|Table of Contents|

Mechanical behavior of HFRC bridge deck for composite bridge(PDF)

长安大学学报(自然科学版)[ISSN:1006-6977/CN:61-1281/TN]

Issue:
2023年2期
Page:
80-88
Research Field:
桥梁与隧道工程
Publishing date:

Info

Title:
Mechanical behavior of HFRC bridge deck for composite bridge
Author(s):
HE Yu-liang1 LIU Jia-meng1 CAO Xin-yu1 YING Sen-yuan2 YANG Ying1 XIANG Yi-qiang3
(1. School of Civil Engineering, Shaoxing University, Shaoxing 312000, Zhejiang, China; 2. Zhejiang Zhongqingda Construction Industry Co., LTD, Shaoxing 312000, Zhejiang, China; 3. College of Civil Engineering and Architecture, Zhejiang University, Hangzhou 310058, Zhejiang, China)
Keywords:
bridge engineering HFRC bridge deck experiment numerical stimulation capacity
PACS:
U441
DOI:
10.19721/j.cnki.1671-8879.2023.02.008
Abstract:
In order to solve the problem that the reinforced concrete bridge panel was easy to crack under the action of load, which made it difficult to replace the bridge panel in concrete, a new hybrid fiber concrete(HFRC)composite beam bridge panel was proposed. First, four test specimens(2 HFRC specimens, 2 ordinary concrete specimens)were designed and tested under monotonic and cyclic loading, the mechanical properties of the bridge deck were analyzed from the failure mode, crack development, load-deflection and load-strain. Then the standard finite element model was set up considering the constitution relationship of HFRC, and the effects of different dosages(volume fraction, the same below)steel fiber(0%, 0.5%, 1% and 1.5%)and polypropylene fiber(0%, 0.05%, 0.1% and 0.15%)on the static properties of bridge deck were studied. Finally, according to the experimental and numerical results, based on the existing specification of the formula of reinforced concrete slab shear bearing capacity, fiber characteristic values were introduced, the calculation method of bearing capacity of HFRC bridge deck was proposed based on the specifications. The results show that the fiber not only increases the bearing capacity of the bridge deck under monotonic and cyclic loading by 9% and 6%, but also plays an effective role in strengthening, toughening and crack resistance. The capacity and crack resistance of bridge deck are improved with the increasing of steel fiber content, however the amount of polypropylene fiber has little effect on the improvement of the cracking load and ultimate bearing capacity of the bridge deck, but it can improve the ductility of the bridge deck. The combination of polypropylene fiber and steel fiber can improve the bearing capacity, stiffness and toughness of the bridge panel after buckling. The calculation method can provide a reference for the design of HFRC bridge deck.5 tabs, 13 figs, 24 refs.

References:

[1] MASOUD M,HAMID V,STEPHEN F.Fatigue behaviour of transversely restrained precast steel fibre reinforced concrete slabs in a deconstructable composite deck[J].Construction and Building Materials,2017,132:516-528.
[2]HYUNG-KEUN R,YOUNG-JIN K,SUNG-PIL C.Crack control of a continuous composite two-girder bridge with prefabricated slabs under static and fatigue loads[J].Engineering Structures,2007,29(6):851-864.
[3]杨 勇,刘玉擎,范海丰.FRP-混凝土组合桥面板疲劳性能试验研究[J].工程力学,2011,28(6):66-73.
YANG Yong,LIU Yu-qing,FAN Hai-feng.Experimental study on the fatigue behavior of FRP-concrete composite decks[J].Engineering Mechanics,2011,28(6):66-73.
[4]CHENG L J.Flexural fatigue analysis of a CFRP form reinforced concrete bridge deck[J].Composite Structures,2011,93(11):2895-2902.
[5]BROWN D L,BERMAN J W.Fatigue and strength evaluation of two glass fiber-reinforced polymer bridge decks[J].Journal of Bridge Engineering,2010,15(3):290-301.
[6]VALBONA M,REZA H,PETER H.Bridge decks of fibre reinforced polymer(FRP):A sustainable solution[J].Construction and Building Materials,2014,50:190-199.
[7]GARA F,LEONI G,DEZI L.Slab cracking control in continuous steel-concrete bridge decks[J].Journal of Bridge Engineering,2013,18(12):1319-1327.
[8]ACI Committee,Building code requirements for structural concrete and commentary[S].
[9]MATSUMOTO T,WANGSIRIPAISAL K,HAYASHIKAWA T,et al.Uniaxial tension-compression fatigue behavior and fiber bridging degradation of strain hardening fiber reinforced cementitious composites[J].International Journal of Fatigue,2010,32(11):1812-1822.
[10]徐礼华,黄 彪,李 彪,等.循环荷载作用下聚丙烯纤维混凝土受压应力-应变关系研究[J].土木工程学报,2019,52(4):1-12.
XU Li-hua,HUANG Biao,LI Biao,et al.Study on the stress-strain relation of polypropylene fiber reinforced concrete under cyclic compression[J].China Civil Engineering Journal,2019,52(4):1-12.
[11]罗 章.中应变率下钢纤维混凝土的本构关系研究[D].长沙:中南大学,2004.
LUO Zhang.Study on the constitutive relationship of steel fiber reinforced concrete under intermediate strain rate[D].Changsha:Central South University,2004.
[12]CECS 38—2004,纤维混凝土结构技术规程[S].
CECS 38—2004,Technical specification for fiber reinforced concrete structures[S].
[13]ANTONIO C,SERENA G,ENZO M,et al.Experimental characterization of the post-cracking response in hybrid steel/polypropylene fiber-reinforced concrete[J].Construction and Building Materials,2016,125:1035-1043.
[14]ALMUSALLAM T,IBRAHIM S M,AL-SALLOUM Y,et al.Analytical and experimental investigations on the fracture behavior of hybrid fiber reinforced concrete[J].Cement and Concrete Composites,2016,74:201-217.
[15]NAM-WOOK K,HYUN-HO L,CHUN-HO K.Fracture behavior of hybrid fiber reinforced concrete according to the evaluation of crack resistance and thermal[J].Computers and Concrete,2016,18(5):621-633.
[16]HE Y L,WU X D,XIANG Y Q,et al.Mechanical behavior of stud shear connectors embedded in HFRC[J].Steel & Composite Structures,2017,24(2):177-189.
[17]HE Y L,GUO S J,WANG L C,et al.Experimental and numerical analysis of grouped stud shear connectors embedded in HFRC[J].Construction and Building Materials,2020,242:118197.
[18]何余良,胡立普,曹鑫雨,等.混杂纤维混凝土螺栓剪力键试验[J].中国公路学报,2021,34(6):90-98.
HE Yu-liang,HU Li-pu,CAO Xin-yu,et al.Experimental study on behavior of bolt connectors in steel-hybrid fiber concrete[J].China Journal of Highway and Transport,2021,34(6):90-98.
[19]何余良,周仁甫,胡立普,等.混杂纤维混凝土螺栓剪力键疲劳性能[J].长安大学学报(自然科学版),2021,41(3):95-105.
HE Yu-liang,ZHOU Ren-fu,HU Li-pu,et al.Fatigue properties of bolt connectors in HFRC[J].Journal of Chang’an University(Natural Science Edition),2021,41(3):95-105.
[20]HE Y L,XIANG Y Q,SI L L,et al.Mechanical behavior of steel-HFRC composite girders[J].Journal of Bridge Engineering,2018,23(10):040180701.
[21]YIN C,YU M,HUANG L,et al.Finite element modeling of steel-polypropylene hybrid fiber reinforced concrete using modified concrete damaged plasticity[J].Engineering Structures,2017,148:23-35.
[22]Eurocode 2,Design of concrete structures-Part 2:Concrete bridges-design and detailing rules[S].
[23]CHI Y,XU L H,YU H S.Plasticity model for hybrid fiber-reinforced concrete under true triaxial compression[J].Journal of Engineering Mechanics,2014,140(2):393-405.
[24]徐礼华,梅国栋,黄 乐,等.钢-聚丙烯混杂纤维混凝土轴心受拉应力-应变关系研究[J].土木工程学报,2014,47(7):35-45.
XU Li-hua,MEI Guo-dong,HUANG Le,et al.Study on uniaxial tensile stress-strain relationship of steel-polypropylene hybrid fiber reinforced concrete[J].China Civil Engineering Journal,2014,47(7):35-45.

Memo

Memo:
-
Last Update: 2023-03-30