: 3D printing technology has proven to be an emerging one of real utility, supporting the realization of manufacturing processes in different industries. Including the field of engineering education, it has enjoyed investments and the development of laboratories, Makerspaces, or FabLabs that are equipped with 3D printing printers. The way they work, their exploitation has created an interesting and very attractive world for the training of engineers who have been challenged not only to imagine but also to create artifacts. This approach is successfully implemented in most technical, polytechnic universities because the learning experience created is particularly efficient and effective (develops imagination and creativity through 3D CAD drawings and artifacts). This research analyses the situation of learning, education in the field of 3D printing in universities and beyond (other training providers). Finally, the case of implementation of the INNO3D project (2019-1-IE203-000693INNO3D) at the Politehnica University of Timisoara, Romania, is presented, which led to the diversification of the services offered to users of the Central University Library. The final conclusions focus on the main advantages of the 3D printing education for engineers and brief presentation of the Timisoara new Makerspace at the Central Library Politehnica University of Timisoara (Romania) that has been co-financed by the “3D Printing Support Service for Innovative Citizens”- INNO3D project.

Ford, S., Minshall, T., Invited review article: Where and how 3D printing is used in teaching and education. Additive Manufacturing, 25, 131-150, (2019).

Pizzolato, N., Limongelli, M., Di Francesca, A., Kirkar, M., Koch, V., Gomez, V. G., ... Silva, R. P., The “E3D+ VET” Erasmus+ project: Interdisciplinary teaching and learning in VET centres through 3D printing. In Journal of Physics: Conference Series, 1512(1), p. 012038. IOP Publishing, (2020, April).

Szulzyk-Cieplak, J., Duda, A., Sidor, B., 3D printers–new possibilities in education, Advances in Science and Technology Research Journal, 8(24), 96-101, (2014).

Huleihil, M., 3D printing technology as innovative tool for math and geometry teaching applications. In IOP Conference Series: Materials Science and Engineering (Vol. 164, No. 1, p. 012023). IOP Publishing, (2017, January).

Wohlers, T., Caffrey, T., Campbell, R. I., Diegel, O., Kowen, J., Wohlers Report 2019: 3D Printing and Additive Manufacturing State of the Industry; Annual Worldwide Progress Report. Wohlers Associates, (2018).

Marschall, H., Personal für die additive Fertigung. Kompetenzen, Berufe, Ausund Weiterbildung, Sringer Fachmedien Wiesbaden, (2016).

Bagley, J. R., Galpin, A. J., Three‐dimensional printing of human skeletal muscle cells: An interdisciplinary approach for studying biological systems. Biochemistry and Molecular Biology Education, 43(6), pp. 403-407), (2015).

McGahern, P., Bosch, F., Poli, D., Enhancing learning using 3D printing: An alternative to traditional student project methods. The American Biology Teacher, 77(5), 376-377. (2015).

Hall, S., Grant, G., Arora, D., Karaksha, A., McFarland, A., Lohning, A., Anoopkumar-Dukie, S., A pilot study assessing the value of 3D printed molecular modelling tools for pharmacy student education. Currents in Pharmacy Teaching and Learning, 9(4), 723-728., (2017).

Golub, M., Guo, X., Jung, M., Zhang, J., 3D printed ABS and carbon fiber reinforced polymer specimens for engineering education. In REWAS 2016 (pp. 281-285). Nashvilee, USA: Springer, Cham (2016).

Romero, M., Lille, B., Intergenerational techno-creative activities in a library FabLab. International Conference on Human Aspects of IT for the Aged Population (pp. 526-536). Springer, Cham, (2017, July).

Fab Lab Network: https://fabfoundation.org/global-community/

Motyl, B., Filippi, S., Trends in engineering education for additive manufacturing in the industry 4.0 era: a systematic literature review. International Journal on Interactive Design and Manufacturing (IJIDeM), 1-4, (2020).

D printing Media Network There Are 800 3D Printers in Libraries Worldwide (and There Could Be a Lot More) (2017). Retrieved from: https://www.3dprintingmedia.network/800-registered-3d-printers-in-libraries/ (Access 20-09-2021)

INNO3D project homepage: https://www.inno3d.eu/ (Access 28-09-2021)

Lyon, L. Librarians in the lab: Toward radically re-engineering data curation services at the research coalface. New Review of Academic Librarianship, 22(4), 391-409, (2016).

Koltay, T., Accepted and emerging roles of academic libraries in supporting research 2.0. The Journal of Academic Librarianship, 45(2), 75-80, (2019).

Junk, S., Matt, R., Workshop Rapid Prototyping - A new approach to introduce digital manufacturing in engineering education. In 2015 International Conference on Information Technology Based Higher Education and Training (ITHET) (pp. 1-6). IEEE, (2015a).

Junk, S., Matt, R., New approach to introduction of 3D digital technologies in design education. Procedia CIRP, 36, 35-40, (2015b).

Go, J., Hart, A. J., A framework for teaching the fundamentals of additive manufacturing and enabling rapid innovation. Additive Manufacturing, 10, 76-87, (2016).

Ullah, A. M. M., Kubo, A., Harib, K. H., Tutorials for integrating 3D printing in engineering curricula. Education sciences, 10(8), 194, (2020).

Liou, F. W., Ming, L. C., Landers, R. G., Interactions of an additive manufacturing program with society. In 23rd Annul. Int. Solid Free. Fabr. Symp., Laboratory for Freeform Fabrication and University of Texas at Austin, Austin, USA (pp. 45-61), (2012, August).