Journal of Jilin University(Engineering and Technology Edition) ›› 2025, Vol. 55 ›› Issue (8): 2619-2629.doi: 10.13229/j.cnki.jdxbgxb.20231193

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Calculation method of deflection of composite box beam with considering the deformation of the steel truss web

Fang-xu WANG(),Shi-zhong LIU,Xia-lin YANG,Ning JIANG,Xin-yi LIU,Chi MA   

  1. School of Civil Engineering,Lanzhou Jiaotong University,Lanzhou 730070,China
  • Received:2023-11-02 Online:2025-08-01 Published:2025-11-14

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Abstract:

To analyze the influence of steel truss web deformation on the deflection of the steel truss composite box beam. Firstly, establishing displacement functions based on the rotation angle of the top flange, bottom flange, steel truss web,and composite box beam section, the expression of deflection displacement of composite box beam was obtained by energy variational method. Secondly, the beam segment analysis element stiffness matrix and nodal load array were derived based on the finite beam segment method, and the deflection displacement of the composite box beam was solved. Thirally, the deflection of the composite box beam under different load conditions for the compasite box beam were analyzed and compared with the elementary beam theory. Lastly, the influence of structural parameters such as height-span ratio, diameter of steel truss web, wall thickness of steel truss web and tilt angle of steel truss web on additional deflection were analyzed. The results show that, the influence of the deformation of the steel truss web deformation on the deflection of the composite box beam cannot be ignored, the maximum deflection error of the composite box beam was 27.75% by using the elementary beam theory. Among the structural parameters influence the deformation of the steel truss web, the wall thickness of steel truss web has the greatest influence on the additional deflection, followed by the diameter of steel truss web, the height-span ratio and the tilt angle of steel truss web. In addition, the additional deflection ratio was positively correlated with the height-span ratio and tilt angle of steel truss web, negatively correlated with the diameter of steel truss web and wall thickness of steel truss web.

Key words: bridge and tunnel engineering, steel truss web deformation, deflection, energy variational method, finite beam segment method

CLC Number: 

  • U443.3

Fig.1

Diagram of composite box beam with steel truss web"

Fig.2

Deformation diagram"

Fig.3

Diagram composite box beam cross-section"

Fig.4

Equivalent conversion of steel truss web"

Fig.5

Finite beam segment model"

Fig.6

Diagram of composite box beam (unit: m)"

Table 1

Node details parameters"

组件几何尺寸/mm数量材料
腹杆351×162Q345C
开孔钢板1 000×450×202Q345C
对穿钢筋2522
键销钢筋251010
连接螺栓M168

Fig.7

Calculation flowchart diagram"

Fig.8

Finite element model"

Fig.9

Simplified loading diagram of condition Ⅰ"

Fig.10

Load-deflection curve in condition Ⅰ"

Fig.11

Simplified loading diagram of condition Ⅱ"

Fig.12

Load-deflection curve in condition Ⅱ"

Fig.13

Simplified loading diagram of condition Ⅲ"

Fig.14

Load-deflection curve in condition Ⅲ"

Table 2

Comparison of mid-span deflection under different conditions"

荷载形式wiρ计算方法
EulerANSYS-M1ANSYS-M2

Eq.

(26)

简支梁

集中荷载

wi /mm-2.133-2.469-2.611-2.725
ρ/%15.7422.4127.75

简支梁

均布荷载

wi /mm-1.633-1.835-1.951-2.035
ρ/%12.3419.4724.62

连续梁

均布荷载

wi /mm-0.797-0.892-0.944-0.985
ρ/%11.9118.4123.61

Table 3

Parameter value table"

参数高跨比腹杆直径/mm腹杆壁厚/mm腹杆倾角/(°)
23/1163311460.10
23/1943411664.34
23/2723511867.00
23/3113612069.24
23/3503712271.07

Fig.15

Mid-span deflection with different height- span ratio of Condition Ⅰ"

Fig.16

Mid-span deflection with different height- span ratio of condition Ⅱ"

Fig.17

Mid-span deflection with different diameter of steel truss web of condition Ⅰ"

Fig.18

Mid-span deflection with different diameter of steel truss web of condition Ⅱ"

Fig.19

Mid-span deflection with different wall thicknesses of steel truss web of condition Ⅰ"

Fig.20

Mid-span deflection with different wall thicknesses of steel truss web of condition Ⅱ"

Fig.21

Mid-span deflection with different tilt angle of steel truss web of condition Ⅰ"

Fig.22

Mid-span deflection with different tilt angle of steel truss web of condition Ⅱ"

Table 4

Significance index"

荷载形式高跨比腹杆直径腹杆壁厚腹杆倾角
集中荷载0.1350.1970.2690.132
均布荷载0.1500.1750.2380.099
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