水泥生产全过程硫循环机制的研究进展

doi:10.11896/j.issn.1005-023X.2018.23.018

材料导报

2018, Vol. 32

Issue (23): 4160-4169 https://doi.org/10.11896/j.issn.1005-023X.2018.23.018

无机非金属及其复合材料

水泥生产全过程硫循环机制的研究进展

王俊杰, 房晶瑞, 汪澜

中国建筑材料科学研究总院绿色建筑材料国家重点实验室,北京 100024

The Sulfur Cycle Mechanism in the Whole Process of Cement Manufacturing: a Review

WANG Junjie, FANG Jingrui, WANG Lan

State Key Laboratory of Green Building Materials, China Building Materials Academy, Beijing 100024

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摘要 SO₂是水泥行业产生的主要大气污染物之一。国内外对水泥行业SO₂排放量进行了严格限定。随着劣质原燃材料及替代燃料的大规模使用,更多的硫将被带入水泥生产过程中。这不仅会引起SO₂排放水平的增高,而且会加重硫在水泥窑炉内的循环富集,影响窑炉的正常操作,同时对熟料质量产生影响。
水泥生产过程中的硫由原料和燃料带入。其中,部分原料硫在预热器内转变为SO₂并随烟气离开,在生料磨和收尘器内被生料部分吸收,并再次进入预热器,形成了硫在预热器和生料磨、收尘器间的低温循环。未转变为SO₂的原料硫和燃料硫在水泥窑炉高温环境下形成SO₂,并被分解炉内的碱性氧化物吸收,形成硫酸盐进入回转窑,在回转窑烧成区部分硫酸盐发生分解,产生的SO₂再次进入分解炉,由此形成了硫在分解炉-回转窑间的高温循环。
围绕水泥生产过程硫的低温循环和高温循环,国内外开展了大量研究。围绕硫的低温循环,首先揭示了水泥生产排放的SO₂主要是由原料中硫铁矿和有机硫的氧化反应引起。硫铁矿的氧化温度约为400 ℃,反应产物以FeS_X、Fe₂O₃为主。根据反应条件的差异,硫铁矿氧化机理包括直接氧化和先分解为硫黄铁矿再氧化。在预热器内CaCO₃和CaO可吸收部分SO₂,其中CaCO₃对SO₂的吸收为直接硫化反应,反应速率受烟气温度、水分含量、CO₂浓度等影响;部分研究者对CaO在预热器内吸收SO₂提出争议,认为CaO会优先与CO₂反应而影响其对SO₂的吸收。生料磨内SO₂的吸收效率被认为随烘干温度升高而降低,随原料水分含量增加而提高,固硫产物以CaSO₃·1/2H₂O为主,其会在生料颗粒表面富集。围绕硫的高温循环,研究结果表明硫酸盐在回转窑内的分解反应受温度、O₂浓度、硫碱比等影响。水泥窑协同处置替代燃料时产生的热解气体会显著降低CaSO₄的分解温度,促进SO₂释放;该现象随着替代燃料粒径的减小、挥发分含量的增加而加剧。熟料中硫的存在形式主要为K₂SO₄、3K₂SO₄·Na₂SO₄、K₂SO₄·2CaSO₄、CaSO₄或替换其他物质存在于硅酸盐矿物中,熟料中硫含量的增加会稳定C₂S而抑制C₃S形成。
本文综述了水泥生产全过程硫的循环机制,聚焦硫的低温和高温循环。围绕硫的低温循环,阐述了生料含硫形式及其检测方法、硫铁矿氧化及SO₂释放特性、CaCO₃和CaO在预热器环境下对SO₂的吸收机理以及粉磨过程生料的固硫作用;围绕硫的高温循环,阐述了硫在水泥窑炉内的挥发与循环机制、替代燃料对硫释放的影响、硫在熟料中的存在形式及对熟料质量的影响。

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	王俊杰
	房晶瑞
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关键词: 水泥行业硫循环机制

Abstract: As one of the principal air pollutants produced by cement industry, the SO₂ emission levels have been strictly limi-ted all over the word. However, with the mass adoptions of inferior quality raw materials and alternative fuels in the future, more sulfur will be brought into the cement production process. Hence leading to the increase of the SO₂ emission level and aggravate the circulation enrichment of sulfur in the cement kiln, which has an impact on the operation of the kiln and the quality of clinker as well.
During the cement production process, SO₂ originated from both raw meal and fuel. Among them, part of the sulfur from raw meal was oxidized to SO₂ in the preheater system and left with flue gas, then a portion of the SO₂ was captured by the raw meal in the grinding and de-dusting system and entered the preheater system again, thus, forming a low-temperature sulfur cycle among the preheater, the raw meal mill and the dust collector. The rest of the sulfur from the raw meal and the fuel was transformed to SO₂ in the kiln and calciner under high temperature, and the most of the SO₂ was absorbed in the calciner generating the alkali sulfates, afterwards the alkali sulfates would enter the rotary kiln and partially decomposed in the burning zone, the generated SO₂ would enter the calciner again and a high-temperature sulfur cycle was established in the kiln and calciner.
Extensive research on low-temperature cycle and high temperature cycle of sulfurt in the cement production process has been devoted at home and abroad. For the relative low-temperature sulfur cycle, the emission of SO₂ in the cement production was produced through the oxidation of pyrite and organic sulfur. The oxidation temperature of pyrite begins at about 400 ℃, and the reaction pro-ducts mainly consist of FeS_X and Fe₂O₃. According to the diverse reaction conditions, the oxidation mechanisms of pyrite were classified into the direct oxidation and the reoxidation by thermal decomposition to pyrrhotite first. In the preheater, CaCO₃ and CaO absorbed a portion of SO₂. The SO₂ absorption by CaCO₃ belonged to direct sulfuration reaction, whose reaction rate highly depended on the temperature, moisture content and CO₂ concentration of the flue gas. Some researches deemed that CaO was prior to react with CO₂ in the preheater circumstance, which would affect the absorption of SO₂. The absorption efficiency of SO₂ in the raw meal mill was considered to decrease with the increasing drying temperature or decreasing moisture content of the raw material particles. The reaction product was dominated by CaSO₃·1/2H₂O, which would form an enrichment on the surface of the raw meal particles. For the relative high-temperature sulfur cycle, the studies indicated that the temperature, O₂ concentration, and sulfur/alkali ratio played a pivotal role in the decomposition reaction of sulfate in the rotary kiln. The pyrolysis gas generated when the cement kiln co-disposes the alternative fuel would significantly reduce the decomposition temperature of CaSO₄ and promote the release of SO₂, which would aggravate with the decrease of the size of alternative fuel and the increase of volatile matter content. The sulfur contained in the clinker was mainly in the form of K₂SO₄、3K₂SO₄·Na₂SO₄、K₂SO₄·2CaSO₄、CaSO₄, and other substances in the silicate minerals, wherein increasing the sulfur content in the clinker would stabilize the C₂S and inhibite the formation of C₃S.
This paper reviews the cycle mechanisms of sulfur in the whole process of cement production and emphases the low-temperature and high-temperature cycle of sulfur. Revolving round the low-temperature cycle of sulfur, the writer detailedly expounds the sulfur-containing form of raw meal and its detection methods, the oxidation of pyrites and the characteristics of releasing the SO₂, the absorption mechanism of CaCO₃ and CaO in the preheater environment, and the sulfur fixation of the raw meal in the grinding process, respectively. Furthermore, the writer elaborates the volatilization and circulation mechanism of sulfur in the cement kiln, the in-fluence of alternative fuels on sulfur release, the form of sulfur in the clinker and its effects on the quality of clinker on the high-temperature cycle of sulfur.

Key words: cement industry sulfur looping mechanism

出版日期: 2018-12-10 发布日期: 2018-12-20

ZTFLH:	TU522.064
	TB321

基金资助: 国家重点研发计划(2017YFC0210801)

作者简介: 王俊杰:男,1989年生,博士研究生,工程师,研究方向为水泥窑炉节能减排技术 E-mail:cbmawangjunjie@163.com;王澜:通信作者,男,1959年生,博士研究生导师,教授,研究方向为水泥生产新工艺、节能减排新技术

引用本文:

王俊杰, 房晶瑞, 汪澜. 水泥生产全过程硫循环机制的研究进展[J]. 材料导报, 2018, 32(23): 4160-4169.
WANG Junjie, FANG Jingrui, WANG Lan. The Sulfur Cycle Mechanism in the Whole Process of Cement Manufacturing: a Review. Materials Reports, 2018, 32(23): 4160-4169.

链接本文:

http://www.mater-rep.com/CN/10.11896/j.issn.1005-023X.2018.23.018 或 http://www.mater-rep.com/CN/Y2018/V32/I23/4160

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