Brzić, Danica


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2023 (1)
2022 (1)


article (2)


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restrictedAccess (1)

Link to this page

http://cer.ihtm.bg.ac.rs/APP/faces/author.xhtml?author_id=orcid%3A%3A0000-0002-8109-316X&item_offset=0&project_offset=0&sort_by=dc.date.issued

Authority Key	Name Variants
orcid::0000-0002-8109-316X	Brzić, Danica (2)

Projects

Ministry of Education, Science and Technological Development, Republic of Serbia, Grant no. 451-03-68/2020-14/200026 (University of Belgrade, Institute of Chemistry, Technology and Metallurgy - IChTM)	The development of efficient chemical-engineering processes based on the transport phenomena research and process intensification principles
Ministry of Education, Science and Technological Development, Republic of Serbia, Grant no. 451-03-68/2020-14/200135 (University of Belgrade, Faculty of Technology and Metallurgy)

Author's Bibliography

Heat transfer to a sphere immersed in a fluidized bed of coarse particles with transition from bubbling to turbulent flow regime

Brzić, Danica; Pešić, Radojica; Arsenijević, Zorana; Đuriš, Mihal; Bošković-Vragolović, Nevenka; Kaluđerović-Radoičić, Tatjana

(Taylor & Francis, 2023)

TY  - JOUR
AU  - Brzić, Danica
AU  - Pešić, Radojica
AU  - Arsenijević, Zorana
AU  - Đuriš, Mihal
AU  - Bošković-Vragolović, Nevenka
AU  - Kaluđerović-Radoičić, Tatjana
PY  - 2023
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/5247
AB  - The present work concerns an experimental study on heat transfer in gas-solid fluidized bed of coarse (Geldart D) particles to a larger immersed sphere at high superficial velocities from 2 to 5.5 Umf. The heat transfer coefficient was determined by measuring the temperature of the test sphere during its heating in a fluidized bed in the temperature range of 65–175 °C. The test spheres of different sizes and different materials were utilized. For the given gas-particles system the flow regime changes from rapidly growing bubbles to turbulent fluidization at superficial velocity Uc ≈ 3Umf. It has been found that in rapidly growing bubbles regime, the heat transfer coefficient is higher for smaller test spheres while it is almost independent of the superficial gas velocity. In turbulent regime, the heat transfer coefficient increases with increase of gas velocity while the size of the test sphere exhibits less influence. In the rapidly growing bubbles regime, experimental data for heat transfer coefficient can be predicted adequately with correlation of Scott et al.. For the turbulent flow regime a new correlation for prediction of the heat transfer coefficient has been proposed.
PB  - Taylor & Francis
T2  - Particulate Science and Technology
T1  - Heat transfer to a sphere immersed in a fluidized bed of coarse particles with transition from bubbling to turbulent flow regime
VL  - 41
IS  - 1
SP  - 75
EP  - 83
DO  - 10.1080/02726351.2022.2053015
ER  -

@article{
author = "Brzić, Danica and Pešić, Radojica and Arsenijević, Zorana and Đuriš, Mihal and Bošković-Vragolović, Nevenka and Kaluđerović-Radoičić, Tatjana",
year = "2023",
abstract = "The present work concerns an experimental study on heat transfer in gas-solid fluidized bed of coarse (Geldart D) particles to a larger immersed sphere at high superficial velocities from 2 to 5.5 Umf. The heat transfer coefficient was determined by measuring the temperature of the test sphere during its heating in a fluidized bed in the temperature range of 65–175 °C. The test spheres of different sizes and different materials were utilized. For the given gas-particles system the flow regime changes from rapidly growing bubbles to turbulent fluidization at superficial velocity Uc ≈ 3Umf. It has been found that in rapidly growing bubbles regime, the heat transfer coefficient is higher for smaller test spheres while it is almost independent of the superficial gas velocity. In turbulent regime, the heat transfer coefficient increases with increase of gas velocity while the size of the test sphere exhibits less influence. In the rapidly growing bubbles regime, experimental data for heat transfer coefficient can be predicted adequately with correlation of Scott et al.. For the turbulent flow regime a new correlation for prediction of the heat transfer coefficient has been proposed.",
publisher = "Taylor & Francis",
journal = "Particulate Science and Technology",
title = "Heat transfer to a sphere immersed in a fluidized bed of coarse particles with transition from bubbling to turbulent flow regime",
volume = "41",
number = "1",
pages = "75-83",
doi = "10.1080/02726351.2022.2053015"
}

Brzić, D., Pešić, R., Arsenijević, Z., Đuriš, M., Bošković-Vragolović, N.,& Kaluđerović-Radoičić, T.. (2023). Heat transfer to a sphere immersed in a fluidized bed of coarse particles with transition from bubbling to turbulent flow regime. in Particulate Science and Technology
Taylor & Francis., 41(1), 75-83.
https://doi.org/10.1080/02726351.2022.2053015

Brzić D, Pešić R, Arsenijević Z, Đuriš M, Bošković-Vragolović N, Kaluđerović-Radoičić T. Heat transfer to a sphere immersed in a fluidized bed of coarse particles with transition from bubbling to turbulent flow regime. in Particulate Science and Technology. 2023;41(1):75-83.
doi:10.1080/02726351.2022.2053015 .

Brzić, Danica, Pešić, Radojica, Arsenijević, Zorana, Đuriš, Mihal, Bošković-Vragolović, Nevenka, Kaluđerović-Radoičić, Tatjana, "Heat transfer to a sphere immersed in a fluidized bed of coarse particles with transition from bubbling to turbulent flow regime" in Particulate Science and Technology, 41, no. 1 (2023):75-83,
https://doi.org/10.1080/02726351.2022.2053015 . .

	2
	2

Heat transfer by liquid convection in particulate fluidized beds

Jaćimovski, Darko; Brzić, Danica; Garić Grulović, Radmila; Pjanović, Rada; Đuriš, Mihal; Arsenijević, Zorana; Bošković-Vragolović, Nevenka

(Belgrade : Serbian Chemical Society, 2022)

TY  - JOUR
AU  - Jaćimovski, Darko
AU  - Brzić, Danica
AU  - Garić Grulović, Radmila
AU  - Pjanović, Rada
AU  - Đuriš, Mihal
AU  - Arsenijević, Zorana
AU  - Bošković-Vragolović, Nevenka
PY  - 2022
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/5248
AB  - In this work the theoretical model for heat transfer from a wall to aliquid-solid fluidized bed by liquid convective mechanism has been proposed.The model is based on thickness of boundary layer and film theory. The keyparameter in the model is the distance between two adjacent particles whichcollide with the wall. According to the proposed model, the liquid convectiveheat transfer in a fluidized bed is 4 to 5 times more intense than in a single-phaseflow. Additionally, the wall-to-bed heat transfer coefficient has been measuredexperimentally in water –glass particles fluidized bed, for different particle sizes.Comparison of the model prediction with experimental data has shown that sizeof the particles strongly influences the mechanism of heat transfer. For fineparticles of 0.8 mm in diameter, the liquid convective heat transfer modelrepresents adequately the experimental data, indicating that particle convectivemechanism is negligible. For coarse particles of 1.5 - 2 mm in diameter, theliquid convective heat transfer mechanism accounts for 60 % of the overall heattransfer coefficient
AB  - У овом раду развијен је теоријски модел преноса топлоте конвективним механизмомса зида колоне на течност у партикулативно флуидизованом слоју. Модел је заснован надебљини граничног слоја и теорији филма. Кључни параметар модела је растојање измеђудвe суседне честице које се сударају са зидом колоне. Према предложеном моделу преностоплоте конвекцијом на течност у флуидизованом слоју је 4 до 5 пута интензивнији него уједнофазном току. Коефицијенти преноса топлоте су експериментално одређени уфлуидизованом слоју вода-стаклене сфере, за различите пречнике честица. Поређењеексперименталних резултата и предвиђања модела је показало да пречник честица значајноутиче на механизам преноса топлоте. За веома ситне честице пречника 0.8 mm, моделпреноса топлоте конвекцијом на течност у потпуности репрезентује експерименталнерезултате, указујући да је пренос топлоте честицама занемарљив. За крупне честице,пречника 1.5 -2 mm, конвективни пренос на течност чини 60 % од укупног коефицијентапреноса топлоте
PB  - Belgrade : Serbian Chemical Society
T2  - Journal of the Serbian Chemical Society
T1  - Heat transfer by liquid convection in particulate fluidized beds
T1  - Пренос топлоте конвективним механизмом у партикулативно флуидизованом слоју
VL  - 87
IS  - 7-8
SP  - 911
EP  - 924
DO  - 10.2298/JSC211216020J
ER  -

@article{
author = "Jaćimovski, Darko and Brzić, Danica and Garić Grulović, Radmila and Pjanović, Rada and Đuriš, Mihal and Arsenijević, Zorana and Bošković-Vragolović, Nevenka",
year = "2022",
abstract = "In this work the theoretical model for heat transfer from a wall to aliquid-solid fluidized bed by liquid convective mechanism has been proposed.The model is based on thickness of boundary layer and film theory. The keyparameter in the model is the distance between two adjacent particles whichcollide with the wall. According to the proposed model, the liquid convectiveheat transfer in a fluidized bed is 4 to 5 times more intense than in a single-phaseflow. Additionally, the wall-to-bed heat transfer coefficient has been measuredexperimentally in water –glass particles fluidized bed, for different particle sizes.Comparison of the model prediction with experimental data has shown that sizeof the particles strongly influences the mechanism of heat transfer. For fineparticles of 0.8 mm in diameter, the liquid convective heat transfer modelrepresents adequately the experimental data, indicating that particle convectivemechanism is negligible. For coarse particles of 1.5 - 2 mm in diameter, theliquid convective heat transfer mechanism accounts for 60 % of the overall heattransfer coefficient, У овом раду развијен је теоријски модел преноса топлоте конвективним механизмомса зида колоне на течност у партикулативно флуидизованом слоју. Модел је заснован надебљини граничног слоја и теорији филма. Кључни параметар модела је растојање измеђудвe суседне честице које се сударају са зидом колоне. Према предложеном моделу преностоплоте конвекцијом на течност у флуидизованом слоју је 4 до 5 пута интензивнији него уједнофазном току. Коефицијенти преноса топлоте су експериментално одређени уфлуидизованом слоју вода-стаклене сфере, за различите пречнике честица. Поређењеексперименталних резултата и предвиђања модела је показало да пречник честица значајноутиче на механизам преноса топлоте. За веома ситне честице пречника 0.8 mm, моделпреноса топлоте конвекцијом на течност у потпуности репрезентује експерименталнерезултате, указујући да је пренос топлоте честицама занемарљив. За крупне честице,пречника 1.5 -2 mm, конвективни пренос на течност чини 60 % од укупног коефицијентапреноса топлоте",
publisher = "Belgrade : Serbian Chemical Society",
journal = "Journal of the Serbian Chemical Society",
title = "Heat transfer by liquid convection in particulate fluidized beds, Пренос топлоте конвективним механизмом у партикулативно флуидизованом слоју",
volume = "87",
number = "7-8",
pages = "911-924",
doi = "10.2298/JSC211216020J"
}

Jaćimovski, D., Brzić, D., Garić Grulović, R., Pjanović, R., Đuriš, M., Arsenijević, Z.,& Bošković-Vragolović, N.. (2022). Heat transfer by liquid convection in particulate fluidized beds. in Journal of the Serbian Chemical Society
Belgrade : Serbian Chemical Society., 87(7-8), 911-924.
https://doi.org/10.2298/JSC211216020J

Jaćimovski D, Brzić D, Garić Grulović R, Pjanović R, Đuriš M, Arsenijević Z, Bošković-Vragolović N. Heat transfer by liquid convection in particulate fluidized beds. in Journal of the Serbian Chemical Society. 2022;87(7-8):911-924.
doi:10.2298/JSC211216020J .

Jaćimovski, Darko, Brzić, Danica, Garić Grulović, Radmila, Pjanović, Rada, Đuriš, Mihal, Arsenijević, Zorana, Bošković-Vragolović, Nevenka, "Heat transfer by liquid convection in particulate fluidized beds" in Journal of the Serbian Chemical Society, 87, no. 7-8 (2022):911-924,
https://doi.org/10.2298/JSC211216020J . .