produits
EINZELHEITEN ZU DEN PRODUKTEN
Haus > Produits >
HGTECH Nickel Mesh Electrode Laser Welding Equipment Designed for Electrolyzer R&D Pilot Manufacturing

HGTECH Nickel Mesh Electrode Laser Welding Equipment Designed for Electrolyzer R&D Pilot Manufacturing

Mindestbestellmenge: 1 Satz
Preis: USD 80000-250000 / Set
Standardverpackung: Standard-Export-Holzkiste mit vakuumversiegelter Feuchtigkeitsbarriere und korrosionsbeständiger VCI
Lieferfrist: 60-90 Werktage
Zahlungsmethode: T/T, L/C, Western Union
Lieferkapazität: 50 Sätze pro Jahr
Ausführliche Information
Herkunftsort
Hubei, China
Markenname
HGTECH
Zertifizierung
CE, ISO 9001:2015, ISO 14001
Modellnummer
HG-NMW-Serie
Schweißende Leistungsfähigkeit:
3-4,5 Minuten pro Stück (einzelne Elektrodenplatte)
Jährliche Produktionskapazität:
280 Einheiten Elektrolyseure mit 1000 Nm³/h
Kompatible Elektrolyseurgröße:
500-2000 Nm³/h
Schweißausbeute:
≥96%
Produktwechselzeit:
< 1 Stunde
Schweißverfahren:
Punktschweißen und kontinuierliches Linienschweißen
Nickelschichtschutz:
Gasschutzvorrichtung, hochweiße Oberfläche, Höhenüberschuss ≤0,8 mm
Nahtverfolgung:
XYZ-Echtzeitverfolgung, gratfreie Kanten
Stationskonfiguration:
Doppelstationsstruktur, automatisches Be- und Entladen
Gleichmäßigkeit des Nickelnetzes:
Dynamischer Pressvorrichtungsmechanismus
Kontrollsystem:
CNC mit HMI-Touchscreen-Schnittstelle
Laserquelle:
Faserlaser, 2000W-6000W-Optionen
Hervorheben:

HGTECH-Nickelmaschenelektrode

,

mit einer Leistung von mehr als 50 W und einer Leistung von mehr als 50 W

,

Forschung und Entwicklung von Elektrolyzern

Produkt-Beschreibung

HGTECH Nickel Mesh Electrode Laser Welding Equipment — R&D and Pilot-Scale Electrolyzer Development

Product Description

The HGTECH HG-NMW Series Nickel Mesh Electrode Laser Welding Equipment in its R&D configuration is specifically adapted for electrolyzer research laboratories, pilot production lines, and technology validation centers. While retaining the full precision and quality capabilities of the production-grade system, this variant emphasizes flexibility, rapid changeover, and comprehensive process data capture — essential features for organizations developing next-generation alkaline electrolyzer designs, testing novel electrode materials, or validating manufacturing processes before scaling to full production.

The system's standout feature for R&D applications is its sub-1-hour product changeover capability, supporting electrode sizes from 500 to 2000 Nm³/h electrolyzer formats. This allows research teams to test multiple electrode configurations within a single working day — dramatically accelerating design iteration cycles compared to traditional manual welding methods that require hours of setup adjustment between different electrode sizes. The dual welding mode (spot welding and continuous line welding) enables researchers to experiment with different weld patterns and their impact on electrode performance, providing a comprehensive experimental platform for welding process optimization.

Every weld is digitally documented with full XYZ seam tracking data, laser power profiles, and gas protection parameters — creating a complete digital twin of the welding process for each electrode. This weld data package supports patent applications, technology transfer to manufacturing partners, and academic publications requiring detailed process documentation. The system's 2000W-6000W fiber laser options accommodate a wide range of nickel mesh specifications and experimental electrode substrate materials.

Key Advantages for R&D and Pilot Production

  • Rapid Design Iteration: Less than 1-hour changeover between electrode sizes (500-2000 Nm³/h formats) enables research teams to test multiple electrode configurations daily, compressing development timelines from months to weeks for new electrolyzer designs.
  • Complete Process Data Capture: Every weld generates a comprehensive digital record including XYZ seam coordinates, laser power profile, gas flow rates, and dynamic pressing pressure — creating verifiable process documentation for technology validation, patent filings, and manufacturing scale-up.
  • Multi-Mode Welding Flexibility: Both spot welding and continuous line welding modes are available with software-switchable parameter sets, allowing researchers to directly compare weld pattern performance on electrode efficiency, durability, and gas bubble release characteristics.
  • Material Development Platform: The adjustable laser power range (2000W-6000W) and programmable welding parameters support testing of novel nickel mesh alloys, alternative coating materials, and next-generation electrode substrate configurations — future-proofing R&D investments as electrolyzer technology evolves.
  • Scale-Up Ready: Process parameters developed and validated on the HG-NMW R&D system transfer directly to production-scale HG-NMW equipment with identical laser sources and control architecture — eliminating the common R&D-to-production translation gap that delays manufacturing ramp-up.

Application: Electrolyzer Innovation Centers

Use CaseTypical UserKey Requirement
New Electrode Design ValidationElectrolyzer OEM R&D CenterRapid prototyping, multi-size compatibility
Welding Process OptimizationManufacturing Engineering LabProcess parameter library development
Material Qualification TestingNational Research InstituteComprehensive data capture, reproducibility
Pilot Production LineStartup Electrolyzer CompanyScale-up pathway, moderate throughput
Technology Transfer CenterUniversity-Industry PartnershipTraining capability, process documentation

FAQ

Q: Can we use this system to weld experimental electrode materials beyond standard nickel mesh?

A: Yes. The HG-NMW Series' programmable laser parameters support welding of various nickel-based alloys, stainless steel mesh substrates, and coated electrode materials. Our applications engineering team provides parameter development support for novel materials — we typically require 3-5 sample pieces to develop and validate an optimized welding recipe. This capability has been utilized by several national hydrogen research programs exploring advanced electrode architectures for next-generation alkaline electrolyzers.

Q: How do process parameters developed on the R&D system transfer to full production equipment?

A: The HG-NMW R&D and production systems share identical laser source specifications, control architecture, and welding head design. Validated process parameters — including laser power, travel speed, pulse frequency, gas flow, and pressing pressure — transfer directly via USB/network export to production-scale HG-NMW units. This design philosophy eliminates the common scaling challenge where R&D-developed processes require extensive re-validation on production equipment, saving 3-6 months in manufacturing ramp-up timelines.

Q: What training and support is included for research institution customers?

A: All HG-NMW systems include 5 days of on-site installation and operator training, covering equipment operation, welding parameter optimization, maintenance procedures, and safety protocols. For research institution customers, we offer an extended 10-day training package that includes hands-on parameter development workshops, data analysis training for weld quality metrics, and a starter parameter library for common nickel mesh specifications. Remote technical support is available via video call during your local business hours, with optional annual service contracts for ongoing research support.

Research Partnership Program

✔ Priority access to HGTECH applications engineering team for novel material development
✔ Co-authored technical publications support for joint research outcomes
✔ Early access to firmware and software updates with advanced welding strategies
✔ Invitation to annual HGTECH Hydrogen Equipment Technology Symposium
✔ Discounted consumables and spare parts program for academic and non-profit research institutions