Axial compressive behavior of basalt fiber reinforced polymer-confined damaged concrete after exposed to elevated temperatures

被引：0

作者：

Ouyang L. ^{[1
]}

Xu F. ^{[1
]}

Lu Z. ^{[2
]}

机构：

[1] School of Environment and Architecture, University of Shanghai for Science and Technology, Shanghai

[2] College of Civil Engineering, Tongji University, Shanghai

来源：

Ouyang, Lijun (ouyang@usst.edu.cn) | 2002年 / Beijing University of Aeronautics and Astronautics (BUAA)卷 / 35期

关键词：

Axial compressive properties; Basalt fiber; Concrete cylinders; Confinement; Elevated temperature damaged;

D O I：

10.13801/j.cnki.fhclxb.20170926.002

中图分类号：

学科分类号：

摘要：

An experimental study on the axial compressive behavior of 36 elevated temperature damaged and 15 unheated concrete cylinders wrapped with basalt fiber reinforced polymer(BFRP) sheets was conducted. The test results show that confinement can significantly change failure mode, improve the strength and ductility of elevated temperature damaged concrete cylinders. After confined with two layers of BFRP sheets, the strength of the cylinders damaged by 200℃, 400℃, 600℃ and 800℃ increases by 56%, 82%, 234% and 250%, respectively; And the axial deformation increases by 328%, 198%, 232% and 136%, respectively. The typical ultimate stress models and ultimate strain models for FRP-confined undamaged concrete are not suitable for confined elevated temperature damaged concrete cylinders. Based on the test results, variables for calculation of ultimate stress and ultimate strain are determined, and ultimate stress model and ultimate strain model of confined elevated temperature damaged concrete cylinders are proposed. © 2018, Editorial Office of Acta Materiae Compositae Sinica. All right reserved.

引用

页码：2002 / 2013

页数：11

共 29 条

[11] Ouyang L., Experimental and theoretical study of basalt fiber and carbon fiber reinforced concrete members, (2011)
[12] Ouyang L., Ding B., Lu Z., Et al., Experimental study on seismic performance of short columns strengthened with BFRP and CFRP, Journal of Tongji University (Natural Science Edition), 41, 2, pp. 166-172, (2013)
[13] Jian C.L., Ozbakkaloglu T., Confinement model for FRP-confined high-strength concrete, Journal of Compo-sites for Construction, 18, 4, pp. 2537-2547, (2013)
[14] Toutanji H., Han M., Gilbert J., Et al., Behavior of large-scale rectangular columns confined with FRP composites, Journal of Composites for Construction, 14, 1, pp. 62-71, (2010)
[15] Yaqub M., Bailey C.G., Repair of fire damaged circular reinforced concrete columns with FRP composites, Construction and Building Materials, 25, 1, pp. 359-370, (2011)
[16] Yaqub M., Bailey C.G., Cross sectional shape effects on the performance of post-heated reinforced concrete columns wrapped with FRP composites, Composite Structures, 93, 3, pp. 1103-1117, (2011)
[17] Bisby L.A., Chen J.F., Li S.Q., Et al., Strengthening fire-damaged concrete by confinement with fiber-reinforced polymer wraps, Engineering Structures, 33, 12, pp. 3381-3391, (2011)
[18] Technical code for infrastructure application of FRP composites: GB50608-2010, (2010)
[19] Guide for the design and construction of externally bonded FRP systems for strengthening concrete structures: ACI 440.2R, (2008)
[20] Design code for strengthening concrete structure: GB50367-2013, (2013)

← 1 2 3 →