Quality management of production processes of engineering products in the network

Statement of the problem (relevance of the work): the article outlines the main advantages of using the network to improve the quality of the production processes of engineering products, which is especially important in the context of the formation of technological sovereignty. The purpose of the work: the purpose of the article is to systematize and analyze the models of product quality management in the engineering industry and develop, on their basis, an intersectoral model of a quality management system in a network.
Methods used: the article uses general scientific methods of cognition, namely, the method of description, generalization, critical analysis, visualization. As a theoretical basis for the study, theories of process and network management in the industrial complex are used.
Novelty: generalization and systematization of theoretical approaches to quality management in mechanical engineering made it possible to design an intersectoral model of a quality management system in a network, the use of which will make it possible to create and strengthen technological sovereignty.
Result: as a result of a study on the analysis of quality management models of the production process, their distinctive characteristics are determined in relation to the network, the core of which is a machine-building enterprise, which made it possible to develop an intersectoral model of a quality management system, the use of which allows obtaining such network effects as the achievement of integrated production support at all stages of the life cycle; reducing transaction costs, increasing the flexibility of the design and production of new science-intensive and high-tech products, which makes it possible to increase the level of technological sovereignty of the industry by strengthening cooperation ties.
Practical significance: the conclusions and results contained in the article can be used in the development of strategies for the formation and strengthening of technological sovereignty both in the machine-building industry and in the industrial complex as a whole.

1. GOST R ISO 9001-2015. Sistemy Menedzhmenta Kachestva. Trebovaniya. [Quality Management Systems. Requirements]. Moscow, 2015. 23 p. (In Russ.).

2. Koroleva M. A. Sistema menedzhmenta kachestva kak osnova ustoychivogo razvitiya [Quality management system as the basis of sustainable development] // Gazovaya Promyshlennost’. GAS Industry of Russia. 2021. No. 2 (812). P. 117. EDN: BNTAHW. (In Russ.).

3. Mamonov V. I., Poluektov V. A., Yakutin E. M. Nekotoryye aspekty kontseptsii bystroreagiruyushchego proizvodstva [Some elements of quick response manufacturing conception] // Sibirskaya Finansovaya Shkola. Sibirskaya Finansovaya Shkola. 2014. No. 5 (106). P. 49–52. EDN: SZSKXZ. (In Russ.).

4. Merkulov A. S., Nikolenko S. D., Sazonov S. A. Modelirovaniye protsessov, vliyayushchikh na kachestvo betonnykh pokrytiy dorog [Modeling of processes affecting the quality of concrete road surfaces] // Modelirovaniye Sistem i Protsessov. Modeling of Systems and Processes. 2021. Vol. 14, no. 1. P. 38–44. DOI: 10.12737/2219-0767-2021-14-1-38-44. EDN: EWOPLA. (In Russ.).

5. Ponomareva M. A. Sistema menedzhmenta kachestva na predpriyatii — effektivnoye upravleniye zatratami [Quality management system at the enterprise — effective cost management] // Samoupravleniye. Samoupravlenie. 2020. No. 3 (120). P. 353–357. EDN: IJCCYH. (In Russ.).

6. Popova D. D., Popov D. A., Samoylenko N. A. Issledovaniye vliyaniya parametrov setochnoy modeli i modeli turbulentnosti na kachestvo modelirovaniya aerodinamicheskikh protsessov v oblasti radial’nogo zazora rabochikh lopatok turbiny [Investigation of the grid model and turbulence model parameters influence on quality of turbine rotor blade tip clearance area aerodynamic processes modeling] // Vestnik Permskogo Natsional’nogo Issledovatel’skogo Politekhnicheskogo Universiteta. Aerokosmicheskaya Tekhnika. Bulletin of Perm State Technical University. Aerospace Engineering. 2021. No. 66. P. 67–78. DOI: 10.15593/2224-9982/2021.66.07. EDN: WZFDIT. (In Russ.).

7. Solov’yeva I. P., Asayeva T. A., Ignat’yev A. I. Organizatsionnyye osnovy optimizatsii zatrat promyshlennykh predpriyatiy [Organizational basis for cost optimization of industrial enterprises] // Ekonomika i upravleniye v Mashinostroyenii. Ekonomika i Upravlenie v Mashinostroenii. 2012. No. 3. P. 47–50. EDN: PWBJLV. (In Russ.).

8. Kudryavtseva S. S., Shinkevich M. V. Otsenka effektivnosti resursosberegayushchikh tekhnologiy v mashinostroitel’noy promyshlennosti [Evaluation of effectiveness of resource-saving technologies in machine-building industry] // Omskiy Nauchnyy Vestnik. Omsk Scientific Bulletin. 2020. No. 3 (171). P. 14–20. DOI: 10.25206/1813-8225-2020-171-14-20. EDN: ZPXSER. (In Russ.).

9. Krasnova O. M., Kudryavtseva S. S. Transportnyy kompleks v ekonomike Respubliki Tatarstan [Transport complex in economy in the Republic of Tatarstan] // Ekonomicheskiy Vestnik Respubliki Tatarstan. Economic Bulletin of the Republic of Tatarstan. 2014. No. 1. P. 27–37. EDN: RYIJDX. (In Russ.).

10. Shinkevich A. I., Barsegyan N. V. Puti povysheniya effektivnosti organizatsii proizvodstvennykh protsessov na neftekhimicheskikh predpriyatiyakh za schet primeneniya sistem avtomatizatsii [Ways to improve the organization of production processes in the petrochemical industry through the application of automation systems] // Russkiy Inzhener. Russian Engineer. 2019. No. 4 (65). P. 48–51. EDN: BXIVBC. (In Russ.).