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Shape size: X 600 mm × Y 600 mm × Z 600 mm + tilt and rotating table.
Directed Energy Deposition (DED) Metal 3D Printer RPMI XR series features the "smallest" size RPMI 222 XR, which ensures a build size of [X 600 mm × Y 600 mm × Z 600 mm]. With 5-axis control through X, Y, Z + tilt and a rotating table, it allows for free-form shaping, part repair, and cladding (build-up) with ease.
Shape size: [X 1500 mm × Y 1500 mm × Z 2100 mm] "Largest" size within the RPMI XR series.
Directed Energy Deposition (DED) Metal 3D Printer RPMI XR series, featuring the "largest" size RPMI 557 XR. Build size [X 1500 mm × Y 1500 mm × Z 2100 mm]. With 5-axis control through X, Y, Z + tilt and rotating table, free-form shaping, part repair, and cladding (build-up) are possible.
Proven track record of domestic implementation in Japan. 557XR maximum build size: [X 1500 mm × Y 1500 mm × Z 2100 mm]
Directed Energy Deposition (DED) Metal 3D Printer RPMI XR Device Series RPMI 557XR, RPMI 222 XR. RPMI 557 XR Build Size [X 1500 mm × Y 1500 mm × Z 2100 mm] RPMI 222 XR Build Size [X 600 mm × Y 600 mm × Z 600 mm] With 5-axis control through X, Y, Z + tilt and rotating table, free-form fabrication, part repair, and cladding (build-up) are possible.
![Metal 3D Printer [AconityMIDI]](https://image.www.ipros.com/public/product/image/26f/2000691705/IPROS01587679229241569403.png?w=280&h=280)
The second process chamber can optionally add preheating at 1200°C.
AconityMIDI is a new approach by Aconity3D aimed at a flexible production system. This system, which can be equipped with a second process chamber as an option, allows for the preparation of the next setup to proceed simultaneously while the main system is still in production, saving time. Additionally, this system can also optionally include process monitoring or high-temperature preheating up to 1200°C. Like all Aconity3D devices, the AconityMIDI device is equipped with the control software AconitySTUDIO, allowing Aconity3D service engineers to remotely access all relevant process parameters and machine components, enabling timely support for customers.
![Metal 3D Printer [AconityMINI]](https://image.www.ipros.com/public/product/image/ee1/2000691722/IPROS62513111977314072527.png?w=280&h=280)
Entry-level lab system. By utilizing the Φ55mm reduction component (optional), process development is possible even with a small amount of powder material!
AconityMINI is an entry-level lab system from Aconity3D. The build space can be reduced from a standard Φ140mm to Φ55mm, and this system, which provides complete access to all relevant process parameters, is designed for efficient materials research. Furthermore, this system allows for flexible configuration of the equipment by selecting optional features such as preheating, process monitoring, and laser output to best meet the customer's needs. Like all Aconity3D devices, the AconityMINI is equipped with the control software AconitySTUDIO, which allows Aconity3D service engineers to remotely access all relevant process parameters and machine components, providing timely support to customers.
This is a schematic diagram explaining the laser powder bed fusion method (laser powder bed process) for metal 3D printers!!
"What is the Laser Powder Bed Fusion (LPBF) method?" For those in charge of gathering information on metal 3D printers, we provide an explanatory diagram of the Laser Powder Bed Fusion method! A series of operations is repeated for layered manufacturing: the recoater deposits powder, the laser irradiates to melt and solidify the powder, the build stage descends, the powder reservoir rises, and again, the recoater deposits powder. Excess surrounding powder from the recoater's deposition operation falls into a collection tank through the overflow opening and is sieved for recycling during the manufacturing process. *The diagram is based on Aconity3D's equipment and may not necessarily apply to all laser powder bed fusion metal 3D printers currently sold by various manufacturers.
What is directional energy deposition method? What is DED? Let me explain it simply!
"What is Directed Energy Deposition (DED)?" We provide an explanatory diagram of Directed Energy Deposition (DED) for those responsible for gathering information on metal 3D printers! Directed Energy Deposition involves spraying metal powder into a melt pool created by a laser heat source, moving the melt pool along with the laser head, and repeatedly melting and solidifying to create a layered structure. Unlike typical metal 3D printers that have a powder bed, it fixes the base plate or pipes on a table with tilt (90°) and rotation (360°) functions for manufacturing. 1. Free-form manufacturing 2. Free-form manufacturing of complex shapes 3. "Additive" manufacturing to conventional machined parts 4. "Build-up" repairs (+ regrinding*) for worn-out parts (*The diagram is based on equipment from RPM Innovations and may not necessarily apply to all metal 3D printers using Directed Energy Deposition currently sold by various manufacturers. Please note.)
![[Explanation] Electron Beam Powder Bed Melting Method Metal 3D Printer](https://image.www.ipros.com/public/product/image/aad/2000820391/IPROS39826353215074647105.png?w=280&h=280)
What is the electron beam powder bed fusion method (powder bed fusion)? What is EB-PBF? Let me explain it simply!
"What is Electron Beam Powder Bed Fusion (EB-PBF)?" "What is EB-PBF?" Let me explain briefly! We provide a schematic explanation of Electron Beam Powder Bed Fusion (EB-PBF) for those in charge who have started gathering information on metal 3D printers! The process involves powder supply by a powder dispenser, powder deposition by a recoater (forward motion), vertical movement of the build stage and the recoater's excess powder passing motion, melting and solidification of the powder by electron beam irradiation, and powder deposition by the recoater (return motion). This series of actions is repeated to create layered structures. The vertical movement of the build stage and the recoater's excess powder passing motion help save powder and reduce waste. *The schematic is based on equipment from Wayland Additive and may not necessarily apply to all electron beam powder bed fusion (EB-PBF) metal 3D printers currently sold by various manufacturers.
![Metal 3D Printer [AconityTWO]](https://image.www.ipros.com/public/product/image/c0e/2000691679/IPROS30687849390395724736.png?w=280&h=280)
This is Aconity3D's latest solution for efficient industrial laser powder bed fusion (LPBF) manufacturing and production.
The AconityTWO device is Aconity3D's latest solution for efficient industrial laser powder bed fusion (LPBF) manufacturing and production. With a large build envelope of Ø 400 mm x H 400 mm and an easy-to-open machine cover, it allows for the production of large parts with minimal setup time, thereby reducing manufacturing costs. To maximize flexibility in the types of materials that can be processed and to enhance quality assurance, it can be equipped with optional high-temperature preheating up to 800°C and Aconity3D's entirely new process monitoring system (optional). The AconityTWO can also utilize up to four lasers in a quad-laser configuration, further improving productivity. Like all Aconity3D devices, the AconityTWO is equipped with the AconitySTUDIO control software, allowing Aconity3D service engineers to remotely access all relevant process parameters and machine components, providing timely support to customers.
