Development and simulation of annular flow photoreactors: integration of light-diffusing fibers as optical diffusers with laser diodes†

IF 3.4 3区 化学 Q2 CHEMISTRY, MULTIDISCIPLINARY
Sergio Carrillo De Hert, Rafael Lopez-Rodriguez, Michael J. Di Maso, Jonathan P. McMullen and Steven Ferguson
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引用次数: 0

Abstract

Continuous flow chemical photoreactors have emerged as a highly attractive platform, garnering considerable attention in both industry and academia. Utilizing thin channels, these reactors offer a promising solution for achieving more uniform irradiation in the reactor volume. While advancements have been enabled by the implementation of LEDs, significant limitations persist. These include managing the heat generated by light emitting diodes (LEDs), requiring proximity of electrical equipment and hot surfaces to flammable environments, ensuring operator safety amidst high levels of irradiating light, and addressing efficiency issues arising from irradiation of unintended areas, light scattering, and divergent photon emission. Herein, we introduce a novel approach that involves guiding photons emitted by a laser diode via total reflection optic fiber to an optical diffuser inside the reactor, specifically a light-diffusing fiber (LDF). This system capitalizes on the radial photon distribution capability of LDFs to irradiate the tubular annulus, enclosing all irradiation within it. The Continuous Annular Photoreactor (CAP-Flow system) effectively divorces photon generation from potentially explosive environments, enhancing safety, and operational convenience. The CAP-Flow system underwent testing via actinometry and a C–N coupling reaction across various flow rates and catalyst loadings. Our results found superior efficiency for the CAP-Flow system when compared to current LED configurations. The defined geometry, flow-field and photon absorption distribution facilitated mathematical modeling to de-convolute the reaction kinetics governing the photocatalytic process, offering valuable insights for optimizing operational parameters to enhance process understanding, productivity, and selectivity.

Abstract Image

连续流化学光反应器已成为一个极具吸引力的平台,在工业界和学术界都引起了广泛关注。这些反应器利用细通道,为在反应器容积内实现更均匀的辐照提供了一种前景广阔的解决方案。虽然 LED 的应用带来了进步,但仍然存在很大的局限性。这些限制包括管理发光二极管(LED)产生的热量,要求电气设备和热表面靠近易燃环境,确保操作员在高水平照射光下的安全,以及解决因照射非预期区域、光散射和发散光子发射而产生的效率问题。在此,我们介绍一种新方法,即通过全反射光纤将激光二极管发射的光子引导至反应器内的光扩散器,特别是光扩散光纤(LDF)。该系统利用光扩散光纤的径向光子分布能力,对管状环形结构进行辐照,将所有辐照都包围在其中。连续环形光反应器(CAP-Flow 系统)有效地将光子生成与潜在爆炸环境分离开来,提高了安全性和操作便利性。CAP-Flow 系统在不同的流速和催化剂负载条件下,通过光度计和 C-N 偶联反应进行了测试。我们的结果发现,与当前的 LED 配置相比,CAP-Flow 系统具有更高的效率。确定的几何形状、流场和光子吸收分布有助于建立数学模型,从而解构光催化过程的反应动力学,为优化操作参数提供宝贵的见解,以提高对过程的理解、生产率和选择性。
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来源期刊
Reaction Chemistry & Engineering
Reaction Chemistry & Engineering Chemistry-Chemistry (miscellaneous)
CiteScore
6.60
自引率
7.70%
发文量
227
期刊介绍: Reaction Chemistry & Engineering is a new journal reporting cutting edge research into all aspects of making molecules for the benefit of fundamental research, applied processes and wider society. From fundamental, molecular-level chemistry to large scale chemical production, Reaction Chemistry & Engineering brings together communities of chemists and chemical engineers working to ensure the crucial role of reaction chemistry in today’s world.
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