• 제목/요약/키워드: calcium sulfoaluminate cement

검색결과 29건 처리시간 0.027초

칼슘설포알루미네이트 시멘트의 탄산화 양생과 열 안정성에 관한 검토 (Review on Carbonation Curing and Thermal Stability of Calcium Sulfoaluminate Cement)

  • 오현유;쿠날 크뤼쉬나 다스;장정국
    • 한국건축시공학회:학술대회논문집
    • /
    • 한국건축시공학회 2023년도 봄 학술논문 발표대회
    • /
    • pp.53-54
    • /
    • 2023
  • In recent decades, climate change has become an issue of global importance. The calcium sulfoaluminate (CSA) cement emits lower CO2 than the Portland cements while manufacturing. However, ettringite, which is a main hydration product of CSA cement, starts dehydrating at a temperature above 100℃, hence it may limit the CSA cement for high temperature application. Recently, an early carbonation curing of cement-based material has been extensively studied in terms of carbon neutralization. The carbonation curing of CSA cement has a potential to transform the AFt and AFm phases into calcium carbonate, and the transformation of unstable hydrates to stable hydrates can increase the resistance to elevated temperature. This review study summarizes and discusses the carbonation curing effect of CSA cement and the thermal stability of CSA cement exposed to elevated temperatures.

  • PDF

Triaxial shear behavior of calcium sulfoaluminate (CSA)-treated sand under high confining pressures

  • James Innocent Ocheme;Sakiru Olarewaju Olagunju;Ruslan Khamitov;Alfrendo Satyanaga;Jong Kim;Sung-Woo Moon
    • Geomechanics and Engineering
    • /
    • 제33권1호
    • /
    • pp.41-51
    • /
    • 2023
  • Cementitious materials such as Ordinary Portland Cement (OPC), fly ash, lime, and bitumen have been employed for soil improvement over the years. However, due to the environmental concerns associated with the use of OPC, substituting OPC with calcium sulfoaluminate (CSA) cement offers good potential for ground improvement because it is more eco-friendly. Although earlier research has investigated the stabilizing effects of CSA cement-treated sand, no attempt has been made to examine soil behavior under high confining pressure. As a result, this study aimed to investigate the shear strength and mechanical behavior of CSA cement-treated sand using a consolidated drained (CD) triaxial test with high confining pressure. The microstructure of the examined sand samples was investigated using scanning electron microscopy. This study used sand with CSA cement contents of 3%, 5%, and 7% and confining pressures of 0.5, 1.0, and 1.5 MPa. It revealed that the confining pressures and CSA cement content significantly affected the stress-strain and volumetric change behavior of CSA cement-treated sand at high confining pressures.

이산화탄소 분위기에서 칼슘실리케이트와 칼슘설포알루미네이트 혼합시멘트의 광물 및 압축강도 특성 (Mineral and Compressive Strength Characteristics of Calcium Silicate and Calcium Sulfoaluminate Mixed Cement in Carbon Dioxide Atmosphere)

  • 이대근;이선목;박정준;문기연;조계홍;조진상
    • 자원리싸이클링
    • /
    • 제32권6호
    • /
    • pp.10-17
    • /
    • 2023
  • 칼슘실리케이트 시멘트(Calcium silicate cement, CSC)는 친환경 저탄소 시멘트로써 최근에 많은 연구가 진행되고 있다. 하지만 이산화탄소 반응 활성화와 시료 handling을 위하여 사전경화 단계를 진행하여야하는 어려움이 있다. 본 연구에서는 CSC에 칼슘설포아루미네이트(Calcium sulfoaluminate, CSA) 속경시멘트를 혼합하여 초기강도 발현으로 사전경화 없이 사용할 수 있는 CSC의 확대적용 가능성을 살펴보고자 하였다. 이를 위하여 이산화탄소 분위기에서 CSC 와 CSA 속경성 시멘트 혼합비율 변화에 따른 압축강도와 Q-XRD 광물특성 함량 변화를 측정하였다. 압축강도 측정결과, CSC 50% 조건에서 3일과 7일 압축강도가 각 각 14.18MPa과 22.98MPa로 1종시멘트 KS규격을 만족하였다. 광물특성 분석을 통하여 이산화탄소 반응생성물인 calcite 광물이 증가하여 강도발현에 기여했음을 알 수 있었다. 7일 경과 후에도 수화광물인 dicalcium silicate 및 yeelimite광물뿐 아니라, 이산화탄소와 반응하지 않은 rankiniten 및 pseudowollastonite 광물이 다량 관찰되어 7일이후의 강도발현 가능성을 확인하였다.

산업 부산물을 이용한 칼슘설포알루미네이트의 합성 (Synthesis of Calcium sulfoaluminate Usng Industrial By-products and Wastes)

  • 문정호;이범재;노재성
    • 한국콘크리트학회:학술대회논문집
    • /
    • 한국콘크리트학회 1998년도 가을 학술발표대회 논문집(III)
    • /
    • pp.888-893
    • /
    • 1998
  • Calcium sulfoaluminate, $C_4$A$_3$$\bar{S}$, was prepared for reutilizing industrial by-products, such as II-CaSO$_4$, Al(OH), CaF$_2$ and cement sludge wastes. Mixed powder was fired at 1,15$0^{\circ}C$. $C_4$A$_3$$\bar{S}$ clinkers fired at 1,15$0^{\circ}C$ were analyzed by SEM and XRD. Also were added in cement paste and mortar and characterized as setting time, flow values and compressive strength. $C_4$A$_3$$\bar{S}$ could be found in the X-ray diffraction pattern. The setting time of cement pastes added clinkers fired at 1,15$0^{\circ}C$ was shorter than that of ordinary portland cement. Also the compressive strengths of the cement mortar added clinkers was higher than those of ordinary portland cement.

  • PDF

Pore Structure of Calcium Sulfoaluminate Paste and Durability of Concrete in Freeze-Thaw Environment

  • de Bruyn, Kyle;Bescher, Eric;Ramseyer, Chris;Hong, Seongwon;Kang, Thomas H.K.
    • International Journal of Concrete Structures and Materials
    • /
    • 제11권1호
    • /
    • pp.59-68
    • /
    • 2017
  • Mercury intrusion and nitrogen sorption porosimetry were employed to investigate the pore structure of calcium sulfoaluminate ($C{\bar{S}}A$) and portland cement pastes with cement-to-water ratio (w/c) of 0.40, 0.50, and 0.60. A unimodal distribution of pore size was drawn for $C{\bar{S}}A$ cement pastes, whereas a bimodal distribution was established for the portland cement pastes through analysis of mercury intrusion porosimetry. For the experimental results generated by nitrogen sorption porosimetry, the $C{\bar{S}}A$ cement pastes have a smaller and coarser pore volume than cement paste samples under the same w/c condition. The relative dynamic modulus and percentage weight loss were used for investigation of the concrete durability in freeze-thaw condition. When coarse aggregate with good freeze-thaw durability was mixed, air entrained portland cement concrete has the same durability in terms of relative dynamic modulus as $C{\bar{S}}A$ cement concrete in a freeze-thaw environment. The $C{\bar{S}}A$ cement concrete with poor performance of durability in a freeze-thaw environment demonstrates the improved durability by 300 % over portland cement concrete. The $C{\bar{S}}A$ concrete with good performance aggregate also exhibits less surface scaling in a freeze-thaw environment, losing 11 % less mass after 297 cycles.

Mechanical and microstructural investigations on cement-treated expansive organic subgrade soil

  • Nazerke Sagidullina;Jong Kim;Alfrendo Satyanaga;Taeseo Ku;Sung-Woo Moon
    • Geomechanics and Engineering
    • /
    • 제38권4호
    • /
    • pp.353-366
    • /
    • 2024
  • Organic soils pose significant challenges in geotechnical engineering due to their high compressibility and low stability, which can result in issues like differential settlement, rutting, and pavement deformation. This study explores effective methods for stabilizing organic soils. Rather than conventional ordinary Portland cement (OPC), the focus is on using environmentally friendly calcium sulfoaluminate (CSA) cement, known for its rapid setting, high early strength development, and environmental benefits. Mechanical behavior is analyzed through 1-D free swell, unconfined compressive strength (UCS), and bender element (BE) tests. Microstructural analyses, including Fourier transform infrared spectroscopy (FTIR) and scanning electron microscopy (SEM), characterize the soil mixed with CSA cement. Experimental results demonstrate improved soil properties with increasing cement dosage and curing periods. A notable strength increase is observed in soil samples with 15% cement content, with UCS doubling after 7 days. This trend aligns with shear wave velocity results from the BE test. SEM and FTIR spectroscopy reveal how CSA cement hydration forms hydrated calcium silicate gel and ettringite, enhancing soil properties. CSA cement is recommended for reinforcing organic subgrade soil due to its eco-friendly nature and rapid strength gain, contributing to improved durability.

Sustainable use of OPC-CSA blend for artificial cementation of sand: A dosage optimization study

  • Subramanian, Sathya;Tee, Wei Zhong;Moon, Juhyuk;Ku, Taeseo
    • Geomechanics and Engineering
    • /
    • 제31권4호
    • /
    • pp.409-422
    • /
    • 2022
  • The use of calcium sulfoaluminate (CSA) cement as a rapid-hardening cement admixture or eco-friendly alternate for ordinary Portland cement (OPC) has been attempted over the years, but the cost of CSA cement and availability of suitable aluminium resource prevent its wide practical application. To propose an effective ground improvement design in sandy soil, this study aims at blending a certain percentage of CSA with OPC to find an optimum blend that would have fast-setting behavior with a lower carbon footprint than OPC without compromising the mechanical properties of the cemented sand. Compared to the 100% CSA case, initial speed of strength development of blended cement is relatively low as it is mixed with OPC. It is found that 80% OPC and 20% CSA blend has low initial strength but eventually produces equivalent ultimate strength (28 days curing) to that of CSA treated sand. The specific OPC-CSA blend (80:20) exhibits significantly higher strength gain than using pure OPC, thus allowing effective geotechnical designs for sustainable and controlled ground improvement. Further parametric studies were conducted for the blended cement under various curing conditions, cement contents, and curing times. Wet-cured cement treated sand had 33% lower strength than that of dry-cured samples, while the stiffness of wet-cured samples was 25% lower than that of dry-cured samples.

Analysis of Characteristics of Slurry and Thermal Insulation Materials Using Hauyne Cement

  • Kim, Tae Yeon;Jo, Ki Sic;Chu, Yong Sik
    • 한국세라믹학회지
    • /
    • 제56권5호
    • /
    • pp.468-473
    • /
    • 2019
  • This study focused on manufacturing an inorganic insulation material set with various amounts of calcium-sulfoaluminate (CSA) (hauyne) content for enhancing both workability (demolding, handling) and the high thermal insulating property. To carry out the experiment, the amounts of CSA utilized were 5%, 10%, 15%, and 20%, with anhydrous gypsum added in equal proportion to produce a stable formation. As the content of CSA increased, a sinking phenomenon occurred because of the hydration reaction from the slurry, so it was difficult to utilize a retarder normally used in the cement manufacturing process. However, an RCOOM surfactant was able to solve the local clumping problem from cement and CSA and obtain a rapid retarding effect, so it was included in this process at 0.3%. Furthermore, the cement fineness was not 7000 ㎠/g but rather 3300 ~ 4000 ㎠/g to prevent a rapid temperature increase in the slurry. The specific gravity of the sample manufactured with 20% CSA was approximately 0.11 g/㎤, and its thermal conductivity was 0.041 W/m·K, providing an excellent insulating property.

Physicochemical properties and autogenous healing performance of ternary blended binders composed of OPC-BFS-CSA clinker

  • H.N. Yoon;Joonho Seo;Naru Kim;H.M. Son;H.K. Lee
    • Advances in concrete construction
    • /
    • 제15권1호
    • /
    • pp.11-22
    • /
    • 2023
  • Autogenous healing of concrete can be helpful in structural maintenance by healing cracks using a healing material created by the precipitation of calcite and by the hydration of unhydrated binder around the cracks. Against this backdrop, this study investigated the physicochemical properties and autogenous healing performance of ternary blended binder composed of ordinary Portland cement (OPC), blast furnace slag (BFS), and calcium sulfoaluminate (CSA) clinker. Ternary blended binders with various contents of OPC-BFS-CSA clinker were prepared, and their physicochemical properties and autogenous healing performances were examined using various analytical techniques and visually observed using a microscope. The obtained results indicated that increase in the BFS content accompanied the increased the amount of unreacted BFS even after 28 days of curing and had a positive effect on the autogenous healing performance due to its latent hydration. However, replacing the CSA clinker did not increase the autogenous healing performance owing to an insufficient sulfate source for the formation of ettringite. The main precipitates around the cracks were calcite, C-S-H. Other hydration products such as portlandite, monosulfate, and ettringite, which were not found in the Raman and scanning electron microscope analyses.