Resonator

Abstract

A resonator (1) has at least first and second annular chambers (2, 3, 17) arranged between inlet and outlet pieces (22, 21). An inner pipe (4) extends between the inlet piece (22) and the outlet piece (21) and has wall holes (23) that connect to the annular chambers (2, 3, 17). The first annular chamber (2) has a U-shaped circumferential wall (6) coaxial to the resonator longitudinal axis (5) and transitions at both ends to engage the inner pipe (4). The second annular chamber (3) has an L-shaped circumferential wall (12) coaxial to the resonator longitudinal axis (5). An end of the L-shaped circumferential wall remote from the first annular chamber (2) transitions into a cylindrical end piece (13), and an opposite end of the L-shaped circumferential wall lies on part of the outer wall (9) of the first annular chamber (2) extending parallel to the resonator longitudinal axis (5).

Claims

1. A resonator for lowering airborne sound and solid-borne sound, comprising: an inner pipe extending along a resonator longitudinal axis between an inlet piece and an outlet piece, the inner pipe having a wall and a plurality of wall holes formed in the wall; and at least first and second annular chambers engaging the plurality of wall holes to be mounted to the inner pipe between the inlet piece and the outlet piece, the at least first and second annular chambers arranged side-by-side along the resonator longitudinal axis, wherein the first annular chamber has a U-shaped circumferential wall including an outer wall portion coaxial to the resonator longitudinal axis and first and second ring walls connected to the outer wall portion at positions spaced along the resonator longitudinal axis and arranged normal to the resonator longitudinal axis, first and second cylindrical end pieces connected respectively to the first and second ring walls and extending in directions opposite one another along and parallel to the resonator longitudinal axis, the first and second cylindrical end pieces engaging the inner pipe, and the second annular chamber has an L-shaped circumferential wall including an outer wall coaxial to the resonator longitudinal axis and a side wall projecting inward from the outer wall and normal to the resonator longitudinal axis on a side of the second annular chamber opposite the first annular chamber, a cylindrical end piece arranged parallel to the resonator longitudinal axis connected to the side wall, and an end of the outer wall of the second annular chamber opposite the side wall arranged to at least partially overlap a part of the outer wall of the first annular chamber in surface-to-surface contact.

2. The resonator according to claim 1, further comprising a third annular chamber with an L-shaped circumferential wall coaxial to the resonator longitudinal axis, an end of the L-shaped circumferential wall of the third annular chamber facing away from the first annular chamber and transitioning into a cylindrical end piece, and an end of the L-shaped circumferential wall of the third annular chamber facing the first annular chamber lying on the part of the outer wall of the first annular chamber extending parallel to the resonator longitudinal axis.

3. The resonator according to claim 1, wherein the cylindrical end piece of the second annular chamber is engaged around the inner pipe.

4. The resonator according to claim 1, wherein the cylindrical end piece of the second annular chamber is engaged with the inlet piece or the outlet piece.

5. The resonator according to claim 4, wherein the inlet piece and/or the outlet piece engage with the inner pipe.

6. The resonator according to claim 1, wherein the wall holes are slits that communicate with the annular chambers.

7. The resonator according to claim 1, wherein the inner pipe has at least one end located outside of the annular chambers and defining a part of an air or gas supply system.

8. The resonator according to claim 7, wherein the inner pipe is angled at its end that is located outside of the annular chambers.

9. The resonator according to claim 8, further comprising a connection flange arranged at the at least one end of the inner pipe.

10. The resonator according to claim 1, wherein, for predetermined installation volumes, the annular chambers and the inner pipe and the wall holes of the inner pipe are matched to required damping characteristics.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a 3D cutaway view of a resonator for lowering airborne and solid-borne sound, designed with three annular chambers.

(2) FIG. 2 is an exploded view of the resonator from FIG. 1.

(3) FIG. 3 is a cross-sectional lateral view of another resonator with three annular chambers.

(4) FIG. 4 is a cross-sectional lateral view of another resonator with three annular chambers and modified slit-shaped wall holes.

(5) FIG. 5 is a lateral view of another resonator with three annular chambers and modified slit-shaped wall holes.

(6) FIG. 6 is a cross-sectional lateral view of another resonator with two annular chambers.

DETAILED DESCRIPTION

(7) A resonator 1 for lowering airborne and solid-borne sound essentially comprises a first annular chamber 2, a second annular chamber 3 and an inner pipe 4.

(8) The first annular chamber 2 is arranged coaxial to a resonator longitudinal axis 5 and has an essentially U-shaped circumferential wall 6 which at both ends transitions into cylindrical end pieces 7, 8. The U-shaped wall 6 has an outer wall 9 running parallel to the resonator longitudinal axis 5, said outer wall being limited by two ring-shaped side walls 10, 11 arranged perpendicular to the resonator longitudinal axis 5. The outer wall 9 transitions into the end pieces 7, 8 by way of the side walls 10, 11.

(9) The second annular chamber 3 has an L-shaped circumferential wall 12 coaxial to the resonator longitudinal axis 5, which L-shaped circumferential wall, at its end facing away from the first annular chamber 2, transitions into a cylindrical end piece 13. At its end 14 facing the first annular chamber 2, the L-shaped wall 12 lies on the outer wall 9 of the first annular chamber 2. The L-shaped wall 12 of the second annular chamber 3 has an outer wall 15 running parallel to the resonator longitudinal axis 5 with the end 14 facing the first annular chamber. In the direction of the end piece 13 of the second annular chamber, the outer wall 15 is limited by a side wall 16 running perpendicular to the resonator longitudinal axis 5, which side wall transitions into the end piece 13 of the second annular chamber 3. The second side wall of the second annular chamber 3 is thus formed by the second side wall 11 of the first annular chamber 2.

(10) In accordance with the exemplary embodiments in FIGS. 1 to 5, a third annular chamber 17 is provided, which also has an L-shaped circumferential wall 18 coaxial to the resonator longitudinal axis 5, which L-shaped circumferential wall, at its end facing away from the first annular chamber 2, transitions into a cylindrical end piece 19, and at its end 20 facing the first anular chamber 2, the said L-shaped circumferential wall lies, with its outer wall 24, on the outer wall 9 of the first annular chamber 2 or the U-shaped wall 6. The outer wall 24 transitions into the end piece 19 by way of a side wall 25. The third annular chamber 17 thus essentially corresponds to the second annular chamber 3, however it will generally have a different longitudinal extension in the direction of the resonator longitudinal axis 5.

(11) According to the exemplary embodiment of FIGS. 1 and 2, the cylindrical end pieces 7, 8, 13, 19 are designed to accommodate the inner pipe 4, i.e. the inner pipe 4 is insertable into the end pieces 7, 8, 13, 19.

(12) According to the exemplary embodiments of FIGS. 3 to 5, the end pieces 7, 8 and 19 of the annular chambers 2, 17 are designed to accommodate the inner pipe 4. The end piece 13 of the second annular chamber 3 is designed to accommodate an outlet piece 21 that is connected to the inner pipe 4. According to the exemplary embodiments of FIGS. 1 to 5, the end piece 19 of the third annular chamber 17 transitions into the inlet piece 22.

(13) According to the exemplary embodiment of FIGS. 1 and 2, the inlet piece 22 is formed by the end piece 19 of the third annular chamber 17 and the outlet piece 21 is formed by the end piece 13 of the second annular chamber.

(14) According to the exemplary embodiment of FIG. 6, the inlet piece 22 is formed by the first end piece 7 of the first annular chamber 2. The end piece 13 of the second annular chamber is designed to accommodate the outlet piece 21, which in turn is connectable to the inner pipe.

(15) The inner pipe 4 has wall holes 23 as a connection to the annular chambers 2, 3, 17. The wall holes 23 are designed as slits in the exemplary embodiments of FIGS. 1 to 6.

(16) According to the exemplary embodiments of FIGS. 3 to 6, the inner pipe 4 is connected to a second inner pipe 26 that expands in steps towards the outlet piece 21.

(17) The embodiments discussed in the specific description and shown in the figures obviously represent merely illustrative embodiments of the present invention. In the light of the present disclosure a person skilled in the art has a broad spectrum of optional variations available. In particular, additional annular chambers or other volume chambers can be added. It is also possible to reverse the position of the inlets and outlets in order to reverse the flow direction. Finally, it is also possible to divide up the inner pipe and to form a gap instead of a slit-shaped wall hole.

LIST OF REFERENCE NUMBERS

(18) 1 resonator 2 first annular chamber 3 second annular chamber 4 inner pipe 5 resonator longitudinal axis of 1 6 U-shaped wall of 2 7 first end piece of 2 8 second end piece of 2 9 outer wall of 6 10 first side wall of 6 11 second side wall of 6 12 L-shaped wall of 3 13 end piece of 3 14 end of 12 15 outer wall of 12 16 side wall of 12 17 third annular chamber 18 L-shaped wall of 17 19 end piece of 17 20 end of 18 21 outlet piece 22 inlet piece 23 wall hole 24 outer wall 25 side wall of 18 26 second inner pipe