AEROTECH100W
NMARK GCLWork Area200×200mm
Price$40,000 - $80,000
Browse 7 laser marking systems with 200×200mm work area from 7 brands. Compare power, capabilities, and pricing. Pricing from $3,000 to $40,000.
7 machines from 7 manufacturers offer the 200x200 work area format. Average laser power across these machines is 0.1kW. Work area selection is driven by your maximum sheet/part dimensions: the 3015 format (3000×1500mm) fits standard European sheet sizes, while 4020 (4000×2000mm) covers North American 4×8ft and large-format Asian sheets. Oversized formats (6020, 8025) serve structural steel, shipbuilding, and heavy equipment manufacturing.
Larger work areas don't always mean better: they increase machine footprint, building cost, and sheet handling complexity. Match your work area to your dominant sheet size plus a 10–20% reserve, unless you specifically process oversize parts. The 7 machines listed above let you compare configurations at this work area size across 5 manufacturing origins.
| Brand / Model | Power | Work Area | Max Steel | Speed @5mm | Price Range | Origin |
|---|---|---|---|---|---|---|
| AEROTECH NMARK GCL | 100W | 200×200 | — | — | $40,000 - $80,000 | 🇺🇸 |
| Rofin-Sinar PowerLine F 100 | 100W | 200×200 | — | — | $30,000 - $50,000 | 🇩🇪 |
| Scanlab intelliSCAN 30 | 100W | 200×200 | — | — | $5,000 - $10,000 | 🇩🇪 |
| JPT Opto-electronics MOPA M7 60W | 60W | 200×200 | — | — | $3,000 - $6,000 | 🇨🇳 |
| SIC Marking i104 L-G Fiber 50W | 50W | 200×200 | — | — | $20,000 - $35,000 | 🇫🇷 |
| Panasonic MOPA Laser Marker 30W | 30W | 200×200 | — | — | $15,000 - $25,000 | 🇯🇵 |
| Gravotech FIBER F20 | 20W | 200×200 | — | — | $20,000 - $40,000 | 🇫🇷 |
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 7 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 7 listed machines using the table above.