Sistem u oblaku za praćenje i upravljanje procesom sušenja baziran na mikrokontroleru i veb aplikaciji
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Jul 16, 2025
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Željko Eremić
http://orcid.org/0009-0003-3310-3081
Aleksandar Dedić
http://orcid.org/0000-0001-6120-6414
Matilda Lazić
http://orcid.org/0009-0000-9174-554X
Dragan Halas
http://orcid.org/0009-0005-1426-0326
http://orcid.org/0009-0003-3310-3081
Aleksandar Dedić
http://orcid.org/0000-0001-6120-6414
Matilda Lazić
http://orcid.org/0009-0000-9174-554X
Dragan Halas
http://orcid.org/0009-0005-1426-0326
Apstrakt
Ovaj rad predstavlja sistem za sušenje integrisan sa web aplikacijom za daljinsko praćenje i upravljanje procesom u maloj laboratorijskoj sušari. Aplikacija omogućava korisnicima da podese i prilagode kritične parametre sušenja i čuvaju podatke u odgovarajućem formatu za dalju analizu. Dat je pregled relevantne literature i prethodnog rada autora. Detaljno su razmotreni ključni aspekti procesa sušenja, zajedno sa njegovim kritičnim parametrima, nakon čega sledi pregled hardverskih i softverskih komponenti sistema. Objašnjen je interfejs i funkcionalnosti web aplikacije, i prikazani rezultati provedenih eksperimenata. Rad se završava rezimeom rezultata koji pokazuju da je glavni cilj, korištenje modernih tehnologija kao što su React.js, JavaScript, CSS i HTML za razvoj korisničkog interfejsa za daljinsko praćenje i upravljanje procesima, uspešno postignut.
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Kako citirati
EREMIĆ, Željko et al.
Sistem u oblaku za praćenje i upravljanje procesom sušenja baziran na mikrokontroleru i veb aplikaciji.
Zbornik Međunarodnog kongresa o procesnoj industriji – Procesing, [S.l.], v. 38, n. 1, p. 209-218, july 2025.
Dostupno na: <http://www.izdanja.smeits.rs/index.php/ptk/article/view/8223>. Datum pristupa: 10 mar. 2026
doi: https://doi.org/10.24094/ptk.025.1.209.
Sekcija
Sušenje i sušare
Reference
[1] Roman, F., O. Hensel, Effect of air temperature and relative humidity on the thin-layer dry-ing of celery leaves (Apium graveolens var. secalinum), Agricultural Engineering Interna-tional Journal, 13 (2011), 2, 8 pages.
[2] Wang, D., M. Ma, Z. Zhao, Y. Yuan, Chitrakar B., C. Li, P. Li, H. Xiao, American Gin-seng Slice Drying and Optimization: Effect of Different Drying Methods on Drying Kinetics and Physicochemical Properties, Processes 12(2024), pp. 1206-1226.
[3] Nino, A., O. Valladares, A. Gomez, P. Velazquez, C. Sánchez, B. Tellez, G. Solano, Con-vective Drying of Pumpkin Flower (Cucurbita maxima): Effect of Temperature and Airflow on Carotenoid Content, Wiley Journal of Food Processing and Preservation. 2024, Article ID 5773594, 8 pages.
[4] Ogunbayo, A.O., A.A. Akinola, O.O. Olanipekun, A. Abdulsalam, Colour Change Kinetics of Plantain During Refractance Window Drying at Different Temperatures, In: 22nd Interna-tional Drying Symposium Worcester, Massachusetts, USA, June 26 – June 29, 2022, 8 pages.
[5] Salemović, D. R., et al., A Mathematical Model and Simulation of the Drying Process of Thin Layers of Potatoes in a Conveyor-Belt Dryer, Thermal Science, 19 (2015), 3, pp. 1107-1118.
[6] Salemović, D., A. Dedić, N. Ćuprić, 2-D mathematical model for simulation of the drying process of thick layers of natural materials in a conveyor-belt dryer, Thermal Science, DOI: 10.2298/TSCI160308259S, 21(2017), 3, pp. 1161-1561, ISSN: 0354-9836 (printed edition); 2334-7163 (Online edition), UDC 621.
[7] Sihombing, H.V., H. Ambarita, J.F. Silalahi, Comparative study of mathematical and ex-perimental models of coffee bean drying rate in a solar dryer simulator. In: 5th Talenta Con-ference on Engineering, Science and Technology, Medan, Indonesia, 2024, 8 pages.
[8] Ndukwu, M.C., I.T. Horsfall, D.I. Onwude, M.S. Tagne, F.I.Abam, Physics-based numeri-cal simulation of heat and moisture transport in red chili subjected to mix-mode solar drying with phase change energy storage, Energy Storage, 3(2021), 6, pp. 270-282.
[9] Dharma, A., Haikal M.G.Z., Ridlwan M., Dewanto S.A., Rahman M.A., Heat transfer sim-ulation for re-design of tray dryer to reduce the energy consumption in the cocoa bean drying process, In: IOP Conference Series: Earth and Environmental Science, IOP Publishing, 2024, 10 pages.
[10] Miano, J.I., M.A. Nabua, A.R. Gaw, A.R.B. Alce, C.A.M. Ecleo, J.V. Repulle, J.J. Omar, Optimizing Drying Efficiency Through an IoT-based Direct Solar Dryer System: Integration of Web Data Logger and SMS Notification. International Journal of Advanced Computer Sci-ence and Applications (IJACSA), 14(2023), 7, pp. 233-240.
[11] LIU, Kuiyuan, Design of porous media burner control system based on arm embedded pro-cessor, Thermal Science, 26(2022), 3 Part B, pp. 2831-2844.
[12] Medojević, M.M., B.B. Tejić, M. S. Medojević, M. V. Kljajić, Design and development of industrial IoT-based system for behavior profiling of non-linear dynamic production systems based on energy flow theory, Thermal Science, 26(2022), 3 Part A, pp. 2147-2161.
[13] Eremić, Ž., I. Borjanović, Web Application for Displaying Results of Air Quality Measure-ment Using View Plus Radon Detector. In: Sinteza, Univerzitet Singidunum, Beograd, Serbia, 2023, pp. 185-190.
[14] Eremić, Ž., D. Halas, IoT u realnom vremenu korišćenjem NodeMCU, Firebase i React, DIT, 2019, 32, pp. 35-39, ISSN 0354-7140.
[15] Ž. Eremić, D. Halas, D. Nemet, Sistem za automatsko merenje i čuvanje meteoroloških po-dataka, DIT, 36, 2021, pp. 45-50, ISSN 0354-7140.
[16] Firebase, https://firebase.google.com/docs/database, Accessed September 26, 2024.
[17] Eremić, Ž., Sistem za automatsko merenje meteoroloških podataka i prikaz putem web ap-likacije, DIT, 34, 2020, pp. 57-61, ISSN 0354-7140.
[18] Danielsson, W., React Native application development thesis, Linköpings universitet, Swe-dia, 2016.
[2] Wang, D., M. Ma, Z. Zhao, Y. Yuan, Chitrakar B., C. Li, P. Li, H. Xiao, American Gin-seng Slice Drying and Optimization: Effect of Different Drying Methods on Drying Kinetics and Physicochemical Properties, Processes 12(2024), pp. 1206-1226.
[3] Nino, A., O. Valladares, A. Gomez, P. Velazquez, C. Sánchez, B. Tellez, G. Solano, Con-vective Drying of Pumpkin Flower (Cucurbita maxima): Effect of Temperature and Airflow on Carotenoid Content, Wiley Journal of Food Processing and Preservation. 2024, Article ID 5773594, 8 pages.
[4] Ogunbayo, A.O., A.A. Akinola, O.O. Olanipekun, A. Abdulsalam, Colour Change Kinetics of Plantain During Refractance Window Drying at Different Temperatures, In: 22nd Interna-tional Drying Symposium Worcester, Massachusetts, USA, June 26 – June 29, 2022, 8 pages.
[5] Salemović, D. R., et al., A Mathematical Model and Simulation of the Drying Process of Thin Layers of Potatoes in a Conveyor-Belt Dryer, Thermal Science, 19 (2015), 3, pp. 1107-1118.
[6] Salemović, D., A. Dedić, N. Ćuprić, 2-D mathematical model for simulation of the drying process of thick layers of natural materials in a conveyor-belt dryer, Thermal Science, DOI: 10.2298/TSCI160308259S, 21(2017), 3, pp. 1161-1561, ISSN: 0354-9836 (printed edition); 2334-7163 (Online edition), UDC 621.
[7] Sihombing, H.V., H. Ambarita, J.F. Silalahi, Comparative study of mathematical and ex-perimental models of coffee bean drying rate in a solar dryer simulator. In: 5th Talenta Con-ference on Engineering, Science and Technology, Medan, Indonesia, 2024, 8 pages.
[8] Ndukwu, M.C., I.T. Horsfall, D.I. Onwude, M.S. Tagne, F.I.Abam, Physics-based numeri-cal simulation of heat and moisture transport in red chili subjected to mix-mode solar drying with phase change energy storage, Energy Storage, 3(2021), 6, pp. 270-282.
[9] Dharma, A., Haikal M.G.Z., Ridlwan M., Dewanto S.A., Rahman M.A., Heat transfer sim-ulation for re-design of tray dryer to reduce the energy consumption in the cocoa bean drying process, In: IOP Conference Series: Earth and Environmental Science, IOP Publishing, 2024, 10 pages.
[10] Miano, J.I., M.A. Nabua, A.R. Gaw, A.R.B. Alce, C.A.M. Ecleo, J.V. Repulle, J.J. Omar, Optimizing Drying Efficiency Through an IoT-based Direct Solar Dryer System: Integration of Web Data Logger and SMS Notification. International Journal of Advanced Computer Sci-ence and Applications (IJACSA), 14(2023), 7, pp. 233-240.
[11] LIU, Kuiyuan, Design of porous media burner control system based on arm embedded pro-cessor, Thermal Science, 26(2022), 3 Part B, pp. 2831-2844.
[12] Medojević, M.M., B.B. Tejić, M. S. Medojević, M. V. Kljajić, Design and development of industrial IoT-based system for behavior profiling of non-linear dynamic production systems based on energy flow theory, Thermal Science, 26(2022), 3 Part A, pp. 2147-2161.
[13] Eremić, Ž., I. Borjanović, Web Application for Displaying Results of Air Quality Measure-ment Using View Plus Radon Detector. In: Sinteza, Univerzitet Singidunum, Beograd, Serbia, 2023, pp. 185-190.
[14] Eremić, Ž., D. Halas, IoT u realnom vremenu korišćenjem NodeMCU, Firebase i React, DIT, 2019, 32, pp. 35-39, ISSN 0354-7140.
[15] Ž. Eremić, D. Halas, D. Nemet, Sistem za automatsko merenje i čuvanje meteoroloških po-dataka, DIT, 36, 2021, pp. 45-50, ISSN 0354-7140.
[16] Firebase, https://firebase.google.com/docs/database, Accessed September 26, 2024.
[17] Eremić, Ž., Sistem za automatsko merenje meteoroloških podataka i prikaz putem web ap-likacije, DIT, 34, 2020, pp. 57-61, ISSN 0354-7140.
[18] Danielsson, W., React Native application development thesis, Linköpings universitet, Swe-dia, 2016.