Photoelectric Sensor for Fast and Low-Priced Determination of Bi- and Triphasic Segmented Slug Flow Parameters

Vietinghoff, Niclas von; Lungrin, Waldemar; Schulzke, Raphael; Tilly, Jonas; Agar, David W.

doi:10.3390/s20236948

Cited by 10 publications

(6 citation statements)

References 28 publications

(36 reference statements)

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“…Arsenjuk et al and Vietinghoff et al developed systems where the slug length at the reactor inlet is measured by an optical sensor shown in Fig. 7 consisting of a double infrared gate, where the passage of aqueous slugs through the infrared beam results in a reduction in measured beam intensity [29,30]. The slug flow is formed in the slug generator shown in Fig.…”

Section: Flow Experiments and Resultsmentioning

confidence: 99%

“…Data is gathered from the sensors using an analogue data acquisition device (National Instruments NI-9205) and Gemoets, Su et al state that the overall performance of an oxidation reaction is mainly determined by intrinsic kinetics and transport properties inside the reactor. They also make a case that for a fast liquid-phase oxidation reaction, the reaction rate and selectivity are influenced by the mass transfer rate and internal circulations within the slugs along with reaction kinetics [30]. The individual effects of the setpoints, i.e., volumetric flow rate, phase ratio, and the length of the slugs, on the solvent-free Aliquat® 336 assisted oxidation of MO are discussed in the following sections.…”

Section: Flow Experiments and Resultsmentioning

confidence: 99%

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Slug flow as tool for selectivity control in the homogeneously catalysed solvent-free epoxidation of methyl oleate

et al. 2021

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Catalytic oxidation of sustainable raw materials like unsaturated fats and oils, or fatty acids and their esters, lead to biobased, high-value products. Starting from technical grade methyl oleate, hydrogen peroxide as a green oxidant produces only water as by-product. A commercially available, cheap water-soluble tungsten catalyst is combined with Aliquat® 336 as a phase-transfer agent in solvent-free reaction conditions. In this study, we first report the transfer of this well-known batch system into continuous mode. The space–time yield is improved from 0.08 kg/L.h in batch to 1.29 kg/L.h in flow mode. The improved mass transfer and reduced back mixing of the biphasic liquid–liquid slug flow allows for selectivity control depending on physical parameters of slug flow namely volumetric phase ratio, volumetric flow rate, and slug length. Even though the product, methyl 9,10-epoxystearate is obtained at a maximum selectivity of only 58% in flow mode, higher space time yield combined with possible reactant recycling in flow mode offers a promising avenue of research. This work analyses the use of slug flow parameters as tools for controlling selectivity towards oxidation products of methyl oleate.

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Section: Flow Experiments and Resultsmentioning

confidence: 99%

Section: Flow Experiments and Resultsmentioning

confidence: 99%

Slug flow as tool for selectivity control in the homogeneously catalysed solvent-free epoxidation of methyl oleate

et al. 2021

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“…Prior research shows that for even fluid distribution in all parallel channels of a multi-capillary liquid-liquid contactor, some additional considerations must be made (Kashid et al 2010): Although all parallel capillaries are nominally identical, manufacturing tolerances, corrosion, solid precipitation, or deposition are non-negligible for the fluid distribution across parallel capillaries at the micro scale. Therefore, to achieve uniform results across all units, vs, φ and Ls must be measured and regulated in each capillary (Arsenjuk et al 2020b;Vietinghoff et al 2020). For this purpose, Arsenjuk et al (2020b) developed a concept for the active regulation of multichannel liquid-liquid contactors with the ability to control all slug flow parameters across several parallel capillaries.…”

Section: Wetting Phasementioning

confidence: 99%

“…Wolffenbuttel et al (2002) provides a summary of the four most common sensing techniques employed in liquid-liquid slug flow monitoring, including impedance-, absorbance-and reflectance sensors, as well as video imaging, which is concluded to be slow and elaborate. In addition, Arsenjuk et al (2020b) andVietinghoff et al (2020) describe the use of infrared (IR) optical sensors. While the IR-based sensor may be realized in a non-intrusive and cost-effective way, at least one sensor per parallel capillary is required and the sensor is prone to irregularities in the slug flow pattern as well as requiring precise positioning.…”

Section: Wetting Phasementioning

confidence: 99%

A computer vision sensor for the parallelization of actively regulated capillary slug flow microreactors

Gladius,

Mylenbusch,

Agar

2023

Preprint

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In this work, a computer vision sensor for the extraction of slug length, slug velocity and phase ratio from capillary liquid-liquid slug flows from video feeds in real-time, including the necessary post-processing algorithms, is developed. The developed sensor is shown to be capable of simultaneously monitoring multiple capillaries and provides reasonable accuracy at less than 3.5% mean relative error. Subsequently, the sensor is used for the control of a parallelized and actively regulated dual-channel slug flow capillary microreactor setup. As a model reaction, the solvent-free epoxidation of methyl oleate with hydrogen peroxide and a phase-transfer catalyst based on tungstophosphoric acid and a quaternary ammonium salt to yield the product 9,10-epoxystearic acid methyl ester is conducted. A space-time yield of 0.679 kg L-1 h-1 is achieved.

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“…Taking advantage of the optical features of interfaces and how they affect intensity measures, an optical sensor can more reliably discover the interface location under different conditions. In Vietinghoff et al [27], for example, optical properties of interfaces in capillary tubes are used to detect different phases in the flow of a micro reactor.…”

Section: Related Workmentioning

confidence: 99%

Near Infrared Sensor Setup for General Interface Detection in Automatic Liquid-Liquid Extraction Processes

2022

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This work presents a novel sensor setup for the general detection of liquid-liquid interfaces in different mixes of liquids as part of a liquid-liquid extraction device. The sensor setup is applied to a laboratory scale separatory funnel. It uses a near infrared sensor array which receives light going through the liquids inside the funnel, which are illuminated by a light source located on the other side and below the funnel. Light refracts inside the funnel and the liquids and reflects on the interface creating changing patterns in the light intensity measured by the sensor, providing a way of locating the liquid-liquid interface. Liquid mixes with different optical features, from transparent to opaque, emulsion and clean, are used to test whether different types of interfaces produce a distinguishable response on the sensor, allowing to detect interfaces in different situations that can occur as part of an Artificial Intelligence orchestrated battery chemical synthesis process. Emulsion interfaces create a discernible change in the sensor input by lowering the light intensity registered when crossing in front of the sensor making them easier to locate than with other optical techniques. The setup opens the possibility of detecting a liquid-liquid interface as it is forming and can be miniaturized to be attached to laboratory funnels as a manual aid or used with other transparent vessels in automatic solutions like liquid handling robots or pipetting robots.

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Photoelectric Sensor for Fast and Low-Priced Determination of Bi- and Triphasic Segmented Slug Flow Parameters

Cited by 10 publications

References 28 publications

Slug flow as tool for selectivity control in the homogeneously catalysed solvent-free epoxidation of methyl oleate

Slug flow as tool for selectivity control in the homogeneously catalysed solvent-free epoxidation of methyl oleate

A computer vision sensor for the parallelization of actively regulated capillary slug flow microreactors

Near Infrared Sensor Setup for General Interface Detection in Automatic Liquid-Liquid Extraction Processes

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