| Customization: | Available |
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| Cooling Way: | Air Cooling |
| Style: | Portable |
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Overheating is a common challenge in welding machines, often leading to reduced performance and shorter lifespans. The latest models address this issue by incorporating four separated heat sinks, a design that maximizes thermal dissipation. Unlike traditional single or dual heat sink systems, this advanced configuration ensures even heat distribution across multiple cooling zones, preventing localized overheating.
Improved Heat Resistance: The separated design allows for better airflow, reducing thermal buildup even during prolonged high-amperage welding.
Extended Component Lifespan: By maintaining lower operating temperatures, critical electronic components such as IGBTs and MOSFETs experience less stress, enhancing durability.
Consistent Performance: Stable temperature control prevents power fluctuations, ensuring smooth and reliable welding output.
This innovation is particularly beneficial for industrial applications where continuous operation is required, minimizing downtime due to overheating.
Post-flow gas control is crucial in processes like TIG welding, where shielding gas must continue after the arc extinguishes to protect the weld pool from oxidation. The latest welding machines feature adjustable post-flow timing, allowing welders to customize gas flow duration based on material thickness, welding current, and environmental conditions.
Optimized Gas Usage: By fine-tuning post-flow duration, users can reduce unnecessary gas consumption, lowering operational costs.
Enhanced Weld Quality: Proper post-flow settings prevent contamination, resulting in cleaner, stronger welds with reduced porosity.
Versatility: Adjustable settings accommodate different metals (e.g., aluminum, stainless steel) and varying weld durations, improving adaptability across projects.
This feature is especially valuable for precision welding applications where gas coverage directly impacts weld integrity.
Arc ignition is a critical phase in welding, and inconsistent striking can lead to poor weld starts, spatter, and electrode sticking. Advanced welding systems now achieve an arc striking success rate of over 99%, thanks to high-frequency ignition technology and optimized power delivery.
Reduced Weld Defects: Reliable arc starts minimize imperfections at the beginning of a weld, improving overall joint quality.
Increased Productivity: Fewer failed starts mean less time spent re-igniting the arc, boosting efficiency in high-volume welding tasks.
User-Friendly Operation: Both beginners and professionals benefit from consistent performance, reducing frustration and material waste.
This improvement is particularly advantageous in automated welding and high-precision manual applications where consistent arc initiation is essential.
| Input Voltage (V) | Frequency (HZ) | Rated Input Current (A) | Output Current Range (A) | Rated Output Voltage (V) | No-load Voltage (V) |
| AC220V±15% | 50/60 | 28 | 10-180 | 18 | 42 |
| Power Factor | Efficiency (%) | Duty Cycle (%) | No-load Loss (W) | Insulation Grade | Protection Grade |
| 0.93 | 85 | 30 | 40 | F | IP21S |
| Net Weight (kg) | Size (mm) | ||||
| 9 | 450x345x345 |
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