A novel dual-PCM configuration to improve simultaneous energy storage and recovery in triplex-tube heat exchanger

A novel triplex-tube heat exchanger (TTHX) is proposed to improve the simultaneous storage and recov-ery processes via an effective dual-PCM configuration. The proposed design achieves better storage and recovery compared to the application of aluminum oxide (Al2O3) nanoparticles of 1% or 3% volume frac-tion with a single-PCM configuration. The storage/recovery system contains two sections holding PCMs with equal volumes but different melting points. Different dual-PCM configurations are examined and compared for two different scenarios of initially fully melted or solidified conditions. A numerical model is developed and validated against existing data. The results show that employing an optimum arrange-ment of dual-PCMs can improve the rate of melting and solidification in the TTHX under simultaneous charging and discharging (SCD). A configuration with radial separation of PCMs is found to be ideal to accelerate both melting and solidification, such that the PCM with lower melting temperature is housed close to the hot tube. In that case, 23.43%, and 18.87% enhancement is achieved in energy storage and recovery, respectively, compared with the reference case. A parametric optimization reveals that signifi-cant improvement could be achieved by applying an upward eccentricity of 17 mm to the radial sector of the selected configuration. In 3 h SCD process with initially solidified/melted conditions in TTHX, the new design enhances the thermal energy storage and recovery as 37.93%, and 21.06%, respectively, which could be further improved to 76.9% in storage and 32.9% in recovery by adding 3% nanoparticles. (c) 2021 Elsevier Ltd. All rights reserved.

Automated summary

A novel triplex-tube heat exchanger (TTHX) with an effective dual-PCM configuration is proposed to improve the simultaneous storage and recovery processes. The optimized arrangement of dual-PCMs enhances the rate of melting and solidification, and the addition of nanoparticles further improves the performance.