微填充床反應器中苯乙烯臭氧分解連續合成苯甲醛

為了研究系統壓力的影響，使用的是一臺臭氧發生器(Atlas P30)可以產生高達0.5 MPa的高壓。

摘要：

由于微反應器固有的安全性和較高的傳質/傳熱效率，近年來連續微反應技術在危險化學中得到了廣泛的應用。在這項工作中，以苯甲醛的合成為模型反應，開發了一種基于微型填充床反應器 (µPBR) 的連續臭氧分解系統。研究了操作變量（如攪拌時間、臭氧/烯烴摩爾比、反應壓力、反應溫度和液體停留時間）對烯烴轉化率和產物分布的影響。根據實驗結果，很佳反應條件為：攪拌時間1 h，臭氧與烯烴的摩爾比1.2，反應壓力0.1 MPa，反應溫度為-15～10℃，而不是低溫。 (< -50℃）通常用于批量操作。此外，在 3.8-30.8 s 的液體停留時間下，觀察到苯乙烯完全轉化，苯甲醛收率約為 93%。因此，與傳統方法相比，基于 µPBR 的流動臭氧分解技術能夠以可持續、安全和有效的方式將烯烴氧化為醛/酮。

原文

Continuous synthesis of benzaldehyde by ozonolysis of styrene in a micro-packed bed reactor

Journal of Flow Chemistry ( IF 2.7 ) Pub Date : 2022-05-18 , DOI: 10.1007/s41981-022-00220-6

Fengyan Lou, Qiang Cao, Chenghao Zhang, Ning Ai, Qining Wang, Jisong Zhang

 

Due to the inherent safety and high mass/heat transfer efficiency of microreactor, the continuous micro-reaction technology has been widely applied in hazardous chemistry recently. In this work, a continuous ozonolysis system based on micro-packed bed reactors (µPBRs) was developed with the synthesis of benzaldehyde as a model reaction. The effects of operating variables (e.g., stirring time, molar ozone/olefin ratio, reaction pressure, reaction temperature and liquid residence time) on the olefins conversion and product distribution were investigated. Based on the experimental results, the optimum reaction conditions are as follows: stirring time 1 h, molar ratio of ozone to olefin 1.2, reaction pressure 0.1 MPa, and the reaction temperature ranging from − 15 to 10℃, as opposed to the low temperature (<-50℃) routinely employed for batch operation. In addition, the full conversion of styrene and a benzaldehyde yield of ~ 93% was observed with the liquid residence time of 3.8–30.8 s. Consequently, the flow ozonolysis technique upon µPBRs allows for a sustainable, safe and efficient approach to oxidize olefins to aldehydes/ketones compared to traditional methods.