Composite effects on rotational constraints of a double-beam system reinforced with beam-end concrete

•Conduct flexural experimental tests of 1/3-scale four composite double-beam systems.•Investigate the composite effects of installing beam-end concrete in composite double-beam and column connection.•Quantify analytically the joint rotational constraints and negative/positive moment demands.•Verify...

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Veröffentlicht in:	Engineering structures 2021-02, Vol.228, p.111585, Article 111585
Hauptverfasser:	Choi, Insub, Kim, JunHee, Jang, Jisang, Chang, Hakjong, Kang, Gisung
Format:	Artikel
Sprache:	eng
Schlagworte:	Beam-columns Bending Composite beams Composite joint Composite materials Concrete Concrete reinforcements Demand Double-beam system Failure modes Flexural capacity Moment demands Rotational constraint Stiffness Ultimate tensile strength Vertical loads
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creator	Choi, Insub Kim, JunHee Jang, Jisang Chang, Hakjong Kang, Gisung
description	•Conduct flexural experimental tests of 1/3-scale four composite double-beam systems.•Investigate the composite effects of installing beam-end concrete in composite double-beam and column connection.•Quantify analytically the joint rotational constraints and negative/positive moment demands.•Verify the constraint effects by comparing to rigid and pinned connection criteria defined in ANSI/AISC 360. Composite beam systems have been widely used for building structures since the combination of two materials can provide the effective bending capacity. However, it is still challenging to estimate the constraint effects of concrete material in beam-column joints. In this study, the flexural behavior and composite constraint effects of a novel steel double-beam system with composite joints are investigated for the use of high vertical loads. First, the flexural performance of four 1/3-scale test specimens was experimentally examined according to the presence of beam-end concrete reinforcement in terms of the initial stiffness, ultimate strength, and failure modes. Second, the composite joints were idealized as beam-end rotational springs and the degree of rotational constraints were analytically estimated to quantify the negative moment demand at beam-end and positive moment demand at mid-span. The results showed that the composite joint of the double-beam system made an effective and efficient way to increase the bending capacity and to decrease the moment demands by providing significant rotational constraint effects. It was also found that the test specimen exhibits the constraint effect similar to the rigid connection defined in the ANSI/AISC 360 criteria, thereby reducing the moment demand by 89.3%.
doi_str_mv	10.1016/j.engstruct.2020.111585
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Composite beam systems have been widely used for building structures since the combination of two materials can provide the effective bending capacity. However, it is still challenging to estimate the constraint effects of concrete material in beam-column joints. In this study, the flexural behavior and composite constraint effects of a novel steel double-beam system with composite joints are investigated for the use of high vertical loads. First, the flexural performance of four 1/3-scale test specimens was experimentally examined according to the presence of beam-end concrete reinforcement in terms of the initial stiffness, ultimate strength, and failure modes. Second, the composite joints were idealized as beam-end rotational springs and the degree of rotational constraints were analytically estimated to quantify the negative moment demand at beam-end and positive moment demand at mid-span. The results showed that the composite joint of the double-beam system made an effective and efficient way to increase the bending capacity and to decrease the moment demands by providing significant rotational constraint effects. 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Composite beam systems have been widely used for building structures since the combination of two materials can provide the effective bending capacity. However, it is still challenging to estimate the constraint effects of concrete material in beam-column joints. In this study, the flexural behavior and composite constraint effects of a novel steel double-beam system with composite joints are investigated for the use of high vertical loads. First, the flexural performance of four 1/3-scale test specimens was experimentally examined according to the presence of beam-end concrete reinforcement in terms of the initial stiffness, ultimate strength, and failure modes. Second, the composite joints were idealized as beam-end rotational springs and the degree of rotational constraints were analytically estimated to quantify the negative moment demand at beam-end and positive moment demand at mid-span. 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Composite beam systems have been widely used for building structures since the combination of two materials can provide the effective bending capacity. However, it is still challenging to estimate the constraint effects of concrete material in beam-column joints. In this study, the flexural behavior and composite constraint effects of a novel steel double-beam system with composite joints are investigated for the use of high vertical loads. First, the flexural performance of four 1/3-scale test specimens was experimentally examined according to the presence of beam-end concrete reinforcement in terms of the initial stiffness, ultimate strength, and failure modes. Second, the composite joints were idealized as beam-end rotational springs and the degree of rotational constraints were analytically estimated to quantify the negative moment demand at beam-end and positive moment demand at mid-span. 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subjects	Beam-columns Bending Composite beams Composite joint Composite materials Concrete Concrete reinforcements Demand Double-beam system Failure modes Flexural capacity Moment demands Rotational constraint Stiffness Ultimate tensile strength Vertical loads
title	Composite effects on rotational constraints of a double-beam system reinforced with beam-end concrete
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