Your search keyword '"Roberto Saponelli"' showing total 5 results

1. Combined numerical approach for the evaluation of the energy efficiency and economic investment of building external insulation technologies

Author

Matteo Venturelli, Roberto Saponelli, Massimo Milani, and Luca Montorsi

Published

2023

2. Numerical analysis of an entire ceramic kiln under actual operating conditions for the energy efficiency improvement

Author

Maurizio Lizzano, Roberto Saponelli, Massimo Milani, Luca Montorsi, and Matteo Stefani

Subjects

Engineering, Ceramics, Environmental Engineering, Hot Temperature, Kiln, 020209 energy, Mechanical engineering, Thermal power station, 02 engineering and technology, 010501 environmental sciences, Management, Monitoring, Policy and Law, 01 natural sciences, Energy efficiency, Heat transfer, Numerical modeling, Transient analysis, Tunnel kiln, Waste Management and Disposal, Natural gas, heat transfer, 0202 electrical engineering, electronic engineering, information engineering, Ceramic, Process engineering, Lumped and distributed parameter model, heat transfer, energy efficiency, emissions, energy efficiency, 0105 earth and related environmental sciences, business.industry, Temperature, emissions, General Medicine, Carbon Dioxide, visual_art, Fuel efficiency, visual_art.visual_art_medium, Combustor, business, Lumped and distributed parameter model, Efficient energy use

Abstract

The paper focuses on the analysis of an industrial ceramic kiln in order to improve the energy efficiency and thus the fuel consumption and the corresponding carbon dioxide emissions. A lumped and distributed parameter model of the entire system is constructed to simulate the performance of the kiln under actual operating conditions. The model is able to predict accurately the temperature distribution along the different modules of the kiln and the operation of the many natural gas burners employed to provide the required thermal power. Furthermore, the temperature of the tiles is also simulated so that the quality of the final product can be addressed by the modelling. Numerical results are validated against experimental measurements carried out on a real ceramic kiln during regular production operations. The developed numerical model demonstrates to be an efficient tool for the investigation of different design solutions for the kiln's components. In addition, a number of control strategies for the system working conditions can be simulated and compared in order to define the best trade off in terms of fuel consumption and product quality. In particular, the paper analyzes the effect of a new burner type characterized by internal heat recovery capability aimed at improving the energy efficiency of the ceramic kiln. The fuel saving and the relating reduction of carbon dioxide emissions resulted in the order of 10% when compared to the standard burner.

Published

2017

3. A novel Carbon Capture and Utilisation concept applied to the ceramic industry

Author

Matteo Venturelli, Roberto Saponelli, Stefano Stendardo, Massimo Milani, Luca Montorsi, Vincenzo Barbarossa, Bianca Rimini, Sayegh, M.A., Saponelli, R., Milani, M., Montorsi, L., Rimini, B., Venturelli, M., Stendardo, S., and Barbarossa, V.

Subjects

lcsh:GE1-350, Hydrogen, Kiln, business.industry, 020209 energy, chemistry.chemical_element, 02 engineering and technology, Energy consumption, Raw material, 021001 nanoscience & nanotechnology, Methane, chemistry.chemical_compound, chemistry, Natural gas, visual_art, 0202 electrical engineering, electronic engineering, information engineering, visual_art.visual_art_medium, Environmental science, Ceramic, 0210 nano-technology, business, Process engineering, Carbon, lcsh:Environmental sciences

Abstract

This paper investigates a new concept for the CO2 emission mitigation in the ceramic industry based on carbon reduction and methane formation. The concept is analysed as a retrofit to the natural gas fuelled ceramic kiln that represents the main responsible of this industry in terms of energy consumption and exhaust emissions. The carbon dioxide conversion to methane is obtained by reduction with hydrogen on a Ni catalyst and thus methane is used to fuel the standard burners that equip the kiln. The paper addresses different sources for the hydrogen used as a feedstock for the proposed concept as well as alternative catalysts are explored and compared in terms of reduction efficiency and costs. A lumped and distributed parameter simulation of the entire ceramic kiln is combined to the CFD simulation of the reactor to estimate the efficiency of the CO2 reduction and the corresponding methane production for a reference ceramic kiln. The results of the numerical simulations are then employed to discuss the potential benefits of the proposed concept in terms of carbon dioxide emission reduction for the ceramic production. An economic assessment of the system analysed is also carried out concept to determine the investment necessary to implement the technology in an existing ceramic kiln. The potential replicability for other industrial sector is also addressed.

Published

2019

4. Ceramic sanitary wares: Prediction of the deformed shape after the production process

Author

S. de Miranda, Francesco Ubertini, M. Ricci, Roberto Saponelli, Luca Patruno, De Miranda, S, Patruno, L., Ricci, M., Saponelli, R., and Ubertini, F.

Subjects

Engineering, Mould prediction, Process (engineering), Mechanical engineering, High temperatures creep, Sanitary ware, Industrial and Manufacturing Engineering, Sintering, Digital manufacturing, Production (economics), Ceramic, Process engineering, Volumetric shrinkage, business.industry, Final product, Metals and Alloys, Trial and error, Ceramic material, Computer Science Applications, Modeling and Simulation, visual_art, New product development, Ceramics and Composites, visual_art.visual_art_medium, business

Abstract

Ceramic materials are nowadays widely used in many industrial applications, ranging from the production of sanitary wares to advanced mechanics. Despite their diffusion, their production process still involves inefficient product development procedures, often based on a trial and error approach. In particular, during drying and firing, the initial shape given by the mould undergoes significant deformations due to plastic strains and volumetric shrinkage. As a consequence, the prediction of the mould shape, needed to obtain a given final product, becomes a problem of primary importance. The first step towards the definition of an effective mould prediction procedure is to accurately simulate the whole industrial process. The aim of the present paper is to build an effective, yet simple, simulation procedure suitable for implementation in the industrial practice. In this article, the adopted modelling strategy is discussed and the results of the numerical model are compared with experimental data highlighting the effectiveness of the proposed approach. The arguments discussed in the paper have been addressed in collaboration with SACMI, a world leading company in the production of machineries for the ceramic industry.

Published

2015

5. Cfd analyses of syngas-fired industrial tiles kiln module

Author

Marco Cavazzuti, Gianluca Masina, Mauro Alessandro Corticelli, and Roberto Saponelli

Subjects

Work (thermodynamics), Engineering, General Computer Science, Kiln, business.industry, Nozzle, Mechanical engineering, Ambientale, Computational fluid dynamics, syngas, Methane, chemistry.chemical_compound, industrial kiln, Economica, chemistry, Modeling and Simulation, Combustor, Heat of combustion, CFD analysis, business, Syngas

Abstract

Industrial kilns for ceramic tiles production demand thorough control of the firing parameters to ensure uniform product quality. A given temperature profile must be imposed along the kiln length, while spanwise temperature profile should be as uniform as possible at the tiles level at any location. Due to special needs in emerging markets, interest is growing towards the use of gases produced by gasification processes as an alternative to methane. This requires specific burner design and proper re-calibration of the firing parameters. In the present work, computational fluid dynamics is used to analyse an industrial kiln section for different fuels, nominal burner powers, and burner nozzle diameters. The results are given in terms of temperature and velocity fields in the kiln room, and temperature distributions over the tiles floor. It is shown that a sensible combination of the three parameters investigated can lead to satisfactory results, even with gases having poor heating value.