高性能混凝土桥面结构行为研究

Q2 Engineering

International Review of Applied Sciences and Engineering Pub Date : 2024-05-14 DOI:10.1556/1848.2024.00811

K. Nehar, Dalila Benamara

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引用次数: 0

摘要

桥面施工中的高性能混凝土（HPC）制造是实验框架的一部分，该框架也在数值领域不断发展，以填补在了解其行为方面的现有空白。然而，桥面用高性能混凝土的数值建模在很大程度上仍未得到充分探索。这项研究的主要目的是加深对 HPC 桥面行为的理解，同时利用具有极高属性（机械、物理、弹性、耐久性和实施）的本地材料和先进的数值建模来制造高效经济的 HPC。这种建模方法使我们能够通过扩展有限元法（X-FEM）研究 HPC 桥面与开裂有关的行为。结果的质量证实了这一点，与实验数据的相关性极佳，凸显了建模的准确性。这些结果还表明，在桥梁建设中使用 HPC 可以显著降低退化风险，同时提高桥梁性能。因此，采用 HPC 是一项有益的战略，不仅能最大限度地减少桥梁退化，还能延长桥梁的耐久性。

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Study of the structural behavior of High-Performance Concrete bridge decks

The manufacture of High-Performance Concrete (HPC) in bridge deck construction is part of an experimental framework that is also developing in the numerical domain to fill the existing gaps in understanding its behavior. However, the numerical modeling of HPC for bridge decks remains largely under-explored. It is precisely this gap that has sparked our interest in this research area, thus giving our work its innovative character.This study primarily aims to deepen the understanding of the behavior of HPC bridge decks while manufacturing an efficient and economical HPC using local materials possessing very high properties (mechanical, physical, elastic, durability, and implementation) and advanced numerical modeling. This modeling has enabled us to study the behavior of HPC bridge decks in relation to cracking through the Extended Finite Element Method (X-FEM), an innovative solution that enables the modeling of discontinuities without complicating the process. This has been confirmed by the quality of the results, which show an excellent correlation with experimental data, underscoring the accuracy of the modeling. These results also reveal that the use of HPC in bridge construction can significantly reduce degradation risks while enhancing their performance. Consequently, the adoption of HPC stands out as a beneficial strategy, not only to minimize bridge degradation but also to extend their durability.

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来源期刊

International Review of Applied Sciences and Engineering Materials Science-Materials Science (miscellaneous)

CiteScore

2.30

自引率

0.00%

发文量

审稿时长

46 weeks

期刊介绍： International Review of Applied Sciences and Engineering is a peer reviewed journal. It offers a comprehensive range of articles on all aspects of engineering and applied sciences. It provides an international and interdisciplinary platform for the exchange of ideas between engineers, researchers and scholars within the academy and industry. It covers a wide range of application areas including architecture, building services and energetics, civil engineering, electrical engineering and mechatronics, environmental engineering, mechanical engineering, material sciences, applied informatics and management sciences. The aim of the Journal is to provide a location for reporting original research results having international focus with multidisciplinary content. The published papers provide solely new basic information for designers, scholars and developers working in the mentioned fields. The papers reflect the broad categories of interest in: optimisation, simulation, modelling, control techniques, monitoring, and development of new analysis methods, equipment and system conception.