Your search keyword '"Chunwei Li"' showing total 4 results

1. Experimental Research on the Flexural Performance of RC Rectangular Beams Strengthened by Reverse-Arch Method

Author

Tao Yu, Quansheng Sun, Chunwei Li, and Yancheng Liu

Subjects

reverse-arch method, reinforced concrete beam, flexural performance, CFRP plate, Mathematics, QA1-939

Abstract

Carbon fiber-reinforced polymer (CFRP) reinforcement technology has been widely used in the reinforcement of reinforced concrete (RC) beams. At this stage, high prestressed CFRP board reinforcement is often used in actual reinforcement. However, most reinforced bridges are designed for a long time, and the design value of the protective layer is low, and it is impossible to achieve a large prestressed tension. Therefore, this paper proposes the reverse-arch method to paste the CFRP board and apply low prestress to strengthen the symmetrical RC beam. Through the three-point forward loading test, the cracking load, ultimate load, crack width, mid-span deflection, strain and failure mode of a reverse-arch method-pasted CFRP board-reinforced beam, a directly pasted CFRP board-reinforced beam and an unreinforced beam are compared. The results show that the load-bearing capacity and stiffness of the test beam can be improved by pasting CFRP plates with anti-arch method, but the ductility of the test beam is reduced. Compared with the unreinforced beam, the maximum cracking load and ultimate load are increased by 56% and 63% respectively. The reverse-arch method can produce low prestress, improve the stiffness and bearing capacity of members, and has a good prospect of engineering application.

Published

2021

2. Force Analysis of Self-Anchored Suspension Bridges after Cable Clamp Slippage

Author

Hongfeng Li, Yancheng Liu, Chunwei Li, Hao Hu, and Quansheng Sun

Subjects

self-anchored suspension bridge, cable clamp, slippage, force analysis, Mathematics, QA1-939

Abstract

The slippage of cable clamps during the long-term operation of suspension bridges is a common and detrimental phenomenon. From an experimental point of view, the cable clamp slippage of a suspension bridge was investigated to reveal the effect of this sliding on the force acting on the full bridge. The forces acting on the bridge before and after the slippage were analyzed using a finite element model. The calculation results showed that the cable clamp slippage directly affects the cable forces of the hangers. The hanger cable force decreased by 19.2% when the slippage reached 10.2 cm, while the maximum increase in the cable force of adjacent hangers was 147.7 kN, an increase of 7.25%. The variation of forces in the hanger cable disrupted the force balance of the main girder, thereby producing a torque effect at the corresponding position in the girder, i.e., increased torque. Meanwhile, the slippage affected the axial tension in the main cable and the main girder. The impact of the tower internal force was less than 1%. Hence, the study concluded that the effect of cable clamp slippage is better understood, ensuring the safety of the suspension bridge.

Published

2021

3. Experimental Research on the Flexural Performance of RC Rectangular Beams Strengthened by Reverse-Arch Method

Author

Yancheng Liu, Chunwei Li, Tao Yu, and Quansheng Sun

Subjects

reinforced concrete beam, Ultimate load, Materials science, Physics and Astronomy (miscellaneous), Tension (physics), business.industry, General Mathematics, Stiffness, Structural engineering, Flexural strength, Chemistry (miscellaneous), Deflection (engineering), reverse-arch method, flexural performance, CFRP plate, QA1-939, Computer Science (miscellaneous), medicine, Bearing capacity, medicine.symptom, Ductility, business, Mathematics, Beam (structure)

Abstract

Carbon fiber-reinforced polymer (CFRP) reinforcement technology has been widely used in the reinforcement of reinforced concrete (RC) beams. At this stage, high prestressed CFRP board reinforcement is often used in actual reinforcement. However, most reinforced bridges are designed for a long time, and the design value of the protective layer is low, and it is impossible to achieve a large prestressed tension. Therefore, this paper proposes the reverse-arch method to paste the CFRP board and apply low prestress to strengthen the symmetrical RC beam. Through the three-point forward loading test, the cracking load, ultimate load, crack width, mid-span deflection, strain and failure mode of a reverse-arch method-pasted CFRP board-reinforced beam, a directly pasted CFRP board-reinforced beam and an unreinforced beam are compared. The results show that the load-bearing capacity and stiffness of the test beam can be improved by pasting CFRP plates with anti-arch method, but the ductility of the test beam is reduced. Compared with the unreinforced beam, the maximum cracking load and ultimate load are increased by 56% and 63% respectively. The reverse-arch method can produce low prestress, improve the stiffness and bearing capacity of members, and has a good prospect of engineering application.

Published

2021

4. Force Analysis of Self-Anchored Suspension Bridges after Cable Clamp Slippage

Author

Chunwei Li, Yancheng Liu, Hongfeng Li, Quansheng Sun, and Hao Hu

Subjects

Materials science, Physics and Astronomy (miscellaneous), business.industry, Tension (physics), General Mathematics, Structural engineering, self-anchored suspension bridge, cable clamp, Finite element method, Clamp, Chemistry (miscellaneous), Girder, slippage, force analysis, QA1-939, Computer Science (miscellaneous), Torque, Slippage, business, Suspension (vehicle), Tower, Mathematics

Abstract

The slippage of cable clamps during the long-term operation of suspension bridges is a common and detrimental phenomenon. From an experimental point of view, the cable clamp slippage of a suspension bridge was investigated to reveal the effect of this sliding on the force acting on the full bridge. The forces acting on the bridge before and after the slippage were analyzed using a finite element model. The calculation results showed that the cable clamp slippage directly affects the cable forces of the hangers. The hanger cable force decreased by 19.2% when the slippage reached 10.2 cm, while the maximum increase in the cable force of adjacent hangers was 147.7 kN, an increase of 7.25%. The variation of forces in the hanger cable disrupted the force balance of the main girder, thereby producing a torque effect at the corresponding position in the girder, i.e., increased torque. Meanwhile, the slippage affected the axial tension in the main cable and the main girder. The impact of the tower internal force was less than 1%. Hence, the study concluded that the effect of cable clamp slippage is better understood, ensuring the safety of the suspension bridge.

Published

2021