Collapse Analysis of RC Structures using Improved
Transcription
Collapse Analysis of RC Structures using Improved
Collapse Analysis of RC Structures using Improved Applied Element Method Said ELKHOLY1, Mohamed GOMMA2and Adel AKL3 1 Assistant Professor, Fayoum University, Egypt [email protected] 2 Ph.D. Candidate, Cairo University, Egypt 3 Professor, Cairo University, Egypt ABSTRACT In this paper, the Improved Applied Element Method (IAEM), which was originally developed as an effective analysis technique of large-scale steel structures up to complete failure under different hazard loads, has been progressively developed to carry out modeling of the behavior of plane frame reinforced concrete (RC) and composite structures. By adopting the fiber-beamelement model and the multi-layer-element model, which are developed for RC and composite framed structures, the extreme nonlinear behavior of RC and composite structural elements can be accurately simulated. The technique is an effective tool for the numerical evaluation of the behavior of structures under extreme loading conditions and their collapse mechanisms. Moreover, the proposed model's high simulation capability for the cycle behavior under coupled axial force-bending moment-shear force, the breakdown of structural elements at ultimate states, and the contact between structural elements during the collapse are demonstrated. Finally, the method is used to study the vulnerability of school buildings in Egypt to progressive collapse by conducting a detailed dynamic collapse analysis for an old school building. The analysis is carried out to investigate the cause of the collapse and the method that can be adopted to enhance the structure so that the collapse can be prevented. Keywords: Progressive collapse, Improved Applied Element Method, Multi Layered Element, School buildings, Retrofitting technique. 1. INTRODUCTION Reinforced concrete is one of the most widely used modern building materials. With the rapid growth of urban population, RC frame construction has been widely used for residential construction in both the developing and industrialized countries. One of the major causes of seismic vulnerability associated with RC buildings is that, in the developing countries, a large number of the existing RC frame buildings have been designed without engineering input and have been built by inadequately skilled construction workers. This paper considers issues related to earthquake induced progressive collapse of RC buildings in extreme events. This paper concentrates on developing an efficient numerical technique based on the IAEM. The IAEM is a newly developed method for structural analysis of large-scale steel framed structures (Elkholy and Meguro, 2003) It can trace the 0ctober 2010, Kobe, Japan behavior of steel structures up to the complete failure stage with high accuracy in reasonable CPU (Elkholy and Meguro, 2004). In IAEM, each structural member is divided into a proper number of rigid elements connected by pairs of normal and shear springs distributed on the boundary line between elements. Unlike the conventional AIM (Tagel-Din and Meguro, 2000), the element in IAEM has been modified in order to use different thickness per each connecting spring to follow the change of thickness of the cross-sectional width in the case of modeling nonrectangular cross-sections. This research is concerned with the development of an efficient and accurate numerical technique based on the IAEM to analyze the collapse of large-scale RC and composite structures under hazardous loads, such as earthquakes and explosions. 2. MODELING OF RC AND COMPOSITE STRUCTURES USING IAEM In IAEM, each structural member is divided into several segments. Each segment represents certain cross section properties. A new element type (multi-layered element) is introduced to IAEM to simulate non-homogenous cross sections (Figure 1). This new element is composed of several layers. Each of these layers has its own material properties. All identical layers in the nearby elements are assumed to be connected to each other by sets of normal and shear springs distributed on the boundary line. These sets of springs represent the microscopic material properties of the layer. Moreover, each spring has its own thickness according to the average thickness in the area represented by this spring and its own shear and normal stiffness. Figure 1: Modeling RC framed structures with the new element type The value of normal stiffness ( K ni ) and shear stiffness ( K si ) for each pair of springs in the Lth layer can be determined as: New Technologies for Urban Safety of Mega Cities in Asia Collapse Analysis of RC Structures using Improved Applied Element Method E .d i .(T i ) (K )L = L L n L a i n , ( ) G L .d Li . Tsi (K )L = a i s L (1) where: the subscripts n and s refer to normal and shear springs, respectively; d Li is the distance served by the ith spring in the Lth layer; a is the length of the representative area; EL and GL are the Young’s and shear’s modules of the Lth layer, respectively; Tni and Tsi are the thicknesses represented by the pair of springs “i” for the normal and shear cases, respectively. The corresponding condensed stiffness matrix of each element is obtained by summing the effects of each spring pair at each layer that the element is composed of. This matrix is then transformed from the local (element) co-ordinate system to the global (structure) co-ordinate system. Equation (2) shows the components of the upper left quarter of the stiffness matrix. All used notations in this equation are shown in Figure 2. (2) Figure 2: Contact points and DOF 2.1 Material Modeling The Maekawa compression model for concrete is adopted in the IAEM (Figure 3a). The tangent modulus is calculated according to the strain at the spring location. In tension, the stress-strain curve for concrete is approximately linear elastic up to the maximum tensile strength. After this point, the concrete cracks and its strength decreases gradually down to zero. The steel I-beam and steel bars are modeled as a classical elastic plastic material with strain hardening using bilinear stress–strain relationship in both compression and tension (Figure 3b). Finally, the stress strain relation of all types of FRP material is assumed linear up to failure (Figure 3c). Collapse Analysis of RC Structures using Improved Applied Element Method 0ctober 2010, Kobe, Japan (a) Concrete (b) Steel (c) FRP Figure 3: Material Models used in IAEM 3. MODIFICATION IN DYNAMIC PROPERTIES The general differential equation of motion, governing the response of the structure in a small displacement range can be expressed as: [M ]{ΔU&&}+ [C ]{ΔU& }+ [K ]{ΔU } = Δf (t ) − [M ]{ΔU&&G } (3) where: [M] is mass matrix; [C] is the damping matrix; [K] is the nonlinear stiffness matrix; Δf(t) is the incremental applied load vector; {ΔU&&} , {ΔU& } , {ΔU } and {ΔU&& } are the incremental acceleration, velocity, acceleration, and gravity acceleration vectors, respectively. G Equation (3) is solved numerically using an implicit time-stepping method based on the Newmark-Beta technique (Chopra, 2000). In this technique, the displacement, velocity and acceleration vectors at time t are used to obtain a displacement vector after a time interval (Δt) based on the following equation. ⎡ 1 ⎤ ⎡ 1 ⎤ ⎛ γ ⎞ ⎡ 1 γ γ ⎤ M+ C + K ⎥ ΔU = Δf + ⎢ M + C ⎥U& + ⎢ M + ⎜⎜ − 1⎟⎟ΔtC ⎥U&& ⎢ 2 βΔt β ⎦ ⎝ 2β ⎠ ⎣ β Δt ⎣ 2β ⎦ ⎣ β (Δt ) ⎦ (4) where the parameters β and γ define the variation of acceleration over a time-step and determine the stability and accuracy. Adopting the multi-layered element in the IAEM allows the user to define material specific weights for each layer, with which the distributed self-mass of the structure can then be obtained using the Materials and Sections facilities. The individual structural mass matrix of each element is calculated assuming that masses lumped at the element centroid. The corresponding lumped mass in each DOF direction is calculated by summing the effect of the small segmental mass represented by each spring considering the change of the springs’ thickness. Equation (5) represents the value of lumped mass in each DOF direction. In addition, non-structural mass is added to the model to define any mass not associated to the self-weight of the structure (e.g. slab, finishing, walls, etc). (5) where: a and b are the element dimensions; ρ j is the density of material of the jth layer considered; nlyr is the number of layers; nsp is the number of connecting springs; mix and miy are the ith spring mass per unit area of the element in x and y New Technologies for Urban Safety of Mega Cities in Asia Collapse Analysis of RC Structures using Improved Applied Element Method directions respectively; and t xj and t jy are the ith spring thickness at a certain level in the jth layer in x and y directions respectively. 4 ASSESSMENT OF OLD EXISTING SCHOOL BUILDINGS The vulnerability of schools and other educational facilities has been observed in every recent destructive earthquake all over the world. The work in this section aims to identify the causes of the collapse of one of the typical types of old existing school buildings in Egypt to evaluate its seismic risk, to evaluate the efficiency of different retrofitting techniques, and to propose a national and public policies to reduce the risk of this type of schools. In this section, the multi-layered IAEM is applied to investigate the validity of the proposed method in simulating progressive collapse of RC school buildings under hazardous load conditions. A detailed analysis of the collapsing process of the selected structure with and without retrofitting under severe ground motion conditions is presented. 4.1 School buildings in Egypt School buildings in Egypt are typically one to five-storey long narrow buildings with an open corridor on the school courtyard side and classrooms on the longitudinal side. The courtyard side of a classroom typically has large windows; and the back wall is solid up to about 70 cm from the upper floors, where long and narrow longitudinal windows are located to allow for ventilation and extra lighting. School class blocks are often aligned in an L-shape or U-shape around the school courtyard. The typical structure consists of a moment resistant concrete frame in the longitudinal direction and a concrete frame with unreinforced masonry infill walls in the transversal direction. 4.2 Structural modeling and verification Figure 4 shows the concrete dimensions and reinforcement details of one of the typical school buildings that were designed and constructed according to the Egyptian specifications issued before the October 1992 earthquake. The structure consists of a series of single bay, 3-story RC frames with a cantilever. Using the multi-layered element features, the school building was modelled using only 87 elements for the superstructure. Moreover, three retrofitting techniques for this type are also investigated using the same number of elements (Figure 5). columns Figure 4: Concrete dimensions and reinforcement details Collapse Analysis of RC Structures using Improved Applied Element Method 0ctober 2010, Kobe, Japan RC Jacketing 1st floor CFRP warping RC Jacketing all floors Figure 5: The three proposed retrofitting techniques Mode 1 Mode 2 Mode 3 ω = 6.422 (rad/sec) ω = 22.207 (rad/sec) ω = 43.608 (rad/sec) ω = 6.25 rad/sec 2.693% ω = 21.48 rad/sec 3.370% ω = 40.66 rad/sec 7.264% FEM Multi-layered IAEM To evaluate the accuracy of the modelling, the frame is simulated both in IAEM and SAP2000 (CSI, 2000). A modal analysis was performed to calculate the natural frequencies of the structure. The first three modes are basically coincidentally close and a maximum difference of 7.26 % has been observed. These three mode shapes are shown in Figure 6. Difference Figure 6: Comparison between the first three modes obtained by IAEM and FEM 4.3 Seismic response After verifying the method, the inelastic dynamic collapse analysis has been performed by introducing a displacement time history of three ground motion records at the supports, as shown in Table 1. The acceleration time history and 5% damping elastic response spectra curves of the selected ground motions with the buildings fundamental periods illustrated on the curve by vertical lines are shown in Figure 7 which shows a distinctive difference among each ground motion. Each record has been scaled up and down to different levels in order to determine the PGA value at which a certain building type can resist without collapse. Table 1: Ground motions characteristics Earthquake Kobe Northridge Park field Date 16/1/1995 17/1/1994 28/6/1966 Component KAK090 NWH090 C02065 PGA (g) 0.345 0.583 0.476 PGV (cm/s) 27.6 75.5 75.1 PGD (cm) 9.6 17.57 22.49 A/V 1.247 0.772 0.634 New Technologies for Urban Safety of Mega Cities in Asia Collapse Analysis of RC Structures using Improved Applied Element Method Figure 7: Selected ground motions and their response spectrum 4.4 Analysis results The main objectives of the assessment are to investigate the collapse mechanism of each model and to obtain the minimum value of the PGA of each ground motion record used in this analysis that can produce the collapse. These minimum values are used to evaluate the vulnerability of each model and to assess the efficiency of each retrofitting strategy. Figure 8 summarizes the results of the analysis for the un-retrofitted and the retrofitted models. The figure demonstrated that the un-retrofitted school building has a very poor performance in the short direction (investigated direction). Therefore, even a small magnitude earthquake posed a threat. It was also founded that retrofitting the columns by CFRP warping increased the seismic capacity by around 40%, however, using RC jacketing increased the seismic capacity of the building by at least 80% to 150% based on the height of the jacketing. Figure 8: Minimum values of the PGA that produced complete collapse Figure 9 shows the seismic collapse mechanism of the un-retrofitted school. The figure shows that the collapse initiated at the mid of the ground floor column due to combined actions of axial and flexural moments. The insufficient ductility of the members due to insufficient confinement, and low level of strength due to Collapse Analysis of RC Structures using Improved Applied Element Method 0ctober 2010, Kobe, Japan Northridge earthquake (PGA = 0.233 g) insufficient cross-sectional dimensions, longitudinal reinforcement ratio and low strength of longitudinal bars were the main reasons of the failure. (a) 10.05 (sec) (b) 10.20 (sec) (c) 10.25 (sec) (d) 10.30 (sec) (e) 10.35 (sec) (f) 10.50 (sec) (g) 10.55 (sec) (h) 10.60 (sec) Figure 9: Collapse mechanism of the building without repair The rehabilitation using FRP Figure 10 illustrates the enhancement in the columns capacity due to using CFRP warping which increased the resistance capacity of the building. The FRP composite materials do not significantly affect the initial stiffness of the concrete members but improves the strength. Therefore the rehabilitation using FRP warping for the columns does not significantly change the dynamic response of the frame. FRP-strengthening significantly changes the damage location and the collapse mechanism of the frame. The rehabilitation using RC jacketing The effect of using RC jacketing for columns in the first floor only is shown in Figure 11. However, the seismic capacity of the building increased by more than 80%, Figure 11 shows one of the undesirable collapse mechanisms. Due to the sudden change of the cross-section of columns, the building had a non-ductile soft-story collapse mechanism at the second floor level. The max story deformation occurs at the second story and plastic hinges developed at the ends of columns. Finally the analysis shows that using the RC jacketing for all columns in all floors improves the seismic performance of the structure (Figure 12). According to the figure, the inelastic deformation demand and energy dissipation spread throughout the structure. Beams commence yield before columns and a beam side-sway mechanism occurred. Plastic hinges form at critical sections of all beams in the frame and the bottom of the first story columns. New Technologies for Urban Safety of Mega Cities in Asia Northridge earthquake (PGA = 0.292 g) Collapse Analysis of RC Structures using Improved Applied Element Method (a) 9.50 (sec) (b) 9.60 (sec) (c) 9.85 (sec) (d) 9.95 (sec) (e) 10.50 (sec) (f) 10.70 (sec) (g) 11.00 (sec) (h) 11.50 (sec) Northridge earthquake (PGA = 0.758g) Figure 10: Collapse mechanism of FRP Retrofitted building (a) 23.50 (sec) (b) 24.00 (sec) (c) 24.50 (sec) (d) 24.75 (sec) (e) 25.00 (sec) (f) 25.20 (sec) (g) 25.40 (sec) (h) 25.60 (sec) Figure 11: Collapse mechanism of the building with RC jacketing columns in the ground floor only 5. CONCLUSIONS The numerical method, IAEM, presented in this paper shows a good capability to study the total behavior of RC and composite structural buildings from the early stage of loading until the total collapse occurs. The analysis demonstrated the Collapse Analysis of RC Structures using Improved Applied Element Method Northridge earthquake (140% PGA = 0. 0.816 g) 0ctober 2010, Kobe, Japan (a) 10.00 (sec) (b) 15.00 (sec) (c) 20.00 (sec) (d) 23.00 (sec) (a) 23.50 (sec) (b) 23.75 (sec) (c) 23.85 (sec) (d) 24.35 (sec) Figure 12: Collapse mechanism of building with RC jacketing in all floors reliability of the new IAEM in modeling large scale RC framed structures using the minimum number of elements. The validity of the developed code has been demonstrated by a numerical example. Moreover, less computational effort and a wider applicability for structural analysis have been observed than those of conventional discrete element methods. The proposed method can provide a better understanding of the failure mechanism of buildings due to severe ground motions. Simple two-dimensional analysis tools such as that adopted in this paper can be used to judge in a qualitative and quantitative manner the damage tolerance of buildings. Evaluation of the seismic performance of a sample of old existing school buildings in Egypt is presented. Approaches to reduce the vulnerability of the building are also highlighted. REFERENCES Elkholy, S., H. Tagel-Din, and K. Meguro. Structural Failure Simulation due to Fire by Applied Element Method. in The 5th Japan Conference on Structural Safety and Reliability. 2003. Tokyo, Japan. Elkholy, S. and K. Meguro. Numerical Simulation of High-rise Steel Buildings using Improved Applied Element Method. in 13th World Conference on Earthquake Engineering. 2004. Paper No. 930, Vancouver. Tagel-Din, H. and K. Meguro, Applied Element Method for Simulation of Nonlinear Materials: Theory and Application for RC Structures. Structural Engineering and Earthquake Engineering, 2000. 17(2): p. 137-148. Sap2000 v.12, Structural Analysis Program, Computers and Structures, Inc., CA., USA, 2000 Chopra, A.K., 2000. Theory and Applications to Earthquake Engineering. 2nd edition, ed. P.H. Education.: Prentice Hal New Technologies for Urban Safety of Mega Cities in Asia