Optimization of Organizational Structures for Efficient Implementation of Construction Projects of Complex Engineering Objects

The article evaluates the influence of organizational operating structures on the efficiency of construction projects and their optimization taking into account the specifics of construction processes.

Purpose: Determination of the influence of various types of organizational operating structures on construction project implementation and development of approaches to their optimization.

Methodology/approach: The analysis of factors that determine the construction work during organizing processes and distributing responsibilities. For the data collection, a questionnaire method is used using the Likert scale. The multiple regression analysis, correlation analysis and the Friedman test are used for the data processing.

Research findings: Factors influencing the efficiency of construction projects are identified, systematized and ranked. It is shown that qualifications of specialists and optimization of organizational and production structures have a key impact on achieving the project goals.

Value: The implementation of personnel development systems is required as well as the application of management principles by objectives to improve the efficiency of construction projects.

1. Borisyuk N.K., Smotrina O.S. On Enterprise Functioning in Unstable External Environment. Intellekt. Innovatsii. Investitsii. 2022; (2): 24–30. DOI: 10.25198/2077-7175-2022-2-24. EDN: XLJDGS (In Russian)

2. Dyachkova O.N., Mikhailov A.E., Yakunina G.V. Experience in Assessing the Attractiveness of District Parks in Saint-Petersburg. Sotsiologiya goroda. 2022; (3): 49–63. DOI: 10.35211/19943520_2022_3_49 (In Russian)

3. Zelentsov L.B. Implementation of Construction Projects with Changing Functional Purpose. Stroitel'noe proizvodstvo. 2021; (2): 26–32. DOI: 10.54950/26585340_2021_2_26. EDN: BZKXLZ (In Russian)

4. Zelentsov L.B., Tsapko K.A., Belikova I.F., Pirko D.V. Modern Methods for Assessing the Organizational and Technological Reliability of Investment and Construction Complex. Inzhenernyi vestnik Dona. 2020; 9. Available: www.ivdon.ru/ru/magazine/archive/n9y2020/6602 (accessed April 28, 2023). (In Russian)

5. Lebedev V.M. Organizational and Technological Reliability of Construction Management Systems. Vestnik MGSU. 2008; (4): 191–194. Available: https://cyberleninka.ru/article/n/organizatsionno-tehnologicheskaya-nadezhnost-upravlyayuschih-sistem-stroitelstva-1 (accessed April 28, 2023). (In Russian)

6. Rodin D.A. Accounting for Uncertainty and Risk Factors in Investment Project Evaluation. Izvestiya vysshikh uchebnykh zavedenii. Problemy poligrafii i izdatel'skogo dela. 2022; (3–4): 19–25. EDN: TJRDTU (In Russian)

7. Safaryan G.B. Critical Analysis of Generalized Model of Construction System. Stroitel'stvo: nauka i obrazovanie. 2021; 11 (4): 41–47. DOI: 10.22227/2305-5502.2021.4.4. EDN: PFGTCK (In Russian)

8. Tsopa N.V., Khalilov A.E. Resource Provision for Investment and Construction Projects. Ehkonomika stroitel'stva i prirodopol'zovaniya. 2022; 1–2 (82–83). 23-30. EDN: KOSHPG (In Russian)

9. Beskopylny A.N., Stel’makh S.A., Shcherban’ E.M., Mailyan L.R., Meskhi B.C., El’shaeva D., Varavka V. Developing Environmentally Sustainable and Cost-effective Geopolymer Concrete with Improved Characteristics. Sustainability. 2021; (13): 13607. DOI: 10.3390/su132413607

10. Chen Yi, Zhu D., Tian Z., Guo Q. Factors Influencing Construction Time Performance of Prefabricated House Building: A Multi-Case Study. Habitat International. 2023; 131. DOI: 10.1016/j.habitatint.2022.102731

11. Díaz-López C., Serrano-Jiménez A., Verichev K., Barrios-Padura A. Passive Cooling Strategies to Optimize Sustainability and Environmental Ergonomics in Mediterranean Schools Based on a Critical Review. Building and Environment. 2022; 221. DOI: 10.1016/j.buildenv.2022.109297

12. Falah Al-Alrubaie. The Identity of the Economic System in Iraq Between the Rentier State and the Developmental State. Future Journal of Pharmaceutical Sciences. 2021; 484 (2019): 12–38.

13. Huang X. A Decision-Making Model for Optimizing Project Performance in Construction. International Journal of Project Management. 2018. DOI: 10.1016/j.ijproman.2017.08.005

14. Krichevsky M., Martynova J., Dmitrieva S. Use of Neural Networks to Assess Competitiveness of Organizations. In: Proc. Int. Sci. Conf. ‘Energy Management of Municipal Facilities and Sustainable Energy Technologies’. 2019. Pp. 72–82. DOI: 10.1007/978-3-030-57453-6_8

15. O’Neill C., Gopaldasani V., Coman R. Factors that Influence the Effective Use of Safe Work Method Statements for High-Risk Construction Work in Australia – A Literature Review. Safety Science. 2022; 147. DOI: 10.1016/j.ssci.2021.105628

16. Oparina L.A. Application of Information Modelling Technologies for Construction Time Management. Smart Composite in Construction. 2021; 2 (2): 48–55. DOI: 10.52957/ 27821919_2021_2_48

17. Sarvari H., Chan D.W.M., Alaeos A.K.F., Olawumi T.O., Aldaud A.A.A. Critical Success Factors for Managing Construction Small and Medium-Sized Enterprises in Developing Countries of the Middle East: Evidence from Iranian Construction Enterprises. Journal of Building Engineering. 2021; 43. DOI: 10.1016/j.jobe.2021.103152

18. Vivek A., Rao H. Identification and Analysis of Risk Factors Affecting Cost of Construction Projects. In: Proc. Int. Conf. on Latest Developments in Materials and Manufacturing. 2022; 60, Part 3, 1696–1701. DOI: 10.1016/j.matpr.2021.12.228

19. Velichkin V.Z., Petrochenko M.V., Strelets K.I., Zavodnova E.B., Gorodishenina A.Yu. The Branch and Bound Method Applied to the Construction of Residential Quarters. Vestnik MGSU. 2021; 16 (1): 91–104. DOI: 10.22227/1997-0935.2021.1.91-104 (In Russian)

20. Yilmaz S., Irmak M.A., Qaid A. Assessing the Effects of Different Urban Landscapes and Built Environment Patterns on Thermal Comfort and Air Pollution in Erzurum City, Turkey. Building and Environment. 2022; 219. DOI: 10.1016/j.buildenv.2022.109210.