DECI Duo
Compact solution for powder removal and surface finishing
Характеристики
Производитель
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PostProcessing
Материал
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Металл, Полимер
DECI Duo
With the patent-pending Hybrid DECI Duo™, powder removal and surface finishing of 3D printed parts is automated in a single, multi-functioning system and designed with a space-saving footprint that optimizes production floor space. The Hybrid DECI Duo has been engineered for the most advanced 3D print materials such as resins, thermoplastics, and metals, and offer fast cycle times for even the most complex parts, including those with internal channels, organic geometries, and honeycombs.
The Duo’s unprecedented performance is a result of our Thermal Atomized Fusillade (TAF) technology, in which two perpendicular, single-axis jet streams comprised of compressed air, detergent, and suspended solids providing targeted blast sequences while utilizing 360° part rotation for maximum surface exposure. As a result, the DECI Duo can remove powder and finish surfaces of the following 3D printing technologies: SLA, SLS, DMLS/Binder Jetting, MJF, SLS, and more.
Through a combination of optimized energy, exclusive chemistry including detergents and suspended solids, the system is guided by our proprietary AUTOMAT3D™ software to remove support powder and provide the desired surface finish while preserving fine-detail part geometries.
The Duo’s unprecedented performance is a result of our Thermal Atomized Fusillade (TAF) technology, in which two perpendicular, single-axis jet streams comprised of compressed air, detergent, and suspended solids providing targeted blast sequences while utilizing 360° part rotation for maximum surface exposure. As a result, the DECI Duo can remove powder and finish surfaces of the following 3D printing technologies: SLA, SLS, DMLS/Binder Jetting, MJF, SLS, and more.
Through a combination of optimized energy, exclusive chemistry including detergents and suspended solids, the system is guided by our proprietary AUTOMAT3D™ software to remove support powder and provide the desired surface finish while preserving fine-detail part geometries.