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Performance of cryogenic oxygen production unit with exhaust gas bleed for sewage sludge gasification and different oxygen purities

Maja Kaszuba Paweł Ziółkowski Dariusz Mikielewicz
Archives of Thermodynamics | 2023 | vol. 44 | No 3 | 63-81 | DOI: 10.24425/ather.2023.147537
Keywords Thermodynamic analysis Oxy-combustion of syngas BECCS Cryogenic air separation Penalty of oxygen production
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Abstract

The paper presents a thermodynamic analysis of the integration of a cryogenic air separation unit into a negative CO 2 emission gas power plant. The power cycle utilizes sewage sludge as fuel so this system fits into the innovative idea of bioenergy with carbon capture and storage. A cryogenic air separation unit integrated with the power plant was simulated in professional plant engineering and thermodynamic process analysis software. Two cases of the thermodynamic cycle have been studied, namely with the exhaust bleed for fuel treatment and without it. The results of calculations indicate that the net efficiencies of the negative CO 2 emission gas power plant reach 27.05% (combustion in 95.0% pure oxygen) and 24.57% (combustion in 99.5% pure oxygen) with the bleed. The efficiencies of the cycle without the bleed are 29.26% and 27.0% for combustion in 95.0% pure oxygen and 99.5% pure oxygen, respectively. For the mentioned cycle, the calculated energy penalty of oxygen production was 0.235 MWh/kgO 2 for the lower purity value. However, for higher purity namely 99.5%, the energy penalty of oxygen production for the thermodynamic cycle including the bleed and excluding the bleed was indicated 0.346 and 0.347 MWh/kgO 2, respectively. Additionally, the analysis of the oxygen purity impact on the carbon dioxide purity at the end of the carbon capture and storage installation shows that for the case with the bleed, CO 2 purities are 93.8% and 97.6%, and excluding the bleed they are 93.8% and 97.8%, for the mentioned oxygen purities respectively. Insertion of the cryogenic oxygen production installation is required as the considered gas power plant uses oxy-combustion to facilitate carbon capture and storage method.
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Authors and Affiliations

Maja Kaszuba
1
Paweł Ziółkowski
1
Dariusz Mikielewicz
1
  1. Gdansk University of Technology, Narutowicza 11/12, 80-233 Gdansk, Poland

Fluid solid interactions – a novelty in industrial applications

Tomasz Ochrymiuk Mariusz Banaszkiewicz Marcin Lemański Tomasz Kowalczyk Paweł Ziółkowski Piotr J. Ziółkowski Rafał Hyrzyński Michał Stajnke Mateusz Bryk Bartosz Kraszewski Sylwia Kruk-Gotzman Marcin Froissart Janusz Badur
Archives of Thermodynamics | 2022 | vol. 43 | No 2 | 75-96 | DOI: 10.24425/ather.2022.141979
Keywords Computational fluid dynamics Computational solids dynamics Arbitrary Lagrangian Eulerian description Fluid solid interaction Micro-, Nano-mechanics
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Abstract

The article deals with a current state-of-art of fluid solid interaction (FSI) – the new branch of continuum physics. Fluid-solid interaction is a new quality of modeling physical processes of continuum mechanics, it can be described as the interaction of various (so far treated separately from the point of view of mathematical modeling) physical phenomena occurring in continuous media systems. The most correct is the simultaneous application of the laws of the given physical disciplines, which implies that fluid solid interaction is a subset of multi-physical applications where the interactions between these subsets are exchanged on the surface in interconnected systems. Our purpose is to extend the fluid solid interaction aplications into new phenomena what follow from the industrial needs and inovative thechnologies. Selecting the various approaches, we prefer the arbitraty lagrangean-eulerian description within the bulk of fluid/solid domain and a new sort of advanced boundary condition on a surface of common contact.
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Authors and Affiliations

Tomasz Ochrymiuk
1
Mariusz Banaszkiewicz
1 2
Marcin Lemański
1 3
Tomasz Kowalczyk
1
ORCID: ORCID
Paweł Ziółkowski
1 4
Piotr J. Ziółkowski
1
Rafał Hyrzyński
1 5
Michał Stajnke
1
Mateusz Bryk
1
Bartosz Kraszewski
1
Sylwia Kruk-Gotzman
1 6
Marcin Froissart
1
Janusz Badur
1
  1. Institute of Fluid Flow Machinery Polish Academy of Science, Fiszera 14, 80-331 Gdansk, Poland
  2. General Electric Power, Stoczniowa 2, 82-300 Elblag, Poland
  3. Anwil Grupa Orlen, Torunska 222, 87-800 Włocławek, Poland
  4. Gdansk University of Technology, Narutowicza 11/12, 80-233 Gdansk, Poland
  5. Energa S.A. Grunwaldzka 472, 80-309 Gdansk, Poland
  6. Agencja Rynku Energii, Bobrowiecka 3, 00-728 Warszawa, Poland

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