Your search keyword '"Crina S. Ilea"' showing total 4 results

1. 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

2. Regenerative Energy Storage System for Space Exploration Missions

Author

Stella Balomenou, Kalliopi M. Papazisi, Crina S. Ilea, Ivar Wærnhus, Max Schautz, Dimitrios Tsiplakides, and Arild Vik

Subjects

lcsh:GE1-350, Electrolysis, Engineering, Hydrogen, business.industry, Nuclear engineering, 0211 other engineering and technologies, chemistry.chemical_element, Mechanical engineering, 02 engineering and technology, 010501 environmental sciences, Breadboard, Exploration of Mars, 01 natural sciences, Space exploration, Energy storage, law.invention, chemistry, law, Computer data storage, Solid oxide fuel cell, 021108 energy, business, lcsh:Environmental sciences, 0105 earth and related environmental sciences

Abstract

This paper describes the development and testing of a 1 kW reversible solid oxide fuel cell intended for energy storage on space exploration missions, particularly for long term Mars exploration. The energy is stored as H2 or CO produced by electrolysis of H2 O or CO2 . The reactants are then converted back to its original composition by producing electricity.The breadboard was operated for 1250 hours alternating between electrolyser mode and fuel cell mode with H2 /H2 O as reactants. During the tests, as long as the mechanical integrity of the system was maintained, no degradation effect was observed. At the end of the test period, the fuel cell was operated for three full cycles (approx. 50 hours) with CO/CO2 as reactants. The performance on CO/CO2 was lower than for hydrogen, but sufficient to be used in a compact energy storage system for Mars exploration.

Published

2017

3. Carbon Tolerant Fuel Electrodes for Reversible Sofc Operating on Carbon Dioxide

Author

Stella Balomenou, Dimitrios Tsiplakides, Crina S. Ilea, Kalliopi M. Papazisi, Arild Vik, Ivar Wærnhus, and Max Schautz

Subjects

lcsh:GE1-350, Electrolysis, Materials science, Electrolytic cell, Inorganic chemistry, Oxide, chemistry.chemical_element, Electrolyte, Cermet, Electrochemistry, law.invention, chemistry.chemical_compound, chemistry, law, Solid oxide fuel cell, Carbon, lcsh:Environmental sciences

Abstract

A challenging barrier for the broad, successful implementation of Reversible Solid Oxide Fuel Cell (RSOFC) technology for Mars application utilizing CO2 from the Martian atmosphere as primary reactant, remains the long term stability by the effective control and minimization of degradation resulting from carbon built up. The perovskitic type oxide material La0.75 Sr0.25 Cr0.9 Fe0.1 O3-δ (LSCF) has been developed and studied for its performance and tolerance to carbon deposition, employed as bi-functional fuel electrode in a Reversible SOFC operating on the CO2 cycle (Solid Oxide Electrolysis Cell/SOEC: CO2 electrolysis, Solid Oxide Fuel Cell/SOFC: power generation through the electrochemical reaction of CO and oxygen). A commercial state-of-the-art NiO-YSZ (8% mol Y2 O3 stabilized ZrO2 ) cermet was used as reference material. CO2 electrolysis and fuel cell operation in 70% CO/CO2 were studied in the temperature range of 900-1000°C. YSZ was used as electrolyte while LSM-YSZ/LSM (La0.2 Sr0.8 MnO3 ) as oxygen electrode. Results showed that LSCF had high and stable performance under RSOFC operation.

Published

2017

4. Development of an All Ceramic SOFC

Author

Crina S. Ilea, Arild Vik, Ivar Wærnhus, and Sonia Faaland

Subjects

Materials science, All ceramic, Metallurgy

Abstract

High temperature SOFC with operation temperature from 800 - 1000oC is suitable for high efficiency fuel cell systems based on heat integration with other technologies, such as SOFC-GT, gasification or hydrogen production. This requires alternatives to the commonly used metallic interconnects. Prototech is currently developing an all ceramic SOFC suitable for operation in this temperature region in larger systems with heat integration.

Published

2011