Applied sciences

Archives of Thermodynamics

Description

The aim of the quarterly journal Archives of Thermodynamics is to disseminate knowledge between scientists and engineers worldwide and to provide a forum for original research conducted in the field of thermodynamics, heat transfer, fluid flow, combustion and energy conversion in various aspects of thermal sciences, mechanical and power engineering. Besides original research papers, review articles are also welcome.

The journal scope of interest encompasses in particular, but is not limited to:

Classical and extended non-equilibrium thermodynamics,

Thermodynamic analysis including exergy,

Thermodynamics of heating and cooling,

Thermodynamics of nuclear power generation,

Thermodynamics in defense engineering,

Advances in thermodynamics,

Experimental, theoretical and numerical heat transfer,

Heat and momentum transfer in multiphase flows and nanofluids,

Renewable energy sources including solar energy,

Hydrogen Energy,

Thermal Energy Conversion,

Energy Transition,

Advanced Energy Carriers,

Energy storage and efficiency,

Energy in buildings,

Secondary fuels and fuel conversion,

Combustion and emissions,

Thermal incineration of wastes and waste heat recovery,

Thermal and energy system analysis,

Combined and integrated energy systems,

Distributed energy generation,

Turbomachinery.

Appears since 1980, four issues per year.

Publication funding of this journal is provided by resources of the Polish Academy of Sciences and The Szewalski Institute of the Fluid-Flow Machinery of the Polish Academy of Sciences.

Scoring assigned by the Polish Ministry of Science and Higher Education: 70 points

IMPACT FACTOR 2023: 0.8

CiteScore metrics from Scopus, CiteScore 2023: 1.8

SCImago Journal Rank (SJR) 2023: 0.25

Source Normalized Impact per Paper (SNIP) 2023: 0.395

H-index: 17

Overall Rank/Ranking: 17629

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ISSN

ISSN 1231-0956, eISSN 2083-6023

Publishers

The Committee of Thermodynamics and Combustion of the Polish Academy of Sciences and The Institute of Fluid-Flow Machinery Polish Academy of Sciences

International Advisory Board

J. Bataille, Ecole Central de Lyon, Ecully, France

A. Bejan, Duke University, Durham, USA

A. C. Benim, Duesseldorf University of Applied Sciences, Germany

W. Blasiak, Royal Institute of Technology, Stockholm, Sweden

G. P. Celata, ENEA, Rome, Italy

L.M. Cheng, Zhejiang University, Hangzhou, China

M. Colaco, Federal University of Rio de Janeiro, Brazil

J. M. Delhaye, CEA, Grenoble, France

M. Giot, Université Catholique de Louvain, Belgium

K. Hooman, University of Queensland, Australia

D. Jackson, University of Manchester, UK

D.F. Li, Kunming University of Science and Technology, Kunming, China

K. Kuwagi, Okayama University of Science, Japan

J. P. Meyer, University of Pretoria, South Africa

S. Michaelides, Texas Christian University, Fort Worth Texas, USA

M. Moran, Ohio State University, Columbus, USA

W. Muschik, Technische Universität Berlin, Germany

I. Müller, Technische Universität Berlin, Germany

H. Nakayama, Japanese Atomic Energy Agency, Japan

S. Nizetic, University of Split, Croatia

H. Orlande, Federal University of Rio de Janeiro, Brazil

M. Podowski, Rensselaer Polytechnic Institute, Troy, USA

A. Rusanov, Institute for Mechanical Engineering Problems NAS, Kharkiv, Ukraine

M. R. von Spakovsky, Virginia Polytechnic Institute and State University, Blacksburg, USA

A. Vallati, Sapienza University of Rome, Italy

H.R. Yang, Tsinghua University, Beijing, China

Supervisory Editors

• T. Bohdal, Koszalin University of Technology, Poland

• M. Lackowski, Institute of Fluid Flow Machinery, Gdańsk, Poland

Honorary Editor

• J. Mikielewicz, Institute of Fluid Flow Machinery, Gdańsk, Poland

Editor-in-Chief

• P. Ocłoń, Cracow University of Technology, Cracow, Poland

Section Editors

• P. Lampart, Institute of Fluid Flow Machinery, Gdańsk, Poland

• S. Polesek-Karczewska, Institute of Fluid Flow Machinery, Gdańsk, Poland

• I. Szczygieł, Silesian University of Technology, Gliwice, Poland

• A. Szlęk, Silesian University of Technology, Gliwice, Poland

Technical Editors

• J. Frączak, Institute of Fluid Flow Machinery, Gdańsk, Poland

• S. Łopata, Institute of Fluid Flow Machinery, Gdańsk, Poland

Members of Programme Committee

• D. Kardaś (chairman): Inst. Fluid Flow Mach., Gdańsk, Poland

• J. Badur, Inst. Fluid Flow Mach., Gdańsk, Poland

• T. Chmielniak, Silesian Univ. Tech., Gliwice, Poland

• P. Furmański, Warsaw Univ. Tech., Poland

• R. Kobyłecki, Częstochowa Univ. Tech., Poland

• S. Pietrowicz, Wrocław Univ. Sci. Tech., Poland

• J. Wajs, Gdańsk Univ. Tech., Poland

Wydawnictwo IMP

The Szewalski Institute of Fluid Flow Machinery PAS

Fiszera 14, 80-952 Gdańsk, Poland

telephone: +48 58 5225 141, fax: +48 58 3416 144

e-mail: jfrk@imp.gda.pl; redakcja@imp.gda.pl

http://www.imp.gda.pl/archives-of-thermodynamics/

https://www.journals.pan.pl/ather

For articles published in Archives of Thermodynamics, the authors transfer copyright to publisher.

The Archives of Thermodynamics is published in formula: Open Access Gratis.

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Content

Archives of Thermodynamics | 2021 | vol. 42 | No 3

1 Calculation of the furnace exit gas temperature of stoker fired boilers

Łukasz Rutkowski , Ireneusz Szczygieł

Archives of Thermodynamics | 2021 | vol. 42 | No 3 | 3-24 | DOI: 10.24425/ather.2021.138107

Keywords: FEGT CKTI Grate boilers calculations Furnace

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Abstract

In the paper the methodology of furnace exit gas temperature calculations by using well known normative standard method CKTI is presented. There are shown changes in methodology approach for three editions of it and in additional developments. Furnace exit gas temperature for two stoker grate boilers is calculated. By using described methods, it was possible to determine their effectiveness by comparing with measurements. Knowledge of the furnace exit gas temperature allows to define the division into irradiated and convection surfaces, which has an impact on the design features of the boiler as well as its dimensions and weight.

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Bibliography

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Authors and Affiliations

Łukasz Rutkowski

Ireneusz Szczygieł

Boilers Manufacturer SEFAKO S.A., Przemysłowa 9, 28-340 Sedziszów, Poland
Silesian University of Technology Institute of Thermal Technology, Konarskiego 22, 44-100 Gliwice, Poland

2 Passive cooling through the atmospheric window for vehicle temperature control

Umara Khan , Ron Zevenhoven

Archives of Thermodynamics | 2021 | vol. 42 | No 3 | 25-44 | DOI: 10.24425/ather.2021.138108

Keywords: Thermal radiation Passive cooling Vehicle Skylight greenhouse effect Computational Fluid Dynamics

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Abstract

One of the most energy-intensive activities for a vehicle is space air conditioning, for either cooling or heating. Considerable energy savings can be achieved if this can be decoupled from the use of fuel or electricity. This study analyzes the opportunities and effectiveness of deploying the concept of passive cooling through the atmospheric window (i.e. the 8– 14 nm wavelength range where the atmosphere is transparent for thermal radiation) for vehicle temperature control. Recent work at our institute has resulted in a skylight (roof window) design for passive cooling of building space. This should be applicable to vehicles as well, using the same materials and design concept. An overall cooling effect is obtained if outgoing (long wavelength greater than 4 nm) thermal radiation is stronger than the incoming (short wavelength less than 4 nm) thermal radiation. Of particular interest is to quantify the passive cooling of a vehicle parked under direct/indirect sunlight equipped with a small skylight, designed based on earlier designs for buildings. The work involved simulations using commercial computational fluid dynamics software implementing (where possible) wavelengthdependency of thermal radiation properties of materials involved. The findings show that by the use of passive cooling, a temperature difference of up to 7–8 K is obtained with an internal gas flow rate of 0.7 cm/s inside the skylight. A passive cooling effect of almost 27 W/m2 is attainable for summer season in Finland. Comparison of results from Ansys Fluent and COMSOL models shows differences up to about 10 W/m2 in the estimations.

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Authors and Affiliations

Umara Khan

Ron Zevenhoven

Abo Akademi University, Process and Systems Engineering Laboratory, Henrikinkatu 2, 20500 Turku, Finland

3 Determining steam condensation pressure in a power plant condenser in off-design conditions

Rafał Laskowski , Adam Smyk , Adam Ruciński , Jacek Szymczyk

Archives of Thermodynamics | 2021 | vol. 42 | No 3 | 45-62 | DOI: 10.24425/ather.2021.138109

Keywords: Thermal power plant Steam condenser Condenser model Steam condensation pressure Reference parameters Steam condenser effectiveness

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Abstract

The paper presents formulas which can be used to determine steam condensation pressure in a power plant condenser in off-design conditions. The mathematical model provided in the paper makes it possible to calculate the performance of the condenser in terms of condensing steam pressure, cooling water temperature at the condenser outlet, and condenser effectiveness under variable load conditions as a function of three input properties: the temperature and the mass flow rate of cooling water at the condenser inlet and the mass flow rate of steam. The mathematical model takes into account values of properties occurring in reference conditions but it contains no constant coefficients which would have to be established based on data from technical specifications of a condenser or measurement data. Since there are no such constant coefficients, the model of the steam condenser proposed in the paper is universally applicable. The proposed equations were checked against warranty measurements made in the condenser and measurement data gathered during the operation of a 200 MW steam power unit. Based on the analysis, a conclusion may be drawn that the proposed means of determining pressure in a condenser in off-design conditions reflects the condenser performance with sufficient accuracy. This model can be used in optimization and diagnostic analyses of the performance of a power generation unit.

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Authors and Affiliations

Rafał Laskowski

Adam Smyk

Adam Ruciński

Jacek Szymczyk

Institute of Heat Engineering, Faculty of Power and Aeronautical Engineering, Warsaw University of Technology, Nowowiejska 21/25, 00-665 Warsaw, Poland

4 Wet steam flow in 1100 MW turbine

Gukchol Jun , Michal Kolovratník , Michal Hoznedl

Archives of Thermodynamics | 2021 | vol. 42 | No 3 | 63-85 | DOI: 10.24425/ather.2021.138110

Keywords: Steam turbine Wet steam loss Non-equilibrium condensation CFD

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Abstract

The paper deals with the wet steam flow in a steam turbine operating in a nuclear power plant. Using a pneumatic and an optical probe, the static pressure, steam velocity, steam wetness and the fine water droplets diameter spectra were measured before and beyond the last turbine low-pressure stage. The results of the experiment serve to understand better the wet steam flow and map its liquid phase in this area. The wet steam data is also used to modify the condensation model used in computational fluid dynamics simulations. The condensation model, i.e. the nucleation rate and the growth rate of the droplets, is adjusted so that results of the numerical simulations are in a good agreement with the experimental results. A 3D computational fluid dynamics simulations was performed for the lowpressure part of the turbine considering non-equilibrium steam condensation. In the post-processing of the of the numerical calculation result, the thermodynamic wetness loss was evaluated and analysed. Loss analysis was performed for the turbine outputs of 600, 800, and 1100 MW, respectively.

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Authors and Affiliations

Gukchol Jun

1 2

Michal Kolovratník

Michal Hoznedl

Czech Technical University in Prague, Technická 4, 160 00, Prague, Czech Republic
Doosan Škoda Power s.r.o., Tylova 1/57, 301 28, Pilsen, Czech Republic

5 Computational fluid dynamics simulation of heat transfer from densely packed gold nanoparticles to isotropic media

Piotr Radomski , Paweł Ziółkowski , Luciano de Sio , Dariusz Mikielewicz

Archives of Thermodynamics | 2021 | vol. 42 | No 3 | 87-113 | DOI: 10.24425/ather.2021.138111

Keywords: Heat transfer gold nanoparticles Glasses Polymers Computational Fluid Dynamics

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Abstract

This work aims to determine and compare heat generation and propagation of densely packed gold nanoparticles (Au NPs) induced by a resonant laser beam (532 nm) according to the Mie theory. The heat flux propagation is transferred into the materials, which h