• 한국지진공학회논문집
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• 제13권1호
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• pp.45-52
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• 2009

본 연구의 목적은 일정 축하중과 반복횡하중 하에서 탄소섬유시트와 비좌굴 가새로 보강된 보-기둥 시험체의 횡방향 거동 평가를 통하여 사용된 보강 방법의 구조적 성능을 검증하는 것이다. 세 개의 시험체를 비보강, 탄소섬유보강, 탄소섬유와 비좌굴 가새 보강 방법을 각각 적용하여 제작하였다. 변위에 따른 최대, 최소하중은 하중-변위 관계를 분석함으로써 평가되어지며, 하중과 강성의 관계는 비교구간의 유효강성 분석에 의해 평가된다. 실험의 수행 결과, 보강을 하지 않은 시험체에 비하여 보강을 적용한 시험체는 최대허용하중과 유효강성, 철근 항복 시 재하 횡하중, 변위연성비 등에서 상대적으로 우수한 성능을 보였다.

• Steel and Composite Structures
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• 제27권6호
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• pp.691-702
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• 2018

This paper presents experimental and analytical results of fiber reinforced polymer (FRP) confined steel tubular columns under transverse impact loads. Influences of applied impact energy, thickness of FRP jacket and impact position were discussed in detail, and then the impact responses of FRP confined steel tubes were compared with bare steel tubes. The test results revealed that the FRP jacket contributes to prevent outward buckling deformation of steel at the clamped end and inward buckling of steel at the impact position. For the given applied impact energy, specimens wrapped with one layer and three layers of FRP have the lower peak impact loads than those of the bare steel tubes, whereas specimens wrapped with five layers of FRP exhibit the higher peak impact loads. All the FRP confined steel tubular specimens displayed a longer duration time than the bare steel tubes under the same magnitude of impact energy, and the specimen wrapped with one layer of FRP had the longest duration time. In addition, increasing the applied impact energy leads to the increase of peak impact load and duration time, whereas increasing the distance of impact position from the clamped end results in the decrease of peak impact load and the increase of duration time. The dynamic analysis software Abaqus Explicit was used to simulate the mechanical behavior of FRP confined steel tubular columns, and the numerical results agreed well with the test data. Analytical solution for lateral displacement of an equivalent cantilever beam model subjected to impact load was derived out. Comparison of analytical and experimental results shows that the maximum displacement can be precisely predicted by the present theoretical model.

• Structural Engineering and Mechanics
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• 제65권5호
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• pp.573-585
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• 2018

This article presents strain gradient elasticity-based procedures for static bending, free vibration and buckling analyses of functionally graded rectangular micro-plates. The developed method allows consideration of smooth spatial variations of length scale parameters of strain gradient elasticity. Governing partial differential equations and boundary conditions are derived by following the variational approach and applying Hamilton's principle. Displacement field is expressed in a unified way to produce numerical results in accordance with Kirchhoff, Mindlin, and third order shear deformation theories. All material properties, including the length scale parameters, are assumed to be functions of the plate thickness coordinate in the derivations. Developed equations are solved numerically by means of differential quadrature method. Proposed procedures are verified through comparisons made to the results available in the literature for certain limiting cases. Further numerical results are provided to illustrate the effects of material and geometric parameters on bending, free vibrations, and buckling. The results generated by Kirchhoff and third order shear deformation theories are in very good agreement, whereas Mindlin plate theory slightly overestimates static deflection and underestimates natural frequency. A rise in the length scale parameter ratio, which identifies the degree of spatial variations, leads to a drop in dimensionless maximum deflection, and increases in dimensionless vibration frequency and buckling load. Size effect is shown to play a more significant role as the plate thickness becomes smaller compared to the length scale parameter. Numerical results indicate that consideration of length scale parameter variation is required for accurate modelling of graded rectangular micro-plates.

• 한국자동차공학회논문집
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• 제13권5호
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• pp.171-180
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• 2005

Bending performances of aluminum square tube beams reinforced by aluminum plates under three point bending loads have been evaluated using experimental tests combined with theoretical and finite element analyses. A finite element simulation for the three-point bending test was performed. Basic properties of aluminum materials used for initial input data of the finite element simulation were obtained from the true stress-true strain curves of specimens which had been extracted from the Al tube beams. True stresses were determined from applied loads and cross-sectional area records of a tensile specimen with a rectangular cross-section by real-time photographing, and true strains were obtained from in-situ local elongation measurements of the specimen gage portion by the multi-point scanning laser extensometer. Six kinds of aluminum tube beam specimens adhered by aluminum plates were employed fur the bending test. The bending deformation behaviors up to the maximum load described by the numerical simulation were in good agreement with experimental ones. After passing the maximum load, reinforcing plate was debonded from the aluminum tube beam. An aluminum tube beam strengthened by aluminum plate on the upper web showed an excellent bending capability.

• Composites Research
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• 제30권2호
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• pp.132-137
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• 2017

본 연구에서는 카본/BMI 면재와 노멕스 허니콤 코어를 가지는 샌드위치 포팅 체결부의 다양한 설계변수에 대한 파손특성 연구를 수행하였다. 샌드위치 시편은 코어 높이, 면재 두께 및 밀도에 따라 총 6종류가 제작되었고, 이중 1종류의 시편에 대해 온/습도 효과를 보기 위해 환경 조건이 가해졌다. 시험 결과 밀도가 $64kg/m^3$ 코어를 제외한 모든 시편에서 코어의 전단좌굴이 초기 파손모드로 나타났으며, 이후 하중을 지지하다 윗면재 파손과 동시에 아랫면재에 볼트가 파고드는 파손형상이 나타났다. 하지만 밀도에 의해 높은 강성을 가지는 시편의 경우 초기 전단좌굴 발생 없이 윗면재와 코어의 계면파손에 의해 낮은 최대파손하중을 나타냈다. 샌드위치 시편의 환경적 영향 평가를 위해 수행된 ETW1($82^{\circ}C$, Wet)과 ETW2($177^{\circ}C$, Wet)의 경우 RTD($24^{\circ}C$, Dry) 조건과 확연히 다른 초기 파손모드를 보였으며, 동일한 습도조건 하에 온도가 상승된 ETW2는 ETW1보다 전단좌굴 하중이 약 18% 감소되는 경향을 보였다.

• 한국강구조학회 논문집
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• 제25권3호
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• pp.299-305
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• 2013

본 연구에서는 각형 중공강관(SHS) 장주기둥에 CFRP쉬트를 길이방향으로 보강하여 중심축하중 실험을 수행하였다. 총 3개의 장주실험체와 1개의 stub column 실험체를 제작하였으며, 실험변수는 CFRP 보강겹수이다. 실험결과 장주기둥에 대해 실험체 중간에서 전체좌굴이 발생하며 횡변위가 발생하여 파괴되었지만, CFRP쉬트의 보강을 통해 전체좌굴을 제어하며 횡변위로 인한 안정성을 확보하였다. 또한 CFRP쉬트의 보강으로 최대 22%의 내력이 상승하여 내력상승효과를 확인할 수 있었다.

• Structural Engineering and Mechanics
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• 제71권3호
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• pp.283-290
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• 2019

In global competition manufacturing companies have to produce modern, new constructions from advanced materials in order to increase competitiveness. The aim of my research was to develop a new composite cellular plate structure, which can be primarily used for structural elements of road, rail, water and air transport vehicles (e.g. vehicle bodies, ship floors). The new structure is novel and innovative, because all materials of the components of the newly developed structure are composites (laminated Carbon Fiber Reinforced Plastic (CFRP) deck plates with pultruded Glass Fiber Reinforced Plastic (GFRP) stiffeners), furthermore combines the characteristics of sandwich and cellular plate structures. The material of the structure is much more advantageous than traditional steel materials, due mainly to its low density, resulting in weight savings, causing lower fuel consumption and less environmental damage. In the study the optimal construction of a given geometry of a structural element of a road truck trailer body was defined by single- and multi-objective optimization (minimal cost and weight). During the single-objective optimization the Flexible Tolerance Optimization method, while during the multi-objective optimization the Particle Swarm Optimization method were used. Seven design constraints were considered: maximum deflection of the structure, buckling of the composite plates, buckling of the stiffeners, stress in the composite plates, stress in the stiffeners, eigenfrequency of the structure, size constraint for design variables. It was confirmed that the developed structure can be used principally as structural elements of transport vehicles and unit load devices (containers) and can be applied also in building construction.

• Structural Engineering and Mechanics
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• 제48권1호
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• pp.57-75
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• 2013

It is still inadequate for investigating the highly nonlinear and complex mechanical behaviors of single-layer latticed domes by only performing a force-based demand-capacity analysis. The energy-based balance method has been largely accepted for assessing the seismic performance of a structure in recent years. The various factors, such as span-to-rise ratio, joint rigidity and damping model, have a remarkable effect on the load-carrying capacity of a single-layer latticed dome. Therefore, it is necessary to determine the maximum load-carrying capacity of a dome under extreme loading conditions. In this paper, a mechanical model for members of the semi-rigidly jointed single-layer latticed domes, which combines fiber section model with semi-rigid connections, is proposed. The static load-carrying capacity and seismic performance on the single-layer latticed domes are evaluated by means of the mechanical model. In these analyses, different geometric parameters, joint rigidities and roof loads are discussed. The buckling behaviors of members and damage distribution of the structure are presented in detail. The sensitivity of dynamic demand parameters of the structures subjected to strong earthquakes to the damping is analyzed. The results are helpful to have a better understanding of the seismic performance of the single-layer latticed domes.

• 국제초고층학회논문집
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• 제9권2호
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• pp.187-195
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• 2020

As deep decks are commonly used in construction fields and high-rise building. etc, the slim floor system is increasingly employed. But, the drawback of the slim floor system is that the use of 250 mm deep decks in a structure having a clear span of more than 6 m because of deflection and flexural buckling. This study suggests a non-support construction method where tendons are installed in the deep decks of the slim floor structure to introduce preload in order to control deflection in a structure having a clear span of 9 m. Loading tests were conducted to verify the composite effect and flexural capacity of the preloaded deep deck composite slab and evaluate the serviceability of the supportless construction method. The results showed the complete composite behavior of the preloaded deep deck composite slab with tendons. The specimens satisfied deflection limit and the working load was approximately 25% of the maximum load capacity. It is deemed that the cross-sectional area and yield strength of the deck plate should be taken into account in slab design and the yield strength and diameter of the tendon should be determined with the pre-tension taken into consideration.

• 한국지진공학회논문집
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• 제13권2호
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• pp.37-46
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• 2009

본 연구에서는 1층 1경간 실제크기의 가력 프레임에서 내진보강에 적합한 비좌굴 knee brace을 설치하여 주기하중을 통해 가새의 지진저항능력을 실험하였다. 볼트 고정 채널이 이용된 비좌굴 knee brace는 지진력에 저항하는 코어와 두 개의 철골 플레이트로 만들어졌고 단면의 형태는 코어의 국부좌굴과 횡좌굴에 저항하도록 하였다. 비좌굴 kneebrace는 현장에서 조립이 용이하고, 시공방법 또한 간단하여 공간에 제약이 있는1층에 필로터를 가진 중저층 RC건물의 내진 보수/보강에 효과적으로 사용할 수 있다. 각 실험체에 대한 변수로 중심코어의 크기와 외부 보강재의 크기, 가이드 플레이트의 유무 등으로 정하였으며, 실험을 통해 얻어진 힘-변위 이력곡선을 통해 중심코어의 크기가 가장 큰 영향을 미치는 것으로 나타났다. 또한 가이드 플레이트의 유무에 따라 압축강도 수정계수와 파괴형태가 달라지는 것을 알 수 있었다. 각 실험체에 대한 결과는 AISC 2005 Seismic Provisions 규정에서 제시한 누적 연성도와 누적 소산에너지 측면에서도 충분한 효과를 발휘하는 것으로 나타났다.