Fused Deposition Modelling (FDM) 3D Printer is a revolutionary technology in
Additive Manufacturing (AM). Polylactic Acid (PLA) is a biodegradable and
compostable polymer formed from the condensation of lactic acid. This experimental
study uses a nozzle temperature variation of 210 °C, 220 °C, 230 °C and infill type is
honeycomb pattern which print speed of 3D printer is 80mm/s to print the specimen.
The specimen of tensile test was conducted based on American Society for Testing and
Material (ASTM) standard D638 type 4, while the specimen of flexural test was
conducted based on ASTM standard D790. tensile test, flexural test, and
macrostructural analysis will be carried out to determine the effect of nozzle
temperature on the test. Based on the results of the study, it was found that the shrinkage
produced by 3D Print specimens for tensile tests and flexural tests at nozzle
temperature 230 °C was very high, namely 2.83% and 4.33%, respectively. nozzle
temperature at 230 °C produces a fairly high Ultimate Tensile Strength (σUTS) and
Flexural strength (σFS) of 39.60±2.60 MPa and 49.02±0.76 MPa, respectively. In
macrostructural analysis, the nozzle temperature porosity at 230 °C produces the
smallest porosity of 0.04 mm2 or 1.46%.

1. A. Setiawan, “Pengaruh Parameter Proses Ektrusi 3d Printer Terhadap Sifat Mekanis Cetak Komponen Berbahan Filament PLA (Poly Lactide Acid),” Teknika STTKD: Jurnal Teknik, Elektronika, Engine, vol. 4, no. 2, pp 20-27, 2017. (in Indonesian).

2. A. Baier, P. Zur, A. Kolodziej, P. Konopka, and M. Komander, “Studies On Optimization Of 3d-Printed Elements Applied In Silesian Greenpower Vehicle,” IOP Conf. Ser.: Mat. Sci. Eng., vol. 400, no. 2, article no. 022010, 2018.

3. S. A. Raj, E. Muthukumaran, and K. Jayakrishna, “A Case Study of 3D Printed PLA and Its Mechanical Properties,” Mater. Today Proc., vol. 5, no. 5, pp. 11219-11226, 2018.

4. E. W. Kusuma, A. Larasati, S. Nurkhamidah, and A. Altway, “Pra Desain Pabrik Poly-L-Lactic Acid (PLLA) dari Tetes Tebu,” Jurnal Teknik ITS, vol. 8, no. 2, pp 139-144, 2019. (in Indonesian).

5. H. K. Dave, N. H. Patadiya, A. R. Prajapati, and S. R. Rajpurohit, “Effect of Infill Pattern and Infill Density at Varying Part Orientation on Tensile Properties of Fused Deposition Modeling-Printed Poly-Lactic Acid Part,” Proc. Inst. Mec. Eng., Part C: J. Mec. Eng. Sci.,vol. 235, no. 10, pp. 1811-1827, 2019.

6. Z. S. Suzen, Hasdiansah, and Yuliyanto, “Pengaruh Tipe Infill Dan Temperatur Nozzle Terhadap Kekuatan Tarik Produk 3D Printing Filamen Pla+ Esun,” Manutech: Jurnal Teknologi Manufaktur, vol. 12, no. 2, pp 73-80, 2020. (in Indonesian).

7. A. Ilham, A. Arafat, Rifelino, and H. Nurdin, “Pengaruh Nozzle Temperature dan Layer Height Hasil 3D Printing Terhadap Uji Bending Materiai ABS,” Vomek Jurnal Vokasi Mekanika, vol. 4, no. 1, pp 144-150, 2022. (in Indonesian).

8. ASTM, ASTM D638-14: Standard Test Method For Tensile Properties Of Plastics 1, Pennsylvania: ASTM International, 2015.

9. F. S. Ardion, H. Sukanto, and J. Triyono, “Analisis Pengaruh Infill Overlap Terhadap Karakteristik Produk Hasil 3D Printing Dengan Menggunakan Material Poly Lactic Acid (PLA),” MekanikaMajalah Ilmiah Mekanika, vol. 18, no. 2, pp. 55-58, 2019. (in Indonesian).

10. ASTM, ASTM D790: Standard Test Method For Flexural Properties Of Plastics 1, Pennsylvania: ASTM International, 2015.