Effect of Transient Creep Strain Model on the Behavior of Concrete Columns Subjected to Heating and Cooling

Gernay, Thomas

doi:10.1007/s10694-011-0222-0

Cited by 48 publications

(34 citation statements)

References 9 publications

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“…Although this assumption has proved to yield quite accurate results in structures heated by a standard time-temperature curve, its validity for representing the behaviour of concrete during a cooling phase may be questioned because transient creep is, in nature, not reversible. Recent numerical simulations have been made by the authors on the same columns as the one presented in this paper, now with an explicit transient creep constitutive model [15,16]; it appeared that the occurrence of collapse during or after the cooling phase is predicted even more often with an explicit creep model than with the implicit model of Eurocode 2 that has been used for the results presented in this paper.…”

Section: Discussionmentioning

confidence: 99%

Collapse of concrete columns during and after the cooling phase of a fire

Dimia¹,

Guenfoud²,

Gernay³

et al. 2011

Journal of Fire Protection Engineering

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This paper presents a study performed on the collapse of reinforced concrete columns subjected to natural fire conditions during and after the cooling phase of the fire. The aim is, first, to highlight the phenomenon of collapse of concrete columns during and after the cooling phase of a fire and then, to analyze the influence of some determinant parameters. The main mechanisms that lead to this type of failure are found to be the delayed increase of the temperature in the central zones of the element and the additional loss of concrete strength during the cooling phase of the fire. A parametric study is performed considering different fires and geometric properties of the column. This shows that the most critical situations with respect to delayed failure arise for short fires and for columns with low slenderness or massive sections.

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Section: Discussionmentioning

confidence: 99%

Collapse of concrete columns during and after the cooling phase of a fire

Dimia¹,

Guenfoud²,

Gernay³

et al. 2011

Journal of Fire Protection Engineering

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“…The material models given in Eurocode (EC2, 2004b) are adopted for steel and concrete at elevated temperature, including the compressive strength reduction as a function of the concrete class as plotted in Figure 1. Transient creep strain is considered explicitly in the concrete model (Gernay, 2012;Gernay and Franssen, 2012). The columns are subjected to a vertical load at the top and then to ISO fire on their four sides, the load being kept constant.…”

Section: Methodsmentioning

confidence: 99%

A 2D beam element for the analysis of flexural buckling of steel structures at elevated temperatures

Tondini¹,

Morbioli²,

Battini³

2017

Applications of Fire Engineering

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High strength concrete (HSC) has become a commonly used material over the last decades, in particular in tall buildings where it allows to increase the net marketable area. As it carries loads more efficiently than normal strength concrete (NSC), it is also specified where architectural considerations call for small support elements. The reduction in member size that can be obtained with HSC results in an increase in usable area. Alternatively, for a fixed column size, longer spans can be supported which leads to a reduced number of supports. HSC also provides advantages in terms of durability. These advantages have resulted in the increased use of HSC observed lately in various applications of civil engineering.An important requirement for building structures is the performance under fire situations. Previous research has shown that HSC behaves differently than NSC at elevated temperature (Phan and Carino, 1998). The most notable differences regard the relative loss of compressive strength with temperature and the occurrence of spalling. For these two aspects, the performance of HSC is lower than that of NSC, i.e. HSC experiences higher rates of strength loss with temperature and a higher susceptibility to spalling. In addition, HSC is often used to reduce the size of structural members. However, this reduction may be detrimental to the fire performance as it leads to faster temperature increase in the section core of the members, and inEffect of upgrading concrete strength class on fire performance of reinforced concrete columns ABSTRACT: High strength concrete (HSC) provides several advantages over normal strength concrete (NSC) and is being used in multi-story buildings for reducing the dimensions of the columns sections and increasing the net marketable area. However, upgrading of concrete strength class in a building may affect the fire performance, due to higher rates of strength loss with temperature and higher susceptibility to spalling of HSC compared with NSC. Reduction of columns sections also leads to increased member slenderness and faster temperature increase in the section core. These detrimental effects are well known, but their impact on fire performance of structures has not been established in terms of comparative advantage between NSC and HSC. In other words, it is not clear whether the consideration of fire resistance limits the opportunities for use of HSC for reducing the dimensions of columns sections in multi-story buildings. This research aims to address this question by comparing the fire behaviour of reinforced concrete columns made of NSC and HSC using nonlinear finite element modelling. The evolution of load bearing capacity of the columns is established as a function of the fire exposure duration. A 15-story car park structure is adopted as a case study with alternative designs for the columns based on strength classes ranging from C30 to C90. Results show that, although the replacement of NSC by HSC accelerates the reduction rate of columns capacity under fire, the columns genera...

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“…The material models given in Eurocode [4] are adopted for steel and concrete at elevated temperature. Yet in the concrete model, the transient creep strain is considered explicitly as this has proven to provide more accurate results [6][7][8]. The columns are subjected to a vertical load at the top and then to ISO fire on their four sides.…”

Section: Methodsmentioning

confidence: 99%

Fire Performance of Columns Made of Normal and High Strength Concrete: A Comparative Analysis

Gernay

2016

KEM

Self Cite

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Abstract. The use of high strength concrete (HSC) in multi-story buildings has become increasingly popular. Selection of HSC over normal strength concrete (NSC) allows for reducing the dimensions of the columns sections. However, this reduction has consequences on the structural performance in case of fire, as smaller cross sections lead to faster temperature increase in the section core. Besides, HSC experiences higher rates of strength loss with temperature and a higher susceptibility to spalling than NSC. The fire performance of a column can thus be affected by selecting HSC over NSC. This research performs a comparison of the fire performance of HSC and NSC columns, based on numerical simulations by finite element method. The thermal and structural analyses of the columns are conducted with the software SAFIR ® . The variation of concrete strength with temperature for the different concrete classes is adopted from Eurocode. Different configurations are compared, including columns with the same load bearing capacity and columns with the same cross section. The relative loss of load bearing capacity during the fire is found to be more pronounced for HSC columns than for NSC columns. The impact on fire resistance rating is discussed. These results suggest that consideration of fire loading limits the opportunities for use of HSC, especially when the objective is to reduce the dimensions of the columns sections.

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Effect of Transient Creep Strain Model on the Behavior of Concrete Columns Subjected to Heating and Cooling

Cited by 48 publications

References 9 publications

Collapse of concrete columns during and after the cooling phase of a fire

Collapse of concrete columns during and after the cooling phase of a fire

A 2D beam element for the analysis of flexural buckling of steel structures at elevated temperatures

Fire Performance of Columns Made of Normal and High Strength Concrete: A Comparative Analysis

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