If in the case of the routine design of equipment or manufacturing technology, there is not necessary to identify and apply improvements of equipment or manufacturing technology, when applying the creative design, improved solutions must be found at least for some of the designed objects. Different methods could be applied to identify the ways of improving the object of the design activities, and the theory of solving the creative problems is a useful tool that can be used to solve such problems. Some of the principles of the theory of solving creative problems were applied in the cases of identifying innovative solutions for the components of experimental equipment developed in doctoral research. Thus, the way of defining the main contradiction, of using elements from the operational zone or from the oversystem, and the informational fund in the cases of some equipment for manufacturing or of different process scientific investigation was approached. The use of TRIZ facilitated the identification of improved ways of solving the problems of doctoral research interest.

Sakae, Y., Kato T., Sato, K., Matsuoka, Y., Classification of design methods from the viewpoint of design science, Proceedings of the Design. International Design Confer-ence 14, 493-502 (2016).

Braha, D. and Maimon, O., The design process: Properties, paradigms, and structure, IEEE Transactions on Systems, Man, and Cybernetics-Part A: Systems and Humans 27, 146–166

Ilevbare, M., I., Probert, D., Phaal, R., A review of TRIZ, and its benefits and challeng-es in practice, Technovation 33, 30–37 (2013).

Chechurin, L., Borgianni, Y., Understanding TRIZ through the review of top-cited publications, Computers in Industry 82, 119–134 (2016).

Borgianni, Y. and Matt, T., D., Applications of TRIZ and Axiomatic Design: a compari-son to deduce best practices in industry, Procedia CIRP 39, 91 – 96 (2015).

Jani, H., M., Teaching TRIZ problem-solving methodology in higher education: a review, International Journal of Science and Research (IJSR) 2, 98-103 (2013).

Huang, C., C., Tsai, M., C., Dorrell, D., G., Lin, B. J., Development of a magnetic plan-etary gearbox, IEEE Transactions on Magnetics 44 (3), 403-412 (2008).

Domb, E., Contradictions: Air Bag Applications. The TRIZ Journal, https://triz-journal.com/contradictions-air-bag-applications/

Bang, A., L., Krogh, P., G., Ludvigsen, M., Markussen, T., The role of hypothesis in constructive design research, The Art of Research 4 (2012).

Simon, H., A, The sciences of the artificial, 3rd ed. MIT Press, Cambridge (1996).

Ullman G., D., The Mechanical Design Process, 4th ed. McGraw-Hill, New York (2010) .

Slătineanu, L.: Bazele cercetării științifice, Editura PIM, Iași (2019).

Tomiyama T., A Classification of Design Theories and Methodologies, 18th International Conference on Design Theory and Methodology on Proceedings of the ASME 2006 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference, pp. 43-51. Philadelphia, Pennsylvania (2006).

ISO/ASTM 52900: 2015. Additive manufacturing - General principles – Terminology.

ASTM F2792-12A: 2015. Standard Terminology for Additive Manufacturing Technologies.

Proiectare - definiție și paradigmă, https://dexonline.ro/definitie/proiectare.

Design, https://en.wikipedia.org/wiki/Design.

Price, R., Functional Design: Definition, Process & Example, study.com/academy/lesson/functional-design-definition-process-example.html.

Moya, J., L., Machado, A., S., Robaina, R., Velázquez, J., A., Mestizo, R., Cárdenas, J., A., Goytisolo, R., A., Applications of TRIZ principles to spur gear design,

https://www.researchgate.net/publication/282253583_application_of_triz_principles_to_spur_gear_design.

Filament für standard-drucker, https://3dk.berlin/de/3dktop-hitzebestandig/199-3dktop-grau-hitzebestandig-bis-230c.html.