3D Numerical and Experimental Study on Paraffin Wax Melting in Thermal Storage for the Nozzle-and-Shell, Tube-and-Shell, and Reducer-and-Shell Models

3D Numerical and Experimental Study on Paraffin Wax Melting in Thermal Storage for the Nozzle-and-Shell, Tube-and-Shell, and Reducer-and-Shell Models

Paraffin melting experienced in the nozzle-and-shell, tube-and-shell, and reducer-and-shell models in thermal storage with 3D numerical and experimental approach has been studied. The numerical study aims to evaluate the melting process and discover temperature distribution, liquid-solid interface,...

Full description

Bibliographic Details
Main Authors: Agus Dwi Korawan, Sudjito Soeparman, Widya Wijayanti, Denny Widhiyanuriyawan
Format: Article
Language:English
Published: Hindawi Limited 2017-01-01
Series:Modelling and Simulation in Engineering
Online Access:http://dx.doi.org/10.1155/2017/9590214
id doaj-a95a4d9529ba4d9887d8376353997267
record_format Article
spelling doaj-a95a4d9529ba4d9887d83763539972672020-11-24T23:12:56ZengHindawi LimitedModelling and Simulation in Engineering1687-55911687-56052017-01-01201710.1155/2017/959021495902143D Numerical and Experimental Study on Paraffin Wax Melting in Thermal Storage for the Nozzle-and-Shell, Tube-and-Shell, and Reducer-and-Shell ModelsAgus Dwi Korawan0Sudjito Soeparman1Widya Wijayanti2Denny Widhiyanuriyawan3Mechanical Engineering, Brawijaya University, Malang, IndonesiaMechanical Engineering, Brawijaya University, Malang, IndonesiaMechanical Engineering, Brawijaya University, Malang, IndonesiaMechanical Engineering, Brawijaya University, Malang, IndonesiaParaffin melting experienced in the nozzle-and-shell, tube-and-shell, and reducer-and-shell models in thermal storage with 3D numerical and experimental approach has been studied. The numerical study aims to evaluate the melting process and discover temperature distribution, liquid-solid interface, liquid fraction, and the average surface Nusselt number, while the aim of this experimental study is to determine the distribution of melting temperature. The comparison of temperature distribution between the numerical approach and experimental one indicates a good agreement. The comparison result between the three models shows that the melting process of the nozzle-and-shell model is the best, followed by tube-and-shell and reducer-and-shell models, successively. To finish the melting process, the time required is 6130 s for the nozzle-and-shell model, while tube-and-shell model requires 8210 s and reducer-and-shell model requires 12280 s.http://dx.doi.org/10.1155/2017/9590214
collection DOAJ
language English
format Article
sources DOAJ
author Agus Dwi Korawan
Sudjito Soeparman
Widya Wijayanti
Denny Widhiyanuriyawan
spellingShingle Agus Dwi Korawan
Sudjito Soeparman
Widya Wijayanti
Denny Widhiyanuriyawan
3D Numerical and Experimental Study on Paraffin Wax Melting in Thermal Storage for the Nozzle-and-Shell, Tube-and-Shell, and Reducer-and-Shell Models
Modelling and Simulation in Engineering
author_facet Agus Dwi Korawan
Sudjito Soeparman
Widya Wijayanti
Denny Widhiyanuriyawan
author_sort Agus Dwi Korawan
title 3D Numerical and Experimental Study on Paraffin Wax Melting in Thermal Storage for the Nozzle-and-Shell, Tube-and-Shell, and Reducer-and-Shell Models
title_short 3D Numerical and Experimental Study on Paraffin Wax Melting in Thermal Storage for the Nozzle-and-Shell, Tube-and-Shell, and Reducer-and-Shell Models
title_full 3D Numerical and Experimental Study on Paraffin Wax Melting in Thermal Storage for the Nozzle-and-Shell, Tube-and-Shell, and Reducer-and-Shell Models
title_fullStr 3D Numerical and Experimental Study on Paraffin Wax Melting in Thermal Storage for the Nozzle-and-Shell, Tube-and-Shell, and Reducer-and-Shell Models
title_full_unstemmed 3D Numerical and Experimental Study on Paraffin Wax Melting in Thermal Storage for the Nozzle-and-Shell, Tube-and-Shell, and Reducer-and-Shell Models
title_sort 3d numerical and experimental study on paraffin wax melting in thermal storage for the nozzle-and-shell, tube-and-shell, and reducer-and-shell models
publisher Hindawi Limited
series Modelling and Simulation in Engineering
issn 1687-5591
1687-5605
publishDate 2017-01-01
description Paraffin melting experienced in the nozzle-and-shell, tube-and-shell, and reducer-and-shell models in thermal storage with 3D numerical and experimental approach has been studied. The numerical study aims to evaluate the melting process and discover temperature distribution, liquid-solid interface, liquid fraction, and the average surface Nusselt number, while the aim of this experimental study is to determine the distribution of melting temperature. The comparison of temperature distribution between the numerical approach and experimental one indicates a good agreement. The comparison result between the three models shows that the melting process of the nozzle-and-shell model is the best, followed by tube-and-shell and reducer-and-shell models, successively. To finish the melting process, the time required is 6130 s for the nozzle-and-shell model, while tube-and-shell model requires 8210 s and reducer-and-shell model requires 12280 s.
url http://dx.doi.org/10.1155/2017/9590214
work_keys_str_mv AT agusdwikorawan 3dnumericalandexperimentalstudyonparaffinwaxmeltinginthermalstorageforthenozzleandshelltubeandshellandreducerandshellmodels
AT sudjitosoeparman 3dnumericalandexperimentalstudyonparaffinwaxmeltinginthermalstorageforthenozzleandshelltubeandshellandreducerandshellmodels
AT widyawijayanti 3dnumericalandexperimentalstudyonparaffinwaxmeltinginthermalstorageforthenozzleandshelltubeandshellandreducerandshellmodels
AT dennywidhiyanuriyawan 3dnumericalandexperimentalstudyonparaffinwaxmeltinginthermalstorageforthenozzleandshelltubeandshellandreducerandshellmodels
_version_ 1725600046729134080

Similar Items