Your search keyword '"Serge Nyallang Nyamsi"' showing total 9 results

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

Author

Serge Nyallang Nyamsi, Ivan Tolj, and Mykhaylo Lototskyy

Subjects

industrial waste heat recovery, thermal energy storage, phase change material, metal hydrides, energy recovery efficiency, Technology

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

2. 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

3. 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

4. An outstanding effect of graphite in nano-MgH2–TiH2 on hydrogen storage performance

Author

Cordellia Sita, Jon Eriksen, Jonathan Goh, Franscious Cummings, Roman V. Denys, Serge Nyallang Nyamsi, Mykhaylo Lotoskyy, and Volodymyr A. Yartys

Subjects

Materials science, Hydrogen, Renewable Energy, Sustainability and the Environment, chemistry.chemical_element, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Thermal energy storage, 01 natural sciences, 0104 chemical sciences, Hydrogen storage, Grain growth, chemistry, Chemical engineering, Desorption, General Materials Science, Dehydrogenation, Graphite, 0210 nano-technology, Carbon

Abstract

TiH2-modified MgH2 was prepared by high energy reactive ball milling (HRBM) of Mg and Ti in hydrogen and showed high weight H storage capacity and fast hydrogenation/dehydrogenation kinetics. However, a decrease in the reversible H storage capacity on cycling at high temperatures takes place and is a major obstacle for its use in hydrogen and heat storage applications. Reversible hydrogen absorption/desorption cycling of the materials requires use of the working temperature ≥330 °C and results in a partial step-by-step loss of the recoverable hydrogen storage capacity, with less significant changes in the rates of hydrogenation/dehydrogenation. After hydrogen desorption at 330–350 °C, hydrogen absorption can proceed at much lower temperatures, down to 24 °C. However, a significant decay in the reversible hydrogen capacity takes place with increasing number of cycles. The observed deterioration is caused by cycling-induced drastic morphological changes in the studied composite material leading to a segregation of TiH2 particles in the cycled samples instead of their initial homogeneous distribution. However, the introduction of 5 wt% of graphite into the MgH2–TiH2 composite system prepared by HRBM leads to an outstanding improvement of the hydrogen storage performance. Indeed, hydrogen absorption and desorption characteristics remain stable through 100 hydrogen absorption/desorption cycles and are related to an effect of the added graphite. The TEM study showed that carbon is uniformly distributed between the MgH2 grains covering segregated TiH2, preventing the grain growth and thus keeping the reversible storage capacity and the rates of hydrogen charge and discharge unchanged. Modelling of the kinetics of hydrogen absorption and desorption in the Mg–Ti and Mg–Ti–C composites showed that the reaction mechanisms significantly change depending on the presence or absence of graphite, the number of absorption–desorption cycles and the operating temperature.

Published

2018

5. Synthesis of Mg 2 FeH 6 assisted by heat treatment of starting materials

Author

Mykhaylo Lototskyy, Serge Nyallang Nyamsi, and Volodymyr A. Yartys

Subjects

Yield (engineering), Materials science, Hydrogen, Hydride, 05 social sciences, chemistry.chemical_element, 02 engineering and technology, 021001 nanoscience & nanotechnology, Thermal energy storage, Hydrogen storage, Chemical engineering, chemistry, 0502 economics and business, 050207 economics, 0210 nano-technology, Ternary operation, Ball mill, Stoichiometry

Abstract

Mg-based materials have become the cornerstone of hydrogen storage applications and have shown recently promises in thermal energy storage applications. However, synthesis of some materials including Mg2FeH6 ternary hydride poses a number of challenges. In spite a variety of reports on various synthesis routes yielding Mg2FeH6, none of them produces a 100% pure Mg2FeH6. In this communication, we have attempted to synthesize Mg2FeH6 by high energy reactive ball milling (HERBM) performed in hydrogen gas. Prior to the ball milling, the starting stoichiometric 2:1 mixture of the initial materials Mg+Fe was heat treated through a judicious temperature program. It was found that the yield of Mg2FeH6 is related to the conditions of heat treatment, time and temperature, and the milling parameters such as ball to powder mass ratio (BPR) and rotation speed of the planetary mill. Moreover, it was found that the synthesis took place in less than 5 hours of milling with a maximum yield of Mg2FeH6 of 84 wt%, which is a noticeable improvement as compared to the reference data.

Published

2018

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. 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.