• Title/Summary/Keyword: 이산화탄소 포집광물

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An Experimental Study on the Quality Characteristics of Soil-Cement for Deep Mixing Method Using Carbon Capture Minerals(CCM) (이산화탄소 포집광물을 활용한 심층혼합처리용 Soil-Cement의 품질 특성에 관한 실험적 연구)

  • Jung, Woo-Yong;Ju, Hyang-Jong;Oh, Sung-Rok;Choi, Yun-Wang
    • Journal of the Korean Recycled Construction Resources Institute
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    • v.8 no.2
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    • pp.153-160
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    • 2020
  • In this study, the optimum ratio of soil-cement was derived to utilize carbon capture minerals(CCM) as soil-cement for deep mixing method, quality characteristics of soil-cement mixed with carbon capture minerals were evaluated. The CCM is generated in the form of a slurry, and as a result of evaluating water content, it was found to be about 50%. Accordingly, the water content of CCM was removed in the unit water of Soil-cement mix. As a result of field mixing of soil-cement using CCM on field soil, it showed that the design allowable bearing capacity was satisfied by showing 3.0MPa or more as of 28 days of age. As a result of the hazard verification of carbon capture minerals, 0.055mg/L of Cu was detected, but satisfies the acceptance criteria, and no other harmful substances were eluted.

Biomimetic Engineering of Carbon Dioxide Capture (생체모방공학을 이용한 이산화탄소 포집)

  • Kim, Dae-Hoon;Vinoba, Mari;Shin, Woo-Sup;Lim, Kyong-Soo;Jeong, Soon-Kwan;Kim, Sung-Hyun
    • Proceedings of the KAIS Fall Conference
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    • 2010.11a
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    • pp.491-494
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    • 2010
  • 지구온난화의 주범인 온실가스 중 이산화탄소 농도 증가에 따라 현재 전 세계적으로 사회적, 환경적, 경제적으로 피해가 나타나고 있다. 그래서 CCS연구를 적용하여 이산화탄소를 포집하는 연구가 활발하게 진행 되고 있으나 분리, 수송, 저장 등의 추가적인 비용이 발생하는 문제점을 가지고 있다. 본 논문은 생체촉매효소를 이용하여 이산화탄소를 포집하는 연구를 하였다. 반응온도, pH, 이산화탄소 농도 등의 변수를 이용한 생체촉매효소의 활성평가, 반응속도, 광물화의 특성에 관하여 연구하였다.

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Basic Research for Carbon Dioxide Reaction Hardening Cement Products (이산화탄소 반응경화 시멘트 2차제품 적용을 위한 기초 연구)

  • Lee, Hyang Sun;Song, Hun
    • Cement Symposium
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    • s.49
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    • pp.21-22
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    • 2022
  • The purpose of this study is to reduce carbon dioxide emissions in the cement industry and to collect carbon dioxide generated in industrial facilities such as cement factories and thermal power plants, store and utilize it, and convert high-value-added resources. While conventional Ordinary Portland Cement is characterized by hardening through hydration reactions, basic research is underway to develop cement that reacts with carbon dioxide and converts it into carbonate mineralization.

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Characteristic of Precipitated Metal Carbonate for Carbon Dioxide Conversion Using Various Concentrations of Simulated Seawater Solution (해수 농축수 내 금속 이온 농도에 따른 이산화탄소 전환 생성물의 특성연구)

  • Choi, Eunji;Kang, Dongwoo;Yoo, Yunsung;Park, Jinwon;Huh, Il-sang
    • Korean Chemical Engineering Research
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    • v.57 no.4
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    • pp.539-546
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    • 2019
  • Global warming has mentioned as one of the international problems and these researches have conducted. Carbon Capture, Utilization and Storage (CCUS) technology has improved due to increasing importance of reducing emission of carbon dioxide. Among of various CCUS technologies, mineral carbonation can converted $CO_2$ into high-cost materials with low energy. Existing researches has been used ions extracted solid wastes for mineral carbonation but the procedure is complicated. However, the procedure using seawater is simple because it contained high concentration of metal cation. This research is a basic study using seawater-based wastewater for mineral carbonation. 3 M Monoethanolamine (MEA) was used as $CO_2$ absorbent. Making various concentrations of seawater solution, simulated seawater powder was used. Precipitated metal carbonate salts were produced by mixing seawater solutions and $rich-CO_2$ absorbent solution. They were analyzed by X-ray Diffraction (XRD), Scanning Electron Microscope (SEM), and Thermogravimetric Analysis (TGA) and studied characteristic of producing precipitated metal carbonate and possibility of reusing absorbent.

Variation of the Physical-microstructural Properties of Sandstone and Shale Caused by CO2 Reaction in High Pressure Condition (고압 이산화탄소 반응에 의한 사암과 셰일의 물리적-미세구조적 변화)

  • Park, Jihwan;Son, Jin;Park, Hyeong-Dong
    • Tunnel and Underground Space
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    • v.26 no.4
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    • pp.293-303
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    • 2016
  • Underground $CO_2$ storage technology is one of the most effective methods to reduce atmospheric $CO_2$. In this study, $CO_2$ storage condition was simulated in the laboratory. Sandstone and shale specimens were saturated in 1M NaCl and were reacted at $45^{\circ}C$, 10 atm for 4 weeks. The physical and microstructural properties of rock specimens were measured. Variations on physical properties of shale specimens were bigger than those of sandstone specimens, such as volume, density, elastic wave velocity, Poisson's ratio and Young's modulus. Microstructure were analyzed using X-ray computed tomography. Total number of pores were decreased, and average volume, average area and average equivalent diameter of each pore were changed after $CO_2$ reaction. Swelling and leakage of clay mineral caused by $CO_2$-mineral reaction were the reason of changes. The results of this study can be applied to predict the physical and microstructural changes in underground $CO_2$ storage condition.

CO2 Mineral Carbonation Reactor Analysis using Computational Fluid Dynamics: Internal Reactor Design Study for the Efficient Mixing of Solid Reactants in the Solution (전산유체역학을 이용한 이산화탄소 광물 탄산화 반응기 분석: 용액 내 고체 반응물 교반 향상을 위한 내부 구조 설계)

  • Park, Seongeon;Na, Jonggeol;Kim, Minjun;An, Jinjoo;Lee, Chaehee;Han, Chonghun
    • Korean Chemical Engineering Research
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    • v.54 no.5
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    • pp.612-620
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    • 2016
  • Aqueous mineral carbonation process, in which $CO_2$ is captured through the reaction with aqueous calcium oxide (CaO) solution, is one of CCU technology enabling the stable sequestration of $CO_2$ as well as economic value creation from its products. In order to enhance the carbon capture efficiency, it is required to maximize the dissolution rate of solid reactants, CaO. For this purpose, the proper design of a reactor, which can achieve the uniform distribution of solid reactants throughout the whole reactor, is essential. In this paper, the effect of internal reactor designs on the solid dispersion quality is studied by using CFD (computational fluid dynamics) techniques for the pilot-scale reactor which can handle 40 ton of $CO_2$ per day. Various combination cases consisting of different internal design variables, such as types, numbers, diameters, clearances and speed of impellers and length and width of baffles are analyzed for the stirred tank reactor with a fixed tank geometry. By conducting sensitivity analysis, we could distinguish critical variables and their impacts on solid distribution. At the same time, the reactor design which can produce solid distribution profile with a standard deviation value of 0.001 is proposed.

Research on the Production of CO2 Absorbent Using Railway Tie Concrete Waste (콘크리트 철도 침목 폐기물을 활용한 CO2 포집제 제조 연구)

  • Gyubin Lee;Jae-Young Lee;Hyung-Jun Jang;Sangwon Ko;Hye-Jin Hong
    • Journal of the Korean Recycled Construction Resources Institute
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    • v.11 no.3
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    • pp.260-266
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    • 2023
  • In recent years, excessive emissions of carbon dioxide(CO2) have become the cause of global climate change. Consequently, there has been significant research activity aimed at both removing and utilizing CO2. This study assesses the potential utilization of railway tie concrete waste, generated from railway infrastructure, as a CO2 absorption material and investigates the physicochemical properties before and after CO2 absorption to understand the CO2 removal mechanisms. Railway tie concrete waste primarily consists of Si(26.60 %) and contains 9.82 % of Ca. Compared to samples of Cement and Normal concrete waste, it demonstrated superior potential for use as a CO2 absorption material, with approximately 98 % of the Ca content participating in CO2 absorption reactions. Through Thermogravimetric Analysis(TGA) and X-ray Diffraction(XRD) analysis, it was confirmed that the carbonate reaction, where the Ca in railway tie concrete waste converts into CaCO3 through reaction with CO2 gas, is the primary mechanism for CO2 removal. Furthermore, Scanning Electron Microscopy(SEM) analysis revealed the formation of numerous CaCO3 particles with sizes less than 0.1 ㎛ after the CO2 absorption reaction. This transformation of large internal voids in the CO2 absorption material into mesopores resulted in an increase in the specific surface area of the material.

Mineralogical Analysis of Calcium Silicate Cement according to the Mixing Rate of Waste Concrete Powder (폐콘크리트 미분말 치환율에 따른 이산화탄소 반응경화 시멘트의 광물상 분석)

  • Lee, Hyang-Sun;Song, Hun
    • Journal of the Korea Institute of Building Construction
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    • v.24 no.2
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    • pp.181-191
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    • 2024
  • In the realm of cement manufacturing, concerted efforts are underway to mitigate the emission of greenhouse gases. A significant portion, approximately 60%, of these emissions during the cement clinker sintering process is attributed to the decarbonation of limestone, which serves as a fundamental ingredient in cement production. Prompted by these environmental concerns, there is an active pursuit of alternative technologies and admixtures for cement that can substitute for limestone. Concurrently, initiatives are being explored to harness technology within the cement industry for the capture of carbon dioxide from industrial emissions, facilitating its conversion into carbonate minerals via chemical processes. Parallel to these technological advances, economic growth has precipitated a surge in construction activities, culminating in a steady escalation of construction waste, notably waste concrete. This study is anchored in the innovative production of calcium silicate cement clinkers, utilizing finely powdered waste concrete, followed by a thorough analysis of their mineral phases. Through X-ray diffraction(XRD) analysis, it was observed that increasing the substitution level of waste concrete powder and the molar ratio of SiO2 to (CaO+SiO2) leads to a decrease in Belite and γ-Belite, whereas minerals associated with carbonation, such as wollastonite and rankinite, exhibited an upsurge. Furthermore, the formation of gehlenite in cement clinkers, especially at higher substitution levels of waste concrete powder and the aforementioned molar ratio, is attributed to a synthetic reaction with Al2O3 present in the waste concrete powder. Analysis of free-CaO content revealed a decrement with increasing substitution rate of waste concrete powder and the molar ratio of SiO2/(CaO+SiO2). The outcomes of this study substantiate the viability of fabricating calcium silicate cement clinkers employing waste concrete powder.

Nanoconfinement of Hydrogen and Carbon Dioxide in Palygorskite (팔리고스카이트 내 수소 및 이산화탄소 나노공간한정)

  • Juhyeok Kim;Kideok D. Kwon
    • Korean Journal of Mineralogy and Petrology
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    • v.36 no.4
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    • pp.221-232
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    • 2023
  • Carbon neutrality requires carbon dioxide reduction technology and alternative green energy sources. Palygorskite is a clay mineral with a ribbon structure and possess a large surface area due to the nanoscale pore size. The clay mineral has been proposed as a potential material to capture carbon dioxide (CO2) and possibly to store eco-friendly hydrogen gas (H2). We report our preliminary results of grand canonical Monte Carlo (GCMC) simulations that investigated the adsorption isotherms and mechanisms of CO2 and H2 into palygorskite nanopores at room temperature. As the chemical potential of gas increased, the adsorbed amount of CO2 or H2 within the palygorskite nanopores increased. Compared to CO2, injection of H2 into palygorskite required higher energy. The mean squared displacement within palygorskite nanopores was much higher for H2 than for CO2, which is consistent with experiments. Our simulations found that CO2 molecules were arranged in a row in the nanopores, while H2 molecules showed highly disordered arrangement. This simulation method is promising for finding Earth materials suitable for CO2 capture and H2 storage and also expected to contribute to fundamental understanding of fluid-mineral interactions in the geological underground.

The Effect of Chloride Additives and pH on Direct Aqueous Carbonation of Cement Paste (시멘트 풀의 직접수성탄산화에서 Chloride 첨가제와 pH의 영향)

  • Lee, Jinhyun;Hwang, Jinyeon;Lee, Hyomin;Son, Byeongseo;Oh, Jiho
    • Journal of the Mineralogical Society of Korea
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    • v.28 no.1
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    • pp.39-49
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    • 2015
  • Recently, carbon capture and storage (CCS) techniques have been globally studied. This study was conducted to use waste cement powder as an efficient raw material of mineral carbonation for $CO_2$ sequestration. Direct aqueous carbonation experiment was conducted with injecting pure $CO_2$ gas (99.9%) to a reactor containing $200m{\ell}$ reacting solution and the pulverized cement paste (W:C = 6:4) having particle size less than 0.15 mm. The effects of two additives (NaCl, $MgCl_2$) in carbonation were analyzed. The characteristics of carbonate minerals and carbonation process according to the type of additives and pH change were carefully evaluated. pH of reacting solution was gradually decreased with injecting $CO_2$ gas. $Ca^{2+}$ ion concentration in $MgCl_2$ containing solution was continuously decreased. In none $MgCl_2$ solution, however, $Ca^{2+}$ ion concentration was increased again as pH decreased. This is probably due to the dissolution of newly formed carbonate mineral in low pH solution. XRD analysis indicates that calcite is dominant carbonate mineral in none $MgCl_2$ solution whereas aragonite is dominant in $MgCl_2$ containing solution. Unstable vaterite formed in early stage of experiment was transformed to well crystallized calcite with decreasing pH in the absence of $MgCl_2$ additives. In the presence of $MgCl_2$ additives, the content of aragonite was increased with decreasing pH whereas the content of calite was decreased.