Combined Calcium Looping and Chemical Looping Combustion for Post‐Combustion Carbon Dioxide Capture: Process Simulation and Sensitivity Analysis

Duhoux, Benoît; Mehrani, Poupak; Lu, Dennis Y.; Symonds, Robert T.; Anthony, Edward J.; Macchi, Arturo

doi:10.1002/ente.201600024

Cited by 28 publications

(19 citation statements)

References 76 publications

(222 reference statements)

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“…Estimations for the energy penalty of CaL on the base power plant are also provided as an additional comparison criterion. In this investigation, the gross efficiency associated with power production from the carbon capture process is based on previous work on a similar system . The capture process simulations are based on the cyclic CO 2 sorption of a limestone that was investigated in a series of thermogravimetric analyzer (TGA) experiments.…”

Section: Introductionmentioning

confidence: 99%

“…In this investigation, the gross efficiency associated with power production from the carbon capture process is based on previous work on a similar system. [9] The capture process simulations are based on the cyclic CO 2 sorption of a limestone that was investigated in a series of thermogravimetric analyzer (TGA) experiments. The limestone was subjected to multiple cycles of relatively high-temperature carbonation and lowtemperature calcination.…”

Section: Introductionmentioning

confidence: 99%

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Simulation of a calcium looping CO₂ capture process for pressurized fluidized bed combustion

et al. 2019

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The Canadian regulations on carbon dioxide emissions from power plants aim to lower the emissions from coal‐fired units down to those of natural gas combined cycle (NGCC) units. Since coal is significantly more carbon intensive than natural gas, coal‐fired plants must operate at higher net efficiencies and implement carbon capture to meet the new regulations. Calcium looping (CaL) is a promising post‐combustion carbon capture (PCC) technology that, unlike other capture processes, generates additional power. By capturing carbon dioxide at elevated temperatures, the energy penalty that carbon capture technologies inherently impose on power plant efficiencies is significantly reduced. In this work, the CO2 capture performance of a calcium‐based sorbent is determined via thermogravimetric analysis under relatively high carbonation and low calcination temperatures. The results are used in an aspenONE™ simulation of a CaL process applied to a pressurized fluidized bed combustion (PFBC) system at thermodynamic equilibrium. The combustion of both natural gas and coal are considered for sorbent calcination in the CaL process. A sensitivity analysis on several process parameters, including sorbent feed rate and carbonator operating pressure, is undertaken. The energy penalty associated with the capture process ranges from 6.8–11.8 percentage points depending on fuel selection and operating conditions. The use of natural gas results in lower energy penalties and solids circulation rates, while operating the carbonator at 202 kPa(a) results in the lowest penalties and drops the solids circulations rates to below 1000 kg/s.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Simulation of a calcium looping CO₂ capture process for pressurized fluidized bed combustion

et al. 2019

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“…The main alternative heat sources to drive the calcination process include chemical looping [19][20][21][22], which uses oxygen carriers to transfer oxygen from air to the fuel, and indirect heat transfer from a combustor via solid heat carriers [15,23], heat transfer wall [15,24] or heat pipes [25,26]. The combined calcium and chemical looping system includes an additional reactoran air reactorin which the oxygen carrier reacts with oxygen in the air, forming a metal oxide.…”

Section: Introductionmentioning

confidence: 99%

“…This system can operate as either a single-or dual-loop process [20,22], depending on whether the oxygen carrier is mixed with the sorbent and reduced directly in the calciner, or is handled separately in another loop. In the latter case, the heat is transferred to the calciner indirectly.…”

Section: Introductionmentioning

confidence: 99%

Calcium looping combustion for high-efficiency low-emission power generation

Hanak

2017

Journal of Cleaner Production

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High-temperature solid looping technologies, such as calcium looping and chemical looping combustion are regarded as emerging CO 2 capture technologies with potential to reduce the net efficiency penalties associated with CO 2 separation. Importantly, high-temperature operation of these technologies allows utilisation of the high-grade heat for power generation. Building on these emerging technologies, this study intended to establish a new class of high-temperature solid looping combustion technologies for high-efficiency low-emission power generation called calcium looping combustion. Such combustion technology comprises a combustor, as a primary source of heat for indirect heating in a calciner, and a carbonator where CO 2 is separated from flue gas leaving the combustor; hence high-grade heat, which can be used for power generation, and a concentrated CO 2 stream, which can be either utilised or permanently stored, are generated. The techno-economic performance of calcium looping combustion was comparable to a conventional coal-fired power plant. Depending on whether the concentrated CO 2 stream is utilised elsewhere or permanently stored, calcium looping combustion was characterised with a net efficiency gain of 0.7% HHV points or a net efficiency penalty of 2.4% HHV , respectively. Additionally, the cost of CO 2 avoided for calcium looping combustion was estimated to be 10.0 €/tCO 2 and 33.9 €/tCO 2 , respectively. Therefore, similarly to chemical looping combustion, calcium looping combustion introduced in this study is a viable high-efficiency low-emission power generation technology that produces a concentrated CO 2 stream with no efficiency penalty associated with CO 2 separation.

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“…This introduces the main source of the parasitic load in the process, as O2 production is usually conducted in a cryogenic air separation unit that is characterised with a specific power requirement of 184-230 kWelh/tO2 [22][23][24]. The main alternative options to drive the calcination process include chemical looping [25][26][27][28], which uses oxygen carriers to transfer oxygen from air to the fuel, and indirect heat transfer from a combustor via solid heat carriers [29,30], heat transfer wall [30,31] or heat pipes [32,33].…”

Section: Introductionmentioning

confidence: 99%

High-efficiency negative-carbon emission power generation from integrated solid-oxide fuel cell and calciner

Hanak

Jenkins²,

Kruger³

2017

Applied Energy

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Direct air capture of CO2 has the potential to help meet the ambitious environmental targets established by the Paris Agreement. This study assessed the techno-economic feasibility of a process for simultaneous power generation and CO2 removal from the air using solid sorbents. The process uses a solid-oxide fuel cell to convert the chemical energy of fuel to electricity and high-grade heat, the latter of which can be utilised to calcine a carbonate material that, in turn, can remove CO2 from the air. The proposed process was shown to operate with a net thermal efficiency of 43.7-47.7%LHV and to have the potential to remove 463.5-882.3 gCO2/kWelh, depending on the fresh material used in the calciner. Importantly, the estimated capital cost of the proposed process (1397.9-1740.5 £/kWel,gross) was found to be lower than that for other low-carbon emission power generation systems using fossil fuels. The proposed process was also shown to achieve a levelised cost of electricity of 50 £/MWelh, which is competitive with other low-carbon power generation technologies, for a carbon tax varying between 39.2 and 74.9 £/tCO2. Such figure associated with the levelised cost of CO2 capture from air is lower than for other direct air concepts.

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Combined Calcium Looping and Chemical Looping Combustion for Post‐Combustion Carbon Dioxide Capture: Process Simulation and Sensitivity Analysis

Cited by 28 publications

References 76 publications

Simulation of a calcium looping CO₂ capture process for pressurized fluidized bed combustion

Simulation of a calcium looping CO₂ capture process for pressurized fluidized bed combustion

Calcium looping combustion for high-efficiency low-emission power generation

High-efficiency negative-carbon emission power generation from integrated solid-oxide fuel cell and calciner

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Combined Calcium Looping and Chemical Looping Combustion for Post‐Combustion Carbon Dioxide Capture: Process Simulation and Sensitivity Analysis

Cited by 28 publications

References 76 publications

Simulation of a calcium looping CO2 capture process for pressurized fluidized bed combustion

Simulation of a calcium looping CO2 capture process for pressurized fluidized bed combustion

Calcium looping combustion for high-efficiency low-emission power generation

High-efficiency negative-carbon emission power generation from integrated solid-oxide fuel cell and calciner

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Simulation of a calcium looping CO₂ capture process for pressurized fluidized bed combustion

Simulation of a calcium looping CO₂ capture process for pressurized fluidized bed combustion