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The methods currently used for designing a fluidized bed reactor in gasification plants do not meet an integrated methodology that optimizes all the different parameters for its sizing and operational regime. In the case of small-scale (several tens of kWs biomass gasifiers), this design is especially complex, and, for this reason, they have usually been built in a very heuristic trial and error way. In this paper, an integrated methodology tailoring all the different parameters for the design and sizing of a small-scale fluidized bed gasification plants is presented. Using this methodology, a 40 kWth biomass gasification reactor was designed, including the air distribution system. Based on this design, with several simplified assumptions, a reactor was built and commissioned. Results from the experimental tests using this gasifier are also presented in this paper. As a result, it can be said the prototype works properly, and it produces syngas able to produce thermal energy or even electricity.
Carlos Vargas-Salgado; Elías Hurtado-Pérez; David Alfonso-Solar; Anders Malmquist. Empirical Design, Construction, and Experimental Test of a Small-Scale Bubbling Fluidized Bed Reactor. Sustainability 2021, 13, 1061 .
AMA StyleCarlos Vargas-Salgado, Elías Hurtado-Pérez, David Alfonso-Solar, Anders Malmquist. Empirical Design, Construction, and Experimental Test of a Small-Scale Bubbling Fluidized Bed Reactor. Sustainability. 2021; 13 (3):1061.
Chicago/Turabian StyleCarlos Vargas-Salgado; Elías Hurtado-Pérez; David Alfonso-Solar; Anders Malmquist. 2021. "Empirical Design, Construction, and Experimental Test of a Small-Scale Bubbling Fluidized Bed Reactor." Sustainability 13, no. 3: 1061.
As governments and companies struggle to meet their own objectives for the energy transition, more innovative social and technological measures are needed to reduce Greenhouse Gas (GHG) emissions. For this purpose, an assessment of an off-grid polygeneration system, which can serve the electric and cooling demand of a neighbourhood in Hermosillo, Mexico, has been conducted. Energy computations have been done, the energy demand of one dwelling has been measured to ascertain the correctness of the computations, and a demand model for the entire neighbourhood has been created. Based on the model, an off-grid polygeneration system has been designed, which uses a biodiesel engine, PV panels, and an absorption chiller. The system has been optimized for its economic performance and is compared to the currently used system. The results show that the polygeneration system with higher energy efficiency could reduce GHG emissions down to 14%. However, electricity in Hermosillo is heavily subsidized making it harder for innovative systems to compete. Moreover, even without the state subsidies to the end user, the polygeneration system has still a nearly 30% higher Net Present Cost (NPC) than the conventional system over its project lifetime of 20 years. Nonetheless, with precise political incentives and further advances in the applied technologies, small-scale renewable polygeneration systems could become cost-efficient alternatives in the near future.
Moritz Wegener; Carlos Lopez Ordóñez; Antonio Isalgué; Anders Malmquist; Andrew Martin. How Much Does It Cost to Go Off-Grid with Renewables? A Case Study of a Polygeneration System for a Neighbourhood in Hermosillo, Mexico. Blockchain Technology and Innovations in Business Processes 2019, 395 -405.
AMA StyleMoritz Wegener, Carlos Lopez Ordóñez, Antonio Isalgué, Anders Malmquist, Andrew Martin. How Much Does It Cost to Go Off-Grid with Renewables? A Case Study of a Polygeneration System for a Neighbourhood in Hermosillo, Mexico. Blockchain Technology and Innovations in Business Processes. 2019; ():395-405.
Chicago/Turabian StyleMoritz Wegener; Carlos Lopez Ordóñez; Antonio Isalgué; Anders Malmquist; Andrew Martin. 2019. "How Much Does It Cost to Go Off-Grid with Renewables? A Case Study of a Polygeneration System for a Neighbourhood in Hermosillo, Mexico." Blockchain Technology and Innovations in Business Processes , no. : 395-405.
Trigeneration or combined cooling, heat and power (CCHP) systems fueled by raw biogas can be an interesting alternative for supplying electricity and thermal services in remote rural areas where biogas can be produced without requiring sophisticated equipment. In this sense, this study considers a performance analysis of a novel small-scale CCHP system where a biogas-fired, 5 kWel externally fired microturbine (EFMT), an absorption refrigeration system (ARS) and heat exchangers are integrated for supplying electricity, refrigeration and hot water demanded by Bolivian small dairy farms. The CCHP solution presents two cases, current and nominal states, in which experimental and design data of the EFMT performance were considered, respectively. The primary energy/exergy rate was used as a performance indicator. The proposed cases show better energy performances than those of reference fossil fuel-based energy solutions (where energy services are produced separately) allowing savings in primary energy utilization of up to 31%. Furthermore, improvements in electric efficiency of the EFMT and coefficient of performance (COP) of the ARS, identified as key variables of the system, allow primary energy savings of up to 37%. However, to achieve these values in real conditions, more research and development of the technologies involved is required, especially for the EFMT.
J. Villarroel-Schneider; Anders Malmquist; Joseph A. Araoz; J. Martí-Herrero; Andrew Martin; Villarroel- Schneider; Martí- Herrero. Performance Analysis of a Small-Scale Biogas-Based Trigeneration Plant: An Absorption Refrigeration System Integrated to an Externally Fired Microturbine. Energies 2019, 12, 3830 .
AMA StyleJ. Villarroel-Schneider, Anders Malmquist, Joseph A. Araoz, J. Martí-Herrero, Andrew Martin, Villarroel- Schneider, Martí- Herrero. Performance Analysis of a Small-Scale Biogas-Based Trigeneration Plant: An Absorption Refrigeration System Integrated to an Externally Fired Microturbine. Energies. 2019; 12 (20):3830.
Chicago/Turabian StyleJ. Villarroel-Schneider; Anders Malmquist; Joseph A. Araoz; J. Martí-Herrero; Andrew Martin; Villarroel- Schneider; Martí- Herrero. 2019. "Performance Analysis of a Small-Scale Biogas-Based Trigeneration Plant: An Absorption Refrigeration System Integrated to an Externally Fired Microturbine." Energies 12, no. 20: 3830.
Energy services are especially expensive on remote islands due to longer and more unstable fuel supply chains. In this paper, different renewable energy systems utilizing locally available biomass and solar energy are proposed as alternatives for a hotel resort on Neil Island, India. Based on local demand data, commercial information, and scientific literature, four cases are modelled with the simulation software HOMER and their economic, energetic, as well as ecological (3E) performances are compared. The robustness of each case configuration is tested with a sensitivity analysis. The results show that a biomass-based, solar-assisted combined cooling, heating, and power (CCHP) system offers an economic saving potential of more than 500,000 USD over twenty years and could decrease CO2 emissions by 365 t per year. When not applying CCHP measures, system performance is significantly worsened. A solar and battery-assisted diesel generator system shows similar economic outcomes as the CCHP system but worse ecological performance. Implementing the biomass-based CCHP system could improve the ecological footprint of the island, substantially decrease expenditure for the hotel owner, and generate a new source of income for surrounding farmers through biomass selling.
Moritz Wegener; Antonio Isalgué; Anders Malmquist; Andrew Martin. 3E-Analysis of a Bio-Solar CCHP System for the Andaman Islands, India—A Case Study. Energies 2019, 12, 1113 .
AMA StyleMoritz Wegener, Antonio Isalgué, Anders Malmquist, Andrew Martin. 3E-Analysis of a Bio-Solar CCHP System for the Andaman Islands, India—A Case Study. Energies. 2019; 12 (6):1113.
Chicago/Turabian StyleMoritz Wegener; Antonio Isalgué; Anders Malmquist; Andrew Martin. 2019. "3E-Analysis of a Bio-Solar CCHP System for the Andaman Islands, India—A Case Study." Energies 12, no. 6: 1113.
Design and performance of polygeneration energy systems are highly influenced by several variables, including the climate zone, which can affect the load profile as well as the availability of renewable energy sources. To investigate the effects, in this study, the design of a polygeneration system for identical residential buildings that are located in three different climate zones in Iran has been investigated. To perform the study, a model has previously developed by the author is used. The performance of the polygeneration system in terms of energy, economy and environment were compared to each other. The results show significant energetic and environmental benefits of the implementation of polygeneration systems in Iran, especially in the building that is located in a hot climate, with a high cooling demand and a low heating demand. Optimal polygeneration system for an identical building has achieved a 27% carbon dioxide emission reduction in the cold climate, while this value is around 41% in the hot climate. However, when considering the price of electricity and gas in the current energy market in Iran, none of the systems are feasible and financial support mechanisms or other incentives are required to promote the application of decentralized polygeneration energy systems.
Sara Ghaem Sigarchian; Anders Malmquist; Viktoria Martin. Design Optimization of a Small-Scale Polygeneration Energy System in Different Climate Zones in Iran. Energies 2018, 11, 1115 .
AMA StyleSara Ghaem Sigarchian, Anders Malmquist, Viktoria Martin. Design Optimization of a Small-Scale Polygeneration Energy System in Different Climate Zones in Iran. Energies. 2018; 11 (5):1115.
Chicago/Turabian StyleSara Ghaem Sigarchian; Anders Malmquist; Viktoria Martin. 2018. "Design Optimization of a Small-Scale Polygeneration Energy System in Different Climate Zones in Iran." Energies 11, no. 5: 1115.
Small-scale decentralized polygeneration systems have several energetic, economic and environmental benefits. However, using multiple energy sources and providing multiple energy services can lead to complicated studies which require advanced optimization techniques for determining optimal solutions. Furthermore, several parameters can influence the design and performance of a polygeneration system. In this study, the effects of heat load, renewable generation and storage units on the optimal design and performance of a polygeneration system for a hypothetical hospital located in northern Italy are investigated. The polygeneration system shows higher performance compared to the reference system, which is based on the separate generation of heat and power. It reduces fuel consumption by 14–32%, CO2 emissions by 10–29% and annualized total cost by 7–19%, for various studied scenarios. The avoided fuel and electricity purchase of the polygeneration system has a positive impact on the economy. This, together with the environmental and energetic benefits if the renewable generation and use of storage devices, indicate the viability and competitiveness of the system.
Sara Ghaem Sigarchian; Anders Malmquist; Viktoria Martin. Design Optimization of a Complex Polygeneration System for a Hospital. Energies 2018, 11, 1071 .
AMA StyleSara Ghaem Sigarchian, Anders Malmquist, Viktoria Martin. Design Optimization of a Complex Polygeneration System for a Hospital. Energies. 2018; 11 (5):1071.
Chicago/Turabian StyleSara Ghaem Sigarchian; Anders Malmquist; Viktoria Martin. 2018. "Design Optimization of a Complex Polygeneration System for a Hospital." Energies 11, no. 5: 1071.
Small-scale distributed generation systems are expected to play a vital role in future energy supplies. Subsequently, power generation using micro-gas turbine (MGT) is getting more and more attention. In particular, externally fired micro-gas turbine (EFMGT) is preferred among small-scale distributed generators, mainly due to high fuel flexibility, high overall efficiency, environmental benefits, and low maintenance requirement. The goal of this work is to evaluate the performance of an EFMGT-based standalone polygeneration system with the help of computational simulation studies. The main focus of this work is to develop a dynamic model for an EFMGT. The dynamic model is accomplished by merging a thermodynamic model with a mechanical model of the rotor and a transfer function based control system model. The developed model is suitable for analyzing system performance particularly from thermodynamic and control point of view. Simple models for other components of the polygeneration systems, electrical and thermal loads, membrane distillation unit, and electrical and thermal storage, are also developed and integrated with the EFMGT model. The modeling of the entire polygeneration system is implemented and simulated in matlab/simulink environment. Available operating data from test runs of both the laboratory setups are used in this work for further analysis and validation of the developed model.
Moksadur Rahman; Anders Malmquist. Modeling and Simulation of an Externally Fired Micro-Gas Turbine for Standalone Polygeneration Application. Journal of Engineering for Gas Turbines and Power 2016, 138, 112301 .
AMA StyleMoksadur Rahman, Anders Malmquist. Modeling and Simulation of an Externally Fired Micro-Gas Turbine for Standalone Polygeneration Application. Journal of Engineering for Gas Turbines and Power. 2016; 138 (11):112301.
Chicago/Turabian StyleMoksadur Rahman; Anders Malmquist. 2016. "Modeling and Simulation of an Externally Fired Micro-Gas Turbine for Standalone Polygeneration Application." Journal of Engineering for Gas Turbines and Power 138, no. 11: 112301.