A Simple Approach for the Design of Ductile Earthquake-Resisting Frame Structures Counting for P-Delta Effect

In the last decades, the possibility to use the inelastic capacities of structures have driven the seismic design philosophy to conceive structures with ductile elements, able to obtain large deformations without compromising structural safety. In particular, the utilization of high-strength elements combined with the purpose of reducing inertial masses of the construction has highlighted the second-order effect as a result of the “lightweight” structure’s flexibility. Computational aspects of inclusion of the second-order effects in the structural analysis remain an open issue and the most common method in the current design practices uses the stability coefficient θ. The stability coefficient estimates the ratio between the second-order effect and lateral loads’ effects. This coefficient is used then to amplify the lateral loads’ effects in order to consider the second-order effects, within a certain range proposed by codes of practices. In the present paper, we propose a simple approach, as an alternative to the stability coefficient method, in order to take into consideration P-Delta effects for earthquake-resisting ductile frame structures in the design process. The expected plastic deformations, which can be assessed by the behavior factor and the elastic deformations of the structure, are expected to magnify the P-Delta effects compared to those estimated from an elastic approach. The real internal forces are approximated by modifying the stiffness matrix of the structure in such a way as to provide a compatible amplification effect. This concept is herein implemented with a three-step procedure and illustrated with well-documented case studies from the current literature. The obtained results show that the method, although simple, provides a good approximation compared to more refined and computationally expensive methods. The proposed method seems promising for facilitating the design computations and increasing the accuracy of the internal forces considering the second-order effects and the amplification from the inelastic deformations.

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Evaluating second-order effects in rigid wall-flexible roof diaphragm buildings

Earthquake Spectra ◽

10.1177/8755293020919420 ◽

2020 ◽

Vol 36 (4) ◽

pp. 1864-1885

Author(s):

John Lawson ◽

Maria Koliou

Keyword(s):

Rigid Wall ◽

The United States ◽

Second Order ◽

Order Effects ◽

Building Stock ◽

Stability Coefficient ◽

Multistory Buildings ◽

Flexible Diaphragm ◽

Second Order Effects ◽

The Stability

When evaluating seismically induced second-order effects in buildings, engineers and researchers are most familiar with these concerns in the context of multistory buildings with rigid diaphragms. However, similar concerns are valid for short single-story concrete or masonry-walled buildings with larger flexible diaphragms, which is a significant portion of the building stock in the United States. These rigid wall-flexible diaphragm (RWFD) buildings may have significant diaphragm drifts causing induced second-order effects. The stability coefficient currently found in ASCE 7 has traditionally been used by practitioners to evaluate the relative risk of P-delta instability in multistory buildings, but this indicator can be adapted for use in RWFD buildings. Using numerical studies following the Federal Emergency Management Agency (FEMA) P-695 collapse assessment methodology to evaluate the risk of collapse for a set of RWFD archetype buildings, a modified stability coefficient for RWFD buildings is found to capture the trend toward P-delta collapse and can act as a reasonable indicator without the need for heavy computational efforts.

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Simplified Analysis of Second-Order Effect on Staggered Truss Structure

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.446-449.857 ◽

2012 ◽

Vol 446-449 ◽

pp. 857-862

Author(s):

Qi Shi Zhou ◽

Xu Hong Zhou ◽

Li Ming Yang

Keyword(s):

Structural Characteristics ◽

Order Effect ◽

Second Order ◽

Truss Structure ◽

Order Effects ◽

Good Precision ◽

Finite Element Software ◽

Load Carrying ◽

Second Order Effects ◽

Lateral Displacements

Based on the structural characteristics that the distribution of mass and stiffness is symmetrical in staggered truss structure, the load-carrying performance of staggered truss structure is equivalent to a pressure-bend combinational strut in this paper. By analyzing the relationship among curvatures , bending moments and shear forces of the pressure-bend combinational strut, the balance differential equations of the pressure-bend combinational strut is erected. Based on Runge-Kutta method, the lateral iteration equation derived by considering the influence of the second-order effects is derived. This paper analyzes the lateral displacements of floors of the staggered truss structure examples considering second-order effects or not, and gives a comparative analysis with the existing finite element software Ansys. The results show that the calculation method of second-order effects proposed in this paper has a good precision.

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Second order effects in dissipative media

Proceedings of the Royal Society of London Series A - Mathematical and Physical Sciences ◽

10.1098/rspa.1966.0117 ◽

1966 ◽

Vol 292 (1428) ◽

pp. 14-50 ◽

Cited By ~ 33

Keyword(s):

Strain Hardening ◽

Tensile Load ◽

Order Effect ◽

Elastic Cylinder ◽

Second Order ◽

Tensile Creep ◽

Order Effects ◽

Elastic Solids ◽

Viscoelastic Media ◽

Second Order Effects

Second order or ‘cross’ effects arise as a result of quadratic terms in the constitutive equations of isotropic elastic, viscous and viscoelastic media, which are required by the condition of tensor invariance of those relations. The most pronounced second order effects arise when these are clearly separable from the first order deformation, as in the case of second order elongation and volume change of an elastic cylinder subject to a twisting moment, or of second order normal stress in the case of shear flow of polymeric liquids. The recent I. U. T. A. M. Conference on Second Order Effects (Pergamon Press, London, 1964) was mainly concerned with these two phenomena. The paper discusses second order effects in dissipative (viscoelastic, plastic and strain hardening) solids and reports the results of experiments in which these effects were observed. While the experiments on elastomers confirm the Rivlin-Ericksen theory of those effects in viscoelastic media, the existence of a new accumulating second order effect has been discovered by experiments on aluminium specimens in reversed torsion (Ronay 1965). This effect, which has not been observed before, is probably responsible for the rapid acceleration of tensile creep in metals by small amplitudes of reversed torsion. While the second order effects in elastic solids vanish at zero strain since they are reversible, and vanish at zero velocity in polymeric fluids, they accumulate with the number of repeated torsion cycles in strain-hardening media. Hence their observation is very simple and does not require the elaborate procedures necessary for the observation of second order effects in elastic solids and viscous fluids. The theory of accumulating second order effects in strain-hardening media is developed; the linearity of the interaction between tensile load and torsion amplitude is demonstrated by the experiments.

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Second-Order Effect of Staggered Truss and Simplified Formula

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.163-167.808 ◽

2010 ◽

Vol 163-167 ◽

pp. 808-811

Author(s):

Lin Feng Lu ◽

Li Lin

Keyword(s):

Critical Factor ◽

Order Effect ◽

Internal Force ◽

Second Order ◽

Order Effects ◽

Magnification Factor ◽

Design Code ◽

The World ◽

Second Order Effects ◽

Simplified Formula

This paper summarizes the regulations about steel frame second-order effect of some design code in the world, and find out a critical factor of controlling second-order effect. The second-order effects of staggered truss were studied systematically by using ETABS program, and put forward design proposals the second-order effects of internal force and displacement, the simplified formula on second-order effect magnification factor of displacement was given.

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Analysis of second-order effects of constructions behaviour

The proceedings of the 13th international conference "Modern Building Materials, Structures and Techniques" (MBMST 2019) ◽

10.3846/mbmst.2019.118 ◽

2019 ◽

Author(s):

Raminta Venslavavičiūtė ◽

Kęstutis Urbonas

Keyword(s):

Steel Frame ◽

Second Order ◽

Frame Structure ◽

Frame Structures ◽

Order Effects ◽

Rotational Stiffness ◽

Frame Building ◽

Steel Frame Structures ◽

Second Order Effects ◽

Rigid Joints

This paper presents the importance of the second-order effects in behaviour of steel frame structures. EN 1993-1-1 were distinguished three main methods: taking / without taking into account second order effects depending on the sensitivity of horizontal design effects and tolerance. Using these methods, the susceptibility of steel frame structures to second-order impacts is considered in accordance with EN 1993-1-1. The study was performed taking into account also the rotational stiffness of the joints of the frame structure. In this way, trying to determine the effect of the joint on the rotational rigidity makes the frame structure more sensitive to second order impacts. It is also considered a semi-rigid joints effects the general frame-tailed P-Δ and the second row stress. This establishes the link between the effects of the second-order and the semi-rigid joints in the overall (general) analysis. Frame-building sensitivity makes it possible to compare and measure the importance of such dependencies.

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Design of slender reinforced concrete rectangular columns subjected to eccentric loads by approximate methods

Revista IBRACON de Estruturas e Materiais ◽

10.1590/s1983-41952012000400008 ◽

2012 ◽

Vol 5 (4) ◽

pp. 548-554 ◽

Cited By ~ 1

Author(s):

J. M. Calixto ◽

T. H. Souza ◽

E. V. Maia

Keyword(s):

Reinforced Concrete ◽

Second Order ◽

Order Effects ◽

Test Results ◽

Approximate Methods ◽

Design Procedures ◽

Load Combination ◽

Second Order Effects ◽

The Stability ◽

Slender Columns

Reinforced concrete codes worldwide establish that the design of slender columns must ensure that under the most unfavorable load combination, there is neither instability nor material failures. Thus, it is mandatory to consider material as well as geometrical nonlinearities. The consideration of second order effects can be done using simplified methods or the general method. This work analyses second order effects based on the approximate methods shown in NBR 6118 [1]: approximate curvature method and approximate stiffness procedure. Due to the importance of the columns in the stability of buildings is essential that these simplified design methods provide safe solutions for the design of columns. In this scenario, the objective of this study is to evaluate these simplified design procedures in terms of safety, precision and economy with respect to test results of RC slender columns subjected to eccentric loads found in the literature. The comparative analysis reveals that the approximate stiffness procedure provides better results.

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Second-order torsion effects in concrete buildings

Revista IBRACON de Estruturas e Materiais ◽

10.1590/s1983-41952021000100005 ◽

2021 ◽

Vol 14 (1) ◽

Author(s):

Rodrigo Bezerra Andrade ◽

Petrus Gorgônio Bulhões da Nóbrega

Keyword(s):

Structural Design ◽

Design Methodology ◽

Global Analysis ◽

Second Order ◽

Order Effects ◽

Concrete Buildings ◽

Internal Forces ◽

Second Order Effects

ABSTRACT: The internal forces due to torsion in global analysis of buildings, and its second-order effects, usually are not properly considered in structural design or even in design code’s prescriptions. Although the γZ coefficient, which is used to the evaluation of global second-order effects, has a wide, useful and consolidated application, it is true that specific torsional aspects are not well considered by it. This paper discusses the little-known γθ coefficient, an analogous proposition to the γZ coefficient, but focused specifically on the consideration of torsional effects. After the discussion on the concepts and the design methodology, several buildings are evaluated and their displacements and the coefficients γZ and γθ are calculated. Comparing these parameters, and also the results obtained by the P–Δ method, it is demonstrated the importance and the reliability of the γθ coefficient.

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