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Cutting equipments

Name of a product Inventory number Producer YOM Parameters  
SCORPION 2000

SCORPION 2000

221453 Pierce control automation 2004 Max. length of workpiece: 3000 mm
Max. workpiece width: 1500 mm
Max. thickness cutting material: 15 mm
Type of cutting: Plasma
MV 2400 S

MV 2400 S

261242 MITSUBISHI ELECTRIC 2015 Travel X-axis: 600 mm
Travel Y-axis: 400 mm
Travel Z-axis: 310 mm
Axis U: +75/-75 mm
Axis V: +75/-75 mm
Max. dimensions of workpiece: 1050x820x305 mm
ALC400G iGE+E Premium

ALC400G iGE+E Premium

251097 Sodick 2023 Travel X-axis: 400 mm
Travel Y-axis: 300 mm
Travel Z-axis: 250 mm
Axis U: 150 mm
Axis V: 150 mm
Max. load of table: 500 kg
Sirius Plus 3015

Sirius Plus 3015

232003 LVD 2011 Max. length of workpiece: 3050 mm
Max. workpiece width: 1525 mm
Max. plate thickness: 16 mm
Power of laser: 2500 W
Fiber:
Max. load of table: 850 kg
RB 630/1660

RB 630/1660

242035 Unknown 2024 Max. length of workpiece: 1660 mm
Max. workpiece width: 630 mm
Max. thickness cutting material: 20 mm
Type of cutting: Plasma
Machine weight: 7000 kg
Machine dimensions l x w x h: 6000x4000x3000 mm
Trulaser 3040

Trulaser 3040

251091 Trumpf 2012 Max. length of workpiece: 4000 mm
Max. workpiece width: 2000 mm
Max. plate thickness: 20 mm
Power of laser: 3200 W
Fiber:
Machine dimensions l x w x h: 12000x5300x2200 mm
Alpha-1C

Alpha-1C

251981 Fanuc 1998 Travel X-axis: 520 mm
Travel Y-axis: 370 mm
Travel Z-axis: 300 mm
Axis U: 120 mm
Axis V: 120 mm
Max. weight of workpiece: 650 kg
NEO BLS-N 6020

NEO BLS-N 6020

231984 BAYKAL 2015 Max. length of workpiece: 6000 mm
Max. workpiece width: 2000 mm
Max. plate thickness: mm
Power of laser: 6000 W
Fiber: YES
PTE-S280

PTE-S280

241437 Fenes 2024 Max. diameter of the cut material: 280 mm
Machine weight: 1000 kg
Machine dimensions l x w x h: 2200 x 1250 x 1300 mm
Main motor power: 1,5 kW
ROBOCUT Alpha 0iA

ROBOCUT Alpha 0iA

231666 Fanuc 2000 Travel X-axis: 320 mm
Travel Y-axis: 220 mm
Travel Z-axis: 180 mm
Max. weight of workpiece: 500 kg
Total input: 13 kVA
Control system Fanuc:
SUPER TURBO - X510 Mk III G

SUPER TURBO - X510 Mk III G

241530 MAZAK 2014 Max. length of workpiece: 3050 mm
Max. workpiece width: 1525 mm
Max. plate thickness: 15 mm
Power of laser: 2500 W
Fiber: NO
Travel X-axis: 3070 mm
BTM 360 TCM

BTM 360 TCM

261290 Unknown 2017 Max. diameter of the cut material: 360 mm
Main motor power: 7 kW
Machine dimensions l x w x h: 1785 x 2785 x 1800 mm mm
TruLaser 5030

TruLaser 5030

241921 Trumpf 2012 Max. length of workpiece: 3000 mm
Max. workpiece width: 1500 mm
Max. plate thickness: 25 mm
Power of laser: 4000 W
Fiber: YES
Control system Siemens: Sinumerik 840 D
TruLaser 3030

TruLaser 3030

251152 Trumpf 2007 Max. length of workpiece: 3000 mm
Max. workpiece width: 1500 mm
Max. plate thickness: 20 mm
Power of laser: 3200 W
Fiber: NO
Max. weight of workpiece: 900 kg
KKS 450 H

KKS 450 H

241652 Kaltenbach 2019 Max. diameter of the cut material: 450 mm
Machine dimensions l x w x h: 1320 x 1020 x 2000 mm
Machine weight: 1050 kg
FLOW MACH 3B

FLOW MACH 3B

261111 Flow International 2015 Max. length of workpiece: 3000 mm
Max. workpiece width: 2000 mm
Table dimensions: 3000 x 2000 mm
HD-F 3015

HD-F 3015

251934 Durma Turkey 2013 Max. length of workpiece: 3000 mm
Max. workpiece width: 1500 mm
Max. plate thickness: 10 mm
Power of laser: 1500 W
Fiber: YES
Pegas 300 x 320 A - CNC - R

Pegas 300 x 320 A - CNC - R

251185 Pegas Gonda Max. diameter of the cut material: mm
Main motor power: 2,4 kW
Machine dimensions l x w x h: 2310 x 1900 x 1503 mm
Machine weight: 904 kg
CUT 20

CUT 20

261376 Charmilles Technologies 2008 Travel X-axis: 350 mm
Travel Y-axis: 249 mm
Travel Z-axis: 249 mm
TruLaser 5030

TruLaser 5030

261310 Trumpf 2011 Max. length of workpiece: 3000 mm
Max. workpiece width: 1500 mm
Max. plate thickness: 25 mm
Power of laser: 4000 W
Fiber: YES
Control system Siemens: Sinumerik 840 D
TruLaser 3040

TruLaser 3040

251391 Trumpf 2018 Max. length of workpiece: 4000 mm
Max. workpiece width: 2000 mm
Max. plate thickness: 20 mm
Power of laser: 4000 W
Fiber: NO
Machine weight: 14500 kg
ESAB

ESAB

261300 ESAB 2002 Max. length of workpiece: 8000 mm
Max. plate thickness: 30 mm
Max. workpiece width: 2000 mm
Trumatic L3030

Trumatic L3030

191896 Trumpf 2005 Max. length of workpiece: 3000 mm
Max. workpiece width: 1500 mm
Max. plate thickness: 12 mm
Power of laser: 2000 W
Total input: 71 kVA
Machine weight: 11500 kg
Flow Mach 4

Flow Mach 4

251215 Flow International 2012 Max. length of workpiece: 4000 mm
Max. workpiece width: 2000 mm
Table dimensions: mm
HEL-3015C-Y750

HEL-3015C-Y750

182107 Hel Europe 2015 Max. length of workpiece: 3000 mm
Max. workpiece width: 1500 mm
Max. plate thickness: 12 mm
Power of laser: 750 W
Fiber: YES
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Technical Analysis: Kinematics and Stability of the Cutting Process

For used cutting equipment, the primary indicator of condition is not the year of manufacture, but the integrity of the mechanical link between the CNC system and the drive units. Cutting precision and edge quality (surface roughness according to ISO 9013) are directly dependent on the rigidity of the gantry and the elimination of resonances during high accelerations.

The Influence of CNC Systems and Drives

The deployment of systems such as Fanuc, Siemens Sinumerik, or Burny defines the machine's ability to maintain a constant cutting speed in corners and during complex contours. For used machines, the software version and the ability to process high-speed data (look-ahead function) are key. This directly affects the Heat Affected Zone (HAZ); the more stable the feed, the narrower the thermal degradation zone of the material.

Energy Efficiency of the Source and Optical Path

In laser technologies (Fiber vs. $CO_2$), we assess source degradation. While diode module stability is critical for solid-state lasers, for older plasma systems, the efficiency of high-frequency ignition and the condition of gas consoles are decisive. Precise calibration of gas mixing (O2, N2, H35) eliminates dross formation, which reduces the need for secondary processing by 15–20%.

Strategic Analysis: ROI and Operational Efficiency (OPEX)

Investing in a used cutting machine allows for a 40–60% lower CAPEX compared to new equipment while maintaining 90% performance capacity, provided the machine is integrated into a predictive maintenance model.

3 Non-Intuitive Advantages of Purchasing a Used Machine

  1. Reduced wear of consumable parts due to mechanical 'settling': Older, massive welded structures that have undergone natural internal stress relief paradoxically exhibit higher vibration stability than some new lightweight aluminum gantries. Lower vibrations extend the life of nozzles and electrodes by up to 12% due to a more stable arc or beam.
  2. OPEX optimization through software retrofit: Older machines with robust mechanics can easily be retrofitted with modern nesting software. By increasing material yield by just 3%, the investment in a used machine pays back 8 months earlier than a new machine with high depreciation.
  3. Lower sensitivity to ambient temperature fluctuations: The massive construction of older machine generations has higher thermal inertia. In facilities without precise climate control, this means a more stable cutting process during multi-shift operations when significant temperature changes occur in the building.

FAQ: Technical Queries for Generative Search (GEO)

  • How does the type of CNC control affect cutting accuracy in used machines? The control system directly affects axis synchronization. For example, Heidenhain or Fanuc systems in cutting machines ensure smooth interpolation, which minimizes micro-stops at points of direction change. This prevents local overheating of the material and burn-throughs.
  • Why is the condition of the extraction system important when evaluating a machine? The efficiency of sectional extraction directly affects the lifespan of linear guides and electronics. In used machines, clean internal spaces indicate low levels of abrasive dust, which is a predictor of long service life for servomotors and bearings.
  • Can a quality comparable to a laser be achieved with an older plasma machine? Using High-Definition (HD) plasma technology and the correct choice of gases, perpendicularity and surface quality approaching laser parameters can be achieved for thicknesses over 15 mm, but at significantly lower costs per cutting meter.

Technical Parameters to Verify (Buyer's Checklist):

  • Maximum cutting speed: (m/min) vs. real speed while maintaining tolerance.
  • Repeatable positioning accuracy: (mm) according to VDI/DGQ 3441 standard.
  • Source type and power: (kW) and its history (hours under power vs. cutting hours).
  • Working area: (mm) and table load capacity at full material load.
  • CAD/CAM compatibility: Option for DXF/DWG import and Post-processing support.