Experimental and numerical investigations of laced built-up lightweight concrete encased columns subjected to cyclic axial load

Nagarajan Divyah; Ramaiah Prakash; Sundaresan Srividhya; Siva Avudaiappan; Pablo Guindos; Nelson Maureira Carsalade; Krishna Prakash Arunachalam; Ehsan Noroozinejad Farsangi; Ángel Roco-Videla

Experimental and numerical investigations of laced built-up lightweight concrete encased columns subjected to cyclic axial load

Nagarajan Divyah, Ramaiah Prakash, Sundaresan Srividhya, Siva Avudaiappan, Pablo Guindos, Nelson Maureira Carsalade, Krishna Prakash Arunachalam, Ehsan Noroozinejad Farsangi, Ángel Roco-Videla

Western Sydney University

Research output: Contribution to journal › Article › peer-review

Abstract

The steel-concrete composite column comprises a steel core and surrounding concrete. The purpose of the system is to provide analysis and design techniques for a newly invented class of laced steel-concrete composite short columns for cyclic axial loads. To minimize the increasing density issues associated with nominal strength concrete and in consideration of the depletion of natural resources required to produce concrete, factory-obtained lightweight sintered fly ash aggregates with and without basalt fiber are employed. The normal-weight concrete containing basalt fiber is shown to be more ductile than any other column. The axial deformation of columns LNA and LSA at failure was found to be 3.5 mm, whereas columns LNAF and LSAF reached an axial shortening of 4.5 mm at failure. The column LSAF was found to have 5.3% more energy absorption than the LSA and 11.5% less than the column LNAF. It was observed that the rigidity of these fabricated components had been enhanced. It was found that the section configuration with a lacing system had improved confinement effects and ductility. Comparing the finite element analysis to the experimental data revealed a strong connection with numerical modeling, with a variance of around 8.77%.

Original language	English
Article number	1444
Number of pages	16
Journal	Buildings
Volume	13
Issue number	6
Publication status	Published - Jun 2023

Bibliographical note

Publisher Copyright:
© 2023 by the authors.

Open Access - Access Right Statement

© 2023 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).

Cite this

@article{ef6b8d485c0743cba53cfad8eb60409a,

title = "Experimental and numerical investigations of laced built-up lightweight concrete encased columns subjected to cyclic axial load",

abstract = "The steel-concrete composite column comprises a steel core and surrounding concrete. The purpose of the system is to provide analysis and design techniques for a newly invented class of laced steel-concrete composite short columns for cyclic axial loads. To minimize the increasing density issues associated with nominal strength concrete and in consideration of the depletion of natural resources required to produce concrete, factory-obtained lightweight sintered fly ash aggregates with and without basalt fiber are employed. The normal-weight concrete containing basalt fiber is shown to be more ductile than any other column. The axial deformation of columns LNA and LSA at failure was found to be 3.5 mm, whereas columns LNAF and LSAF reached an axial shortening of 4.5 mm at failure. The column LSAF was found to have 5.3% more energy absorption than the LSA and 11.5% less than the column LNAF. It was observed that the rigidity of these fabricated components had been enhanced. It was found that the section configuration with a lacing system had improved confinement effects and ductility. Comparing the finite element analysis to the experimental data revealed a strong connection with numerical modeling, with a variance of around 8.77%.",

author = "Nagarajan Divyah and Ramaiah Prakash and Sundaresan Srividhya and Siva Avudaiappan and Pablo Guindos and Carsalade, {Nelson Maureira} and Arunachalam, {Krishna Prakash} and {Noroozinejad Farsangi}, Ehsan and {\'A}ngel Roco-Videla",

note = "Publisher Copyright: {\textcopyright} 2023 by the authors.",

year = "2023",

month = jun,

language = "English",

volume = "13",

journal = "Buildings",

issn = "2075-5309",

publisher = "Multidisciplinary Digital Publishing Institute (MDPI)",

number = "6",

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T1 - Experimental and numerical investigations of laced built-up lightweight concrete encased columns subjected to cyclic axial load

AU - Divyah, Nagarajan

AU - Prakash, Ramaiah

AU - Srividhya, Sundaresan

AU - Avudaiappan, Siva

AU - Guindos, Pablo

AU - Carsalade, Nelson Maureira

AU - Arunachalam, Krishna Prakash

AU - Noroozinejad Farsangi, Ehsan

AU - Roco-Videla, Ángel

PY - 2023/6

Y1 - 2023/6

N2 - The steel-concrete composite column comprises a steel core and surrounding concrete. The purpose of the system is to provide analysis and design techniques for a newly invented class of laced steel-concrete composite short columns for cyclic axial loads. To minimize the increasing density issues associated with nominal strength concrete and in consideration of the depletion of natural resources required to produce concrete, factory-obtained lightweight sintered fly ash aggregates with and without basalt fiber are employed. The normal-weight concrete containing basalt fiber is shown to be more ductile than any other column. The axial deformation of columns LNA and LSA at failure was found to be 3.5 mm, whereas columns LNAF and LSAF reached an axial shortening of 4.5 mm at failure. The column LSAF was found to have 5.3% more energy absorption than the LSA and 11.5% less than the column LNAF. It was observed that the rigidity of these fabricated components had been enhanced. It was found that the section configuration with a lacing system had improved confinement effects and ductility. Comparing the finite element analysis to the experimental data revealed a strong connection with numerical modeling, with a variance of around 8.77%.

AB - The steel-concrete composite column comprises a steel core and surrounding concrete. The purpose of the system is to provide analysis and design techniques for a newly invented class of laced steel-concrete composite short columns for cyclic axial loads. To minimize the increasing density issues associated with nominal strength concrete and in consideration of the depletion of natural resources required to produce concrete, factory-obtained lightweight sintered fly ash aggregates with and without basalt fiber are employed. The normal-weight concrete containing basalt fiber is shown to be more ductile than any other column. The axial deformation of columns LNA and LSA at failure was found to be 3.5 mm, whereas columns LNAF and LSAF reached an axial shortening of 4.5 mm at failure. The column LSAF was found to have 5.3% more energy absorption than the LSA and 11.5% less than the column LNAF. It was observed that the rigidity of these fabricated components had been enhanced. It was found that the section configuration with a lacing system had improved confinement effects and ductility. Comparing the finite element analysis to the experimental data revealed a strong connection with numerical modeling, with a variance of around 8.77%.

UR - https://hdl.handle.net/1959.7/uws:71763

M3 - Article

SN - 2075-5309

VL - 13

JO - Buildings

JF - Buildings

IS - 6

M1 - 1444

ER -

Experimental and numerical investigations of laced built-up lightweight concrete encased columns subjected to cyclic axial load

Abstract

Bibliographical note

Open Access - Access Right Statement

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