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大连湾海底沉管隧道机制砂高性能混凝土强度与耐久性试验研究及其工程应用

Experimental Study on the Strength and Durability of Manufactured Sand HPC in the Dalian Bay Undersea Immersed Tube Tunnel and Its Engineering Application.

作者信息

Sun Yuefeng, Song Shanshan, Yu Hongfa, Ma Haiyan, Xu Yu, Zu Guojia, Ruan Yang

机构信息

CCCC First Harbor Bureau No. 3 Engineering Co., Ltd., Dalian 116000, China.

Department of Civil and Airport Engineering, Nanjing University of Aeronautics and Astronautics, Nanjing 210016, China.

出版信息

Materials (Basel). 2024 Oct 12;17(20):5003. doi: 10.3390/ma17205003.

DOI:10.3390/ma17205003
PMID:39459708
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11509216/
Abstract

The usage of manufactured sand concrete is widespread in modern engineering, and it is important to study its performance to improve the overall engineering quality. This paper presents an experimental study on the working performance and durability of 12 groups of manufactured sand high-performance concrete (MSHPC) with varying mix ratios, in the context of the construction of the Dalian Bay undersea immersed tube tunnel. The study reveals that the stone powder content significantly affects the physical and mechanical properties, as well as the durability, of manufactured sand concrete. At an approximately 9% stone powder content, the concrete achieves the highest slump and best workability. However, excessive stone powder reduces early crack resistance. Furthermore, an optimal stone powder content (ranging from 5% to 13%) enhances the compressive strength, with the 28-day compressive strength reaching 60 MPa at a 13% stone powder content, while the effect on the splitting tensile strength is negligible. The stone powder content does not significantly impact impermeability and frost resistance, but at 7-9%, the RCM method shows the lowest chloride ion diffusion coefficient. Additionally, a lower water-binder ratio enhances resistance to chloride ion diffusion. High-performance RCM concrete with a 9% stone powder content was used in the construction of the Dalian Bay Cross-Harbor Tunnel, achieving 28-day and 56-day compressive strengths of C45 and C50, respectively, an impermeability grade of P14, a chloride ion diffusion coefficient of 1.9 × 10 m/s, and a frost durability index of 92%, meeting the project's 100-year lifespan design requirements.

摘要

机制砂混凝土在现代工程中应用广泛,研究其性能对于提高整体工程质量具有重要意义。本文结合大连湾海底沉管隧道建设,对12组不同配合比的机制砂高性能混凝土(MSHPC)的工作性能和耐久性进行了试验研究。研究表明,石粉含量对机制砂混凝土的物理力学性能及耐久性有显著影响。石粉含量约为9%时,混凝土坍落度最大,工作性能最佳。然而,石粉过多会降低早期抗裂性。此外,最佳石粉含量(5% - 13%)可提高抗压强度,石粉含量为13%时,28天抗压强度可达60MPa,而对劈裂抗拉强度的影响可忽略不计。石粉含量对抗渗性和抗冻性影响不显著,但在7% - 9%时,RCM法测得的氯离子扩散系数最低。此外,较低的水胶比可增强抗氯离子扩散能力。大连湾跨海隧道建设中采用了石粉含量为9%的高性能RCM混凝土,28天和56天抗压强度分别达到C45和C50,抗渗等级为P14,氯离子扩散系数为1.9×10⁻¹²m²/s,抗冻耐久性指标为92%,满足项目100年使用寿命设计要求。

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本文引用的文献

1
Experimental Study on the Properties of Mortar and Concrete Made with Tunnel Slag Machine-Made Sand.隧道矿渣机制砂制备砂浆及混凝土性能试验研究
Materials (Basel). 2022 Jul 10;15(14):4817. doi: 10.3390/ma15144817.
2
Orthogonal Experimental Study on Concrete Properties of Machine-Made Tuff Sand.机制凝灰岩砂混凝土性能的正交试验研究
Materials (Basel). 2022 May 13;15(10):3516. doi: 10.3390/ma15103516.