Assessment of the Design Criteria for Concentric V-Braced Steel Structures According to Italian and European Codes

Faggiano, Beatrice; Formisano, Antonio; Fiorino, Luigi; Castaldo, Carmine; Macillo, Vincenzo; Mazzolani, Federico M.

doi:10.2174/1874149501711010464

Cited by 11 publications

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“…A critical review of design methodologies has been made with the scope of providing simplified and more efficient design criteria and procedures, according to the modern design approach, able to ensure adequate safety levels under seismic actions [25]. Some theoretical-numerical studies have been developed on inverted CBF-V by considering common structural configurations of with 3, 6 and 10 storeys, designed according to the current standard provisions by using both linear static and dynamic analyses [26]. The consequences of the use either circular hollow sections (CHS) or HE profiles for braces has been analyzed.…”

Section: Concentric Bracingsmentioning

confidence: 99%

00.03: European research on steel structures in seismic areas

Mazzolani

2017

ce papers

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In Europe the research activities on steel structures in seismic areas is very intense and productive since the '80s of the last century. Many research projects have been developed. In particular, the activity started within the Technical Committee 13 (seismic design) of ECCS deeply contributed to the scientific debate and to the genesis of current Eurocode 8, which is currently under maintenance. This paper summarizes the main topics already consolidated and the related research activities currently ongoing, together with the ones needing further developments, in order to highlight the research perspectives of the European community of experts working on the field of steel structures in seismic areas. In particular, the discussion focuses on material properties, local ductility, full strength and dissipative joints, innovative types of links in eccentrically braced frames, capacity design rules, cold-formed applications, new structural types and devices, the use of steel in structural consolidation.

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Section: Concentric Bracingsmentioning

confidence: 99%

00.03: European research on steel structures in seismic areas

Mazzolani

2017

ce papers

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“…In line with [18], this work critically discusses about (i) the ductility classes and the correlated force-reduction factors; (ii) the structural analysis methods permitted by different codes; (iii) the detailing rules for both dissipative (bracing members) and nondissipative elements. The second paper describes the results of a numerical study carried out by Faggiano et al [19] aimed at investigating the seismic performance of inverted V concentrically braced frames designed according to [15, . The results show that the examined structures experience poor seismic performance without tensile yielding of bracing members.…”

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Nonlinear Behaviour, Design and Analysis of Steel Structures: Recent Findings and New Trends for the Next Generation of European Design Standards

D’Aniello¹

2017

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“…Specifically for Chevron Braced Frames (CBF-V), the ratio between the beam flexural stiffness and the braces vertical stiffness is recognized as affecting the overall performance and the damage of braces under compression [6]. In this context an overview on the codification aspects according to the Italian technical Code (NTC08) and the Eurocode 8 is presented [7,8], evidencing some critical issues both in the design process and in the seismic capacity of structures evaluated through non-linear static analyses. In particular, it is observed that current design criteria lead to structures that behave better than expected, in terms of ductility and dissipative capability, being the behaviour factors calculated larger than the design value, although the ideal collapse condition is not attained, a local beam mechanism occurring at the top story, in absence of brace plastic behaviour in tension.…”

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confidence: 99%

“…2 THE CASE STUDIESThe study structures belong to in-plan and in-elevation regular buildings with 3, 6 and 10 storeys [7]. The geometric features of the structural model are shown in Figure 1.…”

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“…Lastly, according to the Damage Limit State (DLS), the inter-story drift limit is assumed as equal to 1%. More details about the used design assumptions are given in Faggiano et al [7]. The main results of the design phases in terms of total weight W, first vibration period T 1 , base shear F h and over-strength factor Ω min of the investigated structures, with either CHS or HE bracing profiles, are reported in Table 1.…”

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11.64: Seismic behaviour of steel Chevron bracing systems by non‐linear dynamic analyses

et al. 2017

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The paper focuses on steel Chevron concentric bracing systems (CBF-V) as seismic resistant structures, presenting the evaluation of the structural seismic performance through dynamic analyses, aimed at improving the design methods. A wide numerical study is carried out. Different CBF-V configurations are designed, for a total number of 12 structures, by varying number of storeys (3, 6, 10), design methods (linear and dynamic analysis) and braces sections (H-shaped and circular hollow sections). Nonlinear Incremental Dynamic Analyses (IDA) are performed by the SeismoStruct software, considering 7 earthquakes records, in order to investigate the seismic response. The most relevant evaluation parameters are shown and discussed, IDA curves are caught and the behavior factors calculated. Results show that expected collapse modes, involving the braces only, according to the Capacity Design, are not in agreement with the noted mechanisms, in which damage also involves nondissipative elements, in particular the beams. Hence, it is needed to deepen such key issue, through further experimental and numerical investigations in order to optimize the design procedure.1 INTRODUCTIONThe behaviour of Concentric Braced Frames (CBFs) mainly depends on the capacity of bracing members to resist large inelastic displacement reversals without significant loss of strength and stiffness, more specifically, on compressed members, whose behaviour is governed by buckling. This topic is investigated by several researchers through both experimental and analytical studies on either single braces, or single story single bay, or multi-storey multispan structural systems, by analysing both local and global behaviour of bracing systems. For single braces, the optimization of the slenderness [1] and the influence of the cross-section shapes and other member properties on the structural performance, generally estimated in terms of strength, ductility, energy dissipation and mid-length lateral deformation [2], are evaluated. For structural systems, overall cyclic response and brace failure mechanisms are investigated [3], through static non-linear analyses on CBFs with different stories and span lengths, evidencing the great effect of the geometrical configurations on the response modification factors [4,5]. Specifically for Chevron Braced Frames (CBF-V), the ratio between the beam flexural stiffness and the braces vertical stiffness is recognized as affecting the overall performance and the damage of braces under compression [6]. In this context an overview on the codification aspects according to the Italian technical Code (NTC08) and the Eurocode 8 is presented [7,8], evidencing some critical issues both in the design process and in the seismic capacity of structures evaluated through non-linear static analyses. In particular, it is observed that current design criteria lead to structures that behave better than expected, in terms of ductility and dissipative capability, being the behaviour factors calculated larger than the design value, although...

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Assessment of the Design Criteria for Concentric V-Braced Steel Structures According to Italian and European Codes

Cited by 11 publications

References 13 publications

00.03: European research on steel structures in seismic areas

00.03: European research on steel structures in seismic areas

Nonlinear Behaviour, Design and Analysis of Steel Structures: Recent Findings and New Trends for the Next Generation of European Design Standards

11.64: Seismic behaviour of steel Chevron bracing systems by non‐linear dynamic analyses

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