace patching, slag line cleaning and electrode replacement.
2.3 Hydraulic Electrode Lifting System
- Single-column hydraulic lifting unit for independent vertical adjustment of single cathode graphite electrode
- PLC proportional valve dual closed-loop control (constant power regulation via voltage + current), switchable between manual and automatic modes
- Electrode stroke: 1200~1400mm; lifting response time ≤0.3s to stabilize submerged arc and avoid arc breakage or electrode fracture
2.4 Circulating Water Cooling System
- Independent closed pure water cooling unit for rectifier
- Shared industrial circulating cooling water for furnace shell water jackets, furnace cover, conductive cross arms, water-cooled cables and copper shoes
- Inlet water temperature ≤32℃, outlet water temperature ≤45℃, with interlock alarms for flow rate, pressure and temperature
2.5 Automatic Control System
PLC + upper computer DCS centralized monitoring:
- Automatic smelting curve operation (power auto-adjustment for arc striking, melting, reduction, refining and tapping stages)
- Real-time recording and accumulation of DC voltage, current, power and power consumption
- Interlock protection and fault alarm storage for water cooling, hydraulic system, tilting and electrode lifting
- Storage of process parameters, export of historical curves and output statistics
2.6 Auxiliary Supporting Systems
- Raw Material Batching System: silos, belt conveyors, electronic batching scales (precision ±0.5%), mixing machines
- Flue Gas Dust Removal System: water-cooled flue + baghouse dust collector, dust removal efficiency ≥99.5%
- Casting, cooling, crushing, screening and slag recycling systems
3. Main Standard Technical Parameters by Furnace Model
3.1 Core Power Supply & Rectification Parameters
| Parameter Item |
1.5t Ferrovanadium DC Furnace |
3t Ferrovanadium DC Furnace |
5t Ferrovanadium DC Furnace |
| Rectifier Transformer Capacity |
1800kVA |
2500kVA |
3200kVA |
| High-voltage Incoming Supply |
10kV, 50Hz |
10kV, 50Hz |
10kV, 50Hz |
| Secondary AC Tap Range |
90~220V (8 taps) |
90~220V (10 taps) |
100~240V (10 taps) |
| Rated DC Output Current |
6000A |
8000A |
11000A |
| DC No-load Voltage |
230V |
240V |
260V |
| Natural Power Factor |
0.90~0.94 |
0.91~0.95 |
0.92~0.96 |
| Rectifier Cooling Mode |
Closed-circuit Water Cooling |
Closed-circuit Water Cooling |
Closed-circuit Water Cooling |
3.2 Mechanical Furnace Body Parameters
| Parameter Item |
1.5t Furnace |
3t Furnace |
5t Furnace |
| Single-batch Finished Ferrovanadium Output |
1.5t per heat |
3t per heat |
5t per heat |
| Furnace Shell Inner Diameter |
Φ2600mm |
Φ2900mm |
Φ3300mm |
| Effective Furnace Height |
1600mm |
1850mm |
2100mm |
| Cathode Graphite Electrode Spec. |
Φ200mm |
Φ250mm |
Φ300mm |
| Electrode Current Density |
5.8~6.5A/cm² |
5.8~6.5A/cm² |
5.8~6.5A/cm² |
| Maximum Electrode Stroke |
1200mm |
1300mm |
1400mm |
| Maximum Furnace Tilting Angle |
105° |
110° |
110° |
| Tilting Drive |
Dual Hydraulic Cylinders |
Dual Hydraulic Cylinders |
Dual Hydraulic Cylinders |
| Furnace Cover Cooling Type |
Full Tubular Water Cooling |
Full Tubular Water Cooling |
Full Tubular Water Cooling |
3.3 Operational Smelting Parameters (FeV40 Production)
- Melting & Heating Stage: 1600~1700℃
- Main Reduction Reaction Stage: 1800~2100℃ (Aluminothermic/Silicothermic reduction of V₂O₅)
- Refining & Desiliconization Stage: 1650~1850℃
- Single Heat Smelting Cycle
Total duration: 70~90 min per heat; reduction stage 40~55 min, refining stage 10~20 min
- Power Consumption Index
Comprehensive smelting power consumption: 1200~1300 kWh/t FeV40; 5%~8% power saving vs AC furnaces
- Material Control
- Slag basicity control: 1.3~1.7 (adjusted by lime)
- V₂O₅ content in waste lean slag ≤0.35%; overall vanadium recovery rate 97%~98%
- Electrode Consumption
Graphite electrode consumption of DC furnace: 0.8~1.1kg/t ferrovanadium; traditional three-phase AC furnace: 1.6~2.0kg/t, nearly 50% reduction
4. Core Technical Advantages of DC Ferrovanadium Furnace
- Concentrated Arc Heat: Single-electrode DC arc radiates vertically downwards to molten pool, lowering thermal load on furnace wall slag line; service life of magnesia lining increased by over 30% with less frequent furnace patching.
- Grid-friendly Performance: Balanced three-phase current without negative sequence harmonics, requiring smaller capacity reactive power compensation and higher transformer utilization rate.
- Lower Production Cost: Halved electrode consumption, reduced power consumption per ton product and decreased refractory maintenance cost.
- Stable Smelting Quality: Uniform electromagnetic stirring in molten pool for even vanadium distribution and minor fluctuation of ferrovanadium chemical composition.
- Improved Operating Environment: Low noise under submerged arc, less flue gas overflow and slight equipment vibration.