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47 results on '"Fire Condition"'

2. Stability behaviour of sinusoidal corrugated web girders under fire conditions.

Author

Kollár, Dénes

Subjects
GIRDERS, FINITE element method, HIGH temperatures, CIVIL engineering, FAILURE mode & effects analysis, FIRE testing
Abstract

Sinusoidal corrugated web girders, which are in the focus of the current paper, have been increasingly used in the past years in civil engineering applications due to economical design. Recently, a number of experiments dealing with the particular behaviour of this girder type have been carried out at room temperature, while the structural behaviour at elevated temperature has not been widely analysed and requires further investigation and clarification. The current paper deals with the improved geometrically and materially nonlinear analysis with imperfections (GMNIA) of sinusoidal corrugated web girders under fire conditions. The developed finite element model, which is validated based on previous measurements during fire tests found in the international literature, is capable of modelling the specialties, e.g., the so‐called 'accordion effect', of corrugated web girders. The applicability of design formulae is also illustrated in the paper while an extensive numerical parametric study is also carried out to demonstrate the impact of different parameters on the stability behaviour and failure mode of corrugated web girders at elevated temperature. [ABSTRACT FROM AUTHOR]

Published
2023
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3. Study on Membrane Damage and Collapse of Air-Supported Structures under Fire Conditions.

Author

Yan, Fei, Sun, Guojun, and Xue, Suduo

Subjects
*AIR-supported structures, *STRENGTH of materials, *PUBLIC buildings, *TIME management
Abstract

Air-supported structures are widely used as public buildings. Air-supported structures are soft and most traditional fire-fighting installations cannot be used in them. Existing design specifications only specify the fire resistance of the materials to be used for air-supported structures and there is no fire resistance design method for air-supported structures. The destruction process of air-supported structures can be divided into three stages: pre-fracture, leakage, and collapse. Theorical and numerical models were used to research the time span of all those stages. A framework to estimate the collapse and evacuation time was proposed in this paper. Air-supported structures with different spans were researched in this paper, and we found that the height of a structure has a significant influence on its fire resistance. The evacuation time increased by more than 52 times when the structure's span increased from 20 m to 80 m. The pre-fracture stage contributed to more than 90% of the evacuation time when the span of structure was larger than 80 m. [ABSTRACT FROM AUTHOR]

Published
2022
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4. Experimental Study of Flexural Performance of UHPC–NC Laminated Beams Exposed to Fire.

Author

Zhou, Tieming and Sheng, Xingwang

Subjects
*HIGH strength concrete, *LAMINATED materials, *GALENA, *DETERIORATION of concrete, *BEND testing, *PERFORMANCE theory, *ECCENTRIC loads
Abstract

In recent decades, reinforced-concrete bridges have experienced premature deterioration and other problems during service due to severe environmental effects such as fire and corrosion. Previous studies have shown that the use of ultra-high-performance concrete (UHPC) can improve the durability of bridge structures. In this study, four-point bending tests were conducted on twelve UHPC–NC laminated beams with different UHPC-layer heights and at different temperatures in order to evaluate their flexural performance under fire conditions. The test variables were the UHPC heights (20 mm, 50 mm, 80 mm) and temperatures (20 °C, 200 °C, 400 °C, 600 °C), and the effects on the flexural load capacity of UHPC–NC laminated beams under the influence of these factors were investigated. The test results show that the increase in temperature causes the concrete color to change from grayish blue to white and leads to a significant decrease in the flexural load capacity of the stacked beams. The height of the UHPC layer has an important effect on the stiffness of the stacked beams and delays the formation of local cracks, thus improving the durability of the stacked beams. [ABSTRACT FROM AUTHOR]

Published
2022
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6. Study on Membrane Damage and Collapse of Air-Supported Structures under Fire Conditions

Author

Fei Yan, Guojun Sun, and Suduo Xue

Subjects
air-supported structures, fire condition, weld joint, collapse, Physics, QC1-999
Abstract

Air-supported structures are widely used as public buildings. Air-supported structures are soft and most traditional fire-fighting installations cannot be used in them. Existing design specifications only specify the fire resistance of the materials to be used for air-supported structures and there is no fire resistance design method for air-supported structures. The destruction process of air-supported structures can be divided into three stages: pre-fracture, leakage, and collapse. Theorical and numerical models were used to research the time span of all those stages. A framework to estimate the collapse and evacuation time was proposed in this paper. Air-supported structures with different spans were researched in this paper, and we found that the height of a structure has a significant influence on its fire resistance. The evacuation time increased by more than 52 times when the structure’s span increased from 20 m to 80 m. The pre-fracture stage contributed to more than 90% of the evacuation time when the span of structure was larger than 80 m.

Published
2022
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7. Simplified analytical model for prediction of collapse resistance of restrained steel beam-column substructure exposed to fire.

Author

Guo, Zhan, Cai, Wei, Nie, Zhenhua, and Chen, Yu

Subjects
*PROGRESSIVE collapse, *FIRE testing, *PREDICTION models, *STEEL, *THERMAL expansion, *COMPUTER simulation, *NUMERICAL analysis
Abstract

• Mechanical response characteristics of beam-column substructures exposed to fire are analyzed. • Explicit calculation formulas for determining the collapse resistance are derived in detail. • Proposed theoretical calculated formulas agree well with these from numerical simulations. • Error analysis is conducted to reveal deviation reasons between theoretical model and numerical simulations. This paper provides a simplified analytical model for the restrained steel beam-column substructure under a fire-induced progressive collapse scenario, which is applied to predict the collapse resistance of substructures under fire. The simplified model is formulated for axially and rotationally restrained two-span steel beam-column substructures under column-loss scenarios and involves rigid and semi-rigid connections. The response characteristics of restrained substructures exposed to fire under column-loss scenarios in each response stage are elaborately analyzed. A "negative" catenary stage, in consideration of the unique negative axial force effects induced by the temperature thermal expansion, was first introduced in the five-stage simplified model for restrained substructures exposed to fire against progressive collapse. Subsequently, the explicit calculation formulas for determining the vertical loads and deflection of both rigid and semi-rigid joint substructures exposed to fire were derived in a quantified way, based on rigid-plastic mechanisms and restraint coefficient methods. In addition, the corresponding numerical simulation analysis on a restrained two-span steel beam-column substructure with different end constraints and fire conditions was carried out to verify the applicability and reliability of established theoretical formulas. Comparisons of vertical load-deflection relationships between the calculation formulas and corresponding numerical simulation shows good accuracy. For more accurate prediction results, the error analysis was further conducted, and several theoretical formulas were modified, which were verified to be accurate and reliable after correction. With derived resistance functions, the resistance of steel beam-column substructures in fire-induced progressive collapse scenarios can be predicted. [ABSTRACT FROM AUTHOR]

Published
2024
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10. The Effectiveness of Virtual Reality for Studying Human Behavior in Fire

Author

Feng, Xinxin, Cui, Rongzhen, Zhao, Jiabao, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Shumaker, Randall, editor, and Lackey, Stephanie, editor

Published
2015
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11. Effect of discrete glass fibers on the behavior of R.C. Beams exposed to fire

Author

Magdy Riad, M.M. Genidi, Ata El-kareim Shoeib, and Sherif F.M. Abd Elnaby

Subjects
Discrete glass fibers, Fire condition, RC beam ductility and deformability, Engineering (General). Civil engineering (General), TA1-2040, Building construction, TH1-9745
Abstract

The main objective of this paper is to investigate the effect of adding discrete glass fibers on the behavior of reinforced concrete (RC) beams under different fire and cooling conditions. Eighteen beams with different concrete compressive strengths were tested to study the behavior of reinforced concrete (RC) beams containing discrete glass fibers when exposed to different fire and cooling conditions. Nine beams were prepared from normal strength concrete (NSC) with compressive strength equal to 35 MPa while the other beams were prepared from high strength concrete (HSC) with compressive strength equal to 60 MPa. The beams contained different contents of discrete glass fibers. The modes of failure of tested specimens show that the crack patterns change according to fire condition and fiber content. Analysis of test results show that adding discrete glass fibers to NSC increased the residual stiffness of the tested specimens after firing and decreased the rate of the deflection gain during firing. Also adding fibers to concrete has a limited positive effect on the ultimate strength of the specimens compared to the control specimens. Its effect on deflection due to fire is more pronounced. Finally, the recommended optimum ratio of discrete glass fibers is not more than 0.5% of the total concrete weight.

Published
2017
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14. Static strength of axially loaded tubular KT-joints at elevated temperatures: Study of geometrical effects and parametric formulation.

Author

Azari Dodaran, Neda, Ahmadi, Hamid, and Lotfollahi-Yaghin, Mohammad Ali

Subjects
*FINITE element method, *AXIAL loads, *MECHANICAL buckling, *JOINT stiffness, *ULTIMATE strength
Abstract

Abstract This paper aims to study the structural behavior of tubular KT-joints subjected to axial loading at fire induced elevated temperatures. At first, a finite element (FE) model was developed and validated against the data available from experimental tests. Then, a set of 810 FE analyses were performed to study the influence of temperature and dimensionless geometrical parameters ( β , γ , θ , and τ ) on the ultimate strength and initial stiffness. The joints were analyzed under two types of axial loading and five different temperatures (20 °C, 200 °C, 400 °C, 550 °C, and 700 °C). Up to now, there has not been any design formula available for determining the ultimate strength of KT-joints at elevated temperatures. Hence, after parametric study, a new equation was developed through nonlinear regression analyses, for calculating the ultimate strength of KT-joints subjected to axial loading at elevated temperatures. Highlights • The ultimate strength and failure modes of tubular KT-joints at fire-induced elevated temperatures were investigated. • Tubular KT-joints were subjected to two types of axial loading. • Results of 810 steady-state FE analyses were used for the parametric study. • A set of new design equations was derived to calculate the ultimate strength of KT-joints subjected to axial loading. [ABSTRACT FROM AUTHOR]

Published
2018
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15. Stress redistribution of simply supported reinforced concrete beams under fire conditions.

Author

Ding, Fa-xing, Li, Zhe, Cheng, Shan-shan, and Yu, Zhi-wu

Abstract

This study presents experimental and numerical investigations of simply supported steel reinforced concrete (RC) beams under fire. The temperature field of cross sections, the vertical deflection at mid-span, and specifically the axial expansion displacement at beam-ends were measured during the fire tests. A novel finite element (FE) model of a RC beam under fire was developed, in which the water loss in the heat transfer analysis and the concrete transient strain in the mechanical analysis were considered. Based on the validated FE model proposed in this study, parametric studies were conducted to investigate the effects of the beam type, the protective layer thickness, and the load ratio on the thermal and mechanical behavior of simply supported RC beams. It was found that greater fire resistance and fire performance of girder beams in comparison to secondary beams contributed to the non-structural reinforcements, which effectively compensated for the reduced tensile capacities of structural reinforcements because of the degradation of the material properties. In addition, the history of normal stress distributions of concrete under fire can be divided into three phases: expansion, stress redistribution and plateau phases. [ABSTRACT FROM AUTHOR]

Published
2018
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16. Experimental and numerical analysis of a walls made from aerated concrete blocks exposed to fire

Author

Mirković-Marjanović, Milica, Kijanović, Aleksandar, Ilić, Snežana, Todorović, Goran, Gospavić, Radovan, Mirković-Marjanović, Milica, Kijanović, Aleksandar, Ilić, Snežana, Todorović, Goran, and Gospavić, Radovan

Abstract

In this paper solution of a non-stationary one dimensional (1D) heat conduction problem has been presented. The finite difference method, i.e. by applying energy balance has been used. The finite difference method has been applied and the partial differential equation of heat conduction has been reduced to an algebraic form. This procedure is also called discretization problem. By solving the system of algebraic equations, temperatures at discrete points - network nodes were obtained. Additional discretization was performed in non-stationary processes over time. Numerical 1D non- stationary calculation was performed on six walls of different thickness made of aerated concrete 50 mm, 75 mm, 100 mm, 120 mm, 150 mm and 250 mm thick are exposed to the developed fire. The developed fire represents the logarithmic dependence of the temperature as a function of time according to the standard SRPS EN 834-1. The period of wall heating was analyzed, i.e. period until the moment when the temperature rise is observed on the non-exposed side of the wall. The paper compares the achieved experimental results with the obtained numerical results.

Published
2022

17. Uzay çelik yapıların yangın altındaki performansı

Author

Tuyishime, Enock, Türker, Hakan T., and Bursa Uludağ Üniversitesi/Fen Bilimleri Enstitüsü/İnşaat Mühendisliği Anabilim Dalı.

Subjects
Geometrik kusur, Fire condition, Geometric imperfection, Termal genleşme, Thermal expansion, Yangın durumu
Abstract

Yangına dayanıklılık ve tasarımda, yüksek sıcaklığın çeliğin fiziksel ve mekanik özellikleri üzerinde bariz bir etkisi vardır. Ateş altındaki yapı elemanlarının sıcaklıkları arttığında kritik seviyeye ulaşana kadar dirençleri önemli ölçüde azalır. Ayrıca yapı elemalarındaki başlangıç kusurları yapının performansını etkiler. Bu çalışmanın amacı, uzay kafes sistemlerin yangın altında davranışlarına ilişkin modellerini oluşturmaktır. Spesifik olarak, bu çalışma ayrıca, yangın koşulları altında basınç elemanlarındaki başlangıç eğrilik kusurun olması halinde ve yangın altında performanslarını incelemektir. ABAQUS/Explicit sonlu elemanlar programı, yapısal analizleri ve tüm hesaplama simülasyonları yürütmek için kullanılmıştır. Kiriş elemanları malzeme ve geometrik doğrusal olmayan davranış dikkate alınarak kullanılmıştır. Hem ortam hem de artan sıcaklıklarda, başlangıç kusurlu ve kusursuz dış yüklere maruz kalan yapı elemanları, kafes kirişler ve uzay kafes sistemi üzerinde bir dizi incelemenin çözümleri gerçekleştirilmiştir. Mümkün olduğunda, ABAQUS çözümleri teorik çözümlerle karşılaştırılmıştır. Bu çalışma boyunca yapılan analizlere göre, yapısal eleman, termal genleşme kısıtlaması nedeniyle yüksek sıcaklıklarda çok önemli kuvvetler oluşturabilmektedir. Termal olarak üretilen bu kuvvetler, kolonun dış yüke dayanma kapasitesini azaltır ve ayrıca ilk kusurlar yapı kapasitesini de azaltır. Bu nedenle, yangına maruz kalan kolonların performansı, termal olarak oluşturulan kuvvetlerden önemli ölçüde etkilenebilir. In the fire resistance and design, high temperature has an obvious effect on the physical and mechanical properties of steel. When the temperature of structural members which are under fire increases, their resistance reduces significantly until they reach the critical level. And also, the structural defects affect its capacity. The aim of this study is to provide analysis of models on the behaviours of steel structural members in fire as single elements, in truss and in space steel frame. Specifically, this study also, emphases the effect of initial geometric imperfection on structural compression members under fire conditions. The ABAQUS/Explicit finite element program is used to conduct all computational simulations for all structural analyses. The beam elements are used with considerable material and geometric nonlinearity. The solutions of a number of investigations on individual structural element, on truss members and the space frame subjected to the external loads at both ambient and increased temperatures, with and without initial imperfection are conducted. For single members, ABAQUS solutions is compared to theoretical solutions. According to the analyses throughout this study, the structural member can create very significant forces at high temperatures due to thermal expansion constraint. These thermally generated forces diminish the column's capacity to withstand external load and also the initial imperfections reduce the structure capacity as well. Therefore, the performance of columns exposed to fire might be significantly impacted by thermally generated forces.

Published
2022

18. A Guided Vehicle under Fire Conditions Based on a Modified Ultrasonic Obstacle Avoidance Technology

Author

Sen Li, Chunyong Feng, Xiaoge Liang, Hengjie Qin, Haihang Li, and Long Shi

Subjects
Ultrasonic obstacle avoidance technology, guided vehicle, fire condition, baffle calibration method, Chemical technology, TP1-1185
Abstract

Low visibility and hot smoke environment under fire conditions can largely hamper the related fire rescue processes. Ultrasound obstacle avoidance technology is then useful for guidance. However, the biggest challenge of adopting ultrasound technology comes from accurate distance measurements under the disturbances of high temperature and soot particle concentration. It is critical to measure the propagation speed under the complicated fire conditions. Therefore, in this study, a baffle calibration method was proposed to improve the accuracy of distance measurement of an obstacle. The method is based on two ultrasound measurement systems, while one is used to calibrate the propagation speed of ultrasound based on the fixed distanced baffle and the other is for the dynamic measurement of obstacle distance based on the calibrated speed. The viability of this method on the guided vehicle was confirmed based on the experiments. From its comparison to those existing methods, such as constant speed and temperature compensation methods, it was known from that the proposed baffle calibration method provides the best prediction. It was obtained that the maximum errors based on the baffle calibration method are 2.75% and 2.62% under the two representative fire scenarios, respectively, which are much lower than those of constant speed (7.81% and 8.4%) and temperature compensation methods (10.4% and 5.12%).

Published
2018
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19. Experimental study on fire response of double glazed panels in curtain walls.

Author

Wang, Yu, Wang, Qingsong, Su, Yanfei, Sun, Jinhua, He, Linghui, and Liew, K.M.

Subjects
*CONSUMER panels, *CURTAIN walls, *SEALED double glazing, *RESPONSIVE gels, *FIRE risk assessment
Abstract

Double glazing is increasingly employed in glass curtain walls, but very little is known about its thermal response under fire conditions. In this work, a total of twenty seven 600 × 600 mm 2 double glazing units, with 6 mm, 9 mm and 12 mm air spacings, were tested. Three different installation types were adopted: 1) exposed frames, 2) horizontal-hidden frames and 3) vertical-hidden glass in order to study their potential effects on the glazing breakage behavior. A 500 × 500 mm 2 n -heptane pool fire was used to heat the glass panes. The breaking time, surface temperature, total heat flux, heat release rate, and crack and fallout morphology were measured and analyzed. The test result suggests that different installation types have a significant effect on the fracture behavior of double glazing, especially for glass panes located at the fire side. Glass in exposed framing is more prone to cracks than those in semi-exposed frame, but fallout may more easily occur in semi framing façades. When no, or very limited fallout occurs at the fire side pane, thicker air space leads to a longer breakage time of ambient glass panes, thus improving the unit's integrity during fire. The experimental results obtained in this study is valuable for the development of practical guidelines for fire safety design. [ABSTRACT FROM AUTHOR]

Published
2017
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20. Effect of discrete glass fibers on the behavior of R.C. Beams exposed to fire.

Author

Riad, Magdy, Genidi, M.M., Shoeib, Ata El-kareim, and Abd Elnaby, Sherif F.M.

Subjects
GLASS fibers, CONCRETE beams, COMPRESSIVE strength, HIGH strength concrete testing, CRACKING of concrete
Abstract

The main objective of this paper is to investigate the effect of adding discrete glass fibers on the behavior of reinforced concrete (RC) beams under different fire and cooling conditions. Eighteen beams with different concrete compressive strengths were tested to study the behavior of reinforced concrete (RC) beams containing discrete glass fibers when exposed to different fire and cooling conditions. Nine beams were prepared from normal strength concrete (NSC) with compressive strength equal to 35 MPa while the other beams were prepared from high strength concrete (HSC) with compressive strength equal to 60 MPa. The beams contained different contents of discrete glass fibers. The modes of failure of tested specimens show that the crack patterns change according to fire condition and fiber content. Analysis of test results show that adding discrete glass fibers to NSC increased the residual stiffness of the tested specimens after firing and decreased the rate of the deflection gain during firing. Also adding fibers to concrete has a limited positive effect on the ultimate strength of the specimens compared to the control specimens. Its effect on deflection due to fire is more pronounced. Finally, the recommended optimum ratio of discrete glass fibers is not more than 0.5% of the total concrete weight. [ABSTRACT FROM AUTHOR]

Published
2017
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22. Fire behaviour of deep beams under unsymmetrical loading

Author

Kang Hai Tan, Shengxin Fan, Yao Zhang, and School of Civil and Environmental Engineering

Subjects
Materials science, Civil engineering [Engineering], Deep Beams, business.industry, media_common.quotation_subject, Magnitude (mathematics), Structural engineering, Asymmetry, Fire performance, Fire Condition, Shear (sheet metal), Deflection (engineering), Reinforcement, business, Failure mode and effects analysis, Civil and Structural Engineering, Test data, media_common
Abstract

This paper focuses on the condition where a reinforced concrete (RC) deep beam is subjected to two concentrated loads (P1 and P2), which are positioned at respective distances a and c from bottom supports. In general, equal shear spans (a = c) and equal point loads (P1 = P2) are commonly assumed in most experimental programmes. Nevertheless, such cases are rare in practice. In contrast, due to the fact that deep beam floor normally subjects to irregular layout of column grid, deep beams are usually subjected to unequal load magnitude (load inequality or P1 ≠ P2) and unsymmetrical load positions (load asymmetry or a ≠ c). Although previous research has demonstrated the significant influences of load asymmetry and inequality on the structural performance of deep beams at room temperature, no research programme has been performed to study their influences on the fire performance of deep beams. As a result, this study is proposed to investigate the shear behaviour of unsymmetrically-loaded deep beams at fire condition, analytically and experimentally. The current research first derives a strut-and-tie-model (STM) to predict the shear capacity of RC deep beams under unequal/unsymmetrical loading conditions and at elevated temperatures. The STM takes into account the effects of unsymmetrical loading configurations, contribution of steel reinforcement on strut capacity, and thermal-induced gradient. Additionally, a test programme on six RC deep beams under fire condition is conducted for verification of the proposed model. Observations from this experimental programme show that load asymmetry and inequality have different effects on the fire performance of deep beams. To be more specific, an increase in load inequality leads to an alteration in failure mode of the deep beams, whist load asymmetry does not affect the failure mode as much. On the other hand, increasing load inequality can result in a significantly increased mid-span deflection at failure and a slightly increased failure time. Besides, effect of load inequality on deflection and failure duration depends on the loading positions. Furthermore, the proposed STM yields good agreement between test data and model predictions for unequally- and/or unsymmetrically-loaded deep beams, at both room and high temperatures. Ministry of National Development (MND) National Research Foundation (NRF) This research work is supported by the Singapore Ministry of National Development and National Research Foundation under L2 NIC Award No. L2NICCFP1-2013-4.

Published
2022

24. Thermal performance of exposed framing glass façades in fire.

Author

Wang, Yu, Wang, Qingsong, Sun, Jinhua, He, Linghui, and Liew, K.

Abstract

Façades made of glass are viewed as one of the weakest parts of a building which can easily break in case of fire and change the compartment fire dynamic by creating a new opening for air to enter. A total of six clear glass panes were placed 750 and 500 mm away from a 500 × 500 mm n-heptane pool fire to investigate the breakage behavior of fully exposed framing glass façades. Both float and toughened glass panes with a dimension of 600 × 600 × 6 mm were tested. The results presented include the time to breakage occurrence, heat release rates, incident heat flux, central gas temperatures and glass surface temperatures. The crack initiation and propagation as well as the loss of integrity of the glazing assembly were also recorded. The experimental results established that the critical temperature difference and heat flux for float glass were approximately 90 °C and 14 kW/m. All their cracks were initiated from the edge of glass pane and intersected rapidly, forming some islands, but the fraction of fallout was considerably small because of the protection of frame. However, the toughened glass did not break even though the center temperature reached a high value of 413 °C. Using finite element method, breakage mechanism of float glass pane is demonstrated, and the numerical predictions are further compared with the experimental measurements. [ABSTRACT FROM AUTHOR]

Published
2016
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25. 火灾条件下混凝土箱梁梁端预应力衰变规律.

Author

张岗, 刘天龙, 施颖, and 宣纪明

Abstract

Copyright of Journal of Architecture & Civil Engineering is the property of Chang'an Daxue Zazhishe 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
2016
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26. Fracture behavior of framing coated glass curtain walls under fire conditions.

Author

Wang, Yu, Wang, Qingsong, Su, Yanfei, Sun, Jinhua, He, Linghui, and Liew, K.M.

Subjects
*FRACTURE mechanics, *GLASS, *FIRE prevention, *CONSTRAINTS (Physics), *TEMPERATURE effect
Abstract

Breaking glass and its subsequent fallout may markedly affect enclosure fire dynamics. However, little is known about the thermal fracture behavior of framing glass façades in different installation forms. Sixteen 600×600×6 mm 3 solar control coated glass panes, installed in exposed, semi-exposed and hidden frames, were heated by a 500×500 mm 2 n-heptane pool fire to investigate the influence of frame constraints on glass breakage and fallout. Measurements were taken of the time to breakage occurrence, heat release rates, incident heat flux, central gas temperatures and glass surface temperatures. Measurements in relation to crack initiation and propagation as well as loss of integrity of the glazing assembly were also recorded. The experimental results show that all cracks initiated at the edge of covered sections and intersected rapidly, forming islands. The maximum temperature difference and heat flux that the glass can withstand are primarily in the range of 50–90 °C and 9–15 kW/m 2 . Using the finite element method (FEM), the breakage mechanism is demonstrated, the predictions of which are in reasonably good agreement with the experimental results. Among four different installation forms, semi-exposed framing façades showed better fire resistance than exposed framing façades. Meanwhile, the fire resistance of hidden framing façades may depend on the fire location. It is intended that these results will provide practical guidelines for fire safety design. [ABSTRACT FROM AUTHOR]

Published
2015
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27. Experimental Study of Flexural Performance of UHPC–NC Laminated Beams Exposed to Fire

Author

Tieming, Zhou and Xingwang, Sheng

Subjects
ultra-high-performance concrete (UHPC), flexural behavior, fire condition, General Materials Science
Abstract

In recent decades, reinforced-concrete bridges have experienced premature deterioration and other problems during service due to severe environmental effects such as fire and corrosion. Previous studies have shown that the use of ultra-high-performance concrete (UHPC) can improve the durability of bridge structures. In this study, four-point bending tests were conducted on twelve UHPC–NC laminated beams with different UHPC-layer heights and at different temperatures in order to evaluate their flexural performance under fire conditions. The test variables were the UHPC heights (20 mm, 50 mm, 80 mm) and temperatures (20 °C, 200 °C, 400 °C, 600 °C), and the effects on the flexural load capacity of UHPC–NC laminated beams under the influence of these factors were investigated. The test results show that the increase in temperature causes the concrete color to change from grayish blue to white and leads to a significant decrease in the flexural load capacity of the stacked beams. The height of the UHPC layer has an important effect on the stiffness of the stacked beams and delays the formation of local cracks, thus improving the durability of the stacked beams.

Published
2022
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29. Elevated Temperature Effects on Local Buckling of Wide Flange Columns

Author

Baidar, Nikki

Subjects
Civil Engineering, local buckling, elevated temperature, fire condition, steel column, finite element modeling, wide flange column
Abstract

Wide flange steel columns under compression that are designed for ambient conditions may fail due to local buckling when subjected to fire conditions. At elevated temperatures, the sections may behave as slender elements due to strength and stiffness reductions in the mechanical properties of the steel. There is currently no provision in the AISC Specification (2016) for determining the local buckling capacity of columns under fire. This work aims to build on previous studies to better understand the local buckling capacity of columns subjected to uniaxial compression at elevated temperatures. A finite element modeling program, ABAQUS, was used to develop numerical models of wide flange steel columns under fire conditions. A parametric study of steel stub columns subjected to different temperatures (ambient, 400°C, and 600°C) and various section slenderness ratios was conducted. ASTM A992 steel (Gr. 50) steel columns were analyzed to determine the effect of temperature and section slenderness on the local buckling of columns at elevated temperatures. Three different wide flange steel cross-sections, W14×120, W12×96, and W10×88, were studied and their flange and web thicknesses were varied. Some sections that failed due to global buckling at ambient temperature failed due to local buckling at elevated temperatures. When the applied temperature in the column increases, the load capacity of the steel column decreases. Additionally, the column load capacity at elevated temperatures decreases as the slenderness ratio of the cross-section (flange and web) increases. The flange slenderness has a greater influence on column capacity than the web slenderness. The columns with high interactive slenderness ratio were most affected at 600°C.The load capacity for each column was estimated using the current AISC 360 (2016) equation for local buckling at ambient temperature; however, the material properties (yield strength and modulus of elasticity) were modified to correspond to elevated temperature properties. These calculated values were compared to the failure load determined from the modeling for each of the steel columns. The present AISC equations were found to be inadequate for determining the local buckling capacity of a column with slender elements at elevated temperatures. An interactive slenderness term was defined as (&#955f/&#955rf) (&#955w/&#955rw), where &#955f is the flange slenderness of the column, &#955w is the web slenderness of the column, &#955rf is the limiting slenderness ratio of flange, and &#955rw is the limiting slenderness ratio of the web. Thus, the ratio of flange slenderness to limiting flange ratio was multiplied by the ratio of web slenderness to limiting web ratio to develop a slenderness term that incorporates both web and flange slenderness together. As the interactive slenderness of the column increased, the AISC 360 (2016) provisions over-estimated the column capacity at 400°C and 600°C.An equation must be developed to better estimate the local buckling capacity at elevated temperature. Results of this study will serve as the basis of efforts to formulate an independent design equation for local buckling of wide flange columns under fire load. This design equation would be incorporated into the simple method of analysis within Appendix 4 of the AISC Specification (2016).

Published
2022

30. Deterioration of mechanical properties of high strength structural steel S460N under transient state fire condition

Author

Qiang, Xuhong, Bijlaard, Frans S.K., and Kolstein, Henk

Subjects
*DETERIORATION of metals, *MECHANICAL properties of metals, *HIGH strength steel, *STRUCTURAL steel, *FIRE prevention
Abstract

Abstract: 911 World Trade Centre Tragedy put fire safety of constructional steel structures into question. Since then, more and more research attention has been paid to the elevated-temperature mechanical properties of structural steels, which is a critical basis of evaluating the fire performance of steel structures. In the literature the available mechanical properties of structural steels under fire conditions were mainly obtained from steady state test method, as steady state test method is easier to perform than transient state test method and offers stress–strain curves directly. However, the transient state fire condition is considered to be more realistic to represent the real condition when constructions are exposed to fire. In order to reveal the deterioration of mechanical properties of the commonly used high strength structural steel S460N under transient state fire condition, tensile tests were conducted under various constant stress levels up to 800MPa. The reduction factors of elastic modulus, yield and ultimate strengths of S460N under transient state fire condition were obtained and compared with current leading design standards and available literature. The application of such accurate elevated-temperature mechanical properties reduction factors of S460N can ensure a safe fire-resistance design and evaluation of steel structures with high strength steel S460N under transient state fire condition. This experimental study also supports other relative research on fire performance of steel structures with S460N under transient state fire condition. [Copyright &y& Elsevier]

Published
2012
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31. Fire behaviour of deep beams under unsymmetrical loading.

Author

Fan, Shengxin, Zhang, Yao, and Tan, Kang Hai

Subjects
*REINFORCING bars, *HIGH temperatures, *FAILURE mode & effects analysis, *REINFORCED concrete, *ECCENTRIC loads, *STRUT & tie models
Abstract

• A STM approach is proposed for unsymmetrically-loaded RC deep beams at elevated temperatures. • The model considers load inequality , load asymmetry and web steel contribution on strut capacity. • Six deep beams are tested under combined effect of unsymmetrical loads and fire condition. • Load inequality and asymmetry significantly affected the overall behaviour of heated deep beams. • STM yielded conservative predictions for unsymmetrically-loaded deep beams at elevated temperatures. This paper focuses on the condition where a reinforced concrete (RC) deep beam is subjected to two concentrated loads (P 1 and P 2), which are positioned at respective distances a and c from bottom supports. In general, equal shear spans (a = c) and equal point loads (P 1 = P 2) are commonly assumed in most experimental programmes. Nevertheless, such cases are rare in practice. In contrast, due to the fact that deep beam floor normally subjects to irregular layout of column grid, deep beams are usually subjected to unequal load magnitude (load inequality or P 1 ≠ P 2) and unsymmetrical load positions (load asymmetry or a ≠ c). Although previous research has demonstrated the significant influences of load asymmetry and inequality on the structural performance of deep beams at room temperature, no research programme has been performed to study their influences on the fire performance of deep beams. As a result, this study is proposed to investigate the shear behaviour of unsymmetrically-loaded deep beams at fire condition, analytically and experimentally. The current research first derives a strut-and-tie-model (STM) to predict the shear capacity of RC deep beams under unequal/unsymmetrical loading conditions and at elevated temperatures. The STM takes into account the effects of unsymmetrical loading configurations, contribution of steel reinforcement on strut capacity, and thermal-induced gradient. Additionally, a test programme on six RC deep beams under fire condition is conducted for verification of the proposed model. Observations from this experimental programme show that load asymmetry and inequality have different effects on the fire performance of deep beams. To be more specific, an increase in load inequality leads to an alteration in failure mode of the deep beams, whist load asymmetry does not affect the failure mode as much. On the other hand, increasing load inequality can result in a significantly increased mid-span deflection at failure and a slightly increased failure time. Besides, effect of load inequality on deflection and failure duration depends on the loading positions. Furthermore, the proposed STM yields good agreement between test data and model predictions for unequally- and/or unsymmetrically-loaded deep beams, at both room and high temperatures. [ABSTRACT FROM AUTHOR]

Published
2022
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32. An embedded FE model for modelling reinforced concrete slabs in fire

Author

Yu, Xinmeng and Huang, Zhaohui

Subjects
*CRACKS in reinforced concrete, *CONCRETE slabs, *FIRE testing, *FINITE element method, *CORIOLIS force, *CONSTRUCTION materials
Abstract

Abstract: It is evident from a series of tests on simply supported reinforced concrete slabs that the failure of the slabs at large deflections is due to the formation of individual large cracks. This failure mode was also observed in the Cardington full-scale fire tests. Previous research indicates that the global behaviour of concrete slabs subject to large deflections can be well predicted by the smeared cracking model; however, the model cannot quantitatively predict the openings of individual cracks within the slabs at large deflections. For the discrete approach it is usually assumed that the cracks are formed along element edges, therefore continuous re-meshing is required during the analysis. Consequently, the results are mesh-dependent and the computing cost is high. In recent years, mesh independent finite element procedures, such as embedded (EFEM) and extended (XFEM) approaches, were widely used for modelling of the crack initiation and growth in structural members. However, most of the meshless models developed are either based on in-plane loading conditions or confined to thin shells with assumed full-depth cracks, which form apparent displacement jumps within an element. For a reinforced concrete slab, an out-of-plane load causes coupled stretching and bending of the slab, cracks are usually initiated at discrete positions and then propagated, until at last some individual full-depth cracks are formed. Pure stretching or assumed full-depth cracking is inadequate for modelling this kind of failure. Therefore, in this research, a non-linear layered procedure with embedded weak discontinuity is developed to quantitatively model the progressive tensile failure of reinforced concrete slabs subjected to large deflections. The current model inherits the advantage of the smeared approach, and at the same time, introduces the opening width of crack explicitly by taking the advantage of the better description of the kinematic characteristics of the EFEM approach. A series of validations have been conducted against test data at both ambient and elevated temperatures, and the research shows that the model developed in this paper is not sensitive to the FE mesh size and the aspect ratio of the slab. The results predicted by the model developed agreed well with the test data in terms of deflection and crack open width, also agreeing well with those modelled by the smeared model. Hence, this new approach provides a numerical method to predict the load capacity as well as identifying the occurrence and severity of crack failure in reinforced concrete slabs subjected to extreme loading conditions, such as fire. [Copyright &y& Elsevier]

Published
2008
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33. Performance assessment on high strength steel endplate connections after fire

Author

Qiang, X., Wu, N., Jiang, X., Bijlaard, F.S.K., and Kolstein, M.H.

Subjects
Structural fre performance, Mechanics of Materials, Beam-to-column connections, Endplate connections, Mechanical Engineering, 021105 building & construction, 0211 other engineering and technologies, Fire condition, 020101 civil engineering, 02 engineering and technology, High strength steel, Safety, Risk, Reliability and Quality, 0201 civil engineering
Abstract

Purpose This study aims to reveal more information and understanding on performance and failure mechanisms of high strength steel endplate connections after fire. Design/methodology/approach An experimental and numerical study on seven endplate connections after cooling down from fire temperature of 550°C has been carried out and reported herein. Moreover, the provisions of European design standard for steel structures, Eurocode 3, were validated with test results of high strength steel endplate connections. Findings In endplate connections, a proper design using a thinner high strength steel endplate can achieve the same failure mode, similar residual load bearing capacity and comparable or even higher rotation capacity after cooling down from fire. It is found that high strength steel endplate connection can regain more than 90 per cent of its original load bearing capacity after cooling down from fire temperature of 550°C. Originality/value The post-fire performance of high strength steel endplate connection has been reported. The accuracy of Eurocode 3 for endplate connections is validated against test results.

Published
2017
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34. A Guided Vehicle under Fire Conditions Based on a Modified Ultrasonic Obstacle Avoidance Technology

Author

Chunyong Feng, Haihang Li, Liang Xiaoge, Li Sen, Hengjie Qin, and Long Shi

Subjects
fire condition, Computer science, Acoustics, 010401 analytical chemistry, Ultrasonic obstacle avoidance technology, 020101 civil engineering, Baffle, 02 engineering and technology, lcsh:Chemical technology, 01 natural sciences, Biochemistry, Atomic and Molecular Physics, and Optics, Article, 0201 civil engineering, 0104 chemical sciences, Analytical Chemistry, Obstacle, Obstacle avoidance, Ultrasonic sensor, lcsh:TP1-1185, Electrical and Electronic Engineering, baffle calibration method, Instrumentation, guided vehicle
Abstract

Low visibility and hot smoke environment under fire conditions can largely hamper the related fire rescue processes. Ultrasound obstacle avoidance technology is then useful for guidance. However, the biggest challenge of adopting ultrasound technology comes from accurate distance measurements under the disturbances of high temperature and soot particle concentration. It is critical to measure the propagation speed under the complicated fire conditions. Therefore, in this study, a baffle calibration method was proposed to improve the accuracy of distance measurement of an obstacle. The method is based on two ultrasound measurement systems, while one is used to calibrate the propagation speed of ultrasound based on the fixed distanced baffle and the other is for the dynamic measurement of obstacle distance based on the calibrated speed. The viability of this method on the guided vehicle was confirmed based on the experiments. From its comparison to those existing methods, such as constant speed and temperature compensation methods, it was known from that the proposed baffle calibration method provides the best prediction. It was obtained that the maximum errors based on the baffle calibration method are 2.75% and 2.62% under the two representative fire scenarios, respectively, which are much lower than those of constant speed (7.81% and 8.4%) and temperature compensation methods (10.4% and 5.12%).

Published
2018

35. Thermo-mechanical Numerical Modelling of Structural Glass under Fire - Preliminary Considerations and Comparisons

Author

Bedon, Chiara, Louter, P.C., Louter, Christian, Bos, Freek, Belis, Jan, Veer, Fred, Nijsse, Rob, Louter, Bos, Belis, Veer, Nijsse (Eds.), Bedon, Chiara, and Louter, Christian

Subjects
Structural Glass, Thermo-Mechanical Performance, Finite Element (FE) Numerical Modelling, Fire Conditions, Sensitivity Study, Experiments, TP785-869, Clay industries. Ceramics. Glass, Structural Gla, Fire Condition
Abstract

In this paper, careful consideration is paid for structural glass elements under fire loading. In particular, a thermo-mechanical Finite Element (FE) numerical investigation is carried out in ABAQUS on small-scale structural glass elements exposed to fire. Taking advantage of past literature efforts, major thermal effects on the material properties are taken into account in the form of key input parameters for numerical simulations. Further validation of the so calibrated FE models is then carried out towards past small-scale experimental fire tests on monolithic glass panels. A sensitivity FE study is hence proposed, giving evidence of major influencing parameters on the thermo-mechanical performance of the same structural glass elements, including variations in the fire exposure, thermal-to-mechanical loading ratio, geometrical and mechanical features of the specimens., Challenging Glass Conference Proceedings, Vol. 6 (2018): Challenging Glass 6

Published
2018
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36. Performance assessment on high strength steel endplate connections after fire

Author

Qiang, X. (author), Wu, N. (author), Jiang, X. (author), Bijlaard, F.S.K. (author), Kolstein, M.H. (author), Qiang, X. (author), Wu, N. (author), Jiang, X. (author), Bijlaard, F.S.K. (author), and Kolstein, M.H. (author)

Abstract

Purpose – This study aims to reveal more information and understanding on performance and failure mechanisms of high strength steel endplate connections after fire. Design/methodology/approach – An experimental and numerical study on seven endplate connections after cooling down from fire temperature of 550°C has been carried out and reported herein. Moreover, the provisions of European design standard for steel structures, Eurocode 3, were validated with test results of high strength steel endplate connections. Findings – In endplate connections, a proper design using a thinner high strength steel endplate can achieve the same failure mode, similar residual load bearing capacity and comparable or even higher rotation capacity after cooling down from fire. It is found that high strength steel endplate connection can regain more than 90 per cent of its original load bearing capacity after cooling down from fire temperature of 550°C. Originality/value – The post-fire performance of high strength steel endplate connection has been reported. The accuracy of Eurocode 3 for endplate connections is validated against test results. Keywords Numerical study, Experimental study, High strength steel, After fire, Endplate connection, Steel & Composite Structures

Published
2017
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37. Shear design curves of unstiffened plate girder web panels at high temperatures.

Author

Pourmoosavi, Gh, Ghasemi, S.A. Mousavi, B. Farahmand Azar, and Talatahari, S.

Subjects
*PLATE girders, *HIGH temperatures, *FAILURE mode & effects analysis, *ULTIMATE strength, *CURVES, *SHEAR strength, *ANALYTICAL solutions, *FREE convection
Abstract

Owing to the lack of an analytical research on the evaluation of mode change of web panels in addition to the need for shear design curves of unstiffened plate girder web panels exposed to shear buckling especially at elevated temperatures, the present article considers the mentioned topics. To this end, the web panel shear design relationships mentioned in AISC360-16 are modified to be used in fire conditions. This is achieved by direct utilization of steel stress-strain reduction factors in EN1993-1-2 at elevated temperatures. Analytical equations and design curves are developed to estimate the ultimate shear strength, failure mode and critical limiting temperature for the web panels under the action of a specific shear load. The results based on the curves are compared to the findings of current paper numerical analysis, existing experimental and numerical studies, indicating a good agreement between the results. • The shear behavior of unstiffened web panels (UWPs) subjected to shear buckling at elevated temperatures was investigated. • Design curves have been developed to predict the shear strength and failure mode of UWPs at a constant temperature. • Design curves have been proposed to determine the critical limiting temperature of UWPs subjected to constant shear load. [ABSTRACT FROM AUTHOR]

Published
2020
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40. Structural behavior of right-angle two-planar tubular TT-joints subjected to axial loadings at fire-induced elevated temperatures.

Author

Azari-Dodaran, Neda and Ahmadi, Hamid

Subjects
*HIGH temperatures, *ULTIMATE strength, *PARAMETRIC equations, *NONLINEAR regression, *COMPRESSION loads, *JOINTS (Engineering), *AXIAL loads
Abstract

This paper aims to investigate the structural behavior of two-planar tubular TT-joints subjected to axial loading at fire induced elevated temperatures. A total number of 270 FE analyses were performed to investigate the effect of temperatures and dimensionless geometrical parameters (β , γ , and τ) parameters on the ultimate strength and initial stiffness. The joints were analyzed under axially compressive and tensile loads at five different temperatures (20 °C, 200 °C, 400 °C, 550 °C, and 700 °C). Up to now, there has not been any design equation available for determining the ultimate strength of two-planar tubular TT-joints at elevated temperature. Results of the parametric study were used to develop a set of design formulas, through nonlinear regression analyses, to calculate the ultimate strength of two-planar tubular TT-joints subjected to axial loading at elevated temperatures. • Static behavior of two-planar tubular TT-joints at fire-induced elevated temperatures was studied. • Effects of temperature and joint geometry on ultimate strength, failure modes, and initial stiffness were investigated. • Results of 270 steady-state FE analyses were used for the parametric investigation. • Parametric equations were developed to determine the ultimate strength of axially-loaded TT-joints at high temperatures. [ABSTRACT FROM AUTHOR]

Published
2019
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41. Analysis of Composite Steel-concrete Beams Exposed to Fire using OpenSees

Author

Asif Usmani, Jian Jiang, and Guo-Qiang Li

Subjects
Engineering, Concrete beams, business.industry, Mechanical Engineering, OpenSees, Stress–strain curve, Composite number, Structural engineering, Boundary condition, Composite beams, Fire Condition, Composite Beam, Mechanics of Materials, Slab, Safety, Risk, Reliability and Quality, business, Parametric Study, Beam (structure), Parametric statistics
Abstract

OpenSees is an open-source object-oriented software framework developed at UC Berekeley. The OpenSees framework has been recently extended to deal with structural behaviour under fire conditions. This paper summaries the key work done for this extension and focuses on the validation and application of the developed OpenSees to study the behaviour of composite steel-concrete beams under fire conditions. The performance of the developed OpenSees are verified by four mechanical tests and two fire tests on simply supported composite beams. A parametric study is carried out using OpenSees to study the influence of boundary condition as well as composite effect of slab on the behavior of composite beams exposed to fire. The stress and strain along the beam section is output and compared with yield stress limit at elevated temperature to explain these influences in detail. The results show that the stress distribution in the web of the steel beam is more complex due to the support effects.

Published
2015
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42. A Guided Vehicle under Fire Conditions Based on a Modified Ultrasonic Obstacle Avoidance Technology.

Author

Li, Sen, Feng, Chunyong, Liang, Xiaoge, Qin, Hengjie, Li, Haihang, and Shi, Long

Subjects
*ULTRASONIC equipment, *HIGH temperature (Weather), *CALIBRATION, *FIRE, *PREDICTION models
Abstract

Low visibility and hot smoke environment under fire conditions can largely hamper the related fire rescue processes. Ultrasound obstacle avoidance technology is then useful for guidance. However, the biggest challenge of adopting ultrasound technology comes from accurate distance measurements under the disturbances of high temperature and soot particle concentration. It is critical to measure the propagation speed under the complicated fire conditions. Therefore, in this study, a baffle calibration method was proposed to improve the accuracy of distance measurement of an obstacle. The method is based on two ultrasound measurement systems, while one is used to calibrate the propagation speed of ultrasound based on the fixed distanced baffle and the other is for the dynamic measurement of obstacle distance based on the calibrated speed. The viability of this method on the guided vehicle was confirmed based on the experiments. From its comparison to those existing methods, such as constant speed and temperature compensation methods, it was known from that the proposed baffle calibration method provides the best prediction. It was obtained that the maximum errors based on the baffle calibration method are 2.75% and 2.62% under the two representative fire scenarios, respectively, which are much lower than those of constant speed (7.81% and 8.4%) and temperature compensation methods (10.4% and 5.12%). [ABSTRACT FROM AUTHOR]

Published
2018
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43. An embedded FE model for modelling reinforced concrete slabs in fire

Author

Zhaohui Huang and Xinmeng Yu

Subjects
Engineering, Embedded FEM, Computer simulation, business.industry, Structural engineering, Finite element method, Cracking, Discontinuity (geotechnical engineering), Layered slab FE model, Deflection (engineering), Numerical modelling, Reinforced concrete slab, Slab, Weak discontinuity, Fire condition, Tensile failure, business, Failure mode and effects analysis, Civil and Structural Engineering, Extended finite element method
Abstract

This is the post-print version of the final paper published in Engineering Structures. The published article is available from the link below. Changes resulting from the publishing process, such as peer review, editing, corrections, structural formatting, and other quality control mechanisms may not be reflected in this document. Changes may have been made to this work since it was submitted for publication. Copyright @ 2008 Elsevier B.V. It is evident from a series of tests on simply supported reinforced concrete slabs that the failure of the slabs at large deflections is due to the formation of individual large cracks. This failure mode was also observed in the Cardington full-scale fire tests. Previous research indicates that the global behaviour of concrete slabs subject to large deflections can be well predicted by the smeared cracking model; however, the model cannot quantitatively predict the openings of individual cracks within the slabs at large deflections. For the discrete approach it is usually assumed that the cracks are formed along element edges, therefore continuous re-meshing is required during the analysis. Consequently, the results are mesh-dependent and the computing cost is high. In recent years, mesh independent finite element procedures, such as embedded (EFEM) and extended (XFEM) approaches, were widely used for modelling of the crack initiation and growth in structural members. However, most of the meshless models developed are either based on in-plane loading conditions or confined to thin shells with assumed full-depth cracks, which form apparent displacement jumps within an element. For a reinforced concrete slab, an out-of-plane load causes coupled stretching and bending of the slab, cracks are usually initiated at discrete positions and then propagated, until at last some individual full-depth cracks are formed. Pure stretching or assumed full-depth cracking is inadequate for modelling this kind of failure. Therefore, in this research, a non-linear layered procedure with embedded weak discontinuity is developed to quantitatively model the progressive tensile failure of reinforced concrete slabs subjected to large deflections. The current model inherits the advantage of the smeared approach, and at the same time, introduces the opening width of crack explicitly by taking the advantage of the better description of the kinematic characteristics of the EFEM approach. A series of validations have been conducted against test data at both ambient and elevated temperatures, and the research shows that the model developed in this paper is not sensitive to the FE mesh size and the aspect ratio of the slab. The results predicted by the model developed agreed well with the test data in terms of deflection and crack open width, also agreeing well with those modelled by the smeared model. Hence, this new approach provides a numerical method to predict the load capacity as well as identifying the occurrence and severity of crack failure in reinforced concrete slabs subjected to extreme loading conditions, such as fire.

Published
2008

47. Effect of discrete glass fibers on the behavior of R.C. Beams exposed to fire

Author

Sherif F.M. Abd Elnaby, Magdy Youssef Riad, Ata El-kareim Shoeib, and M.M. Genidi

Subjects
Materials science, business.industry, Normal strength concrete, Glass fiber, 0211 other engineering and technologies, Residual stiffness, 020101 civil engineering, 02 engineering and technology, Structural engineering, Reinforced concrete, lcsh:TH1-9745, 0201 civil engineering, Compressive strength, RC beam ductility and deformability, lcsh:TA1-2040, Deflection (engineering), 021105 building & construction, Ultimate tensile strength, Fire condition, Composite material, lcsh:Engineering (General). Civil engineering (General), business, Discrete glass fibers, lcsh:Building construction, High strength concrete
Abstract

The main objective of this paper is to investigate the effect of adding discrete glass fibers on the behavior of reinforced concrete (RC) beams under different fire and cooling conditions. Eighteen beams with different concrete compressive strengths were tested to study the behavior of reinforced concrete (RC) beams containing discrete glass fibers when exposed to different fire and cooling conditions. Nine beams were prepared from normal strength concrete (NSC) with compressive strength equal to 35 MPa while the other beams were prepared from high strength concrete (HSC) with compressive strength equal to 60 MPa. The beams contained different contents of discrete glass fibers. The modes of failure of tested specimens show that the crack patterns change according to fire condition and fiber content. Analysis of test results show that adding discrete glass fibers to NSC increased the residual stiffness of the tested specimens after firing and decreased the rate of the deflection gain during firing. Also adding fibers to concrete has a limited positive effect on the ultimate strength of the specimens compared to the control specimens. Its effect on deflection due to fire is more pronounced. Finally, the recommended optimum ratio of discrete glass fibers is not more than 0.5% of the total concrete weight.

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