EP1691017A2 - Buffer for a vehicle-door or -lid - Google Patents

Abstract

The stop absorber has a flexible spring element (1) bordering in its deflecting direction along with a convergent additional damping section (2) with at least two chambers (4,5) filled with a fluid, which consists of an nozzle plate (6) arranged between the chambers whereby the nozzle plate projects through the chambers having a connecting channel (7). Through the connecting channel, the fluid is pushed from one chamber to another chamber during deflecting of the elastomeric spring element under formation of compression force adding to the restoring force of the spring element.

Description

The invention relates to a stop buffer with an elastomeric spring, for damping the forces occurring when striking a door or flap on fixed body parts of a motor vehicle.

In order to avoid noise or damage to the metallic body parts or the paint means of impact damping are provided in the area of the doors and flaps, in particular the hood and the tailgate of motor vehicles. In most cases, the striking of closing doors or flaps is damped at the respective opening frame by a plurality of distributed on the circumference of the frame arranged stop buffer of an elastomeric material. Corresponding, often mushroom-shaped stop bumpers are used in particular in the range of hoods and tailgates, which are closed by the action of their own weight by dropping with drop locks. The bumpers act as Endbegrenzer for the respective fall path of the flap, whereby they intercept the acceleration forces caused by the falling flap.

A problem to be solved in the use of such bump stop is to choose the installation height so that the respective door or flap is clamped in the closed state rattling on the body and on the other hand result in the smallest possible gap dimensions. The formation of a corresponding stop buffer is described for example in DE 199 29 953 A1. However, said document does not deal with mechanical aspects of the formation of corresponding stop buffers, but with the problem of preventing the deposition of paint on already mounted on the body buffer in the vehicle paint. Furthermore, DE 100 35 201 A1 describes a stop buffer that is adjustable with respect to its height relative to the body frame. By the solution shown tolerances in the production of flaps or doors can be compensated with regard to the gap. With regard to the damping effect on a motor hood, which has been dropped for the purpose of closing, however, it is disadvantageous in the abovementioned solutions of the prior art that the spring characteristic of the buffer remains constant independently of the impact speed of the flap, so that the spring action is independent of the respective one Fall height of the flap is. However, it would be desirable to reduce to the body parts acting on top forces, such as occur in an accidental and careless dropping of a flap from high altitude, by increasing the spring characteristic with increasing impact velocity and at the same time, in view of small gaps, the compression depth of the Flap or door in the stop buffer to limit.

The object of the invention is therefore to provide a stop buffer whose spring action adapts within predeterminable limits to an increasing impact speed of a closing door or flap and by which even high impact forces are effectively damped. Of the Buffer should help to achieve the smallest possible gap.

The object is achieved by a bump stop with the features of the main claim. Advantageous embodiments or further developments of the solution according to the invention are given by the subclaims. For damping the forces occurring when striking a door or flap on fixed body parts of a motor vehicle is, in a conventional manner, at least one designed according to the invention stop buffer, which has an elastomeric spring element, on the door or flap and / or on one of these opposite stationary vehicle part arranged. Preferably, a plurality of these stop buffers are arranged on the inner circumference of an opening frame, on which the pivotable door or flap is articulated.

Deviating from the solutions of the prior art, the stop buffer according to the invention has an additional damping section adjacent to and cooperating with the elastic spring element in its compression direction. This consists of at least two, filled with a fluid chambers and a nozzle plate arranged between them with at least one nozzle plate and connecting the channels connecting channel through which the fluid at a compression of the elastomeric spring element to build up to the restoring force of the spring element adding pressure of one chamber is displaced into another.

According to a possible embodiment of the invention, with respect to its longitudinal axis formed axially symmetrical stop buffer of an elastomeric spring, an inner core projecting into this, with a stop surface for the flap or door and the inner core with him partially surrounding elastomeric spring receiving upper receiving body, which together form a support body. The support body is assembled or integrally connected to a, the nozzle plate and a compensating bellows receiving lower receiving body. Above and below the nozzle plate chambers for receiving a viscous liquid are formed, which are interconnected by the channel in the nozzle plate. As a viscous liquid is used according to a preferred embodiment of the invention, ethylene glycol. The abutment surface of the inner core is preferably made of rubber or a thermoplastic elastomer.

In a particularly advantageous embodiment of the invention, the inner core of the buffer, in terms of the degree with which it protrudes into the elastomeric spring, formed height adjustable. This makes it possible to compensate for tolerances of the body parts or optimally adjust the gap between the door or flap and the fixed body parts. According to a practical embodiment, the height adjustability of the stop buffer is thereby realized that its inner core is formed as a screw whose head consists of an elastomeric material or is covered or enclosed by such. The height is adjusted by screwing in or out of the protruding into the elastomeric spring element screw.

According to one, in view of a long service life of the stop buffer to be regarded as advantageous embodiment of the invention, means for atomizing the entering during compression of the elastomeric spring through the nozzle under pressure into the lower chamber viscous liquid are arranged above the Ausgleichsbalgs. As a result, the compensating bellows is protected from premature destruction by the liquid entering under high pressure in the lower chamber. For atomizing the viscous liquid, for example, a Baffle plate may be provided in the lower chamber or in the region of the inner wall of this limiting Ausgleichsbalgs, which is optionally formed integrally with the nozzle plate.

The nozzle formed by the channel of the nozzle plate preferably has a hole-shaped cross-section, but may also have other cross-sectional shapes. Depending on the intended installation location differently arranged and designed fastening means are provided on the stop buffer, which are preferably arranged on its outer periphery. For example, mounting holes with holes for mounting on a body part are arranged on the outer circumference of the stop buffer according to the invention.

Fig. 1:

Eine Ausführungsform des Anschlagpuffers in einer axial geschnittenen Darstellung

Fig. 2:

Die Ausführungsform nach Fig. 1, ebenfalls im Längsschnitt, in einer um 90° gedrehten Ansicht

Fig. 3

Eine andere Ausführungsform des Anschlagpuffers im Längsschnitt

Fig. 4:

Die Ausführungsform nach der Fig. 3 in isometrischer Darstellung

Details of the invention will be explained in more detail below with reference to exemplary embodiments. In detail show:

Fig. 1:

An embodiment of the stop buffer in an axially sectioned illustration

Fig. 2:

The embodiment of FIG. 1, also in longitudinal section, in a rotated by 90 ° view

Fig. 3

Another embodiment of the stop buffer in longitudinal section

4:

The embodiment of FIG. 3 in isometric view

The stop buffer according to the invention for flaps or doors of a motor vehicle is, as already shown, preferably arranged with further stop buffers of the same or similar design on the door or flap or on a stationary vehicle part. A possible embodiment of the stop buffer is shown in Fig. 1 in an axially sectioned illustration. For the following representations, in particular with regard to based on information such as "top" or "upper" and "lower" or "lower", assumes that the bump stop is intended, for example, as part of a stop damping for an engine hood, based on its longitudinal axis z, in a vertical orientation on fixed parts of the vehicle body, preferably in the opening frame of the hood, mounted.

An upper part of the stop buffer consists of an inner core 3, an elastomeric spring 1 and the upper part 9 of a receiving body 9, 10. The inner core 3 and the upper part 9 of the receiving body 9, 10 are made of metal or a plastic, wherein the inner core preferably rubber on its upper side or covered with rubber. The inner core 3 protrudes into the elastomeric spring 1 and is surrounded by this, except for its upper part with a stop surface 8 formed thereon, for the most part. Both, so inner core 3 and rubber spring 1, are taken up by the upper part 9 of the receiving body 9, 10 of the stop buffer and form together with him a support body. The support body is connected to a lower part 10 of the receiving body 9, 10, which receives as essential elements a compensating bellows 11 and a nozzle plate 6. In the illustrated example, the lower part 10 of the receiving body 9, 10, which consists for example of metal, connected to the upper by turning over its edge. But the receiving body 9, 10 forming parts may also consist of plastic, which are connected by a suitable joining process. Between the elastomeric spring 1 and the nozzle plate 6, a first filled with a viscous fluid chamber 4 is formed. A further chamber 5 is located below the nozzle plate 6, above the compensating bellows 11, in the lower part 10 of the receiving body 9, 10. Both chambers 4, 5 are connected to each other in a flow-conducting manner by a short channel 7 guided through the nozzle plate 6.

When appropriate use of the stop buffer strikes the stop surface 8 of its inner core 3, a portion of the already mentioned, dropped for closing the bonnet. By generating a restoring force, the elastomeric spring 1 of the buffer, into which the inner core 3 protrudes, thereby springs. This reduces the chamber volume of the upper, formed below the elastomeric spring 1 chamber 4. In the present in the chamber 4 viscous fluid builds up due to the reduction in volume of the chamber 4, a pressure from which an adding to the restoring force of the elastomeric spring 1 force results. At the same time parts of the liquid are displaced from the upper chamber 4 with gradual reduction of the built-up pressure and flow into the lower chamber 5 via the channel 7 of small cross-section arranged in the nozzle plate 6. To protect the compensating bellows 11 against destruction of the viscous liquid entering the lower chamber 5 due to the small channel cross-section, a type of baffle plate 12 is arranged above the compensating bellows 11, through which the liquid is atomized.

The channel 7, or the nozzle 7 formed by it, is preferably formed with a lochkreisförmigen cross-section, but may also have other cross-sectional shapes, such as a square or a cone ring gap. It can be seen that the stop buffer can be set via the volumetric compliance of the elastomeric spring 1 or the carrier body and the size of the channel cross section in the nozzle plate 6 in such a way that optimum damping of the impact energy is achieved in an intended (falling) speed range. By the Hydroteil 2 of the buffer, with the chambers 4, 5 and the nozzle 7, whose spring characteristic is raised with increasing impact speed. The kinetic energy of a random flap or door is thereby caused by the channel 7 of the nozzle plate 6 Throttling almost completely converted into energy loss. On the flap or door and the body acting peak forces are effectively reduced and limits the compression travel of the flap or door. This not least has a positive effect on the design possibilities of the bodywork, since this allows the gap between the body parts can be further reduced. After reaching the maximum spring travel, the elastomeric spring 1 of the support body partially springs back in response to the static load caused by the flap or door. As a result, a negative pressure builds up in the upper chamber 4 of the stop buffer, as a result of which the viscous fluid partially flows back from the lower chamber 5 back into the upper chamber 4, wherein the system, with regard to the closed flap or door, assumes a final state , Accordingly, opening the door or flap leads to a complete rebound of the stop buffer.

2, the embodiment of FIG. 1 is shown again in a rotated by 90 ° view. As can be clearly seen here, form the nozzle plate 6 and arranged in the lower chamber 5 on the upper side of the compensating bellows 11 baffle plate 12 a unit. In addition, in the illustration on the outer circumference of the receiving body 9 of the stop buffer provided lateral mounting ears 13, 13 'are arranged therein with holes 14, 14' recognizable, by means of which the stop buffer is preferably to be attached to the edge of a door frame or an opening frame of a flap.

Another possible embodiment of the stop buffer is also shown in Fig. 3 in axial section. In this embodiment, the inner core 3 of the stop buffer is formed by a screw whose head is covered with a rubber layer or a thermoplastic elastomer. By Turning or unscrewing the screw 3 in or out of the elastomeric spring 1, it is possible to compensate for tolerances of the body parts in terms of a uniform gap as possible. The embodiment according to FIG. 3, in which mounting tubes 13, 13 'are likewise formed on the support body of the stop buffer, is shown once more in FIG. 4 in an isometric view. Both the parts of the receiving body 9, 10 and the inner core 3 of the stop buffer according to the invention may be made of metal or plastic.

LIST OF REFERENCE NUMBERS

1

elastomeric spring element or elastomeric spring

2

additional damping section (Hydroteil)

3

inner core

4

chamber

5

chamber

6

nozzle plate

7

Channel or nozzle

8th

stop surface

9

upper receiving body or upper part receiving body

10

lower receiving body or lower part receiving body

11

compensating bellows

12

flapper

13.13 '

mounting ears

14, 14 '

drilling

Claims (12)

Bump stop with an elastomeric spring element (1), which is to be attached to the dampening of occurring when hitting a door or flap on fixed body parts of a motor vehicle forces on the door or flap and / or on one of these fixed to stationary vehicle part, characterized in that the stop buffer a, on the elastic spring element (1) in its compression direction adjacent and cooperating with it additional damping portion (2), which consists of at least two, filled with a fluid chambers (4, 5) and a nozzle plate arranged between them (6) with at least a channel (7) penetrating through the nozzle plate and connecting the chambers (4, 5), via which the fluid upon compression of the elastomeric spring element (1) under construction of a compressive force which adds to the restoring force of the spring element (1), resulting from the pressure build-up due to a volume reduction of a chamber (4) results, is displaced from one chamber to another. Bump stop according to claim 1, characterized in that with respect to a longitudinal axis (z) axially symmetrical stop buffer of an elastomeric spring (1), an inner core projecting into this (3), with a stop surface (8) and the inner core (3) with the it partially surrounding elastomeric spring (1) receiving the upper receiving body (9), which together form a support body which is assembled or integrally connected to a, the nozzle plate (6) and a compensating bellows (11) receiving lower receiving body (10) above and below the nozzle plate (6), the chambers (4, 5) formed for receiving a viscous liquid and connected by the acting as a nozzle channel (7) in the nozzle plate (6) are interconnected. An impact buffer according to claim 2, characterized in that the viscous liquid is ethylene glycol. Bump stop according to claim 2 or 3, characterized in that the stop surface (8) of the inner core (3) consists of rubber or a thermoplastic elastomer. Bump stop according to claim 2 or 4, characterized in that the inner core (3) with respect to the extent with which it protrudes into the elastomeric spring (1) to compensate for tolerances of the body parts and for adjusting the gap between the door or flap and the fixed body parts, is height adjustable. Bump stop according to claim 5, characterized in that the inner core (3) is designed as a screw, the head of a elastomeric material is made or covered by such a material. An abutment buffer according to any one of claims 2 to 5, characterized in that above the compensating bellows (11) means (12) for atomizing the during compression of the elastomeric spring (1) through the nozzle (7) under pressure in the lower chamber (5) entering viscous liquid are arranged. An impact buffer according to claim 7, characterized in that a baffle plate (12) is provided for atomising the viscous liquid entering the lower chamber (5) via the nozzle (7). Bump stop according to claim 7 or 8, characterized in that the means (12) for atomizing the entering into the lower chamber viscous liquid are formed integrally with the nozzle plate (6). Bump stop according to one of claims 1 to 9, characterized in that on the outer periphery of the stop buffer means (13, 13 ', 14, 14') are arranged for attachment of the stop buffer on a body part. Bump stop according to claim 10, characterized in that the fastening means are mounting holes (13, 13 ') provided with bores (14, 14'). An abutment buffer according to one of claims 1 to 10, characterized in that the nozzle formed by the channel (7) of the nozzle plate (6) has a hole-shaped circular cross-section.

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