Modeling Aspects of Chemical-looping Combustion for Solid Fuels PDF Download
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Languages : en
Pages : 42
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Author:
Publisher:
ISBN:
Category :
Languages : en
Pages : 42
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Author: Asad Hasan Sahir
Publisher:
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Category : Combustion
Languages : en
Pages : 148
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Author: Johannes Haus
Publisher: Cuvillier Verlag
ISBN: 3736963351
Category : Technology & Engineering
Languages : en
Pages : 140
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Book Description
In this Ph.D. thesis a system of coupled fluidized bed reactors is modelled and simulated dynamically. Chemical Looping Combustion was used as an exemplary process in both the numerical and the experimental part of this work. For the simulation purpose a novel flowsheeting software was used and models for the needed process units developed and integrated into this software. The needed unit models were three interconnected fluidized bed reactors in circulating and bubbling operation conditions, a cyclone for gas-solid separation and loop seals, which ensured solids transport and gas separation between the reactors. Additionally, lab scale experiments on the reactivity of the used solids, oxygen carrier and solid fuels, were conducted and kinetic parameters extracted. All unit models were connected to a process flowsheet and simulated dynamically. The simulation results were compared to experimental data from a 25 kWth pilot plant operated at the university by the author. It could be shown that a detailed and dynamic simulation of the whole process can be carried out over a time period of more than 45 minutes and the experimental results from start-up, steady state operation and shutdown of the plant were predicted accurately.
Author: Sanjay Mukherjee
Publisher:
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Category :
Languages : en
Pages :
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Author: Marcio L. de Souza-Santos
Publisher: CRC Press
ISBN: 9780203027295
Category : Science
Languages : en
Pages : 480
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Book Description
Bridging the gap between theory and application, this reference demonstrates the operational mechanisms, modeling, and simulation of equipment for the combustion and gasification of solid fuels. Solid Fuels Combustion and Gasification: Modeling, Simulation, and Equipment Operation clearly illustrates procedures to improve and optimize the de
Author: Ronald W. Breault
Publisher: John Wiley & Sons
ISBN: 3527342028
Category : Business & Economics
Languages : en
Pages : 488
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Book Description
This comprehensive and up-to-date handbook on this highly topical field, covering everything from new process concepts to commercial applications. Describing novel developments as well as established methods, the authors start with the evaluation of different oxygen carriers and subsequently illuminate various technological concepts for the energy conversion process. They then go on to discuss the potential for commercial applications in gaseous, coal, and fuel combustion processes in industry. The result is an invaluable source for every scientist in the field, from inorganic chemists in academia to chemical engineers in industry.
Author: T. A. Brown
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Author: Yitao Zhang
Publisher:
ISBN:
Category : Chemical engineering
Languages : en
Pages :
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Book Description
With the rising concern of climate change, extensive research has been conducted in recent years on the mitigation of global warming. Greenhouse gas emissions are considered as the key driver of global warming. Among the various greenhouse gases, CO2 is the major contributor to the greenhouse effect. Therefore, mitigation of CO2 emission is the key to address global warming. Chemical looping is an energy conversion technology that can directly produce a concentrated CO2 stream, ready for sequestration and utilization, without the need for an individual CO2 separation step, and thus, has the potential to drastically reduce the energy consumption and cost associated with CO2 capture in carbonaceous fuel energy conversion systems. In this dissertation, process modeling and analysis are conducted on solid fuel power production processes to quantify the energy penalty and exergy losses associated with CO2 capture technologies, including state-of-the-art solvent-based CO2 absorption, oxy-combustion using high purity oxygen, and chemical looping combustion technology. Following the comparison of various power production processes using solid fuel with and without CO2 capture, a comprehensive analysis is performed to investigate the effect of varying operation conditions on the performance of chemical looping combustion reactor system. The coal-direct chemical looping process is a chemical looping combustion technology using moving bed reducer configuration that can directly use coal as the feedstock without requiring upstream gasification steps. An integrated 250 kWth coal-direct chemical looping pilot unit using iron-based oxygen carriers has been constructed and demonstrated for long-term continuous operations. The principles for the design and operation of the primary reactor system are discussed in this dissertation. The results of a successful 288-hour continuous demonstration with pulverized bituminous coal are reported. The results from the pilot unit highlight the concept of the chemical looping combustion process as a promising solid fuel combustion technology with CO2 capture. To investigate chemical looping technology for hydrogen production, process simulation and analysis is performed on two distinct configurations for chemical looping H2 generation process. The simulation results of two chemical looping H2 generation configurations are compared with the conventional steam-methane reforming system to underscore the attractiveness of the chemical looping configurations.
Author: Liang-Shih Fan
Publisher: John Wiley & Sons
ISBN: 1118063139
Category : Technology & Engineering
Languages : en
Pages : 353
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Book Description
This book presents the current carbonaceous fuel conversion technologies based on chemical looping concepts in the context of traditional or conventional technologies. The key features of the chemical looping processes, their ability to generate a sequestration-ready CO2 stream, are thoroughly discussed. Chapter 2 is devoted entirely to the performance of particles in chemical looping technology and covers the subjects of solid particle design, synthesis, properties, and reactive characteristics. The looping processes can be applied for combustion and/or gasification of carbon-based material such as coal, natural gas, petroleum coke, and biomass directly or indirectly for steam, syngas, hydrogen, chemicals, electricity, and liquid fuels production. Details of the energy conversion efficiency and the economics of these looping processes for combustion and gasification applications in contrast to those of the conventional processes are given in Chapters 3, 4, and 5.Finally, Chapter 6 presents additional chemical looping applications that are potentially beneficial, including those for H2 storage and onboard H2 production, CO2 capture in combustion flue gas, power generation using fuel cell, steam-methane reforming, tar sand digestion, and chemicals and liquid fuel production. A CD is appended to this book that contains the chemical looping simulation files and the simulation results based on the ASPEN Plus software for such reactors as gasifier, reducer, oxidizer and combustor, and for such processes as conventional gasification processes, Syngas Chemical Looping Process, Calcium Looping Process, and Carbonation-Calcination Reaction (CCR) Process. Note: CD-ROM/DVD and other supplementary materials are not included as part of eBook file.
Author:
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Category :
Languages : en
Pages :
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Chemical Looping Combustion (CLC) is one promising fuel-combustion technology, which can facilitate economic CO2 capture in coal-fired power plants. It employs the oxidation/reduction characteristics of a metal, or oxygen carrier, and its oxide, the oxidizing gas (typically air) and the fuel source may be kept separate. This topical report discusses the results of four complementary efforts: (5.1) the development of process and economic models to optimize important design considerations, such as oxygen carrier circulation rate, temperature, residence time; (5.2) the development of high-performance simulation capabilities for fluidized beds and the collection, parameter identification, and preliminary verification/uncertainty quantification; (5.3) the exploration of operating characteristics in the laboratoryscale bubbling bed reactor, with a focus on the oxygen carrier performance, including reactivity, oxygen carrying capacity, attrition resistance, resistance to deactivation, cost and availability; and (5.4) the identification of kinetic data for copper-based oxygen carriers as well as the development and analysis of supported copper oxygen carrier material. Subtask 5.1 focused on the development of kinetic expressions for the Chemical Looping with Oxygen Uncoupling (CLOU) process and validating them with reported literature data. The kinetic expressions were incorporated into a process model for determination of reactor size and oxygen carrier circulation for the CLOU process using ASPEN PLUS. An ASPEN PLUS process model was also developed using literature data for the CLC process employing an iron-based oxygen carrier, and the results of the process model have been utilized to perform a relative economic comparison. In Subtask 5.2, the investigators studied the trade-off between modeling approaches and available simulations tools. They quantified uncertainty in the high-performance computing (HPC) simulation tools for CLC bed applications. Furthermore, they performed a sensitivity analysis for velocity, height and polydispersity and compared results against literature data for experimental studies of CLC beds with no reaction. Finally, they present an optimization space using simple non-reactive configurations. In Subtask 5.3, through a series of experimental studies, behavior of a variety of oxygen carriers with different loadings and manufacturing techniques was evaluated under both oxidizing and reducing conditions. The influences of temperature, degree of carrier conversion and thermodynamic driving force resulting from the difference between equilibrium and system O2 partial pressures were evaluated through several experimental campaigns, and generalized models accounting for these influences were developed to describe oxidation and oxygen release. Conversion of three solid fuels with widely ranging reactivities was studied in a small fluidized bed system, and all but the least reactive fuel (petcoke) were rapidly converted by oxygen liberated from the CLOU carrier. Attrition propensity of a variety of carriers was also studied, and the carriers produced by freeze granulation or impregnation of preformed substrates displayed the lowest rates of attrition. Subtask 5.4 focused on gathering kinetic data for a copper-based oxygen carrier to assist with modeling of a functioning chemical looping reactor. The kinetics team was also responsible for the development and analysis of supported copper oxygen carrier material.
