Your search keyword '"carbonate looping"' showing total 74 results

1. A carbonator model for CO2 capture based on results from pilot tests. Part I: Hydrodynamics and reactor model

Author

Greco-Coppi, Martin, Ströhle, Jochen, and Epple, Bernd

Published

2024

2. Transforming carbon-intensive coal-fired power plants into negative emission technologies via biomass-fired calcium looping retrofit.

Author

Hanak, Dawid P

Subjects

COAL-fired power plants, CO-combustion, FLUE gases, GREENHOUSE gases, CALCIUM, CARBON taxes

Abstract

Calcium looping is a promising CO2 capture technology due to reduced energy and economic penalties compared to mature solvent scrubbing technologies. It also can enable negative CO2 emissions when biomass is used to drive the sorbent regeneration process in the calciner. However, the trade-off between the energy, economic and environmental performance under different biomass co-firing fractions in the calciner and process operating scenarios has not yet been well understood. This study examined the potential for transforming a 580 MWel coal-fired power plant into a negative CO2 emitter via retrofit of calcium looping with biomass co-firing in the calciner. High-fidelity process models were developed in Aspen Plus and used to analyse the effect of biomass co-firing fraction, CO2 capture rate in the carbonator, and the fraction of flue gas fed to the carbonator on the techno-economic performance indicators. The results revealed that co-firing 30% biomass with coal in the calciner was sufficient for the retrofitted process to achieve negative CO2 emissions (−3.9 gCO2/kWelh). In this scenario, the levelized cost of electricity was 5% lower (81.1 €/MWelh) than that in the reference retrofit scenario without biomass co-firing (85.4 €/MWelh) at a carbon tax of 100 €/tCO2. Further improvement to the techno-economic performance was achieved by reducing the amount of CO2 captured in the carbonator by reducing either the CO2 capture rate (81.1 €/tCO2) or the amount of flue gas processed (80.4 €/tCO2). Although this was achieved at the expense of the increased specific CO2 emissions to 65.2 gCO2/kWelh and 109.0 gCO2/kWelh, respectively, the net specific emissions were still about 90% lower than those of the unabated host plant (792.3 gCO2/kWelh). This study demonstrated that depending on design priorities, biomass co-firing in the calciner can transform the existing coal-fired power plants into negative CO2 emission technologies or improve the process techno-economic viability. [ABSTRACT FROM AUTHOR]

Published

2024

3. Proof of Concept of a Novel Solid–Solid Heat Exchanger Based on a Double L-Valve Concept.

Author

Papalexis, Christos, Stefanitsis, Dionisis, Zeneli, Myrto, Nikolopoulos, Nikolaos, and Tzouganakis, Panteleimon

Subjects

*HEAT exchangers, *PROOF of concept, *FINITE element method, *HEAT transfer, *STRUCTURAL design, *GEOLOGICAL carbon sequestration

Abstract

A proof of concept of a novel parallel-flow solid–solid heat exchanger consisting of two L-Valves with concentric vertical tubes, named as Double L-Valve, is presented for the case of the Carbonate Looping process, as a CO2 capture technology. The operational objective of the solid–solid heat exchanger is to heat up the relatively cold solid stream coming from the carbonator reactor by absorbing heat from the hotter stream coming from the calciner. This novel solid–solid heat exchanger concept has been constructed on a small scale to study the hydrodynamic response of the system experimentally at different designs and airflow rates in its cold state. Based on the experimental data from the small prototype, a scaled-up hydrodynamic model is proposed that provides estimations for the operational requirements at an industrial scale. Apart from the cold flow pilot model, the heat exchanger is being assessed in the current work for an industrial case study in terms of the following: (a) the heat transfer via rigorous one-dimensional thermal modelling, (b) the structural integrity of the design through Finite Element Method (FEM) analysis, and (c) a parametric study for its expected cost. The purpose of this work is to provide a holistic approach of this novel solid–solid heat exchanger concept, the main advantage of which is its simple design and relatively low cost. [ABSTRACT FROM AUTHOR]

Published

2023

4. Negative CO2 emissions in the lime production using an indirectly heated carbonate looping process.

Author

Greco-Coppi, Martin, Hofmann, Carina, Walter, Diethelm, Ströhle, Jochen, and Epple, Bernd

Abstract

Lime is an essential raw material for iron and steel production, in construction and agriculture, in civil engineering, in environmental protection, and in manifold chemical manufacturing processes. To address the problem of unavoidable process CO2 emissions associated with the production of lime, efficient capture technologies need to be developed and implemented. The indirectly heated carbonate looping (IHCaL) process is an efficient candidate for this application because it utilizes lime as the sorbent for the CO2 capture. In this work, a retrofit configuration of this process is presented and analyzed for net negative CO2 emissions. This is done considering different fuels that provide the heat required for the regeneration of the sorbent. The different scenarios were simulated with an AspenPlus® model, key performance indicators were calculated, and the process was compared with other post-combustion capture methods. The results show that net negative CO2 emissions as high as −1805 kgCO2/tCaO, calculated with a state-of-the-art coal power plant energy scenario (ηe = 44.2 %; eref,el = 770 kgCO2/MWhel), can be obtained. This represents an equivalent CO2 avoidance of more than 230% with respect to the reference plant without capture (1368 kgCO2/tCaO). A specific primary energy consumption for CO2 avoided (SPECCA) lower than 1.5 MJLHV/kgCO2,av was achieved for the same energy scenario. Particularly promising results can be accomplished when applying fuels with high biogenic fraction and low specific CO2 emissions, such as solid recovered fuels (SRFs) with a high calorific value. [ABSTRACT FROM AUTHOR]

Published

2023

5. Carbon capture for decarbonisation of energy-intensive industries: a comparative review of techno-economic feasibility of solid looping cycles.

Author

Santos, Mónica P. S. and Hanak, Dawid P.

Abstract

Carbon capture and storage will play a crucial role in industrial decarbonisation. However, the current literature presents a large variability in the techno-economic feasibility of CO2 capture technologies. Consequently, reliable pathways for carbon capture deployment in energy-intensive industries are still missing. This work provides a comprehensive review of the state-of-the-art CO2 capture technologies for decarbonisation of the iron and steel, cement, petroleum refining, and pulp and paper industries. Amine scrubbing was shown to be the least feasible option, resulting in the average avoided CO2 cost of between for the pulp and paper and for the iron and steel industry. Its average equivalent energy requirement varied between 2.7 (iron and steel) and (cement). Retrofits of emerging calcium looping were shown to improve the overall viability of CO2 capture for industrial decarbonisation. Calcium looping was shown to result in the average avoided CO2 cost of between 32.7 (iron and steel) and (cement). Its average equivalent energy requirement varied between 2.0 (iron and steel) and (pulp and paper). Such performance demonstrated the superiority of calcium looping for industrial decarbonisation. Further work should focus on standardising the techno-economic assessment of technologies for industrial decarbonisation. [ABSTRACT FROM AUTHOR]

Published

2022

6. Negative CO2 emissions in the lime production using an indirectly heated carbonate looping process

Author

Greco-Coppi, Martin, Hofmann, Carina, Walter, Diethelm, Ströhle, Jochen, and Epple, Bernd

Published

2023

7. Comparative Kinetic Analysis of CaCO3/CaO Reaction System for Energy Storage and Carbon Capture.

Author

Fedunik-Hofman, Larissa, Bayon, Alicia, and Donne, Scott W.

Subjects

CARBON sequestration, CARBONATION (Chemistry), ENERGY storage, CHEMICAL kinetics, KINETIC control, DIFFUSION control

Abstract

Featured Application: Kinetic parameters for the development of CaCO3/CaO reactor systems for carbon capture and storage and thermochemical energy storage. The calcium carbonate looping cycle is an important reaction system for processes such as thermochemical energy storage and carbon capture technologies, which can be used to lower greenhouse gas emissions associated with the energy industry. Kinetic analysis of the reactions involved (calcination and carbonation) can be used to determine kinetic parameters (activation energy, pre-exponential factor, and the reaction model), which is useful to translate laboratory-scale studies to large-scale reactor conditions. A variety of methods are available and there is a lack of consensus on the kinetic parameters in published literature. In this paper, the calcination of synthesized CaCO3 is modeled using model-fitting methods under two different experimental atmospheres, including 100% CO2, which realistically reflects reactor conditions and is relatively unstudied kinetically. Results are compared with similar studies and model-free methods using a detailed, comparative methodology that has not been carried out previously. Under N2, an activation energy of 204 kJ mol−1 is obtained with the R2 (contracting area) geometric model, which is consistent with various model-fitting and isoconversional analyses. For experiments under CO2, much higher activation energies (up to 1220 kJ mol−1 with a first-order reaction model) are obtained, which has also been observed previously. The carbonation of synthesized CaO is modeled using an intrinsic chemical reaction rate model and an apparent model. Activation energies of 17.45 kJ mol−1 and 59.95 kJ mol−1 are obtained for the kinetic and diffusion control regions, respectively, which are on the lower bounds of literature results. The experimental conditions, material properties, and the kinetic method are found to strongly influence the kinetic parameters, and recommendations are provided for the analysis of both reactions. [ABSTRACT FROM AUTHOR]

Published

2019

8. Techno-economic feasibility assessment of calcium looping combustion using commercial technology appraisal tools.

Author

Michalski, Sebastian, Hanak, Dawid P., and Manovic, Vasilije

Subjects

*GAS power plants, *TECHNOLOGY

Abstract

Abstract Calcium looping combustion (CaLC) is a new class of low CO 2 emission technologies for thermochemical conversion of carbonaceous fuels that can help achieve the emissions reduction targets set out in the Paris Agreement. Compared to mature CO 2 capture technologies, which cause net efficiency penalties higher than 7% points, CaLC results in a net efficiency penalty of 2.9% points. However, a thorough economic assessment of CaLC needs to be undertaken to evaluate its economic viability. The levelised cost of electricity is commonly used to assess the economic performance of clean energy systems. However, this method does not account for commercially important parameters, such as tax, interest, and depreciation charges. This study aimed to improve the reliability and accuracy of economic assessments of clean energy systems by implementing the net present value (NPV) approach. This approach was applied to assess the economic performance of two concepts of the CaLC-based power plant with either the conventional steam cycle (SC) or the supercritical CO 2 cycle (s-CO 2) for heat utilisation along with the bottom-up approach to total capital cost estimation. A parametric study for both concepts was also conducted to assess the impact of the key thermodynamic parameters on the economic performance. Although the s-CO 2 case with revised assumptions was shown to result in a 1%-point lower net efficiency compared to the SC case, its break-even cost of electricity was lower by 0.81 €/MWh. Further improvements of the techno-economic performance can be sought by optimisation of the s-CO 2 cycle structure. Highlights • CaLC-based power plant was assessed using NPV approach. • Bottom-up cost estimation method based on CaLC plant equipment scale was derived. • Bottom-up cost method principals can be used for other clean power systems. • Case study of CaLC plant with steam and supercritical CO 2 cycles was evaluated. • Implementing supercritical CO 2 cycle into CaLC power plant improved the economic performance. [ABSTRACT FROM AUTHOR]

Published

2019

9. Enhancement of a 300 kWth pilot plant for testing the indirectly heated carbonate looping process for CO2 capture from lime and cement industry.

Author

Hofmann, Carina, Greco-Coppi, Martin, Ströhle, Jochen, and Epple, Bernd

Subjects

*CARBON sequestration, *PILOT plants, *CEMENT industries, *WASTE products as fuel, *FLUE gases

Abstract

• Acceleration of the development of a the indirectly heated carbonate looping process. • Detailed process description of the 300kWth pilot plant. • Demonstration in close by semi-industrial conditions for cement and lime. • First-of-a-kind application of waste derived fuels in an IHCaL facility for delivering heat for calcination. The indirectly heated carbonate looping process (IHCaL) is a promising technology for decarbonizing the lime and cement industry. Advantages of the IHCaL are the synergy with these industries using same solid materials and the avoidance of an air separation unit (ASU), since no technical pure oxygen is necessary in this capture process. Former pilot tests showed the feasibility of the IHCaL for applications in the power plant sector. However, the integration of the IHCaL into cement and lime plants, as well as the usability of spent sorbents as educts in these processes, has not yet been proven in industrially relevant conditions. In this study, the modification of an existing 300 kW th pilot plant for demonstrating the IHCaL process are described, aiming in accelerating the demonstration in an industrially relevant environment for cement and lime industries. A flue gas circulation system and a solid fueling system into the combustor, allowing the heat generation for the calcination with e.g. waste derived fuels, have been designed and installed. Results gained during the operation with the modified reactor configuration, are presented in order to assess the performance of the new components in the framework of the IHCaL configuration. The external combustor was operated while co-firing propane with either dried lignite or waste derived fuels. The carbonator was fluidized with a real flue gas from the external combustor, having CO 2 concentrations between 11 and 18 vol-% dry. The results, obtained within more than 200 h of continuous testing with modified reactor configuration, show a good hydrodynamic behavior and adequate reactor performance, while providing a sound basis for further improvement and up scaling of the technology. [ABSTRACT FROM AUTHOR]

Published

2024

10. Cyclic CO2 Capture Performance of Carbide Slag: Parametric Study

Author

Zhang, Deng-Feng, Zhao, Peng-Fei, Li, Song-Geng, Song, Wen-Li, Qi, Haiying, editor, and Zhao, Bo, editor

Published

2013

11. Parametric Study on the CO2 Capture Efficiency of The Carbonate Looping Process in a 10 kW Dual Fluidized Bed

Author

Charitos, Hawthorne, C., Bidwe, A. R., Holz, H., Pfeifer, T., Schulze, A., Schlegel, D., Schuster, A., Scheffknecht, G., Yue, Guangxi, editor, Zhang, Hai, editor, Zhao, Changsui, editor, and Luo, Zhongyang, editor

Published

2010

12. Comparative Kinetic Analysis of CaCO3/CaO Reaction System for Energy Storage and Carbon Capture

Author

Larissa Fedunik-Hofman, Alicia Bayon, and Scott W. Donne

Subjects

kinetics, solid–gas reactions, carbonate looping, calcium looping, thermochemical energy storage, carbon capture and storage, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

The calcium carbonate looping cycle is an important reaction system for processes such as thermochemical energy storage and carbon capture technologies, which can be used to lower greenhouse gas emissions associated with the energy industry. Kinetic analysis of the reactions involved (calcination and carbonation) can be used to determine kinetic parameters (activation energy, pre-exponential factor, and the reaction model), which is useful to translate laboratory-scale studies to large-scale reactor conditions. A variety of methods are available and there is a lack of consensus on the kinetic parameters in published literature. In this paper, the calcination of synthesized CaCO3 is modeled using model-fitting methods under two different experimental atmospheres, including 100% CO2, which realistically reflects reactor conditions and is relatively unstudied kinetically. Results are compared with similar studies and model-free methods using a detailed, comparative methodology that has not been carried out previously. Under N2, an activation energy of 204 kJ mol−1 is obtained with the R2 (contracting area) geometric model, which is consistent with various model-fitting and isoconversional analyses. For experiments under CO2, much higher activation energies (up to 1220 kJ mol−1 with a first-order reaction model) are obtained, which has also been observed previously. The carbonation of synthesized CaO is modeled using an intrinsic chemical reaction rate model and an apparent model. Activation energies of 17.45 kJ mol−1 and 59.95 kJ mol−1 are obtained for the kinetic and diffusion control regions, respectively, which are on the lower bounds of literature results. The experimental conditions, material properties, and the kinetic method are found to strongly influence the kinetic parameters, and recommendations are provided for the analysis of both reactions.

Published

2019

13. Kinetics of Solid-Gas Reactions and Their Application to Carbonate Looping Systems

Author

Larissa Fedunik-Hofman, Alicia Bayon, and Scott W. Donne

Subjects

kinetics, solid-gas reactions, carbonate looping, calcium looping, thermochemical energy storage, carbon capture and storage, Technology

Abstract

Reaction kinetics is an important field of study in chemical engineering to translate laboratory-scale studies to large-scale reactor conditions. The procedures used to determine kinetic parameters (activation energy, pre-exponential factor and the reaction model) include model-fitting, model-free and generalized methods, which have been extensively used in published literature to model solid-gas reactions. A comprehensive review of kinetic analysis methods will be presented using the example of carbonate looping, an important process applied to thermochemical energy storage and carbon capture technologies. The kinetic parameters obtained by different methods for both the calcination and carbonation reactions are compared. The experimental conditions, material properties and the kinetic method are found to strongly influence the kinetic parameters and recommendations are provided for the analysis of both reactions. Of the methods, isoconversional techniques are encouraged to arrive at non-mechanistic parameters for calcination, while for carbonation, material characterization is recommended before choosing a specific kinetic analysis method.

Published

2019

14. Prospects of MgO-based sorbents for CO2 capture applications at high temperatures

Author

Felix Donat and Christoph Müller

Subjects

Chemistry (miscellaneous), Process Chemistry and Technology, Management, Monitoring, Policy and Law, Waste Management and Disposal, Catalysis, CO2 capture, Sorbent, Magnesium oxide, molten salts, Carbonate looping

Abstract

MgO-based materials possess favorable thermodynamic properties that enable them to be used as CO2 sorbents in the temperature range of 300–550 °C — at least theoretically. MgO-based sorbents have seen a boost in activity since the discovery of molten alkali metal salt promoters, and yet, they practically remove CO2 from a gas stream efficiently only at very high pressures (p > 10 bar), rendering them suitable for precombustion, but not for postcombustion CO2 capture schemes. Most of the current performance assessments rely on measurements of the transition between MgO and MgCO3 (or Mg-double carbonates) rather than the ability of the sorbents to actually remove CO2 from a gas stream, which may be misleading regarding their practical use and application. Further, reliable thermodynamic data for sorbents involving Mg-double carbonates is missing, although these materials have large potential for industrial CO2 capture applications.

Published

2022

15. Evaluation of natural limestones quarried in the Czech Republic in terms of their use in carbonate looping.

Author

Staf, Marek, Ciahotný, Karel, and Hlinčík, Tomáš

Subjects

*CARBON dioxide, *FLUE gases, *LIMESTONE, *QUARRIES & quarrying, *SORPTION

Abstract

For effective operation of high-temperature sorption of carbon dioxide from the flue gas in industrial scale, it is necessary to ensure an adequate supply of affordable sorbent having suitable technical parameters. For a given technology, natural limestones meet the condition of low cost. Due to current needs to solve the issue of carbon dioxide capture in power as well as other branches of industry, this study is focused on evaluating different types of natural limestones. A set of laboratory methods for evaluation of the physicochemical properties of limestones was proposed. A laboratory apparatus, based on the principle of fixed bed tubular reactor made of quartz glass, represented the main method for measurement sorption capacities. Within the sample base, a wide spread of sorption capacities was determined in the range of 18.0 - 84.6 % of the theoretical values, based on chemical composition. After six cycles the sorption capacity decreased to 3.5 - 35.6 %, compared to the theoretical value, mainly due to sintering. It was verified that appropriate selection of limestone can significantly reduce degradation of the capacity during cyclic use. [ABSTRACT FROM AUTHOR]

Published

2017

16. Suppression of natural limestones deactivation during cyclic carbonation-decarbonation process in CCS technology.

Author

Staf, M., Ciahotny, K., Jilkova, L., and Vrbova, V.

Subjects

LIMESTONE, CARBON dioxide adsorption, CALCIUM carbonate, CARBONATION (Chemistry), PURIFICATION of flue gases

Abstract

The paper summarizes sorption properties of limestones with variable content of calcium carbonate. Changes of sorption capacities during cyclic calcinations and carbonations were investigated using laboratory apparatus with vertical quartz reactor. Application of suitably chosen limestones and process conditions offered sustainable capacity up to 11 kg CO2 / 100 kg of initial limestone. Method of reactivation of the spent limestone using a gas saturated by water vapor was proposed to eliminate decreasing of the capacity in the carbonate looping process. [ABSTRACT FROM AUTHOR]

Published

2016

17. Prospects of MgO-based sorbents for CO2 capture applications at high temperatures

Author

Donat, Felix and Müller, Christoph R.

Subjects

Carbonate looping, Sorbent, molten salts, CO2 capture, Magnesium oxide

Abstract

MgO-based materials possess favorable thermodynamic properties that enable them to be used as CO2 sorbents in the temperature range of 300–550 °C — at least theoretically. MgO-based sorbents have seen a boost in activity since the discovery of molten alkali metal salt promoters, and yet, they practically remove CO2 from a gas stream efficiently only at very high pressures (p > 10 bar), rendering them suitable for precombustion, but not for postcombustion CO2 capture schemes. Most of the current performance assessments rely on measurements of the transition between MgO and MgCO3 (or Mg-double carbonates) rather than the ability of the sorbents to actually remove CO2 from a gas stream, which may be misleading regarding their practical use and application. Further, reliable thermodynamic data for sorbents involving Mg-double carbonates is missing, although these materials have large potential for industrial CO2 capture applications., Current Opinion in Green and Sustainable Chemistry, 36

Published

2022

18. Design and operation of a 300 kWth indirectly heated carbonate looping pilot plant.

Author

Reitz, Michael, Junk, Markus, Ströhle, Jochen, and Epple, Bernd

Subjects

CARBONATES, PILOT plants, CARBON sequestration, CALCINATION (Heat treatment), HEAT transfer

Abstract

Carbonate looping or calcium looping (CaL) is an efficient post-combustion CO 2 -capture technology particularly suited for retrofitting existing power plants. Limestone, an inexpensive and highly available natural product, is utilized for the CaL process. A new concept with an indirectly heated calciner is presented, where the heat for calcination is transferred by means of heat pipes from an external combustor. This process modification offers higher plant efficiencies and lower CO 2 avoidance costs than an oxy-fired CaL process. The worldwide first indirectly heated CaL pilot plant with a nominal power of 300 kW th has been erected at Technische Universität Darmstadt. This paper presents the layout of the pilot plant and first operational results using a natural limestone as sorbent and propane as fuel for the external combustor. The calciner was fluidized with air to support self-fluidization of the sorbent during calcination and to lower the partial CO 2 pressure and therewith the calcination temperature. Proof of concept was demonstrated within more than 400 h continuous testing. The reactor system showed good hydrodynamic stability, and the heat pipe heat exchanger an excellent performance. CO 2 capture rates up to 90% in the carbonator were reached. [ABSTRACT FROM AUTHOR]

Published

2016

19. Technical and Economical Assessment of the Indirectly Heated Carbonate Looping Process.

Author

Junk, Markus, Reitz, Michael, Ströhle, Jochen, and Epple, Bernd

Subjects

*CARBONATES, *CARBONIC acid, *CARBON sequestration, *CARBON dioxide mitigation, *SEQUESTRATION (Chemistry)

Abstract

Carbonate looping promises low energy penalties for postcombustion CO2-capture and is particularly suited for retrofitting existing power plants. To further improve the process, a new concept with an indirectly heated calciner using heat pipes was developed, offering even higher plant efficiencies and lower CO2 avoidance costs than the oxy-fired standard carbonate looping process. The concept of the indirectly heated carbonate looping (1HCL) process was tested at sufficient scale in a 300 kWth pilot plant at Technische Universität Darmstadt. The paper presents a technical overview of the process and shows first test results of the pilot plant. Furthermore, the concept is economically evaluated and compared to other carbon capture processes. [ABSTRACT FROM AUTHOR]

Published

2016

20. Reactivity of CaO with CO2 in molten CaF2-NaF: formation and decomposition of carbonates.

Author

Tomkute, Viktorija, Solheim, Asbjørn, Sakirzanovas, Simas, and Olsen, Espen

Subjects

*GIBBS' energy diagram, *SORPTION, *CARBON dioxide adsorption, *LIME (Minerals), *CARBONATION (Chemistry)

Abstract

The characteristics of CO2 reacting with CaO in a molten eutectic mixture of CaF2 and NaF has been investigated. Calculations of the Gibbs free energy, temperature analysis of the decomposition of the formed carbonates, and XRD analyses of quenched samples taken during CO2 absorption or desorption were employed to identify the phases present in the melt. Efficient CO2 absorption from a simulated flue gas was observed, due to a combined reaction where CaO initially reacts with CO2 and forms CaCO3. Subsequently, Na2CO3 is formed by an ion exchange reaction between CaCO3 and NaF. It was found that the CaO activity is highest in the temperature range 826-834°C. Increasing the CaO concentration from 5 to 20 wt% in the molten salt resulted in reduced CO2 reactivity efficiency, probably because of precipitation and agglomeration of the sorbent. The total carbonation conversion was independent of the CO2 concentration in the inlet gas, and the sorbent carrying capacity was in the range 0.722-0.743 g CO2/g CaO corresponding to 0.037-0.144 g CO2/g total liquid. Decarbonation was conducted by raising the temperature. 40% conversion back to CaO was recorded at 1160°C. The recorded curves for the CO2 concentration in the outlet gas exhibited a rapid desorption step followed by a slow step. [ABSTRACT FROM AUTHOR]

Published

2016

21. Carbonate Looping For Intermediate Temperature Co2 Capture: Evaluating The Sorption Efficiency Of Mineral-Based Mgo Promoted With Caco3 And Alkali Nitrates

Author

Papalas, Theodoros, Antzaras, Andy N., and Lemonidou, Angeliki A.

Subjects

Carbonate looping, MgO-based sorbent, Molten salt promoter, In-situ XRD, CO2 capture, Teknologi: 500 [VDP]

Abstract

This work focused on enhancing the CO2 capture kinetics of magnesite-derived MgO via alkali nitrate and mineral CaCO3 promoters for its application in the Carbonate Looping technology at intermediate temperatures (≤400°C). Alkali salts had a prominent role by shifting into molten state to offer a favorable carbonation pathway and allow a significantly higher CO2 uptake than non-promoted MgO, while their synergy with CaCO3 bestowed even better sorption activity. MgCO3 and CaMg(CO3)2 were detected as the main carbonate products, with the latter exhibiting faster formation rate. The sorbent with CaCO3 and alkali salts to MgO molar ratios of 0.05 and 0.20 respectively attained an uptake of 7.2 moles CO2/kg of sorbent when exposed to a 30%CO2 flow at 300°C with only 6% activity loss after 50 carbonation cycles, proving the applicability of the materials. Despite the cyclic sorption activity loss due to sintering and dewetting, alkali salts redistribution enabled a stable performance under proper conditions.

Published

2021

22. Alstom's Regenerative Calcium Cycle - Norcem Derisking Study: Risk Mitigation in the Development of a 2nd Generation CCS Technology.

Author

Balfe, Michael C., Augustsson, Ola, Tahoces-soto, Raul, and Bjerge, Liv-Margrethe H.

Abstract

Alstom is a pioneer and industrial leader in the development of post combustion CCS technologies. Alstom's Regenerative Calcium Cycle (RCC) is a 2 nd generation post combustion CCS technology utilizing a calcination/ carbonation loop to capture CO 2 from flue gas at high temperatures. The CO 2 capture cycle is driven by introducing heat required to regenerate sorbent at 900 °C (4.0 GJ/t CO 2 , chemically bound CO 2 ) the regenerated sorbent is then used for CO 2 capture from flue gas where the exothermic heat of the reverse reaction (-4.0 GJ/t CO 2 captured) is recovered in a power cycle. Due to the option of using natural sorbent materials (limestone), RCC also provides attractive integration opportunities with industrial processes such as cement production. Recently indirectly fired RCC calcination concepts also open the door for game changing performance gains using natural or even synthetic materials. However, the wide range of performance variability characteristic of natural sorbents contributes to uncertainty in defining process performance. Reliable sorbent deactivation models, which describe both cyclic and chemical deactivation, in combination with mechanistic reactor models which predict gas and solids phase conversions are required to lower the uncertainty associated with new reactor concepts and larger geometries required for commercialization for retrofit power-plant flue gas or for integrated solutions for the cement industry. Parallel to RCC process development, Alstom is currently executing a “Derisking” or risk-mitigation study for Norcem, a Norwegian cement producer, who seeks to take a leading position in the development of technologies for CO 2 -capture from cement production facilities. Norcem is currently heading up a project on behalf of the European cement industry (partners are Norcem, HeidelbergCement and the European Cement Research Academy) investigating various technological options at the pilot scale. In relation to this project, Alstom's RCC technology was selected with the objective to define process performance and the associated uncertainty. Pilot testing was conducted at the Institute of Combustion and Power Plant Technology at the University of Stuttgart (IFK) planned by Alstom focusing on the validation of process models and less the targeting of pilot plant performance, which is often limited by reactor geometries. This paper discusses the characterization of sorbent performance and the gap between the performance expected from thermo- gravimetric analysis (TGA) and that realized during steady state pilot testing under representative operating conditions. Operational stability, material balance closure and the confirmation of sorbent attrition characteristics from pilot testing are also discussed and steady-state operational data, gained from pilot testing are applied to initialize mechanistic process models which allow prediction of reactor performance for larger more efficient designs. [ABSTRACT FROM AUTHOR]

Published

2014

23. Development of the calcium looping CO2 capture technology from lab to pilot scale at IFK, University of Stuttgart.

Author

Dieter, Heiko, Bidwe, Ajay R., Varela-Duelli, Glykeria, Charitos, Alexander, Hawthorne, Craig, and Scheffknecht, Günter

Subjects

*CALCIUM, *CARBON dioxide, *SIMULATION methods & models, *HYDRODYNAMICS, *PILOT projects

Abstract

Highlights: [•] Overview of the R&D work done at IFK, Uni Stuttgart with Calcium Looping (CaL). [•] Economic, simulation, demonstration, hydrodynamic and kinetic studies of CaL performed. [•] In house design and construction of DFB pilot plants based on CaL. [•] Successful demonstration of CaL in the 10kWth and 200kWth DFB pilot plants. [•] Carbonator and regenerator characterization from 10kWth DFB plant. [Copyright &y& Elsevier]

Published

2014

24. NGCC post-combustion CO2 capture with Ca/carbonate looping: Efficiency dependency on sorbent properties, capture unit performance and process configuration.

Author

Berstad, David, Anantharaman, Rahul, Blom, Richard, Jordal, Kristin, and Arstad, Bjørnar

Subjects

CARBON sequestration, CARBONATES, SORBENTS, BIOMASS burning, SIMULATION methods & models

Abstract

Highlights: [•] Simulations of NGCC cycle with post-combustion CO2 capture by carbonate looping. [•] Sorbent review with respect to sorption capacity and semi-empirical model fit. [•] Calciner energy requirement investigated for natural and synthetic sorbents. [•] Power cycle simulations including CO2 capture and compression units. [•] Prerequisites for high efficiency quantified on material and process level. [Copyright &y& Elsevier]

Published

2014

25. Supercritical CO2 cycle for coal-fired power plant based on calcium looping combustion

Author

Vasilije Manovic, Sebastian Michalski, and Dawid P. Hanak

Subjects

Rankine cycle, Power station, 0211 other engineering and technologies, 02 engineering and technology, Combustion, techno-economic analysis, law.invention, 020401 chemical engineering, law, Heat recovery ventilation, 021108 energy, 0204 chemical engineering, Cost of electricity by source, Process engineering, Calcium looping, Fluid Flow and Transfer Processes, business.industry, advanced power cycles, carbonate looping, CO2 capture, Supercritical fluid, heat recovery, Environmental science, solid looping cycles, Electricity, business

Abstract

Calcium looping combustion (CaLC), which comprises an indirectly-heated calciner, is characterised with lower energy intensity and economic penalties compared to that of mature CO2 capture technologies. As CaLC is a standalone power boiler, integration of advanced power cycles can lead to further improvement in net efficiency and reduction in the cost of electricity. Therefore, this study aimed to propose routes for the integration of the supercritical CO2 cycle (sCO2) with CaLC and to evaluate their benefits with respect to the conventional steam cycle. Such processes were modelled in Aspen Plus™. Moreover, the effect of the operating conditions on the techno-economic performance of the considered cases was evaluated. This study has shown that implementation of the optimised recompression sCO2 cycle with a clean gas cooler resulted in the net efficiency and break-even price of electricity of 37.3%HHV and 75.13 €/MWh, respectively. These are 0.7%HHV points lower and 26% higher, respectively, than that of the conventional coal-fired power plant without CO2 capture. Such performance, however, is superior to retrofits of coal-fired power plants with mature CO2 capture technologies as well as CaLC with a conventional steam cycle, proving the benefits of linking CaLC with advanced power cycles.

Published

2020

26. Self-Fluidization in an Indirectly Heated Calciner.

Author

Hoeftberger, D. and Karl, J.

Subjects

*FLUIDIZATION, *CARBONATION (Chemistry), *CALCINATION (Heat treatment), *LIMESTONE, *CARBON sequestration, *HEAT pipes, *FLUIDIZED-bed combustion

Abstract

A promising way to reduce CO2 emissions of fossil-fired power plants is the carbonate looping process with the reversible carbonation-calcination reaction of limestone. The focus is on the gas release in an indirectly heat pipe-heated calciner. Experiments in an electrically heated lab-scale batch calciner demonstrated that transition from a fixed bed to a bubbling fluidized bed is possible without an external fluidization agent only by heating up limestone. Several indirectly heated calciner concepts are presented. [ABSTRACT FROM AUTHOR]

Published

2013

27. Thermodynamic Evaluation and Cold Flow Model Testing of an Indirectly Heated Carbonate Looping Process.

Author

Junk, M., Reitz, M., Ströhle, J., and Epple, B.

Subjects

*CARBON sequestration, *CHEMICAL-looping combustion, *HEAT pipes, *LIMESTONE, *CARBON dioxide mitigation

Abstract

Carbon capture with subsequent compression and storage is a promising possibility for the reduction of CO2 emissions from coal-fired power generation. A very efficient post-combustion CO2 capture technology is the carbonate looping process. To further increase the process efficiency, a new concept is considered where the heat for calcination is transferred from an external combustor to the calciner by means of heat pipes. Some thermodynamic evaluations for a retrofit of a coal-fired host plant with the indirectly heated carbonate looping process and cold flow model tests of a 300-kWth test facility that will be erected in 2013 in Darmstadt are presented. [ABSTRACT FROM AUTHOR]

Published

2013

28. Progress in Calcium Looping Post Combustion CO2 Capture: Successful Pilot Scale Demonstration.

Author

Dieter, Heiko, Hawthorne, Craig, Zieba, Mariusz, and Scheffknecht, Günter

Abstract

Abstract: The development of Calcium-Looping for CO2 capture has made vast progress in recent time. The technology has become a serious option for CO2 capture from fossile fuel fired power plants. Calcium-Looping is a highly efficient process which uses broadly available natural limestone as a CO2 sorbent. The process uses the reversible reaction (CaCO3 ↔CaO+CO2) between calcium carbonate and calcium oxide in the temperature range of 650 and 900°C. This publication presents the results of the work done at IFK to demonstrate the Calcium-Looping process in pilot scale at realistic process conditions. The first experimental campaings with the 200 kWth Dual Fluidized Bed (DFB) Facility have shown hydrodynamic stability as well as high flexibility in operation. CO2 capture efficiencies above 90% were achieved consistently over a broad range of process conditions during multiple hours of operation. The presence of water vapor, which is found naturally in flue gas, was found to significantly improve the CO2 capture efficiency. Sorbent attrition measurements fell within a reasonable range, giving confidence that attrition will not be a major restraint for Calcium Looping. [Copyright &y& Elsevier]

Published

2013

29. Self-activation and effect of regeneration conditions in CO2–carbonate looping with CaO–Ca12Al14O33 sorbent

Author

Stendardo, S., Andersen, L.K., and Herce, C.

Subjects

*ACTIVATION (Chemistry), *ALUMINUM oxide, *METAL absorption & adsorption, *CARBON sequestration, *COMBUSTION gases, *CARBON dioxide adsorption, *TEMPERATURE effect

Abstract

Abstract: CO2 capture by solid sorbents through uptake–regeneration cycling is a promising option for high temperature removal of CO2 from combustion gases and synthesis/fuel gases. The present study investigates the influence of regeneration atmosphere and temperature on the CO2 uptake capacity during repeated cycling of CaO-based solid sorbents. The sorbents were synthesised to contain 75 and 85% w/w of active phase (CaO) and binder (Ca12Al14O33) and were then subjected to cycling tests with repeated CO2 uptake and release in a thermogravimetric analyser TGA for up to 200 cycles. Test conditions were chosen to test high temperature CO2 capture at 600°C in an atmosphere containing 14 and 25% v/v CO2 (N2 balance). Three different regeneration conditions were tested: [(a)] mild condition: regeneration at 900°C in 14% CO2 or 100% N2; [(b)] moderate condition: regeneration at 1000°C in 14% CO2; and [(c)] severe condition: regeneration at 1000°C in 86% CO2. Hydration of the sorbent during synthesis and prolonged carbonation prior to the cycling tests significantly improved the stability of the uptake capacity. Interestingly, the pretreated 75% w/w CaO synthetic sorbent maintained a good uptake capacity up to the 150th cycle under severe regeneration conditions and even showed continuously increasing CO2 uptake capacity throughout the 150 cycle test with 25% CO2. The 75% w/w CaO sorbent is thus an interesting candidate for future work on high temperature CO2 capture. [Copyright &y& Elsevier]

Published

2013

30. Lime enhanced biomass gasification. Energy penalty reduction by solids preheating in the calciner

Author

Martínez, Ana, Pröll, Tobias, and Romeo, Luis M.

Subjects

*BIOMASS gasification, *HYDROGEN production, *CARBON sequestration, *GREENHOUSE gases, *TEMPERATURE effect, *CHEMICAL reactions, *ENERGY consumption, *SEPARATION (Technology)

Abstract

Abstract: Hydrogen is expected to be one of the most important energy carriers in the future. Gasification process may be used to produce hydrogen when joined with carbon capture technologies. Furthermore, the combination of biomass gasification and carbon capture presents a significant technical potential in net negative greenhouse gas emissions. Lime enhanced biomass gasification process makes use of CaO as a high temperature CO2 carrier between the steam biomass gasifier and an oxy-fired regenerator. Important energy penalties derive from the temperature difference between the reactors (around 250–300 °C). A cyclonic preheater similar to those used in the cement industry may improve the energetic efficiency of the process if the particles entering the regenerator reactor are heated up by the gas leaving this reactor. A lime enhanced biomass gasification system was modelled and simulated. A cyclonic preheater was included to evaluate the improvement. Results show an increase of the gasification chemical efficiency and a reduction of the energy consumption in the regenerator. [Copyright &y& Elsevier]

Published

2012

31. H2 production with CO2 capture by sorption enhanced chemical-looping reforming using NiO as oxygen carrier and CaO as CO2 sorbent

Author

Rydén, Magnus and Ramos, Pedro

Subjects

*HYDROGEN production, *CARBON sequestration, *LIME (Minerals), *SORBENTS, *HYDROCARBONS, *NICKEL compounds, *THERMODYNAMICS, *FLUIDIZED-bed furnaces

Abstract

Abstract: A novel process for conversion of hydrocarbons to H2 has been examined. The process, sorption enhanced chemical-looping reforming, involves three interconnected reactor vessels. In the reforming reactor, hydrocarbon fuel is partially oxidized with oxygen provided via a solid oxygen carrier such as NiO. Resulting CO is shifted instantly to CO2 via sorption enhanced water–gas shift, facilitated by the capturing of CO2 with a solid CO2 sorbent such as CaO. Ni and CaCO3, are regenerated downstream in separate reactors. The process produces H2, CO2 and N2 of reasonable purity in separate streams, without need for additional gas separation equipment. The characteristics of the process have been examined by thermodynamic calculations and by process modeling. At 1bar it could produce >2.8mol H2 with a purity of >98vol.% for each mol CH4 added as fuel, while capturing >95% of added carbon as CO2. Increasing the pressure reduces the performance due to lower conversion of CH4. Involved reactions have also been examined in a fluidized-bed reactor at 600–750°C, with particles of NiO and CaO as bed material and CH4 mixed with steam as fuel. The CH4 conversion was incomplete but the results fitted with theory and gas with a H2/(H2 +CO+CO2) ratio of more than 98% was produced at 600°C. [Copyright &y& Elsevier]

Published

2012

32. Modeling the carbonator of a Ca-looping process for CO2 capture from power plant flue gas

Author

Romano, Matteo C.

Subjects

*CARBON dioxide, *CALCIUM, *FLUE gases, *GREENHOUSE gases, *LIME (Minerals), *COAL ash, *PROCESS optimization, *POWER plants

Abstract

Abstract: The calcium-looping process is a promising technique for CO2 capture from coal-fired power plants and for reducing GHG emissions from the power generation sector. This paper presents a calculation model of the carbonator, the key reactor of the Ca-looping process, where CO2 is captured as a result of its reaction with CaO. The model presented is based on the Kunii–Levenspiel theory for circulating fluidized bed and on the recent findings on the properties of CaO as a CO2 sorbent, while taking into account the effects of coal ash and sulfur species. This model can be used for process optimization and for the prediction of the performance of power plants based on the Ca-looping process. Also presented in this paper are the results of a sensitivity analysis of the primary parameters that influence the performance of the carbonator. These results confirm the feasibility of the Ca-looping process with reactors of reasonable size for industrial applications and highlight the importance of the properties of the Ca-based sorbent as they highly affect the carbonator''s performance. [Copyright &y& Elsevier]

Published

2012

33. A novel IGCC plant with membrane oxygen separation and carbon capture by carbonation–calcinations loop.

Author

Kunze, Christian, De, Sudipta, and Spliethoff, Hartmut

Subjects

INTEGRATED gasification combined cycle power plants, POWER plants, INDUSTRIAL pollution, CARBONATES, OXYGEN, SEPARATION (Technology), CARBON sequestration, GREENHOUSE gas mitigation, ENVIRONMENTAL degradation, EMISSIONS (Air pollution), POLLUTANTS, CARBON dioxide

Abstract

Abstract: Environmental degradation due to large emission of pollutants including green house gases from conventional coal based power plants is presently of great concern. On the other hand, existing dependence on the coal based power plants to meet the increasing electricity demand cannot be changed abruptly. Hence developing efficient coal based power plants with low emissions is of great demand. IGCC plants are established technologies for this purpose. However, CO2 capture still causes substantial reduction in efficiency. In this paper, a novel IGCC plant integrating oxygen separation from air by ceramic membrane and post combustion CO2 capture by a twin fluidized bed carbonation–calcinations loop has been proposed. A simulation of this conceptualized plant shows significant increase in efficiency than a comparable IGCC plant with conventional pre-combustion capture. The new IGCC concept reached a net efficiency of 43.2% based on LHV for hard coal. Furthermore, the concept allows CO2 recovery of almost 98% resulting in substantially lower specific CO2 emissions of 22.1g/kWh. A complete description of the plant and detailed simulation results in comparison with the previous IGCC plant are discussed. Additionally, a short parametric study is performed to demonstrate basic process interaction and further thermodynamic potential. [Copyright &y& Elsevier]

Published

2011

34. Synthetic CaO-based sorbent for CO2 capture.

Author

Florin, Nicholas and Fennell, Paul

Subjects

CARBON sequestration, SORBENTS, FLUE gases, ALUMINUM oxide, THERMOGRAVIMETRY, PRECIPITATION (Chemistry), CARBONATES

Abstract

Abstract: The capture and purification of carbon dioxide (CO2) from flue or fuel gas underlies the cost efficiency of carbon capture and storage (CCS) applications in the power and industrial sectors and there is considerable scope for cost reduction with the development of novel capture technologies. High-temperature sorbents are seen as a “next-generation” technology and a promising candidate is calcium oxide (CaO) derived from natural limestone, which is used in a process known as carbonate looping. This process exploits the reversible reaction between CaO and CO2 to form calcium carbonate (CaCO3). Unfortunately, sorbent derived from natural limestone loses its capacity to capture CO2 through long-term cycling, and a large amount of fresh limestone is required to maintain an acceptable CO2 capture efficiency. This work describes the development and characterisation of synthetic CaO-based sorbents, such as those incorporating a mixed calcium-aluminium oxide binder—in this case produced by precipitation in a slurry bubble column. Reactivity tests using a thermogravimetric analyser (TGA) demonstrate the improved long-term CO2 uptake of the synthetic sorbent. The highest CO2 uptake observed after 30 cycles was achieved with 85 wt.% CaO and binder, which was three times higher than the observed capacity of a natural limestone (Havelock). However, contrary to TGA results, experimental results for reactivity tests conducted using a bench-scale fluidised bed reactor (FBR) showed the highest uptake for the precipitated sorbent with no binder. A decrease in uptake was observed corresponding an increase in binder loading from 0–25 wt.%, which was coupled with an increase in mass loss owing to elutriation, attributed to decrepitation during cycling. [Copyright &y& Elsevier]

Published

2011

35. Carbon dioxide capture from combustion flue gases with a calcium oxide chemical loop. Experimental results and process development.

Author

Alonso, M., Rodríguez, N., González, B., Grasa, G., Murillo, R., and Abanades, J.C.

Subjects

CARBON sequestration, FLUE gases, LIME (Minerals), COMBUSTION, FLUIDIZED-bed combustion, COAL-fired power plants, PILOT plants

Abstract

Abstract: Post-combustion carbonate looping processes are based on the capture of carbon dioxide from the flue gases of an existing power plant in a circulating fluidized bed reactor (CFB) of calcium oxide (the carbonator) particles. The calcination of calcium carbonate in a new oxy-fired CFBC power plant regenerates the sorbent (calcium oxide particles) and obtains high purity carbon dioxide. This communication presents experimental results from a small test facility (30kWt) operated in continuous mode using two interconnected CFB reactors as carbonator and calciner. Capture efficiencies between 70 and 97% have been obtained under realistic flue gas conditions in the carbonator reactor (temperatures around 650°C). The similarity between process conditions and those existing in CFBC power plants should allow a rapid scaling up of this technology. The next steps for this process development are also outlined. [Copyright &y& Elsevier]

Published

2010

36. Simulation of the carbonate looping power cycle.

Author

Hawthorne, C., Trossmann, M., Galindo Cifre, P., Schuster, A., and Scheffknecht, G.

Subjects

CARBON sequestration, COMBUSTION, RANKINE cycle, CARBONATES, SEPARATION of gases, FLUE gases, COAL-fired power plants, SIMULATION methods & models

Abstract

Abstract: Carbonate Looping is a promising post-combustion capture process involving the separation of CO2 from the flue gas of a coalfired power plant at high temperatures (600–700 ∘C) using the reversible exothermic CaO carbonation reaction and the endothermic calcination reaction of CaCO3. The core of the carbonate looping process is a dual fluidized bed reactor in which the CO2 acceptor material (CaO) is transported between the carbonator (CO2 absorption) and regenerator (CO2 desorption). Due to the heat requirements for the regenerator, the carbonate looping acts as a CO2 separation unit and an add-on power plant, thereby offering the opportunity for increasing the site electricity production while inflicting only a low electric efficiency penalty on the total power plant. However, the quantity and quality of the Carbonate Looping heat sources differ significantly from a conventional coal-fired power plant. This paper presents the design and simulation of the carbonate looping steam cycle for a large coal-fired plant. The simulation involves the coupling of the carbonate looping reactor model from Aspen Plus with the steam cycle in EBSILON Professional code which is a mass and energy balance cycle calculation program specifically tailored for steam cycle calculations. The resulting simulation includes penalty deduction for the Air Separation Unit and the CO2 conditioning unit, resulting in a net efficiency of 39.2% and while increasing the net power input from 1052 MWe to 1533 MWe, an addition of 481 MWe for the retrofitted power plant. [Copyright &y& Elsevier]

Published

2009

37. Feasibility study on the carbonate looping process for post-combustion CO2 capture from coal-fired power plants.

Author

Ströhle, Jochen, Galloy, Alexander, and Epple, Bernd

Subjects

CARBON sequestration, COMBUSTION, CARBONATES, COAL-fired power plants, RETROFITTING, LIME (Minerals), FLUIDIZED reactors, MASS transfer

Abstract

Abstract: The Carbonate Looping process is a promising technology for post-combustion CO2 capture from power plants by means of CaO in a system of two fluidized bed reactors. The present study focuses on the retrofit with re-powering of an existing 1052 MWel coal-fired power plant. Material and energy balances of the process have been performed using ASPEN PLUS. The effect of make-up mass flow on circulating flow, coal feed to the calciner, electrical output, net plant efficiency, and CO2 capture efficiency is discussed. The energy penalty of 2.75% points is much lower than that of other CO2 capture technologies. [Copyright &y& Elsevier]

Published

2009

38. Capturing CO2 from combustion flue gases with a carbonation calcination loop. Experimental results and process development.

Author

Abanades, J.C., Alonso, M., Rodríguez, N., González, B., Grasa, G., and Murillo, R.

Subjects

CARBON sequestration, COMBUSTION, FLUE gases, CHEMICAL reactions, FLUIDIZED reactors, CHEMICAL processes, CHEMISTRY experiments, COGENERATION of electric power & heat

Abstract

Abstract: Post-combustion carbonate looping processes are based on the capture of CO2 from the flue gases of an existing power plant in a circulating fluidized bed (CFB) reactor of CaO (the carbonator) at around 650 ∘C. The calcination of CaCO3 in a new oxy-fired experimental results from a small test facility (30 kWt) operated in continuous mode using two interconnected CFB reactors as carbonator and calciner. Capture efficiencies between 70 and 97% have been obtained under realistic flue gas conditions in the carbonator reactor. The similarity between process conditions and those existing in CFBC power plants should allow a rapid scaling up of this technology. [Copyright &y& Elsevier]

Published

2009

39. Magnesite-derived MgO promoted with molten salts and limestone as highly-efficient CO2 sorbent.

Author

Papalas, Theodoros, Antzaras, Andy N., and Lemonidou, Angeliki A.

Subjects

FUSED salts, CARBON dioxide adsorption, CARBON dioxide, LIMESTONE, MAGNESIUM oxide, CARBONATION (Chemistry)

Abstract

[Display omitted] • Mineral MgO promoted with CaCO 3 and molten salts shows promise for carbonate looping. • Faster sorption rate is enabled with elevated molten salt and lower CaCO 3 contents. • Higher molten salt loadings lead to more severe sintering and cyclic activity loss. • Extended carbonation conversion enhances cyclic operation and counteracts sintering. • Long sorption duration or low temperature with 30 % CO 2 flow improves stability. This study evaluated the CO 2 capture performance of MgO obtained from mineral magnesite and doped with limestone and molten Li, Na and K nitrates under consecutive sorption/desorption cycles via thermogravimetric analysis. Increasing the molten promoter loading resulted in a higher CO 2 sorption rate, while elevated CaCO 3 amounts impeded CO 2 diffusion. When exposed to a 30 % CO 2 flow at 300 °C for 30 min, the sorbent with alkali salts and CaCO 3 to MgO molar ratios of 0.20 and 0.05 respectively attained a capture of 7.2 mol CO 2 /kg of sorbent and a negligible activity loss (∼6%) after 50 cycles. This performance was promising, considering the mineral nature of precursors. In-situ X-ray diffraction revealed the growth of the MgO crystal after each desorption, proving the gradual MgO sintering. However, the morphological transformations occurring during cyclic operation and especially if high conversions of MgO are reached, trigger an alkali salt redistribution that grants high stability. [ABSTRACT FROM AUTHOR]

Published

2021

40. Advanced power cycles for coal-fired power plants based on calcium looping combustion: A techno-economic feasibility assessment

Author

Sebastian Michalski, Vasilije Manovic, and Dawid P. Hanak

Subjects

Rankine cycle, Power station, Combined cycle, 020209 energy, 02 engineering and technology, Management, Monitoring, Policy and Law, law.invention, 020401 chemical engineering, clean power technologies, law, 0202 electrical engineering, electronic engineering, information engineering, Carbon capture and storage, 0204 chemical engineering, Process engineering, Calcium looping, Clean coal, business.industry, carbon capture, Mechanical Engineering, Building and Construction, carbonate looping, clean coal, Brayton cycle, General Energy, Electricity generation, advanced power generation, Environmental science, business, efficiency penalty

Abstract

Carbon capture and storage is crucial to decarbonising the power sector, as no other technology can significantly reduce emissions from fossil fuel power generation systems. Yet, the mature CO2 capture technologies result in net efficiency penalties of at least 7% points. Emerging technologies, such as calcium looping combustion, can reduce the net efficiency penalty to 2.4% points. Further reductions can be achieved by replacing the conventional steam cycle with advanced power cycles. This study aimed to assess the techno-economic feasibility of the coal-fired power plant based on calcium looping combustion with different advanced Brayton cycles. These included single power cycles, such as recompression supercritical CO2, simple supercritical CO2 cycle, and xenon cycle, as well as combined power cycles based on helium, nitrogen and recompression supercritical CO2 cycles. The net efficiency and break-even electricity price, which was estimated using the net present value method, were used as the key techno-economic performance indicators. A parametric study was also conducted to assess the impact of the key thermodynamic parameters. This study showed that the case based on a single recompression supercritical CO2 cycle had the best overall techno-economic performance, while the recompression supercritical CO2 combined cycle case had the best techno-economic performance among combined cycle cases. The former was characterised with a net efficiency of 38.9%, which is higher than that of the reference coal-fired power plant without CO2 capture (38.0%). Such performance was achieved at a break-even electricity price of 71.2 €/MWel,neth, corresponding to a cost of CO2 avoided of 16.3 €/tCO2.

Published

2020

41. Techno-economic feasibility assessment of calcium looping combustion using commercial technology appraisal tools

Author

Dawid P. Hanak, Vasilije Manovic, and Sebastian Michalski

Subjects

Carbonate looping, Rankine cycle, Power station, Cost estimate, Economic assessment framework, 020209 energy, Strategy and Management, 02 engineering and technology, Industrial and Manufacturing Engineering, law.invention, Efficiency penalty, law, 0202 electrical engineering, electronic engineering, information engineering, Cost of electricity by source, Process engineering, Calcium looping, 0505 law, General Environmental Science, Clean coal, Present value, Renewable Energy, Sustainability and the Environment, business.industry, Depreciation, 05 social sciences, 050501 criminology, Environmental science, Clean power technologies, business, Carbon capture

Abstract

Calcium looping combustion (CaLC) is a new class of low CO2 emission technologies for thermochemical conversion of carbonaceous fuels that can help achieve the emissions reduction targets set out in the Paris Agreement. Compared to mature CO2 capture technologies, which cause net efficiency penalties higher than 7% points, CaLC results in a net efficiency penalty of 2.9% points. However, a thorough economic assessment of CaLC needs to be undertaken to evaluate its economic viability. The levelised cost of electricity is commonly used to assess the economic performance of clean energy systems. However, this method does not account for commercially important parameters, such as tax, interest, and depreciation charges. This study aimed to improve the reliability and accuracy of economic assessments of clean energy systems by implementing the net present value (NPV) approach. This approach was applied to assess the economic performance of two concepts of the CaLC-based power plant with either the conventional steam cycle (SC) or the supercritical CO2 cycle (s-CO2) for heat utilisation along with the bottom-up approach to total capital cost estimation. A parametric study for both concepts was also conducted to assess the impact of the key thermodynamic parameters on the economic performance. Although the s-CO2 case with revised assumptions was shown to result in a 1%-point lower net efficiency compared to the SC case, its break-even cost of electricity was lower by 0.81 €/MWh. Further improvements of the techno-economic performance can be sought by optimisation of the s-CO2 cycle structure.

Published

2019

42. Carbon Capture with Metal Oxides in Molten Salts: MgO, SrO and CaO AS Sorbents

Author

Grøtan, Åshild, Olsen, Espen, and Nygård, Heidi S.

Subjects

Metal Oxides as CO2 sorbents, Carbonate Looping, Carbon Capture in Molten Salts, CCMS, Teknologi: 500 [VDP]

Abstract

Carbon Capture in Molten Salts (CCMS) is an absorption-based method of separating CO2 from a flue gas or industrial gas through a thermal swing technique, where the sorbent is dissolved or partially dissolved in molten salts. The method takes advantage of the reversible carbonation reaction of alkaline earth metal oxides and has previously been studied with CaO as sorbent, showing excellent absorption capacity, regeneration and cyclability compared to similar methods. If the molten salt contains certain alkaline metal halides, these may react with the formed metal carbonates in an exchange reaction, shifting the equilibrium towards further carbonation. The CCMS process is however energy intensive and the regeneration of the sorbent has been identified as a main cost driver due to high operating temperatures and high reaction enthalpy. In this study, a screening of alternative chemical systems with MgO, SrO and CaO as sorbents has been performed. The aim is to find chemical systems with lower operating temperatures and reaction enthalpies that work as efficiently as in previous studies, as this could reduce energy demand and thus operational costs. Promisingly high reaction stability and conversion ratio was found with MgO-FLiNaK, but more experiments are needed to see if the absorption efficiency may be sufficiently improved. SrO-NaCl-CaCl2 showed an even higher conversion ratio, but lower reaction stability which may be improved in a different salt mixture. Furthermore, it was found that the chemical system CaO-LiF-CaF2, which has been very efficient in previous studies, seemed to have no active exchange reaction when the CaF2 was replaced by CaCl2. Another new finding is that even though studies have shown that CCMS may operate well above the solubility limit of the sorbent, the sorbent does need to have a certain solubility in the melt in order to absorb any CO2.

Published

2019

43. Design and Erection of a 300 kWth Indirectly Heated Carbonate Looping Test Facility

Author

Bernd Epple, Michael Reitz, Jochen Ströhle, and Markus Junk

Subjects

Engineering, Air separation, Waste management, business.industry, Carbon Capture, Carbonate Looping, Limestone, Pilot Plant, law.invention, Solid Looping, Heat pipe, Pilot plant, Energy(all), law, Heat Pipe, Combustor, Retrofitting, Calcination, Coal, business, Post Combustion, Chemical looping combustion, Fluidized Bed Conversion

Abstract

Standard carbonate looping promises low energy penalties for post-combustion CO2-capture and is particularly suited for retrofitting existing power plants. The heat for calcination can be provided by supplementary coal firing with oxygen leading to energy penalties and additional investment costs for air separation. To further increase the process efficiency, a new concept is considered where the heat for calcination is transferred from an external combustor to the calciner by means of heat pipes. This process modification offers even higher plant efficiencies and lower CO2 avoidance costs than the oxy-fired standard carbonate looping process. The concept of the indirectly heated carbonate looping process is tested at sufficient scale in a 300 kWth test facility at Technische Universität Darmstadt. The main focus of this paper is on the design and erection of the very innovative pilot plant that is currently being commissioned.

Published

2014

44. Alstom's Regenerative Calcium Cycle - Norcem Derisking Study: Risk Mitigation in the Development of a 2nd Generation CCS Technology

Author

Liv-Margrethe Bjerge, Ola Augustsson, Michael Charles Balfe, and Raul Tahoces-soto

Subjects

Model Development, Engineering, Flue gas, Process modeling, Sorbent, Power station, Waste management, business.industry, Pilot Testing, Regenerative Calcium Cycle, Carbonate Looping, Combustion, Commercialization, Pilot plant, Energy(all), Calcium Looping, Process Performance Predictions, business, Calcium looping

Abstract

Alstom is a pioneer and industrial leader in the development of post combustion CCS technologies. Alstom's Regenerative Calcium Cycle (RCC) is a 2 nd generation post combustion CCS technology utilizing a calcination/ carbonation loop to capture CO 2 from flue gas at high temperatures. The CO 2 capture cycle is driven by introducing heat required to regenerate sorbent at 900 °C (4.0 GJ/t CO 2 , chemically bound CO 2 ) the regenerated sorbent is then used for CO 2 capture from flue gas where the exothermic heat of the reverse reaction (-4.0 GJ/t CO 2 captured) is recovered in a power cycle. Due to the option of using natural sorbent materials (limestone), RCC also provides attractive integration opportunities with industrial processes such as cement production. Recently indirectly fired RCC calcination concepts also open the door for game changing performance gains using natural or even synthetic materials. However, the wide range of performance variability characteristic of natural sorbents contributes to uncertainty in defining process performance. Reliable sorbent deactivation models, which describe both cyclic and chemical deactivation, in combination with mechanistic reactor models which predict gas and solids phase conversions are required to lower the uncertainty associated with new reactor concepts and larger geometries required for commercialization for retrofit power-plant flue gas or for integrated solutions for the cement industry. Parallel to RCC process development, Alstom is currently executing a “Derisking” or risk-mitigation study for Norcem, a Norwegian cement producer, who seeks to take a leading position in the development of technologies for CO 2 -capture from cement production facilities. Norcem is currently heading up a project on behalf of the European cement industry (partners are Norcem, HeidelbergCement and the European Cement Research Academy) investigating various technological options at the pilot scale. In relation to this project, Alstom's RCC technology was selected with the objective to define process performance and the associated uncertainty. Pilot testing was conducted at the Institute of Combustion and Power Plant Technology at the University of Stuttgart (IFK) planned by Alstom focusing on the validation of process models and less the targeting of pilot plant performance, which is often limited by reactor geometries. This paper discusses the characterization of sorbent performance and the gap between the performance expected from thermo- gravimetric analysis (TGA) and that realized during steady state pilot testing under representative operating conditions. Operational stability, material balance closure and the confirmation of sorbent attrition characteristics from pilot testing are also discussed and steady-state operational data, gained from pilot testing are applied to initialize mechanistic process models which allow prediction of reactor performance for larger more efficient designs.

Published

2014

45. Design of a 20 MWth Carbonate Looping Pilot Plant for CO2-capture of Coal Fired Power Plants by Means of Limestone

Author

Johannes Kremer, Bernd Epple, Jochen Ströhle, O. Stallmann, Ulrich Priesmeier, C. Weingärtner, Markus Junk, and N. Eimer

Subjects

Engineering, Waste management, business.industry, Carbon Capture, Test rig, Carbonate Looping, Post combustion, Coal fired, Limestone, chemistry.chemical_compound, Pilot plant, Energy(all), chemistry, Design study, Carbonate, Post Combustion, Large scale application, business, Solids Looping

Abstract

The feasibility of the post combustion process Carbonate Looping has been confirmed through operation of various test rigs at different scales worldwide. This work describes the development of a 1 MWth test rig to a 20 MWth pilot plant, shows some important and essential test results of the 1 MWth plant and presents a basic design study with a final setup of the 20 MWth pilot. The erection and operation of a pilot plant in a scale of 20 MWth is considered as a further milestone with regard to a large scale application of this technology.

Published

2014

46. Synthetic CaO-based sorbent for CO2 capture

Author

Nick Florin and Paul S. Fennell

Subjects

Carbonate looping, Sorbent, Waste management, Oxide, Elutriation, CCS, Synthetic sorbent, chemistry.chemical_compound, Calcium carbonate, Energy(all), chemistry, Chemical engineering, Carbon dioxide, Carbon capture and storage, Slurry, CO2, Calcium oxide

Abstract

The capture and purification of carbon dioxide (CO2) from flue or fuel gas underlies the cost efficiency of carbon capture and storage (CCS) applications in the power and industrial sectors and there is considerable scope for cost reduction with the development of novel capture technologies. High-temperature sorbents are seen as a “next-generation” technology and a promising candidate is calcium oxide (CaO) derived from natural limestone, which is used in a process known as carbonate looping. This process exploits the reversible reaction between CaO and CO2 to form calcium carbonate (CaCO3).Unfortunately, sorbent derived from natural limestone loses its capacity to capture CO2 through long-term cycling, and a large amount of fresh limestone is required to maintain an acceptable CO2 capture efficiency. This work describes the development and characterisation of synthetic CaO-based sorbents, such as those incorporating a mixed calcium-aluminium oxide binder—in this case produced by precipitation in a slurry bubble column. Reactivity tests using a thermogravimetric analyser (TGA) demonstrate the improved long-term CO2 uptake of the synthetic sorbent. The highest CO2 uptake observed after 30 cycles was achieved with 85 wt.% CaO and binder, which was three times higher than the observed capacity of a natural limestone (Havelock). However, contrary to TGA results, experimental results for reactivity tests conducted using a bench-scale fluidised bed reactor (FBR) showed the highest uptake for the precipitated sorbent with no binder. A decrease in uptake was observed corresponding an increase in binder loading from 0–25 wt.%, which was coupled with an increase in mass loss owing to elutriation, attributed to decrepitation during cycling.

Published

2011

47. Performance of the carbonator and calciner during long-term carbonate looping tests in a 1 MWth pilot plant.

Author

Ströhle, Jochen, Hilz, Jochen, and Epple, Bernd

Subjects

PILOT plants, CARBONATES, ENERGY industries, MAXIMUM power point trackers, CONTINUOUS processing, SPACETIME

Abstract

• A 1 MWth carbonate looping plant was operated in steady state for > 2000 h. • A carbonator efficiency > 80 % was obtained under a variety of operating conditions. • A calciner efficiency > 90 % was achieved 30 K above equilibrium temperature. Carbon capture and utilization/storage is an effective means to reduce CO 2 emissions from power and energy intensive industries. Carbonate looping is a 2nd generation post-combustion CO 2 capture technology using solid sorbents that form carbonates when reacting with CO 2. This technology has economic benefits caused by the low efficiency penalty and the low cost of the sorbent. Autothermal continuous operation of this process at high CO 2 capture rates has been successfully proven in several pilot plants up to 1.7 MW th. The 1 MW th pilot plant in Darmstadt has been operated for more than 2000 h with long periods of steady-state conditions, which allows the evaluation of the performance of the reactor system during long-term operation. This paper presents complementary results of these pilot tests focussing on the performance of the carbonator and calciner reactors. A high carbonator efficiency above 80 % is possible in the temperature range of 650–675 °C with a specific solid inventory above 700 kg/m2 combined with either a high sorbent looping ratio of 16 mol Ca /mol CO2 or a high make-up ratio of 0.13 mol Ca /mol CO2. A calcination efficiency of 90 % can be achieved by a calciner space time above 6 min, if the calciner temperature is 30 K above the equilibrium temperature at the prevailing CO 2 concentration. Heating of the sorbent entering the calciner consumes almost half of the thermal fuel input. [ABSTRACT FROM AUTHOR]

Published

2020

48. Kinetics of Solid-Gas Reactions and Their Application to Carbonate Looping Systems.

Author

Fedunik-Hofman, Larissa, Bayon, Alicia, and Donne, Scott W.

Subjects

CHEMICAL kinetics, CARBON sequestration, ACTIVATION energy, CHEMICAL engineering, CARBONATION (Chemistry), ENERGY storage

Abstract

Reaction kinetics is an important field of study in chemical engineering to translate laboratory-scale studies to large-scale reactor conditions. The procedures used to determine kinetic parameters (activation energy, pre-exponential factor and the reaction model) include model-fitting, model-free and generalized methods, which have been extensively used in published literature to model solid-gas reactions. A comprehensive review of kinetic analysis methods will be presented using the example of carbonate looping, an important process applied to thermochemical energy storage and carbon capture technologies. The kinetic parameters obtained by different methods for both the calcination and carbonation reactions are compared. The experimental conditions, material properties and the kinetic method are found to strongly influence the kinetic parameters and recommendations are provided for the analysis of both reactions. Of the methods, isoconversional techniques are encouraged to arrive at non-mechanistic parameters for calcination, while for carbonation, material characterization is recommended before choosing a specific kinetic analysis method. [ABSTRACT FROM AUTHOR]

Published

2019

49. Carbonate Looping for De-Carbonization of Cement Plants

Author

Sharat Kumar Pathi, Maria Friberg Andersen, Weigang Lin, Jytte Boll Illerup, Kim Dam-Johansen, and Klaus Hjuler

Subjects

Carbonate looping, Type of limestone, Cement plant, CO2 capture

Abstract

Cement industry is one of the largest emitter of CO2 other than power generation plants, which includes the emissions from combustion of fuel and also from calcination of limestone for clinker production. In order to reduce CO2 emissions from the cement industry an effective an economically feasible technology is to be developed. The carbonate looping process is a promising technology, which is particularly suitable for the cement industry as limestone could be used for capture and release of CO2. Integration of carbonate looping process into cement pyroprocess has two advantages: 1) to capture emitted CO2 and 2) to generate power for internal use, because high quality energy can be recovered from carbonate looping which is operated at high temperature unlike amine process. A simple carbonate looping process model was developed based on average conversion of calcined limestone defined by Abanades et al. The model is used to investigate the influence of average conversion of limestone in the carbonator on the flow rates of different streams in the looping process and energy required in the calciner for re-activation. The model developed is used for studying the carbonate looping process integrated into cement pyro-process. The energy required for regeneration in the calciner increases with increase in average conversion of calcined limestone and energy that can be extracted from carbonator decreases with increasing average conversion. Further the influence of type of limestone on the calciner capacity is also investigated. The results from this simple model show the importance of cement industry to the carbon capture technology for its application to power plants.

Published

2011

50. Carbon dioxide capture from combustion flue gases with a calcium oxide chemical loop. Experimental results and process development

Author

Ramón Murillo, Belén González, Juan Carlos Abanades, Gemma Grasa, Nuria Rodríguez, and Mónica Alonso

Subjects

Carbonate looping, Pilot testing, Flue gas, Materials science, Sorbent, Waste management, Management, Monitoring, Policy and Law, Combustion, Pollution, CO2 capture, Industrial and Manufacturing Engineering, law.invention, chemistry.chemical_compound, General Energy, Calcium carbonate, chemistry, Chemical engineering, law, Carbonation, Calcination, Fluidized bed combustion, Calcium oxide, Chemical looping combustion

Abstract

Post-combustion carbonate looping processes are based on the capture of carbon dioxide from the flue gases of an existing power plant in a circulating fluidized bed reactor (CFB) of calcium oxide (the carbonator) particles. The calcination of calcium carbonate in a new oxy-fired CFBC power plant regenerates the sorbent (calcium oxide particles) and obtains high purity carbon dioxide. This communication presents experimental results from a small test facility (30 kWt) operated in continuous mode using two interconnected CFB reactors as carbonator and calciner. Capture efficiencies between 70 and 97% have been obtained under realistic flue gas conditions in the carbonator reactor (temperatures around 650 °C). The similarity between process conditions and those existing in CFBC power plants should allow a rapid scaling up of this technology. The next steps for this process development are also outlined. © 2009 Elsevier Ltd. All rights reserved., This work has been carried out thanks to the financial support from the Spanish companies Hunosa and Endesa.

Published

2010