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Author: Zan Liu (Ph. D.)
Publisher:
ISBN:
Category :
Languages : en
Pages : 146
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Book Description
Integrated gasification combined cycle with CO2 capture and sequestration (IGCC-CCS) emerges as one of the most promising technologies for reducing CO2 emission from coal power plant without reducing thermal efficiency significantly. However the high capital cost of these plants has limited their deployment. The current solvent-based low-temperature CO2 capture process (Selexol process) is energy and capital intensive contributing to the problem. Sorbent-based warm CO2 capture has been predicted to be a key enabling technology for lowering down the costs of IGCC-CCS. However, no commercial adsorbents or processes exist for these warm CO2 separations. My thesis work has been devoted to developing a solid sorbent and CO2 capture process which can capture CO2 at an elevated temperature in IGCC system. By combining experimental methods and quantum calculation, I have successfully identified and invented one new sorbent material. The sorbent for warm CO2 capture containing magnesium oxide was developed using incipient wetness impregnation. The reversible adsorption isotherm, cyclic stability, and sorption rate were measured using a custom-built high pressure microbalance system and a thermogravimetric analyzer. Experimental data indicate the sorbent has a fairly large regenerable capacity in 180-240 °C temperature range, fast kinetics, low heat of adsorption, and stable working capacity for at least 84 cycles. The new sorbent performs better than synthetic hydrotalcite and K2CO3-promoted hydrotalcite in the temperature range of interest. To assess the applicability of CO2 removal technology to IGCC via a warm pressure swing adsorption (PSA) process based on our newly invented sorbent which has good cyclic sorption-desorption performance at an elevated temperature, a 16-step warm PSA process was simulated using Aspen Adsorption based on the real sorbent properties. I used the model to fully explore the intercorrelation between hydrogen recovery, CO2 capture percentage, regeneration pressure of sorbent, and steam requirement. Their tradeoff effects on IGCC efficiency were investigated by integrating the PSA process into the plant-wide IGCC simulation using Aspen Plus. On the basis of our analysis, IGCC/warm PSA using our new sorbent can produce slightly higher thermal efficiencies than IGCC/cold Selexol. In order to achieve this, warm PSA needs a narrow range of process parameters to have a good balance between the hydrogen loss, steam consumption and work requirement for CO2 compression. Sensitivity analysis is finally conducted to point out the future direction for making warm syngas cleanup more applicable. Further research is needed toward synthesizing new sorbent materials with higher working capacity and improved mass transfer, a better PSA configuration with higher H2 recovery and less steam consumption, new desulfurization process with reduced H2 consumption, and better heat integration. The development in this research would help further improving the efficiency and economics of IGCC/CCS. Overall, my thesis work provides a rigorous analysis framework for identifying and assessing warm CO2 capture by sorbents in an IGCC system. This adsorbent-based warm CO2 capture technology developed in my work can potentially help make IGCC/CCS more affordable and acceptable.
Author: Zan Liu (Ph. D.)
Publisher:
ISBN:
Category :
Languages : en
Pages : 146
Get Book Here
Book Description
Integrated gasification combined cycle with CO2 capture and sequestration (IGCC-CCS) emerges as one of the most promising technologies for reducing CO2 emission from coal power plant without reducing thermal efficiency significantly. However the high capital cost of these plants has limited their deployment. The current solvent-based low-temperature CO2 capture process (Selexol process) is energy and capital intensive contributing to the problem. Sorbent-based warm CO2 capture has been predicted to be a key enabling technology for lowering down the costs of IGCC-CCS. However, no commercial adsorbents or processes exist for these warm CO2 separations. My thesis work has been devoted to developing a solid sorbent and CO2 capture process which can capture CO2 at an elevated temperature in IGCC system. By combining experimental methods and quantum calculation, I have successfully identified and invented one new sorbent material. The sorbent for warm CO2 capture containing magnesium oxide was developed using incipient wetness impregnation. The reversible adsorption isotherm, cyclic stability, and sorption rate were measured using a custom-built high pressure microbalance system and a thermogravimetric analyzer. Experimental data indicate the sorbent has a fairly large regenerable capacity in 180-240 °C temperature range, fast kinetics, low heat of adsorption, and stable working capacity for at least 84 cycles. The new sorbent performs better than synthetic hydrotalcite and K2CO3-promoted hydrotalcite in the temperature range of interest. To assess the applicability of CO2 removal technology to IGCC via a warm pressure swing adsorption (PSA) process based on our newly invented sorbent which has good cyclic sorption-desorption performance at an elevated temperature, a 16-step warm PSA process was simulated using Aspen Adsorption based on the real sorbent properties. I used the model to fully explore the intercorrelation between hydrogen recovery, CO2 capture percentage, regeneration pressure of sorbent, and steam requirement. Their tradeoff effects on IGCC efficiency were investigated by integrating the PSA process into the plant-wide IGCC simulation using Aspen Plus. On the basis of our analysis, IGCC/warm PSA using our new sorbent can produce slightly higher thermal efficiencies than IGCC/cold Selexol. In order to achieve this, warm PSA needs a narrow range of process parameters to have a good balance between the hydrogen loss, steam consumption and work requirement for CO2 compression. Sensitivity analysis is finally conducted to point out the future direction for making warm syngas cleanup more applicable. Further research is needed toward synthesizing new sorbent materials with higher working capacity and improved mass transfer, a better PSA configuration with higher H2 recovery and less steam consumption, new desulfurization process with reduced H2 consumption, and better heat integration. The development in this research would help further improving the efficiency and economics of IGCC/CCS. Overall, my thesis work provides a rigorous analysis framework for identifying and assessing warm CO2 capture by sorbents in an IGCC system. This adsorbent-based warm CO2 capture technology developed in my work can potentially help make IGCC/CCS more affordable and acceptable.
Author: Yongseung Yun
Publisher: BoD – Books on Demand
ISBN: 9535130056
Category : Technology & Engineering
Languages : en
Pages : 268
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Book Description
Carbon capture and storage (CCS) has been considered as a practical way in sequestering the huge anthropogenic CO2 amount with a reasonable cost until a more pragmatic solution appears. The CCS can work as a bridge before fulfilling the no-CO2 era of the future by applying to large-scale CO2 emitting facilities. But CCS appears to lose some passion by the lack of progress in technical developments and in commercial success stories other than EOR. This is the time to go back to basics, starting from finding a solution in small steps. The CCS technology desperately needs far newer ideas and breakthroughs that can overcome earlier attempts through improving, modifying, and switching the known principles. This book tries to give some insight into developing an urgently needed technical breakthrough through the recent advances in CCS research, in addition to the available small steps like soil carbon sequestration. This book provides the fundamental and practical information for researchers and graduate students who want to review the current technical status and to bring in new ideas to the conventional CCS technologies.
Author: Dariusz Wawrzyńczak
Publisher: CRC Press
ISBN: 1000821730
Category : Nature
Languages : en
Pages : 178
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Book Description
A shift towards implementation of renewable energy has disadvantages, such as power availability, storage capacity, and accompanying costs, and therefore the potential of clean fossil fuel technologies to ensure the stability of electricity generation needs to be reconsidered until these challenges will be overcome. These clean technologies can help prevent the greenhouse effect and, at the same time, guarantee energy security, as coal is a widespread, price-stable raw material that is available in large quantities. This book focuses on the carbon chain, starting from the formation of CO2, through its capture, possible cleaning, to the production of useful products such as dimethylether, methanol, and carbonated cement prefabricates. The comprehensive case study presents the research results of an international team established within the "CCS-CCU technology for carbon footprint reduction using bio-adsorbents" (BIOCO2) project.
Author: National Academies of Sciences, Engineering, and Medicine
Publisher: National Academies Press
ISBN: 0309484529
Category : Science
Languages : en
Pages : 511
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Book Description
To achieve goals for climate and economic growth, "negative emissions technologies" (NETs) that remove and sequester carbon dioxide from the air will need to play a significant role in mitigating climate change. Unlike carbon capture and storage technologies that remove carbon dioxide emissions directly from large point sources such as coal power plants, NETs remove carbon dioxide directly from the atmosphere or enhance natural carbon sinks. Storing the carbon dioxide from NETs has the same impact on the atmosphere and climate as simultaneously preventing an equal amount of carbon dioxide from being emitted. Recent analyses found that deploying NETs may be less expensive and less disruptive than reducing some emissions, such as a substantial portion of agricultural and land-use emissions and some transportation emissions. In 2015, the National Academies published Climate Intervention: Carbon Dioxide Removal and Reliable Sequestration, which described and initially assessed NETs and sequestration technologies. This report acknowledged the relative paucity of research on NETs and recommended development of a research agenda that covers all aspects of NETs from fundamental science to full-scale deployment. To address this need, Negative Emissions Technologies and Reliable Sequestration: A Research Agenda assesses the benefits, risks, and "sustainable scale potential" for NETs and sequestration. This report also defines the essential components of a research and development program, including its estimated costs and potential impact.
Author: Douglas M. Ruthven
Publisher: John Wiley & Sons
ISBN: 9780471866060
Category : Technology & Engineering
Languages : en
Pages : 466
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Book Description
The first up-to-date summary and review for the fundamental principles and industrial practice of adsorption separation processes in more than 30 years. Emphasizes the understanding of adsorption column dynamics and the modeling of adsorption systems, as well as fundamental aspects of kinetics and equilibria.
Author: Gang Li
Publisher:
ISBN:
Category :
Languages : en
Pages : 422
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Book Description
VSA (Vacuum Swing Adsorption) is a promising technology for capturing CO2 which is known to contribute to global warming. Capture of CO2 from flue gas streams using adsorption processes must deal with the prospect of high humidity streams containing bulk CO2 as well as other impurities such as SOx, NOx, etc. However, most studies to date have ignored this aspect of CO2 capture. The major problem caused by water vapour is that water is a much stronger adsorbate than CO2 on most of the polar adsorbents thus drastically reducing the CO2 adsorption capacity. Although the water problem may be tackled by adding a pretreatment drier before the CO2VSA unit, this will result in a large increase of capital and operational cost. Therefore, there is a strong economic motivation to integrate the drying and CO2 recovery in a single VSA process for commercialization of CO2VSA technology.The main purpose of this project is to study the influence of water vapour on the adsorption of CO2 both in the light of fundamentals of adsorption and in the application of post-combustion carbon capture by vacuum swing adsorption experimentally and theoretically. Adsorption equilibria of a CO2/H2O binary mixture were measured on activated alumina F-200 at several temperatures and over a wide range of concentrations from 4% to around 90% relative humidity. In comparison with the single component data, the loading of CO2 was not reduced in the presence of H2O whereas at low relative humidity the adsorption of H2O was depressed. The binary system was described by a competitive/cooperative adsorption model where the readily adsorbed water layers acted as secondary sites for further CO2 adsorption via hydrogen bonding or hydration reactions. The combination of kinetic models namely a Langmuir isotherm for characterizing pure CO2 adsorption and a BET isotherm for H2O was extended to derive a binary adsorption equilibrium model for the CO2/H2O mixture. Models based on the ideal adsorbed solution theory of Myers and Prausnitz failed to characterize the data over the whole composition range and a large deviation of binary CO2/H2O equilibrium from ideal solution behavior was observed. The extended Langmuir-BET (LBET) isotherm, analogous to the extended Langmuir equation, drastically underestimated the CO2 loading. By incorporating the interactions between CO2 and H2O molecules on the adsorbent surface and taking into account the effect of nonideality, the realistic interactive LBET (R-LBET) model was found to be in very good agreement with the experimental data. In contrast, CO2 adsorption on zeolite 13X was entirely depressed at higher water humidity. Direct modification of 13X by silanes increased the hydrophobicity of the adsorbent but also reduced CO2 uptake.A laboratory-scale VSA apparatus was constructed and used to experimentally examine the capture of CO2 from a 10-12% synthetic flue gas stream over a range of water relative humidity. Breakthrough experiments with a binary CO2/H2O mixture in a near-adiabatic double layered 3A/13X column showed a peculiar dual roll-up phenomenon. Water adsorption generated a pure thermal wave which traveled ahead of the water concentration front and swept off the readily adsorbed CO2 leading to a thermal induced roll-up; the slow propagation of the water concentration wave displaced the CO2 by competitive adsorption resulting in n equilibrium induced roll-up. Cyclic VSA experiments with single layered 13X column and multilayered Al2O3/13X column configurations were conducted. The migration of the water and its subsequent impact on capture performance was evaluated. The formation of a water zone creates a "cold spot" which has implications for the system performance. Although the concentration of water leaving the bed under vacuum was high, the low vacuum pressure prevented condensation of this stream. The vacuum pump acted as a condenser and separator to remove bulk water. An important consequence of the presence of a water zone was to elevate the vacuum level thereby reducing CO2 working capacity. On the other hand, the internal purge of CO2 was found to be of critical importance to lower the water partial pressure during evacuation. The penetration of water in the column could be managed by keeping an appropriate volumetric purge-to-feed ratio or a higher vacuum level. This effect was predicted by our axial adiabatic working capacity model. At relatively high water content (> 4% v/v) in the feed, the use of a water prelayer was essential to prevent failure of the system. The overall performance of the VSA with wet feed decreased slightly compared with the performance for dry feed. Reasonable results have been achieved for a triple layered single column VSA in the case with the highest feed humidity of 8.5% v/v, with a product CO2 recovery of 58.2%, purity 52.4% and productivity 0.128 kg CO2/h/L adsorbent. Further scale-up of this process by using multi-columns and a more sophisticated cycle design is expected to further improve the performance. Thus although there is a detrimental effect of water on CO2 capture, long term recovery of CO2 is still possible in a single VSA process.
Author: Mohammad Reza Rahimpour
Publisher: Woodhead Publishing
ISBN: 0128227583
Category : Science
Languages : en
Pages : 574
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Book Description
Advances in Carbon Capture reviews major implementations of CO2 capture, including absorption, adsorption, permeation and biological techniques. For each approach, key benefits and drawbacks of separation methods and technologies, perspectives on CO2 reuse and conversion, and pathways for future CO2 capture research are explored in depth. The work presents a comprehensive comparison of capture technologies. In addition, the alternatives for CO2 separation from various feeds are investigated based on process economics, flexibility, industrial aspects, purification level and environmental viewpoints. - Explores key CO2 separation and compare technologies in terms of provable advantages and limitations - Analyzes all critical CO2 capture methods in tandem with related technologies - Introduces a panorama of various applications of CO2 capture
Author: Shin-ichi Nakao
Publisher: Springer
ISBN: 3030188582
Category : Technology & Engineering
Languages : en
Pages : 83
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Book Description
This book summarises the advanced CO2 capture technologies that can be used to reduce greenhouse gas emissions, especially those from large-scale sources, such as power-generation and steel-making plants. Focusing on the fundamental chemistry and chemical processes, as well as advanced technologies, including absorption and adsorption, it also discusses other aspects of the major CO2 capture methods: membrane separation; the basic chemistry and process for CO2 capture; the development of materials and processes; and practical applications, based on the authors’ R&D experience. This book serves as a valuable reference resource for researchers, teachers and students interested in CO2 problems, providing essential information on how to capture CO2 from various types of gases efficiently. It is also of interest to practitioners and academics, as it discusses the performance of the latest technologies applied in large-scale emission sources.
Author: Qiang Wang
Publisher: Royal Society of Chemistry
ISBN: 1788011082
Category : Science
Languages : en
Pages : 362
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Book Description
An introduction to the different inorganic adsorbents/sorbents used in pre-combustion carbon dioxide capture.
Author: Qiang Wang
Publisher: Royal Society of Chemistry
ISBN: 1788011090
Category : Science
Languages : en
Pages : 318
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Book Description
An introduction to the different inorganic adsorbents/sorbents used in post-combustion carbon dioxide capture.
