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硫酸亚铁在水泥中还原六价铬Cr(Ⅵ)时,其用量较高会增加水泥中SO3的含量,并且会降低水泥的抗压强度等性能。因硫酸亚铁与石膏都属于硫酸盐,具有相似性,且可延长水泥的凝结时间,故可用硫酸亚铁部分替代水泥中的石膏,研究硫酸亚铁替代石膏后对水泥中Cr(Ⅵ)含量和水泥净浆中Cr(Ⅵ)溶出量的影响,并研究了硫酸亚铁替代石膏后对水泥凝结时间、抗压强度和水化产物等性能的影响。结果表明:当硫酸亚铁替代0.3%的石膏时,Cr(Ⅵ)含量从11.8 mg/kg降到2 mg/kg以下且不会降低水泥28 d的抗压强度,硫酸亚铁替代石膏后会促进钙矾石的形成,延长水泥净浆的凝结时间;当硫酸亚铁替代量小于1.0%时会促进水泥的水化;硫酸亚铁替代石膏后会降低水泥净浆中水溶性Cr(Ⅵ)的溶出,且28 d时水溶性Cr(Ⅵ)的溶出量为0。
Abstract:When ferrous sulfate is used to reduce hexavalent chromium Cr(Ⅵ) in cement, its high dosage will increase the content of SO3 in cement and reduce the compressive strength of cement. Because ferrous sulfate and gypsum all belong to sulfate, and they are similar to each other in properties and can prolong the setting time of cement, ferrous sulfate can be used to partially replace gypsum in cement. The effects of replacing gypsum by ferrous sulfate on the content of Cr(Ⅵ) in cement and the dissolution of Cr(Ⅵ) in cement paste were studied. In addition, the effects of replacing gypsum by ferrous sulfate on the setting time, compressive strength and hydration products of cement were studied as well. The results show that when 0.3% gypsum is replaced by ferrous sulfate, the content of Cr(Ⅵ) decreases from 11.8 mg/kg to less than 2 mg/kg without reducing the compressive strength of cement at 28 d. The replacement of gypsum by ferrous sulfate will promote the formation of ettringite and prolong the setting time of cement paste. When the replacement amount by ferrous sulfate is less than 1.0%, it will promote the hydration of cement. The replacement of gypsum by ferrous sulfate will reduce the dissolution of water-soluble Cr(Ⅵ) in cement paste, and the dissolution of water-soluble Cr(Ⅵ) is 0 at 28 d.
[1] 汪学新.水泥工业消除铬害的可行途径[J].新世纪水泥导报,2004(S1):132-135.WANG Xuexin.Possible ways to eliminate chromium hazard in cement industry[J].Cement Guide for New Epoch,2004(S1):132-135.
[2] KAMALUDIN N H,JALALUDIN J,TAMRIN S B M,et al.Exposure to silica,arsenic,and chromium(VI) in cement workers:A probability health risk assessment[J].Aerosol and Air Quality Research,2020,20:2347-2370.
[3] ESTOKOVA A,PALASCAKOVA L,KANUCHOVA M.Study on Cr (VI) leaching from cement and cement composites[J].International Journal of Environmental Research and Public Health,2018,15(4):824.
[4] DEVESH S,REKHA S.Effect of FeSO4·7H2O and SnCl2·2H2O added as chromium (VI) reducers in ordinary portland cement[J].Oriental Journal of Chemistry,2015,31(1):519-526.
[5] ERDEM E,GüNG?RMü? H,KILIN?ARSLAN R.The investigation of some properties of cement and removal of water soluble toxic chromium(VI) ion in cement by means of different reducing agents[J].Construction and Building Materials,2016,124:626-630.
[6] 王德懂,王胜民,赵晓军.水泥中六价铬抑制剂的现状及发展[J].硅酸盐通报,2018,37(5):1625-1631.WANG Dedong,WANG Shengmin,ZHAO Xiaojun.Research status and development of hexavalent chromium inhibitor in cement[J].Bulletin of the Chinese Ceramic Society,2018,37(5):1625-1631.
[7] 赵宏波,刘铁军,韩晓东.水泥生产中六价铬的来源与控制研究[J].中国水泥,2021(2):96-99.ZHAO Hongbo,LIU Tiejun,HAN Xiaodong.Study on the source and control of hexavalent chromium in cement production[J].China Cement,2021(2):96-99.
[8] WANG Y,WANG Z,JIANG L B,et al.Effect of ferrous sulfate replacing gypsum on properties and reducing Cr (VI) of cement paste[J].Journal of Building Engineering,2023,69:106295.
[9] ZHANG M,YANG C,ZHAO M,et al.Immobilization of Cr (VI) by hydrated portland cement pastes with and without calcium sulfate[J].Journal of Hazardous Materials,2018,342:242-251.
[10] LEISINGER S M,BHATNAGAR A,LOTHENBACH B,et al.Solubility of chromate in a hydrated OPC[J].Applied Geochemistry,2014,48:132-140.
[11] OMOTOSO O E,IVEY D G,MIKULA R.Hexavalent chromium in tricalcium silicate:Part I Quantitative X-ray diffraction analysis of crystalline hydration products[J].Journal of Materials Science,1998,33(2):507-513.
[12] WANG S,VIPULANANDAN C.Solidification/stabilization of Cr(VI) with cement leachability and XRD analyses[J].Cement & Concrete Research,2000,30(3):385-389.
[13] JAIN N,GARG M.Effect of Cr(VI) on the hydration behavior of marble dust blended cement:Solidification,leachability and XRD analyses[J].Construction and Building Materials,2008,22(8):1851-1856.
[14] LASHERAS-ZUBIATE M,NAVARRO-BLASCO I,FERNáNDEZ J M,et al.Encapsulation,solid-phases identification and leaching of toxic metals in cement systems modified by natural biodegradable polymers[J].Journal of Hazardous Materials,2012,233/234:7-17.
[15] PARK J Y,KANG W H,HWANG I.Hexavalent chromium uptake and release in cement pastes[J].Environmental Engineering Science,2006,23(1):133-140.
[16] RAE R,GRAHAM M C,KIRK C A.Investigating the hydration of C3A in the presence of the potentially toxic element chromium-a route to remediation?[J].RSC Advances,2022,12(45):29329-29337.
[17] WANG X,CUI S P,YAN B L,et al.Isothermal adsorption characteristics and kinetics of Cr ions onto ettringite[J].Journal of Wuhan University of Technology (Materials Science),2019,34(3):587-595.
基本信息:
DOI:
中图分类号:TQ172.1
引用信息:
[1]王缘,王智,谭斌等.硫酸亚铁替代石膏对水泥中Cr(Ⅵ)降低和水泥性能的影响[J].青岛理工大学学报,2024,45(05):27-32.
基金信息:
重庆市自然科学基金资助项目(CSTB2022NSCQ-MSX0647)