低周反复荷载下混杂纤维混凝土柱抗剪承载力研究
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摘要
通过低周反复荷载试验,研究了钢纤维混凝土、钢-聚丙烯混杂纤维混凝土柱的破坏现象、破坏形态,分析了纤维掺量对抗剪承载力的影响规律;利用桁架+拱的模型理论推导了钢纤维混凝土柱在低周反复荷载作用下的抗剪承载力计算公式,并将试验值与理论计算值进行了比较。结果表明:钢纤维混凝土柱呈现弯曲破坏、钢-聚丙烯混杂纤维混凝土柱呈现弯剪破坏;掺量为1. 0%、1. 5%、2. 0%的三种钢纤维混凝土柱的抗剪承载力比基准混凝土分别提高14. 10%、19. 87%和12. 18%;钢纤维掺量为1. 0%、1. 5%、2. 0%,聚丙烯纤维掺量均为0. 1%的三种混杂纤维混凝土柱的抗剪承载力比基准混凝土分别提高19. 23%、23. 72%、16. 03%;抗剪承载力试验值与理论推导计算值有较好的一致性和适用性。
Through low reversed cyclic loading test,the damage phenomenon,failure mode of steel fiber reinforced concrete and steel-polypropylene hybrid fiber reinforced concrete columns were studied,the effect of fiber content on shear capacity was analyzed. Based on the theory of truss-arch model,the formula for calculating shear capacity of steel fiber reinforced concrete columns under low cyclic loading was derived,the experimental and theoretical values were compared. The results show that the steel fiber reinforced concrete column shows bending failure and the steel-polypropylene hybrid fiber reinforced concrete column shows bending and shearing failure. The shear capacity of steel fiber reinforced concrete columns with steel fiber content of 1. 0%,1. 5% and 2. 0% are 14. 10%,19. 87% and 12. 18% higher than that of ordinary reference concrete respectively. The shear capacity of hybrid fiber reinforced concrete columns with steel fiber content of 1. 0%,1. 5% and 2. 0%,and polypropylene fiber content of0. 1%,are 19. 23%,23. 72% and 16. 03% higher than that of ordinary reference concrete respectively.The experimental value of shear capacity has good consistency and applicability with the calculated value.
Through low reversed cyclic loading test,the damage phenomenon,failure mode of steel fiber reinforced concrete and steel-polypropylene hybrid fiber reinforced concrete columns were studied,the effect of fiber content on shear capacity was analyzed. Based on the theory of truss-arch model,the formula for calculating shear capacity of steel fiber reinforced concrete columns under low cyclic loading was derived,the experimental and theoretical values were compared. The results show that the steel fiber reinforced concrete column shows bending failure and the steel-polypropylene hybrid fiber reinforced concrete column shows bending and shearing failure. The shear capacity of steel fiber reinforced concrete columns with steel fiber content of 1. 0%,1. 5% and 2. 0% are 14. 10%,19. 87% and 12. 18% higher than that of ordinary reference concrete respectively. The shear capacity of hybrid fiber reinforced concrete columns with steel fiber content of 1. 0%,1. 5% and 2. 0%,and polypropylene fiber content of0. 1%,are 19. 23%,23. 72% and 16. 03% higher than that of ordinary reference concrete respectively.The experimental value of shear capacity has good consistency and applicability with the calculated value.
引文
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[2]Ka6kea A,Achoura D,Duplan F,et al.Effect of mineral admixtures and steel fiber volume contents on the behavior of high performance fiber reinforced concrete[J].Materials and Design,2014,63:493-499.
[3]韩建平,刘文林,崔明.PVA-钢混杂纤维增强水泥基复合材料梁柱节点抗震性能试验研究[J].土木工程学报.2018,51(11):32-52.
[4]梁兴文,刘贞珍,邢朋涛,等.纤维增强混凝土对角斜筋小跨高比连梁抗震性能试验研究及受剪承载力分析[J].土木工程学报,2017,50(2):27-35.
[5]罗素蓉,郑建岚,郑作樵,等.钢纤维钢筋混凝土柱的抗剪承载力计算方法[J].工程力学,2002,19(6):80-81.
[6]邓明科,张辉,梁兴文,等.高延性纤维混凝土短柱抗震性能试验研究[J].建筑结构学报,2015,36(12):62-69.
[7]Vecchio F.Disturbed stress field model for reinforced concrete:formulation[J].Journal of Structural Engineering,2000,126(9):1070-1077.
[8]Mitchell D,Collins M P.Diagonal compression field theory-a rational model for structural concrete in puretorsion[J].ACI Structural Journal,1974,71(8):396-408.
[9]Vecchio F J,Collins M P.Predicting the response of reinforced concrete beams subjected to shear using modified compression field theory[J].ACI Structural Journal,1988,85(3):258-268.
[10]Collins M P,Mitchell D.Prestressed concrete structures[M].Englewood Cliffs,NJ:Prentice Hall,1991.
[11]K9ksal F,Gencel O,Unal B,et al.Durability properties of concrete reinforced with steel-polypropylene hybrid fibers[J].Science and Engineering of Composite Materials,2012,19(1):19-27.
[12]Wang P,Huang Z,Jiang J,et al.Performances of hybrid fiber reinforced concrete with steel fibers and polypropylene fibers[J].Civil Engineering and Urban Planning,2012:458-461.
[13]孔祥清,高化东,刚建明,等.钢-聚丙烯混杂纤维再生混凝土弯曲韧性研究[J].硅酸盐通报,2018,37(9):2729-2736.
[14]张广泰,田虎学,李宝元,等.钢-聚丙烯混杂纤维混凝土的抗盐冻性能[J].材料导报B,2018,32(7):2396-2406.
[15]史庆轩,王朋,王秋维.桁架-拱模型用于钢筋混凝土梁的受剪承载力计算分析[J].土木建筑与环境工程,2013,35(4):7-12.
[16]CEB-FIP.CEB-FIP model Code1990[S].London,1991.
[17]黄承逵,曲来福,徐士弢.钢筋混凝土不等肢异型柱抗剪承载力研究[J].工程力学,2009,26(5):197-201.
[18]日本建筑学会.鉄筋コンクリート造建物の終局強度型耐震設計指針.同解説[S].1990.
[19]余波,吴然立,陈冰,等.剪切破坏型钢筋混凝土柱的抗剪承载力分析模型[J].振动与冲击,2018,37(8):180-189.
[20]赵国藩,彭少明,黄承逵.钢纤维混凝土结构[M].北京:中国建筑工业出版社,1999.
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