• 한국공간구조학회논문집
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• 제22권1호
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• pp.41-49
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• 2022

In the case of columns in buildings with soft story, the concentration of stress due to the difference in stiffness can damage the columns. The irregularity of buildings including soft story requires retrofit because combined load of compression, bending, shear, and torsion acts on the structure. Concrete jacketing is advantageous in securing the strength and stiffness of existing members. However, the brittleness of concrete make it difficult to secure ductility to resist the large deformation, and the complicated construction process for integrity between the existing member and extended section reduces the constructability. In this study, two types of Steel Grid Reinforcement (SGR), which are Steel Wire Mesh (SWM) for integrity and Steel Fiber Non-Shrinkage Mortar (SFNM) for crack resistance are proposed. One reinforced concrete (RC) column with non-seismic details and two columns retrofitted with each different types of proposed method were manufactured. Seismic performance was analyzed for cyclic loading test in which a combined load of compression, bending, shear, and torsion was applied. As a result of the experiment, specimens retrofitted with proposed concrete jacketing method showed 862% of maximum load, 188% of maximum displacement and 1,324% of stiffness compared to non-retrofitted specimen.

• Earthquakes and Structures
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• 제26권6호
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• pp.477-487
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• 2024

The interaction between multiple structures through the supporting soil media, known as structure-soil-structure interaction (SSSI), has become an increasingly important issue due to rapid urbanization. There is a need to investigate the effect of SSSI on the structural response of buildings compared to non-interaction analysis (NIA) and soil-structure interaction (SSI) analysis. In the present study, two identical 4-bay×4-bay, three-story RCC buildings are modeled adjacent to each other with a soil domain beneath it to investigate the effect of SSSI on the forces experienced by footings under gravity and seismic load cases. The ANSYS software is used for modeling various non-interaction and interaction models which work on the principle of FEM. The results indicate that in most of the footings, the SSSI effect causes a significant redistribution of forces compared to SSI and NIA under both gravity and seismic load cases. The maximum interaction effect is observed on the footings that are closer to the adjacent building. The axial force, shear force and bending moment values on these footings show that SSI causes a significant increase in these values compared to non-interaction analysis but the presence of adjacent building relieves these forces significantly.

• 한국화재소방학회논문지
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• 제31권1호
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• pp.58-62
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• 2017

국내에서도 내진설계의 필요성이 점차 증대되고 있다. 그 중에서도 비구조요소인 소화배관의 흔들림 방지 버팀대에 관한 연구가 계속되고 있다. 이에 본 연구에서는 흔들림 방지 버팀대의 하중 시험을 통하여 유효한 범위를 측정하였다. 그 결과, 하중 0에서부터 18.5 kN까지 설계안전 범위로 측정되었으며 최대 29.4 kN에서도 흔들림 방지 버팀대의 구조 및 성능에 이상 없이 정상 작동하였다. 또한 사물인터넷의 환경을 이용하여 센서노드로부터 데이터를 전송받아 유효 하중범위 안에서 추출과 예측단계를 거쳐 재난정보를 수신케 하는 모니터링 시스템의 모듈을 구성하였다.

• Earthquakes and Structures
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• 제18권2호
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• pp.201-213
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• 2020

Seismic damages that occurred by the effects of epicenter distance of the earthquake are one of the most important problems for the earthquake engineering. In this study, it is aimed to examine the nonlinear seismic behaviors of concrete gravity (CG) dams considering various epicenter distances. For this purpose, Boyabat CG dam that is one of the biggest concrete gravity dams in Turkey is selected as a numerical application. FLAC3D software based on finite difference method is used for modelling and analyzing of the dam. Drucker-Prager nonlinear material model is used for the concrete body and Mohr-Coulomb nonlinear material model is taken into account for the foundation. Special interface elements are used between dam body and foundation to represent interaction condition. Free-field and quiet non-reflecting boundary conditions are utilized for the main surfaces of 3D model. Total 5 various epicenter distances of 1989 Loma Prieta earthquake are considered in 3D earthquake analyses and these distances are 5 km, 11 km, 24 km, 85 km and 93 km, respectively. According to 3D seismic results, x-y-z displacements, principal stresses and shear strain failures of the dam are evaluated in detail. It is clearly seen from this study that the nonlinear seismic behaviors of the CG dams change depending to epicenter distance of the earthquake. Thus, it is clearly recommended in this study that when a CG dam is modelled or analyzed, distance of the earthquake fault to the dam should be strongly examined in detail. Otherwise, earthquake damages can be occurred in the concrete dam body by the effects of seismic loads.

• 콘크리트학회논문집
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• 제15권6호
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• pp.894-901
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• 2003

본 연구의 목적은 비내진 상세를 가진 RC 구조물의 이력거동 특성과 내진성능 및 특성을 알아보기 위한 것이다. 이를 위해 10층 RC구조물의 내 외부 접합부를 선정하여 슬래브의 유무, 접합부내에서의 전단철근 유무, 외부 접합부의 보 하부 주근의 정착방향에 따라 6개의 1/3 축소 실험체를 만들어 반복횡하중 실험을 수행하였다. 실험결과 내부 접합부의 경우 슬래브의 유무에 관계없이 내진 비내진 상세의 상이에 따른 강도나 연성 능력의 변화는 크지 않는 것으로 나타났고, 외부 접합부의 경우 내부 접합부와는 달리 접합부 전단 보강근의 유무뿐만 아니라 하단 주철근 정착방향에서도 차이가 나기 때문에 비내진 상세의 강도나 연성 능력이 각각 10∼20%와 27% 정도 작은 것으로 나타났다. 또, 비내진 상세를 가지는 경우 국부 변형이 한 곳에서 집중되어 크게 나타남을 알 수 있으며, 슬래브가 있음으로 인해 휨에 의한 회전각을 억제하고 상향 전단변형을 억제하는 것으로 나타났다. 한편 보-기둥 접합부에서의 전단 보강근은 전단변형률에 거의 영향을 끼치지 않는 것으로 나타났다.

• 한국구조물진단유지관리공학회 논문집
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• 제15권3호
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• pp.106-115
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• 2011

본 연구에서는 비선형 지진응답해석을 이용하여 유도된 전단 및 휨파괴형 부재가 혼합된 저층 철근콘크리트(RC) 건물의 비선형 요구내력스펙트럼을 수식화하여, 특정 연성률 별로 지진입력수준과 내진성능잔존률을 산정하여, 건물의 지진손상정도를 정량적으로 평가 가능한 새로운 내진성능 평가법을 제안하였다. 또한 저층 RC 건물을 대상으로 본 연구의 내진성능 평가법을 적용하여 평가한 결과와 보다 정밀한 부재수준의 비선형 동적해석을 실시하여 그 결과를 각각 비교 검토함과 동시에, 내진진단기준에서 입력지진동 0.2g 수준에 대해서 구조체에 대규모이상의 지진피해를 막기 위한 임계값으로 설정한 내진성능판정지표값 (Es=0.6)과의 상관관계를 분석하여 본 연구에서 제안한 내진성능 평가법의 타당성 및 그 적용가능성을 검증하였다. 본 평가법은 비선형해석 또는 능력스펙트럼법 등의 상세 내진성능 평가법을 수행하지 않고도 대상건물에 대한 연성률 단계별의 입력지진 수준, 지진손상도를 정량적으로 평가할 수 있다. 향후 전단 및 휨파괴형 부재가 혼합된 저층 RC 건물의 내진성능을 효과적으로 평가하기 위한 자료로서 활용이 가능하다고 판단된다.

• Geomechanics and Engineering
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• 제31권5호
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• pp.439-452
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• 2022

A forecast of slope behavior during catastrophic events, such as earthquakes is crucial to recognize the risk of slope failure. This paper endeavors to eliminate the significant supposition of predefined slip surfaces in the slope stability analysis, which questions the relevance of simple conventional methods under seismic conditions. To overcome such limitations, a methodology dependent on the slip line hypothesis, which permits an automatic generation of slip surfaces, is embraced to trace the extreme slope face under static and seismic conditions. The effect of earthquakes is considered using the pseudo-static approach. The current outcomes developed from a parametric study endorse a non-linear slope surface as the extreme profile, which is in accordance with the geomorphological aspect of slopes. The proposed methodology is compared with the finite element limit analysis to ensure credibility. Through the design charts obtained from the current investigation, the stability of slopes can be assessed under seismic conditions. It can be observed that the extreme slope profile demands a flat configuration to endure the condition of the limiting equilibrium at a higher level of seismicity. However, a concurrent enhancement in the shear strength of the slope medium suppresses this tendency by offering greater resistance to the seismic inertial forces induced in the medium. Unlike the traditional linear slopes, the extreme slope profiles mostly exhibit a steeper layout over a significant part of the slope height, thus ensuring a more optimized solution to the slope stability problem. Further, the susceptibility of the Longnan slope failure in the Huining-Wudu seismic belt is predicted using the current plasticity approach, which is found to be in close agreement with a case study reported in the literature. Finally, the concept of equivalent single or multi-tiered planar slopes is explored through an example problem, which exhibits the appropriateness of the proposed non-linear slope geometry under actual field conditions.

• Structural Engineering and Mechanics
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• 제65권6호
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• pp.721-730
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• 2018

This paper aims to inspect the effectiveness of the Simple Adaptive Control Method (SACM) to control the response of asymmetric buildings with rotationally non-linear behavior under seismic loads. SACM is a direct control method and was previously used to improve the performance of linear and non-linear structures. In most of these studies, the modeled structures were two-dimensional shear buildings. In reality, the building plans might be asymmetric, which cause the buildings to experience torsional motions under earthquake excitation. In this study, SACM is used to improve the performance of asymmetric buildings, and unlike conventional linear models, the non-linear inertial coupling terms are considered in the equations of motion. SACM performance is compared with the Linear Quadratic Regulator (LQR) algorithm. Moreover, the LQR algorithm is modified, so that it is appropriate for rotationally non-linear buildings. Active tuned mass dampers are used to improve the performance of the modeled buildings. The results show that SACM is successful in reducing the response of asymmetric buildings with rotationally non-linear behavior under earthquake excitation. Furthermore, the results of the SACM were very close to those of the LQR algorithm.

• 한국지진공학회논문집
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• 제27권5호
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• pp.213-220
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• 2023

Seismic fragility curves play a crucial role in assessing potential seismic losses and predicting structural damage caused by earthquakes. This study compares non-sampling-based methods of seismic fragility curve derivation, particularly the probabilistic seismic demand model (PSDM) and finite element reliability analysis (FERA), both of which require employing sophisticated finite element analysis to evaluate and predict structural damage caused by earthquakes. In this study, a three-dimensional finite element model of API 5L X65, a buried gas pipeline widely used in Korea, is constructed to derive seismic fragility curves. Its seismic vulnerability is assessed using nonlinear time-history analysis. PSDM and a FERA are employed to derive seismic fragility curves for comparison purposes, and the results are verified through a comparison with those from the Monte Carlo Simulation (MCS). It is observed that the fragility curves obtained from PSDM are relatively conservative, which is attributed to the assumption introduced to consider the uncertainty factors. In addition, this study provides a comprehensive comparison of seismic fragility curve derivation methods based on sophisticated finite element analysis, which may contribute to developing more accurate and efficient seismic fragility analysis.

• Structural Engineering and Mechanics
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• 제43권4호
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• pp.545-560
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• 2012

Design codes provide the minimum requirements for the design of code-compliant structures to ensure the safety of the life and property. As for code-exceeding buildings, the requirements for design are not sufficient and the approval of such structures is vague. In mainland China in recent years, a large number of code-exceeding tall buildings, whether their heights exceed the limit for the respective structure type or the extent of irregularity is violated, have been constructed. Performance-based seismic design (PBSD) approach has been highly recommended and become necessary to demonstrate the performance of code-exceeding tall buildings at least equivalent to code intent of safety. This paper proposes the general methodologies of performance-based seismic analysis and design of code-exceeding tall buildings in Mainland China. The PBSD approach proposed here includes selection of performance objectives, determination of design philosophy, establishment of design criteria for structural components and systems consistent with the desirable and transparent performance objectives, and seismic performance analysis and evaluation through extensive numerical analysis or further experimental study if necessary. The seismic analysis and design of 101-story Shanghai World Financial Center Tower is introduced as a typical engineering example where the PBSD approach is followed. The example demonstrates that the PBSD approach is an appropriate way to control efficiently the seismic damage on the structure and ensure the predictable and safe performance.