국가관리 간척지내 원예단지 조성에 필요한 기반기술 중에 하나인, 온실기초 연구가 부족한 실정이며 고사양의 PHC파 일을 대체하기 위한 대안을 검토하고자 하였다. 지반개량공법 중 심층혼합처리공법(DCM) 적용시 허용지지력과 침하량 산정을 통하여 온실기초 공법으로써의 적용가능성을 검토하였다. 새만금간척지 농생명용지 1공구 지반조사를 통해 지반 특성을 파악하고, Terzaghi, Meyerhof, Hansen, Schmertmann 이론식을 적용하여 허용지지력과 침하량을 산정하였다. 직경 800mm를 기준으로, 독립 기초 폭과 길이가 3－6m 이고, 기초 심도 3－7m 조건에서 허용지지력과 침하량을 검토하였다. 온실기초 심도가 얕고 콘크리트 매트 간격이 넓을수록 시공비가 절감되는 측면을 고려하여 독립 기초 폭과 길이가 4m, 기초 심도가 3m인 경우가 가장 적합한 것으로 판단 되었다. 독립 기초 폭과 길이가 4m이고, 기초 심도가 3m인 조 건에 대한 해석 결과로 허용지지력은 169kN/m2, 침하량은 2.73mm로 지지력은 이론식 대비 5.6%의 오차를, 침하량은 62.3%의 오차범위를 나타냈다. 향후, 위 검증된 설계 값을 기준으로 구조 시험과 침하모니터링을 통해 신뢰성을 검증하고자 한다. 그 외 나무말뚝, 헬리컬기초 등 유리온실, 내재해형온 실에 적용 가능한 기초 공법과의 비교 검증을 통해 각각의 장, 단점을 파악하고 PHC 파일의 대체 가능 유무를 검토할 예정이다. 이는 온실 유형별 시공 공법을 선정하는데 필요한 기초 데이터로 제시될 수 있을 것으로 기대된다.

최근 대규모 토목 및 건축 구조물 증가 추세로 건설 부재의 고강도 및 경량화에 대한 수요가 높아지고 있다. 기존 시멘트 경량 복합체의 경우 단위 체적 중량이 낮아 강도 저하 문제가 발생할 수 있다. 보통 경량화를 위해서 시멘트 복합체를 배합할 때 일반 경량골재와 고무재질의 경량골재, 플라스틱 펠릿 등 다양한 인공 경량골재를 적용한 시멘트 복합체로 경량화를 확보할 수 있다. 이 중에서도 시멘트 복합체의 인공 경량골재로 플라스틱을 사용하면 상대적으로 골재 자체의 강도를 확보하면서 경량화를 꾀할 수 있지만 재료의 매끄러운 표면 특성으로 인해 시멘트 페이스트와 부착하는 데 불리한 부분이 있고 이는 콘크리트 골재 또는 시멘트 복합체 골재로서의 사용에 있어 단점이 된다. 띠라서 이번 연구에서는 기존 연구에서 플라스틱 골재 로 가장 적합한 유형으로 확인된 PP, PE 두가지 유형의 플라스틱 골재와 강섬유, 양생방법을 변수로 하여 실험을 진행하였고 실험 결과 플라스틱의 비중이나 표면 재질뿐만 아니라 강섬유의 혼입유무, 양생방법에 의해서 시멘트 복합체의 물리적 특성이 변화된다는 것을 확인하였다.

PURPOSES : For high driving performance and service life of cement concrete pavement, construction quality must be secured. The construction quality is to be measured after pavement construction, but in this case, it is difficult to improve construction quality. Therefore, it is necessary to develop a method for measuring and correcting the profile of the pavement and subbase so that the construction quality can be monitored immediately after construction. METHODS : The device that can measure the construction quality of cement concrete pavement has been developed. Through the experiment simulating the field situation, the profile of the pavement and subbase was measured and calibration method was developed. RESULTS : In the measured profile, an outlier by the sensor and noise by the sensor and vibration were measured, and a step-like profile was measured differently from the acture one. To remove outliers, the boxplot outlier removal method was applied by overlapping each data group. The noise were removed by a low pass filtering. And, it was calibrated to a profile similar to the acture one through the sampling interval adjustment and the weighted moving average method. CONCLUSIONS : The method that can measure and calibrate the profile that is almost identical to the actual one has been developed. Accordingly, it is expected that the performance of the pavement can be improved by accurately monitoring the construction quality immediately after construction.

The use of recycled materials, such as the fine recycled aggregate made from concrete waste and carbon fiber (CF) product of industrial waste, for the manufacture of conductive recycled mortars (CRM), transforms the mortar base cement normally made with cement:sand in a sustainable multifunctional material, conferring satisfactory mechanical and electrical properties for non-structural uses. This action provides ecological benefits, reducing the use of natural fine aggregates from rivers and the amount of concrete waste deposited in landfills resulting from construction waste. In this investigation the effect of the addition of CF on electrical properties in hardened, wet and dry state, electric percolation in dry state and fluidity of the wet mixture of a cement based CRM was evaluated: fine recycled aggregate: graphite powder, CRM specimens with dimensions of 4 × 4 × 16 cm. were manufactured for 3, 7 and 28 days of age and sand/cement ratios = 1.00, graphite/cement = 1.00, water/cement = 0.60 and CF = 0.1, 0.3, 0.5, 1.0, 1.5, 2.0, 2.5 and 3.0% compared to the weight of cement. The results demonstrated the effect of the addition of CF in CRM, reducing fluidity of the mixtures due to the opposition generated by its physical interaction of CF with recycled sand or recycled fine aggregate and graphite powder (GP), in its case, placing the electric percolation percolation at 0.30% and 0.45% of CF for CRM with and without GP, respectively. Increases in electrical conductivity (EC) without the presence of GP are defined by the contact between the CF and the conductive paths formed. In contrast, with the presence of GP, the EC is defined by the contact between the CF and the GP simultaneously, forming conductive routes with greater performance in its EC.

PURPOSES : In this study, an ASR-reducing (alkali-silica reaction) cement was developed to prevent the blow-up of concrete pavements. To develop ASR-reducing cement, various amounts of ground granulated blast furnace slag (GGBFS), and fly ash (FA) were substituted with Portland cement, and the ASR reduction effect was verified through various experiments. METHODS : The physical properties of ASR-reducing cement, varying with the substitution amounts of GGBFS and FA, were verified through compressive strength tests. In addition, the ASR reduction effect was examined using accelerated mortar bar tests. Furthermore, the reasons for the ASR reduction were investigated using microstructural analysis techniques, such as XRD and TG/DTG. RESULTS : There was a difference in the compressive strength results according to the amount of GGBFS and FA substitution. In addition, the samples with GGBFS and FA exhibited relatively lower compressive strengths at 3 days, than OPC samples, but the compressive strength at 28 days was higher than that of the OPC samples. The samples with GGBFS and FA had higher compressive strength at 28 days than OPC samples, because the substituted GGBFS and FA induced pozzolanic reaction. Through XRD and TG/DTG analyses, various degrees of pozzolanic reaction occurring in the samples were examined, and a more active pozzolanic reaction occurred in the samples with FA than in the samples with GGBFS. Therefore, it appeared that the ASR reduction effect occurred because of the induced pozzolanic reaction. CONCLUSIONS : GGBFS and FA substituting Portland cement indicated an ASR reduction effect, which was owing to the pozzolanic reaction. In addition, FA indicated a greater ASR reduction effect than GGBFS, which suggested that FA induced a more active pozzolanic reaction than GGBFS.

초고성능 콘크리트(UHPC)는 낮은 물-결합재비(W/B), 고성능 감수제(SP), 혼화재 및 강섬유(Steel Fiber)의 혼입으로 일반 콘크리트보다 유동성, 강도 등에서 월등히 우수한 성능을 지닌 건설 재료이다. 본 연구에서는 진동밀로 분쇄하여 시멘트의 분말도를 6000cm2/g급 까지 높여 최적의 초고성능 모르타르를 제작하였다. 또한, UHPC의 특성상 시멘트, 혼화재뿐만 아니라 화학 혼화제 혼입량에 따라 물성에 많은 차이를 나타내기 때문에 최적의 화학 혼화제를 도출하기 위하여 고성능 혼화제에 따른 물성 평가 실험도 수행하였다. 분쇄된 시멘트를 활용한 초고성능 모르타르의 유동성, 강도 등 물성 테스트를 진행하였으며, 경제성을 고려하여 강섬유와 기타 혼화재를 혼입하지 않고 목표 물성을 달성하고자 하였다. 실험결과, 모든배합에서 플로우 값은 목표치 180±10mm를 확보하였으며, W/B 20%, SP 0.8%에서 최대 압축강도 90MPa, 휨강도 16.8MPa까지 나타났다.

The bone cement used for vertebroplasty must be sufficiently injectable. The introduction of granules reduces the amount of liquid required for liquefaction, implying that higher fluidity is achieved with the same amount of liquid. By employing β-tricalcium phosphate granules with an average diameter of 50 μm, changes in injectability are observed based on the paste preparation route and granular fraction. To obtain acceptable injectability, phase separation must be suppressed during injection, and sufficient capillary pressure to combine powder and liquid must work evenly throughout the paste. To achieve this, the granules should be evenly distributed. Reduced injection rates are observed for dry mixing and excessive granular content, owing to phase separation. All these correspond to conditions under which the clustered granules weakened the capillary pressure. The injected ratio of the paste formed by wet mixing displayed an inverted U-type shift with the granular fraction. The mixture of granules and powder resulted in an increase in the solid volume fraction, and a decrease in the liquid limit. This resulted in the enhancement of the liquidity, owing to the added liquid. It is inferred that the addition of granules improves the injectability, provided that the capillary pressure in the paste is maintained.

The mechanical properties and microstructures of hexagonal boron nitride (h-BN)-reinforced cement composites are experimentally studied for three and seven curing days. Various sizes (5, 10, and 18 μm) and concentrations (0.1%, 0.25%, 0.5%, and 1.0%) of h-BN are dispersed by the tip ultrasonication method in water and incorporated into the cement composite. The compressive strength of the h-BN reinforced cements increases by 40.9%, when 0.5 wt% of 18 μm-sized h-BN is added. However, the compressive strength decreases when the 1.0 wt% cement composite is added, owing to the aggregation of the h-BNs in the cement composite. The microstructural characterization of the h-BN-reinforced cement composite indicates that the h-BNs act as bridges connecting the cracks, resulting in improved mechanical properties for the reinforced cement composite.

최근에는 대규모 건축 및 토목 구조물로 인해 건설 부재의 고강도 및 경량화에 대한 요구가 높아지고 있다. 기존의 경량 시멘트 복합체의 경우 단위 체적 중량이 낮아질 수 있으나 강도 저하 문제가 발생한다. 일반적으로 경량화를 위해서는 시멘트 복합체를 배합할 때 일반 경량골재와 고무경량골재, 플라스틱 펠릿 등 다양한 인공 경량골재를 이용한 시멘트 복합체를 혼 합하여 경량화를 확보할 수 있다. 이 중 시멘트 복합체의 인공 경량골재로 플라스틱을 사용하면 상대적으로 골재 자체의 강도를 확보할 수 있지만 재료의 표면 특성으로 인해 시멘트 페이스트에 부착하는데 불리하고 골재로서의 사용이 불리하다. 이에 본 연구에서는 골재로 가장 적합한 플라스틱의 유형을 선택하기 위해 다양한 유형의 플라스틱 시멘트 화합물을 변수로 하여 실험을 진행하였고 실험 결과 플라스틱의 비중이나 표면 재질에 의해서 시멘트 복합체의 물리적 성질이 변화하는 것을 확인할 수 있었다.

Two waste forms, namely cement and geopolymer, were investigated and tested in this study to solidify the corrosive sludge generated from the surface and precipitates of the tubes of steam generators in nuclear power plants. The compressive strength of the cement waste form cured for 28 days was inversely proportional to waste loading (24.4 MPa for 0wt% to 2.7 MPa for 60wt%). The corrosive sludge absorbed the free water in the hydration reaction to decrease the cementation reaction. When the corrosive sludge waste loading increased to 60wt%, the cement waste form showed decreased compressive strength (2.7 MPa), which did not satisfy the acceptance criteria of the repository (3.45 MPa). Meanwhile, the compressive strength of the geopolymer waste form cured for 7 days was proportional to waste loading (23.6 MPa for 0wt% to 31.9 MPa for 40wt%). The corrosive sludge absorbed the free water in the geopolymer when the water content decreased, such that a compact geopolymer structure could be obtained. Consequently, the geopolymer waste forms generally showed higher compressive strengths than cement waste forms.