DE8714241U1 - Sleeve rubber spring - Google Patents

Description

Description

The invention relates to a sleeve rubber spring according to the preamble of claim II

Such a sleeve rubber spring is known from DE-OS 35 31 182 * The resulting isolation of motor-excited j high-frequency vibrations is not very satisfactory*

The invention is based on the task of further developing such a sleeve rubber spring in such a way that, while ensuring good damping of low-frequency vibrations up to a maximum of 30 Hz, improved insulation of high-frequency vibrations of at least 50 Hz is achieved.

This object is achieved according to the invention with the characterizing features of claim 1. The subclaims refer to advantageous embodiments.

In the sleeve rubber spring according to the invention, the front wall is designed to be slightly movable thanks to a membrane-like structure and is dimensioned in such a way that when vibrations with a frequency of at least 50 Hz are introduced, there is no significant change in the pressure in the chamber. The forces transferred to the foundation when corresponding vibrations are introduced are therefore balanced and the vibrations as such are not noticeable here. They therefore cannot have a detrimental effect on connected units, for example in the interior of a motor vehicle.

In contrast, vibrations of a lower frequency are accompanied by a comparatively larger amplitude of the relative displacements of the inner tube in relation to the outer tube.

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The change in the volumes of the two chambers is accordingly large and, when vibrations of a frequency of less than 30 Hz and in particular less than 20 Hz are introduced, reaches a size that can no longer be compensated for without pressure by simply moving the front wall of the chambers, avoiding a pressure build-up. The result is an alternative displacement of liquid components from the respective

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through the opening connecting both chambers. This is designed in such a way that a dispersion of energy is achieved and in particular a good damping effect. The opening can accordingly be designed as a throttle opening, but in most cases it is more appropriate as a channel in which the liquid column contained in the area of the vibrations to be damped begins to resonate.

To ensure the appropriate mobility of the front wall, the sleeve rubber spring should have a profile that is slightly curved outwards in the axial direction when it is free of vibrations and is statically loaded as intended. When high-frequency vibrations are introduced, this can easily be expanded to a semi-circular curved profile without the need for any special force. The resulting isolation of the corresponding vibrations is therefore excellent.

The outer contour of the axially displaceable part of the front wall can be designed as desired and can be circular, for example. With regard to the idea of forming the front wall as one piece with the spring body, it has proven to be expedient to choose the contour as large as possible while avoiding sharp corners and to give the front wall a kidney-shaped contour.

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In the axial direction, the sleeve rubber spring according to the invention is expediently designed as a mirror image, at least as far as the elastic rubber parts are concerned. The forces introduced during operation are thus absorbed in the same way in the area of the two front sides of the sleeve rubber spring by the elastic parts attached there, which largely excludes any distortion of the inner tube in relation to the outer tube due to operation and makes it easier to assemble the sleeve rubber spring in the opposite direction. Certain simplifications in terms of their manufacturability can also result if the elastic parts of the sleeve rubber spring are designed to be the same on both sides.

In general, the sleeve rubber spring is used in applications where a certain static preload must be absorbed. One such application is, for example, the bearing of an internal combustion engine, and in this case, end walls with a kidney-shaped outline that are as large as possible should be arranged in the area of the upper chamber. As a result of the static preload, there is a certain flattening of the profile of the end walls, which protrudes convexly outwards due to the manufacturing process. This can, however, be absorbed by the material body that forms them, avoiding internal tensile stresses in the end walls, which is a decisive advantage for the durability of the sleeve rubber spring. At the same time, it is possible to make the axially movable end wall extremely large in relation to the overall size of the sleeve rubber spring, thereby achieving satisfactory isolation of high-frequency vibrations.

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^The invention is explained in more ^detail below with reference to the attached drawing.

Figure 1 shows a sleeve rubber spring of the type according to the invention in longitudinally sectioned j unloaded state»

Figure Z shows the sleeve rubber spring according to Figure 1 in cross-sectional view along the EbcSiG A = A·

Figure 3 shows the sleeve rubber spring shown in Figure 1 in a side view.

The sleeve rubber spring shown in Figure 1 comprises the outer tube 1 and the inner tube 2, which are supported on one another by a spring body 3 made of rubber-elastic material. The spring body 3 has two chambers 4, 5 lying one behind the other in the direction of the introduced vibrations, which are connected to one another by an opening 6 and filled with liquid, for example with a mixture of glycol and water.

The upper chamber 4 is delimited in the axial direction on both sides by axially displaceable end walls 7 which are formed integrally with the spring body 3. These are designed to be easily movable due to a membrane-like construction and are dimensioned in such a way that no significant change in the pressure in the chambers h, 5 occurs when vibrations with a frequency of at least 50 Hz are introduced.

If, on the other hand, vibrations of a frequency of less than 50 Hz and in particular a frequency of less than 30 Hz are introduced into the sleeve rubber spring shown, ce .. the deformability limit of the end walls 7 is exceeded and a differential pressure arises between the chambers 4,

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This leads to the pressing through of liquid components

through the channel-like openings 6, which

is associated with a large damping effect. Rsonance-

Overloads of the motor mounted on the sleeve rubber spring

are thereby effectively suppressed.

Figure 2 shows the above-described rubber sleeve spring in cross-section. It can be seen that the opening 6 connecting the two chambers 4, 5 is designed like a channel. The cross-section is dimensioned such that the liquid column contained therein begins to resonate when vibrations of a frequency of 5 to 20 Hz are introduced. This results in a good damping effect in relation to the introduction of corresponding vibrations.

Figure 3 shows the sleeve rubber spring described above in a side view. It can be seen that the front wall 7 is arranged with a substantially kidney-shaped outline and a substantially concentric arrangement in the intermediate zone between the outer tube 1 and the inner tube 2. The area enclosed by the outline is correspondingly large and eliminates the need for reinforcing inserts in the front wall. This can be produced in one piece with the spring body 3 and accordingly in a particularly economical manner.

Claims (3)

Dr. H. Weissenfeld-Richters ·':"":' iii "'·"'·'·' Höhnerweg2-4 Patent Attorney " 6940 Weinheim/Bergstraße Telephone (0 6201) 80-8618 Telex 465 531-14 Fax (06201) 69300 9.10.1987 (WWII M 438a/Deu. Applicant: Carl Freudenberq, 6940 Weinheim Sleeve rubber spring requirements 1. Sleeve rubber spring for mounting an internal combustion engine, comprising an outer and an inner tube which are supported on one ^another by a spring body made of rubber-elastic material, the spring body containing two chambers lying one behind the other in the direction of the introduced vibrations, which chambers are connected by an opening and filled with liquid, and at least one of the chambers is delimited in at least one partial area of its axial boundary by an axially displaceable end wall formed integrally with the spring body, characterized in that the end wall (7) is designed to be easily movable by a membrane-like construction and is dimensioned such that when vibrations of a frequency of at least 50 Hz are introduced, there is no appreciable change in the pressure in the chamber (4, 5). 2. Sleeve rubber spring according to claim 1, characterized in that the end wall (7) has a slightly curved profile on the outside in the vibration-free and statically loaded state. I Il<« Il lit I i «It alt « * does &igr; &bull; · <·< I IHl J 3. Sleeve rubber spring according to claim 1 to 2, characterized in that the end wall (7) has a kidney-shaped outline. »tu * 4Mf « 1 I &bull; t ti i I