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.

PURPOSES : In general, a high-performance concrete construction method is a method of loading mixed cement and other materials on a mobile mixer equipped with a concrete plant. However, the construction cost is high because the unit cost of the mixed cement is very high and the equipment usage fee of the mobile mixer is also high. To compensate for these drawbacks, a cellular spray concrete method was developed. This is a highly functional customized concrete construction method in which admixtures are added to high-flow concrete with cellular (air bubbles) added at the site and constructed through spraying. METHODS : Field workability evaluation using cellular concrete was carried out using a spray method in 2017 and an anti-foaming agent in 2018. The test construction section was set as a new road-pavement construction site. After construction, strength, durability characteristics, and void analysis were performed to compare the construction methods. The results of laboratory tests under optimal conditions were also compared to the on-field results. By comparing the indoor mixing and the on-field results, we analyzed whether there were any problems concerning the performance expression. The economic feasibility at the initial construction stage was analyzed by comparing the existing and the cellular concrete construction methods in terms of material cost and equipment usage fee. RESULTS : In the case of cellular spray concrete, construction through spraying is cumbersome, and the need to additionally use large equipment such as a pump car and compressor constitutes a disadvantage. However, the most relevant feature is that it can be constructed not only on the floor, but also on a slope. In the case of cellular concrete with an antifoaming agent, it was possible to quickly produce high-performance concrete using on-site remixing equipment. By supplying materials to the pouring surface using a conveyor, smooth construction and construction in narrow spaces were also possible. CONCLUSIONS : The cellular concrete method allows the immediate on-site production of high-performance concrete, and it is possible to selectively apply spray construction, antifoaming agent construction, etc.

최근 콘크리트 구조물은 구조적인 역할뿐만 아니라 경관구조물로써의 역할이 증대되고 있다. 이러한 상황에서 자연암반 연출이 용이한 시공기술이 필요하게 되었다. 고성능 숏크리트를 사용한 자연암 옹벽시 공기술 개발로 기존 공법의 조각공정을 단순화하기 위해 스템프형태로 시공하는 문양을 찍는 방법을 선정 하였다. 벽면에 암무늬 및 석축무늬의 형태를 표현하는 기술을 조각공이 아닌 일반인부에 의해 표현하고자 기 존 암반무늬 우레탄틀 또는 사각형틀을 이용하여 숏크리트 타설 후 무늬를 찍는 스템프형 자연암 옹벽 시 공기술을 개발하여 조각공에 의한 공사비용을 저감하였다. 그림 1은 시공 순서이고, 그림 2는 시공전후와 마무리별 무늬 질감을 나타낸 그림이다.

PURPOSES : The objective of this study is to propose a quality control and quality assurance method for use during asphalt pavement construction using non-destructive methods, such as ground penetrating radar (GPR) and an infrared (IR) camera. METHODS: A 1.0 GHz air-coupled GPR system was used to measure the thickness and in situ density of asphalt concrete overlay during the placement and compaction of the asphalt layer in two test construction sections. The in situ density of the asphalt layer was estimated based on the dielectric constant of the asphalt concrete, which was measured as the ratio of the amplitude of the surface reflection of the asphalt mat to that of a metal plate. In addition, an IR camera was used to monitor the surface temperature of the asphalt mat to ensure its uniformity, for both conventional asphalt concrete and fiber-reinforced asphalt (FRA) concrete. RESULTS: From the GPR test, the measured in situ air void of the asphalt concrete overlay gradually decreased from 12.6% at placement to 8.1% after five roller passes for conventional asphalt concrete, and from 10.7% to 5.9% for the FRA concrete. The thickness of the asphalt concrete overlay was reduced from 7.0 cm to 6.0 cm for the conventional material, and from 9.2 cm to 6.4 cm for the FRA concrete. From the IR camera measurements, the temperature differences in the asphalt mat ranged from 10℃ to 30 ℃ in the two test sections. CONCLUSIONS: During asphalt concrete construction, GPR and IR tests can be applicable for monitoring the changes in in situ density, thickness, and temperature differences of the overlay, which are the most important factors for quality control. For easier and more reliable quality control of asphalt overlay construction, it is better to use the thickness measurement from the GPR.

현재 국내에서 시행되고 있는 시멘트 콘크리트 포장의 형식은 줄눈 콘크리트 포장(이하 ʻJCPʼ : Jointed Concrete Pavement)이 대부분이다. JCP 공법은 시공경험이 풍부하고 타 공법에 비해 초기공사비가 저렴 하다는 점에서 가장 많이 쓰여 왔으나 줄눈부의 잦은 손상으로 인한 유지 보수가 필요하며 수축줄눈에 의한 승차감 불량 및 안전 등의 문제점이 발생하였다. 이에 대응하여 2012년부터 한국도로공사와 국토교통부에 서 연속철근콘크리트 포장(이하 ʻCRCPʼ : Continuously Reinforced Concrete Pavement)의 적용이 제안되 었으나 공법특성상 철근배근작업으로 인해 시공상에서 필연적으로 추가 작업 공간이 요구되므로 최근 설계 되고 시공되는 도로포장과 같이 교량과 터널 그리고 상․하행 분리구간에서는 기존 CRCP를 적용할 수 있는 구간은 실질적으로 매우 한정적이다. 이에 포장 공용성 증대를 위하여 JCP포장 위주에서 벗어나, CRCP 포장의 확대적용과 함께 기존 CRCP 공법 의 시공성 해결과 구조적 성능을 향상시킨 연속철근콘크리트 포장의 기계식 시공방법(이하 ʻMRCPʼ : Mechanical-placement Reinforced Concrete Pavement)을 개발하였다. MRCP 장비 및 공법을 이용하여 모 의시공 및 시험시공을 실시한 결과 포설효율 향상을 위한 필요성이 요구되어 추가적인 연구개발을 수행하였다. 연구개발은 기존 MRCP공법 시공시 투입되는 장비인 슬림폼페이버와 철근유도장치의 일체화를 통해 콘크리트 타설, 철근배근 공정을 단순화시키는 일체화 장비개발방향으로 수립하였으며 이에 따라 포설효 율 5~10% 향상, 센서를 통한 철근의 정밀시공 도입, 시공성 10% 향상 및 호퍼용량 개선과 철근이음방안 개선 등을 최종목표로 설정하여 수행하였다. 본 논문에서는 모의시공을 통해 일체화 장비를 이용한 연속철근 콘크리트포장의 기계식 시공방법 현장 검증을 실시하였으며 이를 통해 장비성능 및 공법의 현장검증(장비 작동여부, 철근배근상태, 등)을 실시 하였다. 수행 결과 일체화 장비의 포설 및 시공성 향상을 확인하였으며, 철근유도장비의 기계식 탈부착 및 철근배근 정확성을 검증하였다.

현재 국내에서 시행되고 있는 시멘트 콘크리트 포장 형식은 초기공사비가 저렴하고 시공경험이 풍부하다는 점에서 무근(줄눈)콘크리트 포장이 대부분을 차지하고 있으나 줄눈부의 잦은 손상으로 인해 내구수명이전 파손 이 빈번해짐에 따라 포장공용수명 연장의 방법으로 연속철근콘크리트 포장공법(CRCP공법) 적용이 대두되었다. CRCP공법은 철근배근 방법에 따라 인력 배근방법(Manual method)과 Tube Feeding장비를 이용하여 철근을 배근하는 기계식 배근(Mechanical Placement Method)방법으로 분류된다. 국내의 경우 1984년 경부고속도로 포장개량의 목적으로 처음 CRCP가 도입되었으며 1985년도 중부고속도로에 인력 배근방법으로 시공하여 현재 까지 양호한 공용상태를 보이고 있다. 하지만 인력배근의 경우, 철근조립의 선행공정으로 인한 시공성 저하와 별도의 작업 공간이 필요하여 상․하행 분리구간 및 터널, 확포장구간에 적용이 어려워 시공실적이 저조한 실정 이다. 또한 국외의 경우 기계식 배근방법의 시공이력이 있으나 철근 배근의 부정확성 등 문제점의 개선이 이루 어지지 않아 1990년 이후 시공실적은 없는 실정이다. 콘크리트 포장의 내구성 저하 원인인 횡방향 줄눈을 제거하여 주행성 및 내구성을 확보하고 총 생애주기비용 을 고려하여 경제성 측면에서 유리한 CRCP포장의 확대적용이 필요하다. 이를 위해 기존 CRCP공법의 시공성 을 해결하여 국내여건에 맞는 시공방법의 개선이 요구되며, 철근 배근의 정확성 등의 문제점 개선을 통한 구조 적 성능 향상이 필요하다. 따라서 본 연구에서는 횡방향 철근 없이 철근유도장비를 이용하여 종방향 철근을 자동 배근하는 동시에 콘크 리트를 포설하는 연속철근콘크리트 포장공법을 적용한 시험시공 구간에 대하여 철근배근의 정확성을 확인하였으 며 추적조사를 통한 균열 상태 조사를 실시하였다. 이를 통해 연속철근콘크리트 포장의 개선된 기계식 시공방법 의 현장적용성을 평가하여, 기존 인력식 배근으로 시공한 연속철근콘크리트 포장과 비교평가를 실시하였다.

PURPOSES: The objective of this study is to evaluate construction issues and design for transverse steel in continuously reinforced concrete pavement(CRCP). METHODS : The first continuously reinforced concrete pavement(CRCP) design procedure appeared in the 1972 edition of the“ AASHTO Interim Guide for Design of Pavement Structures,”which was published in 1981 with Chapter 3 “Guide for the Design of Rigid Pavement” revised. A theory that was accepted at that time for the analysis of steel stress in concrete pavement, called subgrade drag theory(SGDT), was utilized for the design of reinforcement of CRCP - tie bar design and transverse steel design - in the aforementioned AASHTO Interim Guide. However SGDT has severe limitations due to simple assumptions made in the development of the theory. As a result, any design procedures for reinforcement utilizing SGDT may have intrinsic flaws and limitations. In this paper, CRCP design procedure for transverse steel was introduced and the limitations of assumptions for SGDT were evaluated based on various field testing. RESULTS: Various field tests were conducted to evaluate whether the assumptions of SGDT are reasonable or not. Test results show that 1) temperature variations exist along the concrete slab depth, 2) very little stress in transverse steel, and 3) warping and curling in concrete slab from the field test results. As a result, it is clearly revealed out that the assumptions of SGDT are not valid, and transverse steel and tie bar designs should be based on more reasonable theories. CONCLUSIONS : Since longitudinal joint is provided at 4.1-m spacing in Korea, as long as joint saw-cut is made in accordance with specification requirements, the probability of full-depth longitudinal cracking is extremely small. Hence, for transverse steel, the design should be based on the premise that its function is to keep the longitudinal steel at the correct locations. If longitudinal steel can be placed at the correct locations within tolerance limits, transverse steel is no longer needed.

PURPOSES : About 35% of air pollutant is occurred from road transport. NOx is the primary pollutant. Recently, the importance of NOx removal has arisen in the world. TiO2 is very efficient for removing NOx by photocatalytic reaction. The mechanism of removing NOx is the reaction of photocatalysis and solar energy. Therefore, TiO2 in concrete need to be contacted with solar radiation to be activated. In general, TiO2 concrete are produced by substitute TiO2 as a part of concrete binder. However, 90% of TiO2 in the photocatalysis can not contacted with the pollutant in the air and solar radiation. Coating and penetration method are attempted as the alternative of mixing method in order to locate TiO2 to the surface of structure. METHODS : The goal of this study was to attempt to locate TiO2 to the surface of concrete, so we can use the concrete in pavement construction. The distribution of TiO2 along the depth were confirmed by basing on the comparison of TiO2 compare by using the EDAX(Energy Dispersive X-ray Spectroscopy). RESULTS : TiO2 were distributed within 3mm from concrete surface. This distribution of TiO2 is desirable, since the TiO2 induce photocatalysis are located to where they can be contacted with the air pollutant and solar radiation. CONCLUSIONS : Nano size TiO2 is easily penetration in the top 3mm of concrete surface. By the penetration TiO2 concrete can be produced with the use of only 10% of TiO2, by comparing the mixing types.