Acoustic device

What is claimed is: 1. An acoustic device suitable for ambient temperature applications having an inlet and an outlet comprising: an external housing defining an expansion chamber; and a tubular wall extending through and partitioning the expansion chamber into a central chamber and a peripheral chamber adjacent the central chamber, wherein both the inlet and outlet communicate with the central chamber, and wherein the tubular wall has a thickness ranging from 50 micrometers to 625 micrometers and comprises a thermoplastic material having a modulus ranging from 0.2 GPa to 10 GPa and includes a plurality of apertures formed therethrough to allow air flow between the central and peripheral chambers, the plurality of apertures configured to provide an average flow resistance ranging from 100 MKS Rayls to 5000 MKS Rayls. 2. The acoustic device of claim 1 , wherein the plurality of apertures are configured to provide an average flow resistance ranging from 250 MKS Rayls to 3000 MKS Rayls. 3. The acoustic device of claim 2 , wherein the plurality of apertures are configured to provide an average flow resistance ranging from 500 MKS Rayls to 2000 MKS Rayls. 4. The acoustic device of claim 1 , wherein the tubular wall has a porosity ranging from 0.3 percent to 5 percent. 5. The acoustic device of claim 1 , wherein the tubular wall reduces pressure drop from the inlet to the outlet at a flow rate of 170 liters per minute by least 20 percent relative to the pressure drop associated with the expansion chamber alone. 6. The acoustic device of claim 5 , wherein the tubular wall reduces pressure drop by least 50 percent relative to the pressure drop associated with the expansion chamber alone. 7. The acoustic device of claim 1 , wherein the inlet and the outlet have cross-sectional diameters that generally match the cross-sectional diameter of the tubular wall. 8. The acoustic device of claim 1 , wherein the tubular wall extends along the entire length of the expansion chamber. 9. The acoustic device of claim 1 , wherein the tubular wall is a first tubular wall, the apertures are first apertures, and the peripheral chamber is a first peripheral chamber and further comprising: a second tubular wall defining a second peripheral chamber adjacent the first peripheral chamber, wherein the second tubular wall has a plurality of second apertures sized to provide an acoustic transfer impedance significantly lower than that of the plurality of first apertures. 10. The acoustic device of claim 9 , wherein the plurality of second apertures are sized to provide an average flow resistance ranging from 100 MKS Rayls to 5000 MKS Rayls. 11. The acoustic device of claim 10 , wherein the plurality of second apertures are sized to provide an average flow resistance ranging from 250 MKS Rayls to 3000 MKS Rayls. 12. The acoustic device of claim 11 , wherein the plurality of second apertures are sized to provide an average flow resistance ranging from 500 MKS Rayls to 2000 MKS Rayls. 13. The acoustic device of claim 1 , wherein the expansion chamber is a first expansion chamber, and the external housing further comprises a second expansion chamber having all the limitations of the first expansion chamber, wherein the outlet of the first expansion chamber communicates with the inlet of the second expansion chamber. 14. A method of attenuating airborne sound energy using an acoustic device suitable for ambient temperature applications with an external housing defining an expansion chamber, a tubular wall having a thickness ranging from 50 micrometers to 625 micrometers and comprising a thermoplastic material having a modulus ranging from 0.2 GPa to 10 GPa and extending through and partitioning the expansion chamber into a central chamber and peripheral chamber adjacent the central chamber, and an inlet and outlet communicating with opposing ends of the central chamber, the method comprising: flowing air through the central chamber; and directing the sound energy from the central chamber through a plurality of apertures disposed in the tubular wall, wherein the plurality of apertures provide an average flow resistance ranging from 100 MKS Rayls to 5000 MKS Rayls. 15. The method of claim 14 , wherein the tubular wall reduces pressure drop from the inlet to the outlet at a flow rate of 170 liters per minute by least 20 percent relative to the pressure drop associated with the expansion chamber alone. 16. The method of claim 14 , wherein the tubular wall extends along the entire length of the expansion chamber. 17. The method of claim 14 , wherein the tubular wall is a first tubular wall, the apertures are first apertures, and the peripheral chamber is a first peripheral chamber and further comprising: a second tubular wall defining a second peripheral chamber adjacent the first peripheral chamber, wherein the second tubular wall has a plurality of second apertures sized to provide an acoustic transfer impedance significantly lower than that of the plurality of first apertures. 18. The method of claim 17 , wherein the expansion chamber is a first expansion chamber, and the external housing further comprises a second expansion chamber having all the limitations of the first expansion chamber, wherein the outlet of the first expansion chamber communicates with the inlet of the second expansion chamber.