Calculation model of concrete-filled steel tube arch bridges based on the “arch effect”

Wang, Shaorui; Li, Yingbin; Zengwu, Liu; Tianlei, Cheng

doi:10.3389/fmats.2022.1084999

Cited by 2 publications

(2 citation statements)

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“…Gradual loading during calculations was implemented through time step increments, with each adjacent time step having a load increment of 2000 N. The calculation results are presented in Table 4. pacity [37][38][39][40][41][42]. We separately calculated the ultimate load-bearing capacity of Models 1 and 2 under four loading scenarios: mid-span loading, quarter-span single-point loading, symmetric loading at quarter-span, and full-span uniformly distributed load (as shown in Figure 16).…”

Section: Ultimate Load-bearing Capacity: Loading Scenarios and Resultsmentioning

confidence: 99%

“…After the completion of the sixth construction phase, the load-bearing distribution between and within the external concrete rings becomes more uniform, avoiding noticeable stress discontinuities. To quantitatively analyze the effect of uneven stress distribution between and within the rings of external concrete on the structure’s load-bearing performance, we referenced other scholars’ research methods in the arch bridge’s ultimate load-bearing capacity [ 37 , 38 , 39 , 40 , 41 , 42 ]. We separately calculated the ultimate load-bearing capacity of Models 1 and 2 under four loading scenarios: mid-span loading, quarter-span single-point loading, symmetric loading at quarter-span, and full-span uniformly distributed load (as shown in Figure 16 ).…”

Section: Ultimate Load-bearing Capacity Analysismentioning

confidence: 99%

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Evolution Law of Concrete Interface Stress of Rigid-Frame Arch under Construction and Its Impact on Ultimate Load-Bearing Capacity

Yong-hui

Luo

Zhou

et al. 2023

Sensors

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To study the evolution of stress on the ring and segment interfaces during the construction process of the concrete encapsulation of the main arch ring in a rigid-frame arch bridge, alongside its impact on the ultimate load-bearing capacity of the main arch ring, a 1:10 scale model experiment was conducted by taking the 600 m Tian’e Longtan Bridge as the prototype. The key cross-section concrete strain data were collected during the entire construction process of the main arch ring via fiber-optic strain sensors, which were used to investigate the stress evolution at ring and segment interfaces. ANSYS APDL was employed to simulate the ultimate bearing capacity under various loading conditions of two different finite element models, which were, respectively, formed segmentally and by single pouring. The results revealed that (1) after the closure of the concrete encapsulation of the main arch ring, the concrete stress in the cross-section exhibits significant stress disparities. At the same cross-section, the level of the web concrete stress can reach 76% of the floor concrete stress, while the roof concrete stress level is less than 20% of the floor concrete stress. (2) At the junction of two adjacent work planes, there are considerable differences in the stress levels of the concrete on both sides. After the closure of the main arch ring, the intersegment stress ratios of the floor, web, and roof concrete are 60~70%, 40~60%, and 0~5%, respectively. (3) Loading conditions remarkably affected the ultimate bearing capacity of the main arch ring. Under mid-span loading and 1/4 span symmetrical loading conditions, compared to single-pour concrete encapsulation, the ultimate bearing capacity of the main arch ring with concrete encapsulated by segmented and ring-divided pouring decreased by 19.16% and 5.23%, respectively, compared to single-pour concrete encapsulation. This suggests that the non-uniformity of stress distribution in the concrete sheath can lead to reductions in the ultimate bearing capacity of the arch ring.

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Section: Ultimate Load-bearing Capacity: Loading Scenarios and Resultsmentioning

confidence: 99%

Section: Ultimate Load-bearing Capacity Analysismentioning

confidence: 99%

Evolution Law of Concrete Interface Stress of Rigid-Frame Arch under Construction and Its Impact on Ultimate Load-Bearing Capacity

Yong-hui

Luo

Zhou

et al. 2023

Sensors

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Analysis of modern approaches to the design and construction of arch bridges using tube-reinforced concrete

Astankov

2023

Russian journal of transport engineering

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This article is a part of the author’s dissertation research. The paper discusses experience of application of tube-reinforced concrete structures in bridge construction on the example of facilities built over the last 30 years in the People’s Republic of China. The peculiarities of the bridge construction over the Xun River in Pingnan County, Guangxi Province, with a record span are considered. The author has made a review of outstanding facilities built with the use of long span braced arches made of tube-reinforced concrete elements working mainly in off-centre compression. Various tube-reinforced concrete arch bridge spans erection techniques, advantages and disadvantages of each method are considered. The technology of tube concrete coating, designs and construction methods of facilities with the use of long span solid cross-section arches with a tie for the bridge constructions of medium and large spans are analysed in detail. The review of modern research works in the field of bending arches operation is carried out, in comparison with the model assuming the operation of the tube-reinforced concrete element as an off-centre compressed column is made, which in the future can provide more effective use of material properties in design. Modern approaches to the tube-reinforced concrete elements study are considered. It is concluded that there is a large amount of research on the work of tube-reinforced concrete in off-centre compression with insufficient experimental data on the work of arch tube-reinforced concrete structures working in bending. It is of interest to study the possibility of tube-reinforced concrete application for small spans in the bridge construction. The author has established the prospect of using tube-reinforced concrete structures for arch spans in the construction of small soil-backfilled bridges, which is especially important in areas remote from the construction industry with a poorly developed network of motorways. The necessity of carrying out the bending tube-reinforced concrete structures research works for realisation of this purpose is revealed.

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Calculation model of concrete-filled steel tube arch bridges based on the “arch effect”

Cited by 2 publications

References 18 publications

Evolution Law of Concrete Interface Stress of Rigid-Frame Arch under Construction and Its Impact on Ultimate Load-Bearing Capacity

Evolution Law of Concrete Interface Stress of Rigid-Frame Arch under Construction and Its Impact on Ultimate Load-Bearing Capacity

Analysis of modern approaches to the design and construction of arch bridges using tube-reinforced concrete

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