TRUMPF100W
TruMark 6030Price$35,000 - $50,000
Browse 12 semi-automatic laser marking systems from 11 manufacturers. Compare automation features and throughput.
12 semi-automatic machines from 11 manufacturers span 0.02kW to 0.1kW (average 0.0kW). Semi-automatic systems add shuttle tables (typically 2-pallet exchange) for continuous production: while one sheet is being cut, the operator loads the next. This eliminates the largest non-cutting time component and can increase actual cutting time from 50% to 75% of total shift hours.
Automation ROI analysis: Shuttle table systems add $15K–$40K to base cost with typical payback under 6 months through reduced idle time. Most operators report 30–50% productivity improvement — the most cost-effective automation upgrade available. Among these 12 systems from 5 manufacturing countries, compare automation features using the table above to match your production volume and labor cost structure.
| Brand / Model | Power | Work Area | Max Steel | Speed @5mm | Price Range | Origin |
|---|---|---|---|---|---|---|
| TRUMPF TruMark 6030 | 100W | — | — | — | $35,000 - $50,000 | 🇩🇪 |
| Trotec SpeedMarker 1300 | 100W | — | — | — | $35,000 - $50,000 | 🇦🇹 |
| Epilog FiberMark Fusion Pro | 50W | — | — | — | $30,000 - $45,000 | 🇺🇸 |
| Gravotech LF510G | 50W | — | — | — | $25,000 - $35,000 | 🇫🇷 |
| Han's Laser EP-50 Fiber Marker | 50W | — | — | — | $5,000 - $9,000 | 🇨🇳 |
| SIC Marking i104 L-G Fiber | 50W | — | — | — | $20,000 - $30,000 | 🇫🇷 |
| JPT Opto-electronics LP-E 30W | 30W | — | — | — | $3,000 - $5,000 | 🇨🇳 |
| Coherent PowerLine E 25 | 25W | — | — | — | $25,000 - $35,000 | 🇺🇸 |
| Bodor BM-20 Fiber Marker | 20W | — | — | — | $2,500 - $5,000 | 🇨🇳 |
| Han's Laser EP-20 Fiber Marker | 20W | — | — | — | $3,000 - $6,000 | 🇨🇳 |
Selecting the right laser marking systems involves evaluating five critical factors: (1) Material type and maximum thickness — determine the minimum laser power required. (2) Work area dimensions — match to your largest sheet or part size, with common formats being 3015 (3000×1500mm) and 4020 (4000×2000mm). (3) Production volume — high-volume shops benefit from automation features like sheet loading/unloading and nesting software. (4) Budget — consider total cost of ownership including installation, training, consumables, and maintenance, not just purchase price. (5) Service and support — verify the manufacturer has local service partners in your region. Use our comparison table above to evaluate 12 options side by side, filtering by the specifications most important to your application.
Five primary factors determine laser cutting edge quality: (1) Laser power and beam quality (BPP/M²) — lower BPP values produce focused spots with higher energy density for cleaner cuts. (2) Cutting head optics — auto-focus heads with collimation adjustment optimize beam characteristics for different materials and thicknesses. (3) Motion system accuracy — positioning accuracy (±0.03mm typical for premium machines) and repeatability directly affect dimensional precision. (4) Assist gas selection and pressure — nitrogen for oxide-free edges on stainless and aluminum, oxygen for faster thick-steel cutting. (5) Mechanical rigidity — machine bed flatness, gantry stiffness, and vibration damping affect edge straightness and surface roughness. Compare these specifications across our 12 listed machines using the table above.