Study on freeze-thaw damage of surface and pore structure of steam cured concrete.

IF 3.9 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2025-07-02 DOI:10.1038/s41598-025-06958-y

Jialin Chen, Zhifan He, Shoukai Chen, Phu Minh Vuong Nguyen, Jinping Liu, Haoke Xu

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引用次数: 0

Abstract

The study of freeze-thaw (F-T) damage of steam cured concrete (SCC) plays a positive role in promoting the development of prefabricated technology in water conservancy project construction and construction industrialization in cold areas. This study aims to investigate and provide a better understanding of the surface damage pattern and pore structure of SCC. In this paper, a 3D scanner was used to scan the surface topography of SCC under five conditions of F-T (the number of F-T was 0, 50, 100, 150, and 200 respectively), and the spatial distribution of point cloud data generated by scanning results was analyzed, and surface roughness was introduced to quantify the damage effect of F-T cycle on the surface of SCC. The results show that the fluctuation range of point cloud data increases from 0-0.15 mm to 0-0.93 mm with the increase of F-T cycles. The F-T cycles result in the continuous deterioration of the surface of SCC, and surface roughness increases from 0.097 mm to 0.899 mm, and the development law basically conforms to the exponential growth law. In addition, the pore structure parameters of SCC under different F-T cycles were obtained based on X-ray computed tomography technology (XCT). It was found that the pore size and porosity increased with the increase of F-T cycles, and the growth rates ranged from 3.41% to 19.69% and 29.29% to 41.85%, respectively. The pore numbers showed a decreasing trend, with the decreasing rate ranging from 2.56% to 11.56%. It is also found that the inhomogeneity of pore space distribution caused by F-T cycles may be one of the main reasons affecting the mechanical properties of SCC. On this basis, the surface fractal dimension and volume fractal dimension of SCC pores were calculated respectively, and they were used to evaluate the F-T damage degree of SCC under different F-T cycles. The results revealed that there is a linear relationship between fractal dimension and F-T cycles. When the fractal dimension is used to characterize the F-T damage degree of SCC, the result of the volume fractal dimension is better than the surface fractal dimension.

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蒸汽养护混凝土表面及孔隙结构冻融损伤研究。

研究蒸汽固化混凝土冻融损伤对促进预制技术在寒区水利工程建设中的发展和建筑工业化具有积极作用。本研究旨在研究和更好地理解SCC的表面损伤模式和孔隙结构。本文利用三维扫描仪对5种F-T条件下（F-T次数分别为0、50、100、150、200次）的SCC表面形貌进行扫描，分析扫描结果产生的点云数据的空间分布，并引入表面粗糙度来量化F-T循环对SCC表面的损伤效应。结果表明：随着F-T周期的增加，点云数据的波动范围从0 ~ 0.15 mm增大到0 ~ 0.93 mm；F-T循环导致SCC表面不断劣化，表面粗糙度从0.097 mm增加到0.899 mm，其发展规律基本符合指数增长规律。此外，基于x射线计算机断层扫描技术（XCT）获得了不同F-T循环下SCC的孔隙结构参数。结果表明，随着F-T旋回的增加，孔隙大小和孔隙率均呈增加趋势，增长率分别为3.41% ~ 19.69%和29.29% ~ 41.85%。孔隙数呈下降趋势，下降幅度在2.56% ~ 11.56%之间。F-T循环引起的孔隙空间分布的不均匀性可能是影响SCC力学性能的主要原因之一。在此基础上，分别计算了SCC孔隙的表面分形维数和体积分形维数，并以此来评价不同F-T循环作用下SCC的F-T损伤程度。结果表明，分形维数与F-T循环之间存在线性关系。用分形维数表征SCC的F-T损伤程度时，体积分形维数优于表面分形维数。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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