Based on the analysis of the non-standard iron-bearing raw materials treatment process and the results of real composition measurements of the flue gas, the study of hazards by identification of harmful substances that occur in the accident, as well as the modeling of the system of protection against air-pollution due to the cancellation of work the bag filter was carried out. Applying the model (Aloha software package) provides an overview of possible developments of events and zones of propagation of the precipitated particulate matter through the share of cadmium (Cd) in them. In the case of malfunction of filter system, emissions of particulate matter enormously exceed the permitted values. In the conditions of the simulated accident, particle velocity of flue gases was amounted E ≈ 738 mg/s or 2657 g/h of dust. The propagation of the precipitated particulate matter in the lower layer of the atmosphere, downwind, given trough the share of Cd in them, is 100 m from the source of pol...lution for the characteristic density of 5 mg/m2×day and 140m for the characteristic density of 2 mg/m2×day, in the stable state of the atmosphere, i.e. 870 m and 1100 m, respectively, in the neutral state of the atmosphere.
TY - JOUR
AU - Anđić, Zoran
AU - Korać, Marija
AU - Kamberović, Željko
PY - 2016
UR - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/3208
AB - Based on the analysis of the non-standard iron-bearing raw materials treatment process and the results of real composition measurements of the flue gas, the study of hazards by identification of harmful substances that occur in the accident, as well as the modeling of the system of protection against air-pollution due to the cancellation of work the bag filter was carried out. Applying the model (Aloha software package) provides an overview of possible developments of events and zones of propagation of the precipitated particulate matter through the share of cadmium (Cd) in them. In the case of malfunction of filter system, emissions of particulate matter enormously exceed the permitted values. In the conditions of the simulated accident, particle velocity of flue gases was amounted E ≈ 738 mg/s or 2657 g/h of dust. The propagation of the precipitated particulate matter in the lower layer of the atmosphere, downwind, given trough the share of Cd in them, is 100 m from the source of pollution for the characteristic density of 5 mg/m2×day and 140m for the characteristic density of 2 mg/m2×day, in the stable state of the atmosphere, i.e. 870 m and 1100 m, respectively, in the neutral state of the atmosphere.
PB - Association of Metallurgical Engineers of Serbia
T2 - Metallurgical & Materials Engineering
T1 - Treatment of dispersed iron-bearing raw materials and modeling of the protection systems against air-pollution
EP - 311
IS - 4
SP - 303
VL - 22
UR - https://hdl.handle.net/21.15107/rcub_technorep_3208
ER -
@article{
author = "Anđić, Zoran and Korać, Marija and Kamberović, Željko",
year = "2016",
abstract = "Based on the analysis of the non-standard iron-bearing raw materials treatment process and the results of real composition measurements of the flue gas, the study of hazards by identification of harmful substances that occur in the accident, as well as the modeling of the system of protection against air-pollution due to the cancellation of work the bag filter was carried out. Applying the model (Aloha software package) provides an overview of possible developments of events and zones of propagation of the precipitated particulate matter through the share of cadmium (Cd) in them. In the case of malfunction of filter system, emissions of particulate matter enormously exceed the permitted values. In the conditions of the simulated accident, particle velocity of flue gases was amounted E ≈ 738 mg/s or 2657 g/h of dust. The propagation of the precipitated particulate matter in the lower layer of the atmosphere, downwind, given trough the share of Cd in them, is 100 m from the source of pollution for the characteristic density of 5 mg/m2×day and 140m for the characteristic density of 2 mg/m2×day, in the stable state of the atmosphere, i.e. 870 m and 1100 m, respectively, in the neutral state of the atmosphere.",
publisher = "Association of Metallurgical Engineers of Serbia",
journal = "Metallurgical & Materials Engineering",
title = "Treatment of dispersed iron-bearing raw materials and modeling of the protection systems against air-pollution",
pages = "311-303",
number = "4",
volume = "22",
url = "https://hdl.handle.net/21.15107/rcub_technorep_3208"
}
Anđić, Z., Korać, M.,& Kamberović, Ž.. (2016). Treatment of dispersed iron-bearing raw materials and modeling of the protection systems against air-pollution. in Metallurgical & Materials Engineering
Association of Metallurgical Engineers of Serbia., 22(4), 303-311.
https://hdl.handle.net/21.15107/rcub_technorep_3208
Anđić Z, Korać M, Kamberović Ž. Treatment of dispersed iron-bearing raw materials and modeling of the protection systems against air-pollution. in Metallurgical & Materials Engineering. 2016;22(4):303-311.
https://hdl.handle.net/21.15107/rcub_technorep_3208 .
Anđić, Zoran, Korać, Marija, Kamberović, Željko, "Treatment of dispersed iron-bearing raw materials and modeling of the protection systems against air-pollution" in Metallurgical & Materials Engineering, 22, no. 4 (2016):303-311,
https://hdl.handle.net/21.15107/rcub_technorep_3208 .
