Share
IIR documentSummary
A two-phase thermosyphon loop is an ideal heat transfer device to achieve compact and efficient cooling with low energy consumption. In this paper, a two-phase thermosyphon loop with a horizontal parallel tube evaporator for multiple heat source cooling is proposed. The effect of the filling ratio on the transient response of temperature and pressure, heat transfer characteristics, instability issues, as well as flow regimes under different heat loads are investigated experimentally and visually. The filling ratios are divided into three groups according to their unique heat transfer and instability characteristics. The research results show that a too low or too high filling ratio is not conducive to the safe and stable operation of the system. At medium and high filling ratios, temperature and pressure overshoot are prone to occur, threatening the safe operation of the system; geyser boiling is another unstable phenomenon that can be inhibited as the heat load increases. Gravity will lead to uneven distribution of working fluid in the evaporator and further affect the temperature uniformity and heat transfer capability. From the perspective of temperature control performance and heat transfer capability, 30% is the optimal filling ratio in this study, with a minimum thermal resistance of 0.12 ℃ ⋅W-1 and a maximum heat transfer coefficient of 1345.36 W⋅m−2⋅℃−1. This paper provides a basis for designing and applying a two-phase thermosyphon loop for multiple heat source cooling in confined spaces.
Available documents
Format PDF
Pages: 230-243
Available
Public price
20 €
Member price*
Free
* Best rate depending on membership category (see the detailed benefits of individual and corporate memberships).
Details
- Original title: Experimental study on the effect of filling ratio on an R141b two-phase thermosyphon loop with a horizontal parallel tube evaporator.
- Record ID : 30029542
- Languages: English
- Source: International Journal of Refrigeration - Revue Internationale du Froid - vol. 137
- Publication date: 2022/05
- DOI: http://dx.doi.org/10.1016/j.ijrefrig.2022.02.013
- Document available for consultation in the library of the IIR headquarters only.
Links
See other articles in this issue (23)
See the source
Indexing
-
Research on the refrigerant column height in th...
- Author(s) : CAO H., DING T., HE Z., et al.
- Date : 2018/10
- Languages : English
- Source: International Journal of Refrigeration - Revue Internationale du Froid - vol. 94
- Formats : PDF
View record
-
Research on the refrigerant distribution and di...
- Author(s) : CAO H., LI H., HE Z., LI Z.
- Date : 2021/05
- Languages : English
- Source: International Journal of Refrigeration - Revue Internationale du Froid - vol. 125
- Formats : PDF
View record
-
Effect of inlet configuration on upward branchi...
- Author(s) : KIM N. H., BYUN H. W.
- Date : 2013/05
- Languages : English
- Source: International Journal of Refrigeration - Revue Internationale du Froid - vol. 36 - n. 3
- Formats : PDF
View record
-
Flow boiling heat transfer and liquid-vapor two...
- Author(s) : MIYATA K., NAKATSURU T., HIRATA K., et al.
- Date : 2015
- Languages : Japanese
- Source: Transactions of the Japan Society of Refrigerating and Air Conditioning Engineers - vol. 32 - n. 2
View record
-
Two-phase flow regimes of condensing R-134a at ...
- Author(s) : VANDERPUTTEN M. A., JACOB T. A., SATTAR M., et al.
- Date : 2017/12
- Languages : English
- Source: International Journal of Refrigeration - Revue Internationale du Froid - vol. 84
- Formats : PDF
View record