• Steel and Composite Structures
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• 제22권3호
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• pp.497-520
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• 2016

The confined concrete stress-strain curves utilised in computational models of concrete-filled steel tubular (CFST) columns can have a significant influence on the accuracy of the predicted behaviour. A generic model is proposed for predicting the stress-strain behaviour of confined concrete in short circular, elliptical and octagonal CFST columns subjected to axial compression. The finite element (FE) analysis is carried out to simulate the concrete confining pressure in short circular, elliptical and octagonal CFST columns. The concrete confining pressure relies on the geometric and material parameters of CFST columns. The post-peak behaviour of the concrete stress-strain curve is determined using independent existing experimental results. The strength reduction factor is derived for predicting the descending part of the confined concrete behaviour. The fibre element model is developed for the analysis of circular, elliptical and octagonal CFST short columns under axial loading. The FE model and fibre element model accounting for the proposed concrete confined model is verified by comparing the computed results with experimental results. The ultimate axial strengths and complete axial load-strain curves obtained from the FE model and fibre element model agree reasonably well with experimental results. Parametric studies have been carried out to examine the effects of important parameters on the compressive behaviour of short circular, elliptical and octagonal CFST columns. The design model proposed by Liang and Fragomeni (2009) for short circular, elliptical and octagonal CFST columns is validated by comparing the predicted results with experimental results.

• 지질공학
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• 제11권2호
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• pp.175-190
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• 2001

오염된 연약지반에 편재하중이 작용하는 경우에 있어서 지반의 소성화에 따른 측방유동에 대한 거동을 규명하기 위하여 기존의 이론적인 배경을 고찰하고, 모형실험을 통하여 실측한 결과를 상호 비교.분석하였다. 모형실험은 모형재하장치인 토조와 재하틀 및 재하판을 제작하여 토조 안에 함수비를 일정하게 유지한 상태에서 자연지반의 시료와 오염물질을 점진적으로 증가시킨 지반시료에 대하여 일정한 시간 간격으로 편재하중을 증가시키면서 침하량과 측방변위량 및 융기량 등을 관측하였다. 그 결과 한계하중은 실험값이 Tschebotarioff(q$_{cr}$=3.0$_{cu}$)의 제안값과 Meyerhof(q$_{cr}$=(B/2H+$\pi$/2)$_{cu}$)의 제안값에 근접하여 q$_{cr}$=2.78$_{cu}$값을 나타냈고, 극한하중은 Prandtl의 제안값에 근접하여 q$_{ult}$=4.84$_{cu}$값을 나타냈다. 측방유동압은 Matsui.Hong의 이론식에 의해서 산정함이 비교적 적절하며, 측방유동압의 최대값은 토층두께(H)의 0.3H 부근에서 발생하였으며, 복합형과 Poulos의 분포형태 및 오염되지 않는 연약점토(CL, CH)지반 보다 지표면측으로 상승하여 발생하였다. 안정관리방법은 지반의 측방유동에 의한 소성변위량을 많이 이용하고 있는 부영.교본, 자전.관구, 송미.천촌 등의 안정관리도에 적용한 결과 송미.천촌의{S$_{v}$-(Y$_{m}$/S$_{v}$)}관리도와 자전.관구의 {(q/Y$_{m}$)-q}관리도에서 얻어진 극한하중은 하중-침하량곡선 (q-S$_{v}$)에서 얻어진 극한하중 보다 적은 경향을 나타냈다.

• Wind and Structures
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• 제28권2호
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• pp.71-87
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• 2019

The yaw and interference effects of blades affect aerodynamic performance of large wind turbine system significantly, thus influencing wind-induced response and stability performance of the tower-blade system. In this study, the 5MW wind turbine which was developed by Nanjing University of Aeronautics and Astronautics (NUAA) was chosen as the research object. Large eddy simulation on flow field and aerodynamics of its wind turbine system with different yaw angles($0^{\circ}$, $5^{\circ}$, $10^{\circ}$, $20^{\circ}$, $30^{\circ}$ and $45^{\circ}$) under the most unfavorable blade position was carried out. Results were compared with codes and measurement results at home and abroad, which verified validity of large eddy simulation. On this basis, effects of yaw angle on average wind pressure, fluctuating wind pressure, lift coefficient, resistance coefficient,streaming and wake characteristics on different interference zone of tower of wind turbine were analyzed. Next, the blade-cabin-tower-foundation integrated coupling model of the large wind turbine was constructed based on finite element method. Dynamic characteristics, wind-induced response and stability performance of the wind turbine structural system under different yaw angle were analyzed systematically. Research results demonstrate that with the increase of yaw angle, the maximum negative pressure and extreme negative pressure of the significant interference zone of the tower present a V-shaped variation trend, whereas the layer resistance coefficient increases gradually. By contrast, the maximum negative pressure, extreme negative pressure and layer resistance coefficient of the non-interference zone remain basically same. Effects of streaming and wake weaken gradually. When the yaw angle increases to $45^{\circ}$, aerodynamic force of the tower is close with that when there's no blade yaw and interference. As the height of significant interference zone increases, layer resistance coefficient decreases firstly and then increases under different yaw angles. Maximum means and mean square error (MSE) of radial displacement under different yaw angles all occur at circumferential $0^{\circ}$ and $180^{\circ}$ of the tower. The maximum bending moment at tower bottom is at circumferential $20^{\circ}$. When the yaw angle is $0^{\circ}$, the maximum downwind displacement responses of different blades are higher than 2.7 m. With the increase of yaw angle, MSEs of radial displacement at tower top, downwind displacement of blades, internal force at blade roots all decrease gradually, while the critical wind speed decreases firstly and then increases and finally decreases. The comprehensive analysis shows that the worst aerodynamic performance and wind-induced response of the wind turbine system are achieved when the yaw angle is $0^{\circ}$, whereas the worst stability performance and ultimate bearing capacity are achieved when the yaw angle is $45^{\circ}$.

• 지질공학
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• 제3권2호
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• pp.177-190
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• 1993

연약지반에서 성토나 교대등에 의한 편재하중이 작용하게 되면 지반중에는 침하, 측방변위, 융기 및 전단파괴 등의 큰 소성적인 전단변형이 발생하여 지반 및 구조물에 큰 피해를 주는 것을 많이 볼 수 있다. 본 연구는 이러한 연약지반에서 편재하중에 의한 지반의 제반변형에 대한 거동을 연구하기 위하여 기존의 이론적인 배경을 조사하고 모형실험을 통한 실측치를 이용하여 서로 비교분석하여 보았다. 모형실험은 먼저 모형재하장치를 제작하고 토조안에 연약한 흙시료를 채워 비배수상태에서 일정한 시간간격으로 하중단계를 증가시켜 가면서 변형의 상태를 관측하였다. 실험결과를 토대로 지반특성과 변위량의 관계, 한계하중 및 극한지지력, 지반의 소성유동의 상태 및 측방 유동압의 검토 등을 상세하게 분석하여 기존의 이론과 비교해 봄으로써 실제 연약지반상에서의 측방변형에 대한 원인을 규명함으로써 그로 인한 피해를 사전에 방지하고자 한다.

• International Journal of Naval Architecture and Ocean Engineering
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• 제6권4호
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• pp.1130-1147
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• 2014

Large size ships have a very flexible construction resulting in low resonance frequencies of the structural eigen-modes. This feature increases the dynamic response of the structure on short period waves (springing) and on impulsive wave loads (whipping). This dynamic response in its turn increases both the fatigue damage and the ultimate load on the structure; these aspects illustrate the importance of including the dynamic response into the design loads for these ship types. Experiments have been carried out using a segmented scaled model of a container ship in a Seakeeping Basin. This paper describes the development of the model for these experiments; the choice was made to divide the hull into six rigid segments connected with a flexible beam. In order to model the typical feature of the open structure of the containership that the shear center is well below the keel line of the vessel, the beam was built into the model as low as possible. The model was instrumented with accelerometers and rotation rate gyroscopes on each segment, relative wave height meters and pressure gauges in the bow area. The beam was instrumented with strain gauges to measure the internal loads at the position of each of the cuts. Experiments have been carried out in regular waves at different amplitudes for the same wave period and in long crested irregular waves for a matrix of wave heights and periods. The results of the experiments are compared to results of calculations with a linear model based on potential flow theory that includes the effects of the flexural modes. Some of the tests were repeated with additional links between the segments to increase the model rigidity by several orders of magnitude, in order to compare the loads between a rigid and a flexible model.

• Wind and Structures
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• 제31권2호
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• pp.143-152
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• 2020

The wind design of buildings is typically based on strength provisions under ultimate loads. This is unlike the ductility-based approach used in seismic design, which allows inelastic actions to take place in the structure under extreme seismic events. This research investigates the application of a similar concept in wind engineering. In seismic design, the elastic forces resulting from an extreme event of high return period are reduced by a load reduction factor chosen by the designer and accordingly a certain ductility capacity needs to be achieved by the structure. Two reasons have triggered the investigation of this ductility-based concept under wind loads. Firstly, there is a trend in the design codes to increase the return period used in wind design approaching the large return period used in seismic design. Secondly, the structure always possesses a certain level of ductility that the wind design does not benefit from. Many technical issues arise when applying a ductility-based approach under wind loads. The use of reduced design loads will lead to the design of a more flexible structure with larger natural periods. While this might be beneficial for seismic response, it is not necessarily the case for the wind response, where increasing the flexibility is expected to increase the fluctuating response. This particular issue is examined by considering a case study of a sixty-five-story high-rise building previously tested at the Boundary Layer Wind Tunnel Laboratory at the University of Western Ontario using a pressure model. A three-dimensional finite element model is developed for the building. The wind pressures from the tested rigid model are applied to the finite element model and a time history dynamic analysis is conducted. The time history variation of the straining actions on various structure elements of the building are evaluated and decomposed into mean, background and fluctuating components. A reduction factor is applied to the fluctuating components and a modified time history response of the straining actions is calculated. The building components are redesigned under this set of reduced straining actions and its fundamental period is then evaluated. A new set of loads is calculated based on the modified period and is compared to the set of loads associated with the original structure. This is followed by non-linear static pushover analysis conducted individually on each shear wall module after redesigning these walls. The ductility demand of shear walls with reduced cross sections is assessed to justify the application of the load reduction factor "R".

• 한국지반공학회논문집
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• 제20권3호
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• pp.107-117
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• 2004

본 연구에서는 폐타이어를 활용하여 새롭게 고안한 타이어셀 매트의 모래지반 보강효과를 알아보기 위하여 다양한 조건의 평판재하시험을 수행하였다. 계하시험조건은 셀 간의 연결을 위한 볼트 수, 상대밀도, 복토두께, 보강층수, 타이어셀 매트 폭을 변수로 보강효과를 조사하였다. 재하시험 결과 연결용 볼트의 수는 지지력에 큰 영향을 미치지 않는 것으로 나타났으며 1개의 볼트로 주어진 하중을 충분히 견딜 수 있었다. 보강토의 극한지지력과 무보강토의 극한지지력의 비로 정의되는 지지력비(BCR)는 낮은 밀도에서 최대값을 나타내었다. 또한 극한상태에서의 침하감소효과도 낮은 밀도에서 큰 것으로 나타났다. 복토에 따른 보강효과는 복토두께가 1.0B이내에서 보강효과를 얻을 수 있었으나 그 이상에서는 보강효과가 나타나지 않았다. 보강층의 간격이 재하판폭의 0.4내지 0.5배일 경우 보강효과는 보강층이 2층일 때까지는 보강효과가 있으나 3층 이상에서는 효과가 없는 것으로 나타났다. 특히 보강층이 1개층일 때 지지력 증가 효과가 크며 2개층으로 증가함에 따라 증가율은 저하되는 것으로 나타났다. 타이어셀 매트폭이 2.0B에서 최대지지력을 보였으나 매트폭의 영향은 타이어셀의 강성이 크기 때문에 미소하였다. 타이어셀 매트의 지반보강효과는 문헌상의 상업용 지오웹과 비교하여 뛰어난 것으로 나타났다.