• Structural Engineering and Mechanics
• /
• 제10권6호
• /
• pp.533-543
• /
• 2000

To prevent major cracking and failure during earthquakes, it is important to design reinforced concrete liquid storage structures, such as water and fuel storage tanks, properly for the hydrodynamic pressure loads caused by seismic excitations. There is a discussion in recent Codes that most of the base shear applied to liquid containment structures is resisted by inplane membrane shear rather than by transverse flexural shear. The purpose of this paper is to underline the importance of the membrane force system in carrying the base shear produced by hydrodynamic pressures in both rectangular and cylindrical tank structures. Only rigid tanks constrained at the base are considered. Analysis is performed for both tall and broad tanks to compare their behavior under seismic excitation. Efforts are made to quantify the percentage of base shear carried by membrane action and the consequent procedures that must be followed for safe design of liquid containing storage structures.

• Earthquakes and Structures
• /
• 제26권2호
• /
• pp.163-174
• /
• 2024

Dynamic equilibrium equations for finite element analysis were derived for the free field one-dimensional shear wave propagation through the horizontally layered soil deposits with the elastic half-space. We expressed Rayleigh's viscous damping consisting of mass and stiffness proportional terms. We considered two cases where damping matrices are defined in the total and relative displacement fields. Two forms of equilibrium equations are presented; one in terms of total motions and the other in terms of relative motions. To evaluate the performance of new equilibrium equations, we conducted two sets of site response analyses and directly compared them with the exact closed-form frequency domain solution. Results show that the base shear force as earthquake load represents the simpler form of equilibrium equation to be used for the finite element method. Conventional finite element procedure using base acceleration as earthquake load predicts exact solution reasonably well even in soil deposits with unrealistically high damping.

• 대한치과보철학회지
• /
• 제42권6호
• /
• pp.654-663
• /
• 2004

Statement of problem. According to the fracture pattern in several reports, fractures most frequently occur in the interface between the ceromer and the substructure. Purpose. The aim of this in vitro study was to compare the macro shear bond strength and microshear bond strength of a ceromer bonded to a fiber reinforced composite (FRC) as well as metal alloys. Material and methods. Ten of the following substructures, type II gold alloy, Co-Cr alloy, Ni-Cr alloy, and FRC (Vectris) substructures with a 12 mm in diameter, were imbedded in acrylic resin and ground with 400, and 1, 000-grit sandpaper. The metal primer and wetting agent were applied to the sandblasted bonding area of the metal specimens and the FRC specimens, respectively. The ceromer was placed onto a 6 mm diameter and 3 mm height mold in the macro-shear test and 1 mm diameter and 2 mm height mold in the micro-shear test, and then polymerized. The macro- and micro-shear bond strength were measured using a universal testing machine and a micro-shear tester, respectively. The macro- and micro-shear strength were analyzed with ANOVA and a post-hoc Scheffe adjustment ($\alpha$ = .05). The fracture surfaces of the crowns were then examined by scanning electron microscopy to determine the mode of failure. Chi-square test was used to identify the differences in the failure mode. Results. The macro-shear strength and the micro-shear strength differed significantly with the types of substructure (P<.001). Although the ceromer/FRC group showed the highest macroand micro-shear strength, the micro-shear strength was not significantly different from that of the base metal alloy groups. The base metal alloy substructure groups showed the lowest mean macro-shear strength. However, the gold alloy substructure group exhibited the least micro-shear strength. The micro-shear strength was higher than the macro-shear strength excluding the gold alloy substructure group. Adhesive failure was most frequent type of fracture in the ceromer specimens bonded to the gold alloys. Cohesive failure at the ceromer layer was more common in the base metals and FRC substructures. Conclusion. The Vectris substructure had higher shear strength than the other substructures. Although the shear strength of the ceromer bonded to the base metals was lower than that of the gold alloy, the micro-shear strength of the base metals were superior to that of the gold alloy.

• 구강회복응용과학지
• /
• 제37권4호
• /
• pp.232-243
• /
• 2021

목적: 다양한 3D 프린팅 의치상 레진과 여러 가지 의치 첨상 재료 간의 전단결합강도를 평가하여 기존의 열중합 의치상 레진과의 전단결합강도를 비교 평가하고자 하였다. 연구 재료 및 방법: 열중합레진(Vertex RS)과 3D프린팅 의치상 레진 두종(DENTCA Denture base II, NextDent^TM Base)을 사용하였다. 의치 첨상 재료로는 성분이 다른 총 4종(Tokuyama Rebase II fast, Kooliner, Denture Liner, Denture Liner, Lang Jet Denture Repair Kit)을 사용하여 12개의 군으로 분류하였다. ISO/TS 11405규격에 따라 접착을 시행하였다. 전단결합강도를 측정하였고, 이후 입체현미경과 주사전자현미경을 이용하여 접착 계면을 관찰하고 파절편의 분석을 통하여 파절 양상을 조사하였다. 결과: 3D 프린팅 의치상 레진 군에서 의치 첨상 재료와의 전단결합강도가 열중합레진 군에 비해 유의하게 낮은 전단결합강도 결과를 나타내었다(P < 0.05). Polymethyl methacrylate계열의 첨상재료의 경우, 의치상종류와 관계없이 높은 전단결합강도를 보였다. 파절 양상은 대부분의 군에서 접착성 파절이 나타났고 일부 군에서 응집성 파절과 혼합성 파절 양상이 나타났다. 결론: Polymethyl methacrylate를 주성분으로 하는 의치 첨상 재료가 실험에 사용된 모든 의치상 레진에서 다른 의치 첨상 재료와 비교하여 높은 전단 결합강도 값을 나타내었지만, 직접법으로 의치 첨상을 시행할 경우 단량체로 Isobutyl methacrylate 성분의 의치 첨상재료를 사용하는 것이 전단결합강도면에서 유리할 것으로 사료된다.

• The Journal of Advanced Prosthodontics
• /
• 제12권5호
• /
• pp.251-258
• /
• 2020

PURPOSE. The bond strengths between resin denture teeth with various compositions and denture base resins including conventional and CAD/CAM purposed materials were evaluated to find influence of each material. MATERIALS AND METHODS. Cylindrical rods (6.0 mm diameter × 8.0 mm length) prepared from pre-polymerized CAD/CAM denture base resin blocks (PMMA Block-pink; Huge Dental Material, Vipi Block-Pink; Vipi Industria) were bonded to the basal surface of resin teeth from three different companies (VITA MFT^®; VITA Zahnfabrik, Endura Posterio^®; SHOFU Dental, Duracross Physio^®; Nissin Dental Products Inc.) using resin cement (Super-Bond C&B; SUN MEDICAL). As a control group, rods from a conventional heat-polymerizing denture base resin (Vertex™ Rapid Simplified; Vertex-Dental B.V. Co.) were attached to the resin teeth using the conventional flasking and curing method. Furthermore, the effect of air abrasion was studied with the highly cross-linked resin teeth (VITA MFT^®) groups. The shear bond strengths were measured, and then the fractured surfaces were examined to analyze the mode of failure. RESULTS. The shear bond strengths of the conventional heat-polymerizing PMMA denture resin group and the CAD/CAM denture base resin groups were similar. Air abrasion to VITA MFT^® did not improve shear bond strengths. Interfacial failure was the dominant cause of failure for all specimens. CONCLUSION. Shear bond strengths of CAD/CAM denture base materials and resin denture teeth using resin cement are comparable to those of conventional methods.

• Earthquakes and Structures
• /
• 제22권2호
• /
• pp.109-120
• /
• 2022

Older or damaged structures can require significant retrofit to ensure they perform well in subsequent earthquakes. Supplemental damping devices are used to achieve this goal, but increase base shear forces, foundation demand, and cost. Displacement reduction without increasing base shear is possible using novel semi-active and recently-created passive devices, which offer energy dissipation in selected quadrants of the force-displacement response. Combining these devices with large, strictly passive energy dissipation devices can offer greater, yet customized response reductions. Supplemental damping to reduce response without increasing base shear enables a net-zero base shear approach. This study evaluates this concept using two incremental dynamic analyses (IDAs) to show displacement reductions up to 40% without increasing base shear, more than would be achieved for either device alone, significantly reducing the risk of response exceeding the unaltered structural case. IDA results lead to direct calculation of reductions in risk and annualized economic cost for adding these devices using this net-zero concept, thus quantifying the trade-off. The overall device assessment and risk analysis method presented provides a generalizable proof-of-concept approach, and provides a framework for assessing the impact and economic cost-benefit of using modern supplemental energy dissipation devices.

• Structural Engineering and Mechanics
• /
• 제82권4호
• /
• pp.491-502
• /
• 2022

A model experiment with a scale of 1:150 has been conducted to investigate the dynamic responses of a freestanding four-column bridge tower subjected to regular wave, random wave and coupled wave-current actions. The base shear forces of the caisson foundation and the dynamic behaviors of the superstructure were measured and analyzed. The comparisons of the test values with the theoretical values shows that wave-induced base shear forces on the bridge caisson foundation can be approximated by using a wave force calculation method in which the structure is assumed to be fixed and rigid. Although the mean square errors of the base shear forces excited by joint random wave and current actions are approximately equal to those excited by pure random waves, the existence of a forward current increases the forward base shear forces and decreases the backward base shear forces. The tower top displacements excited by wave-currents are similar to those excited by waves, suggesting that a current does not significantly affect the dynamic responses of the superstructure of the bridge tower. The experiment results can be used as a reference for similar engineering design.

• 한국구조물진단유지관리공학회 논문집
• /
• 제19권2호
• /
• pp.1-9
• /
• 2015

본 논문에서는 RC 기둥-기초 접합부분을 중공형 및 확장형 강재 Base Plate로 보강한 실험체에 대한 하중 재하 실험을 실시하여, 강재 Base Plate가 부착된 RC 기둥-기초에서의 뚫림전단에 대한 보강효과를 정량화 하기 위한 구조해석 및 기초적 실험 연구를 수행하였다. 실험은 각 실험체별 부착된 Base Plate의 두께, 내민길이, 치수, 형식 등의 변수에 따라 수행하였으며 실험을 통하여 응력분산에 적합한 적정 Base Plate의 모양 및 치수를 확인하였고, 보강효과에 대하여 분석하였다. 실험을 통해 Base Plate가 기초에 전해지는 수직하중의 응력분산에 효과적이었으며 폐쇄형보다 중공형 보강이 효율적인 것을 확인하였다. 보강을 통해 변위연성 능력의 향상으로 기존의 기초두께보다 두께가 감소한 실험체에서도 기존보다 높은 성능을 나타냈다. 보강 후의 실험체로부터 구조물의 거동특성을 취성으로부터 연성으로 유도 할 수 있었으며, 실험체를 파괴시까지 가력함으로써 파괴시 보강 전, 후에 대한 균열 및 파괴양상을 확인 하였다.

• 대한치과교정학회지
• /
• 제29권5호
• /
• pp.599-611
• /
• 1999

금속 브라켓의 결합강도에 영향을 미치는 요소인 브라켓 기저부의 형태와 결합 부위에 적용되는 힘의 특성에 대해 알아보고자 연구를 시행하였다. 형태가 다른 5종의 금속브라켓의 기저부와 결합강도 측정후 접착파절양상을 stereoscope and scanning electron microscope를 통해 관찰하고 결합 부위에 적용되는 힘은 전단결합강도, 인장결합강도, 전단/인장복합결합강도로 구분하고 결합강도를 비교하여 다음과 같은 결론을 얻었다. 1. 브라켓 기저부 형태에 따른 모든 군에서 전단결합강토(SBS)가 제일 컸으며, 인장결합강도(TBS)는 SBS의 50%정도 수준이었고 전단/인장복합결합강도(S/TBS)는 전단결합강도(SBS)의 30%정도이었다. 2. 브라켓의 결합강도는 Micro-Loc base가 가장 크고($SBS:22.86{\pm}1.37kgf,\;TBS:11.37{\pm}1.43kgf,\;S/TBS:6.69{\pm}0.34kgf$), Integral base가 가장 작았다($SBS:10.52{\pm}1.27kgf,\;TBS:4.27{\pm}1.08kgf,\;S/TBS:2.94{\pm}0.58kgf). 3. 단위면적당 결합강도 비교시, Integral base가 가장 작았고(p<0.05), 전단결합강도와 인장결합강도에서는 Micro-Loc과 Chessboard base간의 차이가 없었으며 (p>0.05), Non-Etched Foil Mesh와 Micro-Etched Foil Mesh base간의 전단결합강도와 인장결합강도는 차이가 없었으나, 전단/인장복합결합강도에서는 Micro-Etched Foil Mesh base가 Non-Etched Foil Mesh base보다 더 크게 나타났다. 4. 전단, 인장, 전단/인장복합결합강도 측정후 접착파절은 브라켓/레진 계면에서 일어나 ARI score가 작게 나타났다.

• Geomechanics and Engineering
• /
• 제28권5호
• /
• pp.505-520
• /
• 2022

In recent years, geotextile-encased gravel columns (usually called stone columns) have become a popular method to increasing soil shear strength, decreasing the settlement, acceleration of the rate of consolidation, reducing the liquefaction potential and increasing the bearing capacity of foundations. The behavior of improved loose base-soil with gravel columns under shear loading and the shear stress-horizontal displacement curves got from large scale direct shear test are of great importance in understanding the performance of this method. In the present study, by performing 36 large-scale direct shear tests on sandy base-soil with different fine-content of zero to 30% in both not improved and improved with gravel columns, the effect of the presence of gravel columns in the loose soils were investigated. The results were used to predict the shear stress-horizontal displacement curve of these samples using support vector machines (SVM). Variables such as the non-plastic fine content of base-soil (FC), the area replacement ratio of the gravel column (Arr), the geotextile encasement and the normal stress on the sample were effective factors in the shear stress-horizontal displacement curve of the samples. The training and testing data of the model showed higher power of SVM compared to multilayer perceptron (MLP) neural network in predicting shear stress-horizontal displacement curve. After ensuring the accuracy of the model evaluation, by introducing different samples to the model, the effect of different variables on the maximum shear stress of the samples was investigated. The results showed that by adding a gravel column and increasing the Arr, the friction angle (ϕ) and cohesion (c) of the samples increase. This increase is less in base-soil with more FC, and in a proportion of the same Arr, with increasing FC, internal friction angle and cohesion decreases.