Savić, Aleksandar

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  • Savić, Aleksandar (4)
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Author's Bibliography

Applying concept of 3d printing concrete in wind tower construction

Savić, Aleksandar; Stević, Miša; Martinović, Sanja; Vlahović, Milica; Volkov-Husović, Tatjana

(Beograd : Savez mašinskih i elektrotehničkih inženjera i tehničara Srbije - SMEITS, 2020) 

TY  - CONF
AU  - Savić, Aleksandar
AU  - Stević, Miša
AU  - Martinović, Sanja
AU  - Vlahović, Milica
AU  - Volkov-Husović, Tatjana
PY  - 2020
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/4417
AB  - Although a most prominent material in contemporary construction practice due to its’ obvious advantages, concrete incorporates a number of drawbacks. It is one of the most advantageous principles for decades to enable a large-scale on-site application of this materials with acceptable properties, needed to withstand specific conditions. A concept of 3d printing concrete presents a promising ground for further improvement of this principle. While maintaining as much as possible of the prerequisite and common properties to answer the construction demands, this material has to evolve as much as possible to fulfill the 3d concept, which would, in turn, pave a way for next level of its wide range of construction applications. This paper aims to contain main principles of 3d printing concrete, discussing the main goals and the drawbacks that have to be addressed and solved prior to wider application. Also, wind tower construction, as a specific construction will be discussed as a potentially promising ground for this old construction material dressed in a new suit.
AB  - Iako je najčešće primenjivan materijal u savremenoj građevinskoj praksi zbog svojih očiglednih prednosti, beton poseduje izvestan broj nedostataka. Jedan od najvažnijih principa već decenijama je da se omogući masovna upotreba ovog materijala na gradilištima sa prihvatljivim svojstvima, neophodnim da bi on podneo specifične uslove. Koncept 3d štampe betona predstavlja obećavajuću osnovu za dalje poboljšanje ovog principa. Zadržavajući što veći broj preduslova i osnovnih svojstava da bi se zadovoljili konstruktivni zahtevi, ovaj materijal mora umnogome evoluirati da bi zadovoljio 3d concept, što bi, zauzvrat, popločalo put do sledećeg nivoa njegovog širokog obima primene u graditeljstvu. Cilj ovog rada je da sadrži osnovne principe 3d štampe betona, diskutujući glavne ciljeve I nedostatke koji se moraju sagledati i rešiti pre šire primene. Takođe, konstrukcija stuba vetrogeneratora, kao specifična konstrukcija biće diskutovana kao potencijalno obećavajuća osnova za ovaj stari građevinski materijal odeven u novo odelo.
PB  - Beograd : Savez mašinskih i elektrotehničkih inženjera i tehničara Srbije - SMEITS
C3  - Proceedings - 8th International Conference on Renewable Electrical Power Sources
T1  - Applying concept of 3d printing concrete in wind tower construction
T1  - Primena koncepta 3d štampe betona u izradi vetrogeneratora
EP  - 46
SP  - 43
DO  - 10.24094/mkoiee.020.8.1.43
ER  - 
@conference{
author = "Savić, Aleksandar and Stević, Miša and Martinović, Sanja and Vlahović, Milica and Volkov-Husović, Tatjana",
year = "2020",
abstract = "Although a most prominent material in contemporary construction practice due to its’ obvious advantages, concrete incorporates a number of drawbacks. It is one of the most advantageous principles for decades to enable a large-scale on-site application of this materials with acceptable properties, needed to withstand specific conditions. A concept of 3d printing concrete presents a promising ground for further improvement of this principle. While maintaining as much as possible of the prerequisite and common properties to answer the construction demands, this material has to evolve as much as possible to fulfill the 3d concept, which would, in turn, pave a way for next level of its wide range of construction applications. This paper aims to contain main principles of 3d printing concrete, discussing the main goals and the drawbacks that have to be addressed and solved prior to wider application. Also, wind tower construction, as a specific construction will be discussed as a potentially promising ground for this old construction material dressed in a new suit., Iako je najčešće primenjivan materijal u savremenoj građevinskoj praksi zbog svojih očiglednih prednosti, beton poseduje izvestan broj nedostataka. Jedan od najvažnijih principa već decenijama je da se omogući masovna upotreba ovog materijala na gradilištima sa prihvatljivim svojstvima, neophodnim da bi on podneo specifične uslove. Koncept 3d štampe betona predstavlja obećavajuću osnovu za dalje poboljšanje ovog principa. Zadržavajući što veći broj preduslova i osnovnih svojstava da bi se zadovoljili konstruktivni zahtevi, ovaj materijal mora umnogome evoluirati da bi zadovoljio 3d concept, što bi, zauzvrat, popločalo put do sledećeg nivoa njegovog širokog obima primene u graditeljstvu. Cilj ovog rada je da sadrži osnovne principe 3d štampe betona, diskutujući glavne ciljeve I nedostatke koji se moraju sagledati i rešiti pre šire primene. Takođe, konstrukcija stuba vetrogeneratora, kao specifična konstrukcija biće diskutovana kao potencijalno obećavajuća osnova za ovaj stari građevinski materijal odeven u novo odelo.",
publisher = "Beograd : Savez mašinskih i elektrotehničkih inženjera i tehničara Srbije - SMEITS",
journal = "Proceedings - 8th International Conference on Renewable Electrical Power Sources",
title = "Applying concept of 3d printing concrete in wind tower construction, Primena koncepta 3d štampe betona u izradi vetrogeneratora",
pages = "46-43",
doi = "10.24094/mkoiee.020.8.1.43"
}
Savić, A., Stević, M., Martinović, S., Vlahović, M.,& Volkov-Husović, T.. (2020). Applying concept of 3d printing concrete in wind tower construction. in Proceedings - 8th International Conference on Renewable Electrical Power Sources
Beograd : Savez mašinskih i elektrotehničkih inženjera i tehničara Srbije - SMEITS., 43-46.
https://doi.org/10.24094/mkoiee.020.8.1.43
Savić A, Stević M, Martinović S, Vlahović M, Volkov-Husović T. Applying concept of 3d printing concrete in wind tower construction. in Proceedings - 8th International Conference on Renewable Electrical Power Sources. 2020;:43-46.
doi:10.24094/mkoiee.020.8.1.43 .
Savić, Aleksandar, Stević, Miša, Martinović, Sanja, Vlahović, Milica, Volkov-Husović, Tatjana, "Applying concept of 3d printing concrete in wind tower construction" in Proceedings - 8th International Conference on Renewable Electrical Power Sources (2020):43-46,
https://doi.org/10.24094/mkoiee.020.8.1.43 . .

Enhancing properties of concrete by addition of fly ash from a thermal power plant for application in geothermal systems

Vlahović, Milica; Savić, Aleksandar; Martinović, Sanja; Đorđević, Nataša; Stević, Zoran; Volkov-Husović, Tatjana

(Beograd : Savez mašinskih i elektrotehničkih inženjera i tehničara Srbije - SMEITS, 2020) 

TY  - CONF
AU  - Vlahović, Milica
AU  - Savić, Aleksandar
AU  - Martinović, Sanja
AU  - Đorđević, Nataša
AU  - Stević, Zoran
AU  - Volkov-Husović, Tatjana
PY  - 2020
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/4415
AB  - Electric power in Serbia is predominantly provided by thermal power plants. All of eleven existing thermal power plants in Serbia use coal, mainly lignite in the electricity production process thus generating about 6 million tons of fly ash per year. The estimated amount of fly ash from thermal power plants accumulated in Serbian landfills exceeds 200 million tons. On the other hand, during the last decades, respecting the principles of ecologically sustainable development has been imposed on industries, and one of them is the construction industry. Due to the presence of amorphous SiO2 and Al2O3, fly ash as pozzolanic material is convenient for the production of concrete and mortar. Consequently, multiple positive effects can be expected by the proper consumption of fly ash- reducing landfills and improving concrete properties. The idea of this study is to analyze the possibility of recycling fly ash from a thermal power plant by replacing a part of common mineral filler- limestone in the production of self-compacting concrete (SCC). Properties of conventional SCC with limestone and compositions with different fly ash content were compared. Considering that requirements for SCC should be satisfied and all properties remain or enhance in the case of fly ash addition, this study proved that all designed concretes can be used for structural applications.
AB  - Električnu energiju u Srbiji pretežno obezbeđuju termoelektrane. Svih jedanaest termoelektrana u Srbiji koriste ugalj, uglavnom lignit u procesu proizvodnje električne energije, čime se godišnje generiše oko 6 miliona tona letećeg pepela. Procenjena količina letećeg pepela iz termoelektrana akumulirana na deponijama u Srbiji prelazi 200 miliona tona. S druge strane, poslednjih decenija poštovanje principa ekološki održivog razvoja nametnuto je industrijama, a jedna od njih je i građevinska. Zahvaljujući prisustvu amorfnog SiO2 i Al2O3, pepeo kao pucolanski materijal pogodan je za proizvodnju betona i maltera. Zbog toga se pravilnom upotrebom letećeg pepela mogu očekivati višestruki pozitivni efekti- smanjenje deponija i poboljšanje svojstava betona. Ideja ovog istraživanja je analiziranje mogućnosti recikliranja letećeg pepela iz termoelektrane tako što će delimično zameniti uobičajeni mineralni punioc- krečnjak u proizvodnji samozbijajućeg betona (SCC). Upoređena su svojstva konvencionalnog SCC sa krečnjakom i kompozicija sa različitim sadržajem pepela. S obzirom da je u slučaju dodatka letećeg pepela potrebno da budu zadovoljeni zahtevi za SCC, kao i da svojstva betona ostanu ista ili poboljšana, ova studija je pokazala da se sve dizajnirane smeše mogu koristiti za konstrukcijske primene.
PB  - Beograd : Savez mašinskih i elektrotehničkih inženjera i tehničara Srbije - SMEITS
C3  - Proceedings - 8th International Conference on Renewable Electrical Power Sources
T1  - Enhancing properties of concrete by addition of fly ash from a thermal power plant for application in geothermal systems
T1  - Poboljšanje svojstava betona dodatkom letećeg pepela iz termoelektrane za primenu u geotermalnim sistemima
EP  - 86
SP  - 77
DO  - 10.24094/mkoiee.020.8.1.77
ER  - 
@conference{
author = "Vlahović, Milica and Savić, Aleksandar and Martinović, Sanja and Đorđević, Nataša and Stević, Zoran and Volkov-Husović, Tatjana",
year = "2020",
abstract = "Electric power in Serbia is predominantly provided by thermal power plants. All of eleven existing thermal power plants in Serbia use coal, mainly lignite in the electricity production process thus generating about 6 million tons of fly ash per year. The estimated amount of fly ash from thermal power plants accumulated in Serbian landfills exceeds 200 million tons. On the other hand, during the last decades, respecting the principles of ecologically sustainable development has been imposed on industries, and one of them is the construction industry. Due to the presence of amorphous SiO2 and Al2O3, fly ash as pozzolanic material is convenient for the production of concrete and mortar. Consequently, multiple positive effects can be expected by the proper consumption of fly ash- reducing landfills and improving concrete properties. The idea of this study is to analyze the possibility of recycling fly ash from a thermal power plant by replacing a part of common mineral filler- limestone in the production of self-compacting concrete (SCC). Properties of conventional SCC with limestone and compositions with different fly ash content were compared. Considering that requirements for SCC should be satisfied and all properties remain or enhance in the case of fly ash addition, this study proved that all designed concretes can be used for structural applications., Električnu energiju u Srbiji pretežno obezbeđuju termoelektrane. Svih jedanaest termoelektrana u Srbiji koriste ugalj, uglavnom lignit u procesu proizvodnje električne energije, čime se godišnje generiše oko 6 miliona tona letećeg pepela. Procenjena količina letećeg pepela iz termoelektrana akumulirana na deponijama u Srbiji prelazi 200 miliona tona. S druge strane, poslednjih decenija poštovanje principa ekološki održivog razvoja nametnuto je industrijama, a jedna od njih je i građevinska. Zahvaljujući prisustvu amorfnog SiO2 i Al2O3, pepeo kao pucolanski materijal pogodan je za proizvodnju betona i maltera. Zbog toga se pravilnom upotrebom letećeg pepela mogu očekivati višestruki pozitivni efekti- smanjenje deponija i poboljšanje svojstava betona. Ideja ovog istraživanja je analiziranje mogućnosti recikliranja letećeg pepela iz termoelektrane tako što će delimično zameniti uobičajeni mineralni punioc- krečnjak u proizvodnji samozbijajućeg betona (SCC). Upoređena su svojstva konvencionalnog SCC sa krečnjakom i kompozicija sa različitim sadržajem pepela. S obzirom da je u slučaju dodatka letećeg pepela potrebno da budu zadovoljeni zahtevi za SCC, kao i da svojstva betona ostanu ista ili poboljšana, ova studija je pokazala da se sve dizajnirane smeše mogu koristiti za konstrukcijske primene.",
publisher = "Beograd : Savez mašinskih i elektrotehničkih inženjera i tehničara Srbije - SMEITS",
journal = "Proceedings - 8th International Conference on Renewable Electrical Power Sources",
title = "Enhancing properties of concrete by addition of fly ash from a thermal power plant for application in geothermal systems, Poboljšanje svojstava betona dodatkom letećeg pepela iz termoelektrane za primenu u geotermalnim sistemima",
pages = "86-77",
doi = "10.24094/mkoiee.020.8.1.77"
}
Vlahović, M., Savić, A., Martinović, S., Đorđević, N., Stević, Z.,& Volkov-Husović, T.. (2020). Enhancing properties of concrete by addition of fly ash from a thermal power plant for application in geothermal systems. in Proceedings - 8th International Conference on Renewable Electrical Power Sources
Beograd : Savez mašinskih i elektrotehničkih inženjera i tehničara Srbije - SMEITS., 77-86.
https://doi.org/10.24094/mkoiee.020.8.1.77
Vlahović M, Savić A, Martinović S, Đorđević N, Stević Z, Volkov-Husović T. Enhancing properties of concrete by addition of fly ash from a thermal power plant for application in geothermal systems. in Proceedings - 8th International Conference on Renewable Electrical Power Sources. 2020;:77-86.
doi:10.24094/mkoiee.020.8.1.77 .
Vlahović, Milica, Savić, Aleksandar, Martinović, Sanja, Đorđević, Nataša, Stević, Zoran, Volkov-Husović, Tatjana, "Enhancing properties of concrete by addition of fly ash from a thermal power plant for application in geothermal systems" in Proceedings - 8th International Conference on Renewable Electrical Power Sources (2020):77-86,
https://doi.org/10.24094/mkoiee.020.8.1.77 . .
1

Thermovision monitoring of concrete heat of hydration

Savić, Aleksandar; Stević, Zoran; Martinović, Sanja; Vlahović, Milica; Volkov-Husović, Tatjana

(Beograd : Savez mašinskih i elektrotehničkih inženjera i tehničara Srbije - SMEITS, 2020) 

TY  - CONF
AU  - Savić, Aleksandar
AU  - Stević, Zoran
AU  - Martinović, Sanja
AU  - Vlahović, Milica
AU  - Volkov-Husović, Tatjana
PY  - 2020
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/4404
AB  - Usled hemijske reakcije Portland cementa, koja se uvek javlja u betonu prilikom očvršćavanja, izvesna količina toplote se razvija. Ova toplota mora biti kvantifikovana, obzirom da ona može oštetiti beton ili pomoći mu, zavisno od komponenata betona, elementa konstrukcije, uslova sredine i gradilišta. Postoji veći broj postavki za monitoring toplote hidratacije, od kojih su dve primenjene u slučaju prikazanom u ovom radu. Četiri vrste betona su praćene pomoću pomenute dve tehnike u trajanju od 24 sata. Prva upotrebljena postavka koja je upotrebljena je termovizijska kamera, pomoću koje je praćena površina, a druga je termosenzor – upotrebljena za monitoring unutrašnjosti sveže betonske mase koja je očvršćavala. Potencijal primenjene postavke leži u jednostavnosti montiranja, niskoj ceni i mogućnostima za masovnu upotrebu, što može značajno doprineti monitoringu i preduprediti podbačaj betona.
PB  - Beograd : Savez mašinskih i elektrotehničkih inženjera i tehničara Srbije - SMEITS
C3  - Proceedings - 8th International Conference on Renewable Electrical Power Sources
T1  - Thermovision monitoring of concrete heat of hydration
T1  - Termovizijski monitoring toplote vlaženja betona
EP  - 50
SP  - 47
DO  - 10.24094/mkoiee.020.8.1.47
ER  - 
@conference{
author = "Savić, Aleksandar and Stević, Zoran and Martinović, Sanja and Vlahović, Milica and Volkov-Husović, Tatjana",
year = "2020",
abstract = "Usled hemijske reakcije Portland cementa, koja se uvek javlja u betonu prilikom očvršćavanja, izvesna količina toplote se razvija. Ova toplota mora biti kvantifikovana, obzirom da ona može oštetiti beton ili pomoći mu, zavisno od komponenata betona, elementa konstrukcije, uslova sredine i gradilišta. Postoji veći broj postavki za monitoring toplote hidratacije, od kojih su dve primenjene u slučaju prikazanom u ovom radu. Četiri vrste betona su praćene pomoću pomenute dve tehnike u trajanju od 24 sata. Prva upotrebljena postavka koja je upotrebljena je termovizijska kamera, pomoću koje je praćena površina, a druga je termosenzor – upotrebljena za monitoring unutrašnjosti sveže betonske mase koja je očvršćavala. Potencijal primenjene postavke leži u jednostavnosti montiranja, niskoj ceni i mogućnostima za masovnu upotrebu, što može značajno doprineti monitoringu i preduprediti podbačaj betona.",
publisher = "Beograd : Savez mašinskih i elektrotehničkih inženjera i tehničara Srbije - SMEITS",
journal = "Proceedings - 8th International Conference on Renewable Electrical Power Sources",
title = "Thermovision monitoring of concrete heat of hydration, Termovizijski monitoring toplote vlaženja betona",
pages = "50-47",
doi = "10.24094/mkoiee.020.8.1.47"
}
Savić, A., Stević, Z., Martinović, S., Vlahović, M.,& Volkov-Husović, T.. (2020). Thermovision monitoring of concrete heat of hydration. in Proceedings - 8th International Conference on Renewable Electrical Power Sources
Beograd : Savez mašinskih i elektrotehničkih inženjera i tehničara Srbije - SMEITS., 47-50.
https://doi.org/10.24094/mkoiee.020.8.1.47
Savić A, Stević Z, Martinović S, Vlahović M, Volkov-Husović T. Thermovision monitoring of concrete heat of hydration. in Proceedings - 8th International Conference on Renewable Electrical Power Sources. 2020;:47-50.
doi:10.24094/mkoiee.020.8.1.47 .
Savić, Aleksandar, Stević, Zoran, Martinović, Sanja, Vlahović, Milica, Volkov-Husović, Tatjana, "Thermovision monitoring of concrete heat of hydration" in Proceedings - 8th International Conference on Renewable Electrical Power Sources (2020):47-50,
https://doi.org/10.24094/mkoiee.020.8.1.47 . .

Procedure of solidification and stabilization of heavy metals from mine waste waters adsorbed on fly ash pellets into enviromentally acceptable building material

Martinović, Sanja; Vlahović, Milica; Volkov-Husović, Tatjana; Savić, Aleksandar; Milićević, Sonja; Jovanović, Vladimir; Đorđević, Nataša

(Zavod za intelektualnu svojinu Republike Srbije, 2020) 

TY  - PAT
AU  - Martinović, Sanja
AU  - Vlahović, Milica
AU  - Volkov-Husović, Tatjana
AU  - Savić, Aleksandar
AU  - Milićević, Sonja
AU  - Jovanović, Vladimir
AU  - Đorđević, Nataša
PY  - 2020
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/4419
AB  - Stabilization of heavy metals, especially copper, from acidic mine wastewater is performed by their solidification into sulfur polymer concrete as an environmentally acceptable building material. The procedure is carried out by heating the aggregate in an amount of 56 mass % in a reaction vessel with continuous mixing up to a temperature of 160 °C. Subsequently 5 mass % of fly ash from the thermal power plant is added as a filler and 6 mass % of fly ash pellets with absorbed heavy metals from mine waters. Finally, 33 mass % of the sulfur modified binder, that is mixed melted elemental and modified sulfur in the mass ratio of 98.2 % : 1.8 % is added to the homogenized solid mixture. Modified sulfur is prepared by mixing the elemental sulfur that is by-product of oil refining with dicyclopentadiene at a temperature of 132-141 °C. After the homogenization of the sulfur polymer concrete mixture for 2-5 minutes, the resulting melted mixture is poured into the molds pre-heated to 120 °C and vibrated for 10 seconds. Thus obtained surface of the sulfur polymer concrete mixture is flattened and leave to harden in the mold at room temperature. The samples were removed from the mold after 3 hours of hardening and then cured at room temperature for another 24 hours. After characterization, obtained building material showed satisfactory properties required for all application areas of conventional concrete. By this process, heavy metals from mine wastewater were eliminated, industrial by-products (fly ash and sulfur) were used thus reducing their landfills, while the obtained material does not lead to secondary environmental pollution and therefore is considered as environmentally friendly.
AB  - Stabilizacija teških metala, posebno bakra, iz kiselih otpadnih rudničkih voda izvodi se njihovom solidifikacijom u sumpor polimerni beton kao ekološki prihvatljiv građevinski materijal. Postupak se izvodi tako što se u reakcionom sudu agregat u količini od 56 mas. % zagreva na 160 °C. Zatim se dodaje 5 mas. % letećegpepela iz termoelektrane kao filera i 6 mas. % peleta letećeg pepela sa adsorbovanim teškim metalima iz rudničkih voda. Homogenizovanoj čvrstoj mešavini dodaje se 33 mas. % rastopa elementarnog i modifikovanog sumpora, tzv. sumpor modifikovanog veziva u masenom odnosu 98,2 % elementarnog sumpora i 1,8 % modifikovanog sumpora. Modifikovani sumpor dobijen je mešanjem elementarnog sumpora kao nus-proizvoda iz rafinacije nafte sa diciklopentadienom, na temperaturi od 132-141 °C. Nakon homogenizacije u trajanju od 2 do 5 minuta, dobijena mešavina izliva se u kalupe prethodno zagrejane na 120 °C i vibrira 10 sekundi. Površina ovako dobijene sumpor polimerne betonske mešavine se izravna i ostavi da očvrsne u kalupu na sobnoj temperaturi. Nakon 3 časa očvršćavanja uzorci se vade iz kalupa i neguju na sobnoj temperaturi tokom 24 časa. Dobijeni materijal je nakon ispitivanja pokazao zadovoljavajuće karakteristike potrebne za sve oblasti primene konvencionalnih betona. Ovim postupkom eliminisani su teški metali iz otpadnih rudničkih voda, korišćeni su industrijski nus-proizvodi (leteći pepeo i sumpor), čime su smanjene njihove deponije dok dobijeni materijal ne dovodi do sekundarnog zagađenja životne i stoga se smatra ekološki prihvatljivim.
PB  - Zavod za intelektualnu svojinu Republike Srbije
T2  - Glasnik intelektualne svojine
T1  - Procedure of solidification and stabilization of heavy metals from mine waste waters adsorbed on fly ash pellets into enviromentally acceptable building material
T1  - Postupak solidifkacije i stabilizacije teških metala iz otpadnih rudničkih voda adsorbovanih na peletama u ekološki prihvatljiv građevinski materijal pepela
EP  - 9
SP  - 8
VL  - 10
UR  - https://hdl.handle.net/21.15107/rcub_technorep_4419
ER  - 
@misc{
author = "Martinović, Sanja and Vlahović, Milica and Volkov-Husović, Tatjana and Savić, Aleksandar and Milićević, Sonja and Jovanović, Vladimir and Đorđević, Nataša",
year = "2020",
abstract = "Stabilization of heavy metals, especially copper, from acidic mine wastewater is performed by their solidification into sulfur polymer concrete as an environmentally acceptable building material. The procedure is carried out by heating the aggregate in an amount of 56 mass % in a reaction vessel with continuous mixing up to a temperature of 160 °C. Subsequently 5 mass % of fly ash from the thermal power plant is added as a filler and 6 mass % of fly ash pellets with absorbed heavy metals from mine waters. Finally, 33 mass % of the sulfur modified binder, that is mixed melted elemental and modified sulfur in the mass ratio of 98.2 % : 1.8 % is added to the homogenized solid mixture. Modified sulfur is prepared by mixing the elemental sulfur that is by-product of oil refining with dicyclopentadiene at a temperature of 132-141 °C. After the homogenization of the sulfur polymer concrete mixture for 2-5 minutes, the resulting melted mixture is poured into the molds pre-heated to 120 °C and vibrated for 10 seconds. Thus obtained surface of the sulfur polymer concrete mixture is flattened and leave to harden in the mold at room temperature. The samples were removed from the mold after 3 hours of hardening and then cured at room temperature for another 24 hours. After characterization, obtained building material showed satisfactory properties required for all application areas of conventional concrete. By this process, heavy metals from mine wastewater were eliminated, industrial by-products (fly ash and sulfur) were used thus reducing their landfills, while the obtained material does not lead to secondary environmental pollution and therefore is considered as environmentally friendly., Stabilizacija teških metala, posebno bakra, iz kiselih otpadnih rudničkih voda izvodi se njihovom solidifikacijom u sumpor polimerni beton kao ekološki prihvatljiv građevinski materijal. Postupak se izvodi tako što se u reakcionom sudu agregat u količini od 56 mas. % zagreva na 160 °C. Zatim se dodaje 5 mas. % letećegpepela iz termoelektrane kao filera i 6 mas. % peleta letećeg pepela sa adsorbovanim teškim metalima iz rudničkih voda. Homogenizovanoj čvrstoj mešavini dodaje se 33 mas. % rastopa elementarnog i modifikovanog sumpora, tzv. sumpor modifikovanog veziva u masenom odnosu 98,2 % elementarnog sumpora i 1,8 % modifikovanog sumpora. Modifikovani sumpor dobijen je mešanjem elementarnog sumpora kao nus-proizvoda iz rafinacije nafte sa diciklopentadienom, na temperaturi od 132-141 °C. Nakon homogenizacije u trajanju od 2 do 5 minuta, dobijena mešavina izliva se u kalupe prethodno zagrejane na 120 °C i vibrira 10 sekundi. Površina ovako dobijene sumpor polimerne betonske mešavine se izravna i ostavi da očvrsne u kalupu na sobnoj temperaturi. Nakon 3 časa očvršćavanja uzorci se vade iz kalupa i neguju na sobnoj temperaturi tokom 24 časa. Dobijeni materijal je nakon ispitivanja pokazao zadovoljavajuće karakteristike potrebne za sve oblasti primene konvencionalnih betona. Ovim postupkom eliminisani su teški metali iz otpadnih rudničkih voda, korišćeni su industrijski nus-proizvodi (leteći pepeo i sumpor), čime su smanjene njihove deponije dok dobijeni materijal ne dovodi do sekundarnog zagađenja životne i stoga se smatra ekološki prihvatljivim.",
publisher = "Zavod za intelektualnu svojinu Republike Srbije",
journal = "Glasnik intelektualne svojine",
title = "Procedure of solidification and stabilization of heavy metals from mine waste waters adsorbed on fly ash pellets into enviromentally acceptable building material, Postupak solidifkacije i stabilizacije teških metala iz otpadnih rudničkih voda adsorbovanih na peletama u ekološki prihvatljiv građevinski materijal pepela",
pages = "9-8",
volume = "10",
url = "https://hdl.handle.net/21.15107/rcub_technorep_4419"
}
Martinović, S., Vlahović, M., Volkov-Husović, T., Savić, A., Milićević, S., Jovanović, V.,& Đorđević, N.. (2020). Procedure of solidification and stabilization of heavy metals from mine waste waters adsorbed on fly ash pellets into enviromentally acceptable building material. in Glasnik intelektualne svojine
Zavod za intelektualnu svojinu Republike Srbije., 10, 8-9.
https://hdl.handle.net/21.15107/rcub_technorep_4419
Martinović S, Vlahović M, Volkov-Husović T, Savić A, Milićević S, Jovanović V, Đorđević N. Procedure of solidification and stabilization of heavy metals from mine waste waters adsorbed on fly ash pellets into enviromentally acceptable building material. in Glasnik intelektualne svojine. 2020;10:8-9.
https://hdl.handle.net/21.15107/rcub_technorep_4419 .
Martinović, Sanja, Vlahović, Milica, Volkov-Husović, Tatjana, Savić, Aleksandar, Milićević, Sonja, Jovanović, Vladimir, Đorđević, Nataša, "Procedure of solidification and stabilization of heavy metals from mine waste waters adsorbed on fly ash pellets into enviromentally acceptable building material" in Glasnik intelektualne svojine, 10 (2020):8-9,
https://hdl.handle.net/21.15107/rcub_technorep_4419 .