Non-Uniform Temperature Fields and Effects of Steel Structures: Review and Outlook

Xu, Wucheng; Chen, Deshen; Qian, Hongliang

doi:10.3390/app10155255

Cited by 9 publications

(3 citation statements)

References 102 publications

(129 reference statements)

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“…The maximum temperature difference of approximately 47 • C was determined in the steel girder [33]. Wucheng Xu et al [34] showed that the heat exchange between the different solar radiation components, heat convection and other factors and the boundaries of the steel structures resulted in a significant nonuniform distribution of the temperatures in steel structures. Due to the complexity of the heat exchange phenomena and not applying it accurately, understanding the steel structure thermal actions can be restrained, leading to jeopardizing the structure safety.…”

Section: Experimental and Numerical Thermal Analyses Of Temperature D...mentioning

confidence: 99%

“…Due to the complexity of the heat exchange phenomena and not applying it accurately, understanding the steel structure thermal actions can be restrained, leading to jeopardizing the structure safety. The study provided a better understanding of the steel structure thermal behaviors and some recommendations to improve the temperature prediction and distribution in steel structures [34]. The continued exposure of steel structures to solar radiation and other thermal loads during construction can lead to nonlinear and complex temperature variations and distributions, which might impact the quality of engineering construction, the accuracy of structural closures [35], and consequently, the safety of the structure [36].…”

Section: Experimental and Numerical Thermal Analyses Of Temperature D...mentioning

confidence: 99%

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Predicting Maximum Effective Temperatures and Thermal Gradients for Steel I-Girder in Canadian Climate Regions

Nassar

Amleh

2023

Applied Sciences

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The constant fluctuation of thermal loads on steel members, especially during construction, causes non-uniform distributions of temperatures, resulting in possible constructional and structural defects leading to unfavorable thermally induced responses and potential safety risks. The Canadian Highway Bridge Design Code (CHBDC) provides one thermal gradient variation profile without accounting for the differences in the geometrical parameters of the steel members and the variations in the climate regions of Canada. Therefore, in this study, three-dimensional finite element (FE) thermal simulations were conducted to investigate the maximum effective temperatures and positive vertical thermal gradients for different Canadian climate regions. Parametric studies were performed to conduct the FE thermal analysis using the thermal model validated in ANSYS. The comprehensive study results showed that Canada could be divided into two main zones for vertical thermal gradient calculations, meaning that one stationary thermal gradient profile cannot be applicable to all climate regions of Canada, as recommended by the CHBDC. Based on the FE thermal analysis results, empirical formulas as a function of the significant parameters were proposed to predict the maximum effective temperature and thermal gradient variations of the steel I-girder. The predicted maximum effective temperature and thermal gradient variation values were found to be highly correlated with the FE values with coefficients of determination R2 of approximately 0.97 and 0.98, respectively.

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Section: Experimental and Numerical Thermal Analyses Of Temperature D...mentioning

confidence: 99%

Section: Experimental and Numerical Thermal Analyses Of Temperature D...mentioning

confidence: 99%

Predicting Maximum Effective Temperatures and Thermal Gradients for Steel I-Girder in Canadian Climate Regions

Nassar

Amleh

2023

Applied Sciences

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“…Assuming a sudden rise or drop of ambient temperature happens, the differences in temperature boundaries will cause inhomogeneous temperature change and induce large nonlinear temperature gradients. The nonlinear temperature gradients along the directions of height, the width of the beam, and thickness of plate unquestionably cause significant deformation and stress of temperature under constraints [17][18][19], which threaten the safety and serviceability [11,20] of aqueducts. Thus, the study of thermal stress of an aqueduct is a significant aspect of the design process, and temperature distribution is the prerequisite for stress analysis.…”

Section: Introductionmentioning

confidence: 99%

Numerical Study on Temperature Distribution of Steel Truss Aqueducts under Solar Radiation

Chang

2021

Applied Sciences

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Aqueduct, one kind of bridge structure overpassing a long space, is a significant structure for water delivery for the purpose of agricultural or domestic usage. Aqueduct has quite different loads from other forms of bridges, of which temperature effects due to the environment temperature change, such as seasonal weather or radiation from sunshine, are of great importance. With water flowing inside, the temperature boundary of aqueducts, especially for steel aqueducts, is much more complicated, and relevant researches are limited. In this paper, a 3D Finite Element Method (FEM) simulation process is presented to analyze temperature distribution on the cross-section of a new-type steel truss aqueduct, which belongs to the Water Transfer Project from Yangtze River to Huai River in China. ASHRAE clear-sky model is used to calculate the solar-radiation variation, including direct radiation, diffuse sky radiation, and ground reflected radiation on steel surfaces. The time-dependent sunshine radiation angle of incidence and shielding effect of steel trusses are considered. The water inside the aqueduct is also included in this model, which significantly influences the temperatures of the inner surfaces of the aqueduct. Several temperature distributions under critical conditions of winter and summer are shown in this study, and results of the empty aqueduct under the same circumstances are also provided as a comparison. The effects of wind speed, geographic latitude, and direction of the aqueduct are examined. The conclusions and approach provided by this study could serve as significant references for thermal design and control of similar steel truss aqueducts.

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Experimental and simulation analysis of thermal behavior of large‐span roof system under solar radiation

Wang

Xin

et al. 2023

Structural Design Tall Build

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The large-span metal roof systems can produce a significant nonuniform temperature effect under solar radiation, leading to potential safety hazards. An experiment is conducted to study the nonuniform thermal behavior of a small-scale continuous welded stainless steel roof (CWSSR) system under solar radiation. The small-scale CWSSR system considered different roof slopes and sunward side and nightside. The efficiency of the numerical analysis of the thermal behavior of the roof slab is verified in comparison with the experimental results. Based on the numerical and experimental results, the thermal effect of a full-scale CWSSR system is studied under different orientations, wind speeds, and atmospheric temperature. Through the analysis of research results, the nonuniform thermal features of the CWSSR system are significant and cannot be overlooked. The temperature difference between the sunward side and nightside roof slab is positively correlated with the roof slope. The thermal behavior of the CWSSR system is greatly influenced by wind speeds but is less affected by orientations and atmospheric temperature.

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Non-Uniform Temperature Fields and Effects of Steel Structures: Review and Outlook

Cited by 9 publications

References 102 publications

Predicting Maximum Effective Temperatures and Thermal Gradients for Steel I-Girder in Canadian Climate Regions

Predicting Maximum Effective Temperatures and Thermal Gradients for Steel I-Girder in Canadian Climate Regions

Numerical Study on Temperature Distribution of Steel Truss Aqueducts under Solar Radiation

Experimental and simulation analysis of thermal behavior of large‐span roof system under solar radiation

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