• Title/Summary/Keyword: 탈탄산염

Search Result 3, Processing Time 0.024 seconds

Optimal Abrasion Conditions for Separating Aggregate and Cement paste for Using Waste Concrete Fine Powder as Decarbonization Raw Material (폐콘크리트 미분말을 탈탄산 원료로 사용하기 위한 골재와 시멘트페이스트 분리의 최적 마쇄 조건 분석)

  • Ha-Seog Kim;Min-Chul Lee
    • Land and Housing Review
    • /
    • v.14 no.4
    • /
    • pp.121-129
    • /
    • 2023
  • In this study, we attempted to reduce CO2 generated during manufacturing by replacing limestone (CaCO3), a carbonate mineral used to produce cement clinker, with a decarbonated raw material to which CO2 is not bound. The raw material for decarbonization was cement paste attached to waste concrete, among various industrial by-products. Waste concrete has cement paste adhered to the aggregate, which cannot be separated efficiently by general crushing and grinding methods. Peeling and grinding methods effectively remove only the cement paste without damaging the original aggregate. The abrasion time, steel ball type, and steel ball ratio were selected as effective factors for Abrasion. An optimal abrasion experiment was conducted to produce waste concrete fine powder containing decarbonated CaO as a cement clinker raw material through an experimental design method. The experiment revealed that the optimal conditions for producing waste concrete fine powder were an abrasion time of 7 minutes, a steel ball size for pulverization of 8 mm, and a steel ball ratio for pulverization of 0.6.

CaO Optimal Classification Conditions for the Use of Waste Concrete Fine Powder as a Substitute for Limestone in Clinker Raw Materials (폐콘크리트 미분말을 클링커 원료의 석회석 대체재로 사용하기 위한 CaO 최적 분급 조건)

  • Ha-Seog Kim;Sang-Chul Shin
    • Land and Housing Review
    • /
    • v.15 no.1
    • /
    • pp.147-156
    • /
    • 2024
  • This study aims to reduce CO2 generated during the manufacturing process by using limestone (CaCO3), a carbonate mineral used in the production of cement clinker, as a decarbonated raw material that does not contain CO2. Among various industrial by-products, we attempted to use cement paste attached to waste concrete. In general, limestone for cement must have a CaCO3 content of at least 80% (CaO, 44% or more) to ensure the quality of cement clinker. However, the CaO content of waste concrete fine powder is about 20% on average, so in order to use it as a cement clinker raw material, the CaO content must be increased to more than 35%. Therefore, by using the difference in hardness of the mineral composition of waste concrete fine powder to selectively crush CaO type minerals with relatively low hardness, classify and sieve, the CaO content can be increased by more than 35%. Accordingly, in this study, we experimentally and statistically reviewed and analyzed the optimal conditions for efficiently separating CaO and SiO2 and other components by selectively pulverizing minerals containing relatively low CaO through a grinding process. As a result of the optimal grinding conditions experiment, it was found that the optimal conditions were a grinding time of less than 5 minutes, a type of material to be crushed of 30 mm, and an amount of material to be crushed of 1.0 or more. However, it is judged that it is necessary to review pulverized materials of mixed particle sizes rather than pulverized products of single particle size.

Geology, Mineralization, and Age of the Pocheon Fe(-Cu) Skarn Deposit, Korea (한국 포천 철(-동) 스카른 광상의 지질, 광화작용 및 생성연대)

  • Kim, Chang Seong;Go, Ji Su;Choi, Seon-Gyu;Kim, Sang-Tae
    • Economic and Environmental Geology
    • /
    • v.47 no.4
    • /
    • pp.317-333
    • /
    • 2014
  • The Pocheon iron (-copper) deposit, located at the northwestern part of the Precambrian Gyeonggi massif in South Korea, genetically remains controversial. Previous researchers advocated a metamorphosed (-exhalative) sedimentary origin for iron enrichment. In this study, we present strong evidences for skarnification and Fe mineralization, spatially associated with the Myeongseongsan granite. The Pocheon deposit is composed of diverse carbonate rocks such as dolostone and limestone which are partially overprinted by various hydrothermal skarns such as sodic-calcic, calcic and magnesian skarn. Iron (-copper) mineralization occurs mainly in the sodic-calcic skarn zone, locally superimposed by copper mineralization during retrograde stage of skarn. Age data determined on phlogopites from retrograde skarn stage by Ar-Ar and K-Ar methods range from $110.3{\pm}1.0Ma$ to $108.3{\pm}2.8Ma$, showing that skarn iron mineralization in the Pocheon is closely related to the shallow-depth Myeongseongsan granite (ca. 112 Ma). Carbon-oxygen isotopic depletions of carbonates in marbles, diverse skarns, and veins can be explained by decarbonation and interaction with an infiltrating hydrothermal fluids in open system ($XCO_2=0.1$). The results of sulfur isotope analyses indicate that both of sulfide (chalcopyrite-pyrite composite) and anhydrites in skarn have very high sulfur isotope values, suggesting the $^{34}S$ enrichment of the Pocheon sulfide and sulfate sulfur was derived from sulfate in the carbonate protolith. Shear zones with fractures in the Pocheon area channeled the saline, high $fO_2$ hydrothermal fluids, resulting in locally developed intense skarn alteration at temperature range of about $500^{\circ}$ to $400^{\circ}C$.