SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2729990992> ?p ?o ?g. }

Showing items 1 to 100 of ±108 with 100 items per page.

W2729990992 endingPage "253" @default.
W2729990992 startingPage "243" @default.
W2729990992 abstract "Abstract The large employment of renewable energies requires flexible, efficient and low-carbon production from fossil fuels. From all non-renewable power production routes, the electricity produced with micro Gas Turbines (mGTs) running on natural gas has a very high load flexibility and the lowest CO2 emissions. However, if we want to move towards full carbon clean power production, then CO2 in the exhaust must be captured. In this scenario, mGTs coupled with a Carbon Capture (CC) plant could be a suitable option, but only a few numerical and experimental analyses are available which assess their real potential. The low concentration of CO2 in the mGT exhaust gas is disadvantageous from a CC point of view, however the concentration can be increased by performing Exhaust Gas Recirculation (EGR). Furthermore, the efficiency loss introduced by the CC plant can also be reduced by using the concept of micro Humid Air Turbine (mHAT). In this study, both the dry and the wet operations of the Turbec T100 coupled with a chemical-absorption plant are simulated and compared using the software Aspen Plus®. The goal of these simulations was to investigate state-of-the-art measures which could be applied to small-scale generation to assess what the energy impact of a carbon clean production would be. Simulation results show that applying EGR to a mGT or mHAT can reduce the exhaust gas mass flow rate by 50% and it can increase the concentration of CO2 by three times the traditional cycle. The humidification of the mGT can entirely compensate for the efficiency losses of the EGR application. Both cycle performances are strongly affected by the thermal input from the stripping process, decreasing the global electric efficiency by around 7.9 absolute percentage points in the mGT case and by 8.3 absolute percentage points in the mHAT case in full load conditions. The results of this paper can be used as a starting point for new cycle concepts between the mGT and CC plant." @default.
W2729990992 created "2017-07-14" @default.
W2729990992 creator A5031008443 @default.
W2729990992 creator A5037812821 @default.
W2729990992 creator A5045895054 @default.
W2729990992 creator A5071252945 @default.
W2729990992 creator A5079663033 @default.
W2729990992 creator A5088089171 @default.
W2729990992 date "2017-12-01" @default.
W2729990992 modified "2023-10-16" @default.
W2729990992 title "Carbon capture on micro gas turbine cycles: Assessment of the performance on dry and wet operations" @default.
W2729990992 cites W1412629828 @default.
W2729990992 cites W1966638383 @default.
W2729990992 cites W1984655241 @default.
W2729990992 cites W1986921165 @default.
W2729990992 cites W1987131938 @default.
W2729990992 cites W1995491505 @default.
W2729990992 cites W2007488459 @default.
W2729990992 cites W2011613070 @default.
W2729990992 cites W2012520963 @default.
W2729990992 cites W2018066410 @default.
W2729990992 cites W2023490510 @default.
W2729990992 cites W2026277606 @default.
W2729990992 cites W2027867404 @default.
W2729990992 cites W2029649981 @default.
W2729990992 cites W2035797313 @default.
W2729990992 cites W2044254965 @default.
W2729990992 cites W2048298210 @default.
W2729990992 cites W2048310615 @default.
W2729990992 cites W2049418264 @default.
W2729990992 cites W2058201540 @default.
W2729990992 cites W2066482526 @default.
W2729990992 cites W2074931392 @default.
W2729990992 cites W2083676350 @default.
W2729990992 cites W2088428034 @default.
W2729990992 cites W2089499253 @default.
W2729990992 cites W2090712666 @default.
W2729990992 cites W2093908738 @default.
W2729990992 cites W2150597682 @default.
W2729990992 cites W2151019076 @default.
W2729990992 cites W2265244941 @default.
W2729990992 cites W2345512888 @default.
W2729990992 cites W2522475067 @default.
W2729990992 cites W2531129881 @default.
W2729990992 cites W2552374989 @default.
W2729990992 cites W2568055218 @default.
W2729990992 cites W2593462742 @default.
W2729990992 cites W2596577789 @default.
W2729990992 cites W2048119715 @default.
W2729990992 doi "https://doi.org/10.1016/j.apenergy.2017.06.090" @default.
W2729990992 hasPublicationYear "2017" @default.
W2729990992 type Work @default.
W2729990992 sameAs 2729990992 @default.
W2729990992 citedByCount "19" @default.
W2729990992 countsByYear W27299909922017 @default.
W2729990992 countsByYear W27299909922018 @default.
W2729990992 countsByYear W27299909922019 @default.
W2729990992 countsByYear W27299909922020 @default.
W2729990992 countsByYear W27299909922021 @default.
W2729990992 countsByYear W27299909922022 @default.
W2729990992 countsByYear W27299909922023 @default.
W2729990992 crossrefType "journal-article" @default.
W2729990992 hasAuthorship W2729990992A5031008443 @default.
W2729990992 hasAuthorship W2729990992A5037812821 @default.
W2729990992 hasAuthorship W2729990992A5045895054 @default.
W2729990992 hasAuthorship W2729990992A5071252945 @default.
W2729990992 hasAuthorship W2729990992A5079663033 @default.
W2729990992 hasAuthorship W2729990992A5088089171 @default.
W2729990992 hasConcept C104779481 @default.
W2729990992 hasConcept C11413529 @default.
W2729990992 hasConcept C127413603 @default.
W2729990992 hasConcept C140205800 @default.
W2729990992 hasConcept C21880701 @default.
W2729990992 hasConcept C2987684023 @default.
W2729990992 hasConcept C39432304 @default.
W2729990992 hasConcept C41008148 @default.
W2729990992 hasConcept C548081761 @default.
W2729990992 hasConcept C78519656 @default.
W2729990992 hasConceptScore W2729990992C104779481 @default.
W2729990992 hasConceptScore W2729990992C11413529 @default.
W2729990992 hasConceptScore W2729990992C127413603 @default.
W2729990992 hasConceptScore W2729990992C140205800 @default.
W2729990992 hasConceptScore W2729990992C21880701 @default.
W2729990992 hasConceptScore W2729990992C2987684023 @default.
W2729990992 hasConceptScore W2729990992C39432304 @default.
W2729990992 hasConceptScore W2729990992C41008148 @default.
W2729990992 hasConceptScore W2729990992C548081761 @default.
W2729990992 hasConceptScore W2729990992C78519656 @default.
W2729990992 hasLocation W27299909921 @default.
W2729990992 hasOpenAccess W2729990992 @default.
W2729990992 hasPrimaryLocation W27299909921 @default.
W2729990992 hasRelatedWork W2036647282 @default.
W2729990992 hasRelatedWork W2350613216 @default.
W2729990992 hasRelatedWork W2350742080 @default.
W2729990992 hasRelatedWork W2359483999 @default.
W2729990992 hasRelatedWork W2362021508 @default.
W2729990992 hasRelatedWork W2363212894 @default.
W2729990992 hasRelatedWork W2368490218 @default.