The mVINIS ion source, a part of FAMA installation at Vinca Institute of Nuclear Sciences, is able to produce multiple charged heavy ion beams through the utilization of vapors created by the process of melting solids inside the miniature oven (mini-oven). The mini-oven that was used previously could only reach the maximum temperature of 800?C, which is far too low for evaporating most metals. For this purpose, a higher operating-temperature of 1500?C was needed. Our study focuses on numerical finite element method analysis of the temperature distribution of newly designed mini-oven.
Keywords:
evaporate / finite element method / ion beam / oven
TY - JOUR
AU - Telečki, Igor N.
AU - Vukosavljević, Ljubiša
AU - Trajić, Ivan
AU - Erich, Marko
AU - Jocić, Viktor
PY - 2022
UR - https://vinar.vin.bg.ac.rs/handle/123456789/10179
AB - The mVINIS ion source, a part of FAMA installation at Vinca Institute of Nuclear Sciences, is able to produce multiple charged heavy ion beams through the utilization of vapors created by the process of melting solids inside the miniature oven (mini-oven). The mini-oven that was used previously could only reach the maximum temperature of 800?C, which is far too low for evaporating most metals. For this purpose, a higher operating-temperature of 1500?C was needed. Our study focuses on numerical finite element method analysis of the temperature distribution of newly designed mini-oven.
T2 - Thermal Science
T1 - The finite element method analysis of temperature distribution of the FAMA electron cyclotron resonance mini-oven
VL - 26
IS - 1 Part A
SP - 175
EP - 184
DO - 10.2298/TSCI210519235T
ER -
@article{
author = "Telečki, Igor N. and Vukosavljević, Ljubiša and Trajić, Ivan and Erich, Marko and Jocić, Viktor",
year = "2022",
abstract = "The mVINIS ion source, a part of FAMA installation at Vinca Institute of Nuclear Sciences, is able to produce multiple charged heavy ion beams through the utilization of vapors created by the process of melting solids inside the miniature oven (mini-oven). The mini-oven that was used previously could only reach the maximum temperature of 800?C, which is far too low for evaporating most metals. For this purpose, a higher operating-temperature of 1500?C was needed. Our study focuses on numerical finite element method analysis of the temperature distribution of newly designed mini-oven.",
journal = "Thermal Science",
title = "The finite element method analysis of temperature distribution of the FAMA electron cyclotron resonance mini-oven",
volume = "26",
number = "1 Part A",
pages = "175-184",
doi = "10.2298/TSCI210519235T"
}
Telečki, I. N., Vukosavljević, L., Trajić, I., Erich, M.,& Jocić, V.. (2022). The finite element method analysis of temperature distribution of the FAMA electron cyclotron resonance mini-oven. in Thermal Science, 26(1 Part A), 175-184.
https://doi.org/10.2298/TSCI210519235T
Telečki IN, Vukosavljević L, Trajić I, Erich M, Jocić V. The finite element method analysis of temperature distribution of the FAMA electron cyclotron resonance mini-oven. in Thermal Science. 2022;26(1 Part A):175-184.
doi:10.2298/TSCI210519235T .
Telečki, Igor N., Vukosavljević, Ljubiša, Trajić, Ivan, Erich, Marko, Jocić, Viktor, "The finite element method analysis of temperature distribution of the FAMA electron cyclotron resonance mini-oven" in Thermal Science, 26, no. 1 Part A (2022):175-184,
https://doi.org/10.2298/TSCI210519235T . .
,