Discussion on the Seismic Design Analysis Method of Masonry Building

The main seismic objective in China is defined as “no failure under minor earthquake, repairable damage under moderate earthquake and no collapse under major earthquake”. Both strength and deformation are important to evaluate the seismic performance. For masonry building, only the shear strength check under minor earthquake is stipulated in the current Chinese seismic design code. Due to the poor ductility of masonry building, the seismic design analysis method may not guarantee the collapse-resistant capacity under major earthquake. For the achievement of the seismic objective, the demand of ductility is discussed. A typical severely damaged masonry building by the 5.12 Wenchuan Earthquake of 2008 is presented for the analysis of the through X-shape crack on the load-bearing wall. In order to enhance the collapse-resistant capacity, the authors suggest more shear strength margin to take the influence of structural ductility into consideration. The feasible way can be easily realized as a target to raise the limitation for the shear strength check parameter under minor earthquake and to keep uniform seismic capacity in two directions. The investigated building is also illustrated here as an example to process the shear strength check for better seismic performance by the authors’ suggestion.

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2015 Nepal earthquake: seismic performance and post-earthquake reconstruction of stone in mud mortar masonry buildings

Bulletin of Earthquake Engineering ◽

10.1007/s10518-020-00834-y ◽

2020 ◽

Vol 18 (8) ◽

pp. 3863-3896 ◽

Cited By ~ 1

Author(s):

Rohit Kumar Adhikari ◽

Dina D’Ayala

Keyword(s):

Seismic Performance ◽

Seismic Design ◽

Failure Modes ◽

Construction Materials ◽

Seismic Capacity ◽

Seismic Performance Assessment ◽

Capacity Curves ◽

2015 Gorkha Earthquake ◽

Seismic Design Code ◽

Earthquake Reconstruction

Abstract The residential building typology of Stone in Mud Mortar (SMM) masonry contributed significantly to the seismic losses caused by the 2015 Nepalese seismic sequence, also known as the 2015 Gorkha earthquake. SMM masonry is the most common construction type in Nepal, and notwithstanding the extensive damage, this has persisted in the post-earthquake reconstruction. This paper provides first an overview of the extent of damage and typical failure modes suffered by this typology. Some pressing issues in the ongoing post-earthquake reconstruction, such as building usability, construction quality are then discussed. The results of seismic analyses on both the pre-earthquake (PRE-SMM) and post-earthquake built (POST-SMM) typologies, using the applied element method employing a modelling strategy that accounts for the random shape of stone units, are then presented and discussed in terms of capacity curves and failure mechanisms. As per the seismic design code of Nepal, seismic performance assessment is conducted to understand the seismic design levels of these constructions. Finally, seismic fragility and vulnerability functions for both the PRE-SMM and POST-SMM typologies, considering the uncertainty in ground motions and material quality, are presented and discussed. Considering the seismic hazard in Nepal, the PRE-SMM typology is found to be highly vulnerable and seismic strengthening of these buildings is urgent. On the other hand, the POST-SMM typology has adequate seismic capacity and performs within the serviceability limit, given the quality of both the construction materials and workmanship are not compromised.

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Experimental Study on the Behavior of Existing Reinforced Concrete Multi-Column Piers under Earthquake Loading

Applied Sciences ◽

10.3390/app11062652 ◽

2021 ◽

Vol 11 (6) ◽

pp. 2652

Author(s):

Jung Han Kim ◽

Ick-Hyun Kim ◽

Jin Ho Lee

Keyword(s):

Seismic Performance ◽

Seismic Design ◽

Bridge Piers ◽

Scale Model ◽

Inertia Force ◽

Small Scale ◽

Lap Splice ◽

Existing Structures ◽

Seismic Design Code ◽

Seismic Force

When a seismic force acts on bridges, the pier can be damaged by the horizontal inertia force of the superstructure. To prevent this failure, criteria for seismic reinforcement details have been developed in many design codes. However, in moderate seismicity regions, many existing bridges were constructed without considering seismic detail because the detailed seismic design code was only applied recently. These existing structures should be retrofitted by evaluating their seismic performance. Even if the seismic design criteria are not applied, it cannot be concluded that the structure does not have adequate seismic performance. In particular, the performance of a lap-spliced reinforcement bar at a construction joint applied by past practices cannot be easily evaluated analytically. Therefore, experimental tests on the bridge piers considering a non-seismic detail of existing structures need to be performed to evaluate the seismic performance. For this reason, six small scale specimens according to existing bridge piers were constructed and seismic performances were evaluated experimentally. The three types of reinforcement detail were adjusted, including a lap-splice for construction joints. Quasi-static loading tests were performed for three types of scale model with two-column piers in both the longitudinal and transverse directions. From the test results, the effect on the failure mechanism of the lap-splice and transverse reinforcement ratio were investigated. The difference in failure characteristics according to the loading direction was investigated by the location of plastic hinges. Finally, the seismic capacity related to the displacement ductility factor and the absorbed energy by hysteresis behavior for each test were obtained and discussed.

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Investigation and Analysis on Seismic Damage of Masonry Buildings Subjected to Wenchuan Ms=8.0 Earthquake

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.452-453.105 ◽

2010 ◽

Vol 452-453 ◽

pp. 105-108 ◽

Cited By ~ 2

Author(s):

Hong Fu Chen ◽

Bai Tao Sun

Keyword(s):

Seismic Design ◽

Concrete Slab ◽

Seismic Damage ◽

Impact Factors ◽

Economic Losses ◽

Masonry Building ◽

Masonry Buildings ◽

Seismic Design Code ◽

The Impact ◽

Wenchuan Ms 8.0 Earthquake

During Wenchuan Ms 8.0 earthquake, masonry buildings have suffered severely damaged and collapsed, causing heavy casualties and huge economic losses. In this paper, based on seismic site survey data, some new phenomena and characteristics of earthquake damage in comparison with the 1976 Tangshan earthquake, such as seismic damage of large space buildings, inclined or “X” shaped crack in wall between windows or spandrel wall, stair damage, falling of precast reinforced concrete slab and horizontal crack at the bottom of structure, are discussed in detail. Then, the impact factors of seismic capacity of masonry building in Wenchuan earthquake, including construction age, seismic fortification, bay size, floor (roof) form, layer number, thickness of bearing wall are analyzed, respectively; Finally, some recommendations on seismic design and reconstruction of masonry structure by the seismic design code are proposed.

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Seismic Design of High Rise Building in Shenyang

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.166-169.2436 ◽

2012 ◽

Vol 166-169 ◽

pp. 2436-2443

Author(s):

Rong Qin

Keyword(s):

Seismic Performance ◽

Seismic Design ◽

Phase Iii ◽

Structural Elements ◽

Earthquake Scenarios ◽

High Rise ◽

Code Structure ◽

Moderate Earthquake ◽

Weak Points ◽

Rare Earthquake

This paper examines the A1 tower of the Shenyang Huafu Xintiandi Phase III project as an example of an out of code structure. It also analyzes the seismic performance under three earthquake scenarios; a frequent earthquake, a moderate earthquake and a rare earthquake. This paper will discuss the structural elements design, and address the weak points. This paper also provides several seismic design enhancements for similar high-rise buildings.

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Research on Seismic Vulnerability of Continuous Beam Bridges Based on Incremental Dynamic Analysis Method

E3S Web of Conferences ◽

10.1051/e3sconf/202019802026 ◽

2020 ◽

Vol 198 ◽

pp. 02026

Author(s):

Peizhi Wang

Keyword(s):

Seismic Performance ◽

Seismic Design ◽

Seismic Vulnerability ◽

Analysis Method ◽

Limit States ◽

Limit Values ◽

Vulnerability Curve ◽

Displacement Ductility ◽

Girder Bridges ◽

Multi Stage

The seismic vulnerability of highway continuous girder bridges is analyzed to provide theoretical basis for the study of multi-stage fortification and seismic design of such bridges. Based on the concept of performance seismic design, five performance levels of structures are determined, and the displacement ductility ratio of piers is taken as the performance quantitative index to calculate the damage limit values of bridges in different limit states. On this basis, IDA analysis method is used to calculate 20 subjects. Based on the reliability theory, logarithmic regression fitting analysis is carried out to obtain the seismic vulnerability curve. The theoretical vulnerability curve is indicated that the bridge has good comprehensive seismic performance. Under 0.3 g ground motion, the probability of minor damage, moderate damage and serious damage are 57.9%, 44.7% and 3.6% respectively. The comprehensive seismic performance of bridges and the probability of exceeding the damage status at all levels are reflected in the results, the guiding significance to analysis of the seismic performance of the entire traffic and the formulation of emergency rescue plans.

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Seismic performance of a load-bearing prefabricated composite wall panel structure for residential construction

Advances in Structural Engineering ◽

10.1177/1369433220927257 ◽

2020 ◽

Vol 23 (13) ◽

pp. 2928-2941

Author(s):

Qunyi Huang ◽

John Orr ◽

Yanxia Huang ◽

Feng Xiong ◽

Hongyu Jia

Keyword(s):

Bearing Capacity ◽

Seismic Performance ◽

Seismic Design ◽

Rural Areas ◽

Wall Panel ◽

Load Bearing Capacity ◽

Load Bearing ◽

Ductility Factor ◽

Seismic Design Code ◽

Composite Wall

To improve both seismic performance and thermal insulation of low-rise housing in rural areas of China, this study proposes a load-bearing prefabricated composite wall panel structure that achieves appropriate seismic performance and energy efficiency using field-assembled load-bearing prefabricated composite wall panels. A 1:2 scale prototype built using load-bearing prefabricated composite wall panel is subjected to quasi-static testing so as to obtain damage characteristics, load-bearing capacity and load–displacement curves in response to a simulated earthquake. As a result, seismic performance indicators of load-bearing capacity, deformation and energy-dissipating characteristics, are assessed against the corresponding seismic design requirements for rural building structures of China. Experimental results indicate that the earthquake-resistant capacity of the prototype is 68% higher than the design value. The sample has a ductility factor of 4.7, which meets the seismic performance requirement mandating that the ductility factor of such concrete structures should exceed 3. The design can be further optimized to save the consumption of material. This shows that the load-bearing prefabricated composite wall panel structure developed here has decent load-bearing capacity, ductility and energy dissipation abilities, a combination of which is in line with the seismic design code. A new construction process proposed here based on factory prefabrication and field assembly leads to a considerable reduction of energy consumption.

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Effect of Connection Deficiency on Seismic Performance of Precast Concrete Shear Wall-Frame Structures

Journal of Earthquake and Tsunami ◽

10.1142/s1793431119400050 ◽

2019 ◽

Vol 13 (03n04) ◽

pp. 1940005 ◽

Cited By ~ 3

Author(s):

Zijian Cao ◽

Quanwang Li

Keyword(s):

Seismic Performance ◽

Seismic Design ◽

Precast Concrete ◽

Shear Wall ◽

Frame Structure ◽

Occurrence Rate ◽

Point Estimate ◽

Seismic Reliability ◽

Point Estimate Method ◽

Seismic Design Code

The quality of precast concrete (PC) component connections is one of the main factors that affect the seismic reliability of PC structures. China is developing PC structures in high seismic regions, and it is important to assess the effect of connection deficiency on seismic performance of PC structures. This paper presents a comprehensive method to assess the seismic reliability of PC shear wall-frame structure whose wall panels are assembled through grouted sleeve connections which are susceptible to insufficient grouting. Considering the uncertainties associated with the number, locations and loading behavior of defected sleeve connections, the probabilistic behavior of PC shear wall with defected connections is estimated through point estimate method using simulation results of the experiment-validated finite element model. Then, a simple shear wall-frame building, designed for the seismic intensity of 8 according to China’s seismic design code, is modeled on platform of OpenSees. Static pushover analyses and seismic fragility analyses are performed on the structure with different degrees of connection deficiency, to investigate the effect of deficiency occurrence rate on seismic performance. The seismic performance is significantly affected by connection deficiencies; it no longer meets the requirement of seismic design as the deficiency occurrence rate exceeds 25%, so the occurrence rate of defected connections should be controlled carefully in construction site.

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Anti-Seismic Capacity Analysis and Structural Appraisal & Reinforcement of a Multi-Story Masonry Building with Load-Bearing of Longitudinal Wall

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.243-249.466 ◽

2011 ◽

Vol 243-249 ◽

pp. 466-471

Author(s):

De Yun Ma ◽

Yong Zhi Zuo ◽

Hai Wen Teng ◽

Da Huo

Keyword(s):

Wenchuan Earthquake ◽

Seismic Design ◽

Seismic Behavior ◽

Masonry Structure ◽

Capacity Analysis ◽

Masonry Building ◽

Structural System ◽

Seismic Capacity ◽

Load Bearing ◽

Longitudinal Wall

Based on the analysis for damages of masonry structure from Wenchuan earthquake, the seismic behavior of multi-story masonry school building is analyzed, and the seismic behavior with load-bearing structural system of longitudinal wall is mainly discussed. Based on the analysis and study, several problems which need more attention to the seismic appraisal and reinforcing design are pointed out, and finally the differences and correlation of seismic appraisal, as well as seismic design are discussed.

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Seismic Performance Study of Concrete Porous Brick Wall

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.250-253.2371 ◽

2011 ◽

Vol 250-253 ◽

pp. 2371-2375

Author(s):

Hua Wei Zhao ◽

Xiu Qin Cui ◽

Tong Hao

Keyword(s):

Seismic Performance ◽

Seismic Design ◽

Shear Capacity ◽

Hysteresis Curve ◽

Brick Wall ◽

Performance Study ◽

Design Code ◽

Loading Test ◽

Seismic Design Code ◽

Shear Bearing Capacity

Four constructional columns with concrete porous brick walls were constructed for low cyclic loading test. The damage on the characteristics and strength of the wall, hysteresis curve, ductility and other seismic performance were analyzed. Setting constructional columns in the wall at both ends increase the ultimate strength and improve its deformation, ductility and other properties. Meanwhile the height-wide-ratio of wall, axial pressure and other factors on the shear bearing capacity on the wall have been studied. Based on the shear capacity formula of wall in the Structural Seismic Design Code, considering the contribution of the constructional columns on the shear strength, according to the results, the shear capacity formula of constructional columns with concrete brick walls is presented.

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Nonbuilding Structures Seismic Design Code Developments

Earthquake Spectra ◽

10.1193/1.1586087 ◽

2000 ◽

Vol 16 (1) ◽

pp. 127-140

Author(s):

Harold O. Sprague ◽

Nicholas A. Legatos

Keyword(s):

Seismic Performance ◽

Seismic Design ◽

Nonlinear Behavior ◽

Seismic Energy ◽

Building Design ◽

Structural Elements ◽

Performance Requirements ◽

Seismic Design Code ◽

Wide Range ◽

Structural Engineers

The building code development process has traditionally given little effort to developing the seismic design process of nonbuilding structures. This has created some unique problems and challenges for the structural engineers that design these types of structures. The intended seismic performance requirements for “building” design are based on life safety and collapse prevention. Structural elements in buildings are allowed to yield as a method of seismic energy dissipation. The seismic performance of nonbuilding structures varies depending on the specific type of nonbuilding structure. Nonlinear behavior in some nonbuilding structures is unacceptable while other nonbuilding structures may be allowed to yield during an earthquake. Nonbuilding structures comprise a vast myriad of structures constructed of all types of materials, with markedly different dynamic characteristics, and with a wide range of performance requirements. This paper discusses the development of codes, design practices, and future of the seismic design criteria for nonbuilding structures.

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