HSG X3015 Fiber Laser 3kW – Year 2024
Equipped with:
HSG Control
HSG Laser Head
3kW Raykus Resonator
Chiller
Air-Conditioning Cabinet
Safety Protection Package
CypNest Software
Full Extension Work Bench
Transformer
Voltage Stabilizer
Dust Collector
HSG X3015 Fiber Laser Cutting Machine (3 kW) – Technical Evaluation (Year 2024)
1. Technical Evaluation Overview
The HSG Laser X3015 is a CNC fiber laser cutting machine manufactured in 2024, configured with a 3 kW fiber laser source. Based strictly on the provided information, the system integrates HSG Control, an HSG laser head, and a Raycus 3 kW resonator. Supporting equipment includes a chiller, air-conditioning cabinet, transformer, voltage stabilizer, dust collector, and a safety protection package.
The machine is supplied with CypNest nesting software and a full extension work bench, indicating a standard sheet-processing configuration. Critical cutting parameters—such as maximum sheet size, axis travels, acceleration, positioning accuracy, cutting speed, and supported material thickness—are not provided and must be verified to complete the technical assessment.
2. What to Check Before Buying
Given the limited specification set, inspection should focus on the following:
Laser source and optics:
Verification of the 3 kW Raycus resonator hours, stability, and power output consistency.
Condition and alignment of the HSG laser head, including protective window integrity and focus mechanism performance.
Motion system and table:
Confirmation of the actual working area (commonly associated with the X3015 designation but not stated).
Smoothness and repeatability of linear axes; inspection of guides, racks, and drives.
Flatness and condition of the full extension work bench.
Thermal and electrical systems:
Proper operation of the chiller under load and cabinet air-conditioning for electronics thermal management.
Functionality of the transformer and voltage stabilizer, ensuring stable supply within site conditions.
Software and control:
Operation of HSG Control and CypNest, including nesting efficiency, post-processing, and job transfer.
Availability of backups, licenses, and alarm logs.
Safety and environment:
Integrity of the safety protection package (interlocks, guarding).
Performance of the dust collector for fume and particulate management.
3. Typical Industrial Applications
Based strictly on the stated configuration (3 kW fiber source and standard sheet-cutting peripherals), the machine is technically suitable for:
CNC laser cutting of thin to medium-thickness sheet materials where a 3 kW class source is appropriate.
Production environments requiring integrated nesting (CypNest) and enclosed safety features.
Specific material types, maximum thicknesses, and productivity metrics cannot be confirmed from the provided data.
4. Common Risks in Used Machines
For fiber laser cutting systems, typical risks include:
Laser source degradation or undocumented operating hours.
Optical contamination or misalignment affecting cut quality.
Motion accuracy issues if axis calibration or mechanical condition is compromised.
Software/licensing gaps, including missing backups or expired modules.
5. Maintenance and Service Considerations
With no service history provided, only general technical considerations apply:
Routine inspection of optics, cooling circuits, and filtration is essential.
Electrical stability should be monitored, particularly when relying on transformers and stabilizers.
Control parameters, machine configurations, and software licenses should be backed up prior to operation.
Any maintenance planning should be based on on-site inspection and functional testing rather than assumptions about intervals or spare part availability.
Final Note:
The provided information confirms a modern 3 kW fiber laser cutting system with comprehensive auxiliary equipment. A complete technical evaluation requires verification of working area, axis performance, cutting capability by material and thickness, and detailed machine documentation through direct inspection and testing.
