Modern approaches to assessing the technical condition of building structures at the operational stage

N. V. Knyazeva; Князева Н. В.; E. A. Nazojkin; Назойкин Е. А.; A. A. Orekhov; Орехов А. А.

doi:10.22227/2305-5502.2024.3.131-142

Modern approaches to assessing the technical condition of building structures at the operational stage

Autores: Knyazeva N.V.¹, Nazojkin E.A.², Orekhov A.A.²
Afiliações:
1. Moscow State University of Civil Engineering (National ResearchUniversity) (MGSU)
2. Russian Biotechnological University (BIOTECH University)
Edição: Volume 14, Nº 3 (2024)
Páginas: 131-142
Seção: Engineering systems. Exploitation of buildings. Problems of Housing and Communal Complex. Energy efficiency and energy saving. Safety of buildings and structures. Ecology
URL: https://journals.rcsi.science/2305-5502/article/view/276580
DOI: https://doi.org/10.22227/2305-5502.2024.3.131-142
ID: 276580

Citar

Texto integral

Resumo
Sobre autores
Bibliografia
Arquivos suplementares
Estatísticas

Resumo

Introduction. The paper is devoted to the development of approaches to the construction of an automated assessment system for the technical condition of building structures using defect detection mechanisms and preliminary assessment of the physical deterioration of buildings based on artificial intelligence methods. Modern construction objects are characterized by high complexity and scale, which requires special attention to the quality and reliability of structures. Traditional methods of technical maintenance do not always show their effectiveness due to the influence of human factors. Currently, the primary method of defects detention remains visual inspection, which, although it allows to assess the condition of objects, depends on the level of qualification and attentiveness of the evaluator. This creates risks of error, which can threaten the safety of buildings and lead to incorrect decisions regarding repairs and maintenance. The aim of the research is to analyze the required functionality and modelling of an automated system capable of quickly and accurately identifying potential defects in building structures and assessing likely physical deterioration.Materials and methods. The comprehensive approach includes two main components: a system for analyzing accumulated data on the physical deterioration of residential properties and a defect detection mechanism based on image analysis using artificial intelligence. The main input data for analysis are the results of photographic documentation of the building condition, as well as the volume of accumulated observations and data on the physical deterioration of the housing stock over a long period of observation.Results. The libraries and tools necessary for the implementation of this system are described in detail, including popular frameworks for machine learning and image processing.Conclusions. Modern approaches based on the application of artificial intelligence and machine learning methods open new horizons in the detection of defects and forecasting the technical condition of buildings. They significantly increase the speed and accuracy of analysis.

Palavras-chave

defect detection, physical deterioration assessment, maintenance, photofixation, building operation, artificial intelligence

Bibliografia

Adewale B.A., Ene V.O., Ogunbayo B.F., Aigbavboa C.O. A Systematic Review of the Applications of AI in a Sustainable Building’s Lifecycle // Buildings. 2024. Vol. 14. Issue 7. P. 2137. doi: 10.3390/buildings14072137
Mishra A., Pareek R.K., Kumar S., Varalakshmi S. A review of the current and future developments of artificial intelligence in the management and building sectors // Multidisciplinary Reviews. 2024. Vol. 6. P. 2023ss068. doi: 10.31893/multirev.2023ss068
Сулейманова Л.А., Обайди А.А. Управление жизненным циклом здания на этапе эксплуатации с использованием моделей искусственных нейронных сетей и машинного обучения // Вестник Белгородского государственного технологического университета им. В.Г. Шухова. 2024. № 3. С. 38–46. doi: 10.34031/2071-7318-2024-9-3-38-46. EDN DHJYVT.
Jaufer L., Kader S., Spalevic V., Škatarić G., Dudić B. Machine learning practices during the operational phase of buildings : a critical review // Applied Engineering Letters. 2024. Vol. 9. Issue 1. Pp. 37–45. doi: 10.46793/aeletters.2024.9.1.4
Burgos D.A.T., Vargas R.C.G., Pedraza C., Agis D., Pozo F. Damage Identification in Structural Health Monitoring : а Brief Review from its Implementation to the Use of Data-Driven Applications // Sensors. 2020. Vol. 20. Issue 3. P. 733. doi: 10.3390/s20030733
Entezami A., Sarmadi H., Behkamal B., Mariani S. Health Monitoring of Large-Scale Civil Structures : аn Approach Based on Data Partitioning and Classical Multidimensional Scaling // Sensors. 2021. Vol. 21. Issue 5. P. 1646. doi: 10.3390/s21051646
Thohari A.N.A., Karima A., Santoso K., Rahmawati R. Crack Detection in Building Through Deep Learning Feature Extraction and Machine Learning Approch // Journal of Applied Informatics and Computing. 2024. Vol. 8. Issue 1. Pp. 1–6. doi: 10.30871/jaic.v8i1.7431
Hamishebahar Y., Guan H., So S., Jo J. A Comprehensive Review of Deep Learning-Based Crack Detection Approaches // Applied Sciences. 2022. Vol. 12. Issue 3. P. 1374. doi: 10.3390/app12031374
Hsieh Y.-A., Tsai Y.J. Machine learning for crack detection : review and model performance comparison // Journal of Computing in Civil Engineering. 2020. Vol. 34. Issue 5. doi: 10.1061/(asce)cp.1943-5487.0000918
Сикорский О.С. Обзор сверточных нейронных сетей для задачи классификации изображений // Новые информационные технологии в автоматизированных системах. 2017. № 20. С. 37–42. EDN YNADUJ.
Соснин А.С., Суслова И.А. Функции активации нейросети: сигмоида, линейная, ступенчатая, ReLu, tahn // Наука. Информатизация. Технологии. Образование. 2019. С. 237–246. EDN VUZYBA.
Дорафшан С., Томас Р.Дж., Магуайр М. Сравнение глубоких сверточных нейронных сетей и детекторов краев для обнаружения трещин в бетоне на основе изображений // Строительство и строительные материалы. 2018. № 186. С. 1031–1045.
Князева Н.В., Назойкин Е.А., Орехов А.А. Применение искусственного интеллекта для обнаружения дефектов в строительных конструкциях // Строительство и архитектура. 2023. Т. 11. № 3. С. 18. doi: 10.29039/2308-0191-2023-11-3-18-18. EDN SVXCZV.
Наумов А.Е., Юдин А.В., Долженко А.В. Совершенствование технологии проведения строительно-технических экспертиз с использованием аппаратно-программного комплекса автоматизированной дефектоскопии // Вестник Белгородского государственного технологического университета им. В.Г. Шухова. 2019. № 4. С. 61–69. doi: 10.34031/arti-cle_5cb824d26344e7.45899508. EDN FHPDTK.
Князева Н.В., Лёвина Д.А. Использование BIM-сценариев в работе служб эксплуатации // Вестник Белгородского государственного технологического университета им. В.Г. Шухова. 2019. № 5. С. 99–105. doi: 10.34031/article_5cd6df471c80b0.92422061. EDN IBNDHU.
Курочкина Е.В. Новые информационные системы в строительстве: Технологии информационных систем в проектировании, строительстве, эксплуатации зданий // Научный Лидер. 2022. № 25 (70). С. 27–30. EDN DVSRFK.
Князева Н.В., Медынцев А.А. Алгоритм создания системы мониторинга здания на основе интеграции технологий информационного моделирования и радиочастотной идентификации // Инженерный вестник Дона. 2022. № 12 (96). С. 646–659. EDN NSKKNZ.
Герц В.А., Князева Н.В. Анализ нормативно-технической и законодательной базы при реализации этапа эксплуатации зданий непроизводственного назначения с применением технологий информационного моделирования (ТИМ) // Строительство и архитектура. 2023. Т. 11. № 3. С. 9. doi: 10.29039/2308-0191-2023-11-3-9-9. EDN BCGLSC.
Knyazeva N., Medincev A., Orekhov A. Configuring parameters of information model elements for integration with RFID tags // E3S Web of Conferences. 2023. Vol. 458. P. 09010. doi: 10.1051/e3sconf/202345809010
Munir M., Kiviniemi A., Jones S.W., Finnegan S. BIM-based operational information requirements for asset owners // Architectural Engineering and Design Management. 2020. Vol. 16. Issue 2. Pp. 100–114. doi: 10.1080/17452007.2019.1706439
Zhou X., Qi Y., Tang H. Application of Artificial Intelligence Technology in Big Data Nining // Lecture Notes in Electrical Engineering. 2023. Pp. 737–744. doi: 10.1007/978-981-99-2092-1_92
Dale D.C., Crawford J., Klippel Z., Reiner M., Osslund T., Fan E. et al. A systematic literature review of the efficacy, effectiveness, and safety of filgrastim // Supportive Care in Cancer. 2018. Vol. 26. Issue 1. Pp. 7–20. doi: 10.1007/s00520-017-3854-x
Elkabalawy M., Al-Sakkaf A., Abdelkader E.M., Alfalah G. CRISP-DM-Based Data-Driven Approach for Building Energy Prediction Utilizing Indoor and Environmental Factors // Sustainability. 2024. Vol. 16. Issue 17. P. 7249. doi: 10.3390/su16177249

Arquivos suplementares

Ação

1. JATS XML

Baixar

Nome de usuário
Senha
Lembrar usuário

Esqueceu a senha?	Cadastro

Nome de usuário
Senha
Lembrar usuário

Esqueceu a senha?	Cadastro

Modern approaches to assessing the technical condition of building structures at the operational stage

Texto integral

Resumo

Palavras-chave

Sobre autores

N. Knyazeva

E. Nazojkin

A. Orekhov

Bibliografia

Arquivos suplementares