This paper evaluates the feasibility of implementing post-combustion carbon capture, storage, and utilization (CCSU) technologies in NGCC power plants
In this paper, CO 2 capture from a natural gas fired steam cycle power plant using oxy-fuel combustion technology is studied.
A techno-economic-based feasibility study, which took into consideration local power generation technologies and economic conditions, was performed.
CCUS technologies are essential in the global effort to reduce greenhouse gas emissions, particularly from power generation. By capturing CO2
# The Economic Feasibility and Sensitivity Analysis of Carbon Capture and Utilization in Indonesian Coal-Fired Power Plants. ## Authors. ## DOI:. ## Keywords:. ## Abstract. ## Downloads. ## Published. ## How to Cite. ## Issue. ## Section. ## License. ## Make a Submission. ## Dergi Kapağı. ## Information. | Online ISSN : 2146-4553 Creative Commons License IJEEP is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License. Creative Commons License IJEEP is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License. More information about the publishing system, Platform and Workflow by OJS/PKP.
# Techno-economic Analysis of Carbon Capture Systems for a Natural Gas Power Plant. One technology to combat the emissions of greenhouse gasses is carbon capture, utilization, and sequestration (CCUS). Factors such as the fuel that is burned in the power plant as well as the makeup of the flue gas emissions are key factors in determining the sizing and solvent for the capture system. The objective of this research was to conduct a techno-economic analysis for carbon capture technologies with a parametric study to find the optimal absorption column size and conditions. Utilizing ASPEN HYSYS® software and EXCEL, an optimization model was constructed to determine the minimum overall cost for a carbon capture and sequestration technology by combining the capital and operating and maintenance costs of the CCUS system with the social cost of the CO2 which is not captured and sequestered by the system. A case study was performed on a natural gas combined cycle plant to prove the functionality of the parametric study with respect to a variety of factors which affect the CO2 capture rate.
Retrofitting CO₂ capture to natural gas combined cycle plants would increase the cost of electricity by about 2-3c/kWh, corresponding to about 70-90 $/tonne of
# A techno-economic assessment of CO2 capture in biomass and waste-fired combined heat and power plants – A Swedish case study. Marginal abatement cost curve for CCS from Swedish co-generation plants. The Swedish district heating sector constitutes a large potential for BECCS, with biogenic point sources of CO2 in the form of combined heat and power (CHP) plants that burn biomass residues from the forest industry. This study analyzes the potential of CO2 capture in 110 existing Swedish biomass or waste-fired CHP plants. Process models of CHP steam cycles give the impacts of absorption-based CCS on heat and electricity production, while a district heating system unit commitment model gives the impact on plant operation and the potential for CO2 capture. The results provide a cost for carbon capture and transport to the nearest harbor by truck: up to 19.3 MtCO2/year could be captured at a cost in the range of 45–125 €/tCO2, corresponding to around 40% of the total fossil fuel-based Swedish CO2 emissions.