Publication detail

Assessment of Basic Approaches to Numerical Modeling of Phase Change Problems—Accuracy, Efficiency, and Parallel Decomposition

MAUDER, T. CHARVÁT, P. ŠTĚTINA, J. KLIMEŠ, L.

Original Title

Assessment of Basic Approaches to Numerical Modeling of Phase Change Problems—Accuracy, Efficiency, and Parallel Decomposition

Type

journal article in Web of Science

Language

English

Original Abstract

The fast and accurate modeling of phase change is of a significant importance in many processes from steel casting to latent heat thermal energy storage. The paper presents a numerical case study on the transient 3D heat diffusion problem with phase change. Three different approaches to modeling of the solid–liquid phase change in combination with four commonly used numerical schemes are compared for their efficiency, accuracy, applicability, simplicity of implementation, and robustness. The possibility of parallel decomposition of the approaches is also discussed. The results indicate that the best accuracy was achieved with the second-order implicit methods, and the best efficiency was reached with the simple explicit methods.

Keywords

Numerical discretization, phase change material, parallel decomposition

Authors

MAUDER, T.; CHARVÁT, P.; ŠTĚTINA, J.; KLIMEŠ, L.

Released

11. 4. 2017

Publisher

The Americal Society of Mechanical Engineers ASME

Location

Pennsylvania, USA

ISBN

0022-1481

Periodical

JOURNAL OF HEAT TRANSFER-TRANSACTIONS OF THE ASME

Year of study

139

Number

8

State

United States of America

Pages from

1

Pages to

5

Pages count

5

URL

BibTex

@article{BUT134931,
  author="Tomáš {Mauder} and Pavel {Charvát} and Josef {Štětina} and Lubomír {Klimeš}",
  title="Assessment of Basic Approaches to Numerical Modeling of Phase Change Problems—Accuracy, Efficiency, and Parallel Decomposition",
  journal="JOURNAL OF HEAT TRANSFER-TRANSACTIONS OF THE ASME",
  year="2017",
  volume="139",
  number="8",
  pages="1--5",
  doi="10.1115/1.4036081",
  issn="0022-1481",
  url="http://heattransfer.asmedigitalcollection.asme.org/article.aspx?articleid=2608645"
}