Your search keyword '"Dybiński, Olaf"' showing total 8 results

1. Identification of oxygen ion conductivity of Ba doped Bi0.5Na0.5TiO3 (Ba-BNT) based matrix impregnated by lithium/potassium electrolyte for molten carbonate fuel cells.

Author

Milewski, Jarosław, Dybiński, Olaf, Szczęśniak, Arkadiusz, Martsinchyk, Aliaksandr, Ćwieka, Karol, Xing, Wen, and Szabłowski, Łukasz

Subjects

*MOLTEN carbonate fuel cells, *FLUOROETHYLENE, *IONIC conductivity, *FUEL cells

Abstract

This paper presents the results of research into improving the ionic conductivity of Molten Carbonate Fuel Cell by modifying the matrix material. So far, we have succeeded in using materials such as YSZ and SDC, but we are now trying to use powders based on Ba Na and TiO 2. These materials are characterized by their oxygen ion conductivity at elevated temperatures. A matrix of these materials was produced and used to build MCFCs. Based on the experiments carried out and the mathematical model of the fuel cell, the contribution of the oxygen ion conductivity to the total ionic conductivity was determined. • Research on oxygen ion conduction materials was performed. • BNT material has best oxygen ion conductivity parameters and was chosen for experiments. • New matrix made of BNT was manufactured. • Composite Li/K and BNT membrane was investigated under EIS and in fuel cell. • Model including ionic conductivity and tortuosity is presented and validated. [ABSTRACT FROM AUTHOR]

Published

2024

2. Methanol, ethanol, propanol, butanol and glycerol as hydrogen carriers for direct utilization in molten carbonate fuel cells.

Author

Dybiński, Olaf, Milewski, Jarosław, Szabłowski, Łukasz, Szczęśniak, Arkadiusz, and Martinchyk, Alexander

Subjects

*MOLTEN carbonate fuel cells, *BUTANOL, *METHANOL as fuel, *PROPANOLS, *HYDROGEN as fuel, *ETHANOL, *RENEWABLE energy sources

Abstract

This paper reports the performance of a molten carbonate fuel cell (MCFC) fed directly with liquid fuels referenced against results with hydrogen fuel in experiments conducted by the research team. Alcohols have greater energy density than pure hydrogen in normal conditions and, if presented as biofuels, the MCFC can be deemed a renewable energy source. For evaluation purposes various alcohols occurring in standard conditions in the liquid state were used for electricity generation in the MCFC: methanol, ethanol, propanol, butanol and glycerol. Since these alcohols can be subjected to steam reforming when mixed with water in specific ratios, they can be delivered directly in the liquid state to the fuel cell, where hydrogen is released and used to produce electricity and heat. The alcohols were mixed with water in ratios of 1:2, 1:3, 1:4. The results were compared to the MCFC fed with pure hydrogen as a fuel. In terms of power referenced to hydrogen (100%), the maximums achieved were 78% for butanol, 80% for glycerol, 83% for propanol, 86% for ethanol and 93% for methanol in comparison to the same amount of hydrogen delivered to the fuel cell in ideal steam reforming situation. Threats such as carbon deposition on the fuel cell surface were also evaluated. • MCFC fed directly with various mixtures of alcohols and water have been studied. • The steam reforming of mixtures of alcohols and water generates energy. • Temperature and anode material provide the necessary conditions for steam reforming. • Maximum power compared to hydrogen fuel for various fuels ranges between 78 and 93%. • Carbon deposition in the anode channel of commercial units can be a problem. [ABSTRACT FROM AUTHOR]

Published

2023

3. Artificial neural network model of molten carbonate fuel cells: Validation on experimental data.

Author

Milewski, Jarosław, Szczȩśniak, Arkadiusz, Szabłowski, Łukasz, Dybiński, Olaf, and Miller, Andrzej

Subjects

MOLTEN carbonate fuel cells, ARTIFICIAL neural networks, FUEL cells

Abstract

Summary: This article shows the teaching processes of artificial neural networks that are used to model the molten carbonate fuel cell (MCFC). Researchers model MCFCs to address a variety of issues across a range of complexities, from simply gauging the effect of temperature through to a complete model with 14 input parameters. The architecture of the model is a triple layer network with one hidden layer containing three neurons. The activation function used for the hidden layer was a hyperbolic tangent, with the last layer being based on linear function. We produced various network configurations, mostly networks containing one hidden layer. Models map the work of a real fuel cell with an average error in the range of 2.4% to 4.6%. The model we created guided the optimization of the thermal‐flow and construction parameters of the MCFC. Commercially available software was used to build the model and optimize the operating parameters. The selected objective functions were the efficiency of electricity production and the power density obtained from the cell's surface. The results obtained serve as pointers for possible changes in fuel cell operation and could lead to some structural changes being made. [ABSTRACT FROM AUTHOR]

Published

2019

4. Comparison of mathematical models of steam methane reforming process for the needs of fuel cells.

Author

Wójcik, Małgorzata, Szabłowski, Łukasz, and Dybiński, Olaf

Subjects

*STEAM reforming, *SOLID oxide fuel cells, *FUEL cells, *MOLTEN carbonate fuel cells, *MATHEMATICAL models, *ELECTROCHEMICAL electrodes

Abstract

The article presents a comparison of mathematical models of steam methane reforming. The analysis is divided into two parts. The first concerns the reforming process using separate steam reformers. The second part of the article compares models of steam methane reforming processes directly inside fuel cells. Due to the fact that the steam reforming process takes place at very high temperatures, internal steam reforming can only be carried out in high temperature fuel cells. Therefore, the second part of the article deals with molten carbonate fuel cells and solid oxide fuel cells powered by methane. In the case of both of fuel cells, the methane steam reforming may take place directly on the anodes of these electrochemical devices. The mathematical models (for both external and internal reforming) were compared based on available experimental data. In this analysis of mathematical models, particular attention was paid to the causes of discrepancies between the mathematical models and the experimental data. The steam reforming process is influenced by a number of different parameters such as: temperature, ratio of the amount of water vapor to carbon contained in the fuel (steam to carbon ratio), reaction time, presence of a catalyst, type of catalyst and many others. The models presented in this article were also compared in terms of taking into account various parameters that may affect the process of steam reforming. An attempt was also made to assess the accuracy of mathematical models. Unfortunately, for most of the equations considered in this article, numerical values for inaccuracies are not given or described as acceptable or minor. • Review of mathematical models of SMR. • The kinetics models of the steam methane reforming reaction. • Description of mathematical models for the molten carbonate fuel cell (MCFC). [ABSTRACT FROM AUTHOR]

Published

2024

5. Experimental investigation of novel molten borate fuel cell supported by an artificial neural network for electrolyte composition selection.

Author

Martsinchyk, Aliaksandr, Milewski, Jaroslaw, Dybiński, Olaf, Szczęśniak, Arkadiusz, Siekierski, Maciej, and Świrski, Konrad

Subjects

*MOLTEN carbonate fuel cells, *FUEL cells, *FUEL cell electrolytes, *DEEP learning, *ARTIFICIAL cells, *FEEDFORWARD neural networks, *MACHINE learning

Abstract

This research proposes idea of new kind of high temperature fuel cell – Molten Borate Fuel Cell (MBFC). The idea of new fuel cell is based on technical modification of well-known Molten Carbonate Fuel Cell by changing electrolyte composition to a borate-based mixture. The cell was tested in laboratory conditions as proof-of-concept investigation and reached OCV at around 1 V and 0.05 A/cm2 of current density. The optimization of borate-based electrolyte composition was conducted with a help of ANN and experimentally verified. The deep feedforward artificial neural network (DFF ANN) was proposed in this study to model the behavior of the new Molten Borate Fuel Cell. This modeling approach is well-known as a potent tool for dealing with complicated modeling and prediction tasks. This study presented many network designs for a range of operating circumstances. The ANN has been used to model and optimize the SOFC, MCFC, and PEMFC, but the design and performance of the MBFC were not previously investigated. The innovative type of fuel cells at issue - Molten Borate Fuel Cells - were designed and optimized using a deep learning algorithm. The most advanced model provides a dynamic forecast of fuel cell operation, taking thermal-flow and electrolyte material factors into account. With an average inaccuracy of 0.3%, all the models performed fair enough. An ANN-based technique may also be used to improve cell operating parameters. Moreover, the operating composition of a novel molten borate electrolyte might be improved in terms of electrochemical performance of the fuel cell. • New type of fuel cells is proposed. • Various electrolyte compositions are proposed. • The selected electrolyte composition were tested experimentally. • The Artificial Neural Network is built for tailoring the electrolyte compositions. • New composition is proposed by the ANN. [ABSTRACT FROM AUTHOR]

Published

2023

6. Recycling electronic scrap to make molten carbonate fuel cell cathodes.

Author

Milewski, Jarosław, Cwieka, Karol, Szczęśniak, Arkadiusz, Szabłowski, Łukasz, Wejrzanowski, Tomasz, Skibinski, Jakub, Dybiński, Olaf, Lysik, Aleksandra, Sienko, Arkadiusz, and Stanger, Pawel

Subjects

*MOLTEN carbonate fuel cells, *RARE earth metals, *CATHODES, *ELECTRONIC equipment, *PRECIOUS metals

Abstract

The paper aims to examine the possibility of improving the manufacturing process for MCFC cathodes. using noble, semi-precious, and rare earth metals sourced from waste electric and electronic equipment (WEEE). As MCFC components are not particularly sensitive to ceramic and metal impurities. The addition of noble metals recovered from WEEE as catalysts are economically justifiable. The reported experimental research revealed the positive impact of MCFC cathode fabricated with 20% recycled electronic scrap. Especially the cell with powder marked as 4/1 enjoyed much better performance operating at 550 °C than the reference cell. During the operation at a temperature of 650 °C, the cell with powder marked as 4/1 has almost the same performance as the reference cell, i.e., 1.01 V OCV and power density of 0.13 A/cm2. The cell with cathode with 4/2 powder has the worst performance – current density of 0.09 A/cm2 and OCV of 0.97 V. [Display omitted] • Rare earth elements separated by positive charge contains less cerium than separated by negative charge. • The maximum current densities and Open Circuit Values are similar as reference case for maximum gas flows. • The maximum current densities and Oper Circuit Voltages are better with additives for lower operational temperature. [ABSTRACT FROM AUTHOR]

Published

2023

7. Exploring new solid electrolyte support matrix materials for molten carbonate fuel cells (MCFCs).

Author

Xing, Wen, Martsinchyk, Aliaksandr, Gaukas, Nikolai, Milewski, Jaroslaw, Shuhayeu, Pavel, Denonville, Christelle, Szczesniak, Arkadiusz, Sieńko, Arkadiusz, and Dybiński, Olaf

Subjects

*MOLTEN carbonate fuel cells, *SOLID electrolytes, *FUEL cells, *ALKALI metal ions, *OXYGEN reduction, *ALKALI metals, *SOLID state proton conductors

Abstract

• BNT (0.94Bi 0.5 Na 0.5 TiO 3 -0.06BaTiO 3) and LNT (La 0.5 Na 0.5 TiO 3) containing alkali element and conducting oxide ion were used for replacing the non-conductive LiAlO 2 matrix in MCFCs (Molten carbonate fuel cells). • Cells fabricated using both new oxides as solid matrix support show state-of-the-art electrochemical performance. • LNT sample has extended life-time and better performance than BNT sample and the good performance may related to enhanced oxygen reduction reaction kinetics. New oxide ion conductors with perovskite structures containing alkali metal were explored for use as solid support materials for MCFCs (molten carbonate fuel cells). The conductivity of two candidates, BNT (0.94Bi 0.5 Na 0.5 TiO 3 -0.06BaTiO 3) and LNT (La 0.5 Na 0.5 TiO 3), in an oxidation atmosphere, were measured and compared. The conductivity measurement of BNT in a reducing atmosphere indicated the reduction of BNT to Bi metal by a sharp change in conductivity. It limited the lifetime of the fuel cell using BNT as solid support. Fuel cell measurements using the alternative perovskite LNT showed excellent stability under fuel cell operation conditions and high-power density compared to conventional MCFC with LiAlO 2 as the solid matrix. The reason for obtaining high electrochemical performance using the LNT matrix is discussed. [ABSTRACT FROM AUTHOR]

Published

2024

8. Dynamic model of a molten carbonate fuel cell 1 kW stack.

Author

Szczęśniak, Arkadiusz, Milewski, Jarosław, Szabłowski, Łukasz, Bujalski, Wojciech, and Dybiński, Olaf

Subjects

*MOLTEN carbonate fuel cells, *DYNAMIC models, *FUEL cells, *ELECTRICAL load

Abstract

Molten Carbonate Fuel Cells (MCFC) offer several advantages that are accelerating the research and development effort. Recent advances include improved materials, new fabrication techniques and new designs, flow configurations and applications. Nevertheless, several factors are holding back large scale implementation of fuel cells, especially in distributed energy generation, a major one being their long response time to changing parameters. Whereas alternative mathematical models of the molten carbonate fuel cell stack have been developed over the last decade, there are no reported analyses of regarding the application of models for emergency scenarios such as fuel cell malfunctions. This paper presents the 0D model of MCFC, calibrated to the appropriate available experimental data. This study investigates a generic molten fuel cell stack with nominal power output of 1 kWel. As daily, weekly and monthly variations in the electrical power load are expected, there is a need to develop numerical tools to predict the unit's performance with high accuracy. Hence, a fully physical dynamic model of an MCFC stack was developed and implemented in Aspen HYSYS 10 modeling software to enable predictive analysis of the dynamic response. The model is used to simulate a number of few malfunctions with 5. 66% broken cells in the stack. Losses of performance are obtained, manifested by rising operating temperature and falling power output. Moreover, a number of emergency operation scenarios were investigated, such as sudden loss of electric load, fuel and oxidiant supply. The presented model exhibits high accuracy and accounts for thermal and electrochemical processes and parameters. The paper presents the methodology used in the study to analyze the sensitivity of key scenarios such as load changes and emergencies. Further functionality of the model, which was validated using real operating data, is discussed. • Dynamic model of a Molten Carbonate Fuel Cell 1 kW stackis proposed. • The model was calibrated to the appropriate available experimental data. • The load changes and emergency situations were examined. [ABSTRACT FROM AUTHOR]

Published

2020