EP2031168A2 - Buffer element - Google Patents

Abstract

The buffer element has a mounting element (1), which is fixed at a carrying or moving part and a buffer (2) is held indirectly or directly by a mounting element. The buffer is height adjustable regarding to the mounting element. The buffer has a plastic material, particularly a thermoplastic elastomer, or rubber. The buffer has a buffer body (3) turned away from the mounting element and a connecting element (4) facing to the mounting element. The connecting element is made from a hard plastic material, particularly from polyamide or polyoxymethylene.

Description

The invention relates to a buffer element for use as a stop for a movable part, in particular a front or rear hood of a motor vehicle, on a supporting part, in particular a body.

Such buffer elements are known in particular from the automotive industry. They are used there to support an engine hood damping against a body. The hood can be configured both as a front and as a rear hood, namely depending on the position of the engine in the vehicle. Furthermore, said buffer elements are used, for example, for damping support of trunk lids.

The buffer element is generally intended to prevent noise and damage caused by clashing of the abutted parts. Furthermore, such buffer elements are used to compensate for body tolerances. For this purpose, the buffer elements can be configured adjustable.

A height-adjustable buffer element is, for example, from the DE 43 40 114 A1 known. This buffer element has a depression nut made of an elastic material. This is inserted into a designated opening of a body. As a spacer and stop for a movable body part, a threaded bolt is provided. This can take two positions within the indenting nut. For this purpose, an oblique bore is provided, on the one hand, within the indentation nut, in which the threaded bolt is axially displaceable. In this position, the desired immersion depth of the threaded bolt should be set. Then, the threaded bolt can be pivoted in an extending in the axial direction of the indenting internal thread and fixed there.

However, the known buffer element is disadvantageous in several respects. On the one hand, the height adjustment of the element is made in the pivoted position of the threaded bolt. However, it is not guaranteed that the threaded back into the operating position threaded bolt holds the male body part at exactly the same height as the pivoted bolt. The height adjustment is thus error-prone.

Furthermore, the body part to be stored is directly on the threaded bolt, which is usually made of metal. This can cause rattling noises and damage.

Finally, there is a risk that the threaded bolt suddenly releases during operation, for example. During a drive, due to unforeseen force effects and falls back into the pivoted setting position. This can cause damage and serious impairment of driving.

The present invention is therefore based on the object of specifying a buffer element, in which a simple assembly and safe operation is realized with simultaneously improved function.

This object is solved with the features of claim 1. This is a buffer element for use as a stop for a movable part, in particular a front or rear hood of a motor vehicle, on a supporting part, in particular a body, with a fixable to the supporting or movable part fastener, and with a buffer, indirectly or is held directly by the fastener, wherein the buffer is height adjustable with respect to the fastener.

According to the invention, it has first been recognized that a buffer element that can be secured to a load-bearing or to a movable part allows the greatest possible versatility during assembly. One skilled in the art will generally attach the buffer member to a supporting, fixed member so as not to further increase the mass of the movable member. However, there are applications in which due to constructive constraints, the opposite solution must be realized.

In accordance with the invention, the attachment and the buffer effect of the buffer element are separated from each other. The buffer element according to the invention is fixed with a fastening element on a supporting or movable part. The buffer is spaced from the fastener, but is held directly or indirectly therefrom. As a result, on the one hand, a secure determination and on the other hand achieved an optimal buffering effect. The buffer acts where the damping property is needed, namely directly on the part for which it serves as a stop. Damage or noise due to an imprecise adjustment of the buffer element is thus effectively avoided. Furthermore, the assembly of the buffer element according to the invention is significantly simplified due to the splitting in buffer and fastener.

Finally, the buffer is height adjustable with respect to the fastener. As a result, body tolerances are particularly easy to compensate. Since the buffer forms an independent unit of the buffer element according to the invention, a particularly precise adjustability can be realized. Furthermore, the buffer can be guided in relation to the fastening element so that a "setting position" can be dispensed with. Accordingly, the buffer element according to the invention can not accidentally disengage into such a setting position during operation.

Consequently, a buffer element is specified, in which a simple assembly and safe operation is realized with simultaneously improved function.

The buffer within the buffer element according to the invention may have a cylindrical or a polygonal or polygonal side wall. A cylindrical side wall may be advantageous if an external axial guidance is provided for the buffer. Such an embodiment will be discussed in more detail below. A polygonal or polygonal sidewall is advantageous if the height adjustability of the buffer with respect to the fastener is accomplished by turning or screwing the buffer. In this case, a polygonal or polygonal side wall can provide easier engagement by hand or with a suitable tool.

An embodiment is preferred in which the buffer comprises a soft plastic material, in particular a thermoplastic elastomer, or rubber. Thus, the buffer can provide an optimal damping effect. Damage to the contacted by the buffer, moving part or the formation of rattling noises is effectively prevented.

In general, it is preferred that the buffer with respect to the fastening element is displaceable and / or screwed in and / or out and optionally locked. In such an embodiment, a height adjustability of the buffer with respect to the fastening element can be realized in a particularly simple manner. By an optional lockability of the position of the buffer with respect to the fastener further an unwanted change in the height adjustment is avoided. In addition, unintentional release of the buffer from the fastener is even less likely. This maximum safety of the buffer element according to the invention is realized especially when used in motor vehicles.

The fastening element facing the side wall of the buffer may be at least partially formed by a sleeve. The sleeve may optionally have an inner and / or outer thread. If an embodiment is realized in which the buffer engages with its side wall in the aforementioned manner in the fastener (in particular in a provided in the fastener thread), a buffer element can be provided with a particularly large power and thus increased stability. Alternatively, the side wall of the buffer may be configured without threads, so that a suitably shaped sleeve of the fastener may merely provide axial guidance of the buffer. This axial guidance can be realized both on the outside and on the inside of the sleeve of the buffer.

In a particularly preferred development of the buffer element according to the invention, the transition region between the buffer and the fastening element has one or more predetermined breaking points, after the destruction of which the buffer can be moved in the direction of the fastening element. This embodiment is particularly advantageous with regard to pedestrian protection when used in motor vehicle front hoods. The transition region can be designed so that when a pedestrian hits the bonnet a threshold value of the force acting on the buffer is exceeded. The predetermined breaking point is destroyed, so that the maximum possible way is released for the buffer to move up to the fastener with consumption of impact energy. The force acting on an injured pedestrian is thus reduced to the technically possible minimum.

In a further development of the inventive concept, the buffer has a buffer body facing away from the fastening element and a connecting element facing the fastening element. In this case, the inventive idea of separation of attachment and buffer effect is consistently developed. The buffer body can be provided with particularly advantageous damping properties. The connecting element, however, can correspond in a suitable manner to the fastening element, namely to achieve a technically particularly advantageous holding or a particularly advantageous mounting of the buffer.

For this purpose, the connecting element may be made of a hard plastic material, in particular of polyamide and / or polyoxymethylene. A fastener made of such material is particularly suitable for being suitably clamped within a fastener or held by such elements as screws, staples, etc.

The buffer body and the connecting element may be formed integrally, so in other words may consist of a contiguous part.

In particular, in the case where different materials are provided for the buffer body and the connecting element, however, it may be advantageous to make them separately and then join them together in a suitable manner. If both buffer body and connecting element made of plastic, these can, for example. Welded or glued. Additionally or alternatively, a nail, screw or rivet connection can be provided.

With regard to the aforementioned embodiments of the invention, an embodiment is preferred in which the transition region between the buffer body and the connecting element is designed as a spring element, in particular as a membrane. Such a spring element can provide a further advantageous damping effect in addition to the buffer body. The spring element can be designed so that the restoring force follows a progressive characteristic. Depending on the usual for the intended application force application, the spring element can be designed with a large or a small travel.

In an advantageous development of the buffer element according to the invention, the transition region between the buffer body and the connecting element has at least one predetermined breaking point, after the destruction of which the buffer body can be moved in the direction of the fastening element. In this case, express reference is made to the aforementioned embodiment, which offers particular advantages in terms of improved pedestrian protection.

In this context, an embodiment is preferred in which the transition region is configured such that the movement of the buffer body following the destruction of the predetermined breaking point counteracts a frictional force in the direction of the fastening element. For this purpose, the fastener may be configured so that in this case a guide is provided for a connecting element, wherein during the movement, a frictional force is exerted on the connecting element. For this purpose, the connecting element may have a slight oversize relative to such a guide. Furthermore, the guide may have a tapered cross-section, so that the opposing frictional force increases with an increasing immersion depth of the connecting element. These measures serve to limit as far as possible the negative consequences for an injured pedestrian.

If a proposed connecting element is realized for the buffer element according to the invention, this can force and / or positively engage in the fastening element for fastening and for height adjustment, wherein the position of the connecting element with respect to the fastening element is adjustable and optionally lockable.

If an embodiment is realized in which the buffer has a buffer body and a connecting element, it is proposed that the connecting element is formed as a shank. With such a shaft, a buffer body can be particularly easily spaced from the fastener. On the other hand, a shaft can be set securely and height-adjustable in a fastener.

For this purpose, the shaft may have a cylindrical outer surface and possibly an external thread. Thus, the shaft can be inserted into a suitable opening or bore in the fastening element. The shaft can then be braced by suitable means in the opening of the fastener. Alternatively or additionally, said opening may have an internal thread into which the external thread of the shaft can engage. As a result, both a secure fixing of the shaft and a particularly precise height adjustment of the entire buffer can be achieved.

In this case, an embodiment is particularly preferred, in which the shaft is formed as a sleeve, thus having an inner bore, and the inner bore optionally has an internal thread. About the inner bore of the shaft can be clamped from the inside against one or more suitable counterparts of the fastener, so that a secure fixing of the shaft is realized.

For this purpose, a pin can be provided which can be pressed or screwed into the shaft. Accordingly, this pin serves as a clamping element, which widens the shaft from the inside, whereby it is braced against the fastening element. The pin can have an external thread, which can correspond to a suitable internal thread of the bore within the shaft. The pin can be designed so that it can be pressed into the shaft despite the existing teeth. To remove the pin this can then be unscrewed using the teeth. It is preferred that the force required to push the pin into the shaft is less than the amount required to push the shaft into the fastener. This avoids that when the pin is pressed into the shaft, the height adjustment of the buffer with respect to the fastener is changed.

The pin may have a thickening in the front region, in order to expand the shaft in the area of engagement by the fastening element particularly strongly.

In a further embodiment, the fastening element has a cylindrical or a polygonal or polygonal side wall. The side wall may extend beyond the lower edge of the buffer upwards, so that the lower Area of the buffer is obscured by the side wall of the fastener. In other words, the buffer can at least partially submerge in the fastener. Thus, the fastener may substantially take the form of a sleeve that partially overlaps the buffer.

In this context, a configuration is particularly preferred in which the inner surface of the side wall of the fastening element provides an axial guidance of the buffer. In this case, the buffer is not held or anchored only in the fastener, for example. Via a connecting element, but there is an additional stabilization of the position of the buffer through the side wall of the fastener. This effectively avoids buckling of the buffer or other malfunctions.

In a further advantageous embodiment, the inner surface of the side wall exerts a frictional and / or a clamping force on the buffer. In this case, the inner surface of the side wall of the fastener is in contact with the side wall of the buffer. This can be done, for example, by the fact that the buffer has a slight oversize relative to the opening circumscribed by the side wall of the fastening element. As a result, the buffer is clamped to the side wall and can only move axially under force. Thus, in addition to the damping effect provided by the buffer or the buffer body additional damping. In a particularly advantageous manner, as described above, additionally a spring element can be used. Furthermore, it is possible that the circumscribed by the fastener opening for the buffer tapers down so that the clamping force increases depending on the depth of immersion of the buffer. Thus, a penetration of the buffer on the fastener can be avoided even if - as described above - a predetermined breaking point is provided in terms of improved pedestrian protection. Thus, the force on an injured pedestrian can be further reduced.

In a further embodiment, the side wall of the fastening element has an inner and / or an outer thread. In such a thread now the buffer - for example. By means of a suitable sleeve - rotatably engage. In this case, both the height adjustment of the buffer and the power transmission of the buffer body on the fastener via the provided thread pairing done.

In this embodiment, a particularly high power consumption of the buffer and the corresponding forwarding can be realized in the fastener. Furthermore, the thread can be locked particularly securely due to the large diameter, so that even high adjustment forces can not lead to a change in the height adjustment of the buffer.

To lock the position of the buffer with respect to the internal or external thread of the side wall, a locking ring can be provided in a particularly advantageous manner. In general, this securing ring can be designed so that a tension of the buffer can be brought about with respect to the thread of the fastening element. Thus, in addition to a particularly fine height adjustment, a secure locking of the position of the buffer can be achieved.

The locking ring may have an internal thread which engages in an external thread of a sleeve of the buffer or in an external thread of the side wall of the fastening element. For example. the sleeve of the buffer can be clamped against the thread of the side wall of the fastener by the locking ring is supported against the buffer body. Alternatively, the locking ring can engage directly in the thread of the fastener and clamp a corresponding thread of the buffer against this.

In a particularly preferred manner, optical and / or haptic markings of the locking position are provided, so that the operating personnel in connection with the operation of the locking ring at any time automatically the existing or non-existent locking the position of the buffer is displayed. As a result, operating errors and accidents during the adjustment of the buffer element according to the invention are excluded.

In a further embodiment, the fastening element has a centrally arranged clamping device for receiving the buffer or a connecting element assigned to the buffer. This may in particular be a spring plate. This tensioning device can receive the buffer or a suitable connecting element and hold it by means of a clamping force. A spring plate has the advantage that an additional spring action for the buffer provided. Furthermore, the buffer can make small lateral deflections without fear of damage to the parts.

In an advantageous development, the fastening element has on the underside a foot which can be fixed in the opening of a female part, in particular in a cutout or in a bore of a metal sheet. The receiving part may be the body of a motor vehicle. It is particularly practicable to provide the corresponding body section with a bore into which such a foot can be used. In this case, the foot can be designed so that it widens on the back of the hole and thus prevents withdrawal of the foot.

The foot may have a round or a polygonal or polygonal shape. This can in particular be made dependent on the shape of the intended opening of a receiving part.

Preferably, the foot has an undercut. The undercut can engage in a suitable hole and act as a barb.

The foot may have a collar. Such a collar represents a locally limited enlargement of the outer diameter of the foot. The foot may, for example, have a bead-like thickening for this purpose. The collar clamps on the back of the opening provided for the foot and prevents unintentional removal of the foot.

The foot may have axially divided segments. This is particularly helpful when the diameter of the foot for insertion into the intended opening is to be reduced. The segments can be compressed in a simple manner, whereby the foot is inserted into the intended bore.

In a preferred embodiment of the inventive idea, the foot has an axial passage, in particular with an internal thread, for receiving the buffer or a connecting element assigned to the buffer. In other words, the foot in this embodiment has an internal bore, which is advantageously equipped with an internal thread. This allows the Holder and the height adjustment of a buffer or a suitable connecting element in the foot done. For example. The foot may have a serrated internal thread. The connection element provided with a corresponding external thread can then be pressed into the foot and unscrewed again to the desired height for exact height adjustment. Particularly advantageous is the combination of a foot provided with an axial passage and an overlying spring plate. The buffer can be kept safe on the one hand, on the other hand, the spring plate provides an advantageous spring action and allows small lateral deflections of the buffer.

There are now various possibilities for designing and developing the teaching of the present invention in an advantageous manner. For this purpose, on the one hand to the claims subordinate to claim 1 and on the other hand to refer to the following explanation of three preferred embodiments of the invention with reference to the drawings. In conjunction with the explanation of the preferred embodiments of the invention with reference to the drawings, also generally preferred embodiments and developments of the teaching are explained.

In the drawing show

Fig. 1

a side sectional view of a first preferred embodiment of the buffer element according to the invention,

Fig. 2

a side view of the buffer element Fig. 1 .

Fig. 3

seen from obliquely below perspective view of the buffer element from the Fig. 1 and 2 .

Fig. 4

3 is a side sectional view of a second embodiment of the buffer element according to the invention which is particularly suitable for receiving high loads.

Fig. 5

a perspective view of the buffer element Fig. 4 .

Fig. 6

a side sectional view of a third embodiment of the buffer element according to the invention, and

Fig. 7

a perspective view of the buffer element Fig. 6 ,

Fig. 1 shows a side sectional view of a preferred embodiment of the buffer element according to the invention. The lower part of the buffer element is formed by a fastening element 1. This serves for installation and fixation on a supporting or moving part. Preferably, the fastener 1 is anchored to a body, so that the buffer element can provide a stop for a front or rear hood of a motor vehicle.

By the fastener 1, a buffer 2 is held. Here, the buffer 2 has a fastening body 1 facing away from the buffer body 3 and a fastener 1 facing connecting element 4. The buffer body 3 is made of a soft plastic material, namely a thermoplastic elastomer.

The connecting element 4 is designed here as a downwardly extending shaft 5. This is made of a hard plastic material. About the shaft 5, the buffer 2 is held in the fastener, with height adjustment is possible. For storage of the shaft 5, a spring plate 6 is formed in the lower region of the fastening element 1. By the spring plate 6, the shaft 5 is tensioned free of play.

Finally, a foot 7 is provided on the underside of the fastening element 1, which extends in the axial direction below the fastening element 1. The foot 7 is initially used to fix the fastener 1 and thus the entire buffer element to a supporting or moving part. For this purpose, the foot 7 can be pressed into an opening, in particular into a bore, of a receiving part. The foot 7 has axially divided segments 8. The segments 8 have in the lower region a thickening, namely a collar 9. By a conical end portion of the segments 8, these are when pressed into an opening or bore pressed together, whereby the collar 9 can pass through the opening. After passing the opening, the foot 7 widens again, whereby the collar 9 acts as a barb and prevents removal of the foot 7. The arranged between the collar 9 and the fastener 1 game of the foot 7 is formed as an undercut.

The foot 7 further has an axial passage which is provided with an internal thread. The inner end of the foot 7 can thus receive the lower, provided with an external thread end of the connecting element 4. Depending on the design of the toothing, the buffer 2 can be pushed into the foot 7 with the connecting element 4. Thereafter, it can be unscrewed to fine tune the desired height of the buffer element again from the foot 7 until the desired height is reached.

To lock the height adjustment, a pin 10 is provided, which is hineindrückbar in an inner bore of the shaft 5. Accordingly, the shaft 5 is made in this embodiment as a sleeve. The inner bore may additionally have an internal thread, which may correspond to an external thread of the pin 10. The pin 10 expands the shaft 5 in the region of the foot 7, so that the shaft 5 is clamped against the foot 7 and / or against the spring plate 6 and thus locked.

The transition region between connecting element 4 and buffer body 3 is designed here as a spring element, namely as a membrane 11. The membrane 11 provides a further spring effect in addition to the buffer body 3.

The membrane 11 further has a predetermined breaking point 12, which fails when an axial maximum load is exceeded and allows the immersion of the buffer body 3 with respect to the fastener 1. Thus, for example, in an accident with a pedestrian the maximum possible way can be released to destroy the impact energy. When immersing the buffer body 3, this is guided by the remaining connecting element 4 and acted upon by an opposing frictional force.

In addition, the fastening element 1 has a cylindrical side wall 13. This provides for the likewise cylindrically shaped buffer body 3 an axial guidance. This avoids buckling or other malfunction during normal use of the buffer.

In the case of failure of the predetermined breaking point 12, the immersion process of the buffer body 3 is additionally guided by the side wall 13. It is also possible to make the area between the outer wall of the buffer body 3 and the inner surface of the side wall 13 so that the side wall 13 exerts a frictional force on the buffer body 3. This can be achieved during normal operation, an additional damping effect and take place during an accident, an additional recording of impact energy.

Fig. 2 shows a side view of the already in Fig. 1 shown buffer element. It is particularly easy to see how the buffer body 3 is partially overlapped by the side wall 13 of the fastener 1 and axially guided. Overall, a compact design is realized. A risk of entrapment for users or operating personnel does not exist, since the buffer 2 or the buffer body 3 is shielded from the fastening element 1. Furthermore, it can be clearly seen that the foot 7 serving for attachment to a movable or supporting part is split into a plurality of axially divided segments 8. The segments 8 have a collar 9 as a barb.

Fig. 3 shows a seen from obliquely below perspective view of the buffer element from the Fig. 1 and 2 , It can be seen that the foot 7 extends into the fastening element 1 into it. Furthermore, the foot 7 is provided with an axial passage having an internal thread. This serves to determine and to adjust the height of the connecting element of the buffer.

Fig. 4 shows a side sectional view of a second preferred embodiment of the buffer element according to the invention. This embodiment is characterized by a particularly high load bearing and by the possibility of a particularly secure locking of the height adjustment of the buffer 2 with respect to the fastening element 1.

In contrast to the previously discussed embodiment here is the thread for receiving the buffer 2 from the interior of the fastener 1, namely the foot 7, has been moved to the outside. Thus, the fastening element 1 on the buffer 2 side facing a cylindrical shape. The cylindrical portion has an external thread into which the buffer 2 rotatably engages. For this purpose, the buffer 2 comprises in the lower region a sleeve 14, which has a corresponding internal thread. In the central region of the buffer 2 is still formed by a connecting element 4, which has the shape of a shaft 5. The shaft 5 and the overlying plate-like portion into which the shaft 5 merges, are made of hard plastic. As a result, both the power consumption is increased and improves the reliability of locking the height adjustment.

Above the plate-like portion of the connecting element 4, the buffer body 3 is arranged, which is made of soft plastic material. This provides a soft and gentle stop for the moving part.

The shaft 5 extends within the fastener 1 in an inner bore. This inner bore can be provided with an undersize relative to the shaft 5 in order to achieve a defined clamping force. To adjust the height of the buffer 2, the sleeve 14 is placed with its internal thread on the external thread of the side wall 13 and screwed. At the same time, the shaft 5 dips into the inner bore of the fastening element 1. Once the desired height is reached, a locking ring 15 is actuated, by means of which the position of the buffer 2 with respect to the fastening element 1 can be locked.

In this embodiment, the retaining ring 15 is supported upwards against the buffer body 3 and acts on the sleeve 14. This allows a tension of the internal thread of the sleeve 14 relative to the external thread of the side wall 13 reach. To indicate the locking position optical markers are provided (not shown). For this purpose, the locking position on the sleeve 14 is marked in color. If the position of the buffer 2 is locked, the colored mark is covered. A tapping of the locking position with a gauge with electronic release is possible.

With regard to improved pedestrian protection, the thread pairing between the side wall 13 and the sleeve 14 has predetermined breaking points. When a defined maximum load is exceeded, the thread pairing fails so that the buffer 2 can dip into the fastening element 1. In a particularly advantageous manner, the dipping process counteracts a clamping force between the shaft 5 and the fastening element 1, so that a controlled destruction to impact energy can take place.

Fig. 5 shows a perspective view of the buffer element Fig. 4 , Here it can be clearly seen that the buffer body 3 has a tool engagement on the upper side. Furthermore, markings are provided both on the upper side of the buffer body 3 and on the base plate of the fastening element 1 in order to facilitate the fine adjustment of the height of the buffer 2.

Fig. 6 shows a side sectional view of a third preferred embodiment of the buffer element according to the invention. This development broadly corresponds to the embodiment of the 4 and 5 , However, here the buffer body 3 and the connecting element 4 (shaft 5) are integrally formed. Therefore, in this embodiment, the shaft 5 is also made of soft plastic material. This reduces the tooling costs and facilitates the insertion of the shaft 5 in the fastener 1. Furthermore, the damping effect of the buffer element is further improved. On the other hand, the leadership of the shaft 5 in the fastener 1 and the locking of the buffer 2 may be difficult in comparison to the aforementioned embodiment, if necessary. The choice of each preferred embodiment (according to Fig. 4 or Fig. 6 ) depends on the boundary conditions of the installation and can therefore vary.

Fig. 7 Finally, shows a perspective view of the buffer element Fig. 6 , It is in order to avoid repetition on the comments in relation to Fig. 5 directed.

With regard to further advantageous embodiments of the buffer element according to the invention, reference is made to avoid repetition to the general part of the specification and to the appended claims.

Finally, it should be expressly understood that the above-described embodiments of the buffer element according to the invention are merely for the purpose of discussion of the claimed teaching, but do not limit these to the embodiments.

LIST OF REFERENCE NUMBERS

1

fastener

2

buffer

3

buffer body

4

connecting element

5

shaft

6

spring plate

7

foot

8th

segment

9

collar

10

pen

11

membrane

12

Breaking point

13

Side wall

14

shell

15

circlip

Claims (15)

Buffer element for use as a stop for a movable part, in particular a front or rear hood of a motor vehicle, on a supporting part, in particular a body, with a fixable on the supporting or movable part fastener (1), and with a buffer (2), which is held indirectly or directly by the fastening element (1), wherein the buffer (2) with respect to the fastening element (1) is height adjustable. Buffer element according to claim 1, characterized in that the buffer (2) has a cylindrical or a polygonal or polygonal side wall. Buffer element according to claim 1 or 2, characterized in that the buffer (2) comprises a soft plastic material, in particular a thermoplastic elastomer, or rubber. Buffer element according to one of claims 1 to 3, characterized in that the buffer (2) with respect to the fastening element (1) is displaceable and / or screwed and / or unscrewed and optionally lockable. Buffer element according to one of claims 1 to 4, characterized in that the fastening element (1) facing side wall of the buffer (2) is at least partially formed by a sleeve (14), wherein the sleeve (14) optionally an indoor and / or or has external thread. Buffer element according to one of claims 1 to 5, characterized in that the transition region between the buffer (2) and the fastening element (1) has one or more predetermined breaking points (12), after the destruction of the buffer (2) in the direction of the fastening element (1 ) is movable. Buffer element according to one of claims 1 to 6, characterized in that the buffer (2) facing away from the fastening element (1) buffer body (3) and the fastening element (1) facing connecting element (4) wherein the connecting element (4) can be made of a hard plastic material, in particular of polyamide and / or polyoxymethylene. Buffer element according to claim 7, characterized in that the buffer body (3) and the connecting element (4) are formed integrally or as separate parts. Buffer element according to claim 7 or 8, characterized in that the transition region between the buffer body (3) and the connecting element (4) as a spring element, in particular as a membrane (11), configured and optionally has a predetermined breaking point (12), after their destruction the buffer body (3) is movable in the direction of the fastening element (1), wherein the transition region can be configured so that the movement of the buffer (2) or the buffer body (3) following the destruction of the predetermined breaking point (12) in the direction of Fastening element (1) counteracts a frictional force. Buffer element according to claim 7, characterized in that the connecting element (4) non-positively and / or positively engages in the fastening element (1), wherein the position of the connecting element (4) with respect to the fastening element (1) is adjustable and optionally lockable , Buffer element according to one of claims 7 to 10, characterized in that the connecting element (4) has a shank (5), wherein the shank (5) may have a cylindrical outer surface and optionally an external thread and / or is formed as a sleeve and, if necessary ., An internal thread, wherein a pin (10) may be provided, which for pressing the shaft (5) against the fastening element (1) in the shaft (5) can be pressed or screwed and wherein the pin (10) in the front region may have a thickening. Buffer element according to one of claims 1 to 19, characterized in that the fastening element (1) has a cylindrical or a polygonal or polygonal side wall (13), wherein the inner surface of the side wall (13) can provide an axial guidance of the buffer (2) which can exert a frictional and / or a clamping force on the buffer (2) and / or wherein the side wall (13) has an inner and / or an outer thread, and wherein a securing ring (15) may be provided, by means of which the position of the buffer (2) with respect to the internal or external thread of the side wall (13) can be locked. Buffer element according to claim 12, characterized in that the securing ring (15) has an internal thread which engages in an external thread of a sleeve (14) of the buffer (2) or in an external thread of the side wall (13). Buffer element according to one of claims 1 to 13, characterized in that the fastening element (1) has a centrally arranged clamping device, in particular a spring plate (6) for receiving the buffer (2) or a buffer (2) associated with the connecting element (4) , Buffer element according to one of claims 1 to 14, characterized in that the fastening element (1) on the underside of a foot (7) which in an opening of a female part, in particular in a cutout or in a bore of a sheet, can be fixed, wherein the foot (7) may have a round or a polygonal or polygonal shape, possibly an undercut and / or a collar (9) and / or axially divided segments (8).

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