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: 140 points

IMPACT FACTOR 2022: 0.9

CiteScore metrics from Scopus, CiteScore 2022: 1.5

SCImago Journal Rank (SJR) 2022: 0.258

Source Normalized Impact per Paper (SNIP) 2022: 0.512

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

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

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

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

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

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

• R. Kobyłecki, Częstochowa Univ. 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.

Volumes
Instructions for authors

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Content

Archives of Thermodynamics | 2012 | No 1 August

1 Experiments performed with bubbly flow in vertical pipes at different flow conditions covering the transition region: simulation by coupling Eulerian, Lagrangian and 3D random walks models

José Muñoz-Cobo , Sergio Chiva , Mohamed El Aziz Essa , Santos Mendes

Archives of Thermodynamics | 2012 | No 1 August | 3-39 | DOI: 10.2478/v10173-012-0001-4

Keywords: Bubbly flow measurements Eulerian and Lagrangian models Interfacial area concentration

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Abstract

Two phase flow experiments with different superficial velocities of gas and water were performed in a vertical upward isothermal cocurrent air-water flow column with conditions ranging from bubbly flow, with very low void fraction, to transition flow with some cap and slug bubbles and void fractions around 25%. The superficial velocities of the liquid and the gas phases were varied from 0.5 to 3 m/s and from 0 to 0.6 m/s, respectively. Also to check the effect of changing the surface tension on the previous experiments small amounts of 1-butanol were added to the water. These amounts range from 9 to 75 ppm and change the surface tension. This study is interesting because in real cases the surface tension of the water diminishes with temperature, and with this kind of experiments we can study indirectly the effect of changing the temperature on the void fraction distribution. The following axial and radial distributions were measured in all these experiments: void fraction, interfacial area concentration, interfacial velocity, Sauter mean diameter and turbulence intensity. The range of values of the gas superficial velocities in these experiments covered the range from bubbly flow to the transition to cap/slug flow. Also with transition flow conditions we distinguish two groups of bubbles in the experiments, the small spherical bubbles and the cap/slug bubbles. Special interest was devoted to the transition region from bubbly to cap/slug flow; the goal was to understand the physical phenomena that take place during this transition A set of numerical simulations of some of these experiments for bubbly flow conditions has been performed by coupling a Lagrangian code, that tracks the three dimensional motion of the individual bubbles in cylindrical coordinates inside the field of the carrier liquid, to an Eulerian model that computes the magnitudes of continuous phase and to a 3D random walk model that takes on account the fluctuation in the velocity field of the carrier fluid that are seen by the bubbles due to turbulence fluctuations. Also we have included in the model the deformation that suffers the bubble when it touches the wall and it is compressed by the forces that pushes it toward the wall, provoking that the bubble rebound like a ball.

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Authors and Affiliations

José Muñoz-Cobo

Sergio Chiva

Mohamed El Aziz Essa

Santos Mendes

2 Thermal-hydraulic issues of flow boiling and condensation in organic Rankine cycle heat exchangers

Dariusz Mikielewicz , Jarosław Mikielewicz

Archives of Thermodynamics | 2012 | No 1 August | 41-66 | DOI: 10.2478/v10173-012-0002-3

Keywords: Dynamics of heat exchangers Flow stability Heat exchangers

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Abstract

In the paper presented are the issues related to the design and operation of micro heat exchangers, where phase changes can occur, applicable to the domestic micro combined heat and power (CHP) unit. Analysed is the stability of the two-phase flow in such unit. A simple hydraulic model presented in the paper enables for the stability analysis of the system and analysis of disturbance propagation caused by a jump change of the flow rate. Equations of the system dynamics as well as properties of the working fluid are strongly non-linear. A proposed model can be applicable in designing the system of flow control in micro heat exchangers operating in the considered CHP unit.

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Authors and Affiliations

Dariusz Mikielewicz

Jarosław Mikielewicz

3 Models for water steam condensing flows

Włodzimierz Wróblewski , Tadeusz Chmielniak , Sławomir Dykas

Archives of Thermodynamics | 2012 | No 1 August | 67-86 | DOI: 10.2478/v10173-012-0003-2

Keywords: Wet steam Condensing flow models Laval nozzle

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Abstract

The paper presents a description of selected models dedicated to steam condensing flow modelling. The models are implemented into an in-house computational fluid dynamics code that has been successfully applied to wet steam flow calculation for many years now. All models use the same condensation model that has been validated against the majority of available experimental data. The state equations for vapour and liquid water, the physical model as well as the numerical techniques of solution to flow governing equations have been presented. For the single-fluid model, the Reynolds-averaged Navier-Stokes equations for vapour/liquid mixture are solved, whereas the two-fluid model solves separate flow governing equations for the compressible, viscous and turbulent vapour phase and for the compressible and inviscid liquid phase. All described models have been compared with relation to the flow through the Laval nozzle.

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Authors and Affiliations

Włodzimierz Wróblewski

Tadeusz Chmielniak

Sławomir Dykas

4 Pressure drop during condensation of refrigerants in pipe minichannels

Tadeusz Bohdal , Henryk Charun , Małgorzata Sikora

Archives of Thermodynamics | 2012 | No 1 August | 87-106 | DOI: 10.2478/v10173-012-0004-1

Keywords: Compact condenser Condensation in minichannels Pressure drop during flow in condensation

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Abstract

The present paper describes results of experimental investigations of pressure drop during the condensation of R134a, R404a and R407C refrigerants in pipe minichannels with internal diameter 0.31-3.30 mm. The results concern investigations of the mean and local pressure drop in single minichannels. The results of experimental investigations were compared with the calculations according to the correlations proposed by other authors. A pressure drop during the condensation of refrigerants is described in a satisfactory manner with Friedel and Garimella correlations. On the basis of the experimental investigations, the authors proposed their own correlation for calculation of local pressure drop during condensation in single minichannels.

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Authors and Affiliations

Tadeusz Bohdal

Henryk Charun

Małgorzata Sikora

5 CFD simulation of DEBORA boiling experiments

Roland Rzehak , Eckhard Krepper

Archives of Thermodynamics | 2012 | No 1 August | 107-122 | DOI: 10.2478/v10173-012-0005-0

Keywords: Subcooled flow boiling Computational fluid dynamics simulation Heat flux partitioning Two-fluid model

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Abstract

In this work we investigate the present capabilities of computational fluid dynamics for wall boiling. The computational model used combines the Euler/Euler two-phase flow description with heat flux partitioning. This kind of modeling was previously applied to boiling water under high pressure conditions relevant to nuclear power systems. Similar conditions in terms of the relevant non-dimensional numbers have been realized in the DEBORA tests using dichlorodifluoromethane (R12) as the working fluid. This facilitated measurements of radial profiles for gas volume fraction, gas velocity, bubble size and liquid temperature as well as axial profiles of wall temperature. After reviewing the theoretical and experimental basis of correlations used in the ANSYS CFX model used for the calculations, we give a careful assessment of the necessary recalibrations to describe the DEBORA tests. The basic CFX model is validated by a detailed comparison to the experimental data for two selected test cases. Simulations with a single set of calibrated parameters are found to give reasonable quantitative agreement with the data for several tests within a certain range of conditions and reproduce the observed tendencies correctly. Several model refinements are then presented each of which is designed to improve one of the remaining deviations between simulation and measurements. Specifically we consider a homogeneous MUSIG model for the bubble size, modified bubble forces, a wall function for turbulent boiling flow and a partial slip boundary condition for the liquid phase. Finally, needs for further model developments are identified and promising directions discussed.

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Authors and Affiliations

Roland Rzehak

Eckhard Krepper

6 Chaotic air pressure fluctuations during departure of air bubbles from two neighbouring nozzles

Romuald Mosdorf , Tomasz Wyszkowski

Archives of Thermodynamics | 2012 | No 1 August | 127-137 | DOI: 10.2478/v10173-012-0006-z

Keywords: Bubble chain Bubble dynamics Chaotic dynamics

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Abstract

In the experiment, bubbles were generated from two brass nozzles with inner diameters of 1.1 mm. They were submerged in the glass tank filled with distilled water. There have been measured the air pressure fluctuations and the signal from the laser-phototransistor sensor. For analysis of the pressure signal the correlation (the normalized cross - correlation exponent) and non-linear analyses have been used. It has been shown that hydrodynamic interactions between bubbles can lead to bubble departure synchronization. In this case the bubble departures become periodic. The results of calculation of correlation dimension and the largest Lyapunov exponent confirm that hydrodynamic bubble interactions observed for 4 mm spacing between nozzels cause the periodic bubble departures from two neighbouring nozzles.

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Authors and Affiliations

Romuald Mosdorf

Tomasz Wyszkowski

7 Model of heat transfer in the stagnation point of rapidly evaporating microjet

Dariusz Mikielewicz , Jarosław Mikielewicz , Tomasz Muszyński

Archives of Thermodynamics | 2012 | No 1 August | 139-152 | DOI: 10.2478/v10173-012-0007-y

Keywords: Microjet cooling Surface cooling CHF

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Abstract

The paper presents investigation into the single water microjet surface cooling producing evaporating film. Reported tests were conducted under steady state conditions. Experiments were conducted using the nozzle size of 70 and 100 μm respectively. In the course of investigations obtained were experimental relations between heat flux and wall superheating. It was proved that the phenomenon is similar to that of pool boiling but the boiling curves are showing a smaller value of critical heat flux (CHF) that the stagnant pool boiling. Values of CHF are also reduced with decreasing liquid subcooling. Theoretical model of surface cooling by evaporating microjet impingement in the stagnation point was described theoreticaly. Results of experiments were compared with predictions by the model showing a good consistency.

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Authors and Affiliations

Dariusz Mikielewicz

Jarosław Mikielewicz

Tomasz Muszyński

Instructions for authors

Submission of manuscript

Manuscripts should be electronically submitted to the Editorial System http://www.editorialsystem.com/aot. Each manuscript should be accompanied by a cover letter explaining why the manuscript is considered suitable for publication in the journal. The letter should contain:

• full title of the paper,
• full list of authors with affiliations,
• e-mail address of the authors,
• contact address and telephone numbers of the corresponding author.

The cover letter should explicitly state that the manuscript has not been previously published in any language anywhere and that it is not under simultaneous consideration or in press by another journal.

Manuscripts that have been previously rejected, or withdrawn after being returned for modification, may be resubmitted if the major criticisms have been addressed. The cover letter must state that the manuscript is a resubmission, and the former manuscript number should be provided.
All authors of the manuscript are responsible for its content; they must have agreed to its publication and have given the corresponding author the authority to act on their behalf. The corresponding author is responsible for informing the co-authors of the manuscript status throughout the submission, review, and production process.

From January 1, 2024, the authors are requested to submit their paper using a dedicated template provided at the AOT webpage https://www.imp.gda.pl/archives-of-thermodynamics/.

Notes for Contributors

Archives of Thermodynamics publishes original papers which have not previously appeared in other journals. The journal does not have article processing charges (APCs) nor article submission charges. The language of the papers is English. The authors are responsible to prepare papers with good English. All pages should be numbered.

Paper preparation quidelines

1. The manuscript should be written in very good English, using the two-column format provided in the template.

2. The heading should specify the title (as short as possible), author, his/her complete affiliation, town, zip code, country and e-mail. Please indicate the corresponding author. The heading should be followed by Abstract and Keywords.

3. More important symbols used in the paper should be listed in Nomenclature, placed below Abstract and arranged in a column, e.g.:
u – velocity, m/s
v – specific volume, m/kg etc.

The list should begin with Latin symbols in alphabetical order followed by Greek symbols also in alphabetical order and with a separate heading. Subscripts and superscripts should follow Greek symbols and should be identified with separate headings. Physical quantities should be expressed in SI units ( Système International d’Unités). In the template a dedicated area is created to put the nomenclature.

4. All abbreviations should be spelled out first time they are introduced in the text. Abbreviations should also be listed in the Nomenclature.

5. The equations should be each in a separate line. Standard mathematical notation should be used. All symbols used in equations must be clearly defined. The numbers of equations should run consecutively, irrespective of the division of the paper into sections. The numbers should be given in round brackets on the righthand side of the column.

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9. The figures should also be submitted as separate graphic files in either vector formats (PostScript (PS), Encapsulated PostScript (EPS), preferable, CorelDraw (CDR), etc.) or bitmap formats (Tagged Image File Format (TIFF), Joint Photographic Experts Group (JPEG), etc.), with the resolution not lower than 300 dpi, preferably 600 dpi. These resolutions refer to images sized at dimensions comparable to those of figures in the print journal. Therefore, electronic figures should be sized to fit on single printed page and can have maximum 120 mm x 170 mm.

10. The references for the paper should be numbered in the order in which they are called in the text. Calling the references is by giving the appropriate numbers in square brackets. The references should be listed with the following information provided: the author’s surname and the initials of his/her names, the complete title of the work (in English translation) and, in addition:

The references should be placed after the acknowledgment section. The references citation in the manuscript body should be numbered: [1], [2], etc. Please use the following style of references in bibliography APA – 7th ed:

Journal citation (APA – 7th ed):
[1] Król, J., & Ocłoń, P. (2019). Sensitivity analysis of hybrid combined heat and power plant on fuel and CO2 emission allowances price change. Energy Conversion and Management, 196, 127–148.
doi.org/10.1016/j.enconman.2019.05.090

[2] Zhou, Y., Bi, H., & Wang, H. (2023). Influence of the primary components of the high-speed train on fire heat release rate. Archives of Thermodynamics, 44(1), 37–61.
doi.org/10.24425/ather.2023.145876

When citing scientific papers, it is needed to provide a DOI identifier if available.
Example of citation:
• Król and Ocłoń [1] studied a hybrid CHP sensitivity on fuel and CO2 emission allowances price change.
• Zhou et al. [2] studied the influence of the primary components of the high speed train on fire heat release rate.

Book citation (APA – 7th ed):
[3] Ocłoń, P. (2021). Renewable energy utilization using underground energy systems (1st ed.). Springer Nature.
Example of citation:
• Ocłoń et al. [3] presented renewable energy systems for heating cooling and electrical energy production in buildings.

Book chapter citation (APA – 7th ed):
[4] Ciałkowski, M., & Frąckowiak, A. (2014). Boundary element method in inverse heat conduction problem. In Encyclopedia of Thermal Stresses (pp. 424–433). Springer Netherlands.
Example of citation:
• Ciałkowski and Frąckowiak [4] presented a Boundary element method application for solving inverse heat conduction problems.

Conference proceedings (APA – 7th ed):
[5] Pourghasemi, B., & Fathi, N. (2023). Validation and verification analyses of turbulent forced convection of Na and NaK in miniature heat sinks. ASME 2023 Verification, Validation, and Uncertainty Quantification Symposium, 17-19 May, Baltimore, USA.
Example of citation:
• Pourghasemi and Fathi [5] validated and verified turbulent forced convection of Na and NaK in miniature heat sinks.
For works originally published in a language other than English, the language should be indicated in parentheses at the end of the reference. Authors are responsible for ensuring that the information in each reference is complete and accurate, including the DOI number.

11. As the papers are published in English, the authors who are not native speakers of English are obliged to have the paper thoroughly reviewed language-wise before submitting for publication. When the Editors or Reviewers assess that the writing English of the manuscript is poor, the authors are obliged to correct it, and provide a Certificate of English Editing as attachment in Editorial System.

Further information

All manuscripts will undergo some editorial modification. The paper proofs (as PDF file) will be sent by e-mail to the corresponding author for acceptance, and should be returned within two weeks of receipt. Within the proofs corrections of minor and typographical errors in: author names, affiliations, articles titles, abstracts and keywords, formulas, symbols, grammatical error, details in figures, etc., are only allowed, as well as necessary small additions. The changes within the text will be accepted in case of serious errors, for example with regard to scientific accuracy, or if authors reputation and that of the journal would be affected. Submitted material will not be returned to the author, unless specifically requested. A PDF file of published paper will be supplied free of charge to the Corresponding Author. Submission of the manuscript expresses at the same time the authors consent to its publishing in both printed and electronic versions.

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All papers are published under lincense CC BY 4.0. Once a paper has been accepted for publication, as a condition of publication, the authors are asked to send a scanned copy of the signed original of the Transfer of Copyright Agreement, signed by the Corresponding Author on behalf of all authors.