Usman Ali scite author profile

Post-combustion CO 2 capture systems are gaining more importance as a means of reducing escalating greenhouse gas emissions. Moreover, for natural gas-fired power generation systems, exhaust gas recirculation is a method of enhancing the CO 2 concentration in the lean flue gas. The present study reports the design and scale-up of four different cases of an amine-based CO 2 capture system at 90 % capture rate with 30 wt. % aqueous solution of MEA. The design results are reported for a natural gas-fired combined cycle system with a gross power output of 650 MW e without EGR and with EGR at 20, 35 and 50 % EGR percentage. A combined process and economic analysis is implemented to identify the optimum designs for the different amine-based CO 2 capture plants. For an amine-based CO 2 capture plant with a natural gas-fired combined cycle without EGR, an optimum liquid to gas ratio of 0.96 is estimated. Incorporating EGR at 20, 35 and 50 %, results in optimum liquid to gas ratios of 1.22, 1.46 and 1.90, respectively. These results suggest that a natural gas-fired power plant with exhaust gas recirculation will result in lower penalties in terms of the energy consumption and costs incurred on the amine-based CO 2 capture plant.

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Comparative potential of natural gas, coal and biomass fired power plant with post - combustion CO 2 capture and compression

Ali

Font-Palma

Akram

et al. 2017

International Journal of Greenhouse Gas Control

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Part-load performance of direct-firing and co-firing of coal and biomass in a power generation system integrated with a CO2 capture and compression system

Ali

Akram

Font-Palma

et al. 2017

Fuel

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Bioenergy with Carbon Capture and Storage (BECCS) is recognised as a key technology to mitigate CO2 emissions and achieve stringent climate targets due to its potential for negative emissions. However, the cost for its deployment is expected to be higher than for fossil-based power plants with CCS. To help in the transition to fully replace fossil fuels, co-firing of coal and biomass provide a less expensive means. Therefore, this work examines the co-firing at various levels in a pulverised supercritical power plant with post-combustion CO2 capture, using a fully integrated model developed in Aspen Plus. Co-firing offers flexibility in terms of the biomass resources needed. This work also investigates flexibility within operation. As a result, the performance of the power plant at various part-loads (40%, 60% and 80%) is studied and compared to the baseline at 100%, using a constant fuel flowrate. It was found that the net power output and net efficiency decrease when the biomass fraction increases for constant heat input and constant fuel flow rate cases. At constant heat input, more fuel is required as the biomass fraction is increased; whilst at constant fuel input, derating occurs, e.g. 30% derating of the power output capacity at firing 100% biomass compared to 100% coal. Co-firing of coal and biomass resulted in substantial power derating at each part-load operation.

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Usman Ali

Development of biomass derived highly porous fast adsorbents for post-combustion CO2 capture

Performance evaluation of PACT Pilot-plant for CO 2 capture from gas turbines with Exhaust Gas Recycle

Techno-economic process design of a commercial-scale amine-based CO2 capture system for natural gas combined cycle power plant with exhaust gas recirculation

Comparative potential of natural gas, coal and biomass fired power plant with post - combustion CO 2 capture and compression

Part-load performance of direct-firing and co-firing of coal and biomass in a power generation system integrated with a CO2 capture and compression system

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