№83-23
Criteria and algorithm of operation of the systemically integrated model of optimization of modern energy-efficient construction
D. Halushko1 https://orcid.org/0009-0008-9451-9343
1Zaporizhzhia National University, Zaporizhzhia, Ukraine
Coll.res.pap.nat.min.univ. 2025, 83:256–268
Full text (PDF)
https://doi.org/10.33271/crpnmu/83.256
ABSTRACT
Purpose. The study aims to determine the efficiency parameters of a system-integrated organizational and technological model of energy-efficient construction through the identification of optimal technological solutions, focusing on the interaction of organizational, technological, and energy processes and the criteria that define adaptability, technological stability, and overall energy efficiency.
Methodology. The assessment is based on an integrated analysis of model parameters using multi-criteria optimization, systems analysis, mathematical modeling, and algorithmic tools for energy-efficient process management. The proposed methodology combines principles of energy saving, resource optimization, and technological reliability, enabling a comprehensive evaluation of the model’s performance and operational behavior.
Results. The obtained indicators reflect the model’s efficiency, the degree of technological integration, and the level of energy consumption optimization within construction processes. The quantitative system of parameters allows for an objective evaluation of the organizational-technological model and supports the identification of pathways for enhancing energy performance.
Scientific novelty. The research establishes correlations between the model’s structure, its energy parameters, and the applied optimization algorithms, contributing to the formalization of system-integrated approaches in construction. The findings extend existing scientific concepts related to the design of energy-efficient buildings and form a basis for further investigation of integrated organizational-technological systems.
Practical significance. The results may be applied to improve construction management, develop energy-efficient technological schemes, design resource-saving systems, and implement automated algorithmic solutions. Their practical use contributes to increasing the efficiency and sustainability of modern building systems and supports the rational use of energy resources.
Keywords: system-integrated model, optimization, energy-efficient construction, algorithm, technological solutions, efficiency criteria, organizational and technological systems.
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date of first submission of the article to the publication – 10/03/2025
date of acceptance of the article for publication after review – 11/07/2025
date of publication – 12/29/2025