Your search keyword '"Arianna Parisi"' showing total 6 results

1. Analysis of Carbon Nanoparticle Coatings via Wettability

Author

Raffaella Griffo, Francesco Di Natale, Mario Minale, Mariano Sirignano, Arianna Parisi, and Claudia Carotenuto

Subjects

carbon nanoparticles, soot, thin film, wettability, superhydrophobic materials, contact angle, Chemistry, QD1-999

Abstract

Wettability, typically estimated through the contact angle, is a fundamental property of surfaces with wide-ranging implications in both daily life and industrial processes. Recent scientific interest has been paid to the surfaces exhibiting extreme wettability: superhydrophobic and superhydrophilic surfaces, characterized by high water repellency and exceptional water wetting, respectively. Both chemical composition and morphology play a role in the determination of the wettability “performance” of a surface. To tune surface-wetting properties, we considered coatings of carbon nanoparticles (CNPs) in this study. They are a new class of nanomaterials synthesized in flames whose chemistry, dimension, and shape depend on combustion conditions. For the first time, we systematically studied the wettability of CNP coatings produced in a controlled rich ethylene/air flame stabilized over a McKenna burner. A selected substrate was intermittently inserted in the flame at 15 mm above the burner to form a thin coating thanks to a thermophoretic-driven deposition mechanism. The chemical-physical quality and the deposed quantity of the CNPs were varied by opportunely combing the substrate flame insertion number (from 1 to 256) and the carbon-to-oxygen ratio, C/O (from 0.67 to 0.87). The wettability of the coatings was evaluated by measuring the contact angle, CA, with the sessile drop method. When the C/O = 0.67, the CNPs were nearly spherical, smaller than 8 nm, and always generated hydrophilic coatings (CA < 35°). At higher C/O ratios, the CNPs reached dimensions of 100 nm, and fractal shape aggregates were formed. In this case, either hydrophilic (CA < 76°) or superhydrophobic (CA ~166°) behavior was observed, depending on the number of carbon nanoparticles deposed, i.e., film thickness. It is known that wettability is susceptible to liquid surface tension, and therefore, tests were conducted with different fluids to establish a correlation between the flame conditions and the nanostructure of the film. This method offers a fast and simple approach to determining mesoscale information for coating roughness and topographical homogeneity/inhomogeneity of their surfaces.

Published

2024

2. Application of Electrohydrodynamic Atomisation to Surface Disinfection

Author

Arianna Parisi, Domenico Flagiello, Amodio Piscitelli, and Francesco Di Natale

Subjects

Chemical engineering, TP155-156, Computer engineering. Computer hardware, TK7885-7895

Abstract

The development of improved methods for surface disinfection has gained renewed interest during the first waves of the SARS-COV2 Pandemic when the need to assure massive disinfection of objects and spaces goes against that of reducing the consumption of chemicals and minimize the impact of disinfectants on exposed persons. Electrohydrodynamic atomization is considered a valuable option to improve disinfection efficiency, thanks to the benefits associated with the droplets charge. This paper presents preliminary experimental and model results on the application of an induction charging electrohydrodynamic atomisation process to the spraying of water solution of a conventional disinfectant under model conditions. In particular, electrospraying under simple jet mode with a whipping breakup has been tested. Experiments are aimed to characterize the droplet size distribution, the energy requirements and the spray coverage area over a target surface, while a simplified physical mathematical model is used to estimate the amount of disinfectant lost upon evaporation and the distribution of the droplets over the target surface. The electrospray is able to disperse droplets having a charge-to-mass ratio of around 1.67 mC/kg with an energy consumption of 23.4±7.8 J/L, being more efficient than other conventional hydraulic nozzles. These preliminary findings indicate a good matching between modelled and experimental data and suggest that electrospraying under simple jet mode with a whipping breakup can be a possible option for the spraying of disinfectants over surfaces.

Published

2023

3. A Review on Gas-Liquid Mass Transfer Coefficients in Packed-Bed Columns

Author

Domenico Flagiello, Arianna Parisi, Amedeo Lancia, and Francesco Di Natale

Subjects

separation technologies, unit operations, gas-liquid mass transfer, mass transfer review, mass transfer coefficients for packed columns, structured packing, Chemistry, QD1-999

Abstract

This review provides a thorough analysis of the most famous mass transfer models for random and structured packed-bed columns used in absorption/stripping and distillation processes, providing a detailed description of the equations to calculate the mass transfer parameters, i.e., gas-side coefficient per unit surface ky [kmol·m−2·s−1], liquid-side coefficient per unit surface kx [kmol·m−2·s−1], interfacial packing area ae [m2·m−3], which constitute the ingredients to assess the mass transfer rate of packed-bed columns. The models have been reported in the original form provided by the authors together with the geometric and model fitting parameters published in several papers to allow their adaptation to packings different from those covered in the original papers. Although the work is focused on a collection of carefully described and ready-to-use equations, we have tried to underline the criticalities behind these models, which mostly rely on the assessment of fluid-dynamics parameters such as liquid film thickness, liquid hold-up and interfacial area, or the real liquid paths or any mal-distributions flow. To this end, the paper reviewed novel experimental and simulation approaches aimed to better describe the gas-liquid multiphase flow dynamics in packed-bed column, e.g., by using optical technologies (tomography) or CFD simulations. While the results of these studies may not be easily extended to full-scale columns, the improved estimation of the main fluid-dynamic parameters will provide a more accurate modelling correlation of liquid-gas mass transfer phenomena in packed columns.

Published

2021

4. A tool for mass transfer evaluation in packed-bed columns for chemical engineering students

Author

Arianna Parisi, F. Di Natale, Domenico Flagiello, Amedeo Lancia, Flagiello, D., Parisi, A., Lancia, A., and Natale, Di

Subjects

Packed bed, business.industry, Computer science, Process (engineering), General Chemical Engineering, Experimental data, Solver, Unit operation, Education, law.invention, Software, Chemical engineering, law, Mass transfer, business, Distillation

Abstract

This paper presents a Microsoft Excel tool to calculate liquid-gas mass transfer coefficients in packed towers to support numerical design activities in the courses of Unit Operations for Industrial Process and Sustainable Process Design for the Master’s degree in Chemical Engineering of the University of Naples Federico II (Italy). The Mass Transfer Solver Tool (MT Solver Tool) uses several available models to estimate, separately, the values of liquid and gas mass-transfer coefficients and the wet surface area for 144 random and structured packings of interest for absorption/stripping and distillation processes. In addition, a separate spreadsheet can be used in a user-defined mode, to evaluate the mass transfer coefficients with new packing types or to interpret experimental data when the geometrical and physical characteristics of the packing are known. Eventually, the tool is supplied with a data library, where packing geometry and model fitting parameters can be retrieved. The software is aimed to support students and educators in the Unit Operations for Industrial Process and Sustainable Process Design courses. In particular, this is meant to be an example on how the accuracy of design algorithms adopted in unit operation processes is affected by the use of the underpinning correlations for mass transfer rate or pressure drops. Besides, this is aimed to encourage comparison of different correlations when exact field data are not available. Besides, chemical engineers and researchers interested in packed columns design and modelling data may also benefit from the utilization of the software. The MT Solver Tool was introduced to students in a dedicated tutorial lesson after lecturers on packed column design algorithms for distillation, absorption and stripping. Most of the students of the course participated to a group training aimed to simulate the design of an absorption column supported by the MT Solver Tool providing feedback on its application. After the training, an anonymous survey was proposed to the students to monitor the approval rating of the proposed activity and the use of the MT Solver Tool software to support numerical calculations.

Published

2021

5. Absorption of sulphur dioxide by electrosprayed droplets

Author

Claudia Carotenuto, Arianna Parisi, Francesco Di Natale, Amedeo Lancia, Di Natale, Francesco, Carotenuto, Claudia, Parisi, Arianna, Lancia, Amedeo, Di Natale, F., Carotenuto, C., Parisi, A., and Lancia, A.

Subjects

Electrospray, Materials science, chemistry, General Chemical Engineering, Analytical chemistry, corona charging, chemistry.chemical_element, wet electrostatic scrubber, electrospray, Absorption (electromagnetic radiation), absorption, desulphurization, Sulfur

Abstract

The absorption of SO2 in electrified water sprays, either when the polluted gas is treated as is or when the gas is exposed to a corona source to ionize the SO2 was evaluated. An electrified spray with a charge-to-mass ratio of 50 ΜC/kg enabled the absorption rate of droplets to double, regardless of their polarities. Corona charging gave rise to an increase in the SO2 depletion rate over the scrubber wall, while negligible effects appeared on the actual droplets absorption rate. These findings suggested that faster absorption rates mostly, though not uniquely, depend on the modifications on the morphological and interfacial properties of the sprayed droplets induced by the free electric charge imposed on their surface. Conversely, the absorption rates were negligibly affected by the electrical interactions between droplets (either charged or uncharged) and the SO2 ions/radicals originating from the corona source.

Published

2020

6. Seawater desulphurization scrubbing in spray and packed columns for a 4.35 MW marine diesel engine

Author

Alessandro Erto, Domenico Flagiello, Amedeo Lancia, Arianna Parisi, Claudia Carotenuto, F. Di Natale, Flagiello, D., Parisi, A., Lancia, A., Carotenuto, C., Erto, A., and Di Natale, F.

Subjects

Spray tower, 020209 energy, General Chemical Engineering, Seawater scrubbing, Process design, 02 engineering and technology, 010501 environmental sciences, Diesel engine, Combustion, 01 natural sciences, 0202 electrical engineering, electronic engineering, information engineering, Process engineering, 0105 earth and related environmental sciences, business.industry, Fossil fuel, General Chemistry, Structured packing, Flue-gas desulfurization, FGD unit economic analysi, Mellapak™ 250.X, Environmental science, Packed-bed column, Seawater, business, Data scrubbing, Marine flue-gas desulfurization (FGD)

Abstract

Flue Gas Desulphurization (FGD) is a key topic for all combustion fossil fuel plants and industrial applications. Wet processes are usually preferred when the removal efficiency required to comply with environmental regulation exceeds 90%. Recently, seawater (SW) has been considered as a viable absorbent for FGD processes in coastal and naval applications, thanks to its natural alkalinity and, of course, its large availability. Due to the typical constraints of naval applications, process design should be optimized to improve mass transfer rates and reduce seawater requirements while keeping a suitable absorber size. In this work, we report the experimental findings on process design and optimization of two different SW-FGD units: a spray column equipped with full hydraulic spray nozzles and a packed-bed column with structured packing. The experiments are used to develop and tune suitable models for the packed and spray towers design in representative operating conditions. These models are applied to compare both the units in a reference case study: an IFO fuelled marine diesel engine (4.35 MW) that has to comply with current IMO-MARPOL VI 14 regulation for SECAs. A preliminary costs analysis is also performed for comparison.

Published

2019