The heavyweight industrial waste was used as concrete ingredient instead of natural aggregate, however, design standard did not consider effects of heavyweight aggregate on flexural strength. Therefore, in this paper, correlation between compressive and flexural strength of concrete using industrial was compared. From the results, compressive strength and flexural strength decreased with industrial waste increasing. And, it was shown that the test results of flexural strength were higher than the predicted value from design standard.

Waste concrete powder generated during the process of recycling waste concrete into aggregate has a low recycling rate. This is because fine particles of waste concrete powder and cement components are present. Therefore, in this study, waste concrete powder is used as a raw material for centrifugal concrete. Experimental results show that waste concrete powder has cement and aggregate composition, SEM image has irregular shape, C-S-H and Ettringite exist inside. Waste concrete powder showed the same strength, up to 5% in terms of strength by age according to the substitution rate. Also, as the strength characteristics varied according to the centrifugal forming force, the substitution rate of siliceous matter increased by 5% and the strength decreased by substitution rate of 5%. Because of this study, it is considered difficult to use waste concrete powder as a substitute for silica sand because of the resulting characteristics of centrifugal concrete. It is recommended that economic and environmental concerns be considered when some substitution is made for silica sand.

The purpose of this study is to develop a durable packaging concrete using silica - based LCD waste glass. In order to verify the performance of the waste glass mixed pavement concrete, four types of concrete mixture were classified into general concrete, fly ash concrete, LCD concrete and LCD + fly ash concrete. The performance of the durable concrete pavement was tested for compressive strength, alkali - silica reaction, freezing - thawing, saltation and abrasion resistance. The purpose of this study was to develop a high - performance pavement concrete manufacturing technology using LCD waste glass powder.

Recently, the industrial waste resources have been continually developed because of a lack of natural aggregate. In this study, before the applicability of concrete using steel slag as aggregate, the properties were evaluated. From the test results, it is showed that the water aging period of the steel slag had no effect on the air contents, slump, compressive strength and density.

Filler material (concrete or mortar) has been used for shielding radioactive waste, however, it is proceeded out evaluation for radiation shielding performance. So, it is needed to check the property in the shielding performance. Therefore, in this paper, mechanical properties of concrete was evaluated for the applicability using heavyweight waste glass as fine aggregate of filler material. From the test results, compressive and elasticity modulus were significantly affected by substitution of heavyweight waste glass, however, it could be improved the performance by using mineral admixture as binder.

전자폐기물의 발생량이 급증하고 있고, 전자폐기물로 인한 환경오염 혹은 자원낭비등과 같은 문제를 야기하고 있다. 따라서 전자폐기물 안에 포함된 중금속을 재활용할 수 있는 기술 개발이 필요하다. 한편, 채움재(콘크리트 혹은 모르타르)는 방사성폐기물의 차폐를 위해 사용되나, 방사성 차폐 성능을 확보한 재료를 적용하고 있지 않다. 따라서 채움재는 차폐성능에 관한 신뢰가 부족한 상황이다. 그러므로 본 연구에서는, 전자폐기물을 채움재의 잔골재로 적용하기 위하여 콘크리트의 역학적 특성을 평가하였다. 실험결과, 압축강도, 휨강도, 탄성계수 및 1μm 영역의 공극이 상당히 영향을 받는 것으로 나타났으나, 광물질 혼화재를 결합재로 사용하면 성능이 개선되었다. 따라서 전자폐기물은 채움재의 잔골재로써 적용이 가능할 것으로 판단된다.

In this paper, Results of mock-up test for mitigating carbonation of high volume mineral admixture concrete by spreading waste cooking oil. Concrete incorporating 60% of BS and 30% of FA with the size of 900×600×200 are discussed. Denatured Silicate paint is also applied to compare the performance. Test results indicate that the application of ERCO and DSP enhance carbonation resistance.

Electrical waste, such as heavy weight waste glass, has become a global concern in terms of resource recycling. At the same time, aggregate is one of the most widely used infrastructure materials, and it is being exhausted. So, in this paper, the heavy weight waste glass is considered as aggregate due to its physical characteristics and chemical composition. From the results, when the heavy weight waste glass substitution ratio increase, the compressive strength and flexural strength decreased.

In this paper, the sulfate resistance of concrete substituted the crushed heavy weight waste glass as fine aggregate are compared and evaluated. From the results, when heavy weight waste glass substituted ratio increase, the reduction rate of compressive strength is decreased. So, the sulfate resistance is improved by using heavy weight waste glass in concrete.

In previous research team had reported that the durability of carbonation is improved by filling voids due to the saponification reaction of oil and concrete. The purpose of this study was to have experimental investigation the effect of mock-up experiment on the carbonation resistance of the waste concrete admixture.

In this paper, the flexural behavior of RC member recycled heavy weight waste glass as fine aggregate was evaluated by finite element analysis. From the results, yield point and maximum load decreased with decreasing concrete strength and elastic modulus. Also, the finite element analysis program does not reflect the ductility loss of RC members using heavy weight waste glass as fine aggregate.

In this paper, the sulfate resistance of concrete substituted the crushed heavy weight waste glass as fine aggregate are compared and evaluated. From the results, when heavy weight waste glass substituted ratio increase, the reduction rate of compressive strength is decreased. So, the sulfate resistance is improved by using heavy weight waste glass in concrete.

In previous research team had reported that the durability of carbonation is improved by filling voids due to the saponification reaction of oil and concrete. The purpose of this study was to have experimental investigation the effect of mock-up experiment on the carbonation resistance of the waste concrete admixture.

This study investigated the compressive strength characteristics of concrete and mortar containing waste pottery fine powder. To identify the effects of waste pottery fine powder on the compressive strength of concrete and mortar, cement was replaced with waste pottery fine powder at 5, 10 and 15% rates and the variations in compressive strength were evaluated. For high strength concrete, compared with a control mix, 5% replacement resulted in the reduction of 3.4% in compressive strength at 7 days; however, at 28 days, the strength actually increased by 2.5%. For normal strength concrete, compared with a control mix, 5% replacement resulted in the reduction of 20.4% in compressive strength at 7 days, and 14% reduction at 28 days. As for the mortar, at 5% replacement, compared with a control mortar mix, compressive strength of mortar decreased by 3% at 7 days, while an increase of 5.9% was observed at 28 days. Therefore, the optimum replacement rate of cement with waste pottery fine powder appears to be 5%.

This paper describes the findings of the study conducted to evaluate compressive strength characteristics of high-strength concrete containing waste pottery fine powder. The experimental variables selected were 5, 10, and 15 percent replacements of cement with waste pottery fine powder. The findings are summarized as follows: (1) compared with the strength of the control specimens with no replacement rate, compressive strength of the concrete at 7days decreased by 4% at 5% replacement rate of cement with waste pottery fine powder, but (2) compressive strength of the concrete at 28days increased slightly by 1.3%..

As the industrialization is rapidly growing, the quantities of industrial waste glass have been quickly increased. However the most of them are not recycled. Therefore, it is needed to investigate the possibility of industrial waste glass as concrete material ingredient. In this paper, it is compared and evaluated that the characteristics of freeze-thaw resistance according to industrial waste glass substitution ratio in concrete specimens. From the results, the weight change was not affected by the waste glass substitution ratio. And, the relative dynamic modulus of elasticity was increased slightly with the waste glass substitution ratio. The relative dynamic modulus of elasticity was above 80% up to 300cycles in all of the mixes.

The purpose of this study is to investigate the field application of Permeability recycled asphalt using Waste Asphalt Concrete and Resin. After the test construction, it was not cause problem, such as this stripping, falling and crack of pavement. Also, it was confirmed to be performance of equal or higher than of existing technology.

Along with the increased display devices, the supply for LCD waste glass has rapidly increased. However, there is a problem for recycling. In this study, the possibility of using LCD waste glass as a substitutive material of fine aggregate is determined and compared from the test of the compressive strength and split tensile strength. Finally, it is possible to confirm the results of the failure aspect and analysis of this test.

In this research we carried out the compressive strength, modulus of rupture and scaling resistance tests in order to evaluate the durability of concrete pavement containing waste glass powder. As a results of this research, the concretes incorporating 20% waste glass powder had higher compressive strengths and modulus of ruptures than the concretes with 20% fly-ash. Also, they had a better scaling resistance than ordinary portland cement concretes and fly ash concretes.

This paper describes the findings of the study conducted to evaluate early-age strength characteristics of rapid-setting concrete containing waste pottery powder. The experimental variables selected were 5, 10, and 15 percent replacements of cement with waste pottery powder. The findings are summarized as follows: (1) slump of the concrete decreased as the replacement rate of cement with waste pottery powder increased, and (2) compared with the strength of the control specimens with no replacement rate, compressive strength of concrete increased at 5% replacement rate, and was comparable to the control at 10% replacement rate; however, at 15% replacement rate, compressive strength actually decreased.