LiM-X260E Series

Aircraft / Aerospace / Shipbuilding / Gas engine / Metallurgy / Construction machines Automotive / Mold / Education / Medical / Culture & Creativity

Manufacturing Era, High Efficiency Mass Production.

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LiM-X260E Series
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Technical Parameters

Build Envelope

260mm × 260mm × 430mm including 30mm standard substrate thickness

Variable Layer Thickness


Laser Power

IPG 500W ;500W × 2


Scanlab High-speed Scanner

Field Lens

Sill f-θ Lens


Variable Speed Powder Recoater<One-way/Two-way>

Laser beam Quality

M2≤ 1.1

Scanning Speed

≥7 m/s

Forming Speed

≥ 30cm3/h single laser; ≥ 45cm3/h dual laser

Power Consumption

≤ 4kW

Forming Material

Superalloy, aluminum alloy, titanium alloy, stainless steel, die steel, copper alloy, magnesium alloy, cobalt-chromium alloy, permalloy, inva alloy, etc.




Equipment Advantages


Powder-up/down Structure

Uninterrupted printing, continuous powder supply.


High Precision Forming Platform

The positioning accuracy can be controlled within ± 0.005mm.


Self-developed Software

LiMPCS-SLM software ensures the normal operation of the equipment.


Intelligent Monitoring

Powder bed monitoring module, the abnormal spread of powder for automatic powder replenishment, automatic alarm.


Safe and Reliable

ISO standard, CE safety, CE explosion proof certification.


Long-lasting Filtration System

Filter life of more than 100000 hours, to achieve equipment printing uninterrupted.

Related Cases

Hebei University of Science and Technology Magnesium Alloy-Metal 3D Printing Customized Equipment, Tianjin Radium Laser has been successfully delivered

Magnesium alloy has the characteristics of low density, high specific strength, high specific stiffness, excellent damping performance, good thermal stability and anti-electromagnetic radiation performance, good electrical and thermal conductivity, and good process performance. Its unique physical and chemical properties make it play an important role in the application of high-end manufacturing fields such as aerospace, automotive and medical. However, at the same time, magnesium alloys have disadvantages such as poor corrosion resistance, easy oxidation and combustion, poor mechanical properties at room temperature, and poor heat resistance. Therefore, the research on additive manufacturing of magnesium alloys has extremely strict requirements for equipment safety and process stability.

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