METAL 3D PRINTING IN SRAEL
METAL ADDITIVE MANUFACTuRING
involves the layer-by-layer consolidation of metal powder or wire feedstock to fabricate fully dense, functional metal parts. These processes typically rely on high-energy heat sources such as lasers or electron beams
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Gibson, I., Rosen, D. W., & Stucker, B. (2015). Additive Manufacturing Technologies: 3D Printing, Rapid Prototyping, and Direct Digital Manufacturing (2nd ed.). Springer.
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From Complex Geometry to Mass Production
At NOVAKRON, metal 3D printing is not just about unique components — it’s about industrial-scale production of high-precision metal parts. We specialize in scaling up — moving from prototypes to full-scale serial manufacturing — with full control over repeatability, quality, and cost-efficiency.
Using Laser Powder Bed Fusion (LPBF) technology, we produce single-piece components with complex geometries that are impossible to make using traditional methods — and we do it at volume.
With over 10 years of hands-on experience in additive manufacturing, our team helps customers:
Reduce time-to-market
Minimize assembly through part consolidation and optimization
Lightweight structures without compromising strength
Integrate advanced functionality into single components
Build scalable AM production workflows ready for serial output
Our solutions are trusted by aerospace, defense, and automotive sectors across Israel.
METAL AM TEHNOLOGY
Direct Metal Laser Sintering (DMLS) /
Laser Powder Bed Fusion (LPBF)
is an additive manufacturing technique; used to 3D print metal parts with powdered metal or alloys being the raw material.
It belongs to the family of laser powder bed fusion technologies; which involve a precise high wattage laser selectively sintering the powdered metal such that the particles melt and fuse together to give rise to the final product based on the computer aided design (CAD) model. Fully functional complex parts that cannot be manufactured using conventional methods can be obtained using DMLS/LPBF with high accuracy, superior properties and faster turnaround times in manufacturing.
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Yu, N., (2005): Process parameter optimization for direct metal laser sintering (DMLS), Ph.D. thesis, National University of Singapore, Singapore.
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The EOS M 400-4 system, equipped with multiple lasers (four 400-watt fiber lasers working in parallel) and an advanced optical system, offers a large build volume (400 × 400 × 400 mm) and high productivity, making it suitable for serial production of metal parts in aerospace and automotive sectors
EOS M 400-4 Key Specifications Build Volume: 400 × 400 × 400 mm Laser Type: Yb-fiber laser; 4 × 400 W
Optics: 4 F-theta lenses; 4 high-speed scanners
Scan Speed: up to 7,000 mm/s
Focus Diameter: approx. 90 μm
Power Supply: 3 × 50 A
Power Consumption: max. 45.0 kW / typical 22.0 kW
Compressed Air Supply: 7 bar; 20 m³/h
Additive Manufacturing Technologies: 3D Printing, Rapid Prototyping and Direct Digital Manufacturing, Gibson et al., Springer, 2015.
The Renishaw RenAM 500Q is a high-productivity LPBF system with a build volume of 250 × 250 × 350 mm and four lasers, each up to 500 W. Designed for industrial-scale metal AM, it offers build rates of up to 150 cm³/h depending on material and process parameters. The system allows precise control of mechanical properties and delivers much higher throughput than single-laser systems, making it ideal for scalable, cost-efficient metal part production.
RenAM 500Q ULTRA Key Specifications Build Volume: 250 × 250 × 250 mm Laser Type: Yb-fiber laser; 4 × 500 W
Optics: Dynamic focusing; beam focus diameter 80 μm; scan speed up to 10 m/s
Build Rate: Up to 150 cm³/h
Powder Layer Thickness: 30–120 μm
Power Supply: 3 × 50 A
Wong, H., Dawson, K., Ravi, G.A. et al. Multi-Laser Powder Bed Fusion Benchmarking-Initial Trials with Inconel 625. Int J Adv Manuf Technol 105, 2891–2906 (2019).
The EOS M 400-4 system, equipped with multiple lasers (four 400-watt fiber lasers working in parallel) and an advanced optical system, offers a large build volume (400 × 400 × 400 mm) and high productivity, making it suitable for serial production of metal parts in aerospace and automotive sectors
Aluminium AlSi10Mg
Optics: 4 F-theta lenses; 4 high-speed scanners
Scan Speed: up to 7,000 mm/s
Focus Diameter: approx. 90 μm
Power Supply: 3 × 50 A
Power Consumption: max. 45.0 kW / typical 22.0 kW
Compressed Air Supply: 7 bar; 20 m³/h
Additive Manufacturing Technologies: 3D Printing, Rapid Prototyping and Direct Digital Manufacturing, Gibson et al., Springer, 2015.
- Large and Small Electric Motors
- Large and Small Electric Motors
- Large and Small Electric Motors
The EOS M 400-4 system, equipped with multiple lasers (four 400-watt fiber lasers working in parallel) and an advanced optical system, offers a large build volume (400 × 400 × 400 mm) and high productivity, making it suitable for serial production of metal parts in aerospace and automotive sectors
EOS M 400-4 Key Specifications Build Volume: 400 × 400 × 400 mm Laser Type: Yb-fiber laser; 4 × 400 W
Optics: 4 F-theta lenses; 4 high-speed scanners
Scan Speed: up to 7,000 mm/s
Focus Diameter: approx. 90 μm
Power Supply: 3 × 50 A
Power Consumption: max. 45.0 kW / typical 22.0 kW
Compressed Air Supply: 7 bar; 20 m³/h
Additive Manufacturing Technologies: 3D Printing, Rapid Prototyping and Direct Digital Manufacturing, Gibson et al., Springer, 2015.
- Large and Small Electric Motors
- Generators
- Ballasts
- Transformers
Quality Quantity Repeatability
From Idea to Serial Product — Made In Israel
Nahum Het 9, Tirat Carmel, Israel