Showing total 3,832 results

1. 93‐5: Late‐News Paper: Highly Stretchable Display with Serpentine‐shaped Design and Intrinsically Stretchable Materials.

Author

Yoon, Jangyeol, Kim, Seongwon, Seo, Woosuk, Lee, Gyujeong, Shin, Heonjung, Hong, Jong-Ho, Kim, Yongjo, and Lee, Changhee

Subjects

BRIDGE design & construction, ELECTRODES, DENSITY, METALS

Abstract

Stretchable displays based on conventional materials exhibit a trade‐off relationship between the pixel density and the stretchability. In this paper, we have demonstrated overcoming the technological limitations of stretchable displays through the optimization of serpentine‐shaped bridge design and the application of stretchable metal electrodes. The application of stretchable electrodes has increased stretchability by over 30% without compromising pixel density. [ABSTRACT FROM AUTHOR]

Published

2024

2. The concept of bridge substructure planning using Revit application for BIM approach.

Author

Lubis, Ahmad Mawardi, Rifai, Andri Irfan, Sari, Yusra Aulia, and Handayani, Susanty

Subjects

BUILDING information modeling, CONSTRUCTION projects, LITERATURE reviews, BRIDGE design & construction, CIVIL engineering

Abstract

Bridges are one of the most important infrastructures because they are a link between 2 different points that have an impact on a country's economy. The impact of bridge construction can be controlled with good design and design. In this paper, the author will model the planning of the lower structure of the bridge using Revit Software as a form of Building Information Modeling (BIM) technology. This paper uses references from international and national journals taken from Google Scholar. The references obtained are useful in making a literature review that has a relationship with the topic discussed by the author, namely bridges. It is known that the use of BIM technology is very helpful and makes it easier for engineers in the implementation of a construction project. Therefore, this research enhances the understanding and application of digital tools in civil engineering projects, contributing to innovation in construction practices. [ABSTRACT FROM AUTHOR]

Published

2024

3. Research on Monitoring Technology for Frame Piers of Continuous Box-Girder Bridges Constructed by the Cantilever Method.

Author

Liu, Fanggang, Gu, Lixiong, Fu, Haishan, Li, Xinping, Zhao, Xiaolong, Ma, Niujing, and Liu, Shixun

Subjects

BOX beams, BOX girder bridges, STRAINS & stresses (Mechanics), BRIDGE design & construction, CONTINUOUS bridges, PIERS

Abstract

This paper focuses on the analysis of the stress state of a large-span frame pier-continuous box girder bridge with pier crossbeams anchored by pier crossbeams on the main pier of the Guangfo-Zhao Expressway. The bridge is constructed by the cantilever method, and a refined finite element model of the entire bridge is established using the finite element software Midas/FEA to analyze the stress state of the frame pier during the cantilever construction process. It is found that under the possible combined action of an unbalanced load during construction, the torsional resistance of the frame pier crossbeam does not meet the requirements of the design code. In order to eliminate the torsion of the frame piers, counterweights were used to monitor the frame piers during the construction of the box girders. In this paper, the theoretical calculation formula of the inclination angle of the end section of the frame pier crossbeam with the change of unbalanced bending moment, the calculation formula of the relationship between the horizontal displacement of the frame pier and the unbalanced bending moment, and the calculation formula corresponding to the relationship with the water tank counterweight are derived using the structural mechanics method. Two monitoring methods for the frame pier are proposed. In the construction monitoring of the bridge, the numerical fitting formula obtained by finite element numerical analysis calculation is compared with the calculated formula obtained by substituting the design parameters of the frame pier into the theoretical formula. The basic constants in both formulas are basically equal, verifying the correctness of the monitoring calculation formula proposed in this paper for the torsional resistance of the frame pier crossbeam. The applicability of the two monitoring methods is also compared and analyzed. This paper takes the main pier of Chaoyang overpass's mainline bridge as the engineering background, which adopts the framework pier with a large-span prestressed concrete continuous box girder bridge. It analyzes the torsional state of the beam of the framework pier during the bridge construction process and conducts research on the construction monitoring of the framework pier crossbeam, providing valuable references for the construction monitoring of framework pier crossbeams in the construction of large-span framework pier continuous bridges in the future. The research results of this paper can provide assistance for the construction monitoring of similar projects. This paper's innovation primarily resides in employing structural mechanics methods to compute the torsion of frame piers. On this basis, a simplified beam torsion calculation formula is proposed to strengthen its practical application in construction monitoring. The findings of this paper can help in the construction monitoring of similar projects. [ABSTRACT FROM AUTHOR]

Published

2024

4. STEM Integration in Sixth Grade: Desligning and Constructing Paper Bridges.

Author

English, Lyn D. and King, Donna

Subjects

STEM education, ENGINEERING education, STUDENTS, SCAFFOLDED instruction, BRIDGE design & construction

Abstract

In this article, we report on sixth-grade students' responses to a set of problem activities that required the application of mathematics, science, and engineering knowledge in designing and constructing a paper bridge that could withstand an optimal load. Increasing students' application and awareness of their disciplinary learning and how they are applying this in an integrated STEM activity remains a challenge for educators. In addressing this issue, we included a focus on knowledge reflection and knowledge scaffolding through thought-provoking student workbooks. Among the findings are students' capabilities in planning, designing, reflecting, constructing, and redesigning. Students' planning indicated that they could justify their proposed bridge type/s, which often included a combination of types, by referring to their STEM understandings. At the same time, students remained cognizant of the problem boundaries. Students' design sketches indicated an awareness of the problem constraints, an understanding of basic engineering principles, and an application of mathematics and science knowledge. Students' reflections on their actions helped them to improve their bridge constructions. Suggestions are presented for knowledge scaffolding to facilitate the flexible and innovative application of STEM learning to new problem situations. [ABSTRACT FROM AUTHOR]

Published

2019

5. STUDYING THE INFLUENCE OF ENGINE SPEED ON THE ENTIRE PROCESS OF SPAN-LOWERING OF THE HEAVY MECHANIZED BRIDGE.

Author

Duong Van Le, Thang Duc Tran, Quyen Manh Dao, and Dat Van Chu

Subjects

BRIDGE design & construction, MILITARY bridges, ARTIFICIAL intelligence, ARTIFICIAL neural networks, DEEP learning

Abstract

The paper presents a dynamic model of the TMM-3M heavy mechanized bridge during the span lowering stage. The model is constructed as a multi-body mechanical system, taking into account the elastic deformation of the cable, rear outriggers, front tires, and front suspension system. It is a mechanical model driven by a cable mechanism. Lagrangian equations of the second kind have been applied to establish a system of differential equations describing the oscillations of the mechanical system and serve as the basis for investigating the dynamics of the span-lowering process. The system of differential equations is solved using numerical methods based on MATLAB simulation software. The study has revealed laws of the displacement, velocity, and acceleration of components within the mechanical system, especially those related to the bridge span depending on the choice of the drive speed of the engine during lowering by operator. The research results show that the lowering time increases from 52 seconds to 104 seconds when the engine speed decreases from 1800 rpm to 900 rpm. The tension force on the cable is surveyed to confirm the safety conditions during the span-lowering process. The study also provides recommendations for selecting appropriate engine speeds to minimize span-lowering time while ensuring the safety conditions of the TMM-3M bridge during the span-lowering process. This research is an important part of a comprehensive study on the working process of the heavy mechanized bridge TMM-3M to make practical improvements, aiming to reduce deployment time, decrease the number of deployment crew members, and increase the automation capability of the equipment. [ABSTRACT FROM AUTHOR]

Published

2024

6. Technical Papers: Development of FRP Bridges in the UK - An Overview.

Author

Canning, Lee and Luke, Sam

Subjects

*BRIDGE design & construction, *COST effectiveness, *STRUCTURAL health monitoring, *MATERIALS science, *CONCRETE-filled tubes, *FIBROUS composites

Abstract

The emphasis in bridge design and construction technology in the UK has shifted in recent decades towards improved durability and quick construction, with whole life cost and low maintenance gradually becoming as important as initial capital cost. In conjunction with this, reduced disruption to the travelling public has become more important due to general increased travel and congestion on roads and railways. The combination of these two factors was a primary driver in the development of fibrere-inforced polymer (FRP) composite bridge technology, which can provide improved durability and also reduced time of in-situ construction due to large, lightweight components being manufactured off-site (modular construction) and installed simply and quickly. The growth in the application of FRP bridges in the UK is described and highlighted with a number of representative case studies, generally showing the benefits of this technology in reducing whole life cost and disruption to the public. The future work required to further enable the development of FRP bridge technology is described, with the aim of FRP bridges becoming a mainstream competitor to other bridge materials and technologies. [ABSTRACT FROM AUTHOR]

Published

2010

7. Technical Papers: GFRP Reinforced Corrosion-Free Bridge Deck Slabs Based on ISIS Winnipeg Principles.

Author

Mufti, Aftab, Bakht, Baidar, and Tadros, Gamil

Subjects

*GLASS fibers, *BRIDGE design & construction, *CORROSION fatigue of metals, *CONSTRUCTION slabs, *CONSTRUCTION

Abstract

In places where deicing salts are used to keep roads free of ice, the bridge components most prone to corrosion are concrete deck slabs, which can be made corrosion-free by replacing the steel reinforcement by bars made of fibre reinforced polymer (FRP). Recent experimental investigation has shown that only the transverse bars at the bottom of the deck slab confine the slab for full arching action. The rest of the reinforcement in the two assemblies only controls the widths of environmental and fatigue-induced cracks. An experimental fatigue study on full-scale models of deck slabs showed that slabs with steel bars have the poorest fatigue resistance and slabs with glass fibre reinforced polymer (GFRP) bars the best. ISIS Canada conducted field studies in 2005 to show that the GFRP is not attacked by alkaline reaction in concrete. Because of this finding the Canadian Bridge Highway Bridge Design Code (CSA S06-06) permits GFRP as a primary reinforcement. [ABSTRACT FROM AUTHOR]

Published

2010

8. The new stone age.

Author

Ravilious, Kate

Subjects

BRIDGE design & construction, STONE Age, PAPER chemicals industry, RIVER engineering, WIND turbines

Abstract

This article reports on the building of a bridge with a reference to the book of Roelof Schuiling, an engineer. A geochemist at Utrecht University in the Netherlands, Schuiling has spent 15 years developing an extraordinary construction technique that could see rock bridges, walls and dams sprout from the seabed, driven by the power of chemistry on an unprecedented scale. The project could even help to dispose of millions of tonnes of waste acid from India's chemical industry by locking it up in the fabric of the bridge. Earlier this year, Schuiling read a scientific paper that suggested placing wind turbines on the string of reefs and islands between Sri Lanka and India called Adam's Bridge.

Published

2004

9. Time-Dependent Reliability-Based Methodology for Assessing Fracture Toughness Requirements for Highway Bridges.

Author

Chien, Michelle Yong Xin, Kian, Mohammad Javad Tolou, Chehrazi, Ali, and Walbridge, Scott

Subjects

MONTE Carlo method, BRITTLE fractures, CLIMATIC zones, BRIDGE design & construction, STRAIN rate

Abstract

The provisions for avoidance of brittle fracture in various bridge design codes vary in complexity, from the simple tables in North American codes, which present impact energy requirements as a function of steel grade, climate zone, and member type, to the more involved methods presented in the Eurocodes, which allow factors such as plate thickness, demand-to-capacity ratio, and strain rate to be considered. While these provisions generally appear to be meeting the needs of the code users, two issues are noteworthy. The first is that the North American provisions offer less flexibility and guidance for handling unusual situations than the Eurocode methods. The second is that very few studies can be found in the literature attempting to assess the level of reliability against brittle fracture provided by any of the existing design provisions. The current paper presents a study that attempts to make a first step in addressing both issues, using the Canadian design provisions as an example. Specifically, this paper describes a time-dependent Monte Carlo simulation (MCS)-based probabilistic model and then uses it to assess the extent to which the Canadian provisions provide consistent and adequate levels of reliability against brittle fracture over a range of steel grades, plate thicknesses, and climates. Based on the analysis results, areas of potential improvement of these requirements are identified. [ABSTRACT FROM AUTHOR]

Published

2024

10. Risk assessment of bridge construction investigated using random forest algorithm.

Author

Wu, Ying, Wang, Yigang, Liu, Hongbing, Xie, Liping, Jiao, Lili, and Lu, Pengzhen

Subjects

RANDOM forest algorithms, BRIDGE design & construction, CONSTRUCTION management, DECISION trees, ENVIRONMENTAL risk

Abstract

Bridge construction collapse is one of the most common bridge safety accidents. At present, evaluation results are often affected by the ability and experience of the assessor. Therefore, it is difficult to quickly, accurately and effectively evaluate the risk in the process of bridge construction. Moreover, key factors that can prevent accidents can hardly find from the existing bridge construction safety management and evaluation method. This paper analyzes and classifies the artificial and environmental risk factors that affect the bridge construction stage, and establishes 26 risk factors in 5 categories according to the characteristics of bridge construction and the actual situation of the project. Random forest (RF) algorithm is a non-parametric machine learning method based on decision tree, which does not need to be scored by experts in advance and avoids the influence of subjective factors. Compared with other analysis methods, random forest algorithm has the advantages of accurate and robust risk assessment results. Based on the advantages of random forest algorithm and the characteristics of bridge construction risk, this paper uses random forest algorithm to evaluate the bridge construction risk, and ranks the importance of indicators, and identify the index that has a greater influence on the risk. In order to verify the applicability and feasibility of the proposed method, a typical urban complex pedestrian bridge was taken as an example for actual engineering evaluation and verification. The results obtained are basically consistent with the actual risk assessment results of the pedestrian bridge. [ABSTRACT FROM AUTHOR]

Published

2024

11. An Optimization-Based Case Study of Aluminum Pedestrian Bridge Decks.

Author

Strand, Peter Nilsson, Falkenberg, Emelie, Fredriksson, Markus, Al-Emrani, Mohammad, Cusson, Benoit, and Nyström, Henrik

Subjects

BRIDGE design & construction, ALUMINUM alloys, MECHANICAL behavior of materials, SPOT welding, MAINTENANCE

Abstract

In Sweden, steel bridges are the most common solution regarding prefabricated short-span (15-35 m) pedestrian bridges. The most common bridge type for this application is a carbon steel truss bridge with an orthotropic deck consisting of a 10-12 mm deck plate and trapezoidal stiffeners. For these bridges, the deck is the main driver regarding economic and environmental costs, originating from, e.g., high material consumption and maintenance activities. This paper aims to compare the economic aspects between a conventional steel deck and an extruded aluminum deck from an investment cost perspective. The aluminum deck is homogenous, i.e., containing no mechanical connections. To perform this case study, an optimization routine is developed and executed for the aluminum alternative. This optimization study targets the minimum weight and is constrained by the Eurocode design code. A sub-model approach is adopted for the numerical analysis, based on shell and solid elements. The procedure to go from a cross-section defined by a set of parameters to reach the optimized bridge deck is presented. The studies that are reported in this paper show that the developed optimization routine gives satisfactory results. Furthermore, they indicate that homogenous extruded aluminum decks can be a viable deck option for pedestrian bridges. [ABSTRACT FROM AUTHOR]

Published

2023

12. Numerical Investigation of Tsunami Wave Force Acting on Twin Box-Girder Bridges.

Author

Yan, Quansheng, Li, Xianyun, Jia, Buyu, Yu, Xiaolin, and Luo, Yufan

Subjects

COMPUTATIONAL fluid dynamics, BRIDGE floors, ROGUE waves, WAVE forces, BRIDGE design & construction, TSUNAMI hazard zones, TSUNAMIS

Abstract

Earthquakes in coastal areas frequently trigger tsunami waves, posing significant threats to low-lying coastal bridges. Investigating extreme wave force on bridge deck is crucial for understanding bridge damage mechanisms. However, the majority of current research focuses on single bridge deck, with limited analysis of wave impacts on twin bridge decks. In this paper, solitary wave is utilized to simulate tsunami wave, and a two-dimensional (2D) computational fluid dynamics (CFDs) model to analyze wave–bridge interactions and investigate the impact of tsunami wave on adjacent twin box-girder bridge decks. The numerical model was validated by solitary wave theory and wave force data obtained from the published experiment. Based on this model, the effects of the submergence coefficient, wave height, and deck spacing on the horizontal and vertical forces on the twin box-girder bridge decks were analyzed and compared with those in a single box-girder bridge deck. The results indicate that, firstly, due to wave reflection and the trapped water, the vertical wave force on the twin forward bridge deck significantly surpasses that on the single bridge deck. Furthermore, the twin backward bridge deck experiences greater horizontal force than single deck when the deck is completely submerged. Secondly, the maximum wave force on the twin bridge decks does not always consistently decrease with increasing deck spacing. Finally, the negative horizontal force would exceed the positive horizontal force on the twin forward bridge deck under higher wave. This paper delineates the disparities between twin and single box-girder bridge deck responses to wave action and analyzes the influencing factors. Such insights are pivotal for coastal bridge construction and natural disaster risk assessment. [ABSTRACT FROM AUTHOR]

Published

2024

13. Risk-informed design and safety assessment of structures in a changing climate: a review of U.S. practice and a path forward.

Author

Ghosn, Michel and Ellingwood, Bruce R.

Subjects

SAFETY standards, STRUCTURAL reliability, MAP design, BRIDGE design & construction, HAZARDS, SERVICE life, CLIMATE change

Abstract

Standards for the design of bridges, buildings and other infrastructure specify design loads for climatic hazards such as temperature, snow, wind, and floods based on return periods presented in maps or tables that account for regional differences. These design loads were developed from statistical analyses of historical hazard data under the assumption that the past is representative of the future. Climate change may affect the frequencies and intensities of environmental hazards which, depending on regional variations, raises questions as to whether structures designed to current specifications will meet minimum safety standards over their future service lives. This paper critically appraises issues related to using historical hazard data for future designs. It reviews basic principles of uniform reliability, that modern design codes use as the basis for ensuring minimum levels of safety, describing the relationship between hazard return periods, structural reliability, risk and the maximum loads expected within a structure's service life. Simple examples involving wind effects on structures demonstrate how to calibrate structural design hazard maps for climate-related extreme events to meet the minimum standards of safety implied in current specifications. The paper also introduces a possible practical approach to account for climate change when designing new structures and assessing the safety of existing facilities. [ABSTRACT FROM AUTHOR]

Published

2024

14. Development of a Multi-Robot System for Pier Construction.

Author

Kim, Hyo-Gon, Park, Ji-Hyun, Kim, Jong-Chan, Hwang, Jeong-Hwan, Park, Jeong-Woo, Park, In-Gyu, Lee, Hyo-Jun, Noh, Kyoungseok, Choi, Young-Ho, and Suh, Jin-Ho

Subjects

BUILDING sites, PIERS, BRIDGE design & construction, MOBILE robots, ROBOT control systems, BRIDGE floors, CONSTRUCTION industry

Abstract

The construction industry is a challenging field for the application of robots. In particular, bridge construction, which involves many tasks at great heights, makes it difficult to implement robots. To construct a bridge, it is necessary to build numerous piers that can support the bridge deck. Pier construction involves a series of tasks including rebar connection, formwork installation, concrete pouring, formwork dismantling, and formwork reinstallation. These activities require working at heights, presenting a significant risk of falls. If bridge construction could be performed remotely using robots instead of relying on human labor, it would greatly contribute to the safety of bridge construction. This paper proposes a multi-robot system capable of remote operation and automation for rebar structure connection, concrete pouring, and concrete vibrating tasks in pier construction. The proposed multi-robot system for pier construction is composed of three robot systems. Each robot system consists of a robot arm mounted on a mobile robot that can move along rails. And to apply the proposed system to a construction site, it is essential to implement a compliance control algorithm that adapts to external forces. In this paper, we propose an admittance control that takes into account the weight of the tool for the compliance control of the proposed robot, which performs tasks by switching between various construction tools of different weights. Furthermore, we propose a synchronization control method for the multi-robot system to connect reinforcing structures. We validated the proposed algorithm through simulation. Furthermore, we developed a prototype of the proposed system to verify the feasibility of the suggested hardware design and control. [ABSTRACT FROM AUTHOR]

Published

2024

15. ASCE Awards Based on Meritorious Papers.

Subjects

BRIDGE design & construction, AWARDS, CIVIL engineering, PROFESSIONAL associations, CIVIL engineers

Abstract

Presents call for nominations for the 2006 American Society of Civil Engineers Awards. Aim of the ASCE Honors and Awards Programs to advance the engineering profession by emphasizing exceptionally meritorious achievement; Complete descriptions of the awards and limitations that apply; Content of the nominations for papers; Contact information.

Published

2005

16. Review of design and innovative construction of steel truss cable-stayed bridges in China.

Author

Yu, Xiangmin, Chen, Dewei, and Yu, Jinhong

Subjects

CABLE-stayed bridges, BRIDGE design & construction, SUSPENSION bridges, STEEL

Abstract

Many steel truss cable-stayed bridges have been built in China in the past two decades, providing a wealth of design and construction experience. This paper provides a review of their development, the structural configurations used, the mechanical characteristics of decks, pylons and cables, and the various innovative construction methods adopted. With main spans now exceeding 1 km, the sturdy structures are mainly used for combined rail-and-road crossings in preference to more flexible suspension bridges. The aim of the paper is to provide a comprehensive and useful reference for further design and construction of steel truss cable-stayed bridges worldwide. [ABSTRACT FROM AUTHOR]

Published

2024

17. RECENTLY PUBLISHED PAPERS.

Subjects

BRIDGE design & construction, CIVIL engineering, BRIDGE construction industry, FACILITY management, INDUSTRIAL buildings, PUBLISHING

Abstract

The article presents a list of papers related to civil engineering that were published in the 2005 issue of the journal "Civil Engineering." Some of the papers are: "Innovative Retrofitted Reinforcement Techniques for Masonry Arch Bridges," by S.K. Sumon; "A Risk-Based Decision-Support System for Bridge Management," by K.D. Flaig and R.J. Lark; "Thermal Creep Analysis of Concrete Bridges," by Q. Xu and C. Burgoyne; and "Models for Evaluating the Costs of Bridge Failure," by S.M. Wong, C.J. Onof and R.E. Hobbs.

Published

2005

18. Quantitative analysis of the importance and correlation of urban bridges and roads in the study of road network vulnerability.

Author

Xiao, Qinghua, Huang, Hongwei, and Tang, Chao

Subjects

CITY traffic, BRIDGE design & construction, STATISTICAL correlation, ROAD construction, QUANTITATIVE research, URBAN growth

Abstract

The city development is closely related to the performance of the transportation network system. Bridges and roads are important parts of the transportation system, and are also inseparable components of the transportation network. However, the effect of the correlation between bridges and roads on the network system has not been studies thoroughly in the literature. Therefore, it is necessary to analyse the vulnerability of the road network when both bridges and roads are involved. In this paper, the urban road network is modeled into the form of network connection and node, based on the analysis of the related research results of road network vulnerability in the literature. Taking the urban roads at all levels as the connection and the transportation hubs (including bridges) as the nodes, the paper puts forward the corresponding measurement indexes and calculation methods, and establishes the importance and correlation analysis model of roads and bridges in the urban road network. At last, the model is applied to the road network which is 5 × 3 km2 besides Yangpu Bridge of Shanghai for verification, the importance and correlation of specific roads and bridges in the analyzed urban road network are calculated, which provides a certain basis for dealing with various emergencies leading to the decline of urban road network vulnerability. In this paper, the importance analysis of urban road network is extended to the bridge correlation analysis, so that the proposed model of the vulnerability assessment of the urban road network system is more suitable for the increasingly demand of road and bridge construction in China, and provides a certain basis for dealing with the decline of road network vulnerability caused by various emergencies. [ABSTRACT FROM AUTHOR]

Published

2023

19. Accelerated Bridge Construction.

Author

Azizinamini, Atorod

Subjects

BRIDGE design & construction, CONCRETE columns, CONCRETE slabs, COMPOSITE construction, CONCRETE-filled tubes, SHAKING table tests, PRESTRESSED concrete bridges, ACOUSTIC emission testing

Abstract

The Special Collection on Accelerated Bridge Construction is available in the ASCE library (https://ascelibrary.org/page/jbenf2/accelerated bridge construction). In this technique, a new bridge superstructure is constructed on an offset from the existing bridge, then the existing bridge superstructure is demolished and the new bridge superstructure is slid in place over the existing substructure or a new substructure, which is built underneath the existing bridge prior to sliding the new bridge superstructure. For repairing bridge columns, Farzad et al. ([9]), in their paper entitled "Retrofitting of bridge columns using UHPC", propose an innovative technique to repair damaged bridge columns by the use of thin layers of UHPC, which are applied to column concrete substrates. The bridge towers utilized segmental construction for each pier leg with steel pier caps; in addition, prefabricated deck panels with cast-in-place closure joints were utilized in the bridge superstructure. [Extracted from the article]

Published

2020

20. Safety Risk Analysis of Urban Viaduct Construction Based on Dynamic Weight.

Author

Ran, Ruijiang, Wang, Shengmin, Fang, Jun, and Wang, Yajie

Subjects

RISK assessment, ANALYTIC hierarchy process, EXTREME weather, VALUE engineering, BRIDGE design & construction

Abstract

The safety risk analysis of urban elevated bridge construction is an important management method to reduce the loss of safety accidents, and it has significant scientific research value and engineering application value. Therefore, this study proposes a novel analysis method to address these challenges. Firstly, this paper constructs a Work Breakdown Structure (WBS)–Risk Breakdown Structure (RBS) matrix for the safety risk of urban elevated bridge construction in order to achieve a comprehensive and complete identification of the indicator system. Then, a combination of static weights and dynamic weights calculation methods is developed. The static weights are obtained using the analytic hierarchy process, while the dynamic weights are obtained based on the relationship between the dynamic scores of construction safety risk indicators in different construction stages and the preset evaluation levels. Finally, a case study of the Longlingshan elevated bridge project in Wuhan, China, is conducted to validate the feasibility of the proposed model and its potential application in projects. The case analysis for the first time reveals that with the progress of construction, the weights of each indicator continuously change, and the secondary indicators related to environmental factors, such as extreme high-temperature weather, undergo the greatest changes. A comparison of different dynamic weight calculation methods is conducted to highlight the advancement of the proposed model. The research findings of this paper will provide new insights and guidance for improving the construction safety of urban elevated bridge projects. [ABSTRACT FROM AUTHOR]

Published

2024

21. Fatigue and Ultimate Strength Evaluation of GFRP-Reinforced, Laterally-Restrained, Full-Depth Precast Deck Panels with Developed UHPFRC-Filled Transverse Closure Strips.

Author

Sayed Ahmed, Mahmoud, Sennah, Khaled, and Afefy, Hamdy M.

Subjects

FATIGUE limit, FIBER-reinforced concrete, BRIDGE design & construction, FAILURE mode & effects analysis, CONSTRUCTION materials

Abstract

A depth precast deck panel (FDDP) is one element of the prefabricated bridge element and systems (PBES) that allows for quick un-shored assembly of the bridge deck on-site as part of the accelerated bridge construction (ABC) technology. This paper investigates the structural response of full-depth precast deck panels (FDDPs) constructed with new construction materials and connection details. FDDP is cast with normal strength concrete (NSC) and reinforced with high modulus (HM) glass fiber reinforced polymer (GFRP) ribbed bars. The panel-to-girder V-shape connections use the shear pockets to accommodate the clustering of the shear connectors. A novel transverse connection between panels has been developed, featuring three distinct female-to-female joint configurations, each with 175-mm projected GFRP bars extending from the FDDP into the closure strip, complemented by a female vertical shear key and filled with cementitious materials. The ultra-high performance fiber reinforced concrete (UHPFRC) was selectively used to joint-fill the 200-mm transverse joint between adjacent precast panels and the shear pockets connecting the panels to the supporting girders to ensure full shear interaction. Two actual-size FDDP specimens for each type of the three developed joints were erected to perform fatigue tests under the footprint of the Canadian Highway Bridge Design Code (CHBDC) truck wheel loading. The FDDP had a 200-mm thickness, 2500-mm width, and 2400-mm length in traffic direction; the rest was over braced steel twin girders. Two types of fatigue test were performed: incremental variable amplitude fatigue (VAF) loading and constant amplitude fatigue (CAF) loading, followed by monotonically loading the slab ultimate-to-collapse. It was observed that fatigue test results showed that the ultimate capacity of the slab under VAF loading or after 4 million cycles of CAF exceeded the factored design wheel load specified in the CHBDC. Also, the punching shear failure mode was dominant in all the tested FDDP specimens. [ABSTRACT FROM AUTHOR]

Published

2024

22. Experimental Verification of GFRP Bridge Deck Panels Using an Integrated Distributed Fiber Optic Sensing System.

Author

Kulpa, Maciej, Howiacki, Tomasz, Rajchel, Mateusz, Siwowski, Tomasz, and Bednarski, Łukasz

Subjects

BRIDGE floors, BRIDGE design & construction, FIBER-reinforced plastics, INSPECTION & review, DEAD loads (Mechanics)

Abstract

Fiber-reinforced polymer (FRP) composites are promising materials already being used in bridge construction. Lightweight deck panels, mainly used in the rehabilitation or replacement of existing bridges, are the most commonly used FRP bridge components. However, FRP decks are prone to damage due to delamination, matrix cracking, interlaminar cracking, and debonding. In addition, due to their microstructure, FRP materials tend to deteriorate in ways that are not easily detected by visual inspection. Therefore, nondestructive methods should often complement visual inspections aimed at assessing the technical condition of the structure. New measurement techniques are constantly being researched and developed to assist in the evaluation of FRP structures. Distributed fiber optic sensing (DFOS) has been chosen as the main measurement technique of the newly developed FRP bridge deck panel because this technique provides extended advantages compared to the conventional spot gauges. The concept of a component with an integrated DFOS-based system capable of structural control and detection of overloaded vehicles has been developed and verified both in laboratory conditions. The novelty of the presented approach is that sensors (strain-sensing fibers) are precisely embedded in FRP laminates for simultaneous internal strain and vertical displacement (shape change) measurements and delamination detection. The experimental verification of a full-scale deck under static and dynamic loading is described in the paper. The performance of the DFOS system was verified using reference techniques. The results proved the system to be a reliable tool for diagnosing FRP bridge decks. [ABSTRACT FROM AUTHOR]

Published

2024

23. 知识引导的桥梁建造过程时空叙事 三维可视化方法.

Author

朱 军, 赖建波, 谢亚坤, 陈佩菁, and 孙文锦

Subjects

BRIDGE design & construction, THREE-dimensional imaging, CONSTRUCTION management, EXPERIMENTAL groups, ASSOCIATION management

Abstract

Copyright of Geomatics & Information Science of Wuhan University is the property of Geomatics & Information Science of Wuhan University and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

24. Steel solutions for a sustainable bridge infrastructure of today and tomorrow.

Author

Tibolt, Mike and Ochojski, Wojciech

Subjects

HIGH strength steel, CARBON emissions, GREEN infrastructure, BRIDGE design & construction, BRIDGE maintenance & repair

Abstract

Responsible for 70% of the global CO2 emissions, infrastructure has a significant impact on our climate and the related consequences. Bridges are a major keystone of the infrastructure and take a leading position in its decarbonization. In this framework, low‐carbon emission steels play an important role. Low‐carbon emission steels, like ArcelorMittal's XCarb® recycled and renewably produced steels, are already available on the market. Combining scrap and renewable electricity, it offers very low levels of CO2 emissions per ton of finished steel. The present paper describes how different steel solutions can be combined to lower the material input, to simplify the construction process and to reduce the maintenance efforts in bridge construction. The impact of efficient design has been assessed by a Life‐Cycle Assessment (LCA) for bridge solutions with small and medium spans of up to 40 m. The paper concludes with a summary of recently realized bridge projects in Poland. [ABSTRACT FROM AUTHOR]

Published

2024

25. Shear Performance of Prefabricated Steel Ultra-High-Performance Concrete (UHPC) Composite Beams under Combined Tensile and Shear Loads: Single Embedded Nut Bolts vs. Studs.

Author

Wang, Guodong, Xian, Bingxiong, Ma, Feiyang, and Fang, Shu

Subjects

STEEL-concrete composites, HIGH strength concrete, BRIDGE design & construction, TENSION loads, ULTIMATE strength, COMPOSITE construction

Abstract

Ultra-high-performance concrete (UHPC) is widely used in precast concrete-steel composite beams because of its beneficial properties, including reduced structural weight, higher flexural rigidity, and reduced tensile crack formation. In comparison to conventional steel-concrete composite beams, steel-UHPC composite beams exhibit superior characteristics, including reduced structural deadweight, enhanced flexural stiffness, and the capacity to withstand tensile cracking. One successful attempt at meeting the current demands for expedited girder engineering is the development of steel-UHPC composite beams with full-depth precast slabs as key components affecting the overall structural performance using dismountable single embedded nut bolts (SENBs) and widely used studs as competitive alternatives. In contrast, shear connectors are exposed to a combined tensile and shear stress in service life rather than shear only. The corresponding scientific problem is the problem of combined effects under stress in practical applications, but there is currently no relevant research. The shear performance of SENBs in precast steel-UHPC composite beams under tension and shear loads remains unclear. For this purpose, ten push-out specimens and theoretical analyses were performed in this paper, considering the influence of the connector's type and tensile-to-shear ratio. However, ten specimens were conducted to investigate the tensile-to-shear ratio, and the connector's type on shear performance is limited. In the future, an increasing number of specimens and test parameters should be considered to investigate the shear performance of precast steel-UHPC composite beams. An increase in the tension-to-shear ratio resulted in a substantial reduction in the ultimate shear capacity, initial shear stiffness, and ductility of the studs. The increase in the tensile-shear ratio from 0 to 0.47 resulted in a 16.9% decline in the ultimate shear capacity, a 30.4% reduction in the initial shear stiffness, and a 21.7% decrease in the ductility of the Series I samples. However, an increase in the tensile-to-shear ratio of the Series II samples from 0 to 0.47 resulted in a 31.3% decline in ultimate shear strength, a 33.2% decline in initial shear stiffness, and a 41.9% decline in ductility. The SENBs demonstrated minimal deviations in ultimate shear capacity compared to their stud counterparts, despite exhibiting notable differences in shear stiffness, and ductility. A lower tensile-to-shear ratio was recommended in practical engineering, which might achieve a larger ultimate shear capacity, stiffness, and ductility. The design-oriented models with enhanced applicability were developed to predict the tension-shear relationship and the load-slip curve of SENBs in prefabricated steel-UHPC composite beams subjected to combined tensile and shear loads. For a tensile-shear relationship model, the point error range was 0 to 0.08, with an average error of 0.03. The square coefficient (R2) was 0.99 for a load-slip curve model. The study findings could offer a credible reference for the shear mechanism of such economical and environmentally friendly precast steel-UHPC composite beams in accelerated bridge construction. [ABSTRACT FROM AUTHOR]

Published

2024

26. Award-winning paper in 2016.

Subjects

*CABLE-stayed bridges, *BRIDGE design & construction, *STRUCTURAL engineering

Published

2018

27. Award-winning papers for free download.

Subjects

ENGINEERING, CONSTRUCTION industry, BRIDGE design & construction

Abstract

On 8 October 2018 ICE president Robert Mair will present awards to the following papers published in the various ICE Proceedings journals in 2017. Journal editorial panels nominated their best papers and an awards committee, chaired by Nigel Wright, allocated the awards. These award-winning papers can be downloaded for free from the ICE Virtual Library's 'ICE Publishing Awards 2018' page at . [ABSTRACT FROM AUTHOR]

Published

2018

28. LRFD calibration for soil failure limit state using the Stiffness Method.

Author

Bathurst, Richard J. and Allen, Tony M.

Subjects

LOAD factor design, FAILED states, BUILDING foundations, ROAD construction, BRIDGE design & construction, BEARING capacity of soils

Abstract

The paper describes load and resistance factor design (LRFD) calibration for the resistance factor used in the Stiffness Method internal stability soil failure limit state for geogrid mechanically stabilized earth (MSE) walls. The Stiffness Method was recently adopted in the current American Association of State Highway and Transportation Officials LRFD Bridge Design Specifications in the US, and will appear in the next edition of the Canadian Highway Bridge Design Code. The paper describes the details of the calibration of the soil failure limit state which is unique to the Stiffness Method. Calibration outcomes include consideration of the concept of level of understanding in the selection of nominal load and resistance values which is unique to LRFD foundation engineering practice in Canada. A practical conclusion from these calculations is that if product line-specific creep test data are available to estimate the reinforcement secant creep stiffness used for design, then a resistance factor of 1.0 is reasonable for US practice. If only minimum average roll value tensile strength data are available, then a value of 0.95 is recommended for US practice. For Canadian practice, the corresponding values for typical level of understanding are 0.90 and 0.85, respectively. [ABSTRACT FROM AUTHOR]

Published

2023

29. A Method to Identify the Critical Seismic Input for Curved Bridges.

Author

Tao, Chengcheng and Guan, Shanyue

Subjects

TRAFFIC congestion, TIME series analysis, BRIDGE design & construction, SEISMIC response, FINITE element method

Abstract

To address the rapidly growing demands of traffic congestion, more highway bridges have been constructed, especially curved bridges. With more curved bridges designed and constructed, people have conducted a comprehensive analysis of the structural performance. Due to the nature of the structural complexity of curved bridges, dynamic responses of the curve bridges vary dramatically from the standard linear bridges. Although some work has been conducted to investigate the curved bridge dynamic analysis under seismic inputs, the framework for analyzing the curved bridges' vulnerability under various angles of inputs is still lacking. In this paper, we conducted a series of curved bridge seismic analyses based on different inputs and conducted a parametric study of the bridge performance using finite element models. We conducted time history analyses by applying seismic inputs to investigate the bridge dynamic responses based on different angle inputs and other different structural parameters. We developed an approach identifying the most vulnerable direction of the seismic inputs and the strongest dynamic responses for curved bridges based on time series analysis. This approach was validated with the dynamic analysis of a simplified bridge model. The method developed in this paper will help improve the curved bridge design code and further provide suggestions about mitigating seismic response for device design. [ABSTRACT FROM AUTHOR]

Published

2023

30. Award-winning papers in 2014.

Subjects

*CIVIL engineering, *BRIDGE design & construction

Abstract

The article announces the award-winning papers from the Institution of Civil Engineers (ICE) for 2014 presented by president David Balmforth on October 9, 2015 including the Bill Curtin Medal and the John Henry Garood King Prize.

Published

2016

31. Damage Identification Method of Tied-Arch Bridges Based on the Equivalent Thrust-Influenced Line.

Author

Zhou, Yu, Li, Meng, Shi, Yingdi, Di, Shengkui, and Shi, Xianzeng

Subjects

ARCHES, BRIDGE design & construction, NUMERICAL analysis, ANALYTICAL solutions, ARCH bridges, CATENARY

Abstract

Early tied-arch bridges cannot satisfy the current traffic load demand due to their load grades and maintenance levels. Also, these tied-arch bridges have accumulated structural damage with increasingly prominent safety risks. In order to accurately evaluate the characteristics of tied-arch bridges' structural-influenced lines and identify damage of their arch ribs and suspenders, two analytical solutions are derived and established in this paper for the thrust-influenced lines of parabola and catenary two-hinged arches with a tie beam. A new method and an index for identifying damage of arch ribs and suspenders of tied-arch bridges are proposed. The results of numerical simulation in this paper verified that the proposed analytical solution has good analytical accuracy in practice on those two-hinged nonflat arches. With the use of equivalent thrust-influenced line difference curvature, the effectiveness of damage identification and the verification method were verified on the tie beam, suspender, and arch rib of plane tie arch structure as well as the suspender and arch rib of tied-arch bridges in this research. Furthermore, combining with grey relation analysis, the noise immunity of the proposed index method can be verified. Also, thrust-influenced line recognition based on VMD (variational mode decomposition) is introduced, and a practical process of bridge health assessment based on the quasistatic-influenced line loading of three-axle heavy vehicles is established. Theoretical analysis and numerical verification show that the calculated error of the analytic solution of two-hinged arches with a rise-span ratio greater than 1/8 is less than 9.57%, and the error decreases with the increase of the rise-span ratio. Therefore, it can be applied to the calculation and analysis of tied-arch bridges with a rise-span ratio range between 1/4 and 1/5. With the equivalent thrust-influenced line index proposed in this paper, the damage of suspenders and arch ribs of tied-arch bridges can be accurately located. It has been found that the proposed method is more effective to identify the damage of suspenders than the damage of arch ribs does, showing good noise immunity. In summary, this research has provided theoretical support for arch bridge design and evaluation. Combining with existing bridge-monitoring methods, the new bridge damage identification method proposed in this paper has the prospect of realizing the normal health status assessment of existing tied-arch bridges. [ABSTRACT FROM AUTHOR]

Published

2024

32. Planning and design of the Gordie Howe International Bridge, North America.

Author

Martin, Leslie A., Yousif, Zaher, Campbell, Bruce L., Furrer, Martin, and Chynoweth, Matt

Subjects

CABLE-stayed bridges, BRIDGE design & construction, LONG-span bridges, LIVE loads, SERVICE life, SUSPENSION bridges, BORDER crossing, TOWERS, PUBLIC-private sector cooperation

Abstract

The Gordie Howe International Bridge project is providing a new modern border crossing between Windsor, ON, Canada and Detroit, MI, USA. The centrepiece of the project is a 2.5 km long cable-stayed bridge with 853 m main span over the Detroit River and 220 m tall towers on both sides of the river. In addition to the bridge, the project includes ports of entry on both sides of the border and a new freeway interchange with Interstate-75 in Detroit. The project was procured as a public–private partnership that allowed the proponents to propose either a suspension or cable-stayed bridge, with the ultimate selection creating the longest cable-stayed bridge in North America. The paper outlines the need for the new border crossing and results of the environmental assessment process, as well as describing the project evolution from planning through procurement and into detailed design. The scoping of the bridge design parameters is discussed, including: comprehensive geotechnical investigation; load study to develop project-specific live loading; the approach for durability requirements to achieve a service life of 125 years; special considerations for security; wind engineering; and compliance with both Canadian and US design codes. The paper also discusses the approach to achieving an aesthetically pleasing bridge design. [ABSTRACT FROM AUTHOR]

Published

2023

33. Bridge Construction Quality Evaluation Based on Combination Weighting Method- Technique for Order Preference by Similarity to an Ideal Solution Theory.

Author

Jin, Ruibao, Wang, Lei, Zhang, Tianjing, and Li, Qingfu

Subjects

BRIDGE design & construction, BRIDGE inspection, TOPSIS method, QUALITY control, BRIDGE maintenance & repair

Abstract

The process of bridge construction is accompanied by many uncertainties. These uncertainties can have an impact on the quality of bridge construction and are thus directly related to the safe operation of the bridge. Therefore, it is very important to conduct bridge construction quality control evaluations for safe bridge construction and operation. In this paper, a three-tier bridge construction quality control evaluation system is established. This study uses a combination of subjective and objective assignment methods and TOPSIS theory to carry out an evaluation calculation of bridge construction quality. The CWM-TOPSIS theory was applied to the actual engineering calculation by taking the construction process of a mega bridge across the Yellow River as an example. After a series of calculations, the bridge construction quality evaluation results were obtained as level IV. This showed that a construction quality control method was needed for this bridge as soon as possible, and inspection and protection of the bridge should be started to avoid the emergence of bigger quality problems. Finally, the accuracy and applicability of the method proposed in this paper were proved by comparing and analyzing the evaluation results with the standard element theory. [ABSTRACT FROM AUTHOR]

Published

2023

34. Investigation of Stress Concentration Zones in FEM-Based Design of Welded Plated Structures.

Author

Bärnkopf, Erzsébet, Kövesdi, Balázs, and Dunai, László

Subjects

STRESS concentration, BRIDGE design & construction, PHYSIOLOGICAL stress, NONLINEAR analysis, MATERIALS analysis

Abstract

The numerical model-based design is commonly applied to steel structures using advanced numerical models and analysis. These models often contain stress concentration zones, which can cause problems for designers within the evaluation process. There are two basic questions to answer in the design: (i) are these stress concentrations real physical stresses or numerical singularities and (ii) should these stresses be considered in the design process or can be neglected? The current paper shows a proposal to separate the real physical stresses from the numerical stress concentrations and an improved design method is introduced to consider or neglect them in the daily design. The proposed evaluation method is presented through a design example taken from the daily bridge design practice. The calculation method of the design check is presented first by using (i) linear analysis and (ii) geometrical and material non-linear analysis. Based on the comparison of these two calculation methods the evaluation process of the stress concentration zone is presented as an example. The paper introduces an evaluation method for the stress concentration zone, which can be applied to different structures similarly. [ABSTRACT FROM AUTHOR]

Published

2023

35. PAPER BRIDGE.

Subjects

BRIDGE design & construction

Abstract

The article offers information on a paper bridge constructed by artist Steve Messam in England and presents views of Messam on successful completion of the bridge as all sheets of paper were compressed together tightly.

Published

2015

36. Design of precast UHPFRC retaining walls – Experimental and numerical validations.

Author

Sylvestre, Danny, Charron, Jean-Philippe, and Massicotte, Bruno

Subjects

RETAINING walls, ROAD construction, BRIDGE design & construction, REINFORCED concrete, WALL design & construction

Abstract

This paper focuses on the design as well as on the experimental and numerical validations of the mechanical behavior of a precast ultra-high performance fibre reinforced concrete (UHPFRC) retaining walls. The design, made in accordance with the Canadian Highway Bridge Design Code (CSA S6, 2019), led to the fabrication of a full-scale UHPFRC retaining wall with 3% fibre content which had dimensions of 3 m in height, 2 m in length, 2 m in width, with two vertical and horizontal stiffeners, and very thin vertical and horizontal panels of 40 and 65 mm, respectively. The experimental tests showed that the UHPFRC retaining wall exceeded by 42% the ultimate limit state (ULS) design factored bending moment and showed a very ductile behavior under flexural loading. At service limit state (SLS), the retaining wall had maximum crack opening between 0.15 and 0.28 mm, and a maximum lateral displacement of 4 mm. The finite-element model developed for the application captured accurately the flexural behavior of the UHPFRC retaining wall and was used later in parametric studies to optimize the design. The retaining wall optimal design includes UHPFRC with 3% fibre content and stiffeners with variable cross-section which allows volume reductions of 73% for concrete and 86% for rebars in comparison to the conventional reinforced concrete design. [ABSTRACT FROM AUTHOR]

Published

2024

37. Seismic performance of a new type of prefabricated bridge pier with cast-in-place UHPC jacketing.

Author

Zhang, Zhe, Zou, Pan, Deng, En-Feng, Wang, Shi-Bo, Pang, Yu-Yang, Xue, Hong-Tao, Men, Shao-Rong, and Liu, Dong-Xu

Subjects

PIERS, BRIDGE foundations & piers, BRIDGE design & construction, FINITE element method, FAILURE mode & effects analysis

Abstract

Accelerated bridge construction (ABC) is prevalent all over the world attributable to its technical advantages including the higher construction efficiency, less traffic disruption, and higher construction quality. Grouting sleeves (GS) and grouting corrugated pipes (GCP) are the traditional connection methods of ABC in high seismic regions, with the disadvantages of uncompacted grouting and high requirement of construction accuracy. To this end, this paper developed a new type of prefabricated concrete bridge pier connected with ultra-high performance concrete (PCBP–UHPC) jacketing to solve the problems. To validate the seismic performance of the proposed innovative bridge pier, quasi-static tests on three full-scale specimens PCBP–UHPC, PCBP–GS, and PCBP–GCP were carried out. The results indicated that the failure mode of specimen PCBP–UHPC was similar to that of specimens PCBP–GS and PCBP–GCP with the characteristics of longitudinal steel yielding and concrete crushing at the base of the hollow pier. The obvious plastic hinge outward shifting could be observed during the loading for specimen PCBP–UHPC. The positive ultimate load of specimen PCBP–UHPC was 636.33 kN, which was 14.8% and 13.3% higher than those of specimens PCBP–GS and PCBP–GCP, respectively. In addition, a refined finite element model (FEM) was established by ABAQUS to provide an in-depth understanding on the failure mechanism of the proposed PCBP–UHPC. The parametric analyses were conducted to reveal the influence of the socket depth and axial compression ratio on seismic performance of the proposed PCBP–UHPC. The results indicated that the socket depth had little effect on seismic performance of the prefabricated pier, while the ultimate load bearing capacity of specimen PCBP–UHPC increased to some extent as the increase of the axial compression ratio. The present research work provides an innovative prefabricated bridge pier and a comprehensive experimental–numerical understanding on its seismic performance, which is beneficial for its engineering application. [ABSTRACT FROM AUTHOR]

Published

2024

38. Determination of Accuracy and Usability of a SLAM Scanner GeoSLAM Zeb Horizon: A Bridge Structure Case Study.

Author

Urban, Rudolf, Štroner, Martin, Braun, Jaroslav, Suk, Tomáš, Kovanič, Ľudovít, and Blistan, Peter

Subjects

SCANNING systems, DIGITAL twins, BRIDGE design & construction, OPTICAL scanners, POINT cloud, LEAST squares

Abstract

The presented paper focuses on testing the performance of a SLAM scanner Zeb Horizon by GeoSLAM for the creation of a digital model of a bridge construction. A cloud acquired using a static scanner Leica ScanStation P40 served as a reference. Clouds from both scanners were registered into the same coordinate system using a Trimble S9 HP total station. SLAM scanner acquisition was performed independently in two passes. The data acquired using the SLAM scanner suffered from relatively high noise. Denoising using the MLS (Moving Least Squares) method was performed to reduce noise. An overall comparison of the point clouds was performed on both the original and MLS-smoothed data. In addition, the ICP (Iterative Closest Point) algorithm was also used to evaluate local accuracy. The RMSDs of MLS-denoised data were approximately 0.02 m for both GeoSLAM passes. Subsequently, a more detailed analysis was performed, calculating RMSDs for several profiles of the construction. This analysis revealed that the deviations of SLAM data from the reference data did not exceed 0.03 m in any direction (longitudinal, transverse, elevation) which is, considering the length of the bridge of 133 m, a very good result. These results demonstrate a high applicability of the tested scanner for many applications, such as the creation of digital twins. [ABSTRACT FROM AUTHOR]

Published

2024

39. Short-Term Wind Speed Prediction for Bridge Site Area Based on Wavelet Denoising OOA-Transformer.

Author

Gao, Yan, Cao, Baifu, Yu, Wenhao, Yi, Lu, and Guo, Fengqi

Subjects

WIND speed, OPTIMIZATION algorithms, OUTLIER detection, STANDARD deviations, BRIDGE design & construction, DATA entry, WIND forecasting

Abstract

Predicting wind speed in advance at bridge sites is essential for ensuring bridge construction safety under high wind conditions. This study proposes a short-term speed prediction model based on outlier correction, Wavelet Denoising, the Osprey Optimization Algorithm (OOA), and the Transformer model. The outliers caused by data entry and measurement errors are processed by the interquartile range (IQR) method. By comparing the performance of four different wavelets, the best-performing wavelet (Bior2.2) was selected to filter out sharp noise from the data processed by the IQR method. The OOA-Transformer model was utilized to forecast short-term wind speeds based on the filtered time series data. With OOA-Transformer, the seven hyperparameters of the Transformer model were optimized by the Osprey Optimization Algorithm to achieve better performance. Given the outstanding performance of LSTM and its variants in wind speed prediction, the OOA-Transformer model was compared with six other models using the actual wind speed data from the Xuefeng Lake Bridge dataset to validate our proposed model. The experimental results show that the mean absolute percentage error (MAPE), root mean square error (RMSE), and coefficient of determination ( R 2 ) of this paper's method on the test set were 4.16%, 0.0152, and 0.9955, respectively, which are superior to the other six models. The prediction accuracy was found to be high enough to meet the short-term wind speed prediction needs of practical projects. [ABSTRACT FROM AUTHOR]

Published

2024

40. Application of bi-directional evolutionary structural optimization to the design of an innovative pedestrian bridge.

Author

Lai, Yaping, Li, Yu, Liu, Yanchen, Chen, Peixin, Zhao, Lijun, Li, Jin, and Xie, Yi Min

Subjects

STRUCTURAL optimization, STRUCTURAL design, SKYWALKS, FOOTBRIDGES, BRIDGE design & construction, PERFORMANCE-based design, TECHNOLOGICAL innovations

Abstract

With rapid advances in design methods and structural analysis techniques, computational generative design strategies have been adopted more widely in the field of architecture and engineering. As a performance-based design technique to find out the most efficient structural form, topology optimization provides a powerful tool for designers to explore lightweight and elegant structures. Building on this background, this study proposes an innovative pedestrian bridge design, which covers the process from conceptualization to detailed design implementation. This pedestrian bridge, with a main span of 152 m, needs to meet some unique architectural requirements, while addressing multiple engineering challenges. Aiming to reduce the depth of the girder but still meeting the load-carrying capacity requirements, the superstructure of this bridge adopts a variable-depth spinal-shaped girder in the center of its deck, thus forming an elegant curving facade, from which one pathway cantilevers on either side. At one end of the bridge, given considerable elevation difference between the bridge deck and the ground, a two-level Fibonacci-type spiral-shaped bicycle ramp is provided. The superstructure is supported by a series of organic tree-shaped branching piers resulting from the topology optimization. The ingenious design for the elegant profile of the bicycle ramp generates an enjoyable and dynamic crossing experience, with scenic views in all directions. By virtue of technological innovation, the pedestrian bridge is expected to create an iconic, cost-effective, and low-maintenance solution. A brief overview of the theoretical background of the bi-directional evolutionary structure optimization (BESO) and the multi-material BESO approach is also offered in this paper, while the construction requirements and challenges, conceptual development process, form-finding strategy, detailed design, and construction method of the bridge are presented. [ABSTRACT FROM AUTHOR]

Published

2024

41. Optimization of the One-Size-Fits-All Layout Problem Based on Preparing Material for Steel Bridges.

Author

Dong, Zhikui, Liu, Chunjiang, Sun, Yongkuan, Li, Xuedong, Zhang, Kai, and Jiang, Yunhong

Subjects

METAHEURISTIC algorithms, IRON & steel bridges, OPTIMIZATION algorithms, GENETIC algorithms, BRIDGE design & construction, MATHEMATICAL models

Abstract

Before the construction of a bridge begins, workers arrange the necessary parts and then cut and process them. The quality of the cutting layout directly affects the material utilization rate and the efficiency of the subsequent processes. During bridge construction, an intelligent part layout can improve work efficiency, save time, and reduce the labor intensity and production costs for the company. In this study, we studied a layout optimization algorithm, focusing on rectangular parts in the material preparation process. A mathematical model for the rectangular layout problem was constructed, and a hybrid genetic whale optimization algorithm is proposed that is a combination of the whale optimization algorithm and the genetic algorithm. Based on the "one size fits all" layout strategy, the materials are divided into strips, which are further divided into stacks, serving as the positioning strategy to determine the positional relationships of the parts. Test cases and actual engineering data were used to compare the layouts generated using different algorithms. The results show that the genetic whale algorithm proposed in this paper results in a high utilization rate and is highly effective. [ABSTRACT FROM AUTHOR]

Published

2024

42. Hydraulic Partial Factors in Ultimate Limit State of Bridges against Foundation Scour Based on Inverse Reliability Analysis.

Author

Ma, Xiaolong, Xiong, Wen, Shi, Huiduo, and Cai, C. S.

Subjects

BRIDGE foundations & piers, BRIDGES, BRIDGE design & construction, BRIDGE failures, FLOOD warning systems, FAILURE mode & effects analysis

Abstract

Owing to undesired hydraulic effects, bridge collapse accidents have become increasingly frequent during the flooding season. Considering hydraulic effects in bridge design is paramount to controlling and mitigating hydrological damage. Despite the efforts in previous studies on bridges under floods, a proper partial factor of hydraulic effects considering foundation scour is still lacking for bridge design against floods. To bridge the gap, this study proposed an inverse reliability analysis framework to generate a proper partial factor of hydraulic effects and a corresponding partial factor of resistance. First, failure modes of typical short- to medium-span bridges were summarized to construct limit state functions. Then, an inverse reliability analysis framework considering hydraulic effects was proposed. The optimum partial factors of hydraulic effects and corresponding partial factors of resistance were calculated for various design specifications. Finally, a classification early warning system of foundation scour was built to forecast hydraulic failure accurately. This paper reveals the necessity of considering the hydraulic effects of floods in bridge design. The proposed framework and warning system can effectively enhance bridge safety against floods. [ABSTRACT FROM AUTHOR]

Published

2024

43. Static Push-Out Tests on 29 mm Diameter Shear Studs.

Author

Deng, Xianjue, Engelhardt, Michael, Helwig, Todd, Williamson, Eric, Wan, Lu, and Alp, Yucel

Subjects

GIRDERS, STEEL girders, PRECAST concrete, BRIDGE design & construction, IRON & steel bridges, CRACKING of concrete, CONCRETE panels

Abstract

Composite steel bridges in the United Sates are typically constructed using 22 mm-diameter (7/8 in.-diameter) shear studs. The number of shear studs on a girder can be significantly reduced by using larger-diameter studs. This study employed 11 push-out tests to investigate the static performance of 29 mm-diameter (1-1/8 in.-diameter) shear studs. An extensive welding investigation was conducted to develop the optimum welding parameters for 29 mm-diameter studs. Results from experiments showed the static strength of 29 mm-diameter studs satisfied stud strength equations in the AASHTO LRFD Bridge Design Specifications and Eurocode 4. The ductility of the 29 mm studs was comparable or better than that of 22 mm-diameter shear studs. Concrete cracking under service level loading was similar between specimens with 22 and 29 mm studs. Observations indicate that the minimum allowable stud penetration into the concrete deck may need to increase in order for the 29 mm-diameter studs to have good static performance. Using partial-depth precast concrete panels in the bridge deck reduced the static strength of both 22 and 29 mm-diameter shear studs in push-out specimens. Efficient steel bridge girder design makes use of a composite action between the concrete deck and the steel girders. Composite action is achieved by welding shear studs to the top flange of the steel girder during fabrication or erection. The number of shear studs needed is directly related to the individual stud strength, which is controlled by the stud diameter. The shear stud diameter most commonly used in steel bridge construction throughout most of the United States is 22 mm. This paper presents laboratory experiments evaluating the static strength of 29 mm-diameter shear studs. The test results showed that 29 mm-diameter shear studs have a static strength that satisfies US bridge design standards. Compared with 22 mm-diameter shear studs, the use of 29 mm-diameter shear studs is estimated to reduce the number of studs needed on a steel bridge girder by 40%. This reduction in the number of shear studs can enhance construction safety, reduce the cost of fabrication, and facilitate the use of partial-depth precast concrete deck panels, which in turn can increase the speed of construction. [ABSTRACT FROM AUTHOR]

Published

2024

44. Accelerated Bridge Construction Case: A Novel Low-Carbon and Assembled Composite Bridge Scheme.

Author

Kang, Ling, Xu, Jinhua, Mu, Tingmin, Wang, Huan, and Zhao, Ping

Subjects

BRIDGE design & construction, BRIDGES, VIADUCTS, STEEL-concrete composites, IRON & steel bridges, DEAD loads (Mechanics), COMPOSITE structures, BRIDGE maintenance & repair, SUSTAINABLE construction

Abstract

Modern bridge construction towards a higher degree of low carbonization and assembly has been the general trend, while developing and broadening the low-carbon and assembled-oriented Accelerated Bridge Construction (ABC) technology can better realize the trade-offs between construction quality, efficiency, cost and sustainability. In the current mainstream ABC technologies such as precast-assembled concrete bridge and assembled steel bridge schemes, it is difficult to achieve an excellent balance between the above multicriterion trade-offs. To this end, this paper proposes a novel low-carbon and assembled composite bridge scheme as an innovative case of ABC technology based on a 26.7 km-length urban viaduct project in China with urgent environmental protection and assembly demands. Construction sustainability, the comprehensive economy and low-carbon performance are well balanced by the collaborative application of new steel–concrete composite structures, the rapid assembly interface design and low-carbon material technologies. The proposed scheme has been applied to a completed real-scale bridge, and the whole construction process only experienced 105 days of effective time, accompanied with slight environmental interference and construction noise and a small amount of labor and equipment input. In addition, the safety of the bridge, the rationality of the design concept and the calculation method have been verified by the static and dynamic loading tests of the real-scale bridge. [ABSTRACT FROM AUTHOR]

Published

2024

45. Construction Safety Risk Assessment of High-Pile Wharf: A Case Study in China.

Author

Wang, Ziwen and Yuan, Yuan

Subjects

ANALYTIC hierarchy process, RISK assessment, BRIDGE design & construction, STEEL pipe, BUILDING sites, WARNINGS

Abstract

The complexity of the wharf components and the harshness of the offshore construction environment increase the safety risk of hazards, which has highlighted the importance and urgency of safety risk management in high-pile wharf constructions. This paper established a visualized digital construction safety risk model for high-pile wharf based on a so-called FAHP method (the combination of fuzzy comprehensive evaluation (FCE) and analytic hierarchy process (AHP) methods). The construction safety risk indicators were constructed as the target layer, the principle layer and the scheme layer, and then the corresponding safety risk assessment algorithm was established. The physical, functional and safety risk assessment parameters of the component in the BIM model were employed to the safety risk assessment algorithm, and the risk assessment level of each sub-process was subsequently classified. The case study indicated that the high-pile wharf construction project included five elements in principle layer and 15 risk indicators in the scheme layer. Moreover, it was demonstrated that the sub-processes with the highest construction risk level were steel pipe pile sinking in wharf construction and steel pipe pile, steel sheath-immersed pile sinking and embedded rock pile construction in approaches to bridge construction with a risk level of III. In this way, the quantitative visualization of the construction safety risk was effectively realized, which facilitates the safety risk management of construction sites and timely warning and response to unexpected safety accidents. [ABSTRACT FROM AUTHOR]

Published

2024

46. Tension Force and Structural Parameter Identification of Bridge Cables.

Author

Liao, W. Y., Ni, Y. Q., and Zheng, G.

Subjects

CABLE vibration, VIBRATION measurements, CABLE tension control, BRIDGE design & construction, STIFFNESS (Engineering)

Abstract

Vibration measurement is one of the most widely used methods for tension evaluation and condition assessment of stay cables in cable-stayed bridges. In the existing practice, the tension force of a cable is identified from the measured modal frequencies with the use of the taut string theory or empirical formulae, by assuming pre-determined structural parameters (geometric and material parameters) and boundary conditions of the cable. As a result, an inaccurate estimation of the cable tension may be obtained when there is an error in the pre-determined structural parameters and boundary conditions. Moreover, the commonly used empirical formulae are not applicable in the case when the cable is intermediately attached with dampers. In the present study, a method enabling simultaneous identification of cable tension and other structural parameters from the measured modal frequencies is developed. A precise finite element model (FEM) accounting for cable flexural rigidity, sag-extensibility, spatial variability of dynamic tension, boundary conditions, lumped masses and intermediate supports and/or dampers is first formulated as the reference model in parameter identification so that the modeling error is minimized. Then the measured multiple modal frequencies are used together with the FEM to figure out a nonlinear least-square optimization scheme which helps eliminate measurement error and allows for simultaneous identification of the cable tension and other structural parameters. Application of the proposed method to the Dongting Lake Bridge cables from in-situ ambient vibration measurements illustrates high identification accuracy and fidelity of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2012

47. OLDEST CONCRETE VAULTED AND ARCH BRIDGES IN THE CZECH REPUBLIC - EVALUATION AND PRESERVATION OF THEIR HISTORICAL VALUE.

Author

Šafář, Roman, Hrdoušek, Vladislav, Včelová, Helena, and Hlavničková, Vendula

Subjects

BRIDGE design & construction, CONSTRUCTION industry, SUSTAINABLE development, CLIMATE change

Abstract

The paper is related to a research project focused on tools for an evaluation and preservation of the historical value and function of arch and vaulted road bridges. It deals with the beginning of use of concrete vaulted and arch bridges in the area of the Czech Republic from the first structures built at the end of the 19th century up to the time just before the WWII. The paper includes examples of built structures as well as a general summary and development of the used technical solutions. Important part of the paper is a proposal of criterions for evaluation of their structural and historical value. [ABSTRACT FROM AUTHOR]

Published

2022

48. Literature review of bridge structure's optimization and it's development over time.

Author

Zaheer, Qasim, Tan Yonggang, and Qamar, Furqan

Subjects

LITERATURE reviews, STRUCTURAL optimization, STRUCTURAL engineering, ENGINEERING design, BRIDGE design & construction, BRIDGES

Abstract

The structural development in bridge engineering along with efficiency have got much attention in few decades. Leading to the development, Optimization of structure established on mathematical analysis emerged mostly employed strategies for productive and sustainable design in the bridge engineering. Despite the widespread knowledge, there has yet to be a rigorous examination of recent structural optimization exploration development. Thus, the primary objectives of this paper are to critically review previous structural optimization research, provide a detailed examination of optimization goals and outline recent research field limitations and provide guidelines for future research proposal in the field of bridge engineering structural optimization. This article begins by outlining the relevance of efficiency and sustainability in the bridge construction, aswell as the work done required for this review. Suitable papers are gathered and followed by a statistical analysis of the selected publications. Following that, the selected papers are evaluated in terms of the optimization targets as well as their spatial patterns. Structure's optimization four key steps, includingmodeling, optimization techniques, formulation of optimizationconcernsandcomputational tools, are also researchedandexaminedindepth. Finally, researchgaps in contemporary works are identified, as well as suggested guidance for future works. [ABSTRACT FROM AUTHOR]

Published

2022

49. STRUCTURAL MONITORING: PRACTICAL PERSPECTIVES, ACTIONABLE OUTCOMES AND VALUE FOR MONEY.

Author

Ash, Daniel and Griscti, Henry

Subjects

INFRASTRUCTURE (Economics), TELEMETRY, BRIDGE design & construction, ACCELEROMETERS, THERMOCYCLING

Abstract

This paper takes a practical lens to a highly advanced field which uses technology to monitor structures and other physical assets. The purpose of this work is to help inform engineers and asset owners who are considering implementing monitoring projects such that they can appropriately scope the project and consider some of the less technical aspects that affect cost, timing and outcomes. [ABSTRACT FROM AUTHOR]

Published

2023

50. Experimental and Numerical Study on the Seismic Performances of Reinforcement-Embedded RC Column-to-Precast Cap Beams with Socket Connections.

Author

Peng, Wenqiang, Lu, Wenliang, Liu, Sitian, Liu, Yong, Xu, Linfeng, and Li, Fenglin

Subjects

BRIDGE design & construction, CONCRETE joints, FINITE element method, SEISMIC response, EARTHQUAKE zones, BEARING capacity of soils, PERFORMANCE theory

Abstract

Accelerated bridge construction (ABC) has attracted much attention in China as a new and efficient construction method. However, the seismic performance of the connections between precast piers and other structures limits the application of ABC in medium and high seismic zones. In this paper, a quasi-static test was conducted to investigate the seismic performance differences between a cap–column socket connection (PSC) specimen, which reinforced an embedded RC column-to-precast cap beam with a socket connection, and a cast-in-place (CIP) cap–column specimen. A fiber-based finite element model that considers bond slippage between the connection reinforcement and wet joint concrete is proposed. The numerical simulation results compared with the experimental results show an error of about 12% in peak bearing capacity and about 2% in initial stiffness. The experimental and numerical results show that the PSC specimen demonstrates comparable seismic performance to the CIP specimen. Experimental results verified that the finite element model in this paper is adequate to predict the seismic responses of a precast column with a reinforcement-embedded socket connection. A reinforcement-embedded RC column-to-precast cap beam with socket connection can be an effective solution for construction in medium and high seismic areas. [ABSTRACT FROM AUTHOR]

Published

2023