Your search keyword '"Serge Nyallang Nyamsi"' showing total 12 results

1. Insights into a Thermodynamically Optimal Synthesis of the Ternary Complex Hydride Mg2FeH6 for High-Density Thermal Energy Storage

Author

Fusheng Yang, Chenhui Qian, Leilei Guo, Zhen Wu, Lixian Sun, Serge Nyallang Nyamsi, Fen Xu, Zaoxiao Zhang, Hiroshi Uesugi, and Guohua Yan

Subjects

Materials science, Hydride, Energy Engineering and Power Technology, High density, Thermodynamics, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Thermal energy storage, 01 natural sciences, 0104 chemical sciences, Materials Chemistry, Electrochemistry, Chemical Engineering (miscellaneous), Electrical and Electronic Engineering, 0210 nano-technology, Ternary complex

Published

2021

2. 200 NL H2 hydrogen storage tank using MgH2–TiH2–C nanocomposite as H storage material

Author

Moegamat Wafeeq Davids, Serge Nyallang Nyamsi, Sivakumar Pasupathi, Volodymyr A. Yartys, Mykhaylo Lototskyy, and Giovanni Capurso

Subjects

Materials science, Hydrogen, Energy Engineering and Power Technology, chemistry.chemical_element, Cycle stability, 02 engineering and technology, 010402 general chemistry, MgH2–TiH2–graphite composite, Ball milling in hydrogen, Hydrogen storage tank, Thermal management, 01 natural sciences, Hydrogen storage, Aluminium, Dehydrogenation, Inert gas, Renewable Energy, Sustainability and the Environment, Hydride, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 0104 chemical sciences, Fuel Technology, Chemical engineering, chemistry, Storage tank, Solid oxide fuel cell, 0210 nano-technology

Abstract

MgH2-based hydrogen storage materials are promising candidates for solid-state hydrogen storage allowing efficient thermal management in energy systems integrating metal hydride hydrogen store with a solid oxide fuel cell (SOFC) providing dissipated heat at temperatures between 400 and 600 °C. Recently, we have shown that graphite-modified composite of TiH2 and MgH2 prepared by high-energy reactive ball milling in hydrogen (HRBM), demonstrates a high reversible gravimetric H storage capacity exceeding 5 wt % H, fast hydrogenation/dehydrogenation kinetics and excellent cycle stability. In present study, 0.9 MgH2 + 0.1 TiH2 +5 wt %C nanocomposite with a maximum hydrogen storage capacity of 6.3 wt% H was prepared by HRBM preceded by a short homogenizing pre-milling in inert gas. 300 g of the composite was loaded into a storage tank accommodating an air-heated stainless steel metal hydride (MH) container equipped with transversal internal (copper) and external (aluminium) fins. Tests of the tank were carried out in a temperature range from 150 °C (H2 absorption) to 370 °C (H2 desorption) and showed its ability to deliver up to 185 NL H2 corresponding to a reversible H storage capacity of the MH material of appr. 5 wt% H. No significant deterioration of the reversible H storage capacity was observed during 20 heating/cooling H2 discharge/charge cycles. It was found that H2 desorption performance can be tailored by selecting appropriate thermal management conditions and an optimal operational regime has been proposed.

Published

2021

3. Dehydrogenation of Metal Hydride Reactor-Phase Change Materials Coupled with Light-Duty Fuel Cell Vehicles

Author

Serge Nyallang Nyamsi, Ivan Tolj, and Michał Jan Gęca

Subjects

Control and Optimization, metal hydrides, phase change materials, hydrogen supply, range extender, light-duty fuel cell vehicles, Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, Electrical and Electronic Engineering, Engineering (miscellaneous), Energy (miscellaneous)

Abstract

The popularity of using phase change materials (PCMs) for heat storage and recovery of metal hydrides’ reaction has grown tremendously. However, a fundamental study of the coupling of such a system with a low-temperature PEM (polymer electrolyte membrane) fuel cell is still lacking. This work presents a numerical investigation of the dehydrogenation performance of a metal hydride reactor (MHR)-PCM system coupled with a fuel cell. It is shown that to supply the fuel cell with a constant H2 flow rate, the PCM properties need to be in an optimized range. The effects of some design parameters (PCM freezing point, the initial desorption temperature, the nature and the size of the PCM) on the dehydrogenation performance of MHR-PCM system are discussed in detail. The results showed that the MHR-PCM could supply hydrogen at 12 NL/min only for 20 min maximum due to the significant endothermic effect occurring in the MHR. However, reducing the requested H2 flowrate to 5.5 NL/min, the hydrogen desorption to a fuel cell is prolonged to 79 min. Moreover, this system can accommodate different PCMs such as paraffin and salt hydrates for comparable performance. This study demonstrates the ability of MHR-PCM systems to be used as range extenders in light-duty fuel cell vehicles.

Published

2022

4. A concept of combined cooling, heating and power system utilising solar power and based on reversible solid oxide fuel cell and metal hydrides

Author

Sivakumar Pasupathi, Volodymyr A. Yartys, Arild Vik, Serge Nyallang Nyamsi, Crina S. Ilea, Ivar Wærnhus, and Mykhaylo Lototskyy

Subjects

Materials science, Hydrogen, Renewable Energy, Sustainability and the Environment, 020209 energy, Hydrogen compressor, Nuclear engineering, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Thermal energy storage, law.invention, Waste heat recovery unit, Fuel Technology, Electricity generation, chemistry, law, Waste heat, 0202 electrical engineering, electronic engineering, information engineering, Solid oxide fuel cell, 0210 nano-technology, Heat pump

Abstract

In energy systems, multi-generation including co-generation and tri-generation has gained tremendous interest in the recent years as an effective way of waste heat recovery. Solid oxide fuel cells are efficient power plants that not only generate electricity with high energy efficiency but also produce high quality waste heat that can be further used for hot and chilled water production. In this work, we present a concept of combined cooling, heating and power (CCHP) energy system which uses solar power as a primary energy source and utilizes a reversible solid oxide fuel cell (R-SOFC) for producing hydrogen and generating electricity in the electrolyser (SOEC) and fuel cell (SOFC) modes, respectively. The system uses “high temperature” metal hydride (MH) for storage of both hydrogen and heat, as well as “low temperature” MH's for the additional heat management, including hot water supply, residential heating during winter time, or cooling/air conditioning during summer time. The work presents evaluation of energy balances of the system components, as well as heat-and-mass transfer modelling of MH beds in metal hydride hydrogen and heat storage system (MHHS; MgH2), MH hydrogen compressor (MHHC; AB5; A = La + Mm, B Ni + Co + Al + Mn) and MH heat pump (MHHP; AB2; A = Ti + Zr, B Mn + Cr + Ni + Fe). A case study of a 3 kWe R-SOFC is analysed and discussed. The results showed that the energy efficiencies are 69.4 and 72.4% in electrolyser and fuel cell modes, respectively. The round-trip COP's of metal hydride heat management system (MHHC + MHHP) are close to 40% for both heating and cooling outputs. Moreover, the tri-generation leads to an improvement of 36% in round-trip energy efficiency as compared to that of a stand-alone R-SOFC.

Published

2018

5. Multi-physics field modeling of biomass gasification syngas fueled solid oxide fuel cell

Author

Serge Nyallang Nyamsi, Hongli Yan, Jing Yao, Zhen Wu, Sandra Kurko, Fusheng Yang, Zaoxiao Zhang, Leilei Guo, and Pengfei Zhu

Subjects

Renewable Energy, Sustainability and the Environment, 020209 energy, Nuclear engineering, 05 social sciences, Energy Engineering and Power Technology, Biomass, 02 engineering and technology, 7. Clean energy, Water-gas shift reaction, Anode, Reaction rate, Multi-physics modeling, Operating temperature, Solid oxide fuel cell, 13. Climate action, 0502 economics and business, 0202 electrical engineering, electronic engineering, information engineering, Mass transfer, 050207 economics, Electrical and Electronic Engineering, Physical and Theoretical Chemistry, Chemical reaction, Power density, Syngas

Abstract

In order to uncover the inner working mechanism and performance of solid oxide fuel cell (SOFC) with biomass gasification syngas as fuel, a two dimensional SOFC multi-physical field model is established. This study makes up for the deficiency that the previous studies of coupling biomass gasification unit and SOFC stack mostly stay at the system level. The results show that the SOFC fueled by the syngas produced from gasification of biomass with steam as the agent has the best performance. The peak power density could achieve approximately 10240 W m−2. With the improvement of operating temperature, the peak power density of SOFC will be increased. At the temperature of 1123 K, the peak power density could achieve about 15128 W m−2. The average reaction rate of water gas shift (WGS) reaction is −29.73 mol m−3 s−1 when the operating temperature is 1123 K. This indicates that the WGS reaction will proceed in reverse direction at high temperatures, thereby reducing the hydrogen concentration. In addition, increase in the anode flux and decrease in the cell length lead to the increase of SOFC current density. In general, this work could provide guidance for the optimization and practical application of SOFC using biomass syngas as fuel.

Published

2021

6. The Impact of Active and Passive Thermal Management on the Energy Storage Efficiency of Metal Hydride Pairs Based Heat Storage

Author

Ivan Tolj and Serge Nyallang Nyamsi

Subjects

Technology, Control and Optimization, Materials science, energy storage efficiency, Convective heat transfer, 020209 energy, Nuclear engineering, Energy Engineering and Power Technology, 02 engineering and technology, heat storage, metal hydride, active and passive heat management, energy storage density, Thermal energy storage, 7. Clean energy, Energy storage, Thermal conductivity, Heat recovery ventilation, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Engineering (miscellaneous), Renewable Energy, Sustainability and the Environment, Heat transfer enhancement, 021001 nanoscience & nanotechnology, Phase-change material, 13. Climate action, Heat transfer, 0210 nano-technology, Energy (miscellaneous)

Abstract

Two-tank metal hydride pairs have gained tremendous interest in thermal energy storage systems for concentrating solar power plants or industrial waste heat recovery. Generally, the system’s performance depends on selecting and matching the metal hydride pairs and the thermal management adopted. In this study, the 2D mathematical modeling used to investigate the heat storage system’s performance under different thermal management techniques, including active and passive heat transfer techniques, is analyzed and discussed in detail. The change in the energy storage density, the specific power output, and the energy storage efficiency is studied under different heat transfer measures applied to the two tanks. The results showed that there is a trade-off between the energy storage density and the energy storage efficiency. The adoption of active heat transfer enhancement (convective heat transfer enhancement) leads to a high energy storage density of 670 MJ m−3 (close to the maximum theoretical value of 755.3 MJ m−3). In contrast, the energy storage efficiency decreases dramatically due to the increase in the pumping power. On the other hand, passive heat transfer techniques using the bed’s thermal conductivity enhancers provide a balance between the energy storage density (578 MJ m−3) and the energy efficiency (74%). The utilization of phase change material as an internal heat recovery medium leads to a further reduction in the heat storage performance indicators (142 MJ m−3 and 49%). Nevertheless, such a system combining thermochemical and latent heat storage, if properly optimized, can be promising for thermal energy storage applications.

Published

2021

7. Selection of metal hydrides-based thermal energy storage: energy storage efficiency and density targets

Author

Mykhaylo Lototskyy, Serge Nyallang Nyamsi, and Ivan Tolj

Subjects

Coupling, Materials science, Renewable Energy, Sustainability and the Environment, Hydride, Mass flow, Nuclear engineering, 05 social sciences, Energy Engineering and Power Technology, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Thermal energy storage, metal hydride, heat management, energy storage efficiency, energy storage density, Energy storage, Hydrogen storage, Fuel Technology, 0502 economics and business, Concentrated solar power, 050207 economics, 0210 nano-technology, First law of thermodynamics

Abstract

Thermo-chemical energy storage based on metal hydrides has gained tremendous interest in solar heat storage applications such as concentrated solar power systems (CSP) and parabolic troughs. In such systems, two metal hydride beds are connected and operating in an alternative way as energy storage or hydrogen storage. However, the selection of metal hydrides is essential for a smooth operation of these CSP systems in terms of energy storage efficiency and density. In this study, thermal energy storage systems using metal hydrides are modeled and analyzed in detail using first law of thermodynamics. For these purpose, four conventional metal hydrides are selected namely LaNi5, Mg, Mg2Ni and Mg2FeH6. The comparison of performance is made in terms of volumetric energy storage and energy storage efficiency. The effects of operating conditions (temperature, hydrogen pressure and heat transfer fluid mass flow rates) and reactor design on the aforementioned performance metrics are studied and discussed in detail. The preliminary results showed that Mg-based hydrides store energy ranging from 1.3 to 2.4 GJ m−3 while the energy storage can be as low as 30% due to their slow intrinsic kinetics. On the other hand, coupling Mg-based hydrides with LaNi5 allow us to recover heat at a useful temperature above 330 K with low energy density ca.500 MJ m−3 provided suitable operating conditions are selected. The results of this study will be helpful to screen out all potentially viable hydrides materials for heat storage applications.

Published

2018

8. Metal Hydride Beds-Phase Change Materials: Dual Mode Thermal Energy Storage for Medium-High Temperature Industrial Waste Heat Recovery

Author

Mykhaylo Lototskyy, Serge Nyallang Nyamsi, and Ivan Tolj

Subjects

Control and Optimization, Materials science, 020209 energy, Nuclear engineering, Energy Engineering and Power Technology, 02 engineering and technology, Thermal energy storage, lcsh:Technology, 7. Clean energy, Thermal conductivity, industrial waste heat recovery, thermal energy storage, phase change material, metal hydrides, energy recovery e ciency, Heat recovery ventilation, Latent heat, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Engineering (miscellaneous), Energy recovery, lcsh:T, Renewable Energy, Sustainability and the Environment, Hydride, Enthalpy of fusion, 021001 nanoscience & nanotechnology, Phase-change material, 13. Climate action, energy recovery efficiency, 0210 nano-technology, Energy (miscellaneous)

Abstract

Heat storage systems based on two-tank thermochemical heat storage are gaining momentum for their utilization in solar power plants or industrial waste heat recovery since they can efficiently store heat for future usage. However, their performance is generally limited by reactor configuration, design, and optimization on the one hand and most importantly on the selection of appropriate thermochemical materials. Metal hydrides, although at the early stage of research and development (in heat storage applications), can offer several advantages over other thermochemical materials (salt hydrates, metal hydroxides, oxide, and carbonates) such as high energy storage density and power density. This study presents a system that combines latent heat and thermochemical heat storage based on two-tank metal hydrides. The systems consist of two metal hydrides tanks coupled and equipped with a phase change material (PCM) jacket. During the heat charging process, the high-temperature metal hydride (HTMH) desorbs hydrogen, which is stored in the low-temperature metal hydride (LTMH). In the meantime, the heat generated from hydrogen absorption in the LTMH tank is stored as latent heat in a phase change material (PCM) jacket surrounding the LTMH tank, to be reused during the heat discharging. A 2D axis-symmetric mathematical model was developed to investigate the heat and mass transfer phenomena inside the beds and the PCM jacket. The effects of the thermo-physical properties of the PCM and the PCM jacket size on the performance indicators (energy density, power output, and energy recovery efficiency) of the heat storage system are analyzed and discussed. The results showed that the PCM melting point, the latent heat of fusion, the density and the thermal conductivity had significant impacts on these performance indicators.

Published

2019

9. Three-dimensional modeling and sensitivity analysis of multi-tubular metal hydride reactors

Author

Fusheng Yang, Zaoxiao Zhang, Zhen Wu, Serge Nyallang Nyamsi, and Zewei Bao

Subjects

Materials science, Computer simulation, Turbulence, Hydride, Multiphysics, Energy Engineering and Power Technology, Mechanical engineering, Mechanics, Churchill–Bernstein equation, Industrial and Manufacturing Engineering, Volumetric flow rate, Physics::Fluid Dynamics, Thermal conductivity, Mass transfer

Abstract

In order to predict heat and mass transfer characteristics of metal hydride reactors accurately, a novel three-dimensional multiphysics model was presented. In the newly established model, the velocity field of the heat transfer fluid was obtained by solving the Navier–Stokes equations or the k-e turbulence model. The model was numerically solved using the commercial software package COMSOL Multiphysics V3.5a. Two traditional models were also solved for the reactors under the same set of conditions. A dimensionless parameter N was defined to assess the effects of neglecting the variation of heat transfer fluid temperature on the hydrogen absorption rate. The results from numerical simulation indicated that when N is greater than 0.01, the variation of heat transfer fluid temperature cannot be neglected. In this case, the newly established model was valid while the other two models were not. Moreover, it was found that the effective thermal conductivity of the metal hydride, the flowrate of the heat transfer fluid and the contact resistance were crucial factors for improving the performance of the metal hydride reactors.

Published

2013

10. An optimization study on the finned tube heat exchanger used in hydride hydrogen storage system – analytical method and numerical simulation

Author

Fusheng Yang, Zaoxiao Zhang, and Serge Nyallang Nyamsi

Subjects

Renewable Energy, Sustainability and the Environment, Chemistry, Plate heat exchanger, Energy Engineering and Power Technology, Thermodynamics, Mechanics, Condensed Matter Physics, Annular fin, Concentric tube heat exchanger, Fin (extended surface), Fuel Technology, Heat spreader, Micro heat exchanger, Plate fin heat exchanger, Shell and tube heat exchanger

Abstract

Metal hydrides show great potential for hydrogen storage. However, for efficient hydrogen storage, thermal management is the technical barrier. Among the different heat exchangers proposed in the literature, finned tube heat exchangers are of great technological interest due to their adaptability to wide range of practical applications, high compactness and high heat transfer efficiency. In the present paper, the optimization of finned heat exchanger considering both enhanced heat transfer and vessel volume efficiency is conducted. A semi-analytical expression of heat transfer rate from a single fin is derived. The effects of fin dimension (fin thickness and radius) on the heat exchanger performance are studied. It was shown that the thermal resistance of the whole heat exchanger can be reduced by increasing the fin radius and decreasing the fin thickness, while the fin volume is kept fixed. In the second part of the study, a 2-D numerical simulation was performed in order to validate the results of the analytical study. The effects of two parameters (cooling tube diameter, the fin length) on the hydrogen charging time were highlighted. The increasing in the tube diameter from 2.5 mm to 5 mm results to 25% reduction of the charging time, which is very noticeable. On the other hand, given a reactor radius, increasing the length of fin reduces the overall thermal resistance of the reactor-heat exchanger. The results showed that the decreasing of the thermal resistance of 13% leads to a decreasing in charging time of 42%. Finally, it was found that the results of the numerical simulation agreed qualitatively with those of analytical study. Therefore, the analytical solution presented can be used for a quick assessment of the finned tube heat exchanger design without significant errors.

Published

2012

11. Assessment of errors on the kinetic data by entropy generation analysis

Author

Fusheng Yang, Zewei Bao, Zaoxiao Zhang, Serge Nyallang Nyamsi, and Zhen Wu

Subjects

Computer simulation, Renewable Energy, Sustainability and the Environment, Chemistry, Hydride, Energy Engineering and Power Technology, Thermodynamics, Mechanics, Heat transfer coefficient, Condensed Matter Physics, Kinetic energy, Reaction rate, Hydrogen storage, Fuel Technology, Hydrogen pressure, Mass transfer

Abstract

Metal hydride systems are utilized in many practical applications such as hydrogen storage, heat pumps, etc. The establishment of a metal hydride system requires the expression of reaction rate for the first step design, from an engineering standpoint. However, improper experimental determination of intrinsic kinetics usually leads to significant errors in the kinetic data. This paper presents a novel methodology of estimating these errors based on the entropy generation analysis. For this purpose, numerical simulation is performed taking into account the experimental conditions for a real case. The results showed that if the operating conditions (i.e. hydrogen pressure, heat transfer coefficient) and the size of the experimental setup are not chosen properly, the kinetic data obtained from the experiments will be largely misled. Therefore it should be carefully taken into account in order to minimize the relative errors induced on the kinetic data.

Published

2012

12. Optimal Design of Combined Two-Tank Latent and Metal Hydrides-Based Thermochemical Heat Storage Systems for High-Temperature Waste Heat Recovery

Author

Ivan Tolj, Serge Nyallang Nyamsi, and Mykhaylo Lototskyy

Subjects

Control and Optimization, Materials science, 020209 energy, Nuclear engineering, Energy Engineering and Power Technology, 02 engineering and technology, Thermal energy storage, 7. Clean energy, Storage efficiency, lcsh:Technology, Energy storage, Waste heat recovery unit, Thermal conductivity, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Engineering (miscellaneous), energy efficiency, waste heat recovery, Renewable Energy, Sustainability and the Environment, metal hydride, thermochemical heat storage, phase change materials, lcsh:T, 021001 nanoscience & nanotechnology, Phase-change material, Freezing point, 13. Climate action, Melting point, 0210 nano-technology, Energy (miscellaneous)

Abstract

The integration of thermal energy storage systems (TES) in waste-heat recovery applications shows great potential for energy efficiency improvement. In this study, a 2D mathematical model is formulated to analyze the performance of a two-tank thermochemical heat storage system using metal hydrides pair (Mg2Ni/LaNi5), for high-temperature waste heat recovery. Moreover, the system integrates a phase change material (PCM) to store and restore the heat of reaction of LaNi5. The effects of key properties of the PCM on the dynamics of the heat storage system were analyzed. Then, the TES was optimized using a genetic algorithm-based multi-objective optimization tool (NSGA-II), to maximize the power density, the energy density and storage efficiency simultaneously. The results indicate that the melting point Tm and the effective thermal conductivity of the PCM greatly affect the energy storage density and power output. For the range of melting point Tm = 30&ndash, 50 &deg, C used in this study, it was shown that a PCM with Tm = 47&ndash, 49 &deg, C leads to a maximum heat storage performance. Indeed, at that melting point narrow range, the thermodynamic driving force of reaction between metal hydrides during the heat charging and discharging processes is almost equal. The increase in the effective thermal conductivity by the addition of graphite brings about a tradeoff between increasing power output and decreasing the energy storage density. Finally, the hysteresis behavior (the difference between the melting and freezing point) only negatively impacts energy storage and power density during the heat discharging process by up to 9%. This study paves the way for the selection of PCMs for such combined thermochemical-latent heat storage systems.