Introduction: EP-M150 adopts the metal powder bed fusion (MPBF) process, which can quickly transform complex 3D CAD data into high-quality metal 3D parts, which is suitable for batch additive manufacturing of dental metal crowns and stents. Features: 1. Support cobalt chromium and titanium alloy Cobalt-chromium and titanium alloys are currently the main materials for metal dental restorations. EP-M150 uses metal powder bed fusion (MPBF) technology, which can quickly convert complex 3D CAD data into high-quality metal 3D parts, and supports batch printing of dental cobalt-chromium alloy/titanium alloy crowns, stents and other metal restorations. 2. High efficiency The EP-M150 metal 3D printer only takes about 5.5 hours to print the full-page crown and bridge (about 220 pieces); it only takes about 6.5 hours to print the full-page bracket (about 15 pieces), which enables the technical factory to cope with higher production timeliness. 3. High precision Dental restorations are small in size and require high precision, which puts forward high manual requirements for technicians. The EP-M150 metal 3D printer helps the technical factory liberate the high dependence on the manual skills of the personnel. It has a self-designed optical path system and a professional high-precision correction method with independent intellectual property rights to ensure efficiency and provide high-precision molding results. Details Good, good adhesion. 4. Easy to operate Compared with traditional casting, it takes several years of experience to become a good casting master. Using the EP-M150 metal 3D printer only takes a few months of training to get started, helping technical factories to solve the old and difficult problems of recruitment and training. EP-M150 conforms to the ergonomic structure optimization design, simple operation and maintenance; supports "one-key printing" function, the equipment operation is very convenient. 5. Low operating costs Traditional methods may cause a lot of waste of metal materials and other consumables, making the working environment poor and difficult to pass the environmental assessment. The EP-M150 through the scientific feeding/screening/recycling system to ensure high material utilization, an average of about 550 teeth can be printed per 1kg of metal powder; it supports the recycling of protective gas, and the gas consumption is small: gas consumption in the 3D printing process The amount is less than 0.2L/min (0.3±0.1MPa). The high material utilization rate and low gas consumption also ensure the low operating costs of technical factories, and help technical factories to reduce costs and increase efficiency in scientific development. 6. High security Integrate more than 10 safety assurance technologies; real-time detection of working environment and gas status to ensure the safe operation of equipment. 7. Quick support In the face of digital equipment, many traditional technology factories may have natural anxiety and fear. However, the EP-M150 metal 3D printer is not only easy to operate and efficient, but also comes with a thoughtful and excellent technical support team through remote services and on-site collaboration. Quickly solve technical problems; provide professional application and training solutions for dental users, so that you will have no worries on the road of transformation and upgrading. technical parameter: Product model: EP-M150 Laser: single/dual laser 200W/500W Spot diameter: 40-60μm Layer thickness: 200W laser: 20-50μm 500W laser: 20-80μm Molding room size: Ф150*80mm (height can be expanded to 120mm) Machinable materials: cobalt-chromium alloy, titanium alloy, etc. Gas requirements: Ar/N2 Data format: STL file or other convertible format Power supply and power consumption: 220V; 16A; 50/60 Hz; 3.5kW Equipment size (width x depth x height): 1750mm×800mm×1830mm Equipment weight (without powder): about 900kg
Introduction: EP-M150 adopts the metal powder bed fusion (MPBF) process, which can quickly transform complex 3D CAD data into high-quality metal 3D parts, which is suitable for batch additive manufacturing of dental metal crowns and stents.
