WO2018019608A1 - Grommet - Google Patents

Abstract

The invention relates to a grommet (1, 1') for leading a transmission device through an opening in a wall, which grommet comprises a guide region (3, 3') , by means of which the transmission device is guided, a fixing region (5, 5') running around the guide region (3, 3'), and a decoupling region (11, 11') arranged in the region between the guide region (3, 3') and the fixing region (5, 5'). The decoupling region (11, 11') comprises a cavity (13, 13') which is enclosed on all sides and which is filled with air or another fluid in one or more chambers.

Description

 spout

description

The present invention relates to a grommet for carrying at least one transmission device by at least one at least one, in particular of a motor vehicle, wall at least partially formed opening, comprising at least one guide region by means of which the transmission device is guided, at least one at least partially arranged circumferentially around the guide area Attachment area for at least indirect attachment of the grommet to the wall and at least one decoupling area arranged at least in regions in the area between the guide area and the attachment area.

Such spouts are well known in the art. The main task of such grommets is to achieve a fluidic seal in the area of the implementation of the transmission device, for example at a separation point between the engine compartment and the passenger compartment. In other words, so cables or cables are to be passed through the wall so that a fluidic seal between the two sides of the wall is formed.

In addition, this is of increasing importance that a sound transmission at the separation point is avoided. For this purpose, the grommets should provide an acoustic decoupling between the guided through the grommet transmission device, such as a cable or a line of a vehicle electrical system or an air conditioning line, on the one hand and the wall on the other. Thus, to be prevented by the transmission device to the spout transmitted vibrations, such as engine noise are transmitted to the wall, which could otherwise serve as a sound box. On the other hand, it should be prevented that vibrations generated in the wall are transmitted to the transmission device, which otherwise could lead to these vibrations being transmitted via the transmission device to other elements in the passenger compartment. In this way, it should be prevented that engine noises are transmitted and this task is gaining more and more importance due to the increasing requirements for reducing noise in the passenger compartment. At the same time, the grommet should realize this sound-insulating function, however, also inexpensive.

For example, WO 2006/131298 Al discloses a sealing element for sealing a strand-shaped body in a breakthrough of a wall. It is proposed that a guide of the spout, in which the strand-shaped body is guided, via an elastic element with a holding element, which serves for fastening the spout to a wall, is connected. The connection area acts as an elastomer spring and is intended to allow movement of the strand-shaped body independently of the wall.

A disadvantage of this spout, however, is that due to the desired elastic properties a massive, thick-walled design of the connecting element is necessary to simultaneously achieve a secure holding the strand-shaped body on the one hand and on the other hand an acoustic decoupling. Thus, the spout has a relatively high weight and is difficult to build due to the geometry, since in particular additional holding elements are necessary to achieve a secure connection of the spout to the wall to achieve the fluidic seal. In addition, the acoustic decoupling property of the spout is coupled to the particular geometry of the connection area. So if an acoustic decoupling in another frequency range can be achieved, a new design and redesign of the entire spout is necessary. This leads in particular to the fact that a large number of different grommets must be held in order to achieve the best possible acoustic decoupling.

Furthermore, spouts are known from the prior art, which consist of two different materials, which are connected to each other forming a cavity surrounding the guide device. However, these spouts also have the disadvantage on that an adjustment of the acoustic decoupling properties to the respective environmental conditions makes a new design and new design of the spout necessary which leads to increased manufacturing costs, in particular tooling costs.

It is therefore an object of the present invention to provide a grommet which overcomes the disadvantages known from the prior art. In particular, a grommet is to be provided, which can be easily and securely connected to the wall or be built, can be arranged tightly in the wall and at the same time easily adaptable to existing acoustic ambient conditions in order to provide the best possible acoustic decoupling.

This object is achieved in that the decoupling region comprises at least one cavity enclosed on all sides and the wall of the cavity is integrally formed.

It is particularly preferred that the transmission device comprises at least one line, at least one cable, at least one tube, at least one fluid line, at least one linkage, at least one Bowden cable and / or at least one shaft.

In the two aforementioned embodiments, it is particularly preferred that the motor vehicle is designed as at least one passenger car, at least one ship, at least one truck and / or at least one aircraft, such as an aircraft and / or a helicopter.

It is also proposed with the invention that the wall comprises at least one partition wall, in particular the partition wall adjoining at least one engine compartment, in particular for an internal combustion engine, at least one passenger compartment and / or at least one body cavity.

A grommet according to the invention can also be characterized in that the guide region guides the transfer device along at least one first axis, preferably the first axis runs parallel to at least one normal direction of at least one region of the wall and / or at least one region of an opening surface of the opening. Furthermore, the invention proposes that the guide region, the attachment region and / or the decoupling region are formed at least in regions in one piece, in particular materially bonded.

A particularly preferred embodiment of the spout provides that it is characterized by at least one at least indirectly connectable to the attachment region and / or connected holding element and / or characterized in that the holding element and / or the attachment area to, in particular force and / or positively, attachment of the spout on the wall in operative connection with the wall is or can be brought or is in operative connection with the wall or stand.

Advantageous embodiments of the invention provide that the holding element and / or the attachment region comprises at least one clip device, at least one latching device, at least one threaded device, at least one bayonet connection device, at least one riveting device and / or at least one insertion device.

In the two aforementioned embodiments, it is particularly preferred that the holding element with the attachment region form-fitting, non-positively, cohesively, by means of injection molding, in particular of the attachment portion to the holding element by means of encapsulation, in particular at least a portion of the holding member by the attachment region, by means of at least one adhesive an adhesive and / or connectable by vulcanization and / or is connected.

A grommet according to the invention may also be characterized in that the guide region, the attachment region and / or the decoupling region at least partially comprises at least one plastic material, at least one elastomer material, at least one rubber material, at least one thermoplastic material and / or at least one rubber material.

It is also proposed with the invention that the holding element at least partially has a lower elasticity compared to the attachment region, the guide region and / or the decoupling region, in particular at least partially a plastic material, at least one metallic material, at least one ceramic material and / or at least one thermosetting material. Particularly preferred embodiments of the invention provide that the guide region is mirror-symmetrical at least in regions, in particular along the first axis and / or with respect to a plane of the opening, the wall, a plane of symmetry of the attachment region and / or a plane of symmetry of the decoupling region, and / or Guide region at least partially, preferably along the first axis, a truncated cone-shaped cross-section, preferably double-frustum-shaped is formed.

The invention also proposes that the cavity surrounds the guide area completely, in particular annularly and / or radially symmetrically.

Furthermore, the invention provides that the cavity comprises at least two, preferably a plurality of chambers, preferably at least two chambers are fluidly separated from each other and / or at least two chambers are fluidly connected to each other fluidly by means of at least one throttle element.

Particularly preferred embodiments are characterized in that the cavity, in particular at least one chamber, is filled with at least one fluid, preferably the fluid at least one gas, such as air, helium and / or nitrogen, at least one liquid, such as water and / or at least one Gel comprises, wherein preferably different chambers can be filled with different fluids.

In the aforementioned embodiment, it is proposed that the cavity, at least one chamber, comprises at least one fluid supply opening, the fluid supply opening being closable by means of at least one closure element, such as a stopper, a lid, a valve, in particular a check valve and / or at least one throttle opening.

The two aforementioned embodiments can furthermore be characterized in that the pressure of the fluid in the cavity, in particular in at least one chamber, is variable, preferably the pressure of the fluid in different chambers is adjustable differently. Finally, it is proposed with the invention that the spout, in particular the decoupling region, at least partially by means of injection molding, internal pressure injection molding, blow molding and / or 2K multi-component injection is produced, in particular produced.

The invention is therefore based on the surprising finding that by forming a cavity in a decoupling region of a spout, a fluidic spring element, in particular pneumatic and / or hydraulic spring element can be realized, which on the one hand leads to a significant component weight reduction and on the other hand, the best possible adjustment of the spout the acoustic ambient conditions, in particular to achieve an improved acoustic decoupling, allows.

Due to the hollow body-like construction, an acoustic decoupling, ie a sound insulation, is achieved. At the same time, however, the fastenability of the spout on the wall is not adversely affected. Thus, the attachment area in the usual way a Einknüpf ng the spout allow in the opening of the wall.

It is also possible for a holding element to be arranged on the fastening region, for example a snap-on frame which has a higher strength than the rest of the nozzle can be injection-molded. In particular, a multi-component injection molding process, in particular 2K processes, can be used. Also, the holding element may comprise a Verschraubrahmen.

The use of such a hollow-chamber spring also makes it possible to easily adapt the damping or decoupling properties of the spout to the ambient conditions. Thus, the hollow space allows the spring properties and thus the acoustic decoupling properties to be changed substantially as desired by the corresponding adaptation of the fluid present in the cavity or the pressure of the fluid present in the cavity, without any constructional change the spout needs.

In addition, the grommet according to the invention can be produced in a simple manner, in particular significantly less expensive than spouts known from the prior art with comparable acoustic decoupling properties. Thus, the spout according to the invention can be produced by means of fluid injection or internal pressure injection molding. This manufacturing process allows a simple and cost-effective production of the cavity and at the same time allows the best possible adaptation of the structural properties of the spout, in particular the shapes of the spout in the different areas. This production method also makes it possible to achieve fully automatic production, in particular in conjunction with the 2-component multicomponent injection molding method for direct injection of the holding element, so that production efficiency can be increased while increased process reliability can be achieved.

The present invention is not limited to the use of a grommet for the passage of a cable or fluid conduit. Other transmission devices, such as linkage, the guidance of a Bowden cable or a shaft can be guided by means of the grommet according to the invention, with the best possible acoustic decoupling being achieved, in particular with mechanically movable transmission devices.

Also, the nozzle can be changed by appropriate changes in the fluid disposed in the cavity both in terms of the nature of the fluid as well as in the cavity internal pressure, so that the best possible adaptation to the type of transmission device is achieved.

Also, the use of the grommet according to the invention is not limited to that it is used in a passenger car. There are many applications in which the grommet of the invention can be used, such as in ships or aircraft.

The nozzle according to the invention is particularly preferably used in a partition which separates different functional areas from one another. In addition to a separation between an engine compartment and a passenger compartment and other partitions are adapted to receive a corresponding inventive nozzle, such as a connection of a passenger compartment to a prompt atmosphere.

In particularly preferred embodiments, the majority of the spout is integrally formed. This leads to a particularly advantageous production of the spout, since in a single manufacturing step substantially the entire spout can be produced. In particular, it is not necessary that the individual functional areas of the spout, such as the guiding area, the Decoupling area and the mounting area must be made of different materials in order to achieve the desired fluid and acoustic insulation properties. Due to the adaptability of the decoupling region according to the invention, the same materials can be used as for the guide region and the fastening region, and the desired insulating property can be adjusted by subsequently adapting the decoupling region. Even if it is necessary to provide an additional retaining element in order to achieve attachment of the spout to the wall, this is possible in a simple manner with the grommet according to the invention, since with a single further step, for example a 2K multicomponent injection molding step, a connection of the retaining element can be achieved with the rest of the spout, so that further can be used in comparison to known from the prior art grommets simpler manufacturing process.

In particular, the use of a separate retaining element has the advantage that any type of connection between the spout and the wall can be achieved, for example via a Klips-, latching or screw connection in contrast to a Einknüpfen the spout in the opening of the wall. In this way, the installation of the spout is significantly simplified and achieved a secure connection of the spout to the wall. For example, a connection of the spout by means of a bayonet connection, i. a connection in which the spout is fitted on the element and connected by rotation with the element can be achieved. The use of an additional holding element also offers the advantage that the holding element can have a significantly higher rigidity than the rest of the spout, in order to be able to provide the mounting and fastening forces necessary for the attachment without impairing the structure of the spout.

In particular, it is advantageous if the decoupling region surrounds the guide region substantially annularly, since in this way the best possible acoustic decoupling of the guide region from the fastening region can be achieved in each spatial direction. In other words, it is possible to make the spring constant of the cavity spring in each spatial direction the same. In special applications, however, it may also be desirable for these spring constants to be different in the different spatial directions. For example, the transfer device may have such a high dead weight that comes to a compression of the spout in a direction in which the gravitational force acts, and it can come to a detuning of the spring properties of the cavity spring in this spatial direction or in an opposite spatial direction. This effect can be counteracted by the fact that the cavity can have a multiplicity of chambers. This makes it possible that the spring properties of the cavity in the different spatial directions can be configured differently. Thus, different fluids or fluids with different pressures can be used in the individual chambers. In this case, the individual chambers may be formed hermetically separated from one another or may also have openings with one another, for example throttle openings, in order to further improve the damping properties. Thus, a throttle opening allows fluid to flow from one chamber to another chamber, but the velocity of this flow is restricted by the throttle opening, thus achieving damping of vibration transmitted to the hollow chamber spring. In order to be able to fill the cavity or the respective chambers with different fluids or fluids at different pressures, it is provided that the cavity or the individual chambers each have fluid supply openings. In particular, these fluid ports may include check valves such that fluid is introduced into the chamber or cavity to a predetermined pressure and then held in a chamber at that pressure.

Alternatively or additionally, it can also be provided that the cavity or the respective chamber is opened to the ambient atmosphere through a throttle opening. This enables damping of vibrations transmitted in the cavity area.

Overall, therefore, a spout is provided which has a lower dead weight, in particular if the respective cavity or the chambers are filled with air, since the decoupling region has a significantly reduced dead weight. Compared to a solid body, only a hollow body with comparatively thin walls can be used.

Further features and advantages of the invention will become apparent from the following description, are explained in the preferred embodiments of the invention with reference to schematic drawings.

Showing: Figure 1 is a cross-sectional view of a first embodiment of a spout according to the invention;

Figure 2 is a perspective view of a second embodiment

 spout according to the invention;

Figure 3 is a plan view of the spout of Figure 2 from direction A;

Figure 4 is a plan view of the spout of Figure 2 and 3 from direction B in Figure 2; and

FIG. 5 shows a cross-sectional view of the spout of FIGS. 2 to 4 from the direction C in FIG. 3.

FIG. 1 shows a cross-sectional view of a spout 1. The spout 1 serves to guide a guided along an axis X, not shown, transfer device, such as a cable or a fluid line, through an opening of a wall which is substantially perpendicular to the axis X, to lead. In other words, the normal direction of the wall is parallel to the axis X.

To accomplish this task, the nozzle 1 has a guide portion 3. The guide region 3 is formed both below a plane E and above a plane E in the form of a truncated cone shell. This makes it possible for the transmission device to be frictionally connected to the grommet 1 by expanding the elastic material of the guide region 3.

The grommet 1 also has a fastening region 5. By means of the fastening region 5, the spout 1 is attached to the wall. In the embodiment shown in Figure 1, this attachment can be achieved in particular by a holding element 7. The holding element 7 consists of a material which is less elastic compared to the guide area 3 or the fastening area 5 and allows the grommet 1 to be fastened to the wall by means of clip elements 9. For this purpose, the holding element 7 is positively and materially connected to the attachment region 5, in which the attachment region 5 was molded onto the holding element 7 during the production of the spout 1.

In the area between the attachment area 3 and the attachment area 5, a decoupling area 11 is arranged. The decoupling region 11 has in particular a in essentially the mounting area 3 annularly surrounding cavity 13. The cavity 13 is filled with a fluid, in particular air, with a predetermined pressure. In this case, the wall 13 surrounding the wall is formed integrally, so that a hermetic seal of the cavity 13 is achieved with the surrounding atmosphere.

This results in that the cavity 13 acts as a fluid spring element. Thus, an effective acoustic decoupling between the guide portion 3 and the mounting portion 5 is achieved. This ensures that vibrations introduced by the transmission device into the guide region 3 are absorbed or damped in such a way that they are not passed on to the fastening region 5 and thus do not reach the wall. Conversely, it is also achieved that existing in the wall vibrations are not forwarded to the guide portion 3 and thus the transmission device, which could otherwise lead to a transmission of this sound via the transmission device to other elements.

The grommet shown in FIG. 1 is produced in particular in an injection molding process, in particular an internal pressure injection molding process, in such a way that the guide region 3, the coupling region 13 and the fastening region 5 are integrally formed, with the exception of the retaining element 7.

Only optionally, an encapsulation of the retaining element 7 and thus a positive and cohesive connection between the retaining element 7 and the fastening region 5 is produced in this step.

In this way, a comparatively lightweight component is provided, which can be produced in comparison to known from the prior art grommets by means of a relatively simple manufacturing process and thus is inexpensive. At the same time, the grommet 1 offers improved acoustic decoupling properties compared to grommets known from the prior art and can be adapted to different environmental conditions without changing the geometry of the grommet 1. Thus, for example, by changing the pressure of the fluid within the cavity 13, a change in the spring properties of the decoupling region 11 can be achieved and so the acoustic decoupling are adapted to the prevailing under the respective operating conditions vibrations in order to avoid the best possible decoupling and resonance vibrations. FIG. 2 shows a further embodiment of a connecting sleeve Γ. Those elements of the spout, which correspond to those of the spout 1 bear the same reference numerals, but simply deleted. The spout Γ differs essentially from the spout 1 in that the guide region 3 is mirror-symmetrical to the plane E '. In addition, it can be seen in FIG. 2 that the retaining element 9 'has a total of 4 clip elements 9'. Further, the structure of the cavity 13 'of the spout 1' differs from the structure of the cavity 13 to the spout. 1

Thus, as shown by dashed lines in Figure 3, the cavity 13 'in a plurality of chambers 15' divided. For this purpose, 15 'partitions 17' are arranged between the chambers. In the embodiment of the spout Γ shown in Figure 2 to 5, the chambers 15 'are hermetically separated from each other in which the partitions 17' are closed. In the alternative embodiment shown it can be provided that at least between two chambers 15 ', a partition wall 17' is arranged, which has a throttle opening. This throttle opening allows fluid communication between the individual chambers. However, due to the size of the throttle opening, the velocity and the amount of fluid flowing in the throttle opening are limited, so that there is an attenuation of vibrations introduced into the volume of the first chamber, so that the buildup of resonance vibrations is avoided. In addition, the structure of the chambers 15 'allows the individual chambers 15' to be filled with different pressures of the fluid. Thus, the decoupling properties in the respective directions x and y can be adjusted.

FIG. 4 also shows that a chamber can be filled with fluid by means of a valve 19 or fluid can be removed from this chamber. Thus, the acoustic decoupling properties can be best adapted to the respective environmental conditions in which the type and pressure of the respective chamber existing fluid can be changed.

In particular, it can be seen in FIG. 5 that the guide region 3 'is of mirror-symmetrical design with respect to the plane E'.

The features disclosed in the specification, in the claims and in the drawings may, both individually and in any combination, be essential to the invention in its various embodiments. LIST OF REFERENCE NUMBERS

I, 1 'grommet

3.3 'management area

5.5 'mounting area

7,7 'retaining element

9,9 'clip element

 II, 11 'decoupling area

13, 13 'cavity

15 chamber

 17 'partition

19 'valve

A, B, C direction X axis

 Ε, Ε 'level

 direction

Claims

claims

1. grommet (1, 1 ') for performing at least one transmission device by at least one in at least one, in particular of a motor vehicle comprised, wall at least partially formed opening, comprising at least one

 Guide region (3, 3 ') by means of which the transmission device is guided, at least one at least partially around the guide region (3, 3') circumferentially arranged mounting portion (5, 5 ') for at least indirect attachment of the spout (1, 1') to the Wall and at least one at least partially in the area between the guide portion (3, 3 ') and the mounting portion (5, 5') arranged

 Decoupling region (11, 11 ') characterized in that

 the decoupling region (11, 11 ') comprises at least one cavity (13, 13') which is enclosed on all sides and the wall of the cavity (13, 13 ') is formed in one piece.

2. Grommet according to claim 1, characterized in that

 the transmission device comprises at least one line, at least one cable, at least one tube, at least one fluid line, at least one linkage, at least one Bowden cable, and / or at least one shaft.

3. Grommet according to claim 1 or 2, characterized in that

 the motor vehicle is designed as at least one passenger car, at least one ship, at least one truck and / or at least one aircraft, such as an aircraft and / or a helicopter.

4. Grommet according to one of the preceding claims, characterized in that

the wall comprises at least one partition, in particular the partition to at least one engine compartment, in particular for an internal combustion engine, at least one passenger compartment, and / or at least one body cavity adjoins. Grommet according to one of the preceding claims, characterized in that the guide region (3, 3 ') guides the transfer device along at least one first axis (X), preferably the first axis (X) parallel to at least one

Normal direction of at least a portion of the wall and / or at least a portion of an opening area of the opening extends.

Grommet according to one of the preceding claims, characterized in that the guide region (3, 3 '), the attachment region (5, 5') and / or the

Decoupling region (1 1, 1 1 ') at least partially in one piece, in particular cohesively, are formed.

Grommet according to one of the preceding claims, characterized by

at least one retaining element (7, 7 ') which is at least indirectly connectable and / or connected to the fastening region (5, 5') and / or characterized in that the retaining element (7, 7 ') and / or the fastening region (5, 5') ), in particular non-positive and / or positive, fastening of the spout (1, 1 ') on the wall in

Active connection with the wall can be brought or are or is in operative connection with the wall or stand.

Grommet according to one of the preceding claims, characterized in that the holding element (7, 7 ') and / or the attachment region (5, 5') at least one

Clip device, at least one locking device, at least one threaded device, at least one bayonet connection device, at least one riveting device and / or at least one Einknüpfvorrichtung.

Grommet according to claim 7 or 8, characterized in that

the holding element (7, 7 ') with the mounting portion (5, 5') positively, non-positively, cohesively, by means of injection molding, in particular of the mounting portion (5, 5 ') to the holding element (7, 7'), by means of encapsulation, in particular at least a region of the retaining element (7, 7 ') through the attachment region (5, 5'), by means of at least one adhesive agent, such as an adhesive and / or connected by vulcanization and / or is connected.

10. Grommet according to one of the preceding claims, characterized in that the guide region (3, 3 '), the attachment region (5, 5') and / or the

 Decoupling (11, 11 ') at least partially comprises at least one plastic material, at least one elastomeric material, at least one rubber material, at least one thermoplastic material and / or at least one rubber material.

1 1. Grommet according to one of claims 7 to 10, characterized in that

 the holding element (7, 7 ') in comparison to the attachment region (5, 5'), the

 Guide region (3, 3 ') and / or the decoupling region (11, 11') at least partially has a lower elasticity, in particular at least partially comprises a plastic material, at least one metallic material, at least one ceramic material and / or at least one thermosetting material.

12. Grommet according to one of the preceding claims, characterized in that

 the guide region (3, 3 ') at least in regions, in particular along the first axis (X) and / or with respect to a plane (E) of the opening, the wall, a

 Symmetrieebene of the mounting portion (5, 5 ') and / or a plane of symmetry of the decoupling region (11, 11'), is formed mirror-symmetrically and / or the

 Guide region (3, 3 ') at least partially, preferably along the first axis (X), a frusto-conical cross-section, preferably

 is formed double frustoconical.

13. Grommet according to one of the preceding claims, characterized in that

 the cavity (13, 13 ') surrounds the guide region (3, 3') completely, in particular annularly and / or radially symmetrically.

14. Grommet according to one of the preceding claims, characterized in that

 the cavity (13 ') at least two, preferably a plurality of chambers (15') comprises, wherein preferably at least two chambers (15 ') are fluidly separated from each other and / or at least two chambers (15') fluidly by means of at least one throttle element fluidly with each other are connected.

Grommet according to one of the preceding claims, characterized in that the cavity (13, 13 '), in particular at least one chamber (15'), with at least Fluid is filled, preferably the fluid at least one gas, such as air, helium and / or nitrogen, at least one liquid, such as water and / or at least one gel, wherein preferably different chambers (15 ') can be filled with different fluids.

Grommet according to claim 15, characterized in that

the cavity (13 '), at least one chamber (15'), at least one Fluidzuführöffnung (19 '), wherein the Fluidzuführöffnung by at least one closure element, such as a plug, a lid, a valve, in particular check valve is closed and / or at least includes a throttle opening.

Grommet according to one of claims 15 to 16, characterized in that

the pressure of the fluid in the cavity (13, 13 '), in particular in at least one chamber (15'), is variable, preferably the pressure of the fluid in different chambers (15 ') is adjustable differently.

Grommet according to one of the preceding claims, characterized in that the spout (1, 1 '), in particular the decoupling region (1 1, 11'), at least

can be produced in areas by means of injection molding, internal pressure injection molding, blow molding and / or 2K multi-component injection molding, in particular produced.