Using Scanner and Algorithm to Improve the Accuracy of Fused Deposition Modeling Printer

Yuxuan Chen; Yezheng Li; Yisen Qiao

doi:10.54097/8v0hw135

Authors

Yuxuan Chen
Yezheng Li
Yisen Qiao

DOI:

https://doi.org/10.54097/8v0hw135

Keywords:

FDM laser sensors, 3D printer, Algorithm.

Abstract

This essay explores the application of laser sensors and algorithms to enhance the accuracy of Fused Deposition Modeling (FDM) Three dimensions (3D) printers. Laser sensors, combined with advanced algorithms, provide a promising solution for improving the accuracy of FDM printers. The essay discusses the limitations of traditional FDM printers in achieving high precision and outlines the significance of accuracy improvement in 3D printing. It then explores the principles and functioning of laser sensors. By analyzing real-time sensor measurements, algorithms can identify errors, compensate for mechanical inaccuracies, and adjust the printer's motion to ensure precise printing. Additionally, the essay discusses the advantages and challenges of incorporating laser sensors and algorithms into FDM printers. The benefits include improved print quality, enhanced compatibility with complex geometries, and reduced dependency on manual calibration. However, challenges such as cost, sensor integration, and algorithm optimization must be addressed for specific adoption or further development. The integration of laser sensors with advanced algorithms offers a promising pathway for achieving high precision and detail in printed objects, ultimately advancing the capabilities and applications of FDM technology.

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