Study on inhomogeneous perforation thick micro-perforated panel sound absorbers

Prasetiyo, Iwan; Sarwono, Joko; Sihar, Indra

doi:10.15282/jmes.10.3.2016.12.0218

Cited by 19 publications

(5 citation statements)

References 12 publications

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“…Also, acoustic waves find it harder to enter the structure in the thicker panels, causing a decrease in SAC. Smaller acoustic reactance and higher acoustic resistance are required for an MPP to have a wider peak [20]. Increasing the perforation volume allows acoustic waves to pass through the perforations, lowering acoustic resistance and increasing reactance.…”

Section: Resultsmentioning

confidence: 99%

Effect of Perforation Volume on Acoustic Absorption of the 3D Printed Micro-Perforated Panels made of Polylactic Acid reinforced with Wood Fibers

Sekar

Noum

Sivanesan

et al. 2021

J. Phys.: Conf. Ser.

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In recent times, Additive Manufacturing (AM) has been applied rapidly in almost all fields. This study was conducted to apply the additive manufacturing into an acoustic application by 3D printing the Micro-Perforated Panels (MPP) through Fused Deposition Modelling (FDM) made of Polylactic Acid (PLA) reinforced with wood fibers. MPP were fabricated by altering its perforation volume. Later, the effect of perforation volume on acoustic absorption of the fabricated MPP was measured using the two-microphone impedance tube method as per ISO 10534-2 standard. The result shows altering the perforation volume affects the acoustic absorption of the MPP. MPP with a thickness of 2 mm and a perforation diameter of 0.2 mm shows the maximum sound absorption coefficient of 0.93 at 2173 Hz. It is made possible to absorb the 3D printed MPP made of natural fiber reinforced composite at different spectrums by altering the perforation volume.

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Section: Resultsmentioning

confidence: 99%

Effect of Perforation Volume on Acoustic Absorption of the 3D Printed Micro-Perforated Panels made of Polylactic Acid reinforced with Wood Fibers

Sekar

Noum

Sivanesan

et al. 2021

J. Phys.: Conf. Ser.

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“…where, As the open ratio (V) is increased, like any MPP or combination of MPPs [66][67][68] , it reduces the acoustic reactance of the system following Eqs. 5 and 7.…”

Section: Acoustic Modelmentioning

confidence: 99%

A tunable acoustic absorber using reconfigurable dielectric elastomer actuated petals

Shrestha,

Lau,

Chin

et al. 2024

Commun Eng

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Dielectric elastomer actuator (DEA)-based unimorphs that actively bend in one direction, can mimic the blooming motion of flower petals. Here we explore an application of such reconfigurable DEA to create tunable acoustic absorber capable of adapting to fluctuations in dominant noise frequency. The DEA-unimorphs consist of alternate layers of dielectric elastomers and compliant electrodes bonded to a Mylar sheet and were micro-slotted to form triangular petal-like structures that bend upon voltage activation. When arranged in an array, the micro-slotted dielectric elastomer bending actuators (MSDEBA) can open like flower petals, actively reconfiguring their open-ratio. Integrated with a base resonator comprising a micro-slotted panel (MSP) and a parallelly arranged varying-depth (VD) back-cavity, the MSDEBA forms a tunable acoustic absorber effective in the low-mid acoustic frequency range at inactive state. Meanwhile, upon voltage activation, it increased the absorber’s open-ratio and tuned the absorber to target a higher frequency. A 5 kV activation reconfigured the MSDEBA to shift its transmission loss peak by 72.74% (i.e., from 697 Hz to 1204 Hz). This acoustic spectrum tuning capability doubled the 15 dB absorption bandwidth of these absorbers from a bandwidth of ~435 Hz to 820 Hz. Such absorbers have the potential to tune the absorption spectrum to match the noise frequency in real-time to ensure optimal acoustic attenuation.

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“…Researchers have therefore tried to widen the absorption bandwidth by using multiple layers of MPP arranged in series (Bucciarelli et al, 2019;Sakagami et al, 2006;Yang et al, 2019). They have also proposed more compact configuration by arranging different MPPs in parallel (Mosa et al, 2019(Mosa et al, , 2020Prasetiyo et al, 2016;Qian and Zhang, 2022) and also using turned double layer MPP (Zhao and Lin, 2022). Previous studies have tried to modify the backing air cavity into L-shaped cavities (Gai et al, 2017); coiled cavities (Prasetiyo et al, 2021;Wu et al, 2022); subcavities with different dimensions arranged in parallel (Guo and Min, 2015).…”

Section: Introductionmentioning

confidence: 99%

Bandwidth widening for sound absorption of a flexible microperforated panel backed by a multi-frequency panel-type resonator

Yeang

Halim

2023

Journal of Vibration and Control

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A microperforated panel (MPP) often suffers from a limited absorption bandwidth and poor sound absorption in the low frequency range. The present study aimed to propose an MPP-panel-type resonator (PR) compound structure that can simultaneously widen the half-absorption bandwidth and improve the poor absorption at the low frequency range. A vibroacoustic model is developed and compared to finite element simulations to demonstrate its accuracy. The vibration characteristics of the compound structure and the surface impedance are analyzed to reveal the mechanism forming the absorption characteristics of an MPP-PR structure. It is found that backing an MPP with a panel-type resonator (PR) creates a low frequency absorption peak but followed by an absorption valley that decreases the absorption bandwidth. The analysis showed that the phase difference between velocity of air particles in perforation and the PR panel velocity dictates the absorption characteristics associated with the PR resonance. A multi-resonators panel-type resonator (MPR) is found that the absorption valley associated with the host panel resonance splits into multiple smaller amplitude absorption dips improving absorption performance. The proposed MPP-MPR compound structure demonstrated a relatively wider half-absorption bandwidth with improved low frequency absorption.

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Study on inhomogeneous perforation thick micro-perforated panel sound absorbers

Cited by 19 publications

References 12 publications

Effect of Perforation Volume on Acoustic Absorption of the 3D Printed Micro-Perforated Panels made of Polylactic Acid reinforced with Wood Fibers

Effect of Perforation Volume on Acoustic Absorption of the 3D Printed Micro-Perforated Panels made of Polylactic Acid reinforced with Wood Fibers

A tunable acoustic absorber using reconfigurable dielectric elastomer actuated petals

Bandwidth widening for sound absorption of a flexible microperforated panel backed by a multi-frequency panel-type resonator

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