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AM S5500P

  • AM S5500P
  • AM S5500P

The RICOH AM S5500P is the future of Additive Manufacturing. With its generous build volume, the AM S5500P enables you to produce many components at once, ensuring fast, flexible and cost-effective production. It uses Powder Bed Fusion (or SLS technology) to melt polymer powder to produce parts, and you can choose from a selection of polymer-based materials. Our technology uses heat and a smart re-coater combined with a laser to manufacture end-use components, which can be used in a range of industries such as Aerospace, Automotive and Medical. Using advanced thermal control parameters, you benefit from highly accurate and repeatable manufacturing capabilities.

Features and benefits

High-end additive manufacturing technology with a range of high performance materials for the manufacturing industry and beyond.

  • Substantial build size
  • Advanced Temperature Control
  • Smart re-coater and dual powder distribution
  • High machine reliability
  • Wide material selection – you can select materials from Ricoh’s approved range, including Polypropylene (PP), PA6GB, PA11, PA12, PA12GB*
  • Supported by Ricoh Service

Video: Meet the RICOH AM S5500P

Meet the RICOH AM S5500P
Specifications
GENERAL
Effective work size (W x D x H) 550 x 550 x 500 mm
Actual part size (W x D x H) 500 x 500 x 480 mm
Laser CO2 100 W
Beam diameter Ø 0.48 mm
Layer thickness 0.08 - 0.2 mm
Scanning speed 15 m/sec (3-axis digital galvanometer mirror)
Application software SEMware, Windows 7 Professional, CPU Intel Corei3, 2.4 GHz, 2 GB
Input data STL
Power supply requirements AC 200V +/- 10% 50A 50/60Hz, 3PH
Air conditioning requirements 18-24°C (set within +/- 2°C when modeling)
Primary features Parameter setting flexibility, PA12 support, PA6 GB support, PP support
Specific gravity PA12: 1.03 (26°C), PA11: 1.01 (20°C), PP: 0.84- 0.85 (20°C)
Bulk density PA12/PP: 0.43 g/cm³ / 0.51 g/cm³
Tap density PA12: 0.55 g/cm³, PA12G: 1.23 g/cm³, PA11: 0.62 (W)/0.66 (B) g/cm³, PP: 0.58 g/cm³
Mean particle size PA12/PA12G: 45+/-5 µm, PA11: 46 (W)/50 (B) µm, PP: 51 µm
90% particle range PP: 33-80
Melting point PA12: 185°C, PA12G: 184°C, PA11: 201°C, PP: 125°C
Deflection temperature under load (0.45 Mpa) PA12/PA12G: 174°C
Deflection temperature under load (1.8 Mpa) PA12/PA12G: 100°C / 128°C
Maximum extension stress PA12: 47 Mpa, PA12G: 33 Mpa, PA11: 45 Mpa, PP: 21.4 Mpa
Tensile elasticity PA12: 1689 Mpa, PA12G: 2291 Mpa, PA11: 1500 Mpa, PP: 907 Mpa
Breaking elongation PA12: 14.5%, PA12G: 6%, PA11: 45%, PP: 529%
Maximum bending stress PA12: 58.5 Mpa, PA12G: 52.8 Mpa, PA11: 46 Mpa, PP: 22.8 Mpa
Bending strain PA12/PA12G: 15.3% / 7.4%
Flexural modulus PA12: 1406 Mpa, PA12G: 1904 Mpa, PA11: 1200 Mpa, PP: 698 Mpa
Impact strength (notched) PA12/PA12G: 2.36 kJ/m² / 3.05 kJ/m²
Chemical stability PA12/PA12G/PA11: Alkali, Hydrocarbon, Fuel, Solvent
Applications PA12: Functional testing, Design review, Automotive interior part, Tray, Mechanical, PA12G: Wind tunnel testing, Functional testing, Design review, Intake manifold, PA11: Functional testing, Design review, Hinge parts, PP: Functional testing, Design review, Hinge parts
Dimensions (W x D x H) 2100 x 1520 x 2400 mm
Weight 2000 kg