• Steel and Composite Structures
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• 제42권2호
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• pp.191-207
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• 2022

Undoubtedly, the employment of direct bond interaction between steel and concrete is preceding the other mechanisms because of its ease of construction. However, the large scatter in the experimental data about the issue has hindered the efforts to characterize bond strength. In the following research, the direct bond interaction and bond-slip behavior of CFTs with circular cross-section were examined through repeated load-reversed push-out tests until four cycles of loading. The influence of different parameters including the diameter of the tube and the use of shear tabs were assessed. Moreover, the utilization of expansive concrete and external spirals was proposed and tested as ways of improving bond strength. According to the results section dimensions, tube slenderness, shrinkage potential of concrete, interface roughness and confinement are key factors in a natural bond. Larger diameters will lead to a considerable drop in bond strength. The use of shear tabs by their associated bending moments increases the bond stress up to eight times. Furthermore, employment of external spirals and expansive concrete have a sensible effect on enhancing bonds. Macro-locking was also found to be the main component in achieving bond strength.

• 한국터널지하공간학회 논문집
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• 제22권1호
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• pp.23-46
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• 2020

본 연구에서는 터널 근접 시공으로 인한 기 존재 단독말뚝의 공학적 거동을 파악하기 위하여 터널로부터 말뚝선단의 이격거리와 막장압의 변화를 고려한 3차원 유한요소해석을 수행하였다. 수치해석에서는 터널 막장압을 고려하여 말뚝의 거동을 분석하였으며, 터널굴착으로 유발되는 지반침하, 말뚝두부침하, 말뚝축력 및 말뚝-지반 사이의 경계면에서 발생하는 전단응력을 고찰하였다. 말뚝이 터널 크라운(crown) 바로 상부에 위치하고 말뚝선단까지의 수직 이격거리가 0.25D (여기서, D는 터널직경)인 경우 초기 응력의 50%에 해당하는 막장압을 적용할 경우 25%의 막장압을 적용한 것과 비교한 결과 말뚝두부의 침하가 약 38% 감소하였다. 또한, 막장압의 크기가 작을수록 지반침하, 말뚝의 축력 및 말뚝-지반 사이에서 발생하는 전단응력이 증가하며, 말뚝이 터널굴착 영향권 밖에 존재할 경우 말뚝에는 압축력 형태의 축력이 발생하였다. 따라서 막장압의 크기 및 터널-말뚝선단의 상대위치는 지반 침하와 말뚝 침하에 큰 영향을 미치는 것으로 분석되었다. 본 연구에서 수행된 연구결과의 경우 기존에 보고된 연구결과를 바탕으로 비교분석을 실시하였으며, 터널굴착으로 인한 말뚝의 거동을 심도 있게 분석하였다.

• Steel and Composite Structures
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• 제46권4호
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• pp.451-469
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• 2023

The use of precast hollow-core slabs (PCHCS) in civil construction has been increasing due to the speed of execution and reduction in the weight of flooring systems. However, in the literature there are no studies that present a finite element model (FEM) to predict the load-slip relationship behavior of pushout tests, considering headed stud shear connector and PCHCS placed at the upper flange of the downstand steel profile. Thus, the present paper aims to develop a FEM, which is based on tests to fill this gap. For this task, geometrical non-linear analyses are carried out in the ABAQUS software. The FEM is calibrated by sensitivity analyses, considering different types of analysis, the friction coefficient at the steel-concrete interface, as well as the constitutive model of the headed stud shear connector. Subsequently, a parametric study is performed to assess the influence of the number of connector lines, type of filling and height of the PCHCS. The results are compared with analytical models that predict the headed stud resistance. In total, 158 finite element models are processed. It was concluded that the dynamic implicit analysis (quasi-static) showed better convergence of the equilibrium trajectory when compared to the static analysis, such as arc-length method. The friction coefficient value of 0.5 was indicated to predict the load-slip relationship behavior of all models investigated. The headed stud shear connector rupture was verified for the constitutive model capable of representing the fracture in the stress-strain relationship. Regarding the number of connector lines, there was an average increase of 108% in the resistance of the structure for models with two lines of connectors compared to the use of only one. The type of filling of the hollow core slab that presented the best results was the partial filling. Finally, the greater the height of the PCHCS, the greater the resistance of the headed stud.

• 한국지반공학회논문집
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• 제29권1호
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• pp.161-170
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• 2013

본 연구에서는 사질토지반의 거동을 상세히 모사할 수 있는 탄소성모델 및 말뚝절편 수치해석을 적용하여 말뚝지름에 따른 사질토지반에 설치된 현장타설말뚝의 주면마찰거동을 분석하였다. 수치해석 결과는 현재 사용되는 설계방법과 비교하여 극한주면마찰력과 t-z거동을 잘 예측하는 것으로 나타났다. 말뚝지름이 감소함에 따라 말뚝-지반 경계면 및 주위지반에 국부적으로 발생되는 체적팽창과 이에 따라 말뚝주면에 발현되는 유효수평응력이 더 크게 발생하기 때문에 극한주면마찰력이 증가하는 것으로 나타났다. 말뚝지름이 감소함에 따라 t-z곡선 기울기의 증가는 말뚝재하에 따라 발생하는 세가지 전단단계(초기, 체적팽창, 및 일정체적 전단단계)가 일찍 발현되기 때문인 것으로 나타났다. 이러한 현장타설말뚝의 말뚝지름에 따른 극한주면마찰력에 대한 영향은 사질토지반의 상대밀도가 증가하고 구속압이 감소할수록 커지는 것으로 나타났다.

• 한국지반신소재학회논문집
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• 제12권1호
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• pp.51-61
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• 2013

본 논문에서는 지오텍스타일 공극 크기 분포를 이미지 분석방법을 이용하여 정량적으로 산출하였다. 연구과정은 실내시험을 통해 지오텍스타일-지오멤브레인 층으로 된 재료를 에폭시 레진으로 포화시킨 후, 양생, 절단하여 그 표면을 디지털 광학현미경으로 관찰하고 정량화함으로 이루어졌다. 여기서는 재료공학에서 주로 사용하는 공간학(stereology)의 개념을 사용하였으며, 지오텍스타일 필라멘트에 의해 둘러싸인 공극의 크기를 최대내접공극크기분포(LIOS)로 표현하였다. 지오텍스타일 내부 축적빈도 50%에 해당하는 공극직경이 압축응력이 10kPa에서 300kPa로 증가함에 따라 $45{\mu}m$가량 감소하였으며, 다시 압축응력을 10kPa로 되돌렸을 경우 초기치의 90%정도 수준으로 회복하였다. 마찰형 지오멤브레인 표면에서 연직응력 100, 300 kPa을 받으며 전단되었을 경우 평균 공극의 크기가 각가 32, 16.5% 감소하였다. 본 논문의 시험 및 분석 결과는 지오텍스타일 내부의 최대내접공극 크기분포가 표면거칠기가 다른 지오멤브레인 표면에서 압축 및 인터페이스 전단됨에 따라 어떻게 변화하는지를 보여준다.

• 접착 및 계면
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• 제14권2호
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• pp.75-81
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• 2013

SiC 나노입자를 이용하여 에폭시 복합재료를 제조할 수 있다. SiC 형상에 따른 영향으로 복합재료의 계면 물성이 변화된다. SiC의 형상에 따른 계면 상태의 변화를 관찰하기 위해 베타 형태, 위스커 형태의 SiC 나노입자를 사용하였다. 나노입자에 대한 분산도를 평가하기 위해 커패시턴스를 이용한 분산도 평가방법을 활용하였다. FE-SEM을 이용하여 SiC 나노입자의 활용에 따른 나노복합재료의 파단면을 관찰하여, 그 강화 효과를 비교 분석하였다. 탄소섬유와 SiC 나노입자가 함유된 에폭시를 이용한 복합재료에 계면 물성을 비교하기 위해 층간전단강도 평가법과 계면전단강도 평가법을 이용하였다. 복합재료의 계면 물성을 강화하기 위해서는 베타 형태의 SiC 나노입자를 활용할 경우가 위스커 입자를 이용한 경우보다 높은 계면 강도를 나타냈다.

• International Journal of Air-Conditioning and Refrigeration
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• 제14권2호
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• pp.41-48
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• 2006

Absorption performance at the vertical interface between refrigerant vapor and liquid solution of $LiBr-H_{2}O$ solution was enhanced by the waves formed due to the interfacial shear stress. The present study investigated experimentally and analytically the improvements of absorption performance in a falling film by wavy film flow. The dynamic parameter was the film Reynolds numbers ranged from 50 to 150. The energy and diffusion equations were solved simultaneously to find the temperature and concentration profiles at the interface of liquid solution and refrigerant vapor. Absorption characteristics due to heat and mass transfer were analyzed for the falling film of the LiBr aqueous solution contacted by refrigerant vapor in the absorber. Absorption performance showed a peak value at the solution flow rate of $Re_{f}>100$. Absorption performance for the wavy film flow was found to be greater by approximately 10% than that for uniform film flow. Based on numerical and experimental results, the maximum absorption rate was obtained for the wavy flow caused by spring insert. The difference between the measured and the predicted results were ranged from 5.8 to 12%.

• 설비공학논문집
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• 제12권1호
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• pp.102-111
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• 2000

A numerical model which simulates the simultaneous heat and mass transfer within a vertical tube GAX absorber was developed. The ammonia vapor and the solution liquid are in counter-current flow, and the hydronic fluid flows counter to the solution liquid. The film thickness and the velocity distribution of the liquid film were obtained by matching the shear stress at the liquid-vapor interface. Two-dimensional diffusion and energy equations were solved in the liquid film to give the temperature and concentration, and a modified Colburn-Drew analysis was used for the vapor phase to determine the heat and mass fluxes at the liquid-vapor interface. The model was applied to a GAX absorber to investigate the absorption rates, temperature and concentration profiles, and mass flow rates of liquid and vapor phases. It was shown that the mass flux of water was negligible compared with that of ammonia except the region near the liquid inlet. Ammonia absorption rate increases rapidly near the liquid inlet and decrease slowly. Both the absorption rate of ammonia vapor and the desorption rate of water near the liquid inlet increase as the vapor mass flow rate increases, but the mass fluxes of the ammonia and the water near the liquid outlet decrease as the mass flow rate of the vapor increases.

• 마이크로전자및패키징학회지
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• 제20권4호
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• pp.7-11
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• 2013

As thermosonic ball bonding is developed for more and more advanced applications in the electronic packaging industry, the control of process stresses induced on the integrated circuits becomes more important. If Cu bonding wire is used instead of Au wire, larger ultrasonic levels are common during bonding. For advanced microchips the use of Cu based wire is risky because the ultrasonic stresses can cause chip damage. This risk needs to be managed by e.g. the use of ultrasound during the impact stage of the ball on the pad ("pre-bleed") as it can reduce the strain hardening effect, which leads to a softer deformed ball that can be bonded with less ultrasound. To find the best profiles of ultrasound during impact, a numerical model is reported for ultrasonic bonding with capillary dynamics combined with a geometrical model describing ball deformation based on volume conservation and stress balance. This leads to an efficient procedure of ball bond modelling bypassing plasticity and contact pairs. The ultrasonic force and average stress at the bond zone are extracted from the numerical experiments for a $50{\mu}m$ diameter free air ball deformed by a capillary with a hole diameter of $35{\mu}m$ at the tip, a chamfer diameter of $51{\mu}m$, a chamfer angle of $90^{\circ}$, and a face angle of $1^{\circ}$. An upper limit of the ultrasonic amplitude during impact is derived below which the ultrasonic shear stress at the interface is not higher than 120 MPa, which can be recommended for low stress bonding.

• Geomechanics and Engineering
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• 제4권3호
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• pp.173-190
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• 2012

With recent growing interests in the Performance-Based Seismic Design and Assessment Methodology, more realistic modeling of a structural system is deemed essential in analyzing, designing, and evaluating both newly constructed and existing buildings under seismic events. Consequently, a shallow foundation element becomes an essential constituent in the implementation of this seismic design and assessment methodology. In this paper, a contact interface fiber section element is presented for use in modeling soil-shallow foundation systems. The assumption of a rigid footing on a Winkler-based soil rests simply on the Euler-Bernoulli's hypothesis on sectional kinematics. Fiber section discretization is employed to represent the contact interface sectional response. The hyperbolic function provides an adequate means of representing the stress-deformation behavior of each soil fiber. The element is simple but efficient in representing salient features of the soil-shallow foundation system (sliding, settling, and rocking). Two experimental results from centrifuge-scale and full-scale cyclic loading tests on shallow foundations are used to illustrate the model characteristics and verify the accuracy of the model. Based on this comprehensive model validation, it is observed that the model performs quite satisfactorily. It resembles reasonably well the experimental results in terms of moment, shear, settlement, and rotation demands. The hysteretic behavior of moment-rotation responses and the rotation-settlement feature are also captured well by the model.