PURPOSES: The objective of this study is to evaluate the properties of high-performance concrete and compare them with the properties of ternary blended cement (OPC 60% : BFS 30% : FA 10%) as applied to all-in-one bridge decks. High-performance concrete modified with styrene-butadiene latex (SB latex) was evaluated for strength development and durability through its compressive strength and chloride ion diffusion coefficient. METHODS: The compressive strength test was conducted according to KS F 2405, and the average value of the three specimens was used as the result at each stage. The chloride ion diffusion test was performed at 28 days, 56 days, and 365 days according to NT BUILLD 492. The chloride ion penetration test was conducted according to ASTM C 1202. RESULTS: For the compressive strength of the high-performance concrete, the blast furnace slag 40% replacement (BFS40) mixture had the most similar results to those of the ternary blended cement. The BFS40 mixture exhibited a lower compressive strength at 3 days than the latex modified concrete (LMC) mixture used for the bridge deck pavement, whereas it exhibited a 3.7-9.8% higher compressive strength at 7 days. In addition, the BFS40 mixture had the lowest diffusion coefficient, which was 49.1~59.0% lower than that of the LMC mixture. Mixing with latex tended to decrease in charge passed compared to Plain which is only used ternary blended cement, and showed excellent watertighness (rated “very low”), which is lower than 1,000 coulombs in all mixtures with latex. CONCLUSIONS : The BFS40 mixture exhibited excellent compressive strength, chloride ion permeability resistance, and the lowest chloride ion diffusion coefficient although it included a small amount of latex, which makes it more expensive than the current LMC mixture. It is believed that it is possible to secure excellent economic efficiency and durability by using lesser latex than that in the LMC mixture and using a mixture of the blast furnace slag instead.

PURPOSES: The object of this study is to select appropriate inorganic materials, and find the best mixing formula to secure fast curing time and enough initial strength, and then to evaluate the durability of the asphalt mixtures according to the degree of addition of the compound manufactured by the determined blending ratio. METHODS : The breaking time and reactivity between seven kinds of inorganic minerals, and the selected recycled aggregate and emulsified asphalt were compared to determine the best initial curing strength for the mixtures. Then, three inorganic materials were chosen as the materials that provide good breaking time and reactivity, and the best mixing formula for the three materials was determined. The chemical composition of the compound manufactured using the mixing formula was analyzed by energy dispersive x-ray system method. Finally, indirect tensile strength (ITS) test was performed (for two days) at room temperature to determine the proper amount of additives that will provide the best initial strength. RESULTS: From the results of the reactivity test, the best mixing formula (A:C:G = 60:30:10) for the three selected inorganic materials with short braking time and high reactivity was determined. The four types of cold reclaimed asphalt mixtures for ITS testing were manufactured by adding the inorganic material compounds at 0%, 3%, 5%, and 7%, and the ITS values were measured after two curing days. The ITS values at 5% and 7% were 0.308 MPa and 0.415 MPa, respectively. The results of quality control tests (Marshall stability, porosity, flow value, etc.) at 5% and 7% satisfied the specification criterion for the cold recycled asphalt mixtures. CONCLUSIONS : The selected inorganic materials (A, C, and G) and the best mixing formula (A:C:G = 60:30:10) accelerated the reaction with emulsified asphalt and shortened the curing time. Depending on the inorganic material used, the breaking time and reactivity can be directly related or unrelated. This is because of the chemical compositions of recycled aggregates, infiltrated foreign matter, and chemical reactions between the inorganic materials and other materials. Therefore, it is important to select the proper materials and the best mixing formula when evaluating the characteristics of the practically used materials such as recycled aggregates, inorganic materials, and emulsified asphalt.

PURPOSES: This study investigates the effect on concrete pavement accordance with the curing methods in cool weather and supports the best method in the field. METHODS: Two field tests evaluated the curing methods of concrete pavement in cool weather. Firstly, five curing methods were tested, including normal curing compound, black curing compound, bubble sheet, curing mat, and curing mat covered with vinyl. Concrete maturity was compared from temperature data. Secondly, normal curing compound and curing mat with vinyl, which showed the best performance, were compared in terms of maturity and join condition index. RESULTS: From the field tests, it is an evident that curing mat with vinyl accelerated the concrete strength. Therefore, it is possible to conduct saw-cut works in cool weather, which minimizes damage on concrete at joint. CONCLUSIONS: For concrete pavement in cool weather, using curing mat with vinyl as the curing method could overcome the strength delay. Therefore, strength and durability problems on concrete at joint due to cool weather would be fewer in the future.

PURPOSES : This paper focuses on strength development according to the mix design with cement type and mineral admixture from laboratory and field tests in cool weather. METHODS : Two methods evaluated the mix design of concrete pavement in cool weather. Firstly, laboratory tests including slump, air contents, setting time, strength, maturity, and freezing-thawing test were conducted. Three alternatives were selected based on the tests. Secondly, a field test was conducted and the optimum mix design in cool weather was suggested . RESULTS : It is an evident from the laboratory test that a mix with type Ⅲ cement showed better performance than the one with type Ⅰ cement. There was a delay in strength development of a mix with mineral admixture compared to mix design without any mineral admixture. In the field test, type Ⅲ cement+flyash 20% mix design proved the best performance. CONCLUSIONS : For concrete pavement in cool weather, mix design using type Ⅲ cement could overcome the strength delay due to mineral admixture. Moreover, it is possible to make sure of durability of pavement. Therefore, strength and durability problems due to cool weather would decrease.

PURPOSES: In this study, we analyzed the compressive strength characteristics of lean base concrete in relation to changes in the outdoor temperature after analyzing the cold and hot weather temperature standards and calculated the minimum and maximum temperatures when pouring concrete. We examined the rate of strength development of lean base concrete in relation to the temperature change and derived an appropriate analysis formula for FRC base structures by assigning the accumulated strength data and existing maturity formula. METHODS: We measured the strength changes at three curing temperatures (5, 20, and 35℃) by curing the concrete in a temperature range that covered the lowest temperature of the cold period, 5℃, to the highest temperature of the hot period, 35℃. We assigned the general lean concrete and FRC as test variables. A strength test was planned to measure the strength after 3, 5, 7, 14, and 28 days. RESULTS : According to the results of compressive strength tests of plain concrete and FRC in relation to curing temperature, the plain concrete had a compressive strength greater than 5 MPa at all curing temperatures on day 5 and satisfied the lean concrete standard. In the case of FRC, because the initial strength was substantially reduced as a result of a 30% substitution of fly ash, it did not satisfy the strength standard of 5 MPa when it was cured at 5℃ on day 7. In addition, because the fly ash in the FRC caused a Pozzolanic reaction with the progress into late age, the amount of strength development increased. In the case of a curing temperature of 20℃, the FRC strength was about 66% on day 3 compared with the plain concrete, but it is increased to about 77% on day 28. In the case of a curing temperature of 35℃, the FRC strength development rate was about 63% on day 3 compared with the plain concrete, but it increased to about 88% on day 28. CONCLUSIONS: We derived a strength analysis formula using the maturity temperatures with all the strength data and presented the point in time when it reached the base concrete standard, which was 5 MPa for each air temperature. We believe that our findings could be utilized as a reference in the construction of base concrete for a site during a cold or hot weather period.

기존의 생활 및 사업장 폐기물 등으로 발생하는 병유리를 파쇄 및 재활용 시 불가피하게 섞이게 되는 자기분은 도자기 자체의 강도를 늘리며 기면을 광택이 나도록 하는 유약성분이 포함되어 있다. 이러한 유 약성분을 함유하고 있는 도자기를 성분 분석한 결과, 공통적으로 P2O5라고 하는 오산화인이 상당부분 포함되어 있었으며, 시멘트 대체재료로 활용시 콘크리트의 응결시간을 지연한다는 연구결과가 발표되었다. 따라서 본연구에서는 향후 폐유리 미분말을 이용하여 콘크리트를 제작할 시 발생할 수 있는 응결지연 문제를 방지하기 위해 품질관리 범위를 도출하고자 한다. 이를 위하여 자기분 유약 성분의 초결 지연에 따른 강도 발현에 미치는 영향을 각 재료별로 비교 및 검토하였다. 본 시험은 KS L 5108에 따라 수행되었으며, 사용된 변수는 표 1과 같다. 이 표에서 OPC는 시멘트만을 사용한 페이스트이고, WG는 폐유리 미분말이며, WP는 폐자기 미분말이다. 분석결과, 폐자기를 시멘트 대비 5% 혼입한 페이스트의 경우, OPC (일반 페이스트)의 응결시간보다 지연되는 현상이 발생하였다. 초결은 15초정도 지연되었고, 종결은 10초정도 지연되는 결과가 도출되었다. 또한 폐유리 미분말과 폐자기 미분말을 각각 9:1 및 8:2로 혼입한 페이스트의 경우, 폐자기를 단독으로 사용한 페이스트에 비해 상당히 빠른 응결시간이 측정되었다. 따라서 이러한 시험 결과를 바탕으로 향후 폐자기 혼입에 대한 품질관리 방안을 마련할 시, 폐유리 미분말을 이용한 콘크리트의 시장성은 더욱 넓혀질 것으로 기대된다.

탄산칼슘 형성 미생물은 요소(CO(NH2)2)의 가수분해를 통해 탄산염이온(CO3 2-)을 생성하고, 분해된 탄산 염이온은 칼슘이온(CO3 2+)과 결합하는 탄산칼슘형성작용(Microbially Induced Calcite Precipitation)을 하는 것으로 알려져 있다. Muynck et al.(2008)은 탄산칼슘(CaCO3) 형성 미생물을 콘크리트에 적용하여, 자가 균열보수 및 강도 증진 효과의 가능성을 언급하였다. 이러한 탄산칼슘 형성 미생물을 콘크리트 도로포장에 적용할 경우, 경화 시 발생하는 미세균열을 방지하고, 초기강도 증진효과를 얻을 수 있으며, 장기강도 및 공용성을 증진시킬 수 있을 것으로 예상된다. 따라서 본 연구는 탄산칼슘 형성 미생물을 콘크리트 포장에 적용하기 위한 기초연구로서, Lysobacillus sphaericus종의 탄산칼슘형성 미생물을 적용시킨 시멘트 모르타르에서 탄산칼슘 형성량과 초기강도 발현을 확인하였다. 이를 위해, SEM 촬영 및 EDS 분석을 실시하여 탄산칼슘 형성능력을 비교하였고, 3일, 7일 28일 압축강도 시험을 통해 초기강도를 측정하였다. SEM(Scanning Electron Microscope) 촬영 결과, 미생물에 의해 탄산칼슘이 형성된 공시체의 단면은 그림 1(a)와 같이 탄산칼슘 결정들에 의해 거칠게 나타난 반면, 탄산칼슘 미생물이 주입되지 않은 일반 시멘트 모르타르의 표면은 그림 1(b)와 같이 비교적 매끄러운 것으로 확인되었다. EDS(Energy Dispersive x-ray Spectroscopy) 분석을 실시하여 탄산칼슘 형성량을 비교한 결과, 미생물을 적용한 시멘트모르타르 공시체에서 탄산칼슘 질량이 16.7% 증가함이 확인되었다. 그리고 미생물에 의해 생성된 탄산칼슘이 압축강도에 미치는 영향을 분석한 결과, 탄산칼슘 형성 미생물을 적용시킨 시멘트 모르타르의 경우 일반 시멘트 모르타르에 비해 강도가 48.1% 증가하는 것으로 나타났다.

This paper has fabricated insulation gang-form adhering general gang-form to the polyisocyanurate board and analyzed type of members, temperature record by locations and strength development after placing the concrete, in order to ensure efficient concrete quality under cold weather. According to our test, we can see that general gang-form member with curing under the same conditions as the actual field has a trend of constantly decreasing concrete temperature regardless to surface or central area due to rapid outdoor air temperature reduction, while in the case of insulation gang-from I and II, temperature increased up to around 25℃ after 12 hours under rapid outdoor air temperature change and temperature distribution did not appear large separation according to hydration reaction measurement locations. In addition, results of measurement for temperature records on weak insulation area by types of gang-forms showed that the temperature record distribution on the form tie surface and horizontal bar surface of angle bar has generally similar trend as the temperature records on the surface of the insulation gang-form, while corner area of the insulation gang-form did not have large insulation effect. It is determined that it requires additional curing measure for the weak corner area of the insulation gang-form in the future.

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.

Precast concrete produced in the industry is advantageous in a sense that it meets certain requiring standards and thus is easy to manage, and it saves construction period by shortening concrete curing time in the field. Nevertheless, studies on the strength evaluation of PC material by steam curing have rarely been done. In addition，as concrete becomes of high strength, it is speculated that relevant steam curing temperature history is also required. Therefore this study is on the steam curing method in manufacturing precast concrete products, and cement mortar has been used for experiments to exclude the possibility that concrete aggregate granularity and aggregate shape change may affect on strength development by cement hydration. In addition, this research is to provide the fundamental information of industrial manufacture of PC member by suggesting the optimal steam curing condition. The optimal steam curing condition has been investigated from the relations between temperature history condition and strength development, via modifying temperature patterns in various ways such as pre-tirne, curing maximaI temperature, maximaI temperature maintenance time which are factors that affect on high strength concrete product in steam curing.

Non-sintering cement was manufactured with briquette ash. Alkali activator for compression bodies used a NaOH solution. In order to apply alkali-activated briquette ash and the non-sintering cement to concrete, several experimental studies were performed. It was necessary to study the binder obtained by means of a substitute for the cement. This study concentrated on strength development according to the concentration of NaOH solution, the curing temperature, and the curing time. The highest compressive strength of compression bodies appeared as 353kgf/cm2 cured at 80˚C for 28 days. This result indicates that a higher curing temperature is needed to get a higher strength body. Also, geopolymerization was examined by SEM and XRD analysis after the curing of compression bodies. According to SEM and XRD, the main reaction product in the alkali activated briquette ash is aluminosilicate crystal.

기존의 교면포장공법의 근본적인 문제점으로 인해 새로운 교면포장 공법이 점차 부각되고 있는 실정이며, 새로운 교면포장 공법으로 연구되고 있는 것이 라텍스 개질 콘크리트를 이용하는 것이다. 따라서, 본 연구에서는 신설 콘크리트 교량 교면포장으로 덧씌우기된 LMC의 강도발현 특성과 덧씌우기 될 때의 기존콘크리트와의 부착특성을 파악하고자 하였다. 이런 연구를 위해 라텍스 혼입률에 따른 라텍스 개질 콘크리트의 압축강도와 휨강도, 그리고 기존콘크리트와의 부착강도를 측정하였다. 본 연구결과 라텍스 혼입량 증가로 폴리머 입자들의 볼베어링 작용, 연행된 공기 및 라텍스 안에 있는 계면활성제의 분산작용에 의하여 LMC의 작업성과 휨강도를 증가시킨다는 사실을 파악 할 수 있었고, LMC와 기존 콘크리트 슬래브와의 부착강도는 크게 증진함을 알 수 있었다.

기존의 교면포장공법의 근본적인 문제점으로 인해 새로운 교면포장 공법이 점차 부각되고 있는 실정이며, 새로운 교면포장 공법으로 연구되고 있는 것이 라텍스 개질 콘크리트를 이용하는 것이다. 따라서, 본 연구에서는 신설 콘크리트 교량 교면포장으로 덧씌우기된 LMC의 강도발현 특성과 덧씌우기 될 때의 기존콘크리트와의 부착특성을 파악하고자 하였다. 이런 연구를 위해 라텍스 혼입률에 따른 라텍스 개질 콘크리트의 압축강도와 휨강도, 그리고 기존콘크리트와의 부착강도를 측정하였다. 본 연구결과 라텍스 혼입량 증가로 폴리머 입자들의 볼베어링 작용, 연행된 공기 및 라텍스 안에 있는 계면활성제의 분산작용에 의하여 LMC의 작업성과 휨강도를 증가시킨다는 사실을 파악 할 수 있었고, LMC와 기존 콘크리트 슬래브와의 부착강도는 크게 증진함을 알 수 있었다.

시멘트 산업은 탄소배출 감축을 위한 주요 산업분야로 고려되고 있으며, 콘크리트 분야에서 시멘트 사용량 저감을 위한 노력이 진행되고 있다. 이에 대한 노력의 일환으로 시멘트의 일부를 대체하여 사용할 수 있는 산업부산물을 다량으로 활용하기 위한 연구가 진행되고 있다. 산업부산물을 사용한 콘크리트는 내구성, 친환경성 및 경제성 등의 장점을 가지고 있으나, 응결시간 지연, 초기강도 저하 등의 문제점이 있다. 따라서 이 연구에서는 시멘트의 사용량을 줄이고 산업부산물인 플라이애시를 치환하여 사용하면서도 초기강도가 저하되는 문제점을 해결하는 것을 목표로 하였다. 이에 따라, 먼저 고분말도 시멘트 사용에 의한 수화반응 촉진으로 양생온도에 관계없이 모든 재령에서 강도가 증진되는 것을 확인하였다. 이어서 고분말도 시멘트에 플라이애시를 치환하여 강도발현 특성을 검토한 결과, 초기 재령에서도 보통 포틀랜드 시멘트와 비교하여 동등 이상의 강도 발현이 가능하였다. 또한, 플라이애시를 30%까지 치환하여도 수직․수평부재 거푸집 해체 시기를 단축할 수 있는 것을 확인하였다.

This study examined the effect of outside temperature on the properties of high-strength concrete to determine conditions for four-season construction. With 20 ℃ as the reference temperature, 20, 30, and 40 ℃ were set as hot weather conditions, and 5, -10, and –20 ℃ as cold weather conditions. Properties as the effect of outside temperature on compressive strength of high-strength concrete was studied.

This study examined the effect of outside temperature on the properties of high-strength concrete to determine conditions for four-season construction. With 20 ℃ as the reference temperature, 20, 30, and 40 ℃ were set as hot weather conditions, and 5, -10, and –20 ℃ as cold weather conditions. Properties as the effect of outside temperature on compressive strength of high-strength concrete was studied.