Stable flow characteristics of Geldart C particles of desulfurization ash in a loop-coupled riser

doi:10.11949/0438-1157.20231197

Abstract

Abstract:

The proportion of CO₂ emissions for industrial production is about 70% of the total CO₂ release. It is important to capture this part of the CO₂ emission for carbon peaking and carbon neutrality goals. Flue gas emissions contain a large amount of oxides of sulphur which are harm to the facilities and catalysts. Therefore, deep desulfurization technology of flue gas is key to CO₂ capture process. Circulating fluidized bed semi-dry flue gas desulfurization has attracted wide attention because of its high desulfurization efficiency, no pollution, and controllable residence time. The desulfurization agent in the circulating fluidized bed is mostly desulfurized ash particles which are obviously Geldart C particles. Due to the desulfurized characteristics like strong adhesion, problems are prone to occur during the operation of the fluidized bed. To improve the fluidization situation, this research designed and built a loop-coupled riser reactor with an inner diameter of 100 mm, 300 mm in height, an inner diameter of an outer cylinder of 160 mm, 760 mm in the height, and a conveying section of 75 mm in inner diameter and 12.6 m in height. Under two operating conditions, namely U_g = 4 m/s, G_s = 45 kg/(m²·s) and U_g = 7 m/s, G_s = 25 kg/(m²·s), the pressure distribution, standard deviation and power of the pressure were investigated. It can be considered that when the gas velocity in the annulus zone is 0.4 m/s, the circulation flow in the loop part can reach stable with a continuous dense-phase flow. Then, the distribution of particle flow characteristics including solids holdup and particle velocity in the loop-coupled riser reactor was studied. Experiments have found that the design of circulating flow can strengthen the flow characteristics of Geldart C particles, greatly increase the solid content of Geldart C particle desulfurization ash in the coupling reactor, and achieve stable operation of the Geldart C particle circulation fluidization device. Meanwhile, these results may provide some guide for design new types of reactors for Geldart C particle of emission control.

Key words: circulating fluidized bed, multiphase reactor, fluid mechanics, desulfurization ash particles, Geldart C particle, loop-coupled reactor

摘要：

我国CO₂的排放中70%来自工业领域，故工业过程的碳捕集对实现“双碳目标”十分关键。工业烟气中往往含有的硫氧化物会腐蚀设备并使后续脱碳等过程使用的催化剂中毒。因此，工业烟气的深度脱硫技术对后续的CO₂捕集或提纯过程至关重要。循环流化床半干法烟气脱硫因具有脱硫效率高、无污染、停留时间可控等优点受到广泛关注。循环流化床脱硫工艺中作为脱硫剂的脱硫灰颗粒为典型Geldart C类颗粒。由于C类颗粒的强黏附性，其在循环流化床操作中容易结块，从而影响装置稳定运行。为了强化脱硫灰颗粒在循环流化床内的流动稳定性，提出了环流强化的耦合提升管反应器的概念，并自行设计搭建了一套导流筒内径100 mm、高度300 mm，外筒内径160 mm、高度760 mm，输送段内径75 mm、总高度12.6 m的环流耦合提升管。在U_g = 4 m/s、G_s = 45 kg/(m²·s), U_g = 7 m/s、G_s = 25 kg/(m²·s)的操作条件下，考察了环流段的压力分布、标准差以及功率谱密度。当环隙区气速为0.4 m/s时，环流流动能够实现稳定、连续的密相环流流动。在C类颗粒形成稳定流动基础上，讨论了环流耦合提升管内的流动特性分布规律，包括固含率和颗粒速度。实验发现，环流流动的设计可以强化C类颗粒的流动特性，大幅提高耦合反应器内C类颗粒脱硫灰固含率，并实现了C类颗粒循环流态化装置的稳定运行。同时，这些研究结果可以为C类颗粒新型循环流态化反应器设计提供参考。

关键词: 循环流化床, 多相反应器, 流体力学, 脱硫灰颗粒, Geldart C颗粒, 环流反应器

CLC Number:

TQ 021.1

Chengxiu WANG, Dashan SONG, Zhihui LI, Xiao YANG, Xingying LAN, Jinsen GAO, Chunming XU. Stable flow characteristics of Geldart C particles of desulfurization ash in a loop-coupled riser[J]. CIESC Journal, 2024, 75(4): 1485-1496.

王成秀, 宋大山, 李之辉, 杨潇, 蓝兴英, 高金森, 徐春明. Geldart C类脱硫灰颗粒在环流耦合提升管内稳定流动特性[J]. 化工学报, 2024, 75(4): 1485-1496.

Figures/Tables 9

Fig.1 Schematic diagram of experimental apparatus for circulating coupled riser reactor

Table 1 Dimensionless radial position for each region of the loop-coupled reactor

Dimensionless radial position	Draft tube region	Annulus region	Transition region	Transmission region
R₀/R	0	—	0	0
R₁/R	0.158	—	0.158	0.158
R₂/R	0.382	—	0.382	0.382
R₃/R	0.497	—	0.497	0.497
R₄/R	0.590	—	0.590	0.590
R₅/R	—	0.669	0.669	0.669
R₆/R	—	0.741	0.741	0.741
R₇/R	—	0.805	0.805	0.805
R₈/R	—	0.866	0.866	0.866
R₉/R	—	0.922	0.922	0.922
R₁₀/R	—	0.974	0.974	0.974

Fig.2 Particle size distribution curve of desulphurized ash

Fig.3 The distribution of pressure, pressure difference and flow field in the loop section

Fig.4 The variation of the pressure standard deviation in the loop section with the apparent gas velocity in the draft tube region and annulus region

Fig.5 Power spectral density distributions of pressure signals under different operating conditions (z = 0.2 m)

Fig.6 Distribution of solid holdup of desulphurized ash particles in the draft tube region and annulus region at each axial position of loop zone

Fig.7 Distribution of solids holdup of desulphurized ash particles in the loop-coupled reactor (a) and riser (b)

Fig.8 Distribution of particle velocity of desulphurized ash particles in the loop-coupled reactor (a) and riser (b)

References 38

1	熊波, 陈健, 李克兵, 等. 工业排放气二氧化碳捕集与利用技术进展[J]. 低碳化学与化工, 2023, 48(1): 9-18.
	Xiong B, Chen J, Li K B, et al. Technical progress in carbon dioxide capture and utilization of industrial vent gas[J]. Low-Carbon Chemistry and Chemical Engineering, 2023, 48(1): 9-18.
2	窦立荣, 孙龙德, 吕伟峰, 等. 全球二氧化碳捕集、利用与封存产业发展趋势及中国面临的挑战与对策[J]. 石油勘探与开发, 2023, 50(5): 1083-1096.
	Dou L R, Sun L D, Lyu W F, et al. Trend of global carbon dioxide capture, utilization and storage industry and challenges and countermeasures in China[J]. Petroleum Exploration and Development, 2023, 50(5): 1083-1096.
3	Khoma М S, Vasyliv K B, Chuchman М R. Influence of the hydrogen sulfide concentration on the corrosion and hydrogenation of pipe steels (a survey)[J]. Materials Science, 2021, 57(3): 308-318.
4	Guo K, Ji J W, Song W, et al. Conquering ammonium bisulfate poison over low-temperature NH₃-SCR catalysts: a critical review[J]. Applied Catalysis B: Environmental, 2021, 297: 120388.
5	贠莹, 高峰, 高鲜会. 催化裂化装置再生烟气醇胺法回收CO₂技术模拟研究[J]. 炼油技术与工程, 2023, 53(2): 10-14.
	Yun Y, Gao F, Gao X H. Simulation study of CO₂ recovery from regenerated flue gas of FCC unit by alcohol amine method[J]. Petroleum Refinery Engineering, 2023, 53(2): 10-14.
6	刘忠生, 王学海, 齐慧敏, 等. 催化裂化烟气脱硝脱硫除尘新技术[J]. 石油炼制与化工, 2018, 49(1): 103-108.
	Liu Z S, Wang X H, Qi H M, et al. New technologies of denitration, desulfurization and dust removal for FCC flue gas[J]. Petroleum Processing and Petrochemicals, 2018, 49(1): 103-108.
7	Matsushima N, Li Y, Nishioka M, et al. Novel dry-desulfurization process using Ca(OH)₂/fly ash sorbent in a circulating fluidized bed[J]. Environmental Science & Technology, 2004, 38(24): 6867-6874.
8	Zhou Y G, Wang D F, Zhang M C. Study on multiphase flow and mixing in semidry flue gas desulfurization with a multifluid alkaline spray generator using particle image velocimetry[J]. Industrial & Engineering Chemistry Research, 2009, 48(12): 5808-5815.
9	Hansen B B, Kiil S. Investigation of parameters affecting gypsum dewatering properties in a wet flue gas desulphurization pilot plant[J]. Industrial & Engineering Chemistry Research, 2012, 51(30): 10100-10107.
10	Jin Y. The influence of exit structures on the axial distribution of voidage in fast fluidized bed [C]//Fluidization 88 Science and Technology. Beijing: Science Press, 1988: 165-173.
11	金涌. 流态化工程原理[M]. 北京: 清华大学出版社, 2001.
	Jin Y. Fluidization Engineering Principles[M]. Beijing: Tsinghua University Press, 2001.
12	Montagnaro F, Salatino P, Scala F, et al. A population balance model on sorbent in CFB combustors: the influence of particle attrition[J]. Industrial & Engineering Chemistry Research, 2011, 50(16): 9704-9711.
13	Figueroa I, Li H M, McCarthy J. Predicting the impact of adhesive forces on particle mixing and segregation[J]. Powder Technology, 2009, 195(3): 203-212.
14	Katoh K, Song S, Wakimoto T, et al. A study on the removal of infinitesimal particles on a wall by high-speed air jet―measurements of adhesive force and particle removal rate[J]. Journal of Fluid Science and Technology, 2014, 9(3): JFST0032.
15	Barletta D, Poletto M. Aggregation phenomena in fluidization of cohesive powders assisted by mechanical vibrations[J]. Powder Technology, 2012, 225: 93-100.
16	Montz K W, Beddow J K, Butler P B. Adhesion and removal of particulate contaminants in a high-decibel acoustic field[J]. Powder Technology, 1988, 55(2): 133-140.
17	Lepek D, Valverde J M, Pfeffer R, et al. Enhanced nanofluidization by alternating electric fields[J]. AIChE Journal, 2010, 56(1): 54-65.
18	Zhou T, Li H Z. Effects of adding different size particles on fluidization of cohesive particles[J]. Powder Technology, 1999, 102(3): 215-220.
19	Xu C C, Zhang H, Zhu J. Improving flowability of cohesive particles by partial coating on the surfaces[J]. The Canadian Journal of Chemical Engineering, 2009, 87(3): 403-414.
20	Mori S, Yamamoto A, Iwata S. Vibro-fluidization of group-C particles and its industrial applications[J]. AIChE Symposium Series, 1990, 86(276): 88-94.
21	Brekken R A, Lancaster E B, Wheellock T D. Fluidization of flour in a stirred aerated bed(Ⅰ): General fluidization characteristics[C]// Chemical Engineering Progress, Symposium Series. 1970, 66(101): 81-90.
22	Zhu Q S, Li H Z. Study on magnetic fluidization of group C powders[J]. Powder Technology, 1996, 86(2): 179-185.
23	Lu X S, Li H Z. Fluidization of CaCO₃ and Fe₂O₃ particle mixtures in a transverse rotating magnetic field[J]. Powder Technology, 2000, 107(1/2): 66-78.
24	Kato K, Takarada T, Matsuo N, et al. Residence time distribution of fine particles in a powder-particle fluidized bed[J]. International Chemical Engineering, 1994, 34(4): 605-610.
25	Krupp H. Particle adhesion theory and experiment[J]. Advances in Colloid and Interface Science, 1967, 1(2): 111-239.
26	Nowakw W, Hasatani M. Fluidization and heat transfer of fine particles in an acoustic field[J]. AIChE Symposium Series, 1993, 89(296): 137-149.
27	Chirone R, Massimilla L, Russo S. Bubble-free fluidization of a cohesive powder in an acoustic field[J]. Chemical Engineering Science, 1993, 48(1): 41-52.
28	Milne B J, Berruti F, Behie L A, et al. The internally circulating fluidized bed (ICFB): a novel solution to gas bypassing in spouted beds[J]. The Canadian Journal of Chemical Engineering, 1992, 70(5): 910-915.
29	沈志远, 杨利军, 刘梦溪, 等. 中心气升式环流反应器内压力脉动特性的研究[J]. 中国粉体技术, 2014, 20(6): 1-8.
	Shen Z Y, Yang L J, Liu M X, et al. Investigation of pressure fluctuation in draft tube-lifted gas-solid air loop reactor[J]. China Powder Science and Technology, 2014, 20(6): 1-8.
30	卢春喜, 范怡平, 刘梦溪, 等. 催化裂化反应系统关键装备技术研究进展[J]. 石油学报(石油加工), 2018, 34(3): 441-454.
	Lu C X, Fan Y P, Liu M X, et al. Advances in key equipment technologies of reaction system in RFCC unit[J]. Acta Petrolei Sinica (Petroleum Processing Section), 2018, 34(3): 441-454.
31	Wang F F, Ma S H, Wen J J, et al. Gas hydrodynamics of a novel MTO high-speed loop reactor: the bypassing and backmixing along with average residence time[J]. Powder Technology, 2020, 364: 1062-1075.
32	卢春喜, 徐桂明, 卢水根, 等. 用于催化裂化的预汽提式提升管末端快分系统的研究及工业应用[J]. 石油炼制与化工, 2002, 33(1): 33-37.
	Lu C X, Xu G M, Lu S G, et al. Study and industry application of a pre-stripping separation system for riser termination of FCCU[J]. Petroleum Processing and Petrochemicals, 2002, 33(1): 33-37.
33	刘显成,卢春喜,时铭显. 两段气升式气固环流取热器导流筒壁与床层间的传热特性研究[J]. 过程工程学报, 2004, 4(z1): 611-618.
	Liu X C, Lu C X, Shi M X. Study on heat transfer between gas solids suspension and the surfaces of two draft tubes in an airlift loop heat exchanger[J]. The Chinese Journal of Process Engineering, 2004, 4(z1): 611-618.
34	Zhu L Y, Fan Y P, Wang Z B, et al. Comparative study of hydrodynamic and mixing behaviors in different pre-lifting schemes for an FCC riser[J]. Powder Technology, 2016, 301: 557-567.
35	严超宇. 新型组合流化床石油焦燃烧器内气固流动行为研究[D]. 北京: 中国石油大学(北京), 2007.
	Yan C Y. Gas-solid flow behavior in a new combined fluidized bed petroleum coke combustor[D]. Beijing: China University of Petroleum, 2007.
36	Liu M X, Lu C X, Zhu X M, et al. Bed density and circulation mass flowrate in a novel annulus-lifted gas-solid air loop reactor[J]. Chemical Engineering Science, 2010, 65(22): 5830-5840.
37	Jaiboon O A, Chalermsinsuwan B, Mekasut L, et al. Effect of flow pattern on power spectral density of pressure fluctuation in various fluidization regimes[J]. Powder Technology, 2013, 233: 215-226.
38	丁睿, 王德武, 刘燕, 等. 提升管加床层反应器不同操作模式下的压力脉动特性[J]. 过程工程学报, 2016, 16(5): 721-729.
	Ding R, Wang D W, Liu Y, et al. Pressure fluctuation characteristics of riser-fluidized bed reactor under different operating modes[J]. The Chinese Journal of Process Engineering, 2016, 16(5): 721-729.

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