Economic analysis of a combined heat and power molten carbonate fuel cell system (original) (raw)
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Molten carbonate fuel cell (MCFC) characteristics, technologies and economic analysis: Review
International Journal of Renewable Energy, 2008
The MCFC seems a valid alternative to the traditional plant. MCFC power plants are prime candidates for the utilization of fossil based fuels to generate high efficiency ultra clean power. Largescale commercialization, especially in the distributed generation and cogeneration market, remains a possibility. However, fuel cells are considerably more expensive than comparable conventional technologies and therefore a careful analysis of economics must be taken. In general, the use of a fuel cell at this facility would not be economically feasible at this time. But, a parametric study was conducted to determine scenarios including variation in electric and natural gas rates along with reduced installation costs.
Study of a molten carbonate fuel cell combined heat, hydrogen and power system: Energy analysis
Applied Thermal Engineering, 2013
To address the problem of fossil fuel usage and high greenhouse gas emissions at the Missouri University of Science and Technology campus, using of alternative fuels and renewable energy sources can lower energy consumption and greenhouse gas emissions. Biogas, produced by anaerobic digestion of wastewater, organic waste, agricultural waste, industrial waste, and animal by-products is a potential source of renewable energy. In this work, we have discussed the design of CHHP system for the campus using local resources. An energy flow and resource availability study is performed to identify the type and source of feedstock required to continuously run the fuel cell system at peak capacity. Following the resource assessment study, the team selects FuelCell Energy DFC1500™ unit as a molten carbonate fuel cell. The CHHP system provides electricity to power the university campus, thermal energy for heating the anaerobic digester, and hydrogen for transportation, back-up power and other needs. In conclusion, the CHHP system will be able to reduce fossil fuel usage, and greenhouse gas emissions at the university campus.
Process Simulation for Molten Carbonate Fuel Cells
Fuel Cells, 2005
Natural-gas-fueled solid oxide fuel cell (NGSOFC) power systems yield electrical conversion efficiencies exceeding 55% and may become a viable alternative for distributed generation (DG) if stack life and manufacturing economies of scale can be realized. Currently, stacks last approximately 2 years and few systems are produced each year because of the relatively high cost of electricity from the systems. PNNL has performed cost modeling for production of 270 kW (DC) NGSOFC power systems, sized for light industry or large box stores. If mass manufacturing (10.000 units per year) and a stack life of 15 years can be reached, the cost of electricity from an NGSOFC system is estimated to be about 8,2 ¢/kWh, well within the range of commercial and residential retail prices at the national level (9,9-10 ¢/kWh and 11-12 ¢/kWh, respectively). With 5 ¢/kWh in estimated additional benefits from DG, NGSOFC could be well positioned to replace the forecasted 59-77 gigawatts of capacity loss resulting from coal plant closures due to stricter emissions regulations and low natural gas prices.
Molten Carbonate Fuel Cell Combined Heat, Hydrogen and Power System: Feedstock Analysis
Biogas is an untapped potential in regards to an alternative energy source. This immediately available resource will allow countries to reduce their greenhouse gas emissions, energy consumption, and reliance on fossil fuels. This energy source is created by anaerobic digestion of feedstock. Sources for feedstock include organic and inorganic waste, agricultural waste, animal by-products, and industrial waste. All of these sources of biogas are a renewable energy source. Specifically a fuel cell can utilize the methane present in biogas using integrated heat, power, and hydrogen systems. A study was performed concerning energy flow and resource availability to ascertain the type and source of feedstock to run a fuel cell system unceasingly while maintaining maximum capacity. After completion of this study and an estimation of locally available fuel, the FuelCell Energy 1500 unit (a molten carbonate fuel cell) was chosen to be used on campus. This particular fuel cell will provide ele...
Analysis of a molten carbonate fuel cell: cogeneration to produce electricity and cold water
Energy, 2001
The fuel cell is an emerging cogeneration technology that has been applied successfully in Japan, the USA and some countries in the European Union. This system performs direct conversion of the chemical energy of the oxidation of hydrogen from fuel with atmospheric oxygen into direct current electricity and waste heat via an electrochemical process relying on the use of different electrolytes (phosphoric acid, molten carbonate and solid oxide, depending on operating temperature). This technology permits the recovery of waste heat, available from 200°C up to 1000°C depending on the electrolyte technology, which can be used in the production of steam, hot or cold water, or hot or cold air, depending on the associated recuperation equipment. In this paper, an energy, exergy and economic analysis of a fuel cell cogeneration system (FCCS) is presented. The FCCS is applied in a segment of the tertiary sector to show that it is a feasible alternative for rational decentralized energy production under Brazilian conditions. The technoeconomic analysis shows a global efficiency or fuel utilization efficiency of 86%. Analysis shows that the exergy losses in the fuel cell unit and the absorption refrigeration system are significant. Furthermore, the payback period estimated is about 3 and 5 years for investments in fuel cells of 1000 and 1500 US$/kW, respectively.
Life cycle analysis and cost of a molten carbonate fuel cell prototype
International Journal of Hydrogen Energy, 2011
The LCA is a method enabling the performance of a complete study on the environmental impacts of the product, taking into consideration all its life cycle ("from the cradle to the tomb" or, better "from the cradle to the cradle" when also the maximum recycling/reusing of the materials is provided. There are many procedures to perform an LCA of the consumers' products. In particular, the SUMMA method (Sustainability Multi-criteria Multi-scale Assessment) allows obtaining a number of indices of efficiency and environmental sustainability which make the LCA assessment much more complete and significant. LCA method often represents the basis for an additional assessment of industrial products and processes, the LCC (Life Cycle Costing) which, allowing the association of economic variables to any phase of the life cycle, represents a useful tool for financial planning and management. The case study analysed in the present work concerns an LCA analysis, using the SUMMA method and the LCC of one small size molten carbonate fuel cell, 2.5 kW, assembled in the Fuel Cells Laboratory within the Educational Pole of Terni at the Università degli Studi di Perugia. For sake of completeness of the results, the methods Ecoindicator99 and Impact2002 þ were used in the analysis, as implemented in the used calculation software, the SimaPro 7.1 by PRè Consultants. From the registered results, it emerges that the environmental energy sustainability of the analysed element enables its widespread and in-depth employment in the phase subsequent to the optimisation of the connected economic frame; the scenarios opened by the present work envisage great margins of improvements of said aspects in the future experiments.
Energy Conversion and Management, 2020
A novel hybrid system consisting of a molten carbonate fuel cell (MCFC), a gas turbine (GT), a steam cycle and a thermophotovoltaic (TPV) system to generate power is introduced and investigated. For this purpose, a GT is coupled to a MCFC in order to utilize unused fuel, raise the gas components temperature, supply the required carbon dioxide, and further power generation. Moreover, in order to boost the power generation and ameliorate the overall efficiency, a TPV system together with a steam cycle has been added to the system for heat recovery from the combustion chamber radiation and cathode output stream, respectively. The simulation of the hybrid system was accomplished through ASPEN HYSYS and MATLAB software. The effect of different influential parameters on each subsystem as well as the proposed hybrid system was examined comprehensively through sensitivity analysis. The results obtained revealed that increasing MCFC temperature decreased the anode, cathode, and ohmic overpotentials, while augmented the output voltage of the MCFC led to enhanced MCFC performance. Furthermore, the output voltage, power density, and efficiency of the MCFC enhanced with increasing the operating pressure for both of the fuel consumption rates. The output voltage and power density of the MCFC decreased as the fuel consumption rate incremented due to increased polarization losses, while the electrical efficiency of the MCFC enhanced. Optimizing the output temperature of the first and second heat exchangers increased the power of the steam turbine by about 16 kW. The highest power density and performance of the TPV system was obtained at cell and emitter distance of 1 cm. Incorporating the GT to the MCFC enhanced the system's efficiency to 54.83%. The efficiency of the proposed hybrid system was found to be 67.3%.
2012
In this paper the comparative study of power generation through high temperature fuel cells that is Molten Carbonate fuel cells are presented .The MCFCs is not best power generation source compare to other fuel cells for all conditions and places. But it is the better alternative source of power generation coupling with gasification process. The generating renewable electricity is an important way to reduce carbon dioxide (CO 2) emissions and many countries are installing wind and solar power plants to help meet targets for cutting CO 2. Regarding this direction MCFCs is attractive sources of power generation since in it working no emissions of CO &CO 2. The present aspects of this paper are basic ideas regarding my research works that is Energy modeling and optimization of MCFCs will be appear in next papers.