Python implementation of heat accumulation equations for additive manufacturing
C. Hagenlocher. Software, (2022)Related to: Hagenlocher C, O’Toole P, Xu W, Brandt M, Easton MA, Molotnikov A.: Änalytical modelling of heat accumulation in laser based additive manufacturingprocesses of metals", Additive Manufacturing 2022. doi: 10.1016/j.addma.2022.103263.
DOI: 10.18419/darus-2609
Abstract
This is a python implementation of the heat accumulation equations, which describe the increase of the residual temperature in additive manufacturing. The Derivation of the equations is described in the related paper given below.If you run the script in the console, it creates two text-files and four plots in .png format.Process parameter and material characteristics can be changed or adapted in the beginning of the script.Detailled instructions are given within the code by the comments.
Related to: Hagenlocher C, O’Toole P, Xu W, Brandt M, Easton MA, Molotnikov A.: Änalytical modelling of heat accumulation in laser based additive manufacturingprocesses of metals", Additive Manufacturing 2022. doi: 10.1016/j.addma.2022.103263
%0 Generic
%1 hagenlocher2022python
%A Hagenlocher, Christian
%D 2022
%K darus ubs_10007 ubs_20011 ubs_30111 ubs_40311 unibibliografie
%R 10.18419/darus-2609
%T Python implementation of heat accumulation equations for additive manufacturing
%X This is a python implementation of the heat accumulation equations, which describe the increase of the residual temperature in additive manufacturing. The Derivation of the equations is described in the related paper given below.If you run the script in the console, it creates two text-files and four plots in .png format.Process parameter and material characteristics can be changed or adapted in the beginning of the script.Detailled instructions are given within the code by the comments.
@misc{hagenlocher2022python,
abstract = {This is a python implementation of the heat accumulation equations, which describe the increase of the residual temperature in additive manufacturing. The Derivation of the equations is described in the related paper given below.If you run the script in the console, it creates two text-files and four plots in .png format.Process parameter and material characteristics can be changed or adapted in the beginning of the script.Detailled instructions are given within the code by the comments. },
added-at = {2022-11-14T16:46:48.000+0100},
affiliation = {Hagenlocher, Christian/University of Stuttgart},
author = {Hagenlocher, Christian},
biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2bd2e259a32765e85c37b038bddc6ccd5/unibiblio},
doi = {10.18419/darus-2609},
howpublished = {Software},
interhash = {785b846189cffa4e1072f16616f477f2},
intrahash = {bd2e259a32765e85c37b038bddc6ccd5},
keywords = {darus ubs_10007 ubs_20011 ubs_30111 ubs_40311 unibibliografie},
note = {Related to: Hagenlocher C, O’Toole P, Xu W, Brandt M, Easton MA, Molotnikov A.: "Analytical modelling of heat accumulation in laser based additive manufacturingprocesses of metals", Additive Manufacturing 2022. doi: 10.1016/j.addma.2022.103263},
orcid-numbers = {Hagenlocher, Christian/0000-0003-2929-9723},
timestamp = {2022-11-14T15:46:48.000+0100},
title = {Python implementation of heat accumulation equations for additive manufacturing},
year = 2022
}
