The performance improvement of a cascade thermoacoustic engine by adjusting the acoustic impedance in the regenerator

Dhuchakallaya, Isares; Saechan, Patcharin; Rattanadecho, Phadungsak

doi:10.1002/er.3632

Cited by 9 publications

(12 citation statements)

References 14 publications

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“…There are several parameters affecting the cooling performance of the travelling‐wave refrigerator, such as configurations of each component, input heating power, operating pressure, and relative locations of the subsystems; these parameters have an influence on the variation of the acoustic field in the system. Previously, only the cascade thermoacoustic engine was optimally tuned as discussed by Dhuchakallaya et al Results from the earlier study demonstrated the relationship between the configurations and geometrical dimensions of the system and acoustic impedance. In this study, several attempts have been made to evaluate the optimal configurations of the engine‐refrigerator cascaded system.…”

Section: Resultsmentioning

confidence: 99%

“…Due to the hybrid mode of standing wave and travelling wave in the system, the acoustic field, ie, the acoustic impedance and phase difference between pressure and velocity, needed to be adjusted properly, especially in the regenerator in order to obtain a powerful cascade engine. As discussed in Dhuchakallaya et al, the performance of the acoustic generation was improved significantly after the phase adjustment was completely implemented.…”

Section: Introductionmentioning

confidence: 99%

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Design and experimental evaluation of a travelling-wave thermoacoustic refrigerator driven by a cascade thermoacoustic engine

Dhuchakallaya

Saechan

2017

Int J Energy Res

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Summary A travelling‐wave thermoacoustic refrigerator driven by a cascade thermoacoustic engine is evaluated experimentally in this paper. A prototype is developed under the constraint of a low‐cost and less complicated device. In order to reduce the total budget, commercial materials and standard parts are selected, and air at atmospheric pressure is used as working fluid in the system. The thermoacoustic coupled engine‐refrigerator system consists of 1 standing‐wave unit, 1 travelling‐wave unit, and 1 travelling‐wave refrigerator arranged in a linear configuration. A resonator‐tube is connected at each end of the thermoacoustic core. The effects of the length and hydraulic radius of the regenerator in the refrigerator on the cooling performance are investigated at different levels of input power. In the experimental results, the maximum temperature difference of 17.6°C was realised at the no‐load condition. The maximum coefficient of performance relative to Carnot (COPR) of 2.4% was accomplished at the cooling load of 13 W.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Design and experimental evaluation of a travelling-wave thermoacoustic refrigerator driven by a cascade thermoacoustic engine

Dhuchakallaya

Saechan

2017

Int J Energy Res

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“…Later in 1998, Yazaki et al invented a travelling‐wave thermoacoustic prime mover and observed the spontaneous gas oscillations running around the system as a travelling wave. The thermodynamic processes executing in the travelling‐wave thermoacoustic device are based on a reversible thermodynamic cycle, consequently having the potential for higher efficiency . Nevertheless, these thermoacoustic engines typically require high‐temperature heat source (above 300°C) to initiate oscillation, which severely restricts the low‐grade heat recovery.…”

Section: Introductionmentioning

confidence: 99%

Performance of an air‐cooled looped thermoacoustic engine capable of recovering low‐grade thermal energy

et al. 2020

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Summary An air‐cooled looped thermoacoustic engine is designed and constructed, where an air‐cooled cold heat exchanger (consisting of copper heat transfer block, aluminum flange, and aluminum fin plate) is adopted to extract heat and the resonant tube is spiraled and shaped to fit to the available space. Experiments have been conducted to observe how onset temperature difference and resonant frequency are affected by mean pressure, working fluid, and diameter of compliance tube. Besides, the influences of temperature difference, mean pressure, working fluid and diameter of compliance tube on pressure amplitude, output acoustic power, and thermal efficiency of the system have been investigated. The air‐cooled looped thermoacoustic engine can start to oscillate at a lowest temperature difference of 46°C, with the working fluid of carbon dioxide at 2.34 MPa. A highest output acoustic power obtained is 6.65 W at a temperature difference of 199°C, with the working gas of helium at 2.58 MPa, and the thermal efficiency is 2.21%. This work verifies the feasibility of utilizing low‐grade thermal energy to drive an air‐cooled looped thermoacoustic engine and extends its application in the water deficient areas.

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“…6 By investigating the geometrical and thermal characteristics of regenerators with different materials, Guedra et al claimed that the carbon foam was the most efficient material for the regenerator in a TWTAE. 12 From a macroscopic view, the performance of regenerator has also been improved by proposals of novel thermoacoustic configurations that help promote the thermal-to-acoustic conversion and decrease the loss, which has been the focus of many researches. They reported a maximum output acoustic power of 715 W and a highest thermoacoustic efficiency of 35.6% with the stack-type and random-fiber-type regenerators.…”

Section: Introductionmentioning

confidence: 99%

“…9,10 However, the solution to suppressing this effect was not discussed. 12,15,16 A novel looped traveling-wave thermoacoustic engine (LTWTAE) with multiple locally enlarged thermoacoustic cores (each including a regenerator sandwiched by two heat exchangers) was invented by de Blok. 11 Dhuchakallaya et al improved the acoustic field in the regenerator by inserting an appropriate pencil into the down-resonator in a cascade thermoacoustic engine.…”

Section: Introductionmentioning

confidence: 99%

Performance optimization of the regenerator of a looped thermoacoustic engine powered by low-grade heat

et al. 2018

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Summary This paper focuses on the influence of regenerator on the performance of a single‐stage looped thermoacoustic engine. Numerical simulation has firstly been carried out to investigate how the regenerator efficiency, generated acoustic power, and acoustic field in the regenerator are affected by the cross‐sectional area, regenerator length, and mesh number. Based on the numerical optimization, an experimental setup with a normalized cross‐sectional area of 14.5 and a normalized regenerator length of 0.0036 has been established, and the influence of the hydraulic radius of regenerator (determined by regenerator mesh number) on the onset process and the stable oscillation of the system has been studied. The results show that the ratio of the hydraulic radius of regenerator over thermal penetration depth should be in the range of 0.2 to 0.3, in order to achieve a low onset temperature difference and a high thermal efficiency. In the experiments, an onset temperature difference of 84°C and a thermal efficiency above 4% at a temperature difference of about 200°C were obtained, showing the potential to recover low‐grade heat.

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The performance improvement of a cascade thermoacoustic engine by adjusting the acoustic impedance in the regenerator

Cited by 9 publications

References 14 publications

Design and experimental evaluation of a travelling-wave thermoacoustic refrigerator driven by a cascade thermoacoustic engine

Design and experimental evaluation of a travelling-wave thermoacoustic refrigerator driven by a cascade thermoacoustic engine

Performance of an air‐cooled looped thermoacoustic engine capable of recovering low‐grade thermal energy

Performance optimization of the regenerator of a looped thermoacoustic engine powered by low-grade heat

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