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Title:
Numerična simulacija hladilnega sestava pri 3d tiskanju biomateriala : diplomsko delo
Authors:
ID
Jordan, Miha
(Author)
ID
Zadravec, Matej
(Mentor)
More about this mentor...
ID
Gomboc, Timi
(Mentor)
More about this mentor...
Files:
UN_Jordan_Miha_2020.pdf
(2,51 MB)
MD5: F42C2941636E48AA5940ECA2DA75CE0D
PID:
20.500.12556/dkum/95dd4653-61ee-43bc-bc27-9b9e1819dd2b
Language:
Slovenian
Work type:
Bachelor thesis/paper
Typology:
2.11 - Undergraduate Thesis
Organization:
FS - Faculty of Mechanical Engineering
Abstract:
V diplomskem delu je v programskem okolju Ansys obravnavan numerični model hladilnega sestava pri 3D tiskanju biološkega materiala. Izvedli smo tokovno-toplotno analizo sistema in rezultate primerjali z eksperimentalno dobljenimi vrednostmi. Dodani so tudi potrebni preračuni za pravilno postavitev robnih pogojev. Rezultati simulacije so pokazali ustrezno ohlajanje celotnega sestava. Odstopanja rezultatov smo razložili, predstavili smo tudi pomanjkljivosti in možne izboljšave.
Keywords:
3D tiskanje
,
numerična simulacija
,
računalniška dinamika tekočin
,
prenos toplote
Place of publishing:
Maribor
Place of performance:
Maribor
Publisher:
[M. Jordan]
Year of publishing:
2020
Number of pages:
IX, 39 f.
PID:
20.500.12556/DKUM-77496
UDC:
519.876.5:532.5(043.2)
COBISS.SI-ID:
37030403
NUK URN:
URN:SI:UM:DK:VKIUZBAK
Publication date in DKUM:
24.09.2020
Views:
1103
Downloads:
120
Metadata:
Categories:
KTFMB - FS
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Licences
License:
CC BY-NC-ND 4.0, Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International
Link:
http://creativecommons.org/licenses/by-nc-nd/4.0/
Description:
The most restrictive Creative Commons license. This only allows people to download and share the work for no commercial gain and for no other purposes.
Licensing start date:
01.09.2020
Secondary language
Language:
English
Title:
Numerical simulation of a cooling platform in the biomaterial 3d printing process
Abstract:
This diploma thesis deals with a numerical model for the cooling platform during 3D printing of biomaterial. Numerical simulation was performed in Ansys software. We performed a flow-thermal analysis of the system and compared the results with the experimentally obtained data. The necessary calculations for the correct setting of the boundary conditions have also been added. The simulation results showed adequate cooling of the whole cooling platform. We explained the discrepancies in the results, we also presented the shortcomings and possible improvements.
Keywords:
3D printing
,
numerical analysis
,
computational fluid dynamics
,
heat transfer
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