Bonding Performance at the Interface of Glass Fiber-Reinforced Polymer Anchors and Polymer Concrete.

IF 4.9 3区工程技术 Q1 POLYMER SCIENCE

Polymers Pub Date : 2025-10-09 DOI:10.3390/polym17192714

Kai Liu, Wenchao Li, Tianlong Ling, Bo Huang, Meihong Zhou

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引用次数: 0

Abstract

Currently, resin polymer anchoring agents are widely used for bolting support in coal mine roadways to anchor the bolts to the surrounding rock mass. However, due to the relatively low strength of the resin anchoring agent itself, the required anchoring length tends to be excessively long. Based on this, this paper proposes the use of resin concrete as a replacement for resin. Compared to resin anchoring agents, resin concrete offers greater mechanical interlocking force with anchor rods, which can reduce the theoretical anchoring length. To systematically investigate the influence of factors such as the diameter and anchorage length of Glass Fiber-Reinforced Polymer (GFRP) bolt on the bond behavior between GFRP bolts and resin concrete, 33 standard pull-out tests were designed and conducted in accordance with the CSA S807-19 standard. Taking the 18 mm-diameter bolt as an example, when the bond lengths were 2D, 3D, 4D, and 5D, the average bond strengths were 41.32 MPa, 39.18 MPa, 38.84 MPa, and 37.44 MPa, respectively. This represents a decrease of 5.18%, 6.00%, and 9.39% for each subsequent increase in bond length. The results indicate that the bond strength between GFRP anchors and resin decreases as the anchorage length increases. Due to the shear lag effect, the average bond strength also decreases with increasing anchor diameter. Taking a 5D (where D is the anchor diameter) anchorage length as a reference, the average bond strengths for anchor diameters of 18 mm, 20 mm, 22 mm, and 24 mm were 37.44 MPa, 33.97 MPa, 32.18 MPa, and 31.50 MPa, respectively. The corresponding reductions compared to the 18 mm diameter case were 9.27%, 14.05%, and 15.87%. Based on the experimental results, this paper proposes a bond-slip constitutive model between the bolt and resin concrete, which consists of a rising branch, a descending branch, and a residual branch. A differential equation relating shear stress to displacement was established, and the functions describing the variation in displacement, normal stress, and shear stress along the position were solved for the ascending branch. Although an analytical solution for the differential equation of the descending branch was not obtained, it will not affect the subsequent derivation of the theoretical anchorage length for the GFRP bolt-resin concrete system, as structural components in practical engineering are not permitted to undergo excessive bond-slip.

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玻璃纤维增强聚合物锚杆与聚合物混凝土界面的粘结性能。

目前，树脂高分子锚固剂广泛应用于煤矿巷道锚固支护中，将锚杆锚固在围岩上。但由于树脂锚固剂本身强度较低，所要求的锚固长度往往过长。在此基础上，本文提出用树脂混凝土代替树脂混凝土。与树脂锚固剂相比，树脂混凝土与锚杆具有更大的机械联锁力，可减小理论锚固长度。为系统研究玻璃钢锚杆直径、锚固长度等因素对玻璃钢锚杆与树脂混凝土粘结性能的影响，按照CSA S807-19标准设计并进行了33项标准拉拔试验。以直径为18mm的螺栓为例，粘结长度为2D、3D、4D和5D时，平均粘结强度分别为41.32 MPa、39.18 MPa、38.84 MPa和37.44 MPa。这表示每增加一次键长，分别减少5.18%、6.00%和9.39%。结果表明：GFRP锚杆与树脂的粘结强度随锚固长度的增加而减小；由于剪切滞后效应，平均粘结强度也随锚固直径的增加而降低。以5D （D为锚杆直径）锚固长度为基准，锚杆直径为18 mm、20 mm、22 mm和24 mm时锚固强度的平均值分别为37.44 MPa、33.97 MPa、32.18 MPa和31.50 MPa。与直径为18 mm的病例相比，相应的降幅分别为9.27%、14.05%和15.87%。在试验结果的基础上，提出了由上升枝、下降枝和残余枝组成的锚杆与树脂混凝土粘结滑移本构模型。建立了剪切应力与位移的微分方程，求解了上升分支的位移、正应力和剪应力沿位置的变化函数。虽然没有得到下降支微分方程的解析解，但由于实际工程中结构构件不允许发生过大的粘结滑移，因此不会影响GFRP锚杆-树脂混凝土体系理论锚固长度的后续推导。

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

Polymers POLYMER SCIENCE-

CiteScore

8.00

自引率

16.00%

发文量

4697

审稿时长

1.3 months

期刊介绍： Polymers (ISSN 2073-4360) is an international, open access journal of polymer science. It publishes research papers, short communications and review papers. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. Therefore, there is no restriction on the length of the papers. The full experimental details must be provided so that the results can be reproduced. Polymers provides an interdisciplinary forum for publishing papers which advance the fields of (i) polymerization methods, (ii) theory, simulation, and modeling, (iii) understanding of new physical phenomena, (iv) advances in characterization techniques, and (v) harnessing of self-assembly and biological strategies for producing complex multifunctional structures.