Numerical investigation of concrete filled hollow precast composite columns subjected to lateral cyclic loading

•Investigation of monolithic and composite columns under cyclic loads was performed.•Concrete models were investigated to simulate RC structures under cyclic loadings.•Contact algorithm used to model composite columns under cyclic loading was verified.•The FE model can capture responses of the compo...

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Published inEngineering structures Vol. 252; p. 113586
Main Authors Paudel, Satish, Tanapornraweekit, Ganchai, Tangtermsirikul, Somnuk
Format Journal Article
LanguageEnglish
Published Kidlington Elsevier Ltd 01.02.2022
Elsevier BV
Subjects
Algorithms
Composite columns
Composite materials
Composite structures
Concrete
Concrete material model
Cyclic loading
Cyclic loads
Damage
Ductility
Failure modes
Finite element method
Infilled concrete
Interfacial shear strength
Interfacial shear stresses
Mathematical models
Precast concrete
Precast concrete encasement
Reinforced concrete
Shear strength
Shear stress
Stress transfer
Thickness
Ultimate loads
Cyclic loading
Ductility
Infilled concrete
Concrete material model
Composite columns
Precast concrete encasement
Online AccessGet full text
ISSN0141-0296
1873-7323
DOI10.1016/j.engstruct.2021.113586

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Abstract •Investigation of monolithic and composite columns under cyclic loads was performed.•Concrete models were investigated to simulate RC structures under cyclic loadings.•Contact algorithm used to model composite columns under cyclic loading was verified.•The FE model can capture responses of the composite columns under cyclic loadings.•Influence of thickness and strength of precast plate and rebar details was studied.•Methods to enhance ductility of composite columns under cyclic loads are provided. This paper describes a numerical study performed to investigate the behaviour of concrete infilled hollow precast composite columns (HPCC) subjected to lateral cyclic loading. Finite element analysis of monolithic (RC) and composite (HPCC1 and HPCC2) columns are performed and the results thus obtained are compared with documented experimental results. The present study focuses on the capability of numerical codes to capture the behaviour of the columns, such as load–displacement relationship, softening and failure modes under cyclic loading. To capture the performance of tested composite columns, a study was first performed to select a suitable material model that can further be considered appropriate to depict the cyclic performance of reinforced concrete (RC) structures. Moreover, the investigation was performed to model two concrete surfaces (precast and cast-in-situ) in contact through a contact algorithm for a precast encased composite column. Finally, a study on interface shear stress transfer mechanism and effects of confinement provided by the encasement to the inner core was performed for HPCC1 and HPCC2 composite columns. After performing numerical study and comparing with the obtained test results, a continuous surface cap material model (MAT 159) available in LS-DYNA FE code was observed to be suitable to model concrete for analyzing the behavior of RC structures subjected to lateral cyclic loading. Moreover, to simulate the behaviour of composite structures, the use of a tiebreak contact algorithm is suggested. It was observed that due to the presence of cross-ties penetrating into the inner core of HPCC1, the composite action between the inner core and outer precast encasement was enhanced, with delayed damage in the outer encasement. However, in composite column HPCC2, the ties did not penetrate into the inner column core, so interface shear strength, resulted only from cohesion and friction, caused severe damage in the outer encasement at ultimate load. The presence of a single tie and smaller thickness of precast encasement in HPCC1 resulted in lower displacement ductility of HPCC1 compared to composite column HPCC2. Moreover, parametric studies were performed to elucidate the influence of the thickness of the precast plate and reinforcement arrangement to enhance the ductility of the composite columns through a series of numerical analyses of the modified columns.
AbstractList •Investigation of monolithic and composite columns under cyclic loads was performed.•Concrete models were investigated to simulate RC structures under cyclic loadings.•Contact algorithm used to model composite columns under cyclic loading was verified.•The FE model can capture responses of the composite columns under cyclic loadings.•Influence of thickness and strength of precast plate and rebar details was studied.•Methods to enhance ductility of composite columns under cyclic loads are provided. This paper describes a numerical study performed to investigate the behaviour of concrete infilled hollow precast composite columns (HPCC) subjected to lateral cyclic loading. Finite element analysis of monolithic (RC) and composite (HPCC1 and HPCC2) columns are performed and the results thus obtained are compared with documented experimental results. The present study focuses on the capability of numerical codes to capture the behaviour of the columns, such as load–displacement relationship, softening and failure modes under cyclic loading. To capture the performance of tested composite columns, a study was first performed to select a suitable material model that can further be considered appropriate to depict the cyclic performance of reinforced concrete (RC) structures. Moreover, the investigation was performed to model two concrete surfaces (precast and cast-in-situ) in contact through a contact algorithm for a precast encased composite column. Finally, a study on interface shear stress transfer mechanism and effects of confinement provided by the encasement to the inner core was performed for HPCC1 and HPCC2 composite columns. After performing numerical study and comparing with the obtained test results, a continuous surface cap material model (MAT 159) available in LS-DYNA FE code was observed to be suitable to model concrete for analyzing the behavior of RC structures subjected to lateral cyclic loading. Moreover, to simulate the behaviour of composite structures, the use of a tiebreak contact algorithm is suggested. It was observed that due to the presence of cross-ties penetrating into the inner core of HPCC1, the composite action between the inner core and outer precast encasement was enhanced, with delayed damage in the outer encasement. However, in composite column HPCC2, the ties did not penetrate into the inner column core, so interface shear strength, resulted only from cohesion and friction, caused severe damage in the outer encasement at ultimate load. The presence of a single tie and smaller thickness of precast encasement in HPCC1 resulted in lower displacement ductility of HPCC1 compared to composite column HPCC2. Moreover, parametric studies were performed to elucidate the influence of the thickness of the precast plate and reinforcement arrangement to enhance the ductility of the composite columns through a series of numerical analyses of the modified columns.
This paper describes a numerical study performed to investigate the behaviour of concrete infilled hollow precast composite columns (HPCC) subjected to lateral cyclic loading. Finite element analysis of monolithic (RC) and composite (HPCC1 and HPCC2) columns are performed and the results thus obtained are compared with documented experimental results. The present study focuses on the capability of numerical codes to capture the behaviour of the columns, such as load–displacement relationship, softening and failure modes under cyclic loading. To capture the performance of tested composite columns, a study was first performed to select a suitable material model that can further be considered appropriate to depict the cyclic performance of reinforced concrete (RC) structures. Moreover, the investigation was performed to model two concrete surfaces (precast and cast-in-situ) in contact through a contact algorithm for a precast encased composite column. Finally, a study on interface shear stress transfer mechanism and effects of confinement provided by the encasement to the inner core was performed for HPCC1 and HPCC2 composite columns. After performing numerical study and comparing with the obtained test results, a continuous surface cap material model (MAT 159) available in LS-DYNA FE code was observed to be suitable to model concrete for analyzing the behavior of RC structures subjected to lateral cyclic loading. Moreover, to simulate the behaviour of composite structures, the use of a tiebreak contact algorithm is suggested. It was observed that due to the presence of cross-ties penetrating into the inner core of HPCC1, the composite action between the inner core and outer precast encasement was enhanced, with delayed damage in the outer encasement. However, in composite column HPCC2, the ties did not penetrate into the inner column core, so interface shear strength, resulted only from cohesion and friction, caused severe damage in the outer encasement at ultimate load. The presence of a single tie and smaller thickness of precast encasement in HPCC1 resulted in lower displacement ductility of HPCC1 compared to composite column HPCC2. Moreover, parametric studies were performed to elucidate the influence of the thickness of the precast plate and reinforcement arrangement to enhance the ductility of the composite columns through a series of numerical analyses of the modified columns.
ArticleNumber 113586
Author Tangtermsirikul, Somnuk
Paudel, Satish
Tanapornraweekit, Ganchai
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Keywords Cyclic loading
Ductility
Infilled concrete
Concrete material model
Composite columns
Precast concrete encasement
Language English
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  ident: 10.1016/j.engstruct.2021.113586_b0260
  article-title: Interface Shear Transfer on Composite Concrete Members
  publication-title: ACI Struct J
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Snippet •Investigation of monolithic and composite columns under cyclic loads was performed.•Concrete models were investigated to simulate RC structures under cyclic...
This paper describes a numerical study performed to investigate the behaviour of concrete infilled hollow precast composite columns (HPCC) subjected to lateral...
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StartPage 113586
SubjectTerms Algorithms
Composite columns
Composite materials
Composite structures
Concrete
Concrete material model
Cyclic loading
Cyclic loads
Damage
Ductility
Failure modes
Finite element method
Infilled concrete
Interfacial shear strength
Interfacial shear stresses
Mathematical models
Precast concrete
Precast concrete encasement
Reinforced concrete
Shear strength
Shear stress
Stress transfer
Thickness
Ultimate loads
Title Numerical investigation of concrete filled hollow precast composite columns subjected to lateral cyclic loading
URI https://dx.doi.org/10.1016/j.engstruct.2021.113586
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