DE4311334A1 - Method and device for regulating and soundproofing an air flow - Google Patents

Description

The invention relates to a method and a Vorrich device for regulating and soundproofing an air flow.

So-called duct silencers are known from the prior art known in which the air flow at a so-called sound absorber the chamber structure is guided along. On both One side of the flow channel is in their walls perforated chamber construction into which the duct noise are steered, the chamber construction as a damper con structure for the sound waves mentioned. A channel Muffler construction of the type mentioned is for example in U.S. Patent 4,287,962.

When using such from US Pat. No. 4,287,962 or Similar writings known separate dampers were in the mentioned application did not seek a solution for the Find the cause of the real problem. It wasn't tries to create the undesired Störungsge to prevent noise. When throttling the air flow with Controllers create a large part of such disturbing noises, that still require such a separate damper unit, as they e.g. B. is just described in U.S. Patent 4,287,962.  

The aim of the present application is to create a Find a solution to the basic problem. In the A method and a device are described in the application with which the majority of the occurrence of noise is prevented by regulating the air flows a device solution is used, which by itself includes a damper. In the registration is a facility created for air flow control with which the air flow flow rate can be regulated so that the disturbance do not propagate noise in the rest of the sewer system. At the Throttling the air flow will reduce the soundproofing ability of the Regulator increases the more the air flow is throttled becomes.

In the most appropriate embodiment of the invention the throttling is carried out such that the through river cross-section narrowed with increasing throttling. With The narrowing flow channel also reduces sound insulation to.

It is essential for the method according to the invention characteristic that an air flow through a regulator direction is guided in a flow channel, the one Flow channel limiting wall structure, which for Central axis of the flow channel is movable, the Wall construction in the device near the sound insulation chamber is housed, which by bending or moving the to the flow channel bordering wall construction to the through flow channel axis towards the flow cross-sectional area of the through flow channel is reduced and thereby the sound insulation performance and the air flow resistance of the device be enlarged, with the curved or moving wall elements of the flow channel a cheap, uniform give changing shape, so the flow turbulence does not significantly increased.  

For the device solution according to the invention is in essentially characteristic that the device from a there is a wall structure bordering the flow channel, wherein the wall construction is movable such that at Increasing the throttling of the air flow to the wall construction is moved towards the central axis of the flow channel.

In the following the invention with reference to a Aus shown in the pictures of the drawing management examples of the invention, on the details of which However, the invention is not limited, described in detail.

In Fig. 1, a first embodiment of the device solution according to the inven tion is shown in principle.

In Fig. 2, the device solution according to Fig. 1 is shown in perspective, with the side cover removed.

In Fig. 3, the movement mechanism of the Wandele elements is shown in perspective.

In Fig. 4 the wall element according to Fig. 2 is shown perspecti visch.

In Fig. 5, a second form of construction of the cavity structure is shown. The lid 11 a of the body structure is removed to clarify the chamber structure.

In Fig. 6A in a principle view of an embodiment is shown, by being bent in only one wall element moves.

FIG. 6B shows an embodiment in which one wall element is moved linearly (straight in the same direction, not bent), the other wall element being a wall construction that just remains in place.

FIG. 6C shows an embodiment in which both wall elements of the channel are moved linearly. FIGS. 6A-6B are representations veranschauli sponding. The lid 11 a is removed.

In Fig. 7 another advantageous embodiment of the wall element is shown.

In Fig. 8 an embodiment of the device according to the invention is shown which has a tubular construction as the inner flow channel.

In Fig. 1 shows a first advantageous embodiment of the device according to the invention is shown as perspective. The equipped with muffler controller 10 consists of a body 11 having an inlet air connection 12 and an outlet air connection 13 and between them a flow channel 14 , the movable wall elements 15 and 16 limit. In the embodiment shown, the wall elements 15 , 16 consist of a perforated plate 17 , which has a perforation 18 . In the embodiment shown, the perforated plate 17 is connected to sound insulation material 19 , advantageously mineral wool, foam or the like. Be movable wall construction includes a sound insulation chamber 20 a, 20 b, which is provided with a sound-absorbing construction 21 , expediently sound-absorbing material, which in the embodiment shown consists of insulating wool or the like.

The direction of flow of the air is indicated by arrow L ₁ . The regulation of the position of the walls 15 , 16 is represented by the arrows S ₁ and ₂ .

In the embodiment according to FIG. 1, the walls 16 , 17 are adjustable in such a way that the wall elements 15 , 16 are brought closer together when the air flow is throttled in such a way that the narrowest point N of the air flow channel leads through the flow channel 14 increasingly Angle () wedge-shaped narrower. The relatively larger part of the sound waves through the surface plane of the Wandele elements 15 , 16 in the insulation material and the sound entering the chamber 20 a, 20 b increases. The soundproofing effect of the device increases. Thus, with an increased throttling and sound insulation requirement, the sound entry into the chamber 20 a, 20 b and thus the controller insulation is increased in accordance with the increase in the insulation requirement. With the flexible Wandelemen 15 , 16 , the flow channel is fluidically favorable. The air flow runs uniformly through the throttle point N.

In the embodiment according to FIG. 1, the walls 15 , 16 delimiting the channel 14 are moved simultaneously and in phase in such a way that the walls 15 , 16 are bent, the ends a, b of the walls remaining in their place. Thus, the walls 15 , 16 in this embodiment are flexible and shape-changeable components.

In Fig. 2, the device solution according to Fig. 1 is shown per spective. In the illustration of Fig. 1, the cover 11 a of the body structure 11 is removed ent to illustrate the inner structure. The flow channel 14 , which is delimited by the movable wall elements 15 and 16 , is located between the inlet air connection 12 and the outlet air connection 13 . In Fig. 2, a control position is shown in which the air flow is greatly throttled and the wall elements 15 and 16 in the Mittelbe rich of the wall elements are set close to each other, the flow channel 14 in the flow direction (L ₁ ) to the narrowest point (N) of the Flow channel narrowed. The walls 15 , 16 have a perforated plate 17 and on this soundproofing material 19 , advantageously mineral wool or the like. Immediately on the walls 15 , 16 are the soundproofing chambers 20 a, 20 b, which are filled with insulating wool 21 or the like in the embodiment shown.

In Fig. 3, the construction of the movement device of the side walls 15 , 16 of the channel 14 is perspective Darge. On the wall 11 b of the body structure 11 , a rail 22 is attached. In the guides 13 a, 13 b of the rail 22 , movable racks 24 a, 24 b are attached, which are moved by a gear 25 which is functionally connected to the racks. The shaft 25 a of the gear 25 is guided through the wall 11 b. When turning the gear 15 outside the body structure 11 , the racks 24 a, 24 b are moved at the same time and the same distance. In this way, the walls 15 , 16 connected to the toothed racks via the contact pieces 26 , 27 are either either towards one another at the same time or the walls 15 , 16 mentioned are simultaneously moved away from one another. The transport routes of the walls 15 , 16 are the same.

When rotating the shaft 25 a of the gear 25 in the direction D ₁ , the contact pieces 26 , 27 are moved towards one another (arrows E ₁ ), as a result of which the walls 15 , 16 are moved towards one another. Accordingly, when turning the gear 25 in Rich direction P _2, the contact pieces 26 , 27 apart and the walls 16 , 17 moved away from each other.

In Fig. 4, a second wall element 16 is shown perspecti visch. This consists of a border on the channel 14 bordering, expediently made of metal flexible perforated plate 17 , to which sound insulation material 19 , expedient mine wool is attached. The plate 17 is provided with perforation 18 .

In Fig. 5, a second embodiment of the chamber construction 20 is shown in plan view, the Kammerkon construction 20 a, 20 b as a sound-absorbing construction 21 consists of a labyrinth construction formed from several walls. The sound waves reflect on the walls 21 of the labyrinth construction; thus the sound in the chamber 20 a, 20 b is effectively insulated due to the interference (interaction) of the reflections and the reflected sound waves. The chamber construction 20 can also be formed from a plurality of chamber groups which consist of a plurality of small chambers.

In FIG. 6A, one embodiment of the invention, showing Ge, in which only one wall 15 of the structure by being bent is moved (arrow S _1). The other wall 16 is not moved, but is straight and in a fixed position. Via movement mechanisms (as in Fig. 3), the gear 25 is connected to the rack 24 a, which has only one contact piece 26 connected to the wall 15 .

In Fig. 6B an embodiment of the invention is shown ge, in which only one wall 15 of the construction, namely linear (arrows S ₂ ) is moved. The wall 16 remains in place and is straight. The drive of FIG. 6B corresponds to that of FIG. 6A. There is only one rack. The rack 24 a is linearly connected to the wall 15 to be moved via the contact piece 26 . The gear 25 is functionally connected to the rack 24 a. The position of the wall 15 is adjusted by rotating the gear 25 .

In Fig. 6C is an embodiment of the invention shows ge, in which both walls 15, 16 of the construction linear (Pfeiffer le S ₂ and S ₃₎ to be moved. The walls 15 and 16 are moved in the embodiment according to FIG. 6C with a corresponding device as in FIG. 3. Thus, the wall elements 15 and 16 are moved towards one another at the same time and by the same distance and the wall elements 15 and 16 are moved away from each other at the same time and by the same distance, the movements of the wall elements being synchronized with one another. Thus, the shape of the elements 15 , 16 need not be variable in the embodiment according to FIGS. 6B and 6C. The walls 15 , 16 can thus also be rigid constructions in these embodiments.

In Fig. 7 another embodiment of the Wandele element 15 , 16 is shown in perspective. The wall element 15 , 16 consists of a bordering on the duct 14 flexible perforated plate 17 a, on which soundproofing material 19 , advantageously mineral wool, foam or the like, is attached. The wall element also has a second plate 17 b, which is also expediently a perforated plate and is located on the opposite side of the sound insulation material 19 . The perforated plates are miteinan connected by screwing devices, so that by turning the screwing devices the distance between the plates 17 a, 17 b and the air permeability resistance of the material and the density to which the soundproofing material between the plates 17 a, 17 b is brought . Thus, by changing the distance from the plates 17 a, 17 b, the soundproofing properties of the soundproofing material 19 , expediently foam, are also changed. The plates 17 a, 17 b are suitably perforated plates and suitably made of metal. The plates 17 a, 17 b are expedient also of such air-permeable, porous material that they can be bent or pressed in such a way that the mate rial gets back its original thickness when the effect of the compressive force ceases.

In FIG. 8, an embodiment of the erfindungsge MAESSEN device is shown, wherein the device comprises a channel 14 defining tube 160 is composed. The tube 160 is an elastic, such as. B. plastic pipe. The pipe diameter is appropriately round. The air flow is throttled with an air bellows 161 . The pipe 160 has a perforation 162 and on the other side of the perforation a sound insulation material 19 adjacent to the sound insulation chamber 20 , appropriately sound insulation wool such as. B. mineral wool. The air flow restriction is increased by bringing air pressure into the bellows 161 b surrounding the throttling point. The shape of the tube 160 is changed by pressing the tube 160 at least from one direction to the X axis. By increasing the throttling, the flow channel narrows wedge-shaped and, in the embodiment shown, is conical to the narrowest point N of the flow channel and the air flow becomes a smooth course over the point N light. When the throttling is increased, however, the sound waves also enter through the perforated tubular construction 160 into the sound insulation chamber 20 and thus the sound insulation effect is increased. If the pressure inside the tube 160 is reduced, the tube 160 returns to its original shape by its own spring force.

The tube 160 can also consist of porous material such that the air penetrates through it into the soundproofing chamber 20 , which is made of soundproofing material 21 and / or a soundproofing construction such as, for. B. a chamber construction and / or labyrinth construction. If tube 160 is made of porous material, it need not be perforated. In the figure, a broken shape of the tube 160 is shown by the dashed line F.

Claims (25)

1. A method for sound insulation and air flow regulation, characterized in that an air flow through a control device ( 10 ) is guided in a flow channel ( 14 ) having a flow channel ( 14 ) delimiting wall construction ( 15 , 16 ; 160 ), which is movable towards the central axis (X) of the flow channel ( 14 ), the Wandkon construction ( 15 , 16 ; 160 ) in the device ( 10 ) close to the soundproofing chamber ( 20 a, 20 b; 20 ), whereby by Bending or moving the wall structure ( 15 and / or 16 , 160 ) adjacent to the flow channel ( 14 ) towards the flow channel axis (X) reduces the flow cross-sectional area of the flow channel ( 14 ) and thereby increases the sound insulation performance and the air flow resistance of the device, the curved or moving wall elements ( 15 and / or 16 , 160 ) give the flow channel a favorable, uniformly changing shape, which thus the flow turbulence is not significantly increased. 2. The method according to claim 1, characterized in that in the method at least one of the wall elements ( 15 and / or 16 ) adjoining the channel ( 14 ) is bent or moved in a perpendicular direction to the flow channel axis, thereby reducing the width of the flow channel and thus the insulation effect and the flow resistance of the air flow of the device are increased, the curved and moving wall elements ( 15 and / or 16 ) giving the channel a favorable shape, which thus does not substantially increase the flow turbulence. 3. The method according to claim 1, characterized in that a device is used in the method, which consists of a flow channel ( 14 ) delimiting tube, which is elastic, whereby the flow is throttled by changing the shape by the wall of the tube ( 160 ) to the central axis (X) of the flow channel is pressed. 4. The method according to claim 1, characterized in that in the method a tube ( 160 ) with a round cross section is used as the channel ( 14 ) delimiting wall element and that such a tube ( 160 ) is used, which consists of a material which compressing the tube ( 160 ) allows the tube ( 160 ) to return to its original shape when the action of the compressive force ceases. 5. The method according to claim 4, characterized in that the throttling is increased in the method by the wall element ( 160 ) is pressed at least from one direction to the central axis (X) of the flow channel ( 14 ). 6. The method according to claim 4, characterized in that in the method a ring which is filled with a medium, advantageously a bellows ( 161 ) is used to change the shape of the tube ( 160 ), depending on the degree of filling of the medium is acted on the annular bellows ( 161 ) and the throttling caused by the shape change point (N) of the tube ( 160 ) is increased or decreased. 7. The method according to claim 1 and 2, characterized in that in the method both wall elements ( 15 , 16 ) are moved in that the wall elements are bent. 8. The method according to claim 1, 2 and 7, characterized in that when regulating the throttling of the air flow, the wall elements ( 15 , 16 ) are moved at the same time and over equally long distances. 9. The method according to claim 1, 2, 7 and 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 and the bending with respect to the length of the wall element ( 15 and / or 16 ) is carried out in the central region of the wall element ( 15 and / or 16 ). 10. A device ( 10 ) for soundproofing an air flow and for regulating the air flow, the device ( 10 ) having a body construction ( 11 ) and a connector ( 12 ) for inlet air and a connector ( 15 ) for outlet air and that the device between said connections ( 12 , 15 ) has a flow channel ( 14 ) and the device on the flow channel ( 14 ) has a sound insulation chamber ( 20 a, 20 b; 20 ), which consists of sound insulation material and / or a sound insulation construction , characterized in that the device ( 10 ) consists of a wall structure ( 15 , 16 ; 160 ) bordering the flow channel ( 14 ), the wall structure ( 15 , 16 ; 160 ) being movable such that when the throttling is increased, the Air flow the wall construction ( 15 , 16 ; 160 ) to the central axis (X) of the flow channel ( 14 ) is moved. 11. The device according to claim 10 for soundproofing an air flow and for regulating the air flow, characterized in that the device consists of wall elements ( 15 , 16 ) bordering the flow channel ( 14 ), at least one wall element ( 15 and / or 16 ) is movable of the type that when increasing the throttling of the air flow, the flow gap between the wall elements ( 15 , 16 ) is reduced and when reducing the throttling the flow gap between the wall elements ( 15 , 16 ) is increased. 12. The apparatus according to claim 10, characterized in that the device consists of a flow channel ( 14 ) delimiting tubular structure ( 160 ), the cross-sectional shape of which is round and that the device has devices ( 161 ) which the tube structure at the throttling development point Bend (N), whereby the pipe construction can be moved at the throttling point to the central axis (X) of the channel ( 14 ) when increasing the throttling. 13. The apparatus according to claim 12, characterized in that the walls of the tubular structure ( 160 ) have a perforation ( 162 ) and / or the tube ( 160 ) is made of porous material. 14. The apparatus of claim 10, 12, 13, characterized in that the tubular structure ( 160 ) on the circumference of the tubular construction with an annular bellows ( 161 ) is moved, by moving the bellows, the wall of the tubular structure ( 160 ) at least a direction to the central axis (X) of the flow channel ( 14 ) and moved away from it. 15. The apparatus according to claim 10 and 11, characterized in that the wall elements ( 15 , 16 ) from Schalldämmungsma material ( 19 ). 16. The apparatus according to claim 10 and 11, characterized in that the device has devices with which at least one wall element ( 15 and / or 16 ) is moved in order to regulate the flow gap between the wall elements ( 15 and / or 16 ). 17. The apparatus according to claim 10, 11, 16, characterized in that the wall element ( 15 and / or 16 ) is of such a type that it can be bent such that the flow channel is narrowed in a wedge shape with respect to the flow direction when the throttling is increased, which increases the sound insulation effect. 18. The apparatus of claim 10 and 11, characterized in that the wall elements ( 15 and / or 16 ) are such that both or only one of them to the other Wandele element is linearly movable. 19. The apparatus of claim 10 and 11, characterized in that the wall element construction is such that both wall elements ( 15 and / or 16 ) are moved by the wall elements ( 15 and / or 16 ) in relation to the length of the wall element Expediently be bent in the central area and that the wall elements are bent at the same time and moved towards and away from each other by the same distance. 20. The apparatus according to claim 10 to 19, characterized in that the sound insulation chamber ( 20 a, 20 b; 20 ) consists of sound insulation material, advantageously mineral wool. 21. The apparatus according to claim 10 to 20, characterized in that the soundproofing chamber ( 20 a and / or 20 b; 20 ) as a wall structure consists of a labyrinth structure or a chamber group which comprises several chambers. 22. The apparatus of claim 10, 11 and 15 to 19, characterized in that the wall elements ( 15 , 16 ) are moved with a mechanism which consists of racks ( 24 a, 24 b), which is functional via an outside of the body perkonstruction ( 11 ) to be rotated gear ( 25 ) and that the racks ( 24 a, 24 b) have contact pieces ( 26 , 27 ) which each connect to their wall element ( 15 , 16 ), the gear ( 25 ) by rotating its shaft ( 25 a), the racks ( 24 a, 24 b) are moved in opposite directions, depending on the direction of rotation of the shaft ( 15 a), the wall parts ( 15 , 16 ) move away from each other or towards each other will. 23. The apparatus according to claim 22, characterized in that the racks ( 24 a, 24 b) in guides ( 23 a, 23 b) are movably attached. 24. The device according to claim 10, 11 and 15 to 19, characterized in that the device has a wall element ( 15 , 16 ) bordering the channel ( 14 ), which consists of a plate ( 17 ), and that the device consists of a to the plate ( 17 ) adjoining sound insulation material ( 19 ), advantageously mineral wool or air-permeable porous foam, and that a second perforated plate ( 17 b) is present, which is arranged on the opposite side of the sound insulation material as ( 19 ) than that the channel ( 14 ) bordering plate ( 17 ), and that devices ( 27 ), appropriately screw devices, are available with which the distance between the plates ( 17 a, 17 b) and thus the sound insulation properties of the between the plates ( 17 a , 17 b) existing sound insulation materials ( 19 ) is changed. 25. The apparatus according to claim 24, characterized in that the plate ( 17 a) is a perforated plate and expediently a metal plate and that the plate ( 17 b) is also a perforated plate and expediently a metal plate, and that the plates ( 17 a , 17 b) let it bend.