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Researchers develop highly efficient heat-driven thermoacoustic refrigerator

Researchers develop highly efficient heat-driven thermoacoustic refrigerator
The developed novel heat-driven thermoacoustic refrigerator and its performance. Credit: TIPC

Researchers have developed an innovative heat-driven thermoacoustic refrigerator (HDTR) with a novel bypass configuration that significantly improves the efficiency of this technology.

The research, led by Prof. Luo Ercang from the Technical Institute of Physics and Chemistry (TIPC) of the Chinese Academy of Sciences and their collaborators, was published in Cell Reports Physical Science.

HDTR is recognized as a new, promising cooling technology with many advantages. For example, it has no moving parts, uses eco-friendly substances (e.g., helium and nitrogen), and is highly reliable. However, its relatively low efficiency has hindered its .

The efficiency of HDTRs can be estimated by the coefficient of performance (COP), i.e., the ratio of output cooling power to input heating power. For existing advanced direct-coupled HDTRs, the researchers found an unexpected decrease in COP with increased heating temperature. Further, they uncovered the reason: there is a temperature matching constraint in these systems that prevents COP improvement at high heating temperatures.

To overcome this obstacle, the researchers proposed a creative bypass configuration to eliminate the temperature matching constraint. This novel configuration allows part of the acoustic power to be bypassed, thus realizing efficient acoustic power matching between the engine unit and the cooler unit at high heating temperatures.

As a result, the system achieves energy flow field synergy, which significantly improves efficiency. The researchers then built a kilowatt-scale HDTR prototype. Using helium as the working gas, they achieved a record high experimental COP of 1.12 with a cooling capacity of 2.53 kW, at the heating, ambient, and cooling temperatures of 450°C, 35°C, and 7°C, respectively. This COP is 2.7 times higher than the best result ever achieved for existing HDTRs.

According to the researchers, in the field of room-temperature, heat-driven refrigeration, their new HDTR technology not only outperforms adsorption refrigerators and single-effect absorption refrigerators but is comparable to double-effect absorption refrigerators. These results highlight the great promise of this novel HDTR technology in commercial air conditioning applications.

Compared with helium, nitrogen is a more abundant, economical refrigerant with environmental friendliness. Therefore, the researchers also tested the system's performance using nitrogen. The COP results are better than the previously reported by TIPC. The study was published in Applied Physics Letters on Jan. 8, and was specifically reported by Scilight.

The researchers claim that the novel HDTR system has an intrinsically higher COP than absorption refrigerators due to its efficient utilization of high-temperature . Their numerical analysis suggests an outstanding potential COP value of 2 for the proposed HDTR system at a heating temperature of more than 800°C.

The researchers stated that they would make some modifications to the current system and increase the heating temperature to further improve the cooling performance of the system. After making that change, they anticipate achieving a COP that exceeds double-effect absorption refrigerators in the foreseeable future.

More information: A highly efficient heat-driven thermoacoustic cooling system, Cell Reports Physical Science (2024). DOI: 10.1016/j.xcrp.2024.101815. … 2666-3864(24)00040-7

Lei Xiao et al, An efficient and eco-friendly heat-driven thermoacoustic refrigerator with bypass configuration, Applied Physics Letters (2024). DOI: 10.1063/5.0181579

Chris Patrick, Designing an environmentally sound sound-powered refrigerator, Scilight (2024). DOI: 10.1063/10.0024392

Citation: Researchers develop highly efficient heat-driven thermoacoustic refrigerator (2024, February 1) retrieved 13 April 2024 from
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