Influence of parameter on the performance of a standing-wave thermoacoustic prime mover

Murti, Prastowo; Setiawan, Ikhsan; Widyaparaga, Adhika; Utomo, Agung Bambang Setio; Nohtomi, Makoto

doi:10.1063/1.4958538

Cited by 2 publications

(1 citation statement)

References 11 publications

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“…In addition to the higher efficiency seen in traveling-wave thermoacoustic devices, standing-wave types offer advantages stemming from their straightforward configuration, resulting in comparatively lower manufacturing costs. This feature is attributed to the simplicity of accommodating standing-wave phasing using a basic straight resonator (Murti et al, 2016;Piccolo, 2018). On the other hand, traveling-wave types are associated with an intricate and challenging construction that usually requires a loop tube and a resonator (Backhaus and Swift, 2000).…”

Section: Introductionmentioning

confidence: 99%

Analysis of a standing wave thermoacoustic engine with multiple unit stages

Murti,

Setiawan,

Rosafira

et al. 2024

Int. J. Renew. Energy Dev.

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The thermoacoustic engine is an eco-friendly technology capable of harnessing solar and waste energy for electricity generation, in conjunction with a linear alternator, and can function as a heat pump. This engine type holds significant appeal due to its simplistic design, devoid of any mechanical moving components, comprising only a stack sandwiched between heat exchangers within a resonator. When the temperature gradient across the stack reaches the critical threshold (onset temperature), the working gas undergoes spontaneous oscillation. Typically, a high onset temperature is necessary to induce gas oscillation in a thermoacoustic engine due to viscous losses within the system. A method to lower the onset temperature by increasing the number of unit stages consisting of stacks and heat exchangers so that the engine can utilize low-grade thermal sources has been developed to overcome this challenge. However, this method has only been applied to traveling-wave thermoacoustic engines. Its application in standing-wave engines, which offer a more compact and straightforward structure, remains unexplored. This research aims to examine how the number of unit stages in a standing-wave thermoacoustic engine influences the onset temperature and acoustic field. The onset temperature is estimated using a fundamental hydrodynamics equation and the investigation of the acoustic field throughout the engine using DeltaEC software. Results showed that the strategic positioning of multiple unit stages is essential to achieve a low onset temperature. The minimum onset temperature, approximately 92°C, is obtained when three- or four-unit stages are installed. Additionally, increasing the number of unit stages does not affect the acoustic impedance and phase difference between pressure and velocity in the stack, while simultaneously enhancing both acoustic power output and thermal efficiency.

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Section: Introductionmentioning

confidence: 99%

Analysis of a standing wave thermoacoustic engine with multiple unit stages

Murti,

Setiawan,

Rosafira

et al. 2024

Int. J. Renew. Energy Dev.

Self Cite

View full text Add to dashboard Cite

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Construction and testing of small-scale thermoacoustic electricity generator with different heating power

Setiawan,

Farikhah,

Rahmawati

2024

THERM SCI

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The necessity of renewable energy is indispensable. Nowadays, researchers focus on converting waste or solar heat into advantageous energy, such as electric energy, using thermoacoustic scientific knowledge. The thermoacoustic machine converts the heat energy into sound energy and conversely. Then, using a Linear alternator, it converts into electric energy. In this study, we focus on the construction and testing of small-scale thermoacoustic electricity generators with different heating temperatures. The heat is converted into acoustic energy employing the thermoacoustic engine, and the acoustic energy is converted into electrical energy using the linear alternator. In this investigation, the heating power varies from 226 W to 389 W. The result shows that 32.2 mW of electricity was found as the thermal power at 389 W. Moreover, the onset heating temperature span is 316 .

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Influence of parameter on the performance of a standing-wave thermoacoustic prime mover

Cited by 2 publications

References 11 publications

Analysis of a standing wave thermoacoustic engine with multiple unit stages

Analysis of a standing wave thermoacoustic engine with multiple unit stages

Construction and testing of small-scale thermoacoustic electricity generator with different heating power

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