SE516785C2 - Method and apparatus for controlling and silencing an air flow - Google Patents

Abstract

The flow passage 14 between an inlet 12 and an outlet 15 has a movable wall or walls 15, 16 to vary the flow cross section and sound absorbing means 19, 21 is arranged outwardly of the passage. The walls 15, 16 may be moved by bending or bodily (Fig. 6) or a circular plastics tube (160, Fig. 8) may be centrally constricted by a bellows (161). The material 21 may be replaced by baffles (Fig. 5). The walls 15, 16 may be formed by pairs of plates (17a, 17b, Fig. 7) variably compressing sound absorbing material there between.

Description

The more the sound attenuation capacity of the control device the more the more the air flow is restricted.

In a most advantageous embodiment of the invention, the throttling is regulated in such a way that the flow cross-section tapers in the direction of flow when the throttling increases. As the flow channel becomes narrower, the sound attenuation also increases.

The method according to the invention is mainly characterized in that the air flow is regulated by controlling the flow cross-sectional area towards or away from the flow channel by bending the wall structure which delimits the flow channel towards or away from the center axis of the flow channel, through which the air flow is increased or decreased, which wall structure maintains an even shape when the wall structure is bent. In this way, the sound-absorbing effect of the device and the flow resistance of the air flow is increased, whereby the curved or displaced wall elements form for the flow channel an advantageously smooth shape, which thus does not significantly increase the turbulence in the flow.

The device according to the invention is mainly characterized in that it comprises a flexible and arcuate wall construction, which delimits the sound attenuation chamber, which wall construction is perforated or porous, so that the sound waves can pass therethrough, and which wall construction can be moved by bending thereof, so that for To increase the restriction of the air flow, the wall construction is moved towards the center axis of the flow channel.

The invention is described in the following with reference to some advantageous embodiments of the invention shown in the figures in the accompanying drawings. The intention is, however, not to limit the invention only to these embodiments.

Fig. 1 shows a basic view of a first embodiment of the device according to the invention.

Fig. 2 shows the axonometric device according to Fig. 1 with a side cover lifted away.

Fig. 3 shows an axonometric view of a mechanism for displacing wall elements.

Fig. 4 shows axonometrically a wall element according to Fig. 2.

Fig. 5 shows another embodiment of a chamber construction. A lid lla on a frame structure is lifted off to damage the chamber structure.

Fig. 6A 'shows a schematic view of an embodiment of the device, where only one of the wall elements is displaced by bending it.

Fig. 6B shows an embodiment of the invention, where one of the wall elements is displaced linearly (rectilinearly in the same direction without bending the element) while another element consists of a straight stationary wall construction.

Fig. 6C shows an embodiment of the invention, where both channel wall elements are displaced linearly. Figs. 6A-6C are illustrated figures with the lid 11a removed.

Fig. 7 shows another advantageous embodiment of the wall element.

Fig. 8 shows an embodiment of the device according to the invention, where the inner flow channel in the device is constituted by a pipe construction. u non oss. Fig. 1 shows an axonometric view of a first advantageous embodiment of a device according to the invention. A device 10 provided with sound attenuation for regulating an air flow comprises a body 11, which has a connection 12 for supply air and a connection 13 for exhaust air and between these a flow channel 14, which is delimited by displaceable wall elements 15 and 16. In the embodiment according to the figure, the wall elements 15, 16 comprise a hollow disc. an advantageous insulating wool, cellular plastic or the like, connected to the neck plate 17. To the displaceable wall construction is connected a sound-absorbing chamber 20a, 20b, which is provided with a sound-absorbing construction 21, advantageously a sound-absorbing material. sound-absorbing material 19, the shape according to the figure of insulating wool or the like.

The air flow direction is indicated by arrows L1. The adjustment of the position on the walls 15,16 is indicated by arrows S1 and S2.

In the embodiment according to Fig. 1, the walls 15,16 can be adjusted so that when the air flow is restricted, the wall elements 15,16 are moved closer to each other and so that the flow channel 14 tapers wedge-shaped at an increasingly steeper angle (oi) towards the narrowest point N of the flow channel. In this case, a relatively larger part of the sound waves passes through the surface of the wall elements 15, 16 into the damping material and in this way the propagation of the sounds to the chamber 20a, 20b increases. The sound attenuation effect. of the device increases. Thus, as the need for choking and sound attenuation increases, so does the propagation of sound to the chamber 20a, 20b. The attenuation in the control device is thus increased according to the increasing need for attenuation. 15,16 are flexible, the flow channel becomes advantageous in terms of flow technology.

In the embodiment according to Fig. 1, the walls 15, 16, which delimit the duct 14, are displaced simultaneously and symmetrically in such a way that the walls 15, 16 are bent while the ends a. , b of the walls are stationary. The walls 15,16 are thus in this embodiment flexible or deformable structural details.

Fig. 2 shows an axonometric view of a device according to Fig. 1. In Fig. 2, a lid 11a on a frame structure 11 is removed to damage the inner structure. A flow channel 14 between a connection 12 for supply air and a connection 13 for exhaust air is limited by displaceable wall elements 15 and 16. Fig. 2 shows a control position with strongly restricted air flow, the wall elements 15 and 16 being close to each other at the central area of the wall elements. The flow channel 14 thus becomes tapered in the flow direction (L1) towards the narrowest point N of the channel. The walls 15,16 comprise a neck plate 17 and in connection with this sound-absorbing material 19, advantageously in the immediate vicinity of the walls 15,16, sound-absorbing housings 20a, 20b are arranged, which in the embodiment according to the figure are filled with insulating wool 21 or the like. insulating wool or equivalent. In Fig. 3 the axonometric construction of a device for displacing the side walls 15, 16 of the channel 14. shows a rail 22 mounted on a wall 11b of the frame structure 11. 22. The racks are displaced by a gear 25, which functionally engages the rods.

A shaft 25a of the gear 25 is passed through the wall 11b.

When the gear 25 is rotated from the outside of the frame structure 11, the racks 24a, 24b are displaced simultaneously and an equally long distance. The walls 15,16, which are connected to the racks by means of coupling parts 26,27, are thus simultaneously displaced either towards each other or v a o oc; anno too. n. 516 7 8 5 5 ": '.__: _', .§ ¿: .§.. g 6 from equal distances. each other. The walls 15,16 are displaced long When the shaft 25a of the gear 25 is rotated in. the direction D1 is moved the coupling parts 26,27 towards each other (arrows E1), the walls 15,16 moving towards each other, the wheel 26,27 correspondingly from each other and the walls When the tooth is rotated in the direction P2, the coupling parts 16,17 are moved apart.

Fig. 16. This comprises a flexible neck disc 17 adjacent to the channel 14, advantageous. connected the disc. 5 shows a top view of another embodiment of 20. 20a, 20b show as sound-absorbing construction 21 one of several sound waves is thrown. Fig. The chamber construction The chamber construction walls consisting of labyrinth construction. back from the walls 21 of the labyrinth construction, and sound is thus effectively attenuated in the chamber 20a, 20b due to interference (interaction) between incoming and reflected sound waves. The chamber structure 20 may also consist of several chamber groups, which contain several small chambers.

Fig. 6A shows an embodiment of the invention, where only one wall 15 in the construction is displaced (arrow S1) by bending the wall. The second wall 16 is not displaced, but is straight and in a fixed position. The gear 25 in the displacement mechanism (similar to Fig. 3) engages in which is the rack 24a, which has the coupling part 26, coupled only to the wall 15.

Fig. 6B shows an embodiment of the invention, where only one wall 15 in the construction is displaced and this linearly (arrows S2). The wall 16 is stationary and 7 The drive device in Fig. 6B corresponds to the drive device 6A. 24a is connected to the linearly displaceable wall 15 of the gear 25a. on the wall 15 is adjusted by turning the gear 25. straight. in Fig. Only one rack is present. The rack by means of the coupling part 26 intervenes functionally with the rack. The position Fig. 6C shows an embodiment of the invention, in which both the walls 15, 16 i (arrows S2 and S3). the embodiment according to the Fig. construction is linearly displaced. The walls 15 and 16 are displaced at 6C by means of a device similar to that shown in Fig. 3. The wall elements 15 and 16 are thus displaced simultaneously towards each other and an equal length, and said wall elements 15 and 16 are also simultaneously displaced from each other and an equal length. The movements of the wall elements are thus synchronized with each other- 6B and GC need not be controllable. ra. Thus, in the embodiments according to Figs. The shape of the walls 15,16 The walls 15,16 can thus consist of rigid constructions in these embodiments.

Fig. 7 shows axonometrically another embodiment of the wall element 15,16. The wall element 15, 16 comprises a flexible neck plate 17a adjacent to the channel 14, to which is attached: a damping material 19, advantageously mineral wool, cellular plastic or the like. The wall element further comprises another disc 17b, which is advantageously also a neck disc, on the other side of the sound-absorbing material 19. The hollow discs are connected to screw means 27, whereby by screwing 17a, 17b and the air-permeable resistance of the material and the tightness obtained the sound-absorbing material 19 between the discs l7a, l7b. When changing the distance between the screw means, regulating the distance between the discs, the discs 17a, 17b can thus also change the sound-absorbing properties of the sound-absorbing material 19, which advantageously consists of cellular plastic. The discs l7a, l7b are advantageously hollow discs and advantageously of metal. The discs l7a, l7b are u .. no nu unquooo: nnovqnqonu vn uounvvnnuvvuvu "v .. o: nu n .. n. .- uv. No nu uunvn 1 n nu u Q f. A 8 advantageous of such that they can Fig. 8 shows an embodiment of the device according to the invention, in which the device comprises a tube 160, of which the tube 160 is composed. The flexible flow is restricted by means of an air bellows delimiting a duct 14. tubes of eg plastic The tube cross section is 161. The tube 160 has a perforation 162 and on the other side sound attenuation chamber 20 advantageous sound insulation wool eg mineral wool. of the air flow of the perforation one to an adjacent sound attenuation material 19, the increase is increased by supplying air pressure to the bellows 161b, 160 shape is changed by subjecting the tube 160 to pressure against the X-axis from surrounding str ypstället. The pipe at least one hall. As the choke increases, the flow channel tapers wedge-shaped and in the embodiment according to the figure conformally to the narrowest point N of the flow channel and the air flow can flow smoothly over the narrowest point N. in. in the sound attenuation chamber, the sound attenuation effect is thus increased. As the pressure in the bellows 161 decreases, the tube 160 regains its original 20. The original shape of the device by its own resilience. so that air can pass through it to the sound-absorbing chamber. The tube 160 can also be of a porous material, 20, which comprises a sound-absorbing material 21 and / or a sound-absorbing construction e.g. a chamber structure and / or a labyrinth structure. If the tube 160 is of porous material, it need not be perforated. The dashed line F in the figure shows a curved shape of the tube 160. q nn-

Claims (25)

10 15 20 25 30 516 785 “in Patent Claims A method of sound attenuation and control of an air flow, wherein air is caused to flow through a control device (10) in a flow channel (14), which device comprises a perforated or porous flexible wall structure (15, 16; 160), so that air and sound waves can pass through it, which wall construction delimits a part of the flow channel (14) and is also delimited by a sound attenuation chamber, which comprises a sound attenuation material and / or a sound attenuation construction, characterized in that the air flow is regulated by control of the flow cross-sectional area towards or away from the flow channel (14) by bending the wall structure delimiting the flow channel (14) towards or away from the center axis of the flow channel, whereby the sound attenuation effect of the device and the air flow resistance increase or decrease. the wall structure is bent. Method according to Claim 1, characterized in that in the method at least one of the wall elements (15 and / or 16) adjacent to the channel (14) is bent and displaced in a perpendicular direction towards the axis of the flow channel, the width of the flow channel is reduced and the damping effect of the device and the flow resistance of the air flow is thus increased, the curved and displaced wall elements (15 and / or 16) forming for the flow channel (14) an advantageous shape, which thus does not significantly increase the turbulence in the flow. A method according to claim 1, characterized in that in the method such a device is used, which comprises a pipe delimiting a flow channel (14), which is flexible, the flow being restricted by changing the shape by pressing the wall of the pipe ( 160) towards the central axis (X) of the flow channel. Method according to claim 1, characterized in that in the method a tube (160) with a circular cross-section as wall delimiting the channel (14) is used and that such a tube (160) is used, which is of a material which enables compressing the tube (160), the tube (160) regaining its original shape when the pressing force ceases to act. Method according to claim 4, characterized in that in the method the throttling is increased by pressing the wall element (160) at least from a direction against the central axis (X) of the flow channel (14). Method according to claim 4, characterized in that a medium-filled ring is advantageously used in the method, advantageously a bellows (161) for changing the shape of the tube (160), the annular bellows (161) being actuated according to the degree of medium filling and the throttling of the air flow effected by the O: \ EIP \ DOK \ WORD-DOK \ P33384.p.doc 10 15 20 25 30 516 785 / O -form change point (N) on the pipe (160) is increased or decreased. Method according to Claim 1 or 2, characterized in that during the method two wall elements (15, 16) are displaced by bending the wall elements. Method according to Claim 2 or 7, characterized in that the wall elements (15, 16) are displaced simultaneously and an equally long distance when regulating the restriction of the air flow. Method according to one of the preceding claims 2, 7, 8, characterized in that when bending the wall element (15 and / or 16) the ends of the wall element (15 and / or 16) are held in place and the raising is performed at the central area of the element (15 and / or 16) in relation to the length of the wall element (15 and / or 16). Device (10) for sound attenuation of an air stream and for regulating the air flow, which device (10) comprises a body structure (11) and a connecting connection (12) for supply air and a connection (13) for exhaust air and the device comprises a flow channel (14) between said connections (12, 13) and the device comprises in connection with the flow channel (14) a sound attenuation chamber (20a, 20b; 20), which comprises a sound attenuation material and / or a sound attenuation construction, characterized - The device (10) comprises a flexible and arcuate wall structure (15, 16; 160) defining the sound attenuation chamber, which wall structure is perforated or porous so that the sound waves can pass therethrough, and which wall structure can be moved by bending thereof, so that to increase the throttling of the air flow, the wall structure is moved towards the center axis of the flow channel. Device according to claim 10 for sound attenuation of an air flow and for regulating the air flow, characterized in that the device comprises wall elements (15, 16) adjacent to the flow channel (14), of which at least one wall element (15 and / or 16 ) can be displaced in such a way that the flow gap between the wall elements (15, 16) is reduced when the restriction of the air flow increases and the flow gap between the wall elements 15, 16) is destroyed when the restriction is reduced. Device according to claim 10, characterized in that the device comprises a pipe structure (160) delimiting the flow channel (14), the cross-sectional shape of which is circular and that the device comprises means (161) which bend the pipe structure at the throttle point (N), wherein the pipe structure can be displaced at the throttle point towards the central axis (X) of the channel (14) when the throttle is increased. O: \ EJP \ DOK \ WORD-DOK \ P33384.p.d0c 10 15 20 25 30 5 1 6 7 8 5 I I Device according to the preceding claim, characterized in that the walls of the pipe structure (160) comprise a perforation (162) and / or the pipe (160) is of a porous material. Device according to any one of the preceding claims 10, 12, 13, characterized in that the pipe structure (160) is displaced at the periphery of the pipe structure by means of an annular bellows (161), the wall of the pipe structure (160) being displaced by of the bellows is displaced from at least one direction towards the central axis (X) of the flow channel (14) and from it. Device according to claim 11, characterized in that the wall elements (15, 16) comprise a sound-absorbing material (19). Device according to claim 11, characterized in that the device comprises means, by means of which at least one wall element (15 and / or 16) can be displaced for regulating the flow gap between the wall elements (15, 16). Device according to one of the preceding claims 11, 16, characterized in that it is such a wall element (15 and / or 16) that it can be bent in such a way that when the throttle is increased, the flow channel is made narrower. wedge-shaped in relation to the flow direction, whereby the sound-absorbing effect of the device is increased. Device according to claim 11, characterized in that it is such wall elements (15 and 16), two or only one of which can be displaced linearly towards the other wall element. Device according to claim 11, characterized in that it is such a wall element construction that two wall elements (15 and 16) are displaced by bending the wall elements (15, 16) advantageously at their central region in relation to the length of the wall elements. and that the wall elements are bent and displaced towards each other and from each other at the same time and the same distance. Device according to one of the preceding claims 10-19, characterized in that the sound-absorbing chamber (20a, 20b; 20) comprises a sound-absorbing material, advantageously mineral wool. Device according to any one of the preceding claims 10-20, characterized in that the sound-absorbing chamber (20a and / or 20b; 20) comprises, in the form of a wall construction, a labyrinth construction or a chamber group, which comprises fl your cores . Device according to one of the preceding claims 11, 15-19, characterized in that the wall elements (15, 16) are displaced by a mechanism comprising gears (25) which are rotated from the outside of the frame structure (11). ) and that racks (24a, 24b) comprise coupling parts (26, 27), each of which is connected to its wall element (15), 516 785 / Z. , 16), the racks (24a, 24b) being displaced in opposite directions by rotation of the gear (25) by rotation of its shaft 25a), the wall parts (15, 16) being displaced from each other or the wall parts (depending on the direction of rotation of the shaft (25a) 15, 16) shifted towards each other. Device according to the preceding claim, characterized in that the racks (24a, 24b) are arranged to move along guides (23a, 23b). Device according to one of the preceding claims 10, 11, 15-19, characterized in that the device comprises a wall element (15, 16) adjacent to the channel (14), which comprises a first plate (17a), and that the device comprises a sound-absorbing material (19) adjacent to the first disc (17a), advantageously mineral wool or air-permeable porous foam and that it comprises a second disc (17b), which is placed on the opposite side of the sound-absorbing material (19) than that of the duct (14) adjacent the first disc (17a), and that there are means (27), advantageously screw means, by means of which the distance between the discs (17a, 17b) is changed and thus the sound-absorbing properties of the sound-absorbing material (19) between the discs (17a, 17b) . Device according to claim 24, characterized in that the first disc (17a) is a perforated disc and advantageously a metal disc and that the second disc (17b) is also a perforated disc and advantageously a metal disc, and that the discs (17a, l7b) are flexible. O: \ EIP \ DOK \ WORD-DOK \ P33384.p.doc