Investigation of the strength property of 3D printed products in bending deformation to optimize material distribution

The article considers a method of optimal material distribution inside a 3D printed sample. Several variants of material distribution are considered, including the beam shape of equal resistance while retaining the outer frame of the specimen as a rectangular parallelepiped with a square cross-section. The manufactured samples are subjected to destruction during static bending testing. The results show the reduction of used material by 30 % and preservation of specimen strength properties with 100 % material filling. Moreover, experimental results are presented and research issues for further investigations are highlighted.

1. Ozerov A. Topologicheskaya optimizatsiya i 3D-pechat′ kak primer vzaimnogo razvitiya. QIB Tehnologies [Topological optimization and 3D-printing as examples of cross-development]. URL: https://blog.iqb.ru/topology-optimization-3d-printing/ (accessed: 07.07.2024). (In Russ.).

2. Antsiferov S. I., Karachevtseva A. V., Sychev E. A., Litvishko A. A. Topologicheskaya optimizatsiya elementov konstruktsii robotizirovannoy yacheyki [Topological optimization of design elements of a robotic cell]. Vestnik Belgorodskogo gosudarstvennogo tekhnologicheskogo universiteta im. V. G. Shukhova. Bulletin of Belgorod State Technological University Named after V. G. Shukhov. 2023. No. 11. P. 93–102. DOI: 10.34031/2071-7318-2023-8-11-93-102. EDN: FODJWS. (In Russ.).

3. Russkikh G. S., Shalygin S. V. Algoritm formirovaniya vnutrenney struktury izdeliya s uchetom napryazhennodeformirovannogo sostoyaniya na primere trekhtochechnogo izgiba [The algorithm for generating internal structure of product considering stress-strain on example three-point bending]. Omskiy nauchnyy vestnik. Seriya Aviatsionno-raketnoye i energeticheskoye mashinostroyeniye. Omsk Scientific Bulletin. Series Aviation-Rocket and Power Engineering. 2021. Vol. 5, no. 1. P. 80–85. DOI: 10.25206/2588-0373-2021-5-1-80-85. EDN: TXWRGA. (In Russ.).

4. Kondratov S. V., Pykhtin A. A., Larionov S. A., Sorokin A. E. Vliyaniye tekhnologicheskikh rezhimov FDM-pechati i sostava ispol′zuyemykh materialov na fiziko-mekhanicheskiye kharakteristiki FDM-modeley (obzor) [Influence of the technological FDM-modes of the press and structure of used materials on physic-mechanical characteristics of FDM-models (review)]. Trudy VIAM. Proceedings of VIAM. 2019. No. 10 (82). P. 34–49. DOI: 10.18577/2307-6046-2019-0-10-34-49. EDN: RARUXZ. (In Russ.).

5. Shimokhin A. V., Soyunov A. S., Bitkina E. E., Yankovskiy K. A. K voprosu o primenenii additivnoy tekhnologii na predpriyatiyakh sel′skokhozyaystvennogo mashinostroyeniya [On applicability of additive technology at agricultural engineering enterprises]. Traktory i sel′khozmashiny. Tractors and Agricultural Machinery. 2022. Vol. 89, no. 5. P. 357–365. DOI: 10.17816/0321-4443-111103. EDN: KPBBLF. (In Russ.).

6. Petrova G. N., Platonov M. M., Bol′shakov V. A. [et al.]. Issledovaniye kompleksa kharakteristik bazovykh materialov dlya FDM-tekhnologii additivnogo sinteza. Fiziko-mekhanicheskiye i teplofizicheskiye svoystva [Research of the complex of characteristics of base materials for fdm of technology of the additive synthesis. physico-mechanical and heat-physical properties]. Plasticheskiye massy. Plasticheskie Massy. 2016. No. 5–6. P. 53–58. EDN: WIOBNL. (In Russ.).

7. Kovalenko R. V. Sovremennyye polimernyye materialy i tekhnologii 3D pechati [Modern polymer materials and 3D printing technologies]. Vestnik Tekhnologicheskogo universiteta. Herald of Technological University. 2015. Vol. 18, no. 1. P. 263–266. EDN: TJKZCT. (In Russ.).

8. Kichko A. E. Analiz sovremennykh materialov dlya 3D-pechati [Analysis of modern 3D printing materials]. 72-ya Mezhdunar. stud. nauch. tekhn. konf. Astrakhan’, 2022. P. 758–760. EDN: SRYIOG. (In Russ.).

9. GOST 4648-2014 (ISO 178:2010). Plastmassy. Metod ispytaniya na staticheskiy izgib [Plastics. Method of static bending test]. Moscow, 2016. 20 p. (In Russ.).

10. Bogdanov V. V., Ivanov R. V. K voprosu ispol′zovaniya balok ravnogo soprotivleniya izgibu s peremennym poperechnym secheniyem [To the question of use of equal bending resistance beams with variable cross-sections]. Aktual’nyye problemy nauki i obrazovaniya v usloviyakh sovremennykh vyzovov. Moscow, 2022. P. 228–234. (In Russ.).

11. Kuzubov A. S., Bushuev D. A., Parashchuk E. M. Postroyeniye i validatsiya konechno-elementnoy virtual’noy modeli balki ravnogo soprotivleniya vesoizmeritel’noy sistemy [Construction and validation of the finite element virtual model of the beam of equal resistance of the weight measuring system]. Nauchnyye vedomosti Belgorodskogo gosudarstvennogo universiteta. Seriya: Ekonomika. Informatika. Belgorod State University. Scientific Bulletin. Series: Economics. Information Technologies. 2019. Vol. 46, no. 2. P. 274–282. DOI: 10.18413/2411-3808-2019-46-2-274-282. EDN: JPWOJO. (In Russ.).