Ultra High Performance Fiber Reinforced Concrete (UHPFRC) has a outstanding tensile hardening behaviour after a crack develops, which gives ductility to structures. Existing shear strength model for fiber reinforced concrete is entirely based on crack opening behavior(mode I) which comes from flexural-shear failure, not considering shear-slip behavior(mode II). To find out the mode I and mode II behavior on a crack in UHPFRC simultaneously, maximum shear strength of cracked UHPFRC is investigated from twenty-four push-off test results. The shear stress on a crack is derived as variable of initial crack width and fiber volume ratio. Test results show that shear slippage is proportional to crack opening, which leads to relationship between shear transfer strength and crack width. Based on the test results a hypothesis is proposed for the physical mechanics of shear transfer in UHPFRC by tensile hardening behavior in stead of aggregate interlocking in reinforced concrete. Shear transfer strength based on tensile hardening behavior in UHPFRC is suggested and this suggestion was verified by comparing direct tensile test results and push-off test results.

This study is a part of high strength lightweight aggregate concrete researches using lightweight aggregates and the purpose of this study is to find out the basic physical characteristics and tension cracking fracture characteristics of lightweight concrete. Crack Mouth Opening Displacement is measured through three point flexure experiment about embellish notch beam. Load-CMOD characteristics are examined through rules of countries, characteristics of lightweight concrete and tension cracking fracture experiments. The degree of tensile characteristic alteration according to size changes of specimen and the characteristics about crack surface are analyzed. The changes of softening curve are analyzed and fracture energy is drawn through inverse analysis by the obtained Load-CMOD curve. To decide fracture energy and analysis parametric, inverse analysis is conducted and Ant Colony Method is conducted for optimization and then a way to find out optimal parameterization fracture energy is suggested.

강도 한계상태 설계에서는 균열이 일어난 이후 철근콘크리트 부재의 인장영역에서 철근이 모든 인장력을 부담하는 것으로 가정한다. 그러나 균열 사이의 콘크리트가 실제 콘크리트 부재에서는 특히 사용하중 수준에서의 어느 정도의 인장 응력을 견디는데, 일조 하는 것으로 보고 있다. 이러한 효과를 Tension stiffening 효과라 한다. 본 연구에서는 Tension stiffening 모델과 고강도 철근 콘크리트 보의 휨 실험결과의 비교를 통해 해석모델의 유효성을 평가 하고자 한다. 이를 통해 선정 된 6가지의 Tension stiffening 모델과 실험에 의한 모멘트-곡률, 하중-처짐등을 관계를 평가하였다. 실험결과 설계기준에서는 ACI 318이 Tension stiffening 모델에서는 Owen & Damjanic이 실험 값과 가장 적은 오차율을 보이며 높은 신뢰도를 보였다.

Ultra high performance concrete which has recently been studied was developed to complement the brittle behaviour and dynamic uppermost limit of high strength concrete. Fiber reinforced concrete which mixed steel fiber is receiving attention as an alternative about this and is being developed to complement the disadvantages of high strength concrete including lower toughness coefficients and crack resistance and spalling in fires. Review about fiber reinforced ultra high strength concrete that this study tries to treat includes reduction of self shrinkage generated by high cement content per unit volume of concrete, evaluation of compression and tension strength to lower internal and external spalling resistance and fragility factors of member of framework, and flow characteristics of concrete which doesn't harden according to steel fiber amounts and used materials. As the result, the more fiber reinforcement increases, the more compression and tensile strength increase and deformation control of cement matrix and improvement of energy absorption ability showed the great effect in shrinkage reduction.

This paper intends to review possible application in the high strength area through compressive strength estimation of the simulated high strength concrete member using Rock Test Hammer and suggest it as a reference data for the strength estimation technique of the ultra high strength concrete in the future. From the results of test, in the low strength area less than 15MPa and normal strength area in 15∼60MPa, as shown on the existing studies, it is indicated that P Type Schmidt Hammer in the low strength area and N Type Schmidt Hammer in the normal strength area have high correlation of rebound-compressive strength. As the Rock Test Hammer indicated more or less reduced accuracy in the low strength area and the normal strength area but high correlation on the high strength area (50∼100MPa) defined on this test, it is determined that it would be possible to make the fastest and simplest compressive strength estimation on the site where the high strength concrete is applied. As was resulted above the experiments, on the basis of the result of Rebound Hardness Method and Compressive Strength on the high strength area which is over 50MPa, the conclusion is drawn which is Fc=4.409e0.059R through regression analizing the relations of Compressive Strength which is based on Rebound Hardness Method.

In this study, expedite curing period at curing temperature being 40, 60, 80℃ similar to strength of standard 28days curing temperature to confirm methods and applicability of early estimation of strength by warm water curing. Also, checked the effect related to different conditions such as using various kinds of material, differentiating quantity of material, with or without fiber mixing at same rate of water-bonding material. Existing method proposed by KS and JIS to estimate strength of 28 days standard curing temperature curing for 7days at 40℃ is not relevant because it takes so long to estimate strength. Already known method of estimating strength of 28days standard curing temperature curing for 3days in 60℃ warm water, too, is not relevant to apply 3day cycle of super high-rise. It also had the problem which didn’t consider fiber mixed concrete. According to the result of experiment, traits and rate of strength revelation were different relating to the kinds and quantity of bonding material. Strength value of mix without fiber was higher than that of mix with fiber, but without any relation to that, over 96% of similar confidence level with strength of 28 days standard curing temperature was shown in 7 days at 40℃, 3 days at 60℃, 2days at 80℃. Confidence level of estimation method of 2 days at 80℃ was similar to those of estimation methods of 4 days at 40℃, 3 days at 60℃, so it(2 days at 80℃) is regarded as the most relevant method because it’s possible to estimate strength fastly. As a result it can be said that early quality control of recently increasing super high-rise may be possible through estimation method of 2 days at 80℃.

In this study, prediction of later-age compressive strength of ultra-high strength concrete, based on the accelerated strength of concrete cured in hot water was investigated. Comparing other acceleration method, hot water curing method is relatively easy and intuitive to use in the real construction site. The amount of time for evaluation of the concrete strength using the hot water curing method in KS and JIS is too long to predict the strength of the ultra-high strength concrete that are used in the tall building structure. For that reason, curing temperature of 40, 50, 60℃ 3 levels were examined to shorten the amount of time for the evaluation of the strength. When curing in warm water, different strength characteristics are verified from the experiment. In case of F3 substituting 30% fly ash in combination, because of the curing temperature sensitivity of fly ash, differences of strength expression velocity was verified according to the curing temperature at the same age. In case of B4 substituting 40% ground granulated blast furnace slag, there were no big strength expression velocity differences of the specimen cured in 3 different level of curing temperature(40, 50, 60℃). The results show reliable accuracy by regression relation between 28day strength cured by standard curing method and accelerated strength of concrete cured in warm water.(y=1x-0.0002 R2=0.9866) As a result, the feasibility of 3day-prediction was confirmed using warm water curing method with accelerated strength of concrete cured for three days in warm water.

Strength bar has merits in workability improvement, construction time shortening and connection details to be easy. But, lap splice length tends to be longer. In this study, high strength threaded bar will be reviewed whether it is appropriate in domestic standards by KCI concrete structural criteria and propose the mechanical splice.

In case of general concrete, autogenous shrinkage is about 10% of the drying shrinkage. Therefore it was not considered significant to be a subject matter about managing the crack control and design. It was reported that cracks can be generated from the autogenous shrinkage. Because of the low W/B rate and the high unit binder of the high strength concrete. In this study, autogenous shrinkage and drying shrinkage are examined which is the main reason of the cracks of the high strength concrete based on the previous studies. Comparing the data from this study and previous studies, we developed the shrinkage reduced concrete using shrinkage reducing agent. The purpose of this study is to provide the data for reducing and managing the column shortening of the high strength concrete structures.

In this study, prediction of later-age compressive strength of ultra-high strength concrete, based on the accelerated strength of concrete cured in hot water was investigated. Comparing other acceleration method, hot water curing method is relatively easy and intuitive to use in the real construction site. The amount of time for evaluation of the concrete strength using the hot water curing method in KS and JIS is too long to predict the strength of the ultra-high strength concrete that are used in the tall building structure. For that reason, curing temperature of 40, 50, 60˚c 3 levels were examined to shorten the amount of time for the evaluation of the strength. As a result, the feasibility of the three days hot water curing method was confirmed.

High-performance concrete (HPC) is a new terminology used in concrete construction industry. Several studies have shown that concrete strength development is determined not only by the water-to-cement ratio but also influenced by the content of other conc

High-performance concrete(HPC) is a new terminology used in concrete construction industry. Several studies have shown that concrete strength development is determined not only by the water-to-cement ratio but also influenced by the content of other concrete ingredients. HPC is a highly complex material, which makes modeling its behavior a very difficult task. This paper aimed at demonstrating the possibilities of adapting artificial neural network (ANN) to predict the comprresive strength of HPC. Mahalanobis Distance(MD) outlier detection method used for the purpose increase prediction ability of ANN. The detailed procedure of calculating Mahalanobis Distance (MD) is described. The effects of outlier compared with before and after artificial neural network training. MD outlier detection method successfully removed existence of outlier and improved the neural network training and prediction perfomance.

Basic creep in concrete at an early age plays an important role in the mechancal properties of young concrete and many researches on this field have been carried out. According to recent some studies, however, it is the conclusion that for some cases the basic creep measured from the sealed concrete specimen shows inaccurate results. More specifically, for high-strength concrete (HSC), the incorrectness is more apparent due to autogenous shrinkage occurred at an early age. This paper shows the results obtained from experimental study to evaluate the effect of autogenous shrinkage on basic creep. In this study, four different mixture proportions of which primany test variable is water-cement ratio (w/c) were placed and autogenous shrinkage and basic creep tests on the specimen were performed with age and various loading levels. From this research, it was found that the differences between apparent creep and real creep were remarkable in HSC at an early age. Therefore, it is recommended to modify existing basic creep model equation by considering autogenous shrinkage.

As architectures have recently become high-risers and mega-structured, stable high strength products have been ensured. Accordingly, use of precast concrete accouplement has been increased in order to facilitate air compression and rationalize construction. Since external rising by the steam heating and internal rising by the accumulation of cement hydration heat for the temperature of members, precast concrete members with large cross-section used for high-rise mega-structure's columns and beams may exhibit different temperature history compared to the precast concrete members for wall and sub-floor with relatively small cross-sections. Therefore, this study aims to elucidate the characteristics of temperature history of mass concrete members cast with high-strength concrete for precast concrete application. In this study, large cross-sectional precast concrete mock-up, unit cement quantity, and temperature histories in manufacturing precast concrete member under different curing condition were inclusively investigated.

Recently, as architectural concrete structures become high-rise and megastructured, concrete become high-strengthened and, by ensuring products of more stability, and rationalization of construction are required.large cross-sectional precast concrete members such as columns show large temperature increase in manufacturing process not only by external heating but also by concrete itself's hydration heating. Therefore, it is expected that specimen for management to predict strength and compression strength of precast concrete member shows different strength characteristics. Conceming this, in order to suggest strength characteristics of high strength mass concrete suitable for precast concrete application, this study comprises the inclusive investigations on the relations between core strength and the strength characteristics per member cross-section dimensional value and per water-bonding material ratio value.

본 연구에서는 고강도 고내구성 시멘트콘크리트 포장을 위하여 도출된 배합 콘크리트의 굳지않은 콘크리트 특성, 강도발현 특성, 염소이온의 투수특성 및 동결-융해에 대한 저항성 등의 역학적 내구적 특성을 분석하였다. 제시된 배합의 목표스럼프와 공기량은 적절한 혼화제의 사용으로 확보가 가능하나, 혼화제의 적정사용량은 충분한 현장배합실험을 통하여 구하여야 할 것이다. 단위시멘트량을 증가한 경우 일반적으로 강도가 증가하였으며 특히 재령 28일 이후의 강도가 지속적으로 증가하는 양상을 나타내었다. 휨강도는 그 특성상 단위시멘트량을 증가하더라도 뚜렷한 효과는 나타나지 않았다. 염소이온 침투저항성도 단위시멘트량보다는 재령에 따른 영향을 더 크게 받는 것으로 나타났다. 공기량에 가장 많은 영향을 받는 동결-융해 저항성은 각 실험변수에 대한 시험체를 공기량이 3% 이하 및 이상인 경우에 대하여 그리고 동결시 수돗물을 사용한 경우와 현장의 열악한 환경을 모사하기 위하여 4%의 NaCl 용액을 사용한 경우로 구분하여 실시하였다. 공기량에 상관없이 수돗물을 사용한 경우에는 동결-융해반복회수가 300회까지 상대동탄성계수나 표면의 손상이 거의 발생하지 않았다. 4% NaCl 용액을 사용한 경우에는 단위시멘트량이 현재의 한국도로공사의 표준배합인 경우 손상이 발생하였으며, 단위시멘트량이 동결-융해 저항성에 미치는 영향이 큰 것으로 나타났다. 따라서, 동결-융해에 대한 저항성을 충분히 확보하는 고내구성의 시멘트콘크리트 포장을 위해서는 단위시멘트량을 현재의 수준보다 증가시키는 것이 유리한 것으로 판단되며, 실험결과로부터 이러한 요구성능을 발휘하기 위해서는 단위시멘트량을 400kg/m3 이상으로 할 것을 권장한다.

국내에서 시멘트콘크리트 포장이 차지하는 비율이 증가하는 수준에 비하여 이의 기술적인 발전은 상대적으로 뒤쳐져 있다고 할 수 있다. 또한, 사용기간의 증가와 함께 여러 가지 기술적인 문제점도 부각되고 있는 실정이다. 이에 본 연구에서는 외국의 콘크리트포장 배합의 특성을 분석하고 이를 기초로 한국의 실정에 부합하는 장수명의 고강고 고내구성의 콘크리트 포장의 최적배합을 도출하고자 하였다. 단위시멘트량, 잔골재율(S/a), 그리고 물-시멘트(W/C)비 등을 변수로 하여 배합에 대한 실험적 연구를 수행하였다. 장기적인 공용수명을 확보하고 고강도 고내구성의 포장을 위하여 우선적으로 단위시멘트량을 375kg/m3, 400kg/m3, 425kg/m3 수준으로 증가시킬 것을 권장한다. 또한, 최적배합표는 포장타설 장비를 활용하여 포설하므로 슬럼프 40mm로 결정하였고, 동결융해 방지를 위하여 공기량을 5%로 결정하였다. 또한 시공 시 재료 수급의 원활함을 위하여 굵은골재 최대 치수를 25mm로 결정하였다. 도로의 장수명을 위한 고강도 배합을 위해 낮은 W/C비와 단위시멘트량의 증가가 요구되는데, 예비실험 결과 공기연행제와 폴리카본산고성능 AE감수제를 사용하여 W/C비를 0.4까지 낮추어도 증가된 단위시멘트량에 대하여 충분히 목표 슬럼프를 가지는 배합이 가능한 것으로 나타났다. 예비 실험 결과 S/a를 0.34까지 낮추어도 골재의 분리 등 문제를 보이지 않고 충분히 배합이 가능하였으며, 이는 단위 시멘트페이스트 양의 증가로 인한 점착력 증가와 워커빌리티의 향상에 의한 것으로 판단된다.

본 연구에서는 콘크리트의 건조수축을 저감시키며 강도와 내구성을 높임과 동시에 콘크리트의 주간 태양광에 의한 반사도를 줄인 저수축, 저반사, 고강도, 고내구성, 콘크리트 포장재료를 개발하였다. 문헌조사를 바탕으로 건조수축 저감과 장기강도 발현에 효과가 있는 플라이 애쉬와 반사도를 저감시키기 위하여 검은색 안료를 넣고 강도와 내구성을 좋게 하기 위해 최적입도를 고려하여 배합설계를 하였다. 실내실험을 통해 검은색 안료의 첨가율에 따른 명암값과 반사율은 차이가 없는 것으로 나타났으며 최적입도를 고려하면 강도와 내구성에서 좋은 것으로 평가되었다. 또한 플라이 애쉬를 사용한 배합이 건조수축 저감에 효과가 있었으며 염화이온 침투 저항성도 높은 것으로 드러났다. 플라이 애쉬(25% 치환)와 검은색 안료(3% 첨가)를 넣고 최적입도를 고려한 배합이 건조수축과 반사율 저감, 강도와 내구성 향상에 가장 적합한 배합으로 판단하였다. 경제성 분석을 통하여 일반 콘크리트 포장보다 저수축 저반사 고강도 고내구성 콘크리트 포장이 초기공사비는 많은 것으로 분석되었지만 장기적인 관점에서 유지보수비용과 사회비용 감소로 인하여 경제성으로 타당한 것으로 나타났다.

CFT(Concrete Filled Steel Tube)기둥은 부재의 합성효과와 경제적인 측면 때문에 최근 고층건물 시공 시 널리 쓰이고 있다. 그러나 기존의 연구문헌을 살펴보면 CFT 기둥은 강관의 항복이후 강관의 일정지점에 국부좌굴이 생기는 단점을 지니고 있다. 이러한 문제점을 해결하기 위하여 예상 국부좌굴부위를 탄소섬유쉬트로 보강하여 국부좌굴을 방지하거나 지연시키는 TR-CFT (Transversely Reinforced Concrete Filled Steel Tube) 기둥에 관한 연구가 진행되고 있다. 본 연구에서는 고강도 콘크리트를 사용한 TR-CFT기둥의 실험을 수행하였으며 휨내력에 대한 해석을 수행한 결과 실험값과 해석값이 잘 일치하였다. 또한 기존의 ACI 318 설계법은 강관내부에서 발생하는 콘크리트에 대한 구속효과를 고려하지 않아 저평가가 되어있음을 알 수 있었다.