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钢渣中的铁氧化物是影响钢渣粉活性的因素之一。为改善钢渣粉水化活性,实现钢渣和煤矸石协同处置,利用煤矸石中残碳还原和分离出钢渣中的铁,研究了不同温度下煤矸石与钢渣制备的水淬残渣的物相变化以及水化活性。结果表明:提高还原温度,可以显著提高铁的回收率,最高可达94%。还原温度低于1 450℃时,水淬残渣中的矿物相主要为钙镁蔷薇辉石和钙铝黄长石。随着温度分别升高到1 450℃和1 500℃,钙镁蔷薇辉石和钙铝黄长石相消失。此时,水淬残渣主要由玻璃相组成。还原温度升高导致水淬残渣中玻璃相含量增多,胶凝活性增强,掺加高还原温度水淬渣的水泥水化反应累计放热量更大。
Abstract:Introduction Using as supplementary cementitious materials (SCM) is one of the most important research topics in the resource utilization field of steel slag.However,the iron oxide content in steel slag is greater than that of other cementitious materials (i.e.,clinker,granulated blast furnace slag,and fly ash).The solid solution formed by FeO and CaO-MnO-MgO (RO phase),hematite,wustite,Ca2Fe2O5(C2F) and other Fe-bearing phases have little contribution to the activity of ground steel slag.Some researchers use reductants such as H2,CO,anthracite,silicon carbide,and carbon powder to reduce iron oxides from molten steel slag into ferroalloys.Aluminosilicate melt is quenched and resultant residual used as SCM.These methods have a challenge of high cost of reducing agents and difficulty in industrial utilization.This paper used residual carbon in coal gangue as a reductant to reduce iron oxides of steel slag.The remaining aluminosilicate was quenched to prepare slag with a high hydration activity,which could achieve the synergistic disposal of two types of industrial solid waste.Methods Based on the chemical composition of steel slag and coal gangue,as well as the fixed carbon content of coal gangue,the amount of coal gangue required for the sufficient reduction of iron oxide in the two raw materials was determined.After mixing ground coal gangue and ground steel slag thoroughly,the mixture was heated to 1 200,1 300,1 350,1 400,1 450℃and 1 500℃at40℃/min in an argon atmosphere (3 L/min),and then quenched with water after holding for 30 min.The resultant strip off iron particles,and the remaining aluminum silicate is called water quenched residue (WQR).The iron recovery rate was determined according to the chemical composition of the WQR.The mineral phases were determined by an X-ray diffractometer (XRD,Rigaku Co.,Japan),and the glass content in water quenched residue was calculated using the Rietveld quantitative analysis method.The paste and mortar samples were prepared by adding 30%(in mass fraction) WQR into the reference cement.The cross-sectional morphology was determined by a model GeminiSEM 500 scanning electron microscope (Zeiss Co.,Germany).The elements distribution of the paste samples was analyzed.The heat release curve of hydration for the first 72 h was recorded with a model TAM-Air-8microcalorimeter (TA Instruments Co.,USA).The thermal behavior of the pure slurry after hydration for 3 d,7 d and 28 d were analyzed by a model TGA/DSC1/1600 thermogravimeter (TG,Mettler Toledo Co.,USA).The mortar specimens with a dimension of 40 mm×40 mm×160 mm were used for testing flexural and compressive strength after standard curing to the specific age.Results and discussion The reduction temperature is an important factor affecting the iron recovery rate in steel slag and the vitrification of WQR.When the reduction temperature exceeds 1 300℃,the reduction rate significantly increases.When the temperature exceeds 1 350℃,the Fe2O3 content decreases from 20%in the steel slag raw material to less than 2%in the WQR.The main mineral phases in the reduced residue at 1 100℃are merwinite and gehlenite.When the temperature rises to 1 350℃,the diffraction peaks of gehlenite disappear.At 1 450℃,the diffraction peaks of merwinite almost disappear.When the reduction temperature is less than 1 300℃,the glass content in WQR is less than 60%.When the temperature reaches 1 350℃,the glass increases rapidly,approaching 80%.The glass exceeds 90%with further increasing the reduction temperature to 1 450℃.The fusion temperature is an important factor for the degree of vitrification of WQR.The hydration heat release curve of cement paste shows that the second exothermic peak of sample prepared with WQR generated at 1 500℃is similar to the peak of the reference cement,but the exothermic peak attributed to the formation of the second ettringite decreases.The second exothermic peak of cement with WQR at 1 400℃is 1 mw/g lower than that of WQR cement at1 500℃.A lower heat release rate is due to the presence of crystalline phases in the WQR at 1 400℃.After 72-h hydration,a higher cumulative heat of the paste prepared with WQR at a higher melting temperature occurs.The cumulative heat of WQR cement at1 400℃and 1 500℃is 71.65%and 85.64%of the reference cement,respectively.This is due to the high reduction temperature leading to a high degree of vitrification,thereby improving the hydration activity of the WQR.The XRD and TG results indicate that the Ca(OH)2 content in the paste gradually decreases with the increase of steel slag reduction temperature and the hydration time of WQR cement.This is because the glass content and pozzolanic activity of WQR increase with the increase of reduction temperature.Consequently,the Ca(OH)2 content of WQR cement decreases.The strength results of the mortar show that the 3-d flexural strength of cement with 30%WQR is almost equivalent to that of the reference cement.The growth rate of flexural strength of WQR cement is higher than that of reference cement with curing time,and its strength reaches 130%of reference cement strength at 28 d.The compressive strength of WQR cement at 3 d is 60%of the reference cement.The compressive strength development rate of WQR cement is higher than that of reference cement.After 28-d hydration,the compressive strength of cement prepared with WQR at 1 400℃reaches 90%of the reference cement strength.Conclusions The recovery rate of Fe could reach 63%~94%by using carbon in coal gangue as a reducing agent to reduce iron oxide of steel slag.The reduction rate increased as the reduction temperature increased.When the reduction temperature was below 1 300℃,the mineral phases of the WQR mainly consisted of merwinite and gehlenite.The crystalline phase gradually decreased as the temperature increased.When the reduction temperature was>1 450℃,the glass content maintained at 91%.The glass phase content and the pozzolanic activity in WQR increased as the reduction temperature increased.The cement prepared with WQR had good mechanical properties.After 28-d hydration,the flexural strength and compressive strength of WQR cement reached 130%and 90%of the reference cement,respectively.
[1] SHEN H T, FORSSBERG E. An overview of recovery of metals from slags[J]. Waste Manag, 2003, 23(10):933–949.
[2] JIA R Q, LIU J X, JIA R Q. A study of factors that influence the hydration activity of mono-component Ca O and bi-component Ca O/Ca2Fe2O5 systems[J]. Cem Concr Res, 2017, 91:123–132.
[3] WANG Q, YAN P Y, YANG J W, et al. Influence of steel slag on mechanical properties and durability of concrete[J]. Constr Build Mater,2013, 47:1414–1420.
[4] WANG Q, YAN P Y, FENG J W. A discussion on improving hydration activity of steel slag by altering its mineral compositions[J]. J Hazard Mater, 2011, 186(2/3):1070–1075.
[5] LYU B B, WANG G, ZHAO L D, et al. Effect of atmosphere and basicity on softening–melting behavior of primary slag formation in cohesive zone[J]. J Iron Steel Res Int, 2023, 30(2):227–235.
[6] LINDVALL M, YE G. Experiences of using various metallurgical reactors for reduction of vanadium bearing steel slags and other wastes[C]//International smelting technology symposium:incorporating the 6th advances in sulfide smelting symposium,Hoboken, NJ, USA, 2012:147–154.
[7] LIU C W, HUANG S G, WOLLANTS P, et al. Valorization of BOF steel slag by reduction and phase modification:Metal recovery and slag valorization[J]. Metall Mater Trans B, 2017, 48(3):1602–1612.
[8] GUO H, YIN S H, YU Q J, et al. Iron recovery and active residue production from basic oxygen furnace(BOF)slag for supplementary cementitious materials[J]. Resour Conserv Recycl, 2018, 129:209–218.
[9] LEE J, AN S B, SHIN M, et al. Valorization of electrical arc furnace oxidizing slag[M]. Celebrating the Megascale. Cham:Springer, 2014:347–355.
[10]殷素红,郭辉,余其俊,等.还原铁法重构钢渣及其矿物组成[J].硅酸盐学报, 2013, 41(7):966–971.YIN Suhong, GUO Hui, YU Qijun, et al. J Chin Ceram Soc, 2013,41(7):966–971.
[11]杨曜.钢渣中FeOx还原反应热力学、Fe还原回收效果及余渣性能的研究[D].广州:华南理工大学, 2013.YANG Yao. Study on thermodynamics of FeOx deoxidization, Fe recycled from steel slag and properties of residue[D]. Guangzhou:South China University of Technology, 2013.
[12]郭辉.转炉钢渣中铁的还原回收及制备高胶凝性水淬渣的方法研究[D].广州:华南理工大学, 2018.GUO Hui. Iron recovery and preparation of water-quenched slag with high cementitious performance from BOF slag by means of reduction.Guangzhou:South China University of Technology, 2018.
[13]贺宁,侯新凯,赵正富,等.分选出钢渣中惰性矿物改善其胶凝性[J].硅酸盐通报, 2016, 35(2):437–442.HE Ning, HOU Xinkai, ZHAO Zhengfu, et al. Bull Chin Ceram Soc,2016, 35(2):437–442.
[14] PAL S C, MUKHERJEE A, PATHAK S R. Investigation of hydraulic activity of ground granulated blast furnace slag in concrete[J]. Cem Concr Res, 2003, 33(9):1481–1486.
[15] ALLAHVERDI A, MALEKI A, MAHINROOSTA M. Chemical activation of slag-blended Portland cement[J]. J Build Eng, 2018, 18:76–83.
[16] FERNáNDEZ-CARRASCO L, TORRENS-MARTíN D, MORALES L M, et al. Infrared spectroscopy in the analysis of building and construction materials[M]. THEOPHANIDES T. Ed. Infrared Spectroscopy-Materials Science, Engineering and Technology. InTech,2012.
[17] KLEDY?SKI Z, MACHOWSKA A, PACEWSKA B, et al.Investigation of hydration products of fly ash–slag pastes[J]. J Therm Anal Calorim, 2017, 130(1):351–363.
[18] DE BENEDETTO G E, LAVIANO R, SABBATINI L, et al. Infrared spectroscopy in the mineralogical characterization of ancient pottery[J]. J Cult Herit, 2002, 3(3):177–186.
[19] AKYUZ S, AKYUZ T, BASARAN S, et al. Analysis of ancient potteries using FT-IR, micro-Raman and EDXRF spectrometry[J]. Vib Spectrosc, 2008, 48(2):276–280.
[20] VELRAJ G, RAMYA R, HEMAMALINI R. FT-IR spectroscopy,scanning electron microscopy and porosity measurements to determine the firing temperature of ancient megalithic period potteries excavated at Adichanallur in Tamilnadu, South India[J]. J Mol Struct, 2012, 1028:16–21.
[21] TARHAN?, I??K?, S??üT B. Application of ATR-FTIR spectroscopy in tandem with chemometrics for assessing the firing conditions of Hellenistic and Roman ceramic shards excavated from the ancient city of Stratonikeia in South-Western Turkey[J].Microchem J, 2021, 162:105852.
[22] KRISKOVA L, PONTIKES Y, CIZER?, et al. Hydraulic behavior of mechanically and chemically activated synthetic merwinite[J]. J Am Ceram Soc, 2014, 97(12):3973–3981.
[23] SITARZ M. The structure of simple silicate glasses in the light of Middle Infrared spectroscopy studies[J]. J Non Cryst Solids, 2011,357(6):1603–1608.
[24] LI Z, MA G J, ZHENG D L, et al. Effect of Fe2O3 on the crystallization behavior, microstructure and properties of glass-ceramics prepared from the modified tailings after reduction of copper slag[J]. Mater Today Commun, 2022, 31:103516.
[25] SCRIVENER K, OUZIA A, JUILLAND P, et al. Advances in understanding cement hydration mechanisms[J]. Cem Concr Res, 2019,124:105823.
[26] BULLARD J W, JENNINGS H M, LIVINGSTON R A, et al.Mechanisms of cement hydration[J]. Cem Concr Res, 2011, 41(12):1208–1223.
[27] HIRSCH T, MATSCHEI T, STEPHAN D. The hydration of tricalcium aluminate(Ca3Al2O6)in Portland cement-related systems:A review[J].Cem Concr Res, 2023, 168:107150.
[28] HANDKE M. Vibrational spectra, force constants, and Si-O bond character in calcium silicate crystal structure[J]. Appl Spectrosc, 1986,40(6):871–877.
[29] ZHANG L, JIA Y, SHU H, et al. The effect of basicity of modified ground granulated blast furnace slag on its denitration performance[J].J Clean Prod, 2021, 305:126800.
[30] MOZGAWA W, DEJA J. Spectroscopic studies of alkaline activated slag geopolymers[J]. J Mol Struct, 2009, 924–926:434–441.
[31] ISMAIL I, BERNAL S A, PROVIS J L, et al. Microstructural changes in alkali activated fly ash/slag geopolymers with sulfate exposure[J].Mater Struct, 2013, 46(3):361–373.
[32] PRASANNA K M, SHARATH B P, CHOUKADE H, et al. Research on setting time, compressive strength and microstructure of fly ash-based geopolymer mixture containing slag[J]. Iran J Sci Technol Trans Civ Eng, 2023, 47(3):1503–1517.
[33] ASTOVEZA J, TRAUCHESSEC R, MIGOT-CHOUX S, et al.Iron-rich slag addition in ternary binders of Portland cement,aluminate cement and calcium sulfate[J]. Cem Concr Res, 2022, 153:106689.
[34] HORGNIES M, CHEN J J, BOUILLON C. Overview about the use of Fourier Transform Infrared spectroscopy to study cementitious materials[C]. Brebbia C A, Mammoli A A, Klemm A eds, Materials Characterisation VI, WIT PressSouthampton, UK:WIT Press, 2013:251–262.
[35] ZHAN J H, FU B, CHENG Z Y. Macroscopic properties and pore structure fractal characteristics of alkali-activated metakaolin–slag composite cementitious materials[J]. Polymers, 2022, 14(23):5217.
[36] KIM J J, FOLEY E M, REDA TAHA M M. Nano-mechanical characterization of synthetic calcium–silicate–hydrate(C–S–H)with varying Ca O/SiO2 mixture ratios[J]. Cem Concr Compos, 2013, 36:65–70.
[37] SCRIVENER K, SNELLINGS R, LOTHENBACH B. A practical guide to microstructural analysis of cementitious materials[M]. New York:CRC Press, 2018.
基本信息:
DOI:10.14062/j.issn.0454-5648.20230603
中图分类号:X757;TD849.5;TQ172.1
引用信息:
[1]宋强,聂娇,宋甜甜等.温度对煤矸石还原钢渣铁氧化物制备的水淬渣活性的影响[J].硅酸盐学报,2024,52(02):522-532.DOI:10.14062/j.issn.0454-5648.20230603.
基金信息:
陕西省科学技术研究计划(2022GY-418,2022KXJ-008,2023GXLH-052); 陕西省教育厅重点研发计划(20JY040)