[1] 牛旭婧,赵庆新,陈天红.聚丙烯粗纤维对高强混凝土高温后性能影响[J].硅酸盐学报,2013,32(12):2583-2588.
[2] 李云英.自密实混凝土研究现状[J].福建建材,2018(12):24-25,35.
[3] 中国工程建设标准化协会.自密实混凝土应用技术规程:CECS 203-2006[S].北京:中国计划出版社,2006.
[4] 王安成,李喜云.盾构隧道衬砌管片用混杂纤维自密实混凝土的基本力学性能[J].混凝土世界,2014(2):74-77.
[5] 张广泰,陈浩,郭锐,等.纤维混凝土高温性能及作用机理研究综述[J].混凝土与水泥制品,2016(1):62-68.[6] 单晨晨,杨鼎宜,张鑫怡,等.纤维混凝土高温力学机理综述[J].混凝土,2018(4):87-90,94.
[7] 梅国栋,段文付.纤维混凝土增强机理分析[J].江苏建材,2015(2):18-20,23.
[8] 李冬晨.纤维混凝土研究进展及增强机理[J].建材与装饰,2018(10):202.
[9] 元成方,赵军.聚丙烯纤维混凝土的高温损伤机理[J].材料科学与工程学报,2017,35(1):37-40,56.
[10] 鲁浈浈,何杨,李林杰.混凝土高温爆裂性能影响因素及预防措施综述[J].火灾科学,2019,28(2):128-134.
[11] 韩雪,杨鼎宜,单晨晨,等.纤维混凝土高温性能与作用机理[J].江苏建材,2017(4):19-22.
[12] 陈泽世,凌平平,余婵娟,等.基于抗火性能的混杂纤维自密实混凝土设计(1)——蒸汽压力测试[J].混凝土,2016(2):121-123.
[13] 张聪.混杂纤维自密实混凝土梁高温作用前后的受弯性能[D].大连:大连理工大学,2016.
[14] 陶津,柳献,袁勇,等.高温下自密实混凝土强度和变形性能试验研究[J].同济大学学报(自然科学版),2009,37(6):738-743.
[15] ALI S,SAEED H G,BEHZAD T.Residual strength and microstructure of fiber reinforced self-compacting concrete exposed to high temperatures[J].Construction and Building Materials,2020,230:1-15.
[16] DING Y,CECILIA A,AGUIAR J B.Study on residual behaviour and flexural toughness of fibre cocktail reinforced self compacting high performance concrete after exposure to high temperature[J].Construction and Building Materials,2012,26(1): 21-31.
[17] 黄业胜,丁一宁.混杂纤维自密实高性能混凝土高温后残余抗压强度和弯曲性能研究[C]//中国土木工程学会.2013年全国土木工程研究生学术会议论文集.北京:中国建筑工业出版社,2013:50-55.
[18] 张聪,夏超凡,袁振,等.火灾下纤维自密实混凝土的爆裂行为预测[J/OL].建筑材料学报,2019(11):1-14[2020-10-06].http://kns.cnki.net/kcms/detail/31.1764.TU.20191112.0947.006.html.
[19] 陶津,柳献,袁勇,等.自密实混凝土高温爆裂性能影响因素的试验研究[J].土木工程学报,2009,42(10):22-26.
[20] HERNAN X,PAULA F,NICOLAS N,et al.Acoustic emission behavior of thermally damaged self-compacting high strength fiber reinforced concrete[J].Construction and Building Materials,2018,187:519-530.
[21] RIOS J D,CIFUENTES H,LEIVA C,et al.Behavior of High-Strength Polypropylene Fiber-Reinforced Self-Compacting Concrete Exposed to High Temperatures[J].Journal of Materials in Civil Engineering,2018,30(11):1-13.
[22] KARATAS M,DENER M,BENLI A,et al.High Temperature effect on the mechanical behavior of steel fiber reinforced self-compacting concrete containing ground pumice powder[J].Structural Concrete,2019,20(5):1734-1749.
[23] UYSAL M,TANYILDIZI H.Estimation of compressive strength of self compacting concrete containing polypropylene fiber and mineral additives exposed to high temperature using artificial neural network[J].Construction and Building Materials,2012,27(1):404-414.
[24] ASLANI F,SUN J,HUANG G.Mechanical behavior of fiber-reinforced self-Compacting rubberized concrete exposed to elevated temperatures[J].Journal of Materials in Civil Engineering,2019,31(12):1-14.
[25] HERNAN X,PAULA F,LUCIANO S,et al.Temperature effects on failure behavior of self-compacting high strength plain and fiber reinforced concrete[J].Construction and Building Materials,2018,165:723-734.
[26] ZUHAIR M,DESHMUKH S K.Effect of different fibers on compressive strength of self-compacting concrete at elevated temperature[J].Iop Conference,2018,410(1):012007.
[27] ASLANI F,SUN J,BROMLEY D,et al.Fibre-reinforced lightweight self-compacting concrete incorporating scoria aggregates at elevated temperatures[J].Structural Concrete,2019,20(3):1022-1035.
[28] BOZKURT N.The high temperature effect on fiber reinforced self-compacting lightweight concrete design with single and hybrid fibers[J].Acta Physica Polonica A,2014,125(2): 579-583.
[29] ASLANI F,KELIN J.Assessment and development of high-performance fibre-reinforced lightweight self-compacting concrete including recycled crumb rubber aggregates exposed to elevated temperatures[J].Journal of Cleaner Production,2018,200:1009-1025.
[30] 余婵娟,凌平平,陈泽世,等.基于抗火性能的混杂纤维自密实混凝土设计(3)——高温弯曲性能[J].混凝土,2016(4):17-19.
[31] 张聪,丁一宁,曹明莉.混杂纤维自密实混凝土简支梁高温后剩余承载力试验与计算[J].功能材料,2016,47(3):151-157.
[32] ABDULHALEEM K N,GULSAN M E,CEVIK A.Mechanical behavior of steel fiber-reinforced self-ompacting concrete corbels after exposure to elevated temperatures[J].Structural Concrete,2017,19(6):1881-1894.
[33] 陶津,柳献,袁勇,等.高温下自密实混凝土的瞬态应变[J].建筑材料学报,2009,12(1):47-51.
[34] 郭万峰.绿色高性能混凝土与建筑工程材料的可持续发展[J].工程建设与设计,2019(18):11-12.
[35] 张颖.自密实混凝土:绿色高性能混凝土的重要实现形 [J].混凝土世界,2016(5):56-63.