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

This paper evaluates the chemical resistance of mortar according to mixing ratios by using ferronickel slag fine powder which is an industrial by - product and various admixtures. The test results showed that the chlorine ion penetration resistance was the best when the ferronickel slag fine powder and gypsum were used as the admixture. The chemical erosion resistance was highest when ferronickel slag, quicklime, gypsum and calcium chloride were combined.

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, chloride penetration resistance and electrical resistivity properties of concrete using industrial waste were evaluated. From the results, the chloride diffusion coefficient increases and electrical resistivity decreases when electric furnace slag is mixed. It is needed that the comparison of results with long-term because the electric furnace slag has a ferrous component.

This study evaluated the fluidity and compressive strength of concrete by replacement ratio of blast furnace slag fine aggregate and ferronickel slag fine aggregate to investigate the possibility of replacing natural fine aggregate with steel slag for fine aggregate. Test results show that the use of steel slag fine aggregate improves the fluidity of concrete and compressive strength of concrete was higher than plain concrete.

This paper presents the results of the long-term behavior of PC(Precast Concrete) culvert using ferronickel slag blended cement.

In this study, as series of studies to provide how to apply coal gasification slag(CGS) as one of byproducts for high strength concrete, from a newly introduced power generation method in Korea, the possibility of using a mixed aggregate with 25 percent of CGS as a concrete residual were investigated. The results indicated that the compressive strength of concrete using CGS at early age was lower than that using CS, but compressive strength at 28 days showed similar levels of strength enhancement.

In this study, the compressive strength and elastic modulus of concrete mixed with electric furnace slag were evaluated. The concrete specimens were prepared using the steel slag as coarse aggregate and heavyweight waste glass as fine aggregate. From the results, compressive strength and the elastic modulus were improved with the addition of electric furnace slag.

현재 많은 국가들이 천연자원이 고갈되는 문제에 직면해있고, 골재 공급이 어려운 상황이다. 이러한 상황을 고려하기 위하여 대체자원 개발을 위한 다양한 연구들이 수행되어왔다. 특히, 방사성 폐기물의 차폐를 위해 사용되는 고밀도 채움재는 많은 양의 골재를 필요로 한다. 또한, 채움재의 차폐 성능 개선을 위해서는 채움재의 밀도 증가가 요구된다. 따라서 밀도가 높은 산업폐자원의 중량콘크리트 골재로의 활용성을 확대하기 위한 기초 자료의 제공을 위해 본 연구가 수행되었다. 실험결과, OPC의 경우, 고밀도 폐유리에 의해 감소된 콘크리트의 강도는 제강슬래그를 사용해도 개선되지 않으나, 광물질 혼화재를 결합재로 사용하면 성능이 개선되었다. 따라서 고밀도 폐유리와 제강슬래그를 중량 콘크리트에 적용할 경우, 광물질 혼화재와 함께 사용하고, FA보다는 BFS를 사용하는 것이 바람직한 것으로 나타났다. 한편, 제강슬래그를 중량콘크리트의 골재로 대체할 경우, 제강슬래그의 높은 밀도로 인하여 탄성계수와 차폐성능의 개선이 가능할 것으로 판단된다.

스트론튬계 상전이물질은 특정한 온도에서 물질의 상태가 변함에 따라서 열을 흡수하거나 방출하게 된다. 본 연구의 목적은 스트론튬계 상전이물질의 혼입이 플라이애시 치환 모르타르 및 고로슬래그 치환 모르타르의 수화발열 및 역학적 특성에 미치는 영향을 실험적으로 평가하는 것이다. 스트론튬계 상전이물질의 혼입량은 결합재 질량의 1, 2, 3, 4, 5%로 하였다. 총 12개 수준의 모르타르 배합에 대해서 모르타르 흐름성능, 간이수화열온도상승, 압축 및 휨강도 실험을 각각 수행하였다. 실험결과 본 연구에서 사용한 스트론튬계 상전이물질은 모르타르의 수화열 저감 및 수화지연에 효과적인 것으로 판단된다. 특히 플라이애시 치환 모르타르의 최대온도 상승량은 고로슬래그 치환 모르타르의 최대온도 상승량에 비해 낮게 나타났다. 플라이애시 및 고로슬래그 치환 모르타르의 압축강도는 상전이물질 혼입량이 증가함에 따라 감소하는 것으로 나타났다.

In this paper, the mechanical properties of GGBFS concrete according to the replacement ratio of electric arc furnace oxidizing slag fine aggregate was evaluated. As the replacement rate of EOS fine aggregate increased, the amount of slump and air content decreased. In addition, EOS concrete increased the initial compressive strength, but, it tended to decrease at 28 days.

This study is to perform experiment of concrete according to addition of blast furnace slag powder and sulfur activator dosages. Blast furnace slag powder used at 30, 50, 80% replacement by weight of cement, and liquid sulfur additives was chosen as the alkaline activator. As a result, it should be noted that the sulfur alkali-activators can not only solve the disadvantage of blast furnace slag concrete but also offer the chloride resistance of alkali-activated blast furnace slag concrete to blast furnace slag concrete.

This study is a basic study to CGS, which originates from the IGCC, as fine aggregate for concrete. The study measured density, water absorption ratio, solid volume percentage for grain shape, fineness modulus, grading curve of physical properties of fine aggregate. As a result, the density and solid volume percentage for grain sheet were found to be satisfactory in the aggregate for content (KS F 2527).Water evaluation ratio, fitness modulus, and grinding curve did not meet KS standards. Therefore, it is deemed necessary to adjust the grain size through sieving in case of fineness modulus and grinding curve.

This study investigated the concentration of heavy metals in blast-furnace slag cement by changing the content ratio between blast-furnace slag and ordinary Portland cement for the safe recycling of blast-furnace slag in the cement industry. The analysis of the three main materials of the cement (ordinary Portland cement, blast-furnace slag, and the alternative raw materials), resulted in the ordinary Portland cement having the highest concentration of heavy metals. Also, it is concluded that the heavy metal content of blast-furnace slag cement is mainly attributed to the content of ordinary Portland cement. As the content of furnace slag during the manufacture of cement increases, the overall heavy metal content of the furnace slag cement becomes low. This was highly evaluated as a resource in the cement-production process, in respect of the effective recycling of resources and the safe management of hazardous materials.

The purpose of this study was to verify safe and environmentally-sound recycling of blast-furnace slag in the cement industry. This was accomplished by analyzing the heavy metal contents of three kinds of raw materials: blast-furnace slag, Portland cement, and the substitutes, which were mainly input into the manufacture of cement. The research revealed that, in the five samples tested, the heavy metal level in the blast-furnace slag cements (5.90 ~ 8.38 mg/kg for Cr6+) is lower than the ordinary Portland cement (11.04 ~ 14.92 mg/kg for Cr6+). This suggests that both raw materials have low heavy metal contents compared with the 20 mg/kg limit enforced by the autonomic convention in Korea. As for the substitutes, there was no decisive effect on the overall heavy metal content because of the low input ratio of 2.5%. Therefore, it is of high utility value to recycle the blast-furnace slag in the cement industry, considering slag can dilute the overall heavy metal contents in the cement products.

본 연구에서는 탄소 포집 물질인 γ-C2S를 함유하고 있는 Stainless Steel Slag AOD를 포함한 시멘트 페이스트의 역학적 및 미세구조 변화를 연구하였다. γ-C2S는 비수경성이며 그러므로 물과 반응하지 않는다. 그러나 γ-C2S는 물에 의한 탄산화 양생조건에서 반응성을 가지고 있다. 그 반응은 페이스트 안의 공극을 치밀하게 형성하기 때문에 STS-A를 사용한 시멘트 페이스트의 공극구조는 탄산화 (CO2 농도는 약 5%)후에 수은압입시험에 의해 측정될 수 있다. 또한 Fractal 특성은 시멘트 페이스트의 미세구조변화는 탄산화 영향에 대하여 연구하였다. 그 결과로부터 STS-A를 포함하는 탄산화 시멘트 페이스트는 강도가 증가하였고 공극구조는 더 치밀해졌다.

This study introduces the result of dynamic tests carried out for the field application of ferro-nikel slag powder applied PHC PILE. For the test, a high strength, ultra high strength FNS PHC PILE was used as a test body, and a PHC PILE with a diameter of 600mm and a length of 20m was applied.

In this paper, the mechanical properties of fresh concrete were evaluated by using electric arc furnace oxidizing slag(EOS) aggregate. Water-Cement(W/C) ratio was selected as 0.45 and 0.30, and the mixing amount of EOS aggregate as 0%, 50%, 100%. Experimental items of fresh concrete were slump, flow, air content, unit volume weight. As a results, As the mixing amount of EOS aggregate increased, the slump and flow increased but the air content decreased.

In this paper, the mechanical properties of hardened concrete were evaluated by using electric arc furnace oxidizing slag(EOS) aggregate. Water-Cement(W/C) ratio was selected as 0.45 and 0.30, and the mixing amount of EOS aggregate as 0%, 50%, 100%. Experiments were carried out to compare the unit volume weights by concrete mixing, and the compressive strength test was carried out at 28 days of age. The unit volume weight and compressive strength of the EOS aggregate increased as the amount of the mixture increased. It also shows the difference according to the W/C ratio.

In order to solve the problem of natural aggregate exhaustion, several types of industrial waste have been studied for recycling of construction materials. In general, steel slag has been used as aggregate in concrete, however, steel slag has a problem of causing volume expansion by F-CaO. Therefore, in this study, the expansion properties are compared with aging period to solve the problem of the steel slag expansion. According to the test results, the expansion of the steel slag decreased regardless of the types of steel slag during aging period. And, the Electronic Arc Furnace Oxidizing Slag(EAF) had the better reduction in expanding than the Converter Slag(CS).