Numerical Simulation Study of Coagulation Characteristics of Paraffin Cavity with Gradient TPMS Framework

您当前的位置：

首页 >

文章列表页 >

Numerical Simulation Study of Coagulation Characteristics of Paraffin Cavity with Gradient TPMS Framework

更新时间：2025-01-15

- Numerical Simulation Study of Coagulation Characteristics of Paraffin Cavity with Gradient TPMS Framework
- Journal of Refrigeration (2025)
- 作者机构：
  
  山东建筑大学热能工程学院
- 作者简介：
- 基金信息：
- DOI：
  CLC：
- 稿件说明：
移动端阅览
Numerical Simulation Study of Coagulation Characteristics of Paraffin Cavity with Gradient TPMS Framework. [J/OL]. Journal of refrigeration, 2025.
DOI：

Numerical Simulation Study of Coagulation Characteristics of Paraffin Cavity with Gradient TPMS Framework. [J/OL]. Journal of refrigeration, 2025. DOI：

摘要

本文通过三周期极小曲面法（Triply Periodic Minimal Surface，TPMS）构建均匀金属骨架和梯度孔隙率骨架。基于孔隙尺度，采用有限元方法数值模拟含金属骨架的相变材料的凝固过程，并与纯石蜡腔体的凝固过程进行比较，考察复合相变材料凝固中骨架结构的影响规律。通过对凝固过程中固液相变界面、整体固相率，瞬时固化速率、冷源壁面Nu数、储冷性能等方面综合分析，得到以下结论：在相变腔体中加入TPMS骨架，对固液形变过程影响显著，其中孔隙率为0.78相变腔体较纯石蜡相变腔体凝固时间缩短94.1%，储冷速率提升12.98倍。在平均孔隙率为0.84时，孔隙率沿x正方向梯度增大相变腔体凝固时间最短，提升腔体传热效率，较纯石蜡相变腔体凝固时间缩短93.5%，储冷速率提升12.60倍；较相同孔隙率均匀TPMS骨架相变腔体凝固时间缩短12.23%，储冷速率提升15.3%。

Abstract

In this paper

homogeneous metal skeleton and gradient porosity skeleton are constructed by three-periodic minimal surface method ( TPMS). Based on the pore scale

the finite element method is used to simulate the solidification process with the solidification process of pure paraffin cavity

and investigate the influence law of the skeleton structure in the solidification of composite phase change material. Through the comprehensive analysis of solid-liquid phase change interface

overall solid phase rate

Nu number of cold source wall and cold storage performance

the following conclusion was obtained: Adding TPMS skeleton to the phase change cavity and the porosity of 0.78 phase change cavity was 94.1% shorter than the solidification time of pure paraffin phase change cavity

and the cooling storage rate was increased by 12.98 times. At the average porosity of 0.84

the porosity increases the solidification time of the cavity along the positive direction of x is the shortest

reducing the solidification time by 93.5%

and increasing the cooling storage rate by 12.60 times; the solidification time by 12.23% and the cooling storage rate by 15.3%.

关键词

相变储冷TPMS骨架梯度分布有限元方法传热系数

Keywords

phase change thermal storageTPMS skeletongradient distributionfinite element methodcoefficient of heat transfer

references

Views

下载量

CSCD

Alert me when the article has been cited

提交

Tools

Publicity Resources

Optimization of Shell-side Single Phase Heat Transfer Correlation for Coil-wound LNG Heat Exchanger

Related Author

朱银锋

黄泽忠

张强

范益伟

卢浩

何平

欧阳新萍

苏博文

Related Institution

武汉科技大学冶金装备及其控制教育部重点实验室

安徽建筑大学机械与电气工程学院

上海理工大学

江苏科菱库精工科技有限公司

西安交通大学、美的暖通与楼宇事业部研发中心

Address：10/F, Yindu Mansion, 67 Fucheng Road, Haidian Dist, Beijing, China Postal code：100142
Tel：010-68711412 Email：editor@car.org.cn
Technical support is provided by Beijing Founder electronics co., LTD 京ICP备09064830号-19 京公网安备11010802024621
It is recommended to read the content of this site in Chrome&IE9+. Please switch to extreme mode in browser 360.
Cookies We use cookies to help provide and enhance our service and tailor content. By continuing, you agree to the use of cookies.

⁰