COMPREHENSIVE RECONSTRUCTION OF DESTROYED FRAMELESS BUILDINGS USING ENVIRONMENTAL TECHNOLOGIES
DOI:
https://doi.org/10.32782/mathematical-modelling/2025-8-2-14Keywords:
comprehensive reconstruction, destroyed buildings, frameless structures, environmental technologies, sustainable development in construction, energy efficiency, green construction, restoration of infrastructure around dam- aged buildingsAbstract
In the new socio-economic conditions, the main form of development of industrial production is reconstruction. The main task today is to increase the technical level, quality, introduce energy-saving and resource-saving technologies, using the existing industrial potential of the country. The article presents the results of the comprehensive reconstruction of destroyed frameless buildings and the integration of existing cultural and historical heritage sites into the modern urban environment. The results of the analysis and prospects for the application of building information modeling (BIM) and environmental technologies for the selection of effective organizational, technological and technical solutions in the elimination of emergency destruction of frameless buildings as a result of military operations are presented. It has been established that photogrammetry is a relatively inexpensive and practically universal method for creating three-dimensional models of architectural objects and their measurement plans. Modern images were obtained by combining both images taken by a drone and ground-based external facades and interiors. The optimal option for emergency stabiliza- tion, as well as organizational, technological and technical measures that must be urgently taken to prevent the death of people or the collapse of large-panel buildings after massive damage due to shelling and other military actions. Modern environmental technologies will allow for the reconstruction of destroyed frameless structures quite quickly. In the post-war period, the use of the presented methodology will allow for a prompt assessment of the technical condition of buildings and the selection of a stabilization strategy, including the frequency of monitoring the need and timing of repairs.
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