천연골재의 부족으로 골재 수급이 날이 갈수록 심각해지면서 재활용 가능한 재료에 대한 사회적 관심이 높아지고 있다. 하지만 국내에서는 선진외국에 비해 순환골재에 대한 연구데이터와 그를 사용한 현장 적용실정이 매우 부족한 실정이다. 본 논문에서는 현장에서 사용하는 레미콘 사의 가이드 배합에 순환골재를 전량 치환하는 배합비를 추출하여 압축강도를 평가하였 고 추출된 배합비의 순환골재 콘크리트를 원형강관 내부에 충전하여 순환골재콘크리트충전 합성기둥이 국내ㆍ국외 설계식을 반 영한 내력과 비교하여 구조부재로써 사용이 적합하다고 사료되는 결과를 얻었다. 또한, 강관의 콘크리트 구속효과로 인해 강관 내부의 콘크리트 강도가 미세하게 증가함을 확인하였다.

정확도 높고, 실용적으로 손쉽게 사용될 수 있는 온수양생 방법을 표준화하고 이를 통한 콘크리트 압축강도 예측방법을 제시하고자 변수 실험을 진행하였다. 전양생 시간, 온수양생 온도, 온수양생 시간에 대한 변수실험을 통해 18시간 전양생 시간, 70℃ 온수양생 온도, 24시간 온수양생시간의 온수양생시험 표준 조건을 제시하였다. 온수양생시험 표준 조건에 대한 추가적인 배합시험을 통해 콘크리트의 압축강도를 조기에 산정할 수 있는 선형 추정식을 산정하였고, 압축강도 추정식의 높은 신뢰도를 확인하였다. 또한, 혼화재 종류 및 혼화재 치환율 변수에 대한 온수양생시험을 통해 온수양생을 통한 콘크리트 압축강도 조기 추정방법은 시멘트 종류, 혼화재 종류 및 치환율, 골재의 종류가 동일한 배합에 대해서만 그 적용이 가능하다는 결론을 도출하였다.

The contemporary high-tech structures have become enlarged and their functions more diversified. Steel concrete structure and composite material structures are not exceptions. Therefore, there have been on-going studies on fiber reinforcement materials to improve the characteristics of brittleness, bending and tension stress and others, the short-comings of existing concrete. In this study, the purpose is to develop the estimated model with dynamic characteristics following the steel fiber mixture rate and formation ration by using the nerve network in mixed steel fiber reinforced concrete (SFRC). This study took a look at the tendency of studies by collecting and analyzing the data of the advanced studies on SFRC, and facilitated it on the learning data required in the model development. In addition, by applying the diverse nerve network model and various algorithms to develop the optimal nerve network model appropriate to the dynamic characteristics. The accuracy of the developed nerve network model was compared with the experiment data value of other researchers not utilized as the learning data, the experiment data value undertaken in this study, and comparison made with the formulas proposed by the researchers. And, by analyzing the influence of learning data of nerve network model on the estimation result, the sensitivity of the forecasting system on the learning data of the nerve network is analyzed.

Impact damage tolerance is an important design requirement for composite structures. In this study, the effect of post impact damage and hole size of the composite sandwich skin / sandwich with core specimen on compressive strength of the laminate was analyzed. Three specimen tests were performed in this research. Two tests were carried out on pure bending test specimens subjected to impact damage to the skin and specimen with a hole in one of its skin as a damage. Through this test, we compared the reduction of compressive strength due to the size of skin damage and the size of the hole. Also, core-free specimen with an open hole under uniaxial loading were tested to produce reference data for comparison with the series tested earlier. As results of the tests, the sandwich beams with damage size and open hole are almost identical, and we concluded that the prediction of compressive strength reduction after impact of the sandwich skin structure can be predicted using an analytical model assuming skin open hole as impact inputs.

Recently, as the number of earthquakes has increased, the building structure standard has been revised in 2016. In order to minimize earthquake damage, steel frame is used as the most economical and efficient lateral resistance system. Also, when the steel braces are subject to Compressive load, which causes unstable behavior of the structure. In order to verify the compressive behavior of the reinforced Braces, structural performance tests were conducted with variables of slenderness ratio and the amount of reinforcement. This study investigates the structural performance of existing double - angle steel braces by reinforcing them with non- welded/assembled light-weight steel frames and proposes a suitable reinforced section.

일반골재인 자갈, 모래와 중량골재인 산화 슬래그 및 자철광을 이용하여 5 종류의 콘크리트를 제작하여 감마선 차폐특성과 압축강도를 살펴보았다. 골재는 평균적인 크기에 따라 비교적 작은 크기의 잔골재와 큰 크기의 굵은 골재로 구분하여 사용하였다. 실험 결과 산화 슬래그 잔골재와 굵은 골재를 사용한 콘크리트가 일반 골재만을 이용하여 배합한 콘크리트 시 편보다 137Cs 감마선에 대해 2% 향상된 감쇠계수인 0.371 cm-1을 기록하였다. 각 시편들의 단위중량을 측정한 결과 자철광 잔골재와 산화 슬래그 굵은 골재로 배합한 조건의 단위중량이 가장 높은 3,175 kg·m-3이었다. 산화슬래그를 잔골재와 굵은 골재로 배합한 조건의 단위중량은 3,052 kg·m-3으로 최대 단위중량 조건보다 123 kg·m-3 낮았지만 감쇠계수는 오히려 0.012 cm-1 향상되었다. 골재들의 화학성분 분석결과 산화 슬래그는 자철광에 비해 마그네슘의 비율은 낮고 칼슘의 비율은 높아 구성에 있어서 차이를 보였다. 따라서 산화슬래그만을 골재로 사용한 경우 자철광을 잔골재로 사용한 경우보다 단위 중량은 낮았지만 마그네슘과 비교하여 원자번호가 큰 칼슘의 비율이 높아서 감마선 차폐성능이 향상된 것으로 생각된다. 중량골재가 배합된 모든 시편들은 일반 골재를 이용한 콘크리트보다 압축강도가 높았고, 산화슬래그와 자철광의 잔골재만을 사용한 경우 4주 양생 후 압축강도가 일반 콘크리트에 비해 45% 향상된 50.2 MPa을 기록하였다.

More Roller-compacted concrete (RCC) is a dry concrete consisted of same materials as conventional concrete with different proportioning which requires compaction effort in order to reach its final form. Thus, both hydration and aggregate interlock play important roles in its strength augmentation. Flexural strength, an important factor in pavement design and fatigue cracking resistance, can be difficult to be obtained at in-situ and may be subjected to high variability. Even though its compressive strength is relatively high compared to conventional concrete with similar binder content, the relationship between compressive strength and flexural or tensile strength were not well defined. The goal of this research is to compare the relationship between compressive strength and flexural strength as well as the relationship between compressive strength and splitting tensile strength of RCC with those of conventional concrete using various equations suggested in other researches and also to determine new regression equations for estimating RCC’s flexural and splitting tensile strength. The positive result of RCC’s flexural strength was found; it was higher than majority of predicted values from conventional concrete for the same compressive strength. In contrast, RCC’s splitting tensile strength was relatively low compared to that of conventional concrete for the same compressive strength. Power equations were learned to be suitable for relationship between compressive and flexural strengths as well as relationship between compressive and splitting tensile strengths.

Fly ash is one of the aluminosilicate sources used for the synthesis of geopolymers. The particle size distribution of fly ash and the content of unburned carbon residue are known to affect the compressive strength of geopolymers. In this study, the effects of particle size and unburned carbon content of fly ash on the compressive strength of geopolymers have been studied over a compositional range in geopolymer gels. Unburned carbon was effectively separated in the -46μm fraction using an air classifier and the fixed carbon content declined from 3.04 wt% to 0.06 wt%. The mean particle size (d50) decreased from 22.17μm to 10.79μm. Size separation of fly ash by air classification resulted in reduced particle size and carbon residue content with a collateral increase in reactivity with alkali activators. Geopolymers produced from carbon-free ash, which was separated by air classification, developed up to 50 % higher compressive strength compared to geopolymers synthesized from raw ash. It was presumed that porous carbon particles hinder geopolymerization by trapping vitreous spheres in the pores of carbon particles and allowing them to remain intact in spite of alkaline attack. The microstructure of the geopolymers did not vary considerably with compressive strength, but the highest connectivity of the geopolymer gel network was achieved when the Si/Al ratio of the geopolymer gel was 5.0.

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℃.

This study considered the effect of the heat treatment temperature on the compressive strength of coal powder compacts affected by density, porosity, and crystallinity. Coal powder compacts were made by pressing of milled coal powder and were heat treated at 200, 400, 600, 800, and 1000℃. The density and porosity of the heat treated specimens at each temperature were measured using the Archimedes method and changes in crystallinity were analyzed using Raman spectroscopy. Increases in compressive strength at 600℃ or higher temperatures were proportionally related to increases in the density and the degree of crystallinity.

Geopolymer cements and geopolymer resins are newly advanced mineral binders that are used in order to reducethe carbon dioxide generation that accompanies cement production. The effect of additives on the compressive strength ofgeopolymerized class-F fly ash was investigated. Blast furnace slag, calcium hydroxide(Ca(OH)2), and silica fume powders wereadded to fly ash. A geopolymeric reaction was initiated by adding a solution of water glass and sodium hydroxide(NaOH) tothe powder mixtures. The compressive strength of pure fly ash cured at room temperature for 28 days was found to be as lowas 291kgf/cm−2, which was not a suitable value for use in engineering materials. On the contrary, addition of 20wt% and40wt% of blast furnace slag powders to fly ash increased the compressive strength to 458kgf/cm−2 and 750kgf/cm−2,respectively. 5wt% addition of Ca(OH)2 increased the compressive strength up to 640kgf/cm−2; further addition of Ca(OH)2further increased the compressive strength. When 2wt% of silica fume was added, the compressive strength increased to 577kgf/cm−2; the maximum strength was obtained at 6wt% addition of silica fume. It was confirmed that the addition of CaO andSiO2 to the fly ash powders was effective at increasing the compressive strength of geopolymerized fly ash.

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.

When a new bonding agent using coal ash is utilized as a substitute for cement, it has the advantages of offering a reduction in the generation of carbon dioxide and securing the initial mechanical strength such that the agent has attracted strong interest from recycling and eco-friendly construction industries. This study aims to establish the production conditions of new hardening materials using clean bottom ash and an alkali activation process to evaluate the characteristics of newly manufactured hardening materials. The alkali activator for the compression process uses a NaOH solution. This study concentrated on strength development according to the concentration of the NaOH solution, the curing temperature, and the curing time. The highest compressive strength of a compressed body appeared at 61.24MPa after curing at 60˚C for 28 days. This result indicates that a higher curing temperature is required to obtain a higher strength body. Also, the degree of geopolymerization was examined using a scanning electron microscope, revealing a micro-structure consisting of a glass-like matrix and crystalized grains. The microstructures generated from the activation reaction of sodium hydroxide were widely distributed in terms of the factors that exercise an effect on the compressive strength of the geopolymer hardening bodies. The Si/Al ratio of the geopolymer having the maximum strength was about 2.41.

콘크리트에서 강도는 콘크리트의 물리적 특성을 평가할 수 있는 중요한 인자 중 하나이며 콘크리트에 가장 많은 부피를 차지하는 것이 골재이다. 또한 시멘트는 콘크리트 만드는 결합재로서 이 역시 강도와 매우 밀접한 관계가 있다. 이러한 골재와 시멘트의 특성이 콘크리트 압축강도와 전단파 속도의 상관관계에 미치는 영향을 파악하고자 굵은 골재 최대치수와 시멘트 종류별로 실험을 실시하였다. 시멘트는 1종 시멘트와 초속경 시멘트를 사용했고, 골재는 서로 다른 지역의 3가지 골재를 사용하였다. 골재의 입도는 굵은 골재 최대치수 19mm와 13mm의 단입도 골재를 사용하여 동일 배합시 압축강도와 전단파 속도의 상관관계를 살펴보았다. 또한 골재의 특성을 정량화 하고자 LA마모시험을 실시하였다. 그 결과 압축강도와 전단파 속도의 상관관계는 시멘트 종류에 따라 달랐으나, 골재의 종류, 입도 및 마모감량에 관계없이 일정한 상관성을 보이는 것으로 나타났다.