Comprehensive experimental performance study on a small-capacity transcritical R744 vapour-compression refrigeration unit equipped with an innovative ejector

• Published in: International journal of refrigeration Vol. 152; pp. 192 - 203
• Main Authors: Gullo, Paride, Birkelund, Michael, Kriezi, Ekaterini E., Kærn, Martin Ryhl
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.08.2023
• Subjects: CO2; Condensing unit; Cooling; Expansion work recovery; Flow modulation; Modulation de l’écoulement; Overfed evaporator; Refroidissement; Récupération du travail de détente; Suralimentation de l’évaporateur; Unité de condensation; Refroidissement; Cooling; Unité de condensation; Overfed evaporator; Récupération du travail de détente; CO2; Expansion work recovery; Modulation de l’écoulement; Suralimentation de l’évaporateur; Flow modulation; Condensing unit
• ISSN: 0140-7007; 1879-2081
• DOI: 10.1016/j.ijrefrig.2023.05.007

•Influence of heat sink temperature on PWM ejector and system performance is studied.•Influence of compressor speed and evaporator overfeeding is also studied.•PWM ejector with overfed evaporator shows COP increases up to 15.1% over basic unit.•PWM ejector shows COP enhancements up to 10.2% compared to passive ejector.•PWM ejector offers higher COP improvements than its currently available competitors. Ejector-equipped transcritical R744 condensing units are believed to lead to a low-to-zero commercial refrigeration sector. In order to overcome the persisting barrier to their wider adoption represented by the lack of an affordable ejector control technique, the novel pulse-width modulation (PWM) ejector, being low cost, simple and invulnerable to clogging was recently implemented. However, additional experimental evaluations are needed. Therefore, in this experimental work the performance of two PWM ejector-equipped transcritical R744 condensing units, i.e. with and without overfed evaporator, was carried out. The experimental assessment was implemented at the medium temperature (MT) of about -5 °C, heat sink temperatures from 30 °C to 40 °C and compressor speeds from 40 Hz to 60 Hz. The outcomes obtained revealed that the PWM ejector can effectively control the high pressure in transcritical operating conditions, regardless of the selected heat sink temperature and compressor speed. In addition, at the same cooling capacity, the PWM ejector-equipped R744 system was found to permit energy savings between 7.0% and 11.1% without overfed evaporator and between 11.5% and 16.3% with overfed evaporator compared to the standard R744 unit (i.e. with vapour by-pass valve and without ejector), respectively. Finally, higher values of coefficient of performance (COP) were found to be offered by the PWM ejector compared with its today's available competitors.