Investigation of reactor wall coating due to electrostatic charging in a pilot plant high-pressure gas-solid fluidization system.

对中试装置高压气固流化系统中静电充电引起的反应器壁涂层的研究。

• 批准号: 469535-2014
• 负责人: Mehrani, Poupak
• 金额: $ 1.56万
• 依托单位: University of Ottawa
• 依托单位国家: 加拿大
• 项目类别: Collaborative Research and Development Grants
• 财政年份: 2016
• 资助国家: 加拿大
• 起止时间: 2016-01-01 至 2017-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=598439
• 关键词: Investigation; reactor; wall; coating; due

One major problem in gas-solid fluidized bed reactors is particle agglomeration and reactor wall fouling, which is known to be as a result of generation of electrostatic charges due to vigorous mixing of solid particles in such systems. The significant impact of this phenomenon has been reported in industries such as polymer, and oil and gas. In polyethylene gas-solid fluidized bed reactors, electrostatic adhesion due to highly charged particles results in formation of undesired polymer sheets on the reactor wall, leading to frequent process shut downs for reactor clean up, loss of production; and thus, significant economic losses. Since 2006, I have set up two fluidization laboratories at the University of Ottawa, Chemical and Biological Engineering Department that consist of two pilot plant, one atmospheric and high-pressure, fluidization systems, and have established an extensive experimental program to gain a better understanding of the reactor wall fouling in gas-solid fluidized beds with specific application in polyethylene production. My research team has been successful in developing a new and unique online electrostatic charge measurement technique that has been implemented in both fluidization systems.

气-固流化床反应器中的一个主要问题是颗粒团聚和反应器壁结垢，已知这是由于固体颗粒在这种系统中的剧烈混合而产生静电荷的结果。据报道，这种现象在聚合物、石油和天然气等行业产生了重大影响。在聚乙烯气-固流化床反应器中，由于高度带电的颗粒引起的静电粘附导致在反应器壁上形成不期望的聚合物片，导致用于反应器清理的频繁工艺唐斯、生产损失;以及因此显著的经济损失。自2006年以来，我在渥太华大学化学与生物工程系建立了两个流化实验室，包括两个中试装置，一个常压和高压流化系统，并建立了广泛的实验计划，以更好地了解气固流化床反应器壁结垢，并在聚乙烯生产中具体应用。我的研究团队已经成功地开发了一种新的和独特的在线静电荷测量技术，已在两个流化系统中实施。