Journal of Jilin University(Engineering and Technology Edition) ›› 2023, Vol. 53 ›› Issue (6): 1686-1694.doi: 10.13229/j.cnki.jdxbgxb.20230085

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Bond⁃slip characterization between ultra⁃high performance glass sand concrete and high⁃strength reinforcement based on acoustic emission parameters

Ya-na MAO1,2(),Shi-zhong LIU1,Jian XING3,Hua YANG3,Yu-bo JIAO3()   

  1. 1.School of Civil Engineering,Lanzhou Jiaotong University,Lanzhou 730070,China
    2.Gansu Province Highway Aviation Tourism Investment Group Co. ,Ltd. ,Lanzhou 730030,China
    3.Key Laboratory of Urban Security and Disaster Engineering of Ministry of Education,Beijing University of Technology,Beijing 100124,China
  • Received:2023-01-31 Online:2023-06-01 Published:2023-07-23
  • Contact: Yu-bo JIAO E-mail:361553870@qq.com;jiaoyb@bjut.edu.cn

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Abstract:

In order to investigate the bonding performance between ultra-high performance glass sand concrete (UHPGC) and HRB600 high-strength reinforcement, the influences of water-cement ratio (0.17, 0.19, 0.21), steel fiber volume fraction (1%, 2%, 3%) and glass sand replacement ratio (0%, 50%, 100%) on the working and mechanical properties of UHPGC were analyzed. The variations of bonding performance between UHPGC-HRB600 were clarified based on pull-out test and acoustic emission monitoring. The results reveal that the addition of glass sand can improve the compressive strength of UHPGC, and corresponding optimum replacement ratio is 50%. The bond strength is positively correlated with the water-cement ratio and the amount of steel fiber, while it presents first increase and then decrease with the increase of the replacement ratio of glass sand. The bond-slip failure between UHPGC and HRB600 can be mainly divided into two types: splitting failure and shear pullout failure. The acoustic emission parameters exhibit favorable bond-slip characterization ability.

Key words: bridge and tunnel engineering, ultra-high performance glass sand concrete, high-strength reinforcement, bond-slip performance, acoustic emission monitoring

CLC Number: 

  • U444

Table 1

Chemical composition of raw materials"

化学组成石英砂玻璃砂硅灰石英粉水泥
SiO299.4371.1098.8699.2022.80
Fe2O30.02550.510.140.014.43
Al2O30.182.150.120.104.01
CaO0.1111.100.570.2165.32
MgO0.011.300.200.172.07
Na2O-14.070.350.110.07
K2O0.030.280.210.810.56

Table 2

Physical properties of aggregate"

物理特性石英砂玻璃砂
堆积密度/(kg·m-31536.311579.62
平均粒径/μm300300
最大粒径/μm600600
压碎值/%3.295.28

Table 3

Concrete mix proportion design"

组号材料组成
水泥硅灰石英砂玻璃砂石英粉钢纤维减水剂
1850195.5467.5467.5331.5148.75161.542.5
2850195.59350331.5223.55161.542.5
3850195.5467.5467.5331.5148.75161.542.5
4850195.500331.5148.75178.542.5
5850195.59350331.5148.75178.542.5
6850195.5467.5467.5331.5223.55178.542.5
7850195.5467.5467.5331.5223.55144.542.5
8850195.59350331.574.8161.542.5
9850195.5467.5467.5331.574.8178.542.5
10850195.59350331.5148.75144.542.5
11850195.5467.5467.5331.5148.75161.542.5
12850195.5467.5467.5331.5148.75161.542.5
13850195.5467.5467.5331.5148.75161.542.5
14850195.5467.5467.5331.574.8144.542.5
15850195.50935331.574.8161.542.5
16850195.50935331.5223.55161.542.5
17850195.50935331.5148.75144.542.5

Fig.1

Fluidity test"

Fig.2

Concrete compression test"

Fig.3

Pull-out test"

Fig.4

Three dimensional response surfaces between material variables and fluidity"

Fig.5

Three dimensional response surfaces between material variables and compressive strength"

Fig.6

Three dimensional response surface between material variables and bond strength"

Fig.7

Relationship between compressive strength and bond strength"

Table 4

Test failure mode"

组别水胶比钢纤维掺量/%替换率/%滑移量/mm破坏模式
10.17208劈拉破坏
20.1735012.2劈拉破坏
30.171506.4劈拉破坏
40.1721007.2劈拉破坏
50.1911000.55劈裂破坏
60.193013.4劈拉破坏
70.1931008.8劈拉破坏
80.19100.22劈裂破坏
90.21200.39劈裂破坏
100.2121000.442劈裂破坏
110.211500.15劈裂破坏
120.213503.6劈拉破坏
130.192506.3劈拉破坏

Fig.8

Failure modes of test speicimens"

Fig.9

Bond slip curve between UHPGC and HRB600"

Fig.10

Acoustic emission energy-bond slip parameters curve for test specimen of shear pullout failure"

Fig.11

Acoustic emission energy-bond slip parameters curve for test specimen of splitting failure"

Fig.12

Acoustic emission b-value curve for test specimen of shear pullout failure"

1 Arora A, Almujaddidi A, Kianmofrad F, et al. Material design of economical ultra-high performance concrete (UHPC) and evaluation of their properties[J]. Cement and Concrete Composites, 2019, 104: No. 103346.
2 朱劲松, 秦亚婷, 刘周强.预应力 UHPC-NC 组合梁截面优化设计[J/OL].[2023-01-15].
3 Soliman N A, Omran A F, Tagnit-Hamou A. Laboratory characterization and field application of novel ultra-high-performance glass concrete[J]. Aci Materials Journal, 2016, 113(3): 307-316.
4 Soliman N A, Tagnit-Hamou A. Development of ultra-high-performance concrete using glass powder – towards ecofriendly concrete[J]. Construction and Building Materials, 2016,125:600-612.
5 Soliman N A, Tagnit-Hamou A. Partial substitution of silica fume with fine glass powder in UHPC: filling the micro gap[J]. Construction and Building Materials, 2017,139:374-383.
6 Vaitkevicius V, Šerelis E, Hilbig H. The effect of glass powder on the microstructure of ultra high performance concrete[J]. Construction and Building Materials, 2014, 68: 102-109.
7 Jiao Y B, Zhang Y, Guo M, et al. Mechanical and fracture properties of ultra-high performance concrete (UHPC) containing waste glass sand as partial replacement material[J]. Journal of Cleaner Production, 2020, 277: No. 123501.
8 邓宗才,袁常兴. 高强钢筋与活性粉末混凝土黏结性能的试验研究[J]. 土木工程学报, 2014, 47(3): 69-78.
Deng Zong-cai, Yuan Chuang-xing. Experimental study on bond capability between high strength rebar and reactive powder concrete[J]. China Civil Engineering Journal, 2014, 47(3): 69-78.
9 黄政宇,岑小艳,柳红霞. 碳纤维筋与活性粉末混凝土粘结性能试验研究[J]. 铁道科学与工程学报, 2006(1): 65-69.
Huang Zheng-yu, Cen Xiao-yan, Liu Hong-xia. Experimental research on the bond performance between CFRP bars and reactive powder concrete[J]. Journal of Railway Science and Engineering, 2006(1): 65-69.
10 Choi E S, Lee J W, Kim S J, et al. A Study on the Bond Strength between High Performance Concrete and Reinforcing Bar[J]. Engineering, 2015, 7(7): 373-378.
11 Gallego A, Senavent-Climent A, Suarez E. Concrete-galvanized steel pull-out bond assessed by acoustic emission[J]. Journal of Materials in Civil Engineering, 2016, 28(2): 1543-1552.
12 Abouhussien A A, Hassan A A. Acoustic emission-based analysis of bond behavior of corroded reinforcement in existing concrete structures[J/OL]. [2023-01-02].
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