Customisable sound absorption properties of functionally graded metallic foams

doi:10.1016/j.jmst.2021.07.056

Abstract

Abstract:

In this study, functionally graded foam made of Inconel 625 superalloy was successfully produced using the template replication method, with open-cell polyurethane foams as a precursor. The products have a similar pore morphology as the templates and adjacent layers were successfully sintered together by particle bonding. Sound absorption experiments on graded metallic foams reveal that the sound absorption at particular frequency ranges can be improved by various permutations of foam layers. For graded foam of two distinct pore sizes, a mathematical equation was proposed to predict the location of the intersection point of the sound absorption curves, thereby aiding in graded foam design. An increase in sound absorption coefficients by resonance-like effects can be introduced before the intersection points by placing the foam layer of smaller pore size nearer to the sound source. The sound absorption performances can be further customized when the thickness proportion of the pore sizes is changed and when the number of distinct pore sizes used is increased. The sound absorption performance at lower frequencies is generally boosted by resonance-like effects when the layer of foam with the largest pore size is placed furthest from the sound source. Given the same composition of foam with a fixed thickness proportion of pore sizes, one can introduce resonance-like effects to improve the sound absorption performance compared to other permutations while possibly satisfying weight requirements in practical applications. This study provides valuable insights and mathematical guidelines in the design and manufacturing of functionally graded metallic foam for specific applications.

Key words: Template replication method, Functionally graded foam, Sound absorption, Transfer matrix method, Composite metal foa

Jun Wei Chua, Xinwei Li, Tao Li, Beng Wah Chua, Xiang Yu, Wei Zhai. Customisable sound absorption properties of functionally graded metallic foams[J]. J. Mater. Sci. Technol., 2022, 108: 196-207.

Figures/Tables 15

Fig. 1. Overview of the template replication technique. The polymer template foam is immersed in the metal slurry to fully coat the struts. The excess slurry is removed by repeated compression. The green bodies are then dried and sintered to form the metal foam.

Fig. 2. Representative sample of a functionally graded foam (PPI 45-80-60).

Fig. 3. SEM images of PU template foam and the corresponding metal foam for (a) PPI 45, (b) PPI 60, (c) PPI 80. Notice the similar pore morphology between the PU and metallic foam for the same PPI. The pore sizes for the metallic foam are smaller than that of the respective PU foams.

Fig. 4. SEM images of the boundary between two metallic foam layers of different PPI: (a) PPI 45 and PPI 80, (b) PPI 80 and PPI 60, (c) PPI 60 and PPI 45. By layering the PU green bodies together before sintering, the particles on the struts at the boundary may bond together, such that the adjacent layers are sintered together.

Table 1. Calculated porosities and airflow resistivities of metallic foams of different PPI.

PPI	Porosity (%)	Flow Resistivity ( $\text{Pa}\;\text{s}\;{{\text{m}}^{-2}}$)
45	97.0	996
60	93.7	4968
80	92.9	7363

Fig. 5. Sound absorption coefficient curves (experimental and TMM predictions) for metallic foam: (a) PPI 80, (b) PPI 60-45 and (c) PPI 60-80-45. The observed experimental and predicted curves are close to each other, suggesting that the method in Section 2.4 was adequate in predicting the sound absorption coefficients of functionally graded metallic foam in this study.

Fig. 6. Sound absorption coefficient distribution of metallic foam of one pore size with different pore sizes for thicknesses of (a) 20 mm; (b) 40 mm; and (c) 60 mm, respectively.

Fig. 7. Phasor representation diagram of the impedance of metallic foam of one pore size with different pore sizes for thicknesses of (a) 20 mm; (b) 40 mm; and (c) 60 mm, respectively. The dotted lines represent ellipses with constant absorption coefficients.

Fig. 8. Sound absorption coefficient distribution of metallic foam of one pore size with different thicknesses for (a) PPI 45; (b) PPI 60; and (c) PPI 80, respectively.

Fig. 9. Plots of average sound absorption coefficient between 1000 and 5000 Hz with varying thicknesses for PPI 45, 60 and 80. Generally, the average sound absorption increases with increasing thickness or decreasing pore size.

Fig. 10. Sound absorption coefficient of functionally graded metallic foam of thickness 40 mm with different layer arrangements for (a) PPI 45 and 60; (b) PPI 45 and 80; (c) PPI 60 and 80. Marked in a cross in each figure is the intersection points between the two curves.

Fig. 11. (a) Sound absorption coefficient distribution of the functionally graded metallic foam of thickness 40 mm for PPI 45 and 80, calculated from DB and TMM models for frequencies below 6000 Hz. (b) Plots of Eq. (26) with frequency. Notice the closeness in intersection points with the line $\text{ }\!\!\Delta\!\!\text{ }\alpha =0$.

Fig. 12. Sound absorption coefficient distribution of functionally graded metallic foam of thickness 60 mm with different layer arrangements for (a) PPI 45 (2 layers) and 60 (1 layer); (b) PPI 45 (2 layers) and 80 (1 layer); (c) PPI 60 (2 layers) and 45 (1 layer); (d) PPI 60 (2 layers) and 80 (1 layer); (e) PPI 80 (2 layers) and 45 (1 layer); (f) PPI 80 (2 layers) and 60 (1 layer).

Fig. 13. Sound absorption coefficient distribution of functionally graded metallic foam of thickness 60 mm with different layer arrangements for PPI 45, 60 and 80, each of thickness 20 mm.

Table 2. Average and standard deviation data for cases in Fig. 13.

PPI			Average of $\alpha $				Standard deviation of $\alpha $
Layer 1	Layer 2	Layer 3	1000-2000 Hz	2000-4000 Hz	4000-5000 Hz	Overall	Standard deviation of $\alpha $
45	60	80	0.89070	0.92255	0.92286	0.91467	0.03500
45	80	60	0.91064	0.92812	0.91026	0.91929	0.02755
60	45	80	0.92126	0.89240	0.88771	0.89844	0.06635
60	80	45	0.95100	0.88894	0.93403	0.91572	0.04704
80	45	60	0.92992	0.84724	0.95578	0.89504	0.07625
80	60	45	0.95085	0.86747	0.94296	0.90719	0.06408

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