DE102020201086A1 - Ventilation device for a motor vehicle, Helmholtz resonator and device for manufacturing - Google Patents

Abstract

The invention relates to a ventilation device (1) for a motor vehicle, in particular for an electric vehicle, with an air duct (2) which has a ventilation space (8), with a Helmholtz resonator (3) arranged in the ventilation space (8) and designed for sound insulation, which has a resonator wall (5) which forms a resonator chamber (9) in the air guide space (8) and which has a plurality of resonator openings (10) through which the resonator chamber (9) is fluidically connected to the air guide space (8). It is provided that the resonator wall (5) is designed at least in sections as a cylinder wall in the form of a circular ring segment.

Description

The invention relates to a ventilation device for a motor vehicle, in particular for an electric vehicle, with an air duct which has a ventilation space, with a Helmholtz resonator arranged in the ventilation space and designed for sound insulation, which has a resonator wall which forms a resonator chamber in the air duct and the one Having a plurality of resonator openings, through which the resonator chamber is fluidically connected to the air guide space.

The invention further relates to a Helmholtz resonator for a ventilation device designed as described above and to a device for producing such a Helmholtz resonator.

Ventilation devices of the type mentioned at the beginning are already known from the prior art. For example, the laid-open specification discloses WO 2018/060428 A1 a ventilation device for ventilating an interior of a motor vehicle. The ventilation device has an air duct through which, for example, fresh air drawn in from the outside and possibly conditioned fresh air is passed into the vehicle interior. In the air guide space formed by the air duct, a Helmholtz generator for acoustic insulation is arranged, which has a resonator wall which forms a resonator chamber and which is provided with a multiplicity of throughflow openings. Due to the arrangement, number and design of the flow openings and the resonator wall itself, the acoustic behavior of the ventilation device can advantageously be damped, so that vehicle occupants do not or hardly perceive the ventilation acoustically. In particular, in motor vehicles that are designed as electric vehicles or that at least allow purely electric driving, this leads to an increase in comfort for the vehicle occupants, because the driving noises can otherwise be drowned out by the ventilation device due to the quiet drive technology.

From the published patent application DE 10 2010 006 444 A1 a noise reduction system with a Helmholtz resonator is also known, it being possible to influence a characteristic of the Helmholtz resonator during operation.

The invention is based on the object of creating an advantageous ventilation device, an advantageous Helmholtz resonator and an advantageous device for producing such a Helmholtz resonator, which allow simple assembly of the Helmholtz resonator and in particular also simple adaptation of the Helmholtz resonator to different ventilation devices and / or boundary conditions of the ventilation device make possible.

The object on which the invention is based is achieved by a ventilation device having the features of claim 1. This has the advantage that an advantageous design of the resonator wall, on the one hand, simplifies the manufacturability of the Helmholtz resonator and, on the other hand, ensures advantageous installation of the Helmholtz resonator in the air duct. According to the invention, this is achieved in that the resonator wall is designed as a curved cylinder wall with a continuous cross section in the longitudinal direction. The resonator wall thus extends longitudinally in the manner of a cylinder wall, which ensures that the resonator wall can be easily manufactured on the one hand and that the air duct can be easily adapted to accommodate the Helmholtz resonator on the other hand. The cylindrical shape of the resonator wall means that the resonator wall or the Helmholtz resonator can be mounted displaceably in its longitudinal extension with little effort. As a result, the Helmholtz resonator can be easily installed by pushing it into the air duct. In particular, the air duct only requires an opening in a side wall, the contour of which corresponds to the contour of the Helmholtz resonator, so that the Helmholtz resonator can simply be pushed into the air duct through this opening. In addition, the advantageous design of the resonator wall offers the possibility of simply and precisely producing the Helmholtz resonator using a camshaft and adapting it to different boundary conditions, as will be explained in more detail below.

According to a preferred development of the invention, the cylinder wall is formed at least in sections in the form of a circular ring segment in cross section. As a result, the curvature of the cylinder wall runs along a circular ring shape, which on the one hand results in advantages with regard to insulation / damping and with regard to the manufacture of the Helmholtz resonator.

The air duct particularly preferably has a sliding guide, the Helmholtz resonator being able to be pushed into the air duct from the outside through the sliding guide. The sliding guide aligns the Helmholtz resonator advantageously in the air duct, so that the desired damping effect is reliably guaranteed by simple assembly. The sliding guide also serves to hold the Helmholtz resonator in the desired location when the ventilation device is in operation, so that additional fastening means are not necessary. In particular, the rail guide is aligned such that the Helmholtz resonator at least in Can be pushed into the air duct essentially transversely to the air flow in the air duct.

Furthermore, it is preferably provided that the rail guide leads from a first side wall of the air channel to a second side wall of the air channel opposite the first side wall, a channel opening or recess for inserting and withdrawing the Helmholtz resonator being formed in the first side wall. The Helmholtz resonator can thus be pushed into and out of the air channel through the channel opening, thereby ensuring simple assembly and disassembly of the ventilation device. The contour of the channel opening is preferably adapted to the contour of the Helmholtz resonator in cross section, so that only a small opening area in the side wall is necessary for the Helmholtz resonator.

In particular, the channel opening is designed to be complementary at least to the outer contour of the Helmholtz resonator, preferably to the outer contour and inner contour of the Helmholtz resonator. As a result, the opening also serves in particular to support the Helmholtz resonator on / in the air duct.

Furthermore, it is preferably provided that at least the second side wall has a depression and / or elevation configured to correspond to the resonator wall, for an end-face fluid-tight contact of the resonator wall with the second side wall. During assembly, the Helmholtz resonator with the resonator wall is thus guided up to the second side wall, in particular with the aid of the mentioned rail guide, so that the front side of the resonator wall comes to rest against the second side wall. The indentation or elevation formed there ensures that the resonator wall is in fluid-tight contact with the side wall, thereby avoiding a flow bypass and ensuring the function of the Helmholtz resonator. The elevation and / or depression is particularly preferably designed to form a type of labyrinth seal together with the resonator wall.

Furthermore, it is preferably provided that the channel opening is assigned at least one closing element for closing and releasing the channel opening. The closing element advantageously ensures that an air flow cannot escape from the air duct through the duct opening during operation.

According to a preferred development of the invention, the resonator wall has at least one sliding foot which protrudes laterally from the resonator wall and which is mounted or can be mounted in the rail guide of the air duct so as to be longitudinally displaceable. The sliding foot, in particular a plurality of sliding feet, ensures an advantageous, longitudinally displaceable mounting in the rail guide in a simple manner. In particular, the sliding foot is designed in such a way that it engages in the rail guide, as a result of which the resonator wall is held in the air duct in a form-fitting manner.

The Helmholtz resonator is particularly preferably Ω-shaped (omega-shaped). For this purpose, sliding feet are formed on the resonator wall, each at a free end, seen in cross section, which preferably protrude away from one another. Alternatively, however, the sliding feet can also face one another, in which case the rail guide must then be designed accordingly. As a result of this design, the Helmholtz resonator is provided with an overall continuous cross section, so that its manufacture is simple and assembly, as described above, is advantageously made possible by pushing it in.

The rail guide particularly preferably has one or two guide grooves which are aligned parallel to one another and in each of which a sliding foot of the Helmholtz resonator engages in a longitudinally displaceable manner. This ensures reliable guidance of the Helmholtz resonator and permanent holding of the Helmholtz resonator in the air duct. In addition, the advantageous rail guide offers the advantage that it forms a labyrinth seal together with the sliding feet of the Helmholtz resonator, which ensures that the air flow can only penetrate into the resonator chamber through the specially provided resonator openings in the resonator wall.

The rail guide is particularly preferably designed in the form of a C-profile. This ensures that the Helmholtz resonator is aligned and held securely in the air duct in a simple manner. In particular, for this purpose the Helmholtz resonator has two outwardly protruding sliding feet, which extend over the entire longitudinal extent of the resonator wall and thereby ensure reliable guidance in the rail guide.

The Helmholtz resonator according to the invention with the features of claim 11 is characterized in that its resonator wall is designed as a curved cylinder wall with a continuous cross section in the longitudinal direction. This results in the advantages already mentioned above.

The device according to the invention for producing the Helmholtz resonator described above is characterized by an injection mold which has two tool halves which can be moved relative to one another, the tool halves when assembled form a cavity which corresponds to the shape of the resonator wall of the Helmholtz resonator, with a hole device being arranged in or on one of the tool halves, the several pins which can be displaced independently of one another in the cavity for formation the resonator openings in the resonator wall, wherein the pins are mounted displaceably in a guide wall running parallel to the resonator wall, and wherein the hole device has a rotatably mounted camshaft assigned to the guide wall for displacing the pins. The device according to the invention has the advantage that both the shape of the Helmholtz resonator and the number and type of resonator openings are produced in the injection molding process. The type, number and arrangement of the resonance openings in the resonator wall is determined by the pins actuated by the camshaft. By changing the camshaft and / or the arrangement and / or number of pins, it is possible to adapt the resonance openings in the resonator wall at any time. As a result, a large number of different Helmholtz resonators can be formed with one and the same device. This makes it possible, for example, to adapt the Helmholtz resonator optimally to expected boundary conditions during manufacture.

Each pin is preferably assigned at least one spring element, by means of which the pin is pushed out of the cavity or in the direction of the camshaft. In this way, the respective pin is displaced into the cavity by the camshaft against the spring force and automatically returns to its starting position when the camshaft no longer actuates the pin. This ensures that the pins can be easily displaced into and out of the cavity safely.

Furthermore, it is preferably provided that the hole device has a plurality of cams detachably fastened to the camshaft for the individual actuation of the pins. The selection of which of the pins is actuated in order to produce corresponding resonance openings in the resonator wall is thus made by attaching the cams to the camshaft. Depending on the number and arrangement of the cams attached to the camshaft, the actuation of the pins and thus the hole pattern of the resonance openings in the resonator wall can thus be implemented in a simple manner. The camshaft is particularly preferably designed in such a way that a cam can be fastened to the camshaft for each of the existing pins. Furthermore, it is preferably provided that the camshaft can only be rotated over a limited range of rotation, from an initial position and an end position, so that none of the pins is actuated in the initial position and all the desired pins are actuated by the associated cam in the end position.

• 1 eine vorteilhafte Belüftungseinrichtung in einer perspektivischen Darstellung,
• 2 eine schematische Darstellung der Belüftungseinrichtung,
• 3 eine Seitenansicht der Belüftungseinrichtung,
• 4 eine vereinfachte Schnittdarstellung der Belüftungseinrichtung,
• 5 eine vorteilhafte Vorrichtung zum Herstellen eines Helmholtzresonators für die Belüftungseinrichtung,
• 6 eine Detaildarstellung der Vorrichtung aus 5,
• 7 eine vorteilhafte Nockenwelle der Vorrichtung aus 5 in einer perspektivischen Darstellung, und
• 8A und 8B eine vereinfachte Detailansicht der vorteilhaften Vorrichtung in unterschiedlichen Betriebszuständen.

Further advantages and preferred features and combinations of features emerge in particular from what has been described above and from the claims. The invention will be explained in more detail below with reference to the drawings. To show

• 1 an advantageous ventilation device in a perspective view,
• 2 a schematic representation of the ventilation device,
• 3 a side view of the ventilation device,
• 4th a simplified sectional view of the ventilation device,
• 5 an advantageous device for producing a Helmholtz resonator for the ventilation device,
• 6th a detailed representation of the device 5 ,
• 7th an advantageous camshaft of the device 5 in a perspective view, and
• 8A and 8B a simplified detailed view of the advantageous device in different operating states.

1 shows in a perspective illustration an advantageous ventilation device for a motor vehicle not shown in detail here. The ventilation device has an air duct 2 on, which can be connected at one end, for example, to an air conditioning device of the motor vehicle. In the air duct 2 is a Helmholtz resonator for acoustic insulation 3 arranged, for example in the area of one in the jacket wall of the air duct 2 trained air distribution opening 4th . The Helmholtz resonator 3 has a curved resonator wall 5 which, according to the present exemplary embodiment, is designed as a cylinder wall which has a cross-section that is continuously constant or the same in the longitudinal direction. Here is the curvature of the resonator wall 5 in the present case selected in such a way that the resonator wall 5 from a floor 6th of the air duct 2 starting from the cross section has the course of a Gaussian distribution. At least in the area of the floor 6th the opposite tip is the resonator wall 3 designed in the shape of a circular ring segment. The Helmholtz resonator 3 is advantageously designed as an insert part, which is laterally through a side wall 7th of the air duct 2 into the through the air duct 2 formed air duct 8th is inserted. The resonator wall 5 divides the air duct 8th so that between the Resonator wall 5 and the ground 6th a resonator chamber 9 is trained. The resonator wall has a multiplicity of resonator openings 10 on through which the resonator chamber 9 with the air duct 8th is fluidly connected, so that through the air duct 2 air flowing into the resonator chamber 9 can get in and out of this. The Helmholtz resonator 3 is designed to be in the air duct 2 to act acoustically damping that in operation of the ventilation device 1 Noise otherwise generated by the air flow can be reduced.

2 shows the ventilation device in a simplified representation, in which the Helmholtz resonator 3 from the air duct 2 away. This is the side wall 7th of the air duct 2 open in the area of the Helmholtz resonator. In particular, the side wall 7th in the area of the Helmholtz resonator 3 a recess or channel opening 11 on, through which the Helmholtz resonator laterally into the air duct 2 is retractable. To slide in from the side is in the bottom 6th of the air duct 2 a rail guide 12th educated. The rail guide 12th is designed in the shape of a C profile and has two guide webs running parallel to one another 13th on that from the floor 6th protrude in such a way that between the guide webs 13th and the ground 6th one guide groove each 14th arises. The guide grooves 14th are open facing each other, so that the C-profile of the rail guide 12th results. The guide bars run here 13th transversely to the longitudinal extent of the air duct and thus from the open side wall 7th to that of the open side wall 7th opposite and closed according to the present embodiment side wall 15th . The Helmholtz resonator 3 is therefore easy by means of the rail guide 12th in the air duct 2 through the guide bars 13th up to the side wall 15th retractable. The resonator wall 5 is designed in such a way that its free side edges, seen in cross section, into the guide grooves 14th Can be pushed in so that it can be pushed in by means of the rail guide 12th simply in the air duct 2 can be pushed in and through the guide grooves 13th is also securely held and aligned in the air duct. Optional to the course of the resonator wall described above 5 Seen in cross-section as a Gaussian distribution, a further exemplary embodiment provides that the cross-sectional profile of the Helmholtz resonator is Ω-shaped, as for example in FIG 5 shown.

3 shows an advantageous closing element 16 , which is designed, the open side wall 7th to close during operation. This is the closing element 16 designed as a cover part, the outer contour of which is at least substantially the contour of the channel opening 11 in the air duct 2 is equivalent to. The closing element 16 is on the air duct 2 permanently attachable. For this purpose, it is provided according to the present exemplary embodiment that on the air duct 2 arranged several laterally protruding locking tabs and in particular in one piece with the air duct 2 are trained. The locking tabs 17th , as in 2 shown, each have a locking element in the form of a locking lug at their free ends 18th on. The closing element 16 , as in 3 shown, has a plurality of bow-shaped projections on its outer circumference, each having a latching opening 20th form. The protrusions 19th are designed in such a way that the locking openings 20th to accommodate the locking tabs 18th are formed, the locking lugs 18th only under elastic deformation by the projections 19th can be pushed through so that they are behind the bow-shaped projection after being pushed through 19th snap into place and thereby the locking element 16 on the air duct 2 keep. Alternatively, you can use the locking tabs 17th designed to do so after the assembly of the closing element 16 to be deformed under plastic deformation in such a way that it is the closing element 16 permanently on the air duct 2 keep. The closing element is also conceivable as an option 16 alternatively or additionally on the air duct 2 to screw, to clamp, to brace, to weld or to glue.

Both the side wall 15th as well as by the closing element 16 formed sidewall 7th each preferably have a sealing device 21 on. The sealing devices 21 are in particular as wells 22nd in the respective side wall 7th , 15th formed, the groove-shaped depressions 21 have a course that corresponds to the course of the resonator wall 5 corresponds in cross section, so that the resonator wall 5 both on the side wall 15th as well as on the side wall 7th in the respective recess 22nd can penetrate in areas, so that a labyrinth seal is formed which ensures that an air stream cannot flow past the resonator wall. The depressions 22nd are related to the rail guide 12th arranged such that the Helmholtz resonator 3 simply through the recess 11 in the air duct 2 can be inserted laterally in such a way that the resonator wall 5 into the depressions 22nd got.

4th shows a simplified sectional view of a longitudinal section through the side wall 15th in the area of the sealing device 21 . Here is the deepening 22nd in one down along the side wall 15th extending protrusion 23 educated. The depression 22nd is wedge-shaped and complementary to the resonator wall 5 on that of the side wall 15th assigned end. This causes the resonator wall 5 advantageous in the recess 22nd with the formation of the aforementioned labyrinth seal and ensures, on the one hand, a tight fit of the resonator wall 5 on the side wall 15th and on the other hand, a sturdy bracket of the Helmholtz resonator 3 in the air duct 2 . The wedge shape also allows easy assembly.

5 shows an advantageous device 24 for the production of the Helmholtz resonator described above 3 . The device is designed as an injection molding device which has a two-part injection mold. A first half of the tool 25th and a second tool half 26th the device 24 can be moved relative to one another and, when assembled, form a cavity 27 between them, which is at least substantially the shape of the Helmholtz resonator 3 is equivalent to. According to the present embodiment, the tool half forms 25th the outer contour of the Helmholtz resonator 3 the end. The tool half 26th in the present case applies an advantageous hole device which is designed to open the resonator 10 in the resonator wall 5 to manufacture. Here is the punching device 28 designed to increase the number of resonator openings 10 as well as their arrangement individually. To this end, the hole device 28 a guide wall 29 that is between the tool halves 25th , 26th extends, the extension of the guide wall 29 the extension of the resonator wall 5 so that the resonator wall 5 between the mold half 25th one hand and the guide wall 29 on the other hand can be produced by injection molding.

In the guide wall 29 are a variety of guide openings 30th formed, in each guide opening 30th one pen each 31 is held so that it can be displaced from one into the cavity 27 protruding position in one of the cavity 27 pushed out retraction position is displaceable. This is referring to 8th explained in more detail. The openings 30th and pens 31 are in the form of a matrix over the guide wall 29 arranged distributed, with the pins 31 can be moved independently of one another into the cavity. The respective pen is located 31 inside the cavity, the pin creates an opening in the resonator wall during injection molding 5 generated. Is the respective pen 31 moved into the retracted position, the resonator wall is at this point 5 continuous, i.e. without openings. Depending on which of the pens 31 thus into the cavity 27 is advanced, the number and arrangement of the resonator openings differs 10 in the resonator wall to be produced 5 .

To determine the sliding position of the pins 31 has the punching device 28 a rotatably mounted camshaft 32 on. The camshaft is between an activation position, as in 5 shown, and a deactivation position rotatable, wherein the angle of rotation range is less than 50 °, in particular 10 to 30 ° angle of rotation. There is also a rotation angle limitation 43 present that to the camshaft 32 cooperates in particular in the manner of a bayonet lock.

6th shows a cross-sectional view of the camshaft 32 according to a further embodiment. The camshaft has a large number of screw openings 33 on. There is a screw cam in each of the screw openings 34 Can be screwed in so that it is radial from the camshaft 32 to actuate or move one of the pins 31 protrudes. Alternatively, there are the screw cams 34 on the camshaft 32 releasably attached by a plug connection, clamp connection or the like. In the alternative design, the screw cams are 34 then accordingly not designed as screw cams, but rather as plug-in cams or clamping cams. While in a design as a screw cam 34 , as in 6th shown, also the screw holes 33 have a circular cross-section, the screw openings 33 , according to the alternative embodiment, in the form of plug-in or clamping openings, also have a cross-section deviating from a circular shape. The camshaft 32 points for each of the pens 31 one screw hole each 33 on, not being in any of the screw holes 33 a screw cam 34 must be arranged.

7th shows a simplified perspective view of the camshaft, in which it can be seen that the screw openings 33 preferably in the form of a matrix over the jacket wall of the camshaft 32 are arranged distributed. It also runs through the camshaft 32 axially an air duct 35 , especially through the center of the camshaft 32 . This air duct 35 is through several radial channels 36 , for example radial holes, with the screw openings 33 connected in such a way that through the air duct 35 conveyed air into an air duct 37 of the respective screw cam 34 can flow in to form the Helmholtz resonator from the mold halves 25th , 26th to facilitate. In the activation position of the camshaft 32 are the air ducts 37 the pens 31 each opposite in such a way that an outflow of air flows past the pin in the cavity 27 got. The rotation angle limitation 43 is in the present case formed by two radially protruding and spaced apart in the circumferential direction or on the camshaft 32 arranged, in particular web-shaped rotary stops formed, which with one of the tool halves 25th , 26th , especially with the lower half of the tool 26th , cooperate in the direction of rotation in such a way that the angle of rotation range of the camshaft 32 is restricted to preferably less than 30 °, in particular less than 10 °. While in the in 7th embodiment shown the rotation angle limitation 43 is formed by protruding rotary stops, is according to the embodiment of 5 provided that the camshaft 32 two extend over the length of the camshaft 32 extending depressions for limiting the angle of rotation 43 has, in which projections of the device 24 , especially the tool halves 25th and or 26th intervene to adjust the angle of rotation of the camshaft 32 as described above.

8A and 8B each show the device in a simplified sectional view 24 . 8A shows the device 27 in the event that the camshaft is in the deactivation position, and 8B shows the device 24 in the event that the camshaft 32 has been turned to the activation position. A screw cam is shown in the sectional view 34 shown of one of the pens 31 assigned. Each of the pins is a spring element 38 assigned as a return spring through which the respective pin 31 out of the cavity 27 out towards the camshaft 32 is pushed. The pencil 31 stands in some areas from the guide wall 29 in front, so that a bevel 39 of the pen 31 in the movement path of the screw cam 34 lies when the camshaft 32 is rotated into the activation position. According to 8A is the pen 31 not actuated and lies outside the cavity 27 . Will the camshaft 32 twisted, as described above, the screw cam runs 34 with a bevel 40 against the run-up slope 39 and thereby displaces the pen 31 towards the cavity 27 . The tool half advantageously has 25th on the respective pen 31 facing side each have a receiving recess 41 for receiving the cavity in certain areas 27 facing pin end of the respective pin 31 so that the respective pen 31 the cavity 27 can completely traverse, so that after molding the finished resonator wall 5 in the place of the pen 31 now a resonator opening 10 is present.

By means of the device 24 it is possible, depending on the number and arrangement of the screw cams 37 a different perforation in the resonator wall 5 to train. This is the Helmholtz resonator 3 easily adaptable to different boundary conditions with sound insulation. Preferably the pins are 31 designed in such a way that they are free of play or almost free of play in the receiving recesses 41 can be inserted in order to prevent material from entering the receiving recess during the injection process 41 got himself. The pins are useful 31 in addition, there is no radial play or almost no play in the guide wall 29 guided in order to avoid that the injected plastic material comes out of the mold. Optionally, however, remain between the respective pin 31 and the deepening 41 or guide wall 29 a radial gap through which material can penetrate that is removed from the resonator wall in a final grinding or machining process 5 is removed, and by which it is ensured that the injection mold is completely filled with plastic material and in particular no gas inclusions remain.

As in 5 also shown is the resonator wall according to this exemplary embodiment 5 Seen in cross-section, formed in the shape of a circular ring segment, with sliding feet protruding laterally or radially at the ends of the resonator wall 42 are formed in the guide grooves 14th for guiding and aligning the Helmholtz resonator 3 in the air duct 2 are insertable. In this case the Helmholtz resonator 3 overall Ω-shaped - seen in cross section - formed.

List of reference symbols

1

Ventilation device

2

Air duct

3

Resonator wall

4th

Distributor opening

5

Resonator wall

6th

floor

7th

Side wall

8th

Air duct

9

Resonator chamber

10

Resonator openings

11

Channel opening

12th

Rail guide

13th

Guide groove

14th

Guide groove

15th

Side wall

16

Closing element

17th

Locking tab

18th

Locking lug

19th

head Start

20th

Locking opening

21

Sealing device

22nd

deepening

23

head Start

24

contraption

25th

Tool half

26th

Tool half

27

cavity

28

Punching device

29

Guide wall

30th

Guide opening

31

pen

32

camshaft

33

Screw opening

34

Screw cams

35

Air duct

36

Radial channel

37

Air duct

38

Spring element

39

Approach slope

40

Approach slope

41

Receiving recess

42

Sliding foot

43

Rotation angle limitation

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• WO 2018/060428 A1 [0003]
• DE 102010006444 A1 [0004]

Claims (14)

Ventilation device (1) for a motor vehicle, in particular for an electric vehicle, with an air duct (2) which has a ventilation space (8), with a Helmholtz resonator (3) which is arranged in the ventilation space (8) and designed for sound insulation and which has a resonator wall ( 5) which forms a resonator chamber (9) in the air guide space (8) and which has a plurality of resonator openings (10) through which the resonator chamber (9) is fluidically connected to the air guide space (8), characterized in that the Resonator wall (5) is designed at least in sections as a circular ring segment-shaped cylinder wall. Ventilation device according to the preceding claim, characterized in that the air duct has a rail guide (12), and that the Helmholtz resonator (3) is mounted displaceably in the air duct (2) by the rail guide (12). Ventilation device according to one of the preceding claims, characterized in that the rail guide (12) leads from a side wall (7) of the air duct (2) to a second side wall (15) of the air duct (2) opposite the one side wall (7), wherein in one side wall (7) has a channel opening (11) for inserting or withdrawing the Helmholtz resonator (3). Ventilation device according to one of the preceding claims, characterized in that the channel opening (11) is designed to be complementary to the outer contour of the Helmholtz resonator (3). Ventilation device according to one of the preceding claims, characterized in that at least the second side wall (15) has a recess (22) and / or elevation corresponding to the resonator wall (5) for a frontal fluid-tight contact of the resonator wall (5) with the second side wall (15). Ventilation device according to one of the preceding claims, characterized in that the channel opening (11) is assigned at least one closing element (16) for closing and releasing the channel opening (11). Ventilation device according to one of the preceding claims, characterized in that the resonator wall (5) has on at least one longitudinal edge a sliding foot (42) protruding laterally from the resonator wall (5), which is mounted in the rail guide (12) of the air duct (2) so as to be longitudinally displaceable . Ventilation device according to one of the preceding claims, characterized in that the Helmholtz resonator (3) is Ω-shaped. Ventilation device according to one of the preceding claims, characterized in that the rail guide (12) has one or two guide grooves (14) aligned parallel to one another. Ventilation device according to one of the preceding claims, characterized in that the rail guide (12) is designed in the shape of a C-profile. Helmholtz resonator (3) for a ventilation device (1) of a motor vehicle, in particular an electric vehicle, in particular for a ventilation device according to one of the preceding claims, characterized by a resonator wall (5), which is designed as a circular ring segment-shaped cylinder wall in which a plurality of resonance openings (10) are trained. Device (24) for producing a Helmholtz resonator (3), in particular according to Claim 11 , characterized by an injection mold which has two tool halves (25, 26) which can be moved relative to one another, the tool halves (25, 26) when put together to form a cavity (27) which corresponds to the shape of the Helmholtz resonator (3), one of the tool halves ( 26) has a hole device (28) which has a plurality of pins (31) which can be moved independently of one another into the cavity (27) to form resonance openings (10) in a resonator wall (5) of the Helmholtz resonator (3), the pins (31) are held in a circular segment-shaped guide wall (29), and the guide wall (29) is assigned a rotatably mounted camshaft (32) for displacing the pins (31). Device according to Claim 12 , characterized in that each pin (31) is assigned at least one spring element (38) which urges the pin (31) out of the cavity (27). Device according to Claim 12 or 13th , characterized in that the camshaft (32) has a plurality of releasably attached cams (34) for the individual actuation of the pins (31).

Images