Decomposition of flue gas desulfurization (FGD) gypsum under microwave heating to produce sinter ore

doi:10.16085/j.issn.1000-6613.2016.07.043

Abstract

Abstract: The microwave heating characteristic and decomposition of flue gas desulfurization (FGD) gypsum combined with anthracite and magnetite have been investigated with a microwave reactor. The X-ray diffraction (XRD), scanning electron microscopy (SEM) and microcomputer rapid sulfur tester were used to characterize the decomposition residues. The FGD gypsum- (10%)magnetite- (8%)anthracite mixture showed the best microwave heating characteristics where the temperature rose up to 1000℃within 80min. After held for 60min, the desulfurization rate reached to 93.86%. The addition of magnetite, as a kind of catalyst and microwave absorber, significantly increased the sample's temperature and accelerated the decomposition of FGD gypsum to form Ca_xFe_yO_z and SO₂. With the increase of Ca_xFe_yO_z, the desulfurization rate further increased. The SEM images of the residues showed that the morphology of particle sintering took place during the decomposition of FGD gypsum in the presence of magnetite and anthracite under microwave heating. There were no remarkable difference in the chemical composition between Tai-gang sinter ore and the sinter with addition of 5% of the residues which acted as flux slag. Therefore, the decomposition residue can be used in sinter ore of shaft furnace.

Key words: microwave heating, FGD gypsum, magnetite, decomposition residue, sinter ore

摘要： 研究了在微波炉中配加无烟煤磁铁矿的烟气脱硫石膏混合料的升温特性及还原分解性能,应用X射线衍射、扫描电镜和微机快速测硫仪对分解渣进行检测分析。微波加热下,配加10%磁铁矿和8%无烟煤(质量分数)的脱硫石膏混合粉的升温效果最佳,混合物料在80min内升温到1000℃,保温60min后,脱硫率为93.86%。作为催化剂和微波吸收剂,磁铁矿的加入提高了微波加热物料的温度,促进脱硫石膏分解生成Ca_xFe_yO_z,放出SO₂气体。随着Ca_xFe_yO_z含量的增加,物料的脱硫率提高。混合物料分解渣的SEM图像显示,微波加热下,配加磁铁矿和无烟煤的脱硫石膏混合物料分解的过程中发生粒子团聚烧结。配加5%分解渣的烧结矿化学成分与太钢烧结矿的化学成分无显著区别,此分解渣可以作为高炉烧结矿的熔剂配料来使用。

关键词: 微波加热, 脱硫石膏, 磁铁矿, 分解渣, 烧结矿

CLC Number:

TF044

JI Zhonghai, CHEN Jin, GUO Yu, GUO Lina, QIN Li, MENG Lingjia. Decomposition of flue gas desulfurization (FGD) gypsum under microwave heating to produce sinter ore[J]. Chemical Industry and Engineering Progree, 2016, 35(07): 2251-2257.

吉忠海, 陈津, 郭宇, 郭丽娜, 覃礼, 孟令佳. 微波加热分解脱硫石膏生产烧结矿研究[J]. 化工进展, 2016, 35(07): 2251-2257.

References

[1] 钟史明石灰石(石灰)-石膏湿法脱硫FGD在燃煤锅炉脱硫工程中的应用[J]. 沈阳工程学院学报(自然科学版),2012,8(2): 112-115.
[2] ZHENG D,LU H L,SUN X Y,et al. Reaction mechanism of reductive decomposition of FGD gypsum with anthracite[J]. Thermochimica Acta,2013,559:23.
[3] MAO Z,YANG H R,WU Y X,et al. Experimental studies on decomposing properties of desulfurization gypsum in a thermogravimetric analyzer and multiatmosphere fluidized beds[J]. Ind. Eng. Chem. Res.,2012,51:5419-5423.
[4] MA L P,DU Y L,NIU X K,et al. Thermal and kinetic analysis of the process of thermochemical decomposition of phosphogypsum with CO and additives[J]. Ind. Eng. Chem. Res.,2012,51:6680-6685.
[5] ZHANG X M,SONG X F,SUN Z,et al. Density functional theory study on the mechanism of calcium sulfate reductive decomposition by carbon monoxide[J]. Ind. Eng. Chem. Res.,2012,51:6563-6570.
[6] YAN B,MA L P,MA J,et al. Mechanism analysis of Ca,S transformation in phosphogypsum decomposition with Fe catalyst[J]. Ind. Eng. Chem. Res.,2014,53:7648.
[7] SONG T,ZHENG M,SHEN L H,et al. Mechanism investigation of enhancing reaction performance with CaSO₄/Fe₂O₃ oxygen carrier in chemical-looping combustion of coal[J]. Ind. Eng. Chem. Res.,2013,52:4059-4071.
[8] ZHENG SH C,NING P,MA L P,et al. Reductive decomposition of phosphogypsum with high-sulfur-concentration coal to SO₂in an inert atmosphere[J]. Chemical Engineering Research and Design,2011,89:2736.
[9] LYNCH W M. Processing dynamics of plaster[J]. Ceramic Engineering and Science Proceedings,1995,16:82.
[10] SEKARAN Chandrasekaran,TANMAY Basak,RAMANATHAN Srinivasan. Microwave heating characteristics of graphite based powder mixtures[J]. International Communications in Heat and Mass Transfer,2013,48:22-27.
[11] ZHAO X Q,WANG W L,LIU H Z,et al. Temperature rise and weight loss characteristics of wheat straw under microwave heating[J]. Journal of Analytical and Applied Pyrolysis,2014,107:59-66.
[12] RESURRECCION Jr F P,LUAN D,TANG J,et al. Effect of changes in microwave frequency on heating patterns of foods in a microwave assisted thermal sterilization system[J]. Journal of Food Engineering,2015,150:99-105.
[13] LI W,CHEN J,GUO L N,et al. Electromagnetic properties of high-carbon ferrochrome powders decarburized in solid phase by microwave heating[J]. Materials Science and Engineering B,2014,189:58.
[14] 陈鸣. 电子材料 [M].北京:北京邮电大学出版社,2006:20-32,247.
[15] GRANT E H,BUCHANAN,COOK HF. Dielectric behavior of water at microwave frequencies[J]. J. Chem. Phys,1957,26:156.
[16] HAQUE K E. Microwave energy for mineral treatment processes-a brief review[J]. Int. J. Miner. Process,1999,57:1-24.
[17] KONTOGEORGOS D,GHAZI Wakili K,HUGI E. Heat and moisture transfer through a steel stud gypsum board assembly exposed to fire[J]. Construction and Building Materials,2012,26:746.
[18] MA L P,NING P,ZHENG S C,et al. Reaction mechanism and kinetic analysis of the decomposition of phosphogypsum via a solid-state reaction[J]. Ind. Eng. Chem. Res.,2010,49:3597-3602.
[19] USLU T,ATALAY Ü. Microwave heating of coal for enhanced magnetic removal of pyrite[J]. Fuel Processing Technology,2003,85:21-29.
[20] MIAO Z,YANG H R,WU Y X,et al. Experimental studies on decomposing properties of desulfurization gypsum in a thermogravimetric analyzer and multiatmosphere fluidized beds[J]. Ind. Eng. Chem. Res.,2012,51:5419-5423.
[21] OH J S,WHEELOCK T D. Reductive decomposition of calcium sulfate with carbon monoxide: reaction mechanism[J]. Ind. Eng. Chem. Res.,1990,29:544-550.
[22] NAOTO M,DALIBOR K,YOSHIHIRO K. Reductive decomposition of waste gypsum with SiO₂,Al₂O₃,and Fe₂O₃ additives[J]. J. Mater. Cycles Waste Manag.,2007,9(1):21-26.
[23] ISHIZAKI K,STIR M,GOZZO F,et al,Magnetic microwave heating of magnetiteecarbon black mixtures[J]. Materials Chemistry and Physics,2012,134:1007-1012.
[24] 尹德,贺淑珍. 太钢450m²烧结机高精粉配矿烧结技术研究) [J]. 钢铁,2010,45(7):17-22.