Coal direct chemical looping process: 250 kW pilot-scale testing for power generation and carbon capture

Zhang, Yitao; Wang, Dawei; Pottimurthy, Yaswanth; Kong, Fanhe; Hsieh, Tien-Lin; Sakadjian, Bartev; Chung, Cheng; Park, Cody; Xu, Dikai; Bao, Jinhua; Velazquez-Vargas, Luis G.; Guo, Mengqing; Sandvik, Peter; Nadgouda, Sourabh G.; Flynn, Thomas; Tong, Andrew; Fan, Liang‐Shih

doi:10.1016/j.apenergy.2020.116065

Cited by 27 publications

(18 citation statements)

References 32 publications

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“…Inspection of the experimental OC conversion vs. time plots of CH 4 in Figure 5 for these runs shows that the model fits begin to worsen with a reduction in temperature and the model does not capture the inflection behavior of the experimental curves which generally begins at OC conversion greater than 40% at which the cracking of gaseous reactants on the metallic Fe sites most likely begins to become significant. These deviations do not significantly affect the ability of the model to be predictive in our chemical looping applications of interest in the areas of combustion and reforming, because in these applications a high circulation rate of the OC between the reducer reactor and oxidation reaction is maintained to keep the temperature in the reducer between 950 and 1050°C for thermal management reasons 41 . At these high circulation rates, reduction of the OC in the reducer does not go above 40% 41 (after which point the deviations and inflection of the experimental curves are observed for CH 4 ), and thus the model's application is restricted to the region where the fit is good.…”

Section: Resultsmentioning

confidence: 99%

“…These deviations do not significantly affect the ability of the model to be predictive in our chemical looping applications of interest in the areas of combustion and reforming, because in these applications a high circulation rate of the OC between the reducer reactor and oxidation reaction is maintained to keep the temperature in the reducer between 950 and 1050 C for thermal management reasons. 41 At these high circulation rates, reduction of the OC in the reducer does not go above 40% Further investigation of these exceptions shows that the CI values of k 0,2 (AE193%) and k 0,3 (AE141%) for CH 4 in Table 8 have large variations from the mean values indicating the estimates are illconditioned with respect to errors in the reactant gas concentration and highlighting the potential to improve these estimates with additional data and alternative model forms that better capture concentration dependence for reactions (R8) and (R9). In addition, it can be observed from Table 9 that k 0,3 and n 3 also have wide CI values (AE73:4% and AE78:1%, respectively) suggesting that there might be a need for more experimental data on the reduction of the OC with CO to better determine these parameters (reduce the uncertainty) and better characterize the Fe 2 O 3 to Fe 3 O 4 reduction step for reaction (R4).…”

Section: Parameter Estimates and Goodness Of Fitmentioning

confidence: 99%

“…In our study,

f (X)

, provided by Equations () and (), is the relationship between reactant gas concentration,

C_{bulk}

, and the input measured variables (

V_{gas}, V_{N_{2}}, T, and P

V_{gas}

and

V_{N_{2}}

are measured by MFCs with relative standard deviations of

\pm 0.5 %

, 41 while the pressure controller and temperature controller have relative standard deviations of

\pm 0.5 %

and

\pm 0.2 %

respectively 42 . Based on this, the maximum relative standard deviation in the reactant gas concentration for all the reactant gases and across all experimental runs was found to be

\pm 0.85 %

.…”

Section: Parameter Estimationmentioning

confidence: 99%

“…41 (after which point the deviations and inflection of the experimental curves are observed for T A B L E 8…”

mentioning

confidence: 95%

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Application of an equation‐oriented framework to formulate and estimate parameters of chemical looping reaction models

et al. 2022

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Accurate, predictive reaction models are critical for the design and optimization of chemical looping combustion (CLC) reactors. The formulation and estimation of kinetic parameters for these reaction models using a first‐principles equation‐oriented (EO) approach is particularly beneficial as large amounts of experimental data spanning process‐relevant conditions can be used to estimate parameters in a computationally tractable way. This work demonstrates the application of a novel EO framework to develop reduction reaction kinetic models of an iron‐based CLC oxygen carrier (OC). An optimization problem is formulated to estimate kinetic parameters that provide the best fit to the experimental data. The model predicts the state of the OC with mean square error values of 2.5%–4.4% across the full range of validation data, including multiple reduction cycles.

show abstract

Section: Resultsmentioning

confidence: 99%

Section: Parameter Estimates and Goodness Of Fitmentioning

confidence: 99%

“…In our study,

f (X)

, provided by Equations () and (), is the relationship between reactant gas concentration,

C_{bulk}

, and the input measured variables (

V_{gas}, V_{N_{2}}, T, and P

V_{gas}

and

V_{N_{2}}

are measured by MFCs with relative standard deviations of

\pm 0.5 %

, 41 while the pressure controller and temperature controller have relative standard deviations of

\pm 0.5 %

and

\pm 0.2 %

respectively 42 . Based on this, the maximum relative standard deviation in the reactant gas concentration for all the reactant gases and across all experimental runs was found to be

\pm 0.85 %

.…”

Section: Parameter Estimationmentioning

confidence: 99%

“…41 (after which point the deviations and inflection of the experimental curves are observed for T A B L E 8…”

mentioning

confidence: 95%

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Application of an equation‐oriented framework to formulate and estimate parameters of chemical looping reaction models

et al. 2022

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show abstract

“…The CDCL process has been successfully demonstrated at various scales ranging from a 2.5 kW th bench unit to a 250 kW th pilot unit. A 25 kW th sub-pilot scale unit designed at commissioned at OSU has been subjected to 200 h of continuous operation, whereas the 250 kW th pilot unit has been operated for 288 h for power generation and CO 2 capture with high coal conversion and CO 2 purity. − …”

Section: Introductionmentioning

confidence: 99%

Coal-Direct Chemical Looping Process with In Situ Sulfur Capture for Energy Generation Using Ca–Cu Oxygen Carriers

Joshi

Pottimurthy

Shah

et al. 2021

Ind. Eng. Chem. Res.

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A novel process scheme for energy production from coal with in situ sulfur capture, known as the coal-direct chemical looping process with sulfur removal (CDCL-SR), is proposed in this study. The proposed process utilizes multimetal oxide comprising the oxides of copper and calcium supported on inert SiC as the oxygen carrier to combust coal and simultaneously produce separate streams of CO2 and SO2, thus eliminating the need for downstream processing units. The computational software ASPEN Plus has been utilized to carry out detailed reactor simulations along with a thorough thermodynamic analysis of the process. The reactor modeling results indicate that the moving bed reducer can effectively convert all the carbon present in coal into CO2 while capturing sulfur in the form of calcium sulfide in the reduced oxygen carrier. The reduced oxygen carrier can in turn be oxidized using steam to produce pure SO2 stream that can be readily utilized. Process simulation results indicate that the proposed CDCL-SR process has thermal and exergy efficiencies of 86 and 51%, respectively, significantly higher than both the conventional pulverized coal Rankine cycle and Fe-based CDCL processes.

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Carbon‐negative syngas production: A comprehensive assessment of biomass pyrolysis coupling chemical looping reforming

Liu,

Zhang,

Sun

et al. 2023

AIChE Journal

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This article introduces a pyrolysis chemical looping reforming (PCLR) process that produces carbon‐negative syngas in autothermal operation. To enhance the system's carbon negativity, a process configuration with oxygen carrier two‐stage regeneration is adopted, enabling internal CO2 utilization. The PCLR process is systematically evaluated and compared to chemical looping gasification and steam gasification processes in the process performance, energy efficiency, and environmental impact using a process model. Results reveal significant improvements over chemical looping gasification, including 69%, 45%, and 4% improvement in syngas yield, energy efficiency, and environmental benefit. Process analysis demonstrates that decoupling volatile reforming from pyrolysis and combustion enhances syngas quality, energy efficiency, and process flexibility. While the two‐stage regeneration sacrifices syngas production, it contributes to a 4% increase in carbon negativity and a 15% reduction in carbon emissions. Thus, the PCLR process effectively overcomes the limitations of chemical looping gasification systems and exhibits excellent process intensification performance.

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Coal direct chemical looping process: 250 kW pilot-scale testing for power generation and carbon capture

Cited by 27 publications

References 32 publications

Application of an equation‐oriented framework to formulate and estimate parameters of chemical looping reaction models

Application of an equation‐oriented framework to formulate and estimate parameters of chemical looping reaction models

Coal-Direct Chemical Looping Process with In Situ Sulfur Capture for Energy Generation Using Ca–Cu Oxygen Carriers

Carbon‐negative syngas production: A comprehensive assessment of biomass pyrolysis coupling chemical looping reforming

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