This study investigated the tracking loss rate and shear bond strength under various conditions to evaluate the properties of a trackless tack coat used in asphalt pavement maintenance and conducted a field investigation in which the trackless tack coat was used. Typically, the loss rate and bond strength of a tack coat depend on various conditions. Therefore, to evaluate the loss rate of the tack coat, a wheel-tracking attachment loss rate and tack lifter test were conducted by simulating high-temperature exposure conditions, and the shear bond strength was measured according to the surface condition of the bottom layer. In addition, field investigations of cracks, rutting, and potholes were conducted at 11 sites five years after the application of the trackless tack coat. The results of the wheel-tracking loss rate evaluation showed that the loss rate differed depending on the conditions of the bottom layer, and the loss rate of the trackless tack coat was very low at the same temperature as that of the rapid strength concrete (RSC). In addition, in the results of tack lifter test at 65℃, which had the highest loss rate by wheel tracking loss rate test, it was found that loss rate of trackless tack coat was 0%–29% lower than that of RSC for the same exposure time. As a result of evaluating the effect of the bottom layer's condition on the shear bond strength, it was found that the trackless tack coat was about 20% higher than RSC under the same conditions. In addition, when foreign substances such as dust were present in the bottom layer, the shear bond strength was reduced by approximately 28%. Field investigations of the trackless-applied section showed that potholes and rutting did not occur, and alligator cracks and linear cracks occurred in some sections; however, it was judged that there was little direct relationship with the trackless tack coat. The trackless tack coat was found to have a slight loss owing to tracking, even at relatively high temperatures, and the shear bond strength was excellent. In addition, if the construction process is properly conducted, an advantage will be attained in securing the performance life of asphalt pavements.

PURPOSES : Experimental findings pertaining to the mechanical properties and microstructures of calcium sulfo-aluminate (CSA) cement and amorphous calcium aluminate (ACA) cement based-repair mortars incorporated with anhydrite gypsum (AG) are described herein. METHODS : To prepare the mortars, the CSA or ACA as binders were adopted and the ratio of water–binder was fixed at 0.57. For comparison, mortar made of Type I ordinary Portland cement (OPC) was prepared. The fluidity, setting time, compressive and bond strengths and absorption of the mortars were measured at predetermined periods. In addition, the microstructures of paste samples using OPC, CSA or ACA were visually examined through SEM observation. RESULTS : The ACA-based mortars showed the increases in the fluidity, and the acceleration of the setting time. Furthermore, the ACAbased binder effectively enhanced the compressive and bond strengths of the mortars owing to amount of formation of C2AH8 hydrates. Meanwhile, the mortar with ACA showed an excellence absorption. CONCLUSIONS : Comparing with those of CSA-based mortars, the mechanical properties of ACA based-mortars were more remarkable. However, further studies regarding the durability of repair mortars using aluminate-based binders must be conducted to obtain the optimal mixture.

AZ31 magnesium alloy was used to manufacture a thin plate using a melt drag method. The effects of roll speed, molten metal temperature, and molten metal height, which are the basic factors of the melt drag method, on the surface shape, the thickness of the thin plate, Vickers hardness, and microstructure of the thin plate were investigated. It was possible to manufacture AZ31 magnesium alloy thin plate at the roll speed range of 1 to 90 m/min. The thickness of the thin plate, manufactured while changing only the roll speed, was about 1.8 to 8.8 mm. The shape of the solidified roll surface was affected by two conditions, the roll speed and the molten metal height, and the Vickers hardness of the manufactured magnesium alloy thin plate value ranged from Hv38~Hv60. The microstructure of the thin plate produced by this process was an equiaxed crystal and showed a uniform grain size distribution. The grain size was greatly affected by the contact state between the molten metal and the solidification roll, and the amount of reactive solids and liquids scraped at the same time as the thin plate. The average grain size of the thin plate fabricated in the range of these experimental conditions changed to about 50-300 μm.

PURPOSES : This study set out to investigate the fundamental properties of alkali-activated concrete (AAC) using modified slag as the pavement maintenance material. METHODS: The material properties of modified slag based alkali-activated concrete (MSAAC) were analyzed and evaluated against those of alkali-activated slag concrete (AASC). Several mix formulations were considered, including one MSACC and four AASCs. The main variables considered in the study were slump, air content, compressive strength, rapid chloride permeability test, scaling resistance, freeze-thaw test, XRD, SEM, and EDS. RESULTS: MSAAC exhibits a compressive strength in excess of 21 MPa six hours after curing. Also, the charge passed of the MSACC was found to be less than 2000 coulombs after seven days and about 1000 coulombs after 28 days. The weight loss determined from a scaling test did not exceed 1 kg/cm2 in the case of the MSACC, but that of the AASCs had already exceeded 1kg/cm2 at the 10th cycle. Based on the results of the freeze-thaw test, the relative dynamic modulus of every mix was found to be in excess of 90%. An energy dispersive spectroscopy(EDS) analysis found that the weight rate percentage of the calcium and aluminum in the MSAAC mix is twice that of the AASC mixes. CONCLUSIONS : It was found that the MSAAC mix exhibits significantly better performance than AASC mixes, based on various fundamental properties.

PURPOSES : This study is to investigate the fundamental properties of limestone added cement concrete for application of pavement. METHODS : As the production of Portland cement causes environmental problems, engineers have sought more environment-friendly concrete construction materials. Limestone powder can be used for concrete as a partial replacement of Portland cement. One of the great applications of limestone powder added cement concrete might be a cement concrete pavement since the concrete pavement consumes massive quantity of Portland cement. Experimental variables were different replacement level of limestone powder by 0% to 25% with 5% increment. Before hardening of fresh concrete, setting time and plastic shrinkage characteristics were investigated in addition to other basic properties. Properties of hardened concrete included compressive, tensile and flexural strength as well as drying shrinkage. RESULTS : The addition of limestone powder did not significantly affect the properties of fresh concrete. Strength deceased as the replacement ratio increased and when the replacement ratio was greater than 10% decrease rate increased. CONCLUSIONS : It was found that the partial replacement of the limestone powder to cement in pavement materials can be positively considered as its mechanical properties show comparable performance to those normal concrete.

본 연구는 준고온 공법을 이용한 재생 아스팔트 콘크리트의 강도특성을 평가하기 위해 이루어졌다. 굵은 골재 최대치수 13mm의 화강암과 침입도 60-80인 신규 바인더 60-80을 재생 혼합물을 제조하는데 사용하였다. 배합설계는 RAP(굵은 입자 : 잔입자=6 : 4) 첨가비율 20%와 30%를 사용하였고 GPC, 침입도, 절대점도, 동점도를 준고온 첨가제(Evotherm와 Sasobit)의 첨가 함량을 결정하기 위하여 측정하였다. LD(low-density poly ethylene)를 본 연구에서 준고온 재생 아스팔트 혼합물의 개질제로 사용하였다. 본 연구에서는 8개의 준고온 재생 혼합물(2 RAP함량 × 2 준고온 첨가제 × 2 개질제)뿐만 아니라 2개의 일반 재생 혼합물, 1개의 가열혼합 일반혼합물(control)까지 총 11개의 혼합물을 제조하였다. 변형강도 시험, 간접인장강도 시험, 수분민감성 시험, wheel tracking을 통한 소성변형 시험을 준고온 재생혼합물의 기본 특성을 평가하기 위하여 수행하였다.

본 연구에서는 아스팔트 혼합물의 특성을 평가하는 대표적인 방법인 마샬안정도와 간접인장강도 시험시 양생온도와 양생시간 및 시험온도에서의 처리시간이 결과에 미치는 영향을 비교분석 하였다. 마샬안정도 시험은 공시체를 60°C로 유지되는 수조에 30분 수침 후 수행하지만, 공시체의 양생시간에 관한 기준은 없다. 간접인장강도 시험의 경우는 시험온도는 25°C라고 정해져 있지만 마샬안정도 시험과 마찬가지로 양생시간에 관한 기준은 없다. 또한 간접인장강도 시험을 하기 전 공시체의 온도를 25°C로 맞추기 위하여 항온항습기 등과 같은 장치에 일정시간 보관해야 하는데 이것 역시 정해진 규정이 없다. 연구결과, 공시체의 양생온도에 따라 안정도와 간접인장강도 값은 많은 차이를 나타냈다. 따라서, 실험실 온도가 25°C보다 높거나 낮으면, 혼합물의 양생이 제대로 되지 않아 시험결과의 신뢰성이 떨어질 것이다. 양생온도 변화에 따른 시험값 변화를 최소화하기 위하여. 마샬안정도 시험시 공시체를 60°C 수조에 수침해야 하는 시간과 간접인장강도 시험 전 공시체를 25°C에 보관해야 하는 시간을 제안하였다.

본 연구에서는 아스팔트 혼합물의 특성을 평가하는 대표적인 방법인 마샬안정도와 간접인장강도 시험시 양생온도와 양생시간 및 시험온도에서의 처리시간이 결과에 미치는 영향을 비교분석 하였다. 마샬안정도 시험은 공시체를 60℃로 유지되는 수조에 30분 수침 후 수행하지만, 공시체의 양생시간에 관한 기준은 없다. 간접인장강도 시험의 경우는 시험온도는 25℃라고 정해져 있지만 마샬안정도 시험과 마찬가지로 양생시간에 관한 기준은 없다. 또한 간접인장강도 시험을 하기 전 공시체의 온도를 25℃로 맞추기 위하여 항온항습기 등과 같은 장치에 일정시간 보관해야 하는데 이것 역시 정해진 규정이 없다. 연구결과, 공시체의 양생온도에 따라 안정도와 간접인장강도 값은 많은 차이를 나타냈다. 따라서, 실험실 온도가 25℃보다 높거나 낮으면, 혼합물의 양생이 제대로 되지 않아 시험결과의 신뢰성이 떨어질 것이다. 양생온도 변화에 따른 시험값 변화를 최소화하기 위하여. 마샬안정도 시험시 공시체를 60℃ 수조에 수침해야 하는 시간과 간접인장강도 시험 전 공시체를 25℃에 보관해야 하는 시간을 제안하였다.

본 연구에서는 고 흡수성 폴리머를 혼입한 콘크리트의 기초 물성을 평가하였다. 또한 콘크리트 내부의 SAP의 내부양생 효과를 확인하기 위해 표준양생과 봉함양생을 실시하였다. 실험결과, SAP의 혼입률이 증가함에 따라 슬럼프 감소율이 증가하였으며, 표면전기저항도 증가하였다. 재령 7일과 28일의 압축강도 측정결과, 표준양생을 실시한 경우 압축강도의 증감이 SAP의 종류와 혼입률에 관계없는 것으로 나타났으며, 봉함양생을 실시한 경우 SAP 혼입률에 따라 강도가 증가하였다.

본 연구에서는 선별파쇄 골재 등 부순 골재에 포함된 토분함유량 규정치를 정하는 연구의 일환으로써 골재 토분이 모르타르의 기초적 특성에 미치는 영향을 분석하였다. 토분함유량이 증가할수록 유동성과 휨강도는 감소하고, 공기량은 증가하며 압축강도는 1 % 전후에서 증가하는 경향도 나타났으나 전반적으로 감소하였다.

In this study, the mechanical properties of concrete incorporating blast furnace slag with 60 % were analyzed according to CBS-Dust replacement rate. Results indicate that replacement of more than 10 % of CBS-Dust have a positive effect on reducing waste disposal costs and strength improvement

In this study, the fundamental properties of concrete using industrial waste as aggregate were evaluated. The concrete specimens were prepared using the steel slag as coarse aggregate and heavyweight waste glass. It was found that when the electric arc furnace slag substitution ratio increased, air contents and density also increase. However, the slump is decreased with an increase in the substitution ratio of electric arc furnace slag.

In this study, they were evaluated that the fundamental properties of mortar using a superabsorbent polymer. From the results, the flow value tends to decrease as the SAP content increases, and the compressive strength shows no particular tendency. This is due to the difference in SAP absorption rate. Therefore, it is necessary to accurately measure the absorption rate depending on the type of SAP, and it is considered that addition of water should be depending on the absorption rate.

최근 들어, 첨단산업의 발전으로 다양한 종류의 산업폐기물이 빠르게 발생하고 있다. 특히, 산업폐기물 중 중금속을 함유한 고밀도의 폐 브라운관 유리는 재처리 비용과 환경오염 문제로 인해 전량 매립‧처분되고 있다. 따라서 이러한 폐자원을 재활용하기 위한 기초 연구가 필요한 실정이다. 이에 본 연구에서는 중금속이 함유된 CRT 폐유리를 잔골재로 대체한 모르타르 시험체의 기초 물성과 방사선 차폐 성능을 분석하여 차폐 재료로의 활용성을 평가하였다. 연구 결과에 따르면 중금속을 함유한 CRT 폐유리를 잔골재로 대체한 시험체의 겉보기 밀도가 상승하였으며, 압축강도와 휨강도는 저하되는 현상을 나타냈다. 또한, 납 성분이 다량 함유된 폐유리 대체 시험체는 일반 모르타르 시험체보다 저에너지의 차폐 성능이 상승하는 효과를 보였으며, 122KeV·57Co 방사선원에 대해서는 일반 모르타르 시험체보다 2.5배 높은 선형감쇠계수를 나타냈다.

In this study, a series of studies is intended to elicit the improvement of the quality of Admixture Substitute Concrete using oil refined for petrochemical work (ERCO). In other words, ERCO is used to analyze the basic properties of Admixture Substitute Concrete by pre-adding the AE liquid solution on its products. As an experimental variable, the method of adding ERCO was added after mixing it with concrete. In addition, the mixing ratio was planned to be 2 levels of 0, 0.5 %, and the total volume of the AEs injection quantity is 5 % that combines 0, 1, 2, and 3 % of the mixed ERCO mass of concrete. As a result, as the pre-injection of AE was increased, the characteristics of the concrete showed that the slump, and air contents were not improved, and the pre-adopting effects of AE agent were also significantly increased in the concrete.

This paper was evaluated the mechanical propeties that compressive strength, splitting tensile strength and elastic modulous of self-healing solid type capsules mixed cement composites.