3D-Printed Pyrography Using PLA/Wood Filaments

Wood-filled PLA filaments enable 3D pyrography in material-extrusion (MEX) printing, in which tonal gradients and surface shading are generated in situ by controlling the thermal history during deposition, thereby avoiding post-processing or multi-material strategies. This enables the direct embedding of motifs and graded shading for customized product design, while also allowing appearance stabilization for repeatable manufacturing of wood-filled PLA parts. In this work, PLA/olive-wood (OW) composite filaments containing 0-20 wt.% OW (particle size < 180 µm) were manufactured and printed into 20 mm discs using MEX. The extrusion (nozzle) temperature was varied from 180 to 280 °C, and the printing speed was set to 20 and 200 mm/s to modulate thermal exposure. Surface color was quantified as L^*, a^*, b^* from visible absorbance measurements (400-700 nm) converted into CIELAB coordinates. Percentual differences were assessed using the CIEDE2000 metric ΔE₀₀. The results demonstrated that increasing nozzle temperature progressively reduced lightness L^*, and under severe conditions, a marked loss of chroma (a^* and b^*), particularly for higher OW contents. Low-speed printing (20 mm/s) amplified the pyrographic effect, reaching strong perceptual contrasts (maximum ΔE₀₀ ≈ 9 at 280 °C for 20 wt.% OW), whereas high-speed printing (200 mm/s) mitigated extreme darkening and maintained more moderate, controlled color differences (typically ΔE₀₀< 3). Accordingly, ΔE00< 3 can be used as a practical “color-stable” target for uniform-looking parts, whereas ΔE00= 3-9 provides clearly distinguishable shades for pyrographic marking/shading. These findings defined practical process windows to either maximize tonal contrast for 3D pyrography or stabilize the appearance for consistent manufacturing of PLA/OW parts.

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Polymer Processing and Thermomechanical Properties

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Periodical:

Defect and Diffusion Forum (Volume 451)

Pages:

55-62

DOI:

https://doi.org/10.4028/p-Dcjc3i

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Online since:

April 2026

Authors:

Francisco Comino*, José A. Martínez-Sánchez, Alessandro Pellegrini, Roberto Spina

Keywords:

3D Pyrography, Automotive Composites, Material Extrusion, Wood Filament

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Creative Commons CC BY 4.0

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* - Corresponding Author

References

[1] B. Redwood, F. Schöffer, B. Garret, The 3D Printing Handbook, 3D Hubs B.V., Amsterdam, 2018.

Google Scholar

[2] Y. Tao, H. Wang, Z. Li, P. Li, S.Q. Shi, Development and application of wood flour-filled polylactic acid composite filament for 3d printing, Materials 10 (2017).

DOI: 10.3390/ma10040339

Google Scholar

[3] F. Comino, J.A. Martinez-Sánchez, P.E. Romero, N. Gurrado, R. Spina, Thermo-mechanical properties of polylactic acid/olive wood composite for additive manufacturing, in: Materials Research Proceedings, Association of American Publishers, 2025: p.2344–2351.

DOI: 10.21741/9781644903599-253

Google Scholar

[4] N. V. dos Santos, D.K.K. Cavalcanti, J.S.S. Neto, H.F.M. de Queiroz, M.D. Banea, D.C.T. Cardoso, Analysis of voids, interfacial and thermal properties of additively manufactured continuous natural fiber-reinforced biocomposites, Progress in Additive Manufacturing 10 (2025) 5401–5422.

DOI: 10.1007/s40964-024-00913-5

Google Scholar

[5] A.D. Syanatha, R.A. Setiawan, S. Steven, Y. Mardiyati, Effect of manau rattan (Calamus manan miq.) particle size on processability and mechanical properties of 3D-printed PP/rattan WPC filaments, Progress in Additive Manufacturing 10 (2025) 5387–5399.

DOI: 10.1007/s40964-024-00912-6

Google Scholar

[6] M. Saponari, A. Giampetruzzi, G. Loconsole, D. Boscia, P. Saldarelli, Xylella fastidiosa in olive in apulia: Where we stand, Phytopathology 109 (2019).

DOI: 10.1094/PHYTO-08-18-0319-FI

Google Scholar

[7] E. Petinakis, X. Liu, L. Yu, C. Way, P. Sangwan, K. Dean, S. Bateman, G. Edward, Biodegradation and thermal decomposition of poly(lactic acid)-based materials reinforced by hydrophilic fillers, Polym Degrad Stab 95 (2010) 1704–1707.

DOI: 10.1016/j.polymdegradstab.2010.05.027

Google Scholar

[8] D.D.C.V. Sheng, M.N. Bin Yahya, N.B.C. Din, K.Y. Wong, M.R.M. Asyraf, V. Sekar, Potential of wood fiber/polylactic acid composite microperforated panel for sound absorption application in indoor environment, Constr Build Mater 444 (2024). https://doi.org/10.1016/ j.conbuildmat.2024.137750.

DOI: 10.1016/j.conbuildmat.2024.137750

Google Scholar

[9] F. Comino, P.E. Romero, E. Molero, M. Ruiz de Adana, Experimental evaluation of a 3D printed air dehumidification system developed with green desiccant materials, Appl Therm Eng (2023) 120393.

DOI: 10.1016/j.applthermaleng.2023.120393

Google Scholar

[10] K. (Justin) Moon, J. Yi, V. Savage, A. Bianchi, 3D printed pyrography: Using wood filament and dynamic control of nozzle temperature for embedding shades of color in objects, Addit Manuf 83 (2024).

DOI: 10.1016/j.addma.2024.104064

Google Scholar

[11] M. Kariz, M. Sernek, M. Obućina, M.K. Kuzman, Effect of wood content in FDM filament on properties of 3D printed parts, Mater Today Commun 14 (2018) 135–140.

DOI: 10.1016/j.mtcomm.2017.12.016

Google Scholar

[12] R. Spina, Surface appearance of poly lactic acid due to variations in material extrusion processing parameters, Sci Rep 15 (2025).

DOI: 10.1038/s41598-025-14484-0

Google Scholar