水力喷射-空气旋流器用于湿法烟气脱硫及其传质机理

doi:10.3969/j.issn.0438-1157.2013.11.015

化工学报 ›› 2013, Vol. 64 ›› Issue (11): 3993-4000.DOI: 10.3969/j.issn.0438-1157.2013.11.015

水力喷射-空气旋流器用于湿法烟气脱硫及其传质机理

赵清华, 全学军, 程治良, 晏云鹏

重庆理工大学化学化工学院, 重庆 400050

收稿日期:2013-03-11 修回日期:2013-07-25 出版日期:2013-11-05 发布日期:2013-11-05
通讯作者: 全学军
作者简介:赵清华(1974-),女,副教授。
基金资助:
国家自然科学基金项目(21176273);重庆市科技攻关项目(CSTC2010AA7060);重庆市教委项目(KJ120816)。

Wet desulfurization of flue gas and mass transfer mechanism in water-sparged aerocyclone

ZHAO Qinghua, QUAN Xuejun, CHENG Zhiliang, YAN Yunpeng

College of Chemistry and Chemical Engineering, Chongqing University of Technology, Chongqing 400050, China

Received:2013-03-11 Revised:2013-07-25 Online:2013-11-05 Published:2013-11-05
Supported by:
supported by the National Natural Science Foundation of China(21176273),the Key Scientific and Technological Projects of Chongqing(CSTC2010AA7060)and the Science and Technology Project of CQJW(KJ120816).

摘要/Abstract

摘要： 在一种新型高效的气液传质设备——水力喷射-空气旋流器(WSA)中,以Ca(OH)₂料浆为吸收剂进行了模拟烟气湿法脱硫的实验研究。结果表明:脱硫率随进口气速增加而增加;随液体喷射速度增加先增加,增加到一定程度后几乎不变;随烟气中SO₂的进口浓度增加而减小,存在一适宜的Ca(OH)₂浓度和回流比。在气体流量24～72 m³·h^-1、循环液体量0.4～0.8 m³·h^-1、料浆中Ca(OH)₂浓度7500 g·m^-3时,对SO₂浓度为1891～6373 mg·m^-3的烟气进行湿法脱硫,脱硫率达88.9%～97.7%,且WSA的旋流气体和喷射液体在湿法脱硫中具有自清洁能力,未发现内部结垢和喷孔堵塞现象。总体积传质系数K_Ga、有效相界面积a均随进口气速u_G增大而增大,而总传质系数K_G随u_G增加变化较小;当液体喷射速度 u_L≤0.26 m·s^-1时,K_Ga和K_G随u_L增加快速增大,之后增加缓慢,而a随u_L几乎线性增加,K_Ga和K_G随吸收剂中Ca(OH)₂浓度c_L增加有一最大值。结合实验数据拟合得到了相关的经验公式,这些关联式能较好地预测WSA的湿法脱硫传质性能。气体旋流场强度对总体积传质系数K_Ga和有效相界面积a起支配作用,脱硫传质过程同时受气膜和液膜阻力控制,但以液膜控制为主。

关键词: 水力喷射-空气旋流器, 湿法脱硫, 气-液传质, 有效相界面积

Abstract: Wet desulfurization of flue gas was investigated with Ca(OH)₂ slurry as absorbent in a water-sparged aerocyclone(WSA),new and high efficiency gas-liquid mass transfer equipment.The results show that the removal efficiency of SO₂ increases with the inlet gas velocity,first increases linearly with liquid jet velocity u_L,and then remains almost constant when u_L is equal to or greater than 0.29 m·s^-1.The removal efficiency of SO₂ decreases as SO₂ concentration in the flue gas increases,and presents a maximum value with the increase of liquid reflux ratio and Ca(OH)₂ concentration in the absorbent slurry.The removal efficiency of SO₂ can reach 88.9%-97.7% under the following conditions:flue gas flow rate of 24-72 m³·h^-1,absorbent recirculation flow rate of 0.4-0.8 m³·h^-1,Ca(OH)₂ concentration in absorbent of 7500 g·m^-3,and SO₂ concentration in flue gas of 1891-6373 mg·m^-3.No fouling and blocking were found in the WSA because of the self-cleaning ability of the cyclone gas and liquid jet.The mass transfer mechanism in the WSA was also investigated.The results show that the overall volumetric mass transfer coefficient K_Ga and the interfacial area a increase with the increase of inlet gas velocity u_G,the overall mass transfer coefficient K_G increases with u_G slowly.K_Ga and K_G increase quickly with liquid jet velocity u_L when u_L≤0.26 m·s^-1 and then increase slowly,and a increases almost linearly with the increase of u_L.As Ca(OH)₂ concentration c_L increases,K_Ga and K_G increase first and then decrease.The empirical formulae fit the experimental data well and could be used to predict the mass transfer characteristics for wet desulfurization in WSA.Under the experimental conditions,the mass transfer in wet desulfurization in the WSA is controlled by both gas film and liquid film,mainly by liquid film.

Key words: water-sparged aerocyclone, wet desulfurization, gas-liquid mass transfer, interfacial area

中图分类号:

TQ021.1

赵清华, 全学军, 程治良, 晏云鹏. 水力喷射-空气旋流器用于湿法烟气脱硫及其传质机理[J]. 化工学报, 2013, 64(11): 3993-4000.

ZHAO Qinghua, QUAN Xuejun, CHENG Zhiliang, YAN Yunpeng. Wet desulfurization of flue gas and mass transfer mechanism in water-sparged aerocyclone[J]. CIESC Journal, 2013, 64(11): 3993-4000.

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水力喷射-空气旋流器用于湿法烟气脱硫及其传质机理

Wet desulfurization of flue gas and mass transfer mechanism in water-sparged aerocyclone

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