Stratasys F370
Generated by GPT-5-miniExpansion Funnel Raw 102 → Dedup 0 → NER 0 → Enqueued 0
| Stratasys F370 | |
|---|---|
| Name | Stratasys F370 |
| Manufacturer | Stratasys |
| Introduced | 2016 |
| Type | Fused Deposition Modeling |
| Build volume | 355 × 254 × 355 mm |
| Layer resolution | 0.013–0.254 mm |
| Materials | ABS-M30, ASA, PCABS, ABS-CF10 |
| Connectivity | USB, Ethernet |
| Weight | 130 kg |
Stratasys F370 The Stratasys F370 is a professional fused deposition modeling (FDM) 3D printer introduced by Stratasys for industrial prototyping and tooling. It targets engineering groups and manufacturing operations seeking repeatable thermoplastic parts with integrated support removal and compliance with regulatory workflows. The platform sits within a family of production-focused additive manufacturing systems used across aerospace, automotive, medical, and consumer-products organizations.
Design and specifications
The chassis and enclosure design emphasize dimensional stability and thermal control, influenced by industrial precedents such as Hewlett-Packard, General Electric, Siemens, Ford Motor Company, and Boeing. Build volume and gantry layout are often compared with offerings from Ultimaker, MakerBot, 3D Systems, EOS GmbH, and Carbon, Inc. to position capacity and part-size capability. Electrical and mechanical integration reflects standards deployed by Bosch, Panasonic, ABB Group, Honeywell, and Rockwell Automation for factory-floor compatibility. Safety and certification considerations connect to norms promulgated by Underwriters Laboratories, International Electrotechnical Commission, American National Standards Institute, Occupational Safety and Health Administration, and European Committee for Standardization.
Technology and materials
The F370 uses fused deposition modeling technology derived from patents and engineering lineage associated with founders and contributors who patented extrusion-based systems; peers include Scott Crump, Charles Hull, S. Scott Crump, 3D Systems (Chuck Hull), and companies like Stratasys Ltd.'s contemporaries such as MakerBot Industries, Zortrax, Markforged, Prusa Research, and Raise3D. Supported thermoplastics include engineering-grade ABS-M30, ASA, PCABS, and reinforced blends similar to those used by Victrex, Sabic, Covestro, DuPont, and BASF. Support materials and soluble support strategies relate to chemistry developed by firms like Eastman Chemical Company and solvent-process methods tracked by International Organization for Standardization directives. Material qualification and certification workflows align with processes familiar to NASA, Airbus, Lockheed Martin, General Motors, and Siemens Healthineers.
Performance and printing workflow
Typical layer resolution ranges from 0.013 mm to 0.254 mm, and print speeds and accuracy metrics are benchmarked against systems from 3D Systems, EOS GmbH, SLM Solutions, Desktop Metal, and Carbon, Inc.. The printer's reliability metrics and mean time between failures inform production scheduling practices used at General Electric Aviation, Rolls-Royce Holdings, BMW, Daimler AG, and Tesla, Inc.. Post-processing steps, including support removal and surface finishing, draw parallels with workflows at Jabil, Flex Ltd., Foxconn, Arcam AB, and Materialise. Quality control and part inspection workflows are often integrated with metrology solutions from Zeiss, Renishaw, Mitutoyo, Hexagon AB, and FARO Technologies.
Software and compatibility
Software integration for job preparation and machine control typically references closed-loop systems comparable to those from Autodesk, Inc., Dassault Systèmes, PTC (company), Siemens PLM Software, and SolidWorks for CAD/CAM interoperability. Slicing, build preparation, and print queue management share functional space with applications from Simplify3D, Ultimaker Cura, GrabCAD, Materialise Magics, and Netfabb. Network and IT compatibility considerations echo enterprise deployments at IBM, Microsoft, Oracle Corporation, SAP SE, and Amazon Web Services for data management, security, and version control. Compliance with digital thread and PLM strategies associates implementations with Siemens Digital Industries Software, PTC Windchill, Dassault ENOVIA, Aras Corporation, and Autodesk Vault.
Applications and industry use
Adoption spans aerospace development programs at Airbus, Boeing, NASA, and Rolls-Royce, automotive applications at Ford Motor Company, General Motors, BMW, and Tesla, Inc., and medical device prototyping used by Medtronic, Stryker Corporation, Johnson & Johnson, and Zimmer Biomet. Consumer-products and industrial-design groups at Nike, Procter & Gamble, Whirlpool Corporation, and GE Appliances use the platform for concept models, fit-check fixtures, and manufacturing aids. Tooling and jigs align with lean manufacturing practices showcased by Toyota Motor Corporation, Honda Motor Company, Caterpillar Inc., and John Deere. Research and education deployments appear in labs at Massachusetts Institute of Technology, Stanford University, University of Cambridge, ETH Zurich, and Georgia Institute of Technology.
Maintenance and support
Service, warranty, and field-support models follow patterns deployed by OEMs such as Siemens, Schneider Electric, Rockwell Automation, Honeywell, and Emerson Electric. Preventive maintenance schedules, spare-parts provisioning, and calibration procedures are similar to enterprise equipment support used by General Electric, ABB Group, Boeing, Airbus, and Lockheed Martin. Training, certified technician programs, and customer success initiatives mirror programs offered by Siemens PLM Software, Dassault Systèmes, PTC, Autodesk, and Rockwell Automation to ensure uptime and regulatory compliance.
Category:3D printers