[1] Liaw C.Y., Guvendiren M.:
Current and emerging applications of 3D printing in medicine. Biofabrication 9(2017), 2, 024102.
[2] Tejo-Otero A., Buj-Corral I., Fenollosa-Artés F.:
3D printing in medicine for preoperative surgical planning: A review. Ann. Biomed. Eng. 48(2020), 2, 536– 555.
[3] Christensen A., Rybicki F.J.:
Maintaining safety and efficacy for 3D printing in medicine. J. 3D Print. Med. 3(2017), 1–10.
[4] Kumar L.J., Nair C.K.:
Current trends of additive manufacturing in the aerospace industry. In: Advances in 3D Printing and Additive Manufacturing Technologies (L.J. Kumar, D.I. Wimpenny, P.M. Pandey, Eds.) Springer, Singapore 2017, 39–54.
[5] Lee H., Jang Y., Choe J. K., Lee S., Song H., Lee J. P., Kim J.:
3D-printed programmable tensegrity for soft robotics. Sci. Robotics 5(2020), 45, eaay9024.
[6] Andrearczyk A., Baginski P., Klonowicz P.:
Numerical and experimental investigations of a turbocharger with a compressor wheel made of additively manufactured plastic. Int. J. Mech. Sci. 178(2020), 105613.
[7] Kariz M., Sernek M., Obucina M., Kuzman M.K.:
Effect of wood content in FDM filament on properties of 3D printed parts. Mater. Today Commun. 14(2018), 135–140.
[8] Andrearczyk A, Konieczny B, Sokołowski J.:
Additively Manufactured Parts Made of a Polymer Material Used for the Experimental Verification of a Component of a High-Speed Machine with an Optimised Geometry – Preliminary Research. Polymers 13(2021), 1, 137.
[9] Cantrell J.T., Rohde S., Damiani D., Gurnani R., DiSandro L., Anton J., Ifju P.G.:
Experimental characterization of the mechanical properties of 3D-printed ABS and polycarbonate parts. Rapid Prototyping J. 2017.
[10] Bassett K., Carriveau R., Ting D.K.:
3D printed wind turbines part 1: Design considerations and rapid manufacture potential. Sustainable Energy Technologies and Assessments 11(2015), 186–193.
[11] Constantinou P., Roy S.:
A 3D printed electromagnetic nonlinear vibration energy harvester. Smart Mater. Struct. 25(2016), 9, 095053.
[12] Zhang X., Zhou H., Shi W., Zeng F., Zeng H., Chen G.:
Vibration tests of 3D printed satellite structure made of lattice sandwich panels. AIAA J. 56(2018), 10, 1–5.
[13] Zeppei D., Koch S., Rohi A.:
Ball bearing technology for passenger car turbochargers. MTZ worldwide 77(2016), 26–31.
[14] Idzior M., Karpiuk W., Bielinski M., Borowczyk T., Daszkiewicz P., Stobnicki P.:
A concept of a turbocharger test stand. Combust. Engines 156(2014), 1, 30–40.
[15] Andrearczyk A., Baginski P., Zywica G.:
Test stand for the experimental investigation of turbochargers with 3d printed components. Mechanics and Mechanical Engineering 22(2020), 2, 397–404.
[16] Andrearczyk A., Mieloszyk M., Baginski P.:
Destructive tests of an additively manufactured compressor wheel performed at high rotational speeds. In: Proc. Int. Conf. Applied Human Factors and Ergonomics. Springer, Cham 2020, 117–123.
[17] Wisniewski P.P., Dykas, S., Zhang G.:
Numerical studies of air humidity importance in the first stage rotor of turbine compressor. Arch. Thermodyn. 41(2020), 4, 223–234.
[18] MarSurf PS1,
https://metrology.mahr.com/de/produkte/artikel/6910235-mobilesrauheitsmessgeraet- marsurf-ps-10-c2 [19] LabView software,
https://www.ni.com/pl-pl/shop/labview.html [20] TMD20,
https://www.czaki.pl/produkt/przetwornik-pomiarowy-tmd-20-modbusrtu- rs-485-programowalny/ [21] Optel Thevon,
https://www.optel-texys.com/en/152-g6-gpk-1-152.html [22] Flowmeter EE741,
https://www.epluse.com/en/products/flow-meter/flow-meterindustrial/ ee741/ [23] Peltron NPX pressure transducer,
https://peltron.pl/produkty/przetwornikcisnienia- npx/