Zarić, Milana M.


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2022 (1)
2015 (1)


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conferenceObject (1)


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Link to this page

http://TechnoRep.tmf.bg.ac.rs/APP/faces/author.xhtml?author_id=581e7eeb-2f58-4e1c-b754-05cc97fb59db&item_offset=0&project_offset=0&sort_by=dc.date.issued

Authority Key	Name Variants
581e7eeb-2f58-4e1c-b754-05cc97fb59db	Zarić, Milana M. (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)	Ministry of Education, Science and Technological Development, Republic of Serbia, Grant no. 451-03-68/2020-14/200125 (University of Novi Sad, Faculty of Science)
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)	Novel encapsulation and enzyme technologies for designing of new biocatalysts and biologically active compounds targeting enhancement of food quality, safety and competitiveness
Secretariat for Higher Education and Scientific Research of the Autonomous Province of Vojvodina, Serbia (grant no. 142-451-2545/2021-01/2).

Author's Bibliography

Thermodynamic Properties of Caffeine in Ethylene Glycol at High Pressures and High Temperatures

Zarić, Milana M.; Vraneš, Milan; Bikić, Siniša; Tot, Aleksandar; Papović, Snežana; Borović, Teona Teodora; Kijevčanin, Mirjana Lj.; Radović, Ivona R.

(American Chemical Society, 2022)

TY  - JOUR
AU  - Zarić, Milana M.
AU  - Vraneš, Milan
AU  - Bikić, Siniša
AU  - Tot, Aleksandar
AU  - Papović, Snežana
AU  - Borović, Teona Teodora
AU  - Kijevčanin, Mirjana Lj.
AU  - Radović, Ivona R.
PY  - 2022
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/5246
AB  - Ethylene glycol is recognized as a heat transfer fluid. To improve its performance, caffeine is added to pure ethylene glycol. The experimental measurements of densities at pressures of up to 60 MPa and in the range of temperatures 293.15-413.15 K were performed. Obtained experimental results were fitted by the modified Tammann-Tait equation, and parameters were used to determine some valuable thermodynamic and mechanical properties, the isothermal compressibility, the isobaric thermal expansibility, the internal pressure, and the difference of specific heat capacity at constant pressure and constant volume. The same approach was applied to the equimolar mixture of ethylene glycol and water. The results confirm negligible changes in the investigated thermodynamic properties with the addition of caffeine into pure ethylene glycol and significantly smaller dependence on temperature compared to the mixture of ethylene glycol and water.
PB  - American Chemical Society
T2  - Journal of Chemical and Engineering Data
T1  - Thermodynamic Properties of Caffeine in Ethylene Glycol at High Pressures and High Temperatures
DO  - 10.1021/acs.jced.2c00401
ER  -

@article{
author = "Zarić, Milana M. and Vraneš, Milan and Bikić, Siniša and Tot, Aleksandar and Papović, Snežana and Borović, Teona Teodora and Kijevčanin, Mirjana Lj. and Radović, Ivona R.",
year = "2022",
abstract = "Ethylene glycol is recognized as a heat transfer fluid. To improve its performance, caffeine is added to pure ethylene glycol. The experimental measurements of densities at pressures of up to 60 MPa and in the range of temperatures 293.15-413.15 K were performed. Obtained experimental results were fitted by the modified Tammann-Tait equation, and parameters were used to determine some valuable thermodynamic and mechanical properties, the isothermal compressibility, the isobaric thermal expansibility, the internal pressure, and the difference of specific heat capacity at constant pressure and constant volume. The same approach was applied to the equimolar mixture of ethylene glycol and water. The results confirm negligible changes in the investigated thermodynamic properties with the addition of caffeine into pure ethylene glycol and significantly smaller dependence on temperature compared to the mixture of ethylene glycol and water.",
publisher = "American Chemical Society",
journal = "Journal of Chemical and Engineering Data",
title = "Thermodynamic Properties of Caffeine in Ethylene Glycol at High Pressures and High Temperatures",
doi = "10.1021/acs.jced.2c00401"
}

Zarić, M. M., Vraneš, M., Bikić, S., Tot, A., Papović, S., Borović, T. T., Kijevčanin, M. Lj.,& Radović, I. R.. (2022). Thermodynamic Properties of Caffeine in Ethylene Glycol at High Pressures and High Temperatures. in Journal of Chemical and Engineering Data
American Chemical Society..
https://doi.org/10.1021/acs.jced.2c00401

Zarić MM, Vraneš M, Bikić S, Tot A, Papović S, Borović TT, Kijevčanin ML, Radović IR. Thermodynamic Properties of Caffeine in Ethylene Glycol at High Pressures and High Temperatures. in Journal of Chemical and Engineering Data. 2022;.
doi:10.1021/acs.jced.2c00401 .

Zarić, Milana M., Vraneš, Milan, Bikić, Siniša, Tot, Aleksandar, Papović, Snežana, Borović, Teona Teodora, Kijevčanin, Mirjana Lj., Radović, Ivona R., "Thermodynamic Properties of Caffeine in Ethylene Glycol at High Pressures and High Temperatures" in Journal of Chemical and Engineering Data (2022),
https://doi.org/10.1021/acs.jced.2c00401 . .

	1
	1

Optimization of waste heat recovery via heat integration

Zarić, Milana M.; Stijepović, Mirko; Linke, Patrick; Kijevčanin, Mirjana; Stajić-Trošić, Jasna; Bugarski, Branko

(Zvornik : Tehnološki fakultet, 2015)

TY - CONF
AU - Zarić, Milana M.
AU - Stijepović, Mirko
AU - Linke, Patrick
AU - Kijevčanin, Mirjana
AU - Stajić-Trošić, Jasna
AU - Bugarski, Branko
PY - 2015
UR - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/7358
AB - Fossil fuels are widely used to provide energy in major industrial sectors, while consumption of
fossil fuel leads to undesirable increases in greenhouse gas emissions, causing climate changes.
Because of it is important to use energy in more efficient way in order to reduce theneedofusing
fossil fuel. Heat recovery and reuse of waste heat is a promising approach to increase energy
efficiency, saving energy whichleadstoreduceddemands for fossil fuels.
The goal of this study is to minimize the fuel consumption by maximizing energy efficiency via
indirect heat integration of multiple processes in an industrial zone. Theproposedmodel is
applied on a case study, which consists of multiple plants,served by a centralized
utilitysystem,which provides required heat and power for processes.Theadvantage of the used
model is simplicity and its linear programming formulation (LP).
AB - Fosilna goriva imaju veliku ulogu u obezbeđivanju potrebne energije u većini industrijskih sektora.
Potrošnja fosilnih goriva dovodi do neželjenog povećanja emisije gasova staklene bašte,
koji uzrokuju klimatske promene.Zbog potrebe da se smanji potrošnja fosilnih goriva,
rekuperacija otpadne toplote je pristup koji obećava povećanje energetske efikasnoti, jer se
energija štedi, što dovodi do manjih zahteva za potrošnju fosilnih goriva. Cilj ove studije je svođenje upotrebe fosilnih goriva na minimum, time što se
maksimizuje energetska efikasnost kroz indirektnu toplotnu integraciju. Predloženi model
toplotne integracije je primenjen na case studiju, kojapredstavlja industrijsku zonu sa više postrojenja.
Predpostavlja se da se industrijaska zona snabdeva centralizovani mutiliti sistemom,
koji obezbeđuje potrebnu količinu toplote i energije za sve procese. Prednost korišćenog modela je
jednostavnost i linearnost programske formulacije (LP programiranje).
PB - Zvornik : Tehnološki fakultet
C3 - Knjiga radova = Proceedings / IV međunarodni kongres "Inženjerstvo, ekologija i materijali u procesnoj industriji", Jahorina, 04.03.- 06.03. 2015. = IV International Congress "Engineering, Ecology and Materials in the Processing Industry"
T1 - Optimization of waste heat recovery via heat integration
T1 - Optimizacija rekuperacije toplote pomoću toplotne integracije
EP - 602
SP - 598
DO - 10.7251/EEMEN1501598Z
ER -

@conference{
author = "Zarić, Milana M. and Stijepović, Mirko and Linke, Patrick and Kijevčanin, Mirjana and Stajić-Trošić, Jasna and Bugarski, Branko",
year = "2015",
abstract = "Fossil fuels are widely used to provide energy in major industrial sectors, while consumption of
fossil fuel leads to undesirable increases in greenhouse gas emissions, causing climate changes.
Because of it is important to use energy in more efficient way in order to reduce theneedofusing
fossil fuel. Heat recovery and reuse of waste heat is a promising approach to increase energy
efficiency, saving energy whichleadstoreduceddemands for fossil fuels.
The goal of this study is to minimize the fuel consumption by maximizing energy efficiency via
indirect heat integration of multiple processes in an industrial zone. Theproposedmodel is
applied on a case study, which consists of multiple plants,served by a centralized
utilitysystem,which provides required heat and power for processes.Theadvantage of the used
model is simplicity and its linear programming formulation (LP)., Fosilna goriva imaju veliku ulogu u obezbeđivanju potrebne energije u većini industrijskih sektora.
Potrošnja fosilnih goriva dovodi do neželjenog povećanja emisije gasova staklene bašte,
koji uzrokuju klimatske promene.Zbog potrebe da se smanji potrošnja fosilnih goriva,
rekuperacija otpadne toplote je pristup koji obećava povećanje energetske efikasnoti, jer se
energija štedi, što dovodi do manjih zahteva za potrošnju fosilnih goriva. Cilj ove studije je svođenje upotrebe fosilnih goriva na minimum, time što se
maksimizuje energetska efikasnost kroz indirektnu toplotnu integraciju. Predloženi model
toplotne integracije je primenjen na case studiju, kojapredstavlja industrijsku zonu sa više postrojenja.
Predpostavlja se da se industrijaska zona snabdeva centralizovani mutiliti sistemom,
koji obezbeđuje potrebnu količinu toplote i energije za sve procese. Prednost korišćenog modela je
jednostavnost i linearnost programske formulacije (LP programiranje).",
publisher = "Zvornik : Tehnološki fakultet",
journal = "Knjiga radova = Proceedings / IV međunarodni kongres "Inženjerstvo, ekologija i materijali u procesnoj industriji", Jahorina, 04.03.- 06.03. 2015. = IV International Congress "Engineering, Ecology and Materials in the Processing Industry"",
title = "Optimization of waste heat recovery via heat integration, Optimizacija rekuperacije toplote pomoću toplotne integracije",
pages = "602-598",
doi = "10.7251/EEMEN1501598Z"
}

Zarić, M. M., Stijepović, M., Linke, P., Kijevčanin, M., Stajić-Trošić, J.,& Bugarski, B.. (2015). Optimization of waste heat recovery via heat integration. in Knjiga radova = Proceedings / IV međunarodni kongres "Inženjerstvo, ekologija i materijali u procesnoj industriji", Jahorina, 04.03.- 06.03. 2015. = IV International Congress "Engineering, Ecology and Materials in the Processing Industry"
Zvornik : Tehnološki fakultet., 598-602.
https://doi.org/10.7251/EEMEN1501598Z

Zarić MM, Stijepović M, Linke P, Kijevčanin M, Stajić-Trošić J, Bugarski B. Optimization of waste heat recovery via heat integration. in Knjiga radova = Proceedings / IV međunarodni kongres "Inženjerstvo, ekologija i materijali u procesnoj industriji", Jahorina, 04.03.- 06.03. 2015. = IV International Congress "Engineering, Ecology and Materials in the Processing Industry". 2015;:598-602.
doi:10.7251/EEMEN1501598Z .

Zarić, Milana M., Stijepović, Mirko, Linke, Patrick, Kijevčanin, Mirjana, Stajić-Trošić, Jasna, Bugarski, Branko, "Optimization of waste heat recovery via heat integration" in Knjiga radova = Proceedings / IV međunarodni kongres "Inženjerstvo, ekologija i materijali u procesnoj industriji", Jahorina, 04.03.- 06.03. 2015. = IV International Congress "Engineering, Ecology and Materials in the Processing Industry" (2015):598-602,
https://doi.org/10.7251/EEMEN1501598Z . .