催化剂喷雾成型雾化过程分步式模拟技术及验证

石油炼制与化工 ›› 2024, Vol. 55 ›› Issue (1): 158-163.

催化剂喷雾成型雾化过程分步式模拟技术及验证

张络明^1,2,焦阳¹,苑志伟²,梁维军¹,杨振钰²,赵经伟¹,刘安鼐¹,达志坚³

1. 中国石化催化剂有限公司
2. 中国石化催化剂有限公司工程技术研究院
3. 中石化石油化工科学研究院有限公司

收稿日期:2023-09-18 修回日期:2023-09-25 出版日期:2024-01-12 发布日期:2024-01-15
通讯作者: 焦阳 E-mail:jiaoy.chji@sinopec.com

STEP SIMULATION TECHNIQUE AND EXPERIMENTAL VERIFICATION OF CATALYST SPRAY FORMING ATOMIZATION PROCESS

Received:2023-09-18 Revised:2023-09-25 Online:2024-01-12 Published:2024-01-15

摘要/Abstract

摘要： 雾化过程是催化剂喷雾干燥成型技术中的关键控制步骤，雾化结果直接影响最终产品的粒径分布等性质。针对瞬态雾化过程难以采用试验方法测定其中间过程，且因过程复杂导致无法有效模拟计算的问题，采用将雾化过程分为一级雾化和二级雾化两部分进行分步模拟的方法，分别采用流体体积（VOF）模型对一级雾化的液膜撕裂过程进行模拟，采用流体体积-可变形组件模型（VOF-to-DPM）对二次雾化进行模拟，大幅降低了模拟计算量。结果表明：进料压力为4 MPa以上时，一次雾化足够充分，雾化液滴粒径基本不变；雾化液滴粒径呈双峰分布，较小粒径主要集中于40 μm左右，较大粒径主要集中于95~100 μm；进料压力越高，一次雾化越充分、雾化液滴初始速度越大，二次雾化产生的小粒径雾滴更多。对比模拟结果与试验结果可知，二者一致性较好，说明模拟计算结果具有较好的准确性。

关键词: 催化剂成型, 喷雾干燥, 雾化过程, 分步模拟

Abstract: The atomization process is the key control step in catalyst forming by spray drying technology, and the atomization results directly affect the particle size distribution of the final product. Aiming at the problem that it was difficult to measure the intermediate process of the transient atomization process by the experimental method, and it was difficult to simulate the process effectively because of the complexity of the process, the atomization process was divided into two parts: the first stage atomization and the second stage atomization, and the liquid film tearing process of the first-stage atomization was simulated by the volume of fluid (VOF) model, the volume of fluid-deformable component model (VOF-TO-DPM) was used to simulate the secondary atomization, which greatly reduced the computational load. The results showed that when the feeding pressure was over 4 MPa, the primary atomization was sufficient and the droplet size was basically unchanged. The droplet size presented a bimodal distribution, and the smaller droplet size was mainly concentrated in about 40 μm, and the large droplet size was mainly concentrated in 95~100 μm. The higher the feed pressure was, the fuller the primary atomization and the larger the initial velocity of the droplets was, and the more the small droplets were produced by the secondary atomization. The comparison between the simulation results and the test results showed that they were in good agreement, indicating that the simulation results had a good accuracy.

Key words: catalyst forming, spray drying, atomization process, step-by-step simulation

张络明焦阳苑志伟梁维军杨振钰赵经伟刘安鼐达志坚. 催化剂喷雾成型雾化过程分步式模拟技术及验证[J]. 石油炼制与化工, 2024, 55(1): 158-163.

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