Rate limits of additive manufacturing by fused filament fabrication and guidelines for high-throughput system design

Jamison Go, Scott N. Schiffres, Adam G. Stevens, A. John Hart

Research output: Contribution to journalArticlepeer-review

179 Scopus citations

Abstract

As additive manufacturing (AM) advances rapidly towards new materials and applications, it is vital to understand the performance limits of AM technologies and to overcome these limits via improved machine design and process integration. Extrusion-based AM (i.e., fused filament fabrication, FFF) is compatible with a wide variety of thermoplastic polymer and composite materials, and can be deployed across a wide range of length scales. However, the build rate of both desktop and professional FFF systems is comparable (∼10's of cm 3 /h at ∼0.2 mm layer thickness), suggesting that fundamental aspects of the machine design and process physics limit system performance. We determine the rate limits to FFF by analysis of machine modules: the filament extrusion mechanism, the heater and nozzle, and the motion system. We determine, by direct measurements and numerical analysis, that FFF build rate is influenced by the coincident module-level limits to traction force exerted on the filament, conduction heat transfer to the filament core, and gantry velocity for positioning the printhead. Our findings are validated by direct measurements of build rate versus part complexity using desktop FFF systems. Last, we study the scaling of the rate limits using finite element simulations of thermoplastic flow through the extruder. We map the scaling of extrusion force, polymer exit temperature, and average printhead velocity onto a unifying trade-space of build rate versus resolution. This approach validates the build rate performance of current FFF systems, and suggests that significant enhancements in FFF build rate with targeted quality specifications are possible via mutual improvements to the extrusion and heating mechanism along with high-speed motion systems.

Original languageEnglish
Pages (from-to)1-11
Number of pages11
JournalAdditive Manufacturing
Volume16
DOIs
StatePublished - Aug 1 2017
Externally publishedYes

Funding

Funding for this research was provided by a grant from Lockheed Martin Corporation, managed by Dr. Padraig Moloney. Adam G. Stevens was supported by the Department of Defense (DoD) through the National Defense Science & Engineering Graduate Fellowship (NDSEG) Program. We thank the MIT Department of Mechanical Engineering for providing the Mojo printer, and the MIT International Design Centre (IDC) and MIT MakerWorks for providing experimentation and fabrication spaces. We also thank undergraduate research assistants Maxwell Malinowski and Amelia Helmick for assistance with build rate measurements and materials characterization.

FundersFunder number
Maxwell Malinowski and Amelia Helmick
U.S. Department of Defense
Lockheed Martin Corporation
Massachusetts Institute of Technology
Department of Mechanical Engineering, College of Engineering, Michigan State University
National Defense Science and Engineering Graduate
International Design Centre

    Keywords

    • Filament shear area
    • Fused filament fabrication
    • Liquefier dynamics
    • Module limitations
    • Performance map

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