Behavior of high strength concrete encased steel composite stub columns with C130 concrete and S690 steel

Behavior of high strength concrete encased steel composite stub columns with C130 concrete and S690 steel

•Structural test is conducted on 14 high strength Concrete Encased Steel (CES) composite short columns.•The axial compression capacity of high strength CES columns is evaluated and compared with various design codes.•A concrete strength reduction factor is proposed to account for the brittleness of...

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Veröffentlicht in:Engineering structures 2019-12, Vol.200, p.109743, Article 109743
Hauptverfasser: Lai, Binglin, Liew, J.Y. Richard, Hoang, An Le
Format: Artikel
Sprache:eng
Schlagworte:
Axial bearing capacity
Bearing strength
Carrying capacity
Composite columns
Composite materials
Compression
Compressive strength
Concrete
Damage patterns
Ductility
Ductility tests
High strength concrete
High strength concretes
High strength steel
High strength steels
High-rise
Load carrying capacity
Peak load
Post-peak ductility
Reinforcement
Steel
Steel fiber
Steel fibers
Structural steels
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Hoang, An Le
description •Structural test is conducted on 14 high strength Concrete Encased Steel (CES) composite short columns.•The axial compression capacity of high strength CES columns is evaluated and compared with various design codes.•A concrete strength reduction factor is proposed to account for the brittleness of high strength concrete.•Parametric studies are carried out to determine the critical parameters affecting strength and ductility of CES columns.•An empirical equation is proposed to assess the ductility of high strength CES columns. This paper presents an experimental program that studies the structural behaviour of high strength Concrete Encased Steel (CES) composite columns. The structural performance under compression, including the damage pattern, load-carrying capacity, post-peak ductility, and load-displacement response is experimentally investigated. A total of 14 specimens were tested under concentric compression. The parameters studied in this program include concrete compressive strength, steel yield strength, stirrup spacing, incorporation of steel fiber, as well as the shape of the structural steel section. To evaluate the material compatibility between high strength concrete and high strength steel, two concrete grades (C90, C130) and two steel grades (S500, S690) were used to prepare the test specimens. In addition, 0.5% volume fraction of steel fiber was added in concrete mix to minimize the inherent brittleness of high strength concrete. The comparison between test results and analytical predictions reveals the inability of existing design codes to estimate high strength CES columns, unless steel fiber and dense reinforcement are used in combination. The effect of material strength, steel fibers, volumetric ratios of hoop reinforcement, and shape of steel section on both strength and ductility of CES columns was assessed through a comprehensive parametric study. The analysis of test results demonstrates that steel contribution ratio plays a dominant role in the ductility, whereas increasing hoop reinforcement ratio and adding steel fiber has negligible effect. Finally, a simplified formula is proposed to evaluate ductility of high strength CES columns.
doi_str_mv 10.1016/j.engstruct.2019.109743
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Richard ; Hoang, An Le</creator><creatorcontrib>Lai, Binglin ; Liew, J.Y. Richard ; Hoang, An Le</creatorcontrib><description>•Structural test is conducted on 14 high strength Concrete Encased Steel (CES) composite short columns.•The axial compression capacity of high strength CES columns is evaluated and compared with various design codes.•A concrete strength reduction factor is proposed to account for the brittleness of high strength concrete.•Parametric studies are carried out to determine the critical parameters affecting strength and ductility of CES columns.•An empirical equation is proposed to assess the ductility of high strength CES columns. This paper presents an experimental program that studies the structural behaviour of high strength Concrete Encased Steel (CES) composite columns. The structural performance under compression, including the damage pattern, load-carrying capacity, post-peak ductility, and load-displacement response is experimentally investigated. A total of 14 specimens were tested under concentric compression. The parameters studied in this program include concrete compressive strength, steel yield strength, stirrup spacing, incorporation of steel fiber, as well as the shape of the structural steel section. To evaluate the material compatibility between high strength concrete and high strength steel, two concrete grades (C90, C130) and two steel grades (S500, S690) were used to prepare the test specimens. In addition, 0.5% volume fraction of steel fiber was added in concrete mix to minimize the inherent brittleness of high strength concrete. The comparison between test results and analytical predictions reveals the inability of existing design codes to estimate high strength CES columns, unless steel fiber and dense reinforcement are used in combination. The effect of material strength, steel fibers, volumetric ratios of hoop reinforcement, and shape of steel section on both strength and ductility of CES columns was assessed through a comprehensive parametric study. The analysis of test results demonstrates that steel contribution ratio plays a dominant role in the ductility, whereas increasing hoop reinforcement ratio and adding steel fiber has negligible effect. 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Richard</creatorcontrib><creatorcontrib>Hoang, An Le</creatorcontrib><title>Behavior of high strength concrete encased steel composite stub columns with C130 concrete and S690 steel</title><title>Engineering structures</title><description>•Structural test is conducted on 14 high strength Concrete Encased Steel (CES) composite short columns.•The axial compression capacity of high strength CES columns is evaluated and compared with various design codes.•A concrete strength reduction factor is proposed to account for the brittleness of high strength concrete.•Parametric studies are carried out to determine the critical parameters affecting strength and ductility of CES columns.•An empirical equation is proposed to assess the ductility of high strength CES columns. This paper presents an experimental program that studies the structural behaviour of high strength Concrete Encased Steel (CES) composite columns. The structural performance under compression, including the damage pattern, load-carrying capacity, post-peak ductility, and load-displacement response is experimentally investigated. A total of 14 specimens were tested under concentric compression. The parameters studied in this program include concrete compressive strength, steel yield strength, stirrup spacing, incorporation of steel fiber, as well as the shape of the structural steel section. To evaluate the material compatibility between high strength concrete and high strength steel, two concrete grades (C90, C130) and two steel grades (S500, S690) were used to prepare the test specimens. In addition, 0.5% volume fraction of steel fiber was added in concrete mix to minimize the inherent brittleness of high strength concrete. 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Richard</creatorcontrib><creatorcontrib>Hoang, An Le</creatorcontrib><collection>CrossRef</collection><collection>Engineered Materials Abstracts</collection><collection>Environment Abstracts</collection><collection>METADEX</collection><collection>Technology Research Database</collection><collection>Environmental Sciences and Pollution Management</collection><collection>Engineering Research Database</collection><collection>Materials Research Database</collection><collection>Civil Engineering Abstracts</collection><collection>Environment Abstracts</collection><jtitle>Engineering structures</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Lai, Binglin</au><au>Liew, J.Y. Richard</au><au>Hoang, An Le</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Behavior of high strength concrete encased steel composite stub columns with C130 concrete and S690 steel</atitle><jtitle>Engineering structures</jtitle><date>2019-12-01</date><risdate>2019</risdate><volume>200</volume><spage>109743</spage><pages>109743-</pages><artnum>109743</artnum><issn>0141-0296</issn><eissn>1873-7323</eissn><abstract>•Structural test is conducted on 14 high strength Concrete Encased Steel (CES) composite short columns.•The axial compression capacity of high strength CES columns is evaluated and compared with various design codes.•A concrete strength reduction factor is proposed to account for the brittleness of high strength concrete.•Parametric studies are carried out to determine the critical parameters affecting strength and ductility of CES columns.•An empirical equation is proposed to assess the ductility of high strength CES columns. This paper presents an experimental program that studies the structural behaviour of high strength Concrete Encased Steel (CES) composite columns. The structural performance under compression, including the damage pattern, load-carrying capacity, post-peak ductility, and load-displacement response is experimentally investigated. A total of 14 specimens were tested under concentric compression. The parameters studied in this program include concrete compressive strength, steel yield strength, stirrup spacing, incorporation of steel fiber, as well as the shape of the structural steel section. To evaluate the material compatibility between high strength concrete and high strength steel, two concrete grades (C90, C130) and two steel grades (S500, S690) were used to prepare the test specimens. In addition, 0.5% volume fraction of steel fiber was added in concrete mix to minimize the inherent brittleness of high strength concrete. The comparison between test results and analytical predictions reveals the inability of existing design codes to estimate high strength CES columns, unless steel fiber and dense reinforcement are used in combination. The effect of material strength, steel fibers, volumetric ratios of hoop reinforcement, and shape of steel section on both strength and ductility of CES columns was assessed through a comprehensive parametric study. The analysis of test results demonstrates that steel contribution ratio plays a dominant role in the ductility, whereas increasing hoop reinforcement ratio and adding steel fiber has negligible effect. Finally, a simplified formula is proposed to evaluate ductility of high strength CES columns.</abstract><cop>Kidlington</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.engstruct.2019.109743</doi></addata></record>
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source ScienceDirect Journals (5 years ago - present)
subjects Axial bearing capacity
Bearing strength
Carrying capacity
Composite columns
Composite materials
Compression
Compressive strength
Concrete
Damage patterns
Ductility
Ductility tests
High strength concrete
High strength concretes
High strength steel
High strength steels
High-rise
Load carrying capacity
Peak load
Post-peak ductility
Reinforcement
Steel
Steel fiber
Steel fibers
Structural steels
title Behavior of high strength concrete encased steel composite stub columns with C130 concrete and S690 steel
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