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토목섬유로 보강된 성토지지말뚝 구조에 적합한 말뚝재료의 개발
최충락(Choong-Lak Choi),이광우(Kwang-Wu Lee),김은호(Eun-Ho Kim),정지원(Ji-Won Jung) 한국지반신소재학회 2016 한국지반신소재학회 논문집 Vol.15 No.1
최근 철도는 고속화를 위해 콘크리트궤도를 적용하는 추세이고 연약지반 구간에 건설된 철도는 장기간에 걸친 작은 양의 침하발생으로도 침하에 민감한 콘크리트 궤도의 침하량 허용범위를 초과하여 궤도의 손상과 뒤틀림을 초래할 수 있다. 연약지반에 건설된 철도의 잔류침하를 효과적으로 제어 할 수 있는 방법으로 성토지지말뚝공법을 들 수 있으며 성토하중을 말뚝머리로 전달하기 위해 콘크리트 슬라브가 사용되기도 하나 하중이 전달되는 과정에 나타나는 성토체 내부의 아칭효과를 극대화하는 토목섬유를 이용한 방법이 보다 경제적이다. 그러나 토목섬유 등으로 인해 집중된 성토하중을 받는 성토지지용 말뚝은 일반적으로 교량구조물에 사용하는 PHC말뚝을 그대로 사용하고 있으며 이는 필요이상으로 높은 강도의 재료를 사용함으로써 재료의 효율성이 크게 떨어지고 있는 실정이다. 이에 따라 해외의 적용사례 조사를 통해 성토지지용으로 가장 적합한 말뚝의 형식으로 현장타설 콘크리트 말뚝을 선정하고 산업부산물을 이용한 배합설계와 압축강도시험을 통해 성토지지용 말뚝재료의 최적 배합조건을 도출하였다. 그리고 최적배합조건을 적용한 성토지지용 현장타설말뚝이 기존 PHC말뚝에 비해 재료의 효율성이 약 2.8배 뛰어나다는 것을 수치해석을 통해 확인하였다. It is a current trend that the concrete track is applied for high speed railway. In the case of the railway embankment constructed on soft ground, the damage to concrete track which is sensitive to settlement such as distortion and deflection could be caused by very small amount of long term settlement. Pile Supported Embankment method can be considered as the effective method to control the residual settlement of the railway embankment on soft ground. The Geosynthetics is used inside of the embankment to maximize the arching effect transmitting the load of the embankment to the top of the piles. But, PHC piles that are generally used for bridge structures are also applied as the pile supporting the load of embankment concentrated by the effect of the Geosynthetics. That is very low efficiency in respect of pile material. So, in this study, the cast in place concrete pile was selected as the most suitable pile type for supporting the embankment by a case study and the optimum mixing condition of concrete using a by-product of industry was induced by performing the mixing designs and the compressive strength designs. And it is shown that the cast in place pile with the optimum mixing condition using the by-product of industry is 2.8 times more efficient than the PHC pile for the purpose of Pile Supported Embankment by the finite element analysis method.
박철수(Park Chul-Soo),최찬용(Choi Chan-Yong),최충락(Choi Choong-Lak),목영진(Mok Young-Jin) 한국철도학회 2007 한국철도학회 학술발표대회논문집 Vol.- No.-
Recently, a theoretically-sound design approach, using an elastic multilayer model, is attempted in trackbed designs for the construction of high speed railways and new lines of conventional railways. In the elastic multilayer model, the stress-dependent resilient modulus(E<SUB>R</SUB>) is an important input parameter, that is, reflects substructure performance under repeated traffic loading. However, the evaluation method for resilient modulus using repeated loading triaxial test is not fully developed for practical purpose, because of costly equipment and the significantly fluctuated values depending on the testing equipment and laboratory personnel. In this study, the paper will present an indirect method to estimate the resilient modulus using dynamic properties. The resilient modulus of crushed stone, which is the typical material of sub-ballast, was calculated with the measured dynamic properties and the range of stress level of the sub-ballast, and approximated with the power model combined with bulk and deviatoric stresses. The resilient modulus of coarse grained material decreases with increasing deviatoric stress at a confining pressure, and increases with increasing bulk stress. Sandy soil(SM classified from Unified Soil Classification System) of subgrade was also evaluated and best fitted with the power model of deviatoric stress only.
목영진(Mok Young-Jin),박철수(Park Chul-Soo),임정열(Lim jeong-Yeul),최충락(Choi Choong-Lak) 한국철도학회 2007 한국철도학회 학술발표대회논문집 Vol.- No.-
Reinforced roadbeds are valued from the point of view of maintenance as well as enhanced mechanical capacity. They support more train load and less transmit to the sub-layers than general roadbeds. Also, the lateral sloping surface of the reinforced roadbed and its low permeability, achieved by the controlled compaction, increase drainage capability and prevent the softening of sub-layers. In the study, a series of cross-hole tests was performed to observe the temporal changes in the stiffness of reinforced roadbeds, if any, due to the cyclic loading of trains and alternating rainy and frozen seasons at Pyeong-taek experimental site. The three types of reinforced roadbed materials are slag, crushed stones, and soils, and the thickness of all the reinforced roadbeds is 0.8m. The stiffness of the slag and soil reinforced roadbeds was not changed or slightly decreased. The stiffness of the crushed stone was somewhat increased and is inferred to being densified close to surface.
유승경(Seung-Kyong You),신희수(Heesoo Shin),이광우(Kwang-Wu Lee),박정준(Jeong-Jun Park),최충락(Choong-Lak Choi),홍기권(Gigwon Hong) 한국지반신소재학회 2019 한국지반신소재학회 논문집 Vol.18 No.2
본 연구에서는 말뚝의 인발저항에 대한 합리적 평가를 위하여, 다양한 지반 조건(상대밀도, 세립분 함유율)에서 말뚝의 인발거동 모사에 대한 유한요소해석의 적용성을 평가하였다. 즉, 기존의 실내모형실험 결과(You et al., 2018)를 대상으로 동일한 조건에서의 유한요소해석을 실시하였고, 유한요소해석에 이용된 해석모델의 신뢰성을 검증하였다. 또한 수치해석을 활용한 말뚝의 인발거동 모사에 대한 적정성을 평가하였다. 그 결과, 가상지반이 적용된 축대칭 해석을 이용하여 말뚝의 주면마찰력을 평가할 수 있는 것으로 확인되었다. 또한 다양한 지반 조건에 대하여 말뚝-지반 경계면의 전단저항 특성을 반영할 수 있는 축대칭 해석은 말뚝의 합리적인 인발거동 모사가 가능한 해석방법으로 활용이 가능한 것으로 분석되었다. 따라서 본 연구를 통하여 제안된 해석모델은 말뚝의 응력-변형 관계를 통한 인발거동을 적절하게 모사할 수 있는 것으로 판단되었다. This paper describes the applicability of FEA(Finite Element Analysis) to the simulation of pile pullout behavior under various soil conditions (relative density and fines content), in order to evaluate reasonably the pullout resistance of pile. That is, the results of previous research (You et al., 2018) were analyzed by FEA under the same conditions. The FEA results showed that axisymmetric analysis using virtual ground was able to evaluate the skin friction of the pile. Also, axisymmetric analysis, which can apply the shear resistance characteristics of the pile-soil interface in various soil conditions, could be used as an analytical method that can simulate a reasonable pile pullout behavior. Therefore, the analytical model proposed in this study was able to simulate appropriately the pullout behavior based on the stress-strain relationship of the pile-soil interface.