Increasing concerns over growing CO 2 levels in the atmosphere have led to a worldwide demand for efficient, cost-effective, and clean carbon capture technologies. One of these technologies is the Carbonation-Calcination Reaction (CCR) process, which utilizes a calcium-based sorbent in a high-temperature reaction (carbonation) to capture the CO 2 from the flue gas stream and releases a pure stream of CO 2 in the subsequent calcination reaction that can be sequestered. A 120 KWth subpilot-scale combustion plant utilizing coal at 20 pph along with natural gas has been established at The Ohio State University to test the CCR process. Experimental studies on CO 2 capture using calcium-based sorbents have been performed at this facility. Greater than 99% CO 2 and SO 2 capture has been achieved at the subpilot-scale facility on a once-through basis at a Ca:C mole ratio of 1.6. In addition, the sorbent reactivity is maintained over multiple cycles by the incorporation of a sorbent reactivation hydration step in the carbonation-calcination cycle.
The influence of several process parameters on the calcination of a naturally occurring limestone and a
precipitated mesoporous calcium carbonate (CaCO3) sorbent structure to calcium oxide (CaO) is detailed in
this study. CaCO3 calcination is an integral part of a multicyclic carbonation−calcination reaction (CCR)
process that separates carbon dioxide (CO2) from high-temperature gas mixtures into a pure CO2 stream.
Maintenance of high sorbent reactivity over repeated CCR cycles reduces the capital and operating cost of
the CCR process. A lower calcination temperature, required to maintain high sorbent reactivity, reduces the
calcination rate of CaCO3. This study investigates various process conditions such as subatmospheric calcination,
sorbent dispersion in a rotary calciner, use of a high thermal conductivity sweep gas, etc. in enhancing the
calcination rate at lower calcination temperatures. The high-temperature gas−solid carbonation studies of the
resulting CaO sorbent prove the necessity to maintain a high porosity structure during limestone calcination.
Solar Particle Receivers (SPR) are under development to drive concentrating solar plants (CSP) towards higher operating temperatures to support higher efficiency power conversion cycles. The novel high temperature SPR-based CSP system uses solid particles as the heat transfer medium (HTM) in place of the more conventional fluids such as molten salt or steam used in current state-of-the-art CSP plants. The solar particle receiver (SPR) is designed to heat the HTM to temperatures of 800 °C or higher which is well above the operating temperatures of nitrate-based molten salt thermal energy storage (TES) systems. The solid particles also help overcome some of the other challenges associated with molten salt-based systems such as freezing, instability and degradation. The higher operating temperatures and use of low cost HTM and higher efficiency power cycles are geared towards reducing costs associated with CSP systems. This paper describes the SPR-based CSP system with a focus on the fluidized-bed (FB) heat exchanger and its integration with various power cycles. The SPR technology provides a potential pathway to achieving the levelized cost of electricity (LCOE) target of $0.06/kWh that has been set by the U.S. Department of Energy's SunShot initiative.
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