All Issue

2025 Vol.34, Issue 4 Preview Page

Article Review

Technology for Cement Accelerator Utilization Based on Fe-Al Sludge from Waste Battery Recycling

폐배터리 재활용에서 발생한 Fe-Al 슬러지 기반 시멘트 급결제 활용을 위한 기술

Insung Hwang12
,
Young-Min Kim1*
,
Yong Hwan Kim3
,
Seungyun Han3
황 인성12
,
김 영민1*
,
김 용환3
,
한 승연3
1Flexible Manufacturing R&D Department, Korea Institute of Industrial Technology, Incheon 21999, Korea
2Department of Mechanical Convergence Engineering, Hanyang University, Seoul 04763, Korea
3Materials · Supply Chain R&D Department, Korea Institute of Industrial Technology, Incheon 21999, Korea
1한국생산기술연구원 지능화뿌리기술연구소 유연생산연구부문
2한양대학교 공과대학교 융합기계공학과
3한국생산기술연구원 지능화뿌리기술연구소 소재공급망연구부문
*Corresponding Author
31 August 2025. pp. 31-39
PDF XML Citation
Abstract

Fe–Al sludge generated during waste battery recycling processes is a metal-rich industrial by-product that has recently drawn attention as a promising material for resource circulation and functional construction applications. This review paper comprehensively summarizes recent research trends on the development of fundamental technologies and the practical applicability of utilizing Fe–Al sludge as a cement accelerator. The analysis revealed that Fe–Al composite sludge promotes the formation of ettringite and hydroxysulfate-type hydration products through interactions between metal ions, effectively contributing to the reduction of setting time and the early development of strength in cement paste. Compared to conventional chloride-based accelerators, it offers advantages in terms of durability and environmental stability, and is expected to serve as a strategic turning point that enhances both the eco-friendliness and economic feasibility of the construction materials industry.

Keywords
Waste battery recycling
Fe–Al sludge
Cement accelerator
Hydration reaction
Resource-circulating construction material

폐배터리 재활용 공정에서 발생하는 Fe–Al계 슬러지는 고농도의 금속 성분을 함유한 산업 부산물로, 자원순환 촉진 및 기능성 건설 소재화 측면에서 활용 가능성이 높은 소재로 주목받고 있다. 본 논문은 이러한 Fe–Al계 슬러지를 시멘트 급결제로 활용하기 위한 기초기술 개발 동향과 응용 가능성에 관한 최신 연구를 종합적으로 분석하였다. 분석결과, Fe–Al 복합계 슬러지는 금속 이온 간 상호작용을 통해 Ettringite 및 hydroxysulfate 계열 수화 생성물 형성을 촉진하며, 시멘트 페이스트의 응결 시간 단축과 조기 강도 발현에 효과적으로 기여하는 것으로 나타났다. 이는 기존 염소계 급결제에 비해 내구성 및 환경 안정성 측면에서 유리하며, 건설 소재 산업의 환경친화성과 경제성을 동시에 강화할 수 있는 전략적 전환점을 제공할 수 있을 것으로 기대된다.

키워드
폐배터리 재활용
Fe-Al 슬러지
시멘트 급결제
수화 반응
자원순환 건설소재
References
1

Tarascon, J. M., Armand, M., 2001: Issues and challenges facing rechargeable lithium batteries (Review), Nature, 414(6861), pp.359-367.

10.1038/35104644
2

Goodenough, J. B., Park, K.-S., 2013: The Li-Ion Rechargeable Battery: A Perspective Journal of the American Chemical Society, 135, pp.1167-1176.

10.1021/ja3091438
3

Goodenough, J. B., Kim, Y., 2010: Challenges for Rechargeable Li Batteries, Chemistry of Materials, 22, pp.587-603.

10.1021/cm901452z
4

Armand, M., Tarascon, J. M., 2008: Building better batteries, Nature, 451, pp. 652-665.

10.1038/451652a
5

Hwang, I, Kim, Y.-M., Kim, Y. H., HAn, S., 2024: Review on Life Cycle Assessment of Waste Lithium-ion Battery Recycling Process, Resources Recycling, 33, pp.3-13.

10.7844/kirr.2024.33.5.3
6

Gaines, L., Sullivan, J., Burnham, A., 2011: Life-Cycle Analysis for Lithium-Ion Battery Production and Recycling, Transportation Research Board 90th Annual Meeting, p.11-3891, Transportation Research Board, Washington, D.C., 23-27 January 2011, Printed in USA.

7

Dewulf, J., Van der Vorst, G., Denturck, K., et al., 2010: Recycling rechargeable lithium ion batteries: Critical analysis of natural resource savings, Resource, Conservation and Recycling, 54(4), pp. 229-234.

10.1016/j.resconrec.2009.08.004
8

Fisher, K., Wallén, E., Laenen, P. P., et al., 2006: Battery waste management life cycle assessment, Final report for publication, Environmental Resources Management (ERM), Ltd., London.

9

Hischier, R., Wäger, P., and Gauglhofer, J., 2005: Does WEEE recycling make sense from an environmental perspective?: The environmental impacts of the Swiss take-back and recycling systems for waste electrical and electronic equipment (WEEE), Environmental Impact Assessment Review, 25(5), pp. 525-539.

10.1016/j.eiar.2005.04.003
10

Baum, Z. J., Bird, R. E., Yu, X., et al., 2022: Lithium-Ion Battery Recycling─Overview of Techniques and Trends, ACS Energy Letters, 7(2) pp 712-719.

10.1021/acsenergylett.1c02602
11

Bertuol, D. A., Machado, C. M., Silva, M. L., et al., 2016: Recovery of cobalt from spent lithium-ion batteries using super-critical carbon dioxide extraction, Waste Manage, 51, 245-251.

10.1016/j.wasman.2016.03.009
12

Dorella, G. and Mansur, M. B., 2007: A study of the separation of cobalt from spent Li-ion battery residues, J. Power Sour., 170, 210-215.

10.1016/j.jpowsour.2007.04.025
13

Wang, H., Huang, K., Zhang, Y., et al., 2017: Recovery of lithium, nickel, and cobalt from spent lithium-ion battery powders by selective ammonia leaching and an adsorption separation system, ACS Sustain. Chem. Eng., 5, pp.11489-11495.

10.1021/acssuschemeng.7b02700
14

Zeng, X., Li, J., Singh, N., 2014: Recycling of Spent Lithium-Ion Battery: A Critical Review, Critical Reviews in Environmental Science and Technology, 44(10), pp. 1129-1165.

10.1080/10643389.2013.763578
15

Zhang, P., Yokoyama, T., Itabashi, O., et al., 1998: Hydrometallurgical process for recovery of metal values from spent lithium-ion secondary batteries, Hydrometallurgy, 47, 259-271.

10.1016/S0304-386X(97)00050-9
16

Wang, Y., Lei, L., Liu, J., et al., 2022: Accelerators for normal concrete: A critical review on hydration, microstructure and properties of cement-based materials, Cement and Concrete Composites, 134, 104762.

10.1016/j.cemconcomp.2022.104762
17

Wang, Y., Shi, C., Ma, Y., et al., 2021: Accelerators for shotcrete - Chemical composition and their effects on hydration, microstructure and properties of cement-based materials, Construction and Building Materials, 281, 122557.

10.1016/j.conbuildmat.2021.122557
18

Paglia, C., Wombacher, F., Böhni, H., 2003: The influence of alkali-free and alkaline shotcrete accelerators within cement systems: Influence of the temperature on the sulfate attack mechanisms and damage, Cement and Concrete Research, 33, pp.387-395.

10.1016/S0008-8846(02)00967-5
19

Zhong, H., Yang, L., Wang, F., 2024: Properties of (Al, Fe)-ettringite solid solution: Experiment, atomic simulation, and thermodynamics modeling, Cement and Concrete Research, 182, 107556.

10.1016/j.cemconres.2024.107556
20

Zhang, J., Peng, Z., Yi, L., et al., 2024: CO-H2 Gas-Based Reduction Behavior of Cr-Rich Electroplating Sludge Mixed with Iron Ore Powder, Metals, 14(3), 325.

10.3390/met14030325
21

Yuan, X., Song, J., Hu, W., et al., 2025: Characteristics of iron phase migration and redox performance of Fe/Al particles blending with iron-rich sludge ash, Chemical Engineering Journal, 309, 121501.

10.1016/j.ces.2025.121501
22

Fang, Y., Liu, A., Li, N., et al., 2025: Phosphorus recovery from Fe/Al-rich sewage sludge ash: Combining wet and thermochemical methods, Separation and Purification Technology, 363, 131823.

10.1016/j.seppur.2025.131823
23

Liang, C., Le, X., Fang, W., et al., 2022: The Utilization of Recycled Sewage Sludge Ash as a Supplementary Cementitious Material in Mortar: A Review, Sustainability, 14(8), 4432.

10.3390/su14084432
24

Amri, R. E., Zahnoune, R., Boudouch, O., et al., 2025: Optimization of sludge recirculation for sustainable water treatment at Ait Massoud dam Morocco, Discover Water, 5, 54.

10.1007/s43832-025-00252-8
25

Brykov, A. S., Vasil’ev, A. S., Mokeev, M. V., 2012: Hydration of Portland cement in the presence of high activity aluminum hydroxides, Russian Journal of Applied Chemistry, 85, pp.1793-1799.

10.1134/S1070427212120014
26

ASTM C403 / C403M-16, Standard Test Method for Time of Setting of Concrete Mixtures by Penetration Resistance, ASTM International, West Conshohocken, PA, USA, 2016.

27

Lee, J.-C., 2023: Evaluation of Setting Times of Concrete Using Electro-Mechanical Impedance Sensing Technique, Materials, 16(16), 5618.

10.3390/ma1616561837629909PMC10456224
28

Ahmad, M., Gulzar, A., Haq, Z. U., et al., 2023: Effect of sewage sludge concentrations on concrete strength (Pure and Applied Biology (PAB)), Pure and Applied Biology, 12(2), pp.808-816.

10.19045/bspab.2023.120080
29

Stepanov, S. V., Morozov, N. M., Borovskikh, I. V., et al., 2016: Application of Galvanic Sludge for Acceleration of Concrete Hardening, Indian Journal of Science and Technology, 9(43), pp.1-10.

10.17485/ijst/2016/v9i43/104978
30

Kaish, A. B. M. A., Odimegwu, T. C., Zakaria, I., et al., 2021: Properties of concrete incorporating alum sludge in different conditions as partial replacement of fine aggregate, Construction and Building Materials, 284, 122669.

10.1016/j.conbuildmat.2021.122669
31

Chen, Y., Liang, D., Chen, H., et al., 2022: Review of resource utilization of Fe-rich sludges: purification, upcycling, and application in wastewater treatment, Environ. Rev., 30, pp.460-484.

10.1139/er-2021-0038
32

Malaiškienė, J., Kižinievič, O. and Kižinievič, V., 2019: A Study on Tannery Sludge as a Raw Material for Cement Mortar, Materials, 12(9), 1562.

10.3390/ma1209156231086022PMC6539026
33

Keeley, J., Jarvis, P., Judd, S. J., 2012: An economic assessment of coagulant recovery from water treatment residuals, Desalination, 287(15), pp.132-137

10.1016/j.desal.2011.09.013
Information
  • Publisher :The Korean Institute of Resources Recycling
  • Publisher(Ko) :한국자원리싸이클링학회
  • Journal Title :Resources Recycling
  • Journal Title(Ko) :자원리싸이클링
  • Volume : 34
  • No :4
  • Pages :31-39
  • Received Date : 2025-07-30
  • Revised Date : 2025-08-08
  • Accepted Date : 2025-08-11
  • DOI :https://doi.org/10.7844/kirr.2025.34.4.31
Journal Informaiton Resources Recycling Resources Recycling
E-Book
Online Submission
Archives
: Archives
  • NRF
  • KOFST
  • crossref crossmark
  • crossref cited-by
  • KCI 문헌 유사도 검사
  • orcid
  • open access
  • ccl
Journal Informaiton Journal Informaiton - close