• 한국지진공학회논문집
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• 제14권6호
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• pp.55-65
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• 2010

본 실험 연구의 목적은 횡방향 정적가력을 통하여 2층 R.C 전단벽식 구조의 내진성능을 평가하는 것이다. 본 연구의 실험체는 대상 건물의 개구부를 가지는 T자형 벽체 1층과 2층의 일부분을 대상으로 실물크기의 3/5 크기정도로 축소하였고, 인방보의 유 무를 실험변수로한 2개의 실험체를 제작하여 횡방향의 정적가력 실험을 수행하였다. 인방보 유무에 따른 벽체의 구조적 성능 및 거동의 차이를 비교한 결과, 인방보가 있는 실험체가 인방보가 없는 실험체보다 최대내력과 연성능력 등의 내진성능이 우수한 것으로 판단되었다.

• Structural Engineering and Mechanics
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• 제24권4호
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• pp.463-478
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• 2006

The design of structural frameworks for buildings is constantly evolving and is dependent on regional issues such as loading and constructability. One of the most promising recent developments for low to medium rise construction in terms of efficiency of construction, robustness and aesthetic appearance utilises concrete-filled steel tubular sections as the columns in a moment-resisting frame. These are coupled to rigid or semi-rigid connections to composite steel-concrete beams. This paper includes the results of a pilot experimental programme leading towards the development of economical, reliable connections that are easily constructed for this type of frame. The connections must provide the requisite strength, stiffness and ductility to suit gravity loading conditions as well as gravity combined with the governing lateral wind or earthquake loading. The aim is to develop connections that are stiffer, less expensive and easier to construct than those in current use. A proposed fabricated T-stub connection is to be used to connect the beam flanges and the column. These T-stubs are connected to the column using "blind bolts" with extensions, allowing installation from the outside of the tube. In general, the use of the extensions results in a dramatic increase in the strength and stiffness of the T-stub to column connection in tension, since the load is shared between membrane action in the tube wall and the anchorage of the bolts through the extensions into the concrete.

• Geomechanics and Engineering
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• 제10권5호
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• pp.635-655
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• 2016

The effects of reinforcement on the horizontal and vertical deformations of geosynthetic reinforced retaining walls are investigated under a well-known seismic load (San Jose earthquake, 1955). Retaining walls are designed with internal and external stability (with appropriate factor of safety) and deformation is chosen as the main parameter for describing the wall behavior under seismic load. Retaining walls with various heights (6, 8, 10, 12 and 14 meter) are optimized for geosynthetics arrangement, and modeled with a finite element method. The stress-strain behavior of the walls under a well-known loading type, which has been used by many previous researchers, is investigated. A comparison is made between the reinforced and non-reinforced systems to evaluate the effect of reinforcement on decreasing the deformation of the retaining walls. The results show that the reinforcement system significantly controls the deformation of the top and middle of the retaining walls, which are the critical points under dynamic loading. It is shown that the optimized reinforcement system in retaining walls under the studied seismic loading could decrease horizontal and vertical deformation up to 90% and 40% respectively.

• 대한토목학회논문집
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• 제10권3호
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• pp.87-98
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• 1990

본 연구에서는 Elman둥이 상시하중의 경우에 대해 제안한 새로운 형태의 캔키레바식 옹벽 설계방식을 지진하중을 고려한 경우에까지 확대적용하여 예상되는 효율성을 설계예를 통해 분석하였으며, 좀더 안전한 측에서의 셜계검토를 위해 캔티레바식 옹벽의 자체중량 및 뒷채움 일부분의 모래중량에 의한 수평관성력 등을 포함하는 분석법이 제시되었다. 또한 한계 평형상태가 아닌 다양한 토압상태에서의 설계검토를 목적으로 Mononobe-Okabe 동적토압계산식을 변형하였다. 결론적으로, 기초슬래브의 밑면이 경사진 캔티레바식 옹벽형태가 내진설계에 있어서 가장 효율적임을 알 수 있었다. 즉 다른 형태의 캔티레바식 옹벽에 비해, 활동에 대한 안전율은 가장 크면서도 옹벽축조에 관련된 콘크리트량, 굴착량 및 뒷채움 모래의 양은 가장 절감되는 효과가 있음을 알 수 있었다. 후단부분을 $45^{\circ}$만큼 경사지게하는 캔티레바식 옹벽형태는, 상시하중 및 비교적 낮은 수준의 지진에 대해서는 효율성이 예상되나, 수평진도가 커짐에 따라 이와 같은 효율성을 기대할 수 없음을 알 수 있었다. 이에대한 주된 원인은, 옹벽 후단부분에 작용하는 수평발생토압합력의 감소율이 수평진도가 커짐에 따라 점차적으로 작아지는데 있다. 이외에도 기초슬레브의 밑면이 경사진 캔터레바식 옹벽에 관련된 설계도표를, 뒷채움 및 기초지반모래의 내부마찰각 크기, 지진하중시의 활동에 대한 안전율 규정 등을 각각 달리하여 제시하였다.

• Computers and Concrete
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• 제22권1호
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• pp.123-132
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• 2018

Reinforced concrete (RC) columns which are the main vertical structural members are exposed to several static and dynamic effects such as earthquake and wind. However, impact loading that is sudden impulsive dynamic one is the most effective loading type acting on the RC columns. Impact load is a kind of impulsive dynamic load which is ignored in the design process of RC columns like other structural members. The behavior of reinforced concrete columns under impact loading is an area of research that is still not well understood; however, work in this area continues to be motivated by a broad range of applications. Examples include reinforced concrete structures designed to resist accidental loading scenarios such as falling rock impact; vehicle or ship collisions with buildings, bridges, or offshore facilities; and structures that are used in high-threat or high-hazard applications, such as military fortification structures or nuclear facilities. In this study, free weight falling test setup is developed to investigate the behavior effects on RC columns under impact loading. For this purpose, eight RC column test specimens with 1/3 scale are manufactured. While drop height and mass of the striker are constant, application point of impact loading, stirrup spacing and concrete compression strength are the experimental variables. The time-history of the impact force, the accelerations of two points and the displacement of columns were measured. The crack patterns of RC columns are also observed. In the light of experimental results, low-velocity impact behavior of RC columns were determined and interpreted. Besides, the finite element models of RC columns are generated using ABAQUS software. It is found out that proposed finite element model could be used for evaluation of dynamic responses of RC columns subjected to low-velocity impact load.

• Earthquakes and Structures
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• 제17권1호
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• pp.115-129
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• 2019

The effectiveness of an innovative method for the earthquake-resistant rehabilitation of existing poorly detailed reinforced concrete (RC) structures is experimentally investigated herein. Eight column subassemblages were subjected to earthquake-type loading and their hysteretic behaviour was evaluated. Four of the specimens were identical and representative of columns found in RC structures designed in the 1950s-70s period for gravity load only. These original specimens were subjected to cyclic lateral deformations and developed brittle failure mechanisms. Three of the damaged specimens were subsequently retrofitted with innovative high-strength steel fiber-reinforced concrete (HSSFC) jackets. The main variables examined were the jacket width and the contribution of mesh steel reinforcement in the seismic performance of the enhanced columns. The influence of steel fiber volume fraction was also examined using test results of a previous work of Tsonos et al. (2017). The fourth earthquake damaged subassemblage was strengthened with a conventional RC jacket and was subjected to the same lateral displacement history as the other three retrofitted columns. The seismic behaviour of the subassemblages strengthened according to the proposed retrofit scheme was evaluated with respect to that of the original specimens and that of the column strengthened with the conventional RC jacket. Test results clearly demonstrated that the HSSFC jackets effectively prevented the development of shear failure mechanisms, while ensuring a ductile seismic response similar to that of the subassemblage retrofitted with the conventional RC jacket. Ultimately, an indisputable superiority in the overall seismic performance of the strengthened columns was achieved with respect to the original specimens.

• 한국지반공학회논문집
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• 제20권5호
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• pp.145-159
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• 2004

본 연구에서는 지진시 지반의 안정성 평가시, 진동시험에 기초하여 액상화 발생가능성 여부를 판정하는 상세평가법을 개발하였다. 개발된 평가법에서는 기존의 평가법이 지진을 단순히 정현하중화하는 등가전단응력개념에 기초한점과는 달리, 지진의 최대가속도, 유효지속시간, 지진형태, 그리고 지진규모 등 다양한 지진영향인자가 고려될 수 있도록 실지진기록 입력의 지반응답해석을 포함하도록 하였다. 지반의 고유한 저항특성을 응력-변형률 시험 결과로부터 액상화 전환시점까지의 누적 소성 전단변형률로 하였으며 이와 연계하여 지진의 액상화 발생특성을 지반응답해석을 통해 획득 가능한 전단변형률 시간이력곡선에 기초하도록 하였다. 이때, 액상화를 유발시키는 실지진기록의 특성분석을 위해 실지진하중 재하의 진동삼축시험을 수행하였다. 시험결과, 충격형 지진인 경우, 지진기록의 최대하중이 재하된 직후, 과잉간극수압이 급진적으로 발전하며 액상화가 발생하는 것으로 나타났으며 진동형 지진의 경우에는 최대하중이 재하된 경우, 눈에 띄는 과잉간극수압의 변화가 관찰되었으며 이후, 일정수준 이상의 큰 하중재하시 액상화가 발생하였다. 이로부터 액상화 발생에 가장 큰 영향인자는 최대하중인 것을 알 수 있었으며 진동형 지진형태의 경우, 일정수준 이상의 후속하중에 대한 고려가 필요함을 알 수 있었다. 이상의 결과로부터 본 평가법에서는 우선적으로 충격형 지진에 한하여 사용할 것을 제안하며 이때, 최대 전단변형률까지의 시간이력곡선으로부터 소성 전단변형률을 누적계산하여 이를 해당입력지진의 액상화 발생특성치로 정하였다. 기존의 등가응력개념에 기초한 상세평가법과의 비교를 통한 타당성 분석결과, 본 평가법은 기존의 상세평가법보다 유효응력경로 및 응력-변형률 상관곡선 등 실제적인 지반거동변화에 관한 진동시험결과에 기초하여 지반의 고유특성을 결정하고 지반응답해석을 통해 증폭현상을 포함한 지반 내 지진거동변화와 지진시간이력이 보유하고 있는 지진특성을 충분히 반영하고 있으므로 신뢰성 높은 액상화 상세평가가 가능할 것으로 판단된다.

• 한국지진공학회논문집
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• 제14권4호
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• pp.61-71
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• 2010

프리캐스트 콘크리트 골조에서 실물크기의 보-기둥 접합부 실험체 5개를 대상으로 반복가력 실험을 수행하였다. 지진하중을 받는 골조를 대상으로 1개의 일체식 실험체와 4개의 프리캐스트 실험체를 포함하여 5개의 1/2스케일의 내부 보-기둥 접합부를 대상으로 하였다.주요 변수는 보의 구조적 연속성을 확보하기 위한 접합부의 형태와 접합부의 특별한 보강형태(섬유콘크리트와 횡보강근)로 하였다. 실험체는 강기둥-약보 개념에 따라 설계하였다. 보 철근은 접합부에 큰 비탄성 전단력이 작용할 경우 보에 소성힌지가 발생하도록 계획하였다. 접합부의 성능평가는 접합부의 강도, 강성, 에너지 소산능력과 층간변위비로 평가하였다. 실험결과 실험체의 파괴는 보의 소성힌지부에서 파괴되었다. 보-기둥 접합부의 성능은 대체적으로 우수한 것으로 나타났다. 접합부의 강도는 일체식 RC 구조의 비해 1.15배 정도 향상되었다. 층간변위 3.5%때의 강도에서 실험체는 ECC의 인장변형능력과 철골연결재의 항복에 의해 연성거동 하였다.

• Steel and Composite Structures
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• 제12권4호
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• pp.353-379
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• 2012

The accuracy of the 30% and SRSS rules, commonly used to estimate the combined response of structures, and some related issues, are studied. For complex systems and earthquake loading, the principal components give the maximum seismic response. Both rules underestimate the axial load by about 10% and the COV of the underestimation is about 20%. Both rules overestimate the base shear by about 10%. The uncertainty in the estimation is much larger for axial load than for base shear, and, for axial load, it is much larger for inelastic than for elastic behavior. The effect of individual components may be highly correlated, not only for normal components, but also for totally uncorrelated components. The rules are not always inaccurate for large values of correlation coefficients of the individual effects, and small values of such coefficients are not always related to an accurate estimation of the response. Only for perfectly uncorrelated harmonic excitations and elastic analysis of SDOF systems, the individual effects of the components are uncorrelated and the rules accurately estimate the combined response. In the general case, the level of underestimation or overestimation depends on the degree of correlation of the components, the type of structural system, the response parameter, the location of the structural member and the level of structural deformation. The codes should be more specific regarding the application of these rules. If the percentage rule is used for MDOF systems and earthquake loading, at least a value of 45% should be used for the combination factor.

• Geomechanics and Engineering
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• 제27권5호
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• pp.465-479
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• 2021

One of the important causes of building and infrastructure failure, such as bridges on pile foundations, is the placement of the piles in liquefiable soil that can become unstable under seismic loads. Therefore, the overarching aim of this study is to investigate the seismic behavior of a soil-pile system in liquefiable soil using three-dimensional numerical FEM analysis, including soil-pile interaction. Effective parameters on concrete pile response, involving the pile diameter, pile length, soil type, and base acceleration, were considered in the framework of finite element non-linear dynamic analysis. The constitutive model of soil was considered as elasto-plastic kinematic-isotropic hardening. First, the finite element model was verified by comparing the variations on the pile response with the measured data from the centrifuge tests, and there was a strong agreement between the numerical and experimental results. Totally 64 non-linear time-history analyses were conducted, and the responses were investigated in terms of the lateral displacement of the pile, the effect of the base acceleration in the pile behavior, the bending moment distribution in the pile body, and the pore pressure. The numerical analysis results demonstrated that the relationship between the pile lateral displacement and the maximum base acceleration is non-linear. Furthermore, increasing the pile diameter results in an increase in the passive pressure of the soil. Also, piles with small and big diameters are subjected to yielding under bending and shear states, respectively. It is concluded that an effective stress-based ground response analysis should be conducted when there is a liquefaction condition in order to determine the maximum bending moment and shear force generated within the pile.