Second-Order Effects on Wind-Induced Structural Behavior of High-Rise Steel Buildings

AbstractThis paper investigates second-order effects on wind-induced structural dynamic behavior of a 60-story high-rise steel structure known as the Commonwealth Advisory Aeronautical Research Council (CAARC) building model. These effects are considered in the structural analysis by using a geometr...

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Veröffentlicht in:	Journal of structural engineering (New York, N.Y.) N.Y.), 2018-02, Vol.144 (2)
Hauptverfasser:	Park, Sejun, Yeo, DongHun
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Sprache:	eng
Schlagworte:	Aeronautical research Aeronautics Axial forces Beams (structural) Bending moments Columns (structural) Drift High rise buildings Steel structures Stiffness Structural analysis Structural behavior Structural engineering Technical Papers Vibration analysis Wind effects
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description	AbstractThis paper investigates second-order effects on wind-induced structural dynamic behavior of a 60-story high-rise steel structure known as the Commonwealth Advisory Aeronautical Research Council (CAARC) building model. These effects are considered in the structural analysis by using a geometric stiffness method allowing the dynamic analysis to be performed without iterations. Data sets of the aerodynamic pressure on the CAARC building model for suburban exposure are used in the database-assisted design (DAD) procedure to calculate, in addition to overturning moments and shear forces at the base, members’ demand-to-capacity indexes (DCIs), interstory drift ratios, and resultant accelerations. Dynamic analyses are performed using four reference mean hourly wind speeds at the rooftop for suburban terrain exposure (Uref=20 and 40 m/s for serviceability analysis, and 60 and 80 m/s for strength analysis). The second-order effects decrease natural frequencies of vibration of the building by up to 12%. In the strength analysis with Uref=80 m/s, second-order effects increase nondirectional peak global responses by up to 15% for overturning moments, 9% for base shears, and 10% for torsional moments. The responses of 21 members selected in this study are increased by up to 19% for columns, 41% for beams, and 31% for diagonal bracings in the case of the DCIs for the interaction of axial forces and bending moments (BijPM) and by up to 67% for columns, 26% for beams, and 13% for diagonal bracings in the case of the DCIs for the shear forces (BijV). In the serviceability analysis with Uref=40 m/s, second-order effects increase the interstory drift ratios by up to 17% and the resultant accelerations at the top floor by up to 2%. This case study shows that the second-order effects can considerably affect not only drift control but also the design of members for strength.
doi_str_mv	10.1061/(ASCE)ST.1943-541X.0001943
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These effects are considered in the structural analysis by using a geometric stiffness method allowing the dynamic analysis to be performed without iterations. Data sets of the aerodynamic pressure on the CAARC building model for suburban exposure are used in the database-assisted design (DAD) procedure to calculate, in addition to overturning moments and shear forces at the base, members’ demand-to-capacity indexes (DCIs), interstory drift ratios, and resultant accelerations. Dynamic analyses are performed using four reference mean hourly wind speeds at the rooftop for suburban terrain exposure (Uref=20 and 40 m/s for serviceability analysis, and 60 and 80 m/s for strength analysis). The second-order effects decrease natural frequencies of vibration of the building by up to 12%. In the strength analysis with Uref=80 m/s, second-order effects increase nondirectional peak global responses by up to 15% for overturning moments, 9% for base shears, and 10% for torsional moments. The responses of 21 members selected in this study are increased by up to 19% for columns, 41% for beams, and 31% for diagonal bracings in the case of the DCIs for the interaction of axial forces and bending moments (BijPM) and by up to 67% for columns, 26% for beams, and 13% for diagonal bracings in the case of the DCIs for the shear forces (BijV). In the serviceability analysis with Uref=40 m/s, second-order effects increase the interstory drift ratios by up to 17% and the resultant accelerations at the top floor by up to 2%. 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These effects are considered in the structural analysis by using a geometric stiffness method allowing the dynamic analysis to be performed without iterations. Data sets of the aerodynamic pressure on the CAARC building model for suburban exposure are used in the database-assisted design (DAD) procedure to calculate, in addition to overturning moments and shear forces at the base, members’ demand-to-capacity indexes (DCIs), interstory drift ratios, and resultant accelerations. Dynamic analyses are performed using four reference mean hourly wind speeds at the rooftop for suburban terrain exposure (Uref=20 and 40 m/s for serviceability analysis, and 60 and 80 m/s for strength analysis). The second-order effects decrease natural frequencies of vibration of the building by up to 12%. In the strength analysis with Uref=80 m/s, second-order effects increase nondirectional peak global responses by up to 15% for overturning moments, 9% for base shears, and 10% for torsional moments. The responses of 21 members selected in this study are increased by up to 19% for columns, 41% for beams, and 31% for diagonal bracings in the case of the DCIs for the interaction of axial forces and bending moments (BijPM) and by up to 67% for columns, 26% for beams, and 13% for diagonal bracings in the case of the DCIs for the shear forces (BijV). In the serviceability analysis with Uref=40 m/s, second-order effects increase the interstory drift ratios by up to 17% and the resultant accelerations at the top floor by up to 2%. This case study shows that the second-order effects can considerably affect not only drift control but also the design of members for strength.</description><subject>Aeronautical research</subject><subject>Aeronautics</subject><subject>Axial forces</subject><subject>Beams (structural)</subject><subject>Bending moments</subject><subject>Columns (structural)</subject><subject>Drift</subject><subject>High rise buildings</subject><subject>Steel structures</subject><subject>Stiffness</subject><subject>Structural analysis</subject><subject>Structural behavior</subject><subject>Structural engineering</subject><subject>Technical Papers</subject><subject>Vibration analysis</subject><subject>Wind effects</subject><issn>0733-9445</issn><issn>1943-541X</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2018</creationdate><recordtype>article</recordtype><recordid>eNp1kEtLw0AUhQdRsFb_Q9CNLlLn2WTcaam2UCiYFt0N87hTIzWpM4ngvzehRdy4utxzzzkXPoQuCR4RPCa31_fFZHpTrEZEcpYKTl5HGON-OUKDX-0YDXDGWCo5F6foLMb3zpQJkg_QugBbVy5dBgchmXoPtolJXSUvZafOK9dacEnRhNY2bdDb5AHe9FdZh6T2yazcvKXPZYTOANDd2nLrymoTz9GJ19sIF4c5ROvH6WoySxfLp_nkfpFqxrImpU4bbamWhgP12DNGfQ5OylyMvaMiN4R7MJzl3FohMi64p9oYaQzJKCVsiK72vbtQf7YQG_Vet6HqXioiM5ZhJiTtXHd7lw11jAG82oXyQ4dvRbDqMSrVY1TFSvXIVI9MHTB24fE-rKOFP_WH5P_BH4BAdy4</recordid><startdate>20180201</startdate><enddate>20180201</enddate><creator>Park, Sejun</creator><creator>Yeo, DongHun</creator><general>American Society of Civil Engineers</general><scope>AAYXX</scope><scope>CITATION</scope><scope>8FD</scope><scope>FR3</scope><scope>KR7</scope><orcidid>https://orcid.org/0000-0003-4617-8771</orcidid></search><sort><creationdate>20180201</creationdate><title>Second-Order Effects on Wind-Induced Structural Behavior of High-Rise Steel Buildings</title><author>Park, Sejun ; Yeo, DongHun</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a337t-2dabac2a9b4e2f0f332f8ed99856fd258b14feb4384cc557454f2abb9bb172213</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2018</creationdate><topic>Aeronautical research</topic><topic>Aeronautics</topic><topic>Axial forces</topic><topic>Beams (structural)</topic><topic>Bending moments</topic><topic>Columns (structural)</topic><topic>Drift</topic><topic>High rise buildings</topic><topic>Steel structures</topic><topic>Stiffness</topic><topic>Structural analysis</topic><topic>Structural behavior</topic><topic>Structural engineering</topic><topic>Technical Papers</topic><topic>Vibration analysis</topic><topic>Wind effects</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Park, Sejun</creatorcontrib><creatorcontrib>Yeo, DongHun</creatorcontrib><collection>CrossRef</collection><collection>Technology Research Database</collection><collection>Engineering Research Database</collection><collection>Civil Engineering Abstracts</collection><jtitle>Journal of structural engineering (New York, N.Y.)</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Park, Sejun</au><au>Yeo, DongHun</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Second-Order Effects on Wind-Induced Structural Behavior of High-Rise Steel Buildings</atitle><jtitle>Journal of structural engineering (New York, N.Y.)</jtitle><date>2018-02-01</date><risdate>2018</risdate><volume>144</volume><issue>2</issue><issn>0733-9445</issn><eissn>1943-541X</eissn><abstract>AbstractThis paper investigates second-order effects on wind-induced structural dynamic behavior of a 60-story high-rise steel structure known as the Commonwealth Advisory Aeronautical Research Council (CAARC) building model. These effects are considered in the structural analysis by using a geometric stiffness method allowing the dynamic analysis to be performed without iterations. Data sets of the aerodynamic pressure on the CAARC building model for suburban exposure are used in the database-assisted design (DAD) procedure to calculate, in addition to overturning moments and shear forces at the base, members’ demand-to-capacity indexes (DCIs), interstory drift ratios, and resultant accelerations. Dynamic analyses are performed using four reference mean hourly wind speeds at the rooftop for suburban terrain exposure (Uref=20 and 40 m/s for serviceability analysis, and 60 and 80 m/s for strength analysis). The second-order effects decrease natural frequencies of vibration of the building by up to 12%. In the strength analysis with Uref=80 m/s, second-order effects increase nondirectional peak global responses by up to 15% for overturning moments, 9% for base shears, and 10% for torsional moments. 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subjects	Aeronautical research Aeronautics Axial forces Beams (structural) Bending moments Columns (structural) Drift High rise buildings Steel structures Stiffness Structural analysis Structural behavior Structural engineering Technical Papers Vibration analysis Wind effects
title	Second-Order Effects on Wind-Induced Structural Behavior of High-Rise Steel Buildings
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