Authors:
Orest VoznyakDepartment of Heat and Gas Supply and Ventilation, Institute of Civil Engineering and Building Systems, Lviv Polytechnic National University, Lviv, Ukraine

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Nadiia SpodyniukDepartment of Heat and Power Engineering, Education and Research Institute of Energetics, Automation and Energy Efficiency, National University of Life and Environmental Sciences of Ukraine, Kyiv, Ukraine

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https://orcid.org/0000-0002-2865-9320
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Oleksandr DovbushDepartment of Heat and Gas Supply and Ventilation, Institute of Civil Engineering and Building Systems, Lviv Polytechnic National University, Lviv, Ukraine

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Olena SavchenkoDepartment of Heat and Gas Supply and Ventilation, Institute of Civil Engineering and Building Systems, Lviv Polytechnic National University, Lviv, Ukraine

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Iryna SukholovaDepartment of Heat and Gas Supply and Ventilation, Institute of Civil Engineering and Building Systems, Lviv Polytechnic National University, Lviv, Ukraine

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Mariana KasynetsDepartment of Heat and Gas Supply and Ventilation, Institute of Civil Engineering and Building Systems, Lviv Polytechnic National University, Lviv, Ukraine

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Iryna KirakevychDepartment of Building Production, Institute of Civil Engineering and Building Systems, Lviv Polytechnic National University, Lviv, Ukraine

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Abstract

The article is devoted to research of properties of the round convective air jet. The aim of this work is to establish universal graphical dependencies and empirical formulas for describing velocity and temperature fields over the entire range of development of round convective exhaust ventilation jet; development of an algorithm for solving the transcendent problem of determining the surface temperature of a heat source; introduction of velocity and temperature attenuation coefficients for round convective jet; visualization of its characteristics in the form of a 3D image; achieving reduction of metal consumption of the local exhaust ventilation system due to the overall optimization of the velocity and temperature fields of the round convective air jet.

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    O. Voznyak, N. Spodyniuk, I. Sukholova, O. Dovbush, M. Kasynets, and O. Datsko, “Diagnosis of damage to the ventilation system,” Diagnostyka, vol. 22, no. 3, pp. 9199, 2021.

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    O. Voznyak, N. Spodyniuk, I. Sukholova, O. Savchenko, M. Kasynets, and O. Datsko, “Diagnosis of three types damages to the ventilation system,” Diagnostyka , vol. 23, no. 1, 2022, Paper no. 2022102.

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    V. Petrenko, K. Dykarev, D. Volchok, and O. Kuzmenko, “Evaluation of indoor temperature for various building envelopes damaged,” E3S Web of Conferences , vol. 32, 2018, Paper no. 01019.

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    V. Petrenko, K. Dikarev, A. Petrenko, and R. Papirnyk, “The calculation of indoor air forecast temperature of a space with the replaceable thermotechnical characteristics of the enclosure structures while in operation,” in Proceedings of EcoComfort 2020, Lviv, Ukraine, September 16‒18, 2020, vol. 100, Z. Blikharskyy, Ed., Lecture Notes in Civil Engineering, 2021, pp. 319327.

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    P. Kapalo, H. Klymenko, V. Zhelykh, and M. Adamski, “Investigation of indoor air quality in the selected Ukraine classroom - Case study,” in Proceedings of CEE 2019, Lviv, Ukraine, September 11‒13, 2019, vol. 47, Z. Blikharskyy, P. Koszelnik, and P. Mesaros, Eds, Lecture Notes in Civil Engineering, 2020, pp. 168173.

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    P. Kapalo, M. Sulewska, and M. Adamski, “Examining the interdependence of the various parameters of indoor air,” in Proceedings of EcoComfort 2020, Lviv, Ukraine, September 16‒18, 2020, vol. 100, Z. Blikharskyy, Ed., Lecture Notes in Civil Engineering, 2021, pp. 150157.

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    P. Kapalo, S. Vilčeková, L. Mečiarová, F. Domnita, and M. Adamski, “Influence of indoor climate on employees in office buildings - A case study,” Sustainability, vol. 12, no. 14, 2020, Paper no. 5569.

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    О. Voznyak, N. Spodyniuk, O. Savchenko, O. Dovbush, M. Kasynets, and O. Datsko, “Analysis of premise infrared heating and ventilation with an exhaust outlet and flat decking air flow,” Diagnostyka , vol. 23, no. 2, 2022, Paper no. 2022207.

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    Z. Poorova and Z. Vranayova, “Humidity, air temperature, CO2 and well-being of people with and without green wall,” in Proceedings of EcoComfort 2020, Lviv, Ukraine, September 16‒18, 2020, vol. 100, Z. Blikharskyy, Ed., Lecture Notes in Civil Engineering, 2021, pp. 336346.

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    F. Vranay and Z. Vranayova, “Influence of heat source choice on building energy certification process and CO2 emissions,” in Proceedings of CEE 2019, Lviv, Ukraine, September 11‒13, 2019, vol. 47, Z. Blikharskyy, P. Koszelnik, and P. Mesaros, Eds, Lecture Notes in Civil Engineering, 2020, pp. 541548.

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    O. Voznyak, K. Myroniuk, I. Sukholova, and P. Kapalo, “The impact of air flows on the environment,” in Proceedings of CEE 2019, Lviv, Ukraine, September 11‒13, 2019, vol. 47, Z. Blikharskyy, P. Koszelnik, and P. Mesaros, Eds, Lecture Notes in Civil Engineering, 2020, pp. 534540.

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  • [12]

    O. Gumen, N. Spodyniuk, M. Ulewicz, and Y. Martyn, “Research of thermal processes in industrial premises with energy-saving technologies of heating,” Diagnostyka, vol. 18, no. 2, pp. 4349, 2017.

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    B. Basok, B. Davydenko, G. Farenuyk, and S. Goncharuk, “Computational modeling of the temperature regime in a room with a two-panel radiator,” J. Eng. Phys. Thermophys. , vol. 87, no. 6, pp. 14331437, 2014.

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    R. Khmil, R. Tytarenko, Y. Blikharskyy, and P. Vegera, “The probabilistic calculation model of RC beams, strengthened by RC jacket,” in Proceedings of EcoComfort 2020, Lviv, Ukraine, September 16‒18, 2020, vol. 100, Z. Blikharskyy, Ed., Lecture Notes in Civil Engineering, 2021, pp. 182191.

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  • [15]

    Z. Blikharskyy, N. Shnal, and R. Khmil, “The influence of the damaged reinforcing bars on the stress-strain state of the rein-forced concrete beams,” Prod. Eng. Arch., vol. 14, no. 14, pp. 2326, 2017.

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  • [16]

    U. Marushchak, M. Sanytsky, O. Pozniak, and O. Mazurak, “Peculiarities of nanomodified portland systems structure formation,” Chem. Chem. Technol. , vol. 13, no. 4, pp. 510517, 2019.

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  • [17]

    P. Novosad, O. Pozniak, V. Melnyk, and S. BraichenkoPorous thermal insulation materials on organic and mineral fillers,” in Proceedings of CEE 2019, Lviv, Ukraine, September 11–13, 2019, vol. 47, Z. Blikharskyy, P. Koszelnik, and P. Mesaros, Eds, Lecture Notes in Civil Engineering, 2020, pp. 354360.

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  • [18]

    K. Myroniuk, O. Voznyak, Yu. Yurkevych, and B. Gulay, “Technical and economic efficiency after the boiler room renewal,” in Proceedings of EcoComfort 2020, Lviv, Ukraine, September 16–18, 2020, vol. 100, Z. Blikharskyy, Ed., Lecture Notes in Civil Engineering, 2021, pp. 311318.

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  • [19]

    O. Voznyak, N. Spodyniuk, O. Savchenko, I. Sukholova, and M. Kasynets, “Еnhancing of energetic and economic efficiency of coal mines heating by infrared heaters,” Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu , vol. 2, no. 182, pp. 104109, 2021.

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  • [20]

    N. Spodyniuk, V. Zhelykh, and O. Dzeryn, Combined heating systems of premises for breeding of young pigs and poultry,” FME Trans. , vol. 46, pp. 651657, 2018.

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  • [21]

    О. Voznyak, O. Savchenko, N. Spodyniuk, I. Sukholova, M. Kasynets, and O. Dovbush, “Improving of ventilation efficiency at air distribution by the swirled air jets,” Pollack Periodica, vol. 17, no. 1, pp. 123127, 2022.

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  • [22]

    V. Zhelykh, O. Voznyak, Yu. Yurkevych, I. Sukholova, and O. Dovbush, “Enhancing of energetic and economic efficiency of air distribution by swirled-compact air jets”, Prod. Eng. Arch. , vol. 27, no. 3, pp. 171175, 2021.

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  • [23]

    N. Spodyniuk, O. Voznyak, O. Savchenko, O. Dovbush, M. Kasynets, and O. Datsko, “Analysis of premise infrared heating and ventilation with an exhaust outlet and flat decking air flow,” Diagnostyka , vol. 23, no. 2, 2022, Paper no. 2022107.

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  • [24]

    M. Adamski, “MathModelica in modeling of countercurrent heat exchangers,” in Proceedings, 8th EUROSIM Congress on Modeling and Simulation, Cardiff, UK, Sept. 10–13, 2013, pp. 439442.

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  • [25]

    O. Voznyak, N. Spodyniuk, Yu. Yurkevych, I. Sukholova, and O. Dovbush, “Enhancing efficiency of air distribution by swirled-compact air jets in the mine using the heat utilizators,” Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, vol. 5, no. 179, pp. 8994, 2020.

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  • [26]

    O. Savchenko, O. Voznyak, K. Myroniuk, and O. Dovbush, “Thermal renewal of industrial buildings gas supply system,” in Proceedings of EcoComfort 2020, Lviv, Ukraine, September 16–18, 2020, vol. 100, Z. Blikharskyy, Ed., Lecture Notes in Civil Engineering, 2021, pp. 385392.

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  • [27]

    O. Savchenko, V. Zhelykh, Y. Yurkevych, S. Shapoval, and K. Kozak, “Using vortex tube for decreasing losses of natural gas in engineering systems of gas supply,” Pollack Periodica, vol. 13, no. 3, pp. 241250, 2018.

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  • [28]

    S. Shapoval, P. Shapoval, V. Zhelykh, O. Pona, N. Spodyniuk, B. Gulai, O. Savchenko, and K. Myroniuk, “Ecological and energy aspects of using the combined solar collectors for low-energy houses”, Chem. Chem. Technol., vol. 11, no. 4. pp. 503508, 2017.

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  • [29]

    S. Shapoval, V. Zhelykh, N. Spodyniuk, O. Dzeryn, and B. Gulai, “The effectiveness to use the distribution manifold in the construction of the solar wall for the conditions of circulation,” Pollack Periodica , vol. 14, no. 2, pp. 143154, 2019.

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    I. Tymchuk, M. Malovanyy, O. Shkvirko, V. Zhuk, A. Masikevych, and S. Synelnikov, “Innovative creation technologies for the growth substrate based on the man-made waste - Perspective way for Ukraine to ensure biological reclamation of waste dumps and quarries,” Int. J. Foresight Innovation Pol. , vol. 14, nos 2–4, pp. 248263, 2020.

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    L. Bytčanková, J. Rumann, and P. Dušička, “Distribution of flow velocity in a shaft intake structure,” Pollack Periodica , vol. 17, no. 1, pp. 8387, 2022.

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    R. Hnativ and O. Verbovskiy, “Distribution of local velocities in a circular pipe with accelerating fluid flow”, Eastern-European J. Enterprise Tech. , vol. 2, no. 7–98, pp. 5863, 2019.

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    O. Voznyak, Y. Yurkevych, O. Dovbush, and Y. Serediuk, “The influence of chairs and passengers on air velocity in bus passenger compartment,” in Proceedings of CEE 2019, Lviv, Ukraine, September 11–13, 2019, vol. 47, Z. Blikharskyy, P. Koszelnik, and P. Mesaros, Eds, Lecture Notes in Civil Engineering, 2020, pp. 518525.

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    A. Klymchuk, V. Lozhechnikov, V. Mykhailenko, and N. Lozhechnikova, “Improved mathematical model of fluid level dynamics in a drum-type steam generator as a controlled object,” J. Automation Inf. Sci. , vol. 51, no. 5, pp. 6574, 2019.

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    V. Labay, O. Savchenko, V. Zhelykh, and K. Kozak, “Mathematical modeling of the heating process in a vortex tube at the gas distribution stations,” Math. Model. Comput. , vol. 6, no. 2, pp. 311319, 2019.

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    A. Yefimov and T. Potanina, “Application of interval analysis for improving reliability of estimation of hardness value spread for nuclear structural materials,” Probl. At. Sci. Technologythis, vol. 125, no. 1, pp. 206210, 2020.

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    K. Dikarev, O. Kuzmenko, V. Petrenko, P. Sankov, L. Kyslytsia, and N. Ibadov, “Experimental study of operating indicators of a thermalactic covering panel,” Sci. Innovation, vol. 16, no. 2, pp. 5765, 2020.

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Editor(s)-in-Chief: Iványi, Amália

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  • Bálint Bachmann (Institute of Architecture, Faculty of Engineering and Information Technology, University of Pécs, Hungary)
  • Jeno Balogh (Department of Civil Engineering Technology, Metropolitan State University of Denver, Denver, Colorado, USA)
  • Radu Bancila (Department of Geotechnical Engineering and Terrestrial Communications Ways, Faculty of Civil Engineering and Architecture, “Politehnica” University Timisoara, Romania)
  • Charalambos C. Baniotopolous (Department of Civil Engineering, Chair of Sustainable Energy Systems, Director of Resilience Centre, School of Engineering, University of Birmingham, U.K.)
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  • Matteo Bruggi (Dipartimento di Ingegneria Civile e Ambientale, Politecnico di Milano, Italy)
  • Petra Bujňáková (Department of Structures and Bridges, Faculty of Civil Engineering, University of Žilina, Slovakia)
  • Anikó Borbála Csébfalvi (Department of Civil Engineering, Institute of Smart Technology and Engineering, Faculty of Engineering and Information Technology, University of Pécs, Hungary)
  • Mirjana S. Devetaković (Faculty of Architecture, University of Belgrade, Serbia)
  • Szabolcs Fischer (Department of Transport Infrastructure and Water Resources Engineering, Faculty of Architerture, Civil Engineering and Transport Sciences Széchenyi István University, Győr, Hungary)
  • Radomir Folic (Department of Civil Engineering, Faculty of Technical Sciences, University of Novi Sad Serbia)
  • Jana Frankovská (Department of Geotechnics, Faculty of Civil Engineering, Slovak University of Technology in Bratislava, Slovakia)
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  • Elena Helerea (Dept. of Electrical Engineering and Applied Physics, Faculty of Electrical Engineering and Computer Science, Transilvania University of Brasov, Romania)
  • Ákos Hutter (Department of Architecture and Urban Planning, Institute of Architecture, Faculty of Engineering and Information Technolgy, University of Pécs, Hungary)
  • Károly Jármai (Institute of Energy and Chemical Machinery, Faculty of Mechanical Engineering and Informatics, University of Miskolc, Hungary)
  • Teuta Jashari-Kajtazi (Department of Architecture, Faculty of Civil Engineering and Architecture, University of Prishtina, Kosovo)
  • Róbert Kersner (Department of Technical Informatics, Institute of Information and Electrical Technology, Faculty of Engineering and Information Technology, University of Pécs, Hungary)
  • Rita Kiss  (Biomechanical Cooperation Center, Faculty of Mechanical Engineering, Budapest University of Technology and Economics, Budapest, Hungary)
  • István Kistelegdi  (Department of Building Structures and Energy Design, Institute of Architecture, Faculty of Engineering and Information Technology, University of Pécs, Hungary)
  • Stanislav Kmeť (President of University Science Park TECHNICOM, Technical University of Kosice, Slovakia)
  • Imre Kocsis  (Department of Basic Engineering Research, Faculty of Engineering, University of Debrecen, Hungary)
  • László T. Kóczy (Department of Information Sciences, Faculty of Mechanical Engineering, Informatics and Electrical Engineering, University of Győr, Hungary)
  • Dražan Kozak (Faculty of Mechanical Engineering, Josip Juraj Strossmayer University of Osijek, Croatia)
  • György L. Kovács (Department of Technical Informatics, Institute of Information and Electrical Technology, Faculty of Engineering and Information Technology, University of Pécs, Hungary)
  • Balázs Géza Kövesdi (Department of Structural Engineering, Faculty of Civil Engineering, Budapest University of Engineering and Economics, Budapest, Hungary)
  • Tomáš Krejčí (Department of Mechanics, Faculty of Civil Engineering, Czech Technical University in Prague, Czech Republic)
  • Jaroslav Kruis (Department of Mechanics, Faculty of Civil Engineering, Czech Technical University in Prague, Czech Republic)
  • Miklós Kuczmann (Department of Automations, Faculty of Mechanical Engineering, Informatics and Electrical Engineering, Széchenyi István University, Győr, Hungary)
  • Tibor Kukai (Department of Engineering Studies, Institute of Smart Technology and Engineering, Faculty of Engineering and Information Technology, University of Pécs, Hungary)
  • Maria Jesus Lamela-Rey (Departamento de Construcción e Ingeniería de Fabricación, University of Oviedo, Spain)
  • János Lógó  (Department of Structural Mechanics, Faculty of Civil Engineering, Budapest University of Technology and Economics, Hungary)
  • Carmen Mihaela Lungoci (Faculty of Electrical Engineering and Computer Science, Universitatea Transilvania Brasov, Romania)
  • Frédéric Magoulés (Department of Mathematics and Informatics for Complex Systems, Centrale Supélec, Université Paris Saclay, France)
  • Gabriella Medvegy (Department of Interior, Applied and Creative Design, Institute of Architecture, Faculty of Engineering and Information Technology, University of Pécs, Hungary)
  • Tamás Molnár (Department of Visual Studies, Institute of Architecture, Faculty of Engineering and Information Technology, University of Pécs, Hungary)
  • Ferenc Orbán (Department of Mechanical Engineering, Institute of Smart Technology and Engineering, Faculty of Engineering and Information Technology, University of Pécs, Hungary)
  • Zoltán Orbán (Department of Civil Engineering, Institute of Smart Technology and Engineering, Faculty of Engineering and Information Technology, University of Pécs, Hungary)
  • Dmitrii Rachinskii (Department of Mathematical Sciences, The University of Texas at Dallas, Texas, USA)
  • Chro Radha (Chro Ali Hamaradha) (Sulaimani Polytechnic University, Technical College of Engineering, Department of City Planning, Kurdistan Region, Iraq)
  • Maurizio Repetto (Department of Energy “Galileo Ferraris”, Politecnico di Torino, Italy)
  • Zoltán Sári (Department of Technical Informatics, Institute of Information and Electrical Technology, Faculty of Engineering and Information Technology, University of Pécs, Hungary)
  • Grzegorz Sierpiński (Department of Transport Systems and Traffic Engineering, Faculty of Transport, Silesian University of Technology, Katowice, Poland)
  • Zoltán Siménfalvi (Institute of Energy and Chemical Machinery, Faculty of Mechanical Engineering and Informatics, University of Miskolc, Hungary)
  • Andrej Šoltész (Department of Hydrology, Faculty of Civil Engineering, Slovak University of Technology in Bratislava, Slovakia)
  • Zsolt Szabó (Faculty of Information Technology and Bionics, Pázmány Péter Catholic University, Hungary)
  • Mykola Sysyn (Chair of Planning and Design of Railway Infrastructure, Institute of Railway Systems and Public Transport, Technical University of Dresden, Germany)
  • András Timár (Faculty of Engineering and Information Technology, University of Pécs, Hungary)
  • Barry H. V. Topping (Heriot-Watt University, UK, Faculty of Engineering and Information Technology, University of Pécs, Hungary)

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2021  
Web of Science  
Total Cites
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Scimago  
Scimago
H-index
12
Scimago
Journal Rank
0,26
Scimago Quartile Score Civil and Structural Engineering (Q3)
Materials Science (miscellaneous) (Q3)
Computer Science Applications (Q4)
Modeling and Simulation (Q4)
Software (Q4)
Scopus  
Scopus
Cite Score
1,5
Scopus
CIte Score Rank
Civil and Structural Engineering 232/326 (Q3)
Computer Science Applications 536/747 (Q3)
General Materials Science 329/455 (Q3)
Modeling and Simulation 228/303 (Q4)
Software 326/398 (Q4)
Scopus
SNIP
0,613

2020  
Scimago
H-index
11
Scimago
Journal Rank
0,257
Scimago
Quartile Score
Civil and Structural Engineering Q3
Computer Science Applications Q3
Materials Science (miscellaneous) Q3
Modeling and Simulation Q3
Software Q3
Scopus
Cite Score
340/243=1,4
Scopus
Cite Score Rank
Civil and Structural Engineering 219/318 (Q3)
Computer Science Applications 487/693 (Q3)
General Materials Science 316/455 (Q3)
Modeling and Simulation 217/290 (Q4)
Software 307/389 (Q4)
Scopus
SNIP
1,09
Scopus
Cites
321
Scopus
Documents
67
Days from submission to acceptance 136
Days from acceptance to publication 239
Acceptance
Rate
48%

 

2019  
Scimago
H-index
10
Scimago
Journal Rank
0,262
Scimago
Quartile Score
Civil and Structural Engineering Q3
Computer Science Applications Q3
Materials Science (miscellaneous) Q3
Modeling and Simulation Q3
Software Q3
Scopus
Cite Score
269/220=1,2
Scopus
Cite Score Rank
Civil and Structural Engineering 206/310 (Q3)
Computer Science Applications 445/636 (Q3)
General Materials Science 295/460 (Q3)
Modeling and Simulation 212/274 (Q4)
Software 304/373 (Q4)
Scopus
SNIP
0,933
Scopus
Cites
290
Scopus
Documents
68
Acceptance
Rate
67%

 

Pollack Periodica
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Pollack Periodica
Language English
Size A4
Year of
Foundation
2006
Volumes
per Year
1
Issues
per Year
3
Founder Akadémiai Kiadó
Founder's
Address
H-1117 Budapest, Hungary 1516 Budapest, PO Box 245.
Publisher Akadémiai Kiadó
Publisher's
Address
H-1117 Budapest, Hungary 1516 Budapest, PO Box 245.
Responsible
Publisher
Chief Executive Officer, Akadémiai Kiadó
ISSN 1788-1994 (Print)
ISSN 1788-3911 (Online)

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