Hokenberry and Lopez (2012) and Aoude et al. (2012) have shown that the steel fiber can be a substitute of the stirrup for shear strengthening. In this study, Vector 2 program which takes into account modified compression field theory tensile softening behaviors of SFRC were used for prediction of the shear capacities of SFRC beams.

In this study, shear behaviors of various SFRC were predicted using Vector 2 program. Obtained analytical data was compared with preceded experimental data performed by other researchers. It was found that one increase in the span to depth ratio results in 54% decrease in the shear strength. Likewise, 1% increase in the reinforcement ratio causes a 19.9 % increase in the shear strength.

GFRP 보강근의 역학적 성능은 고온과 콘크리트의 알칼리 환경에서 크게 감소된다. 본 연구에서는 GFRP 보강근이 열손상 뒤, 알칼리 환경에 추가로 노출되었을 때의 계면전단강도변화를 고찰하는데 집중하였다. 이를 위하여 GFRP 보강근 시편은 270도의 열에 1시간동안 노출된 후 알칼리 용액에 장기간 노출되었으며, 전단시험에 의하여 파괴되었다. 비교를 위하여 열손상이 없는 시편도 같은 기간 동안 알칼리 용액에 노출된 후 전단에 의하여 파괴되었다. 결과에서, 열손상을 받은 GFRP보강근의 계면전단강도의 감소가 열손상이 없는 보강근 보다 훨씬 큰 것으로 나타났다. 본 실험을 근거로 하여, 열손상을 미리 받은 GFRP 보강근이 알칼리에 노출되었을 때, 장기 잔존계면전단강도의 예측을 위한 2차식을 제시하였다.

본 연구의 목적은 고강도 SFRC 보의 강섬유 보강효과를 평가하기 위한 것이다. 이를 위하여 13개의 실험체를 제작하여 성능실험을 실시하였다. 실험 변수는 전단경간비, 강섬유 혼입률, 전단보강근비이며 콘크리트 강도는 60 MPa이다. 기존 연구결과와 재료 및 부재 실험결과에 대한 분석에 의하면, 전단경간비 2.5와 강섬유 혼입률 1.0%인 경우가 강섬유 보강효과가 최대로 발휘되는 것으로 평가되었다. 강섬유 보강 및 전단경간비를 고려한 기존 전단내력식은 고강도 SFRC보의 내력을 과소평가하는 것으로 평가되었다. 향후 고강도 SFRC 보의 강도특성에 대한 보완 연구가 필요한 것으로 판단된다.

In case of Enlargement method using Post-installed Anchors, mechanical expansion anchors were resisting tensile and shear force of Modular extension structure in exist building. The purpose of this study is to investigate strength of Post-installed Anchor on 16 MPa low strength Concrete under less than standard effective depth(hef). The fracture pattern of the specimens in Pull-out tests was pull-out failure and the strength showed 19% less than that of the design strength on test anchor manufacturer. In cyclic load shear tests the fracture pattern was steel failure of anchor and the strength showed 10% less value than that.

철근콘크리트 구조물의 전단거동은 수년간의 많은 연구에도 불구하고, 이론적으로 명확하게 규명하기에 어려운 문제중에 하나이다. 중공슬래브의 휨강도와 전단강도는 중공부로 인하여 감소되기 때문에, 이에 따른 구조물의 성능을 예측하는 것은 중요한 문제라 할 수 있다.현재 각국의 중공슬래브 전단설계기준은 실험에 의한 기준식을 제시하고 있다. 따라서 본 연구에서는 철근비에 따른 일방향 중공슬래브 전단강도 산정방법에 관한 연구를 수행하기 위해 실험결과를 분석하고, 전단강도 산정식들을 비교, 분석하였다.

플랫 플레이트 시스템은 기둥 주위의 국부적인 응력집중 현상으로 인한 뚫림전단 파괴에 대해 취약하다. 이를 보강하기위하여 전단보강재로 철근 스터럽을 사용하지만 부재에 높은 전단력이 작용할 경우, 배근이 조밀해지고 자중이 증가하고, 골재가 고르게 배치되지 않아 구조물의 성능저하를 유발한다. 철근과 달리 FRP는 높은 내부식성과 경량 등의 장점을 가지고 있어 철근 스터럽의 대체재로서 선택하였다. 전단보강재를 GFRP (Glass Fiber Reinforced Polymer) 판의 형태로 제작하고 플랫 플레이트 슬래브에 매립하였다. 본 연구에서는 무 보강, 스터럽, GFRP 판으로 보강된 3개의 시험체를 제작하였으며 GFRP 판으로 보강된 플랫 플레이트 슬래브의 역학적 거동 파악 및 전단내력을 평가하는데 목적을 두었다.

In this study, experimental research was carried out to evaluate the structural performance of high strength R/C interior beam-column joints regions, with or without the shear reinforcement. Specimens designed by the interior beam-column joint regions without the shear reinforcement of existing reinforced concrete building showed a unstable mode of failure and an decrease in load-carrying capacity and energy dissipation capacity and ductility ratio.

This paper reports the result of fourteen push-off tests to understand shear transfer between UHPC and normal concrete. To recommend a reliable shear transfer formula for the design of composite section of UHPC and normal concrete, the test results are compared to available shear transfer formulas for UHPC and normal concrete.

이 연구에서는 전단하중을 받는 부유식 콘크리트 구조물 모듈 접합부의 구조거동 실험연구를 수행하였다. 모듈 접합부 전단키의 균열 양상, 전단거동 및 전단강도를 파악하였다. 전단강도의 영향을 파악하기 위해 전단키의 경사각도, 횡방향 구속응력 및 콘크리트의 압축강도 등을 실험변수로 고려하였다. 전단키의 경사각도가 증가함에 따라 접합부의 전단강도가 증가하였다. 또한, 구속응력이 증가함에 따라 전단키의 전단강도가 증가하였다. 실험변수에 따른 전단거동 실험결과를 토대로 접합부의 전단강도 평가식을 제안하였으며, 제안식에 의한 전단강도 예측값은 실험값에 근접하는 것으로 나타났다.

In this study, shear assessment equation of reinforced concrete interior beam-column joints without shear reinforcement using high ductile fiber reinforced mortar based on the test results was proposed. Suggested equation was proposed to modify Hegger's seismic design equation. It was reflected the effect of high ductile fiber incorporated

Under cyclic loading, the shear capacity of reinforced concrete (RC) beam-column connections is significantly decreased by the joint bond-slip and shear cracking as deformation increases. In the present study, Joint shear strength model on the basis of bond-slip was developed to evaluate deformability at the joint shear failure.

In this study, experimental research was carried out to study the high strength RC exterior beam-column joints regions, without the shear reinforcement, using high ductile fiber-reinforced mortar. Specimens designed by retrofitting the exterior beam-column joint regions of existing reinforced concrete building showed a stable mode of failure and an increase in shear strength capacity due to the effect of enhancing dispersion of crack control at the time of initial loading and bridging of fiber from retrofitting new high ductile materials during testing.

To define the shear reinforcing effect of steel fiber in high strength concrete, 4 column specimens designed with a volume fraction of steel fiber such as 0.0%, 1.0%, 1.5%, 2.0%. The column specimens were tested lateral cyclic load under constant axial load. From test results, steel fiber can reduced brittle shear failure, and can increased strength and ductility capacity in RC columns.

In this study, experiments to evaluate concrete breakout capacity of anchor under dynamic shear loading were performed. The cast-in-place anchors without reinforcement were prepared for dynamic and static loading tests. Three specimens were tested for dynamic tests and one specimen for static test. It was found from the tests that the concrete breakout capacity of anchors without reinforcement under dynamic loading was about 6% higher than static loading.

In the construction of nuclear power plants using massive walls in Korea, the use of high-strength re-bars for shear design is necessary to enhance the constructability and economy. In the present study, low-rise walls(aspect ratio = 1.0) with 550MPa grade bars, were tested under cyclic loading to investigate shear capacity and deformation capacity of the walls. The results were compared with the performance of walls with grade 420 bars and predictions by current design code. The test results showed that ACI 349 underestimated the shear strength of the walls with 550 MPa grade bars. This result indicated that the ACI 349 predictions can be safely used for the earthquake design of the low-rise walls (aspect ratio =1.0) with 550 MPa grade bars.

It is reported that alkalinity of concrete decreases inter-laminar shear strength of FRP rebar. This could be more significant on thermally damaged FRP rebar. In this study, accelerated ISS test was conducted on FRP specimens previously exposed to temperature of 270℃ for 60 days. For 60 days, the ISS of thermally damaged FRP rebar was not significant

In this study, structural analysis was performed for the trapezoidal steel box girders. The girder is assumed to be made not by welded but by folded. Because the girder has no welded connection, the material can show its full strength without residual stresses. In the nonlinear analysis, however, there should be difference between sharp-corner girder and rounded-corner girder. Therefore, the parametric study was performed due to the radius of fillet to estimate the shear buckling strength of the girders.

In this study, a reduction in inter-laminar shear strength of FRP reinforcing bars, which is domestically produced, subjected to high temperatures was investigated. The inter-laminar shear tests were conducted on the rebar specimens conditioned in a chamber for specified times at high temperatures. The exposure temperatures were 100℃∼300℃, The exposure time were 0.5 hours to 4 hours. It was found that the critical temperature was for both GFRP and CFRP reinforcing bars, 270℃. Based on the results, a linear equation for evaluation of the effect of exposure time is proposed.

The Non-Shrinkage Epoxy using Silanol(Si-OH) was developed for repairing and strengthening, and it has excellent material properties that overcomes many limits of other existing epoxy products. In this study, direct shear strength tests were conducted to investigate the superior bond and shear capacity of the Non-Shrinkage Epoxy. The test results showed that the specimens with Non-Shrinkage Epoxy applied to their shear plane had higher shear strength than those with other existing epoxy.