DE2947018C2 - Elastic bearing, in particular for mounting an internal combustion engine in a motor vehicle - Google Patents

Description

The invention relates to an elastic bearing, in particular for mounting an internal combustion engine in one Motor vehicle, of the type specified in the preamble of the main claim.

There is a problem with the storage of internal combustion engines in motor vehicles in particular in that the vibrations excited by the internal combustion engine for reasons of internal noise only little should be transferred to the vehicle structure. Conventional rubber / metal bearings or else with liquid and / or gas-filled bearings are only able to do this to a limited extent, since the movement of the Internal combustion engine is transmitted relative to the vehicle structure via the bearing directly and to Changes in the transmitted forces at least according to the static elasticity of the bearing leads.

CA-PS 7 81817 is a generic one Known camp in which an object to be stored rests on a resilient hollow ball, which is filled with liquid is and is connected to a cylinder in which a bulk piston works. the The hollow sphere is deformed with every movement of the object, so that the piston is deflected and forms a damper mass

A peculiarity of the known bearing is that the coupling between the movement of the bearing Object and the piston for each direction of movement of the object is different so that the

ίο resonance frequency of the system necessary for the suppression the transmission of forces or vibrations is essential, is undefined. Furthermore, the movement of the Piston connected with static friction in relation to the cylinder, whereby the response of the system suffers.

Another peculiarity of the system is that vibrations transverse to the longitudinal direction of the cylinder, which carries out the foundation, affect the functionality, since such vibrations affect the piston are impressed and push this in increasing contact with the cylinder wall.

The invention is based on the object of providing an elastic bearing in the preamble of the main claim to create specified genus, with which the transmission of disruptive excitation frequencies

•> 5 reduce the abutment in a well-defined way leaves.

This object is achieved with the characterizing features according to the main claim.

Durci; the inventive attachment of the damper mass on an elastic element it is first achieved that the vibrations of the entire system, For example, the vehicle body, do not affect the functionality of the absorber mass. Because that is assigned to the absorber mass

! 5 elastic element, for example a membrane the space filled with liquid and / or gas is adjacent, which the transmission of motion between the spring element assigned to the bearing core and the absorber mass, the absorber mass is only from

4 «such vibrations of the bearing core or the one attached to it attached object, such as an internal combustion engine, stimulated, which leads to pressure fluctuations in lead to the space filled with liquid and / or gas. The camp can be matched in this way be that with a defined natural frequency it only responds to those engine vibrations that need to be suppressed is intended. For example, in the case of a piston internal combustion engine, this can be done in the direction of movement of the piston as a result of the inertia forces acting vibrations. On movements across the direction of vibration the piston or the torsional vibrations of the internal combustion engine do not speak to the damper mass at. In summary, it is possible with the bearing according to the invention to use a very specific eigenfrequency of a mass, freely oscillating body, which in itself has several natural oscillation forms with different frequencies. This is possible because only one in a direction taking place movement of the body displaces liquid and / or gas volume, which in Movements taking place in another direction are not associated with any displacement.

The dependent claims 2 to 8 characterize advantageous developments of the bearing according to the invention.

ο5 With the features according to claim 2 can be Influence the transmission behavior between the spring element and the damper mass and different operating conditions adjust.

With the features according to claim 3, damping, in particular, of low-frequency vibrations is achieved or achieved by vibrations with a very large amplitude, such as those caused by the vehicle-side excitation appear.

Claim 4 characterizes an embodiment of the bearing, the transmission of which is theoretically possible above a resonance frequency. ^r zero decreases and then increases again slightly with increasing frequencies.

With the features according to claim 5 ka: .n the transmission behavior of the bearing according to claim 4 be adapted in an advantageous manner to the respective operating conditions.

Claims 6 to 8 characterize a simple execution shape of the bearing according to claim 5. The Pressure in the container can for example correspond to the oil pressure of the internal combustion engine, which is with the speed changes, according to a mechanical signal derived from centrifugal force, etc. changed will. Overall, the minimum transmission of the bearing to the respective speed of the internal combustion engine adjust. The force to change the pressure in the container can also be applied to one with the Inside the container connected line adjacent electromagnets can be changed with a speed-dependent current is applied. This is particularly easy with the embodiment of the bearing according to claim 8 possible, in which the effective size of the movable wall forming the damper spring increasing pressure in the container due to increasing contact between the movable wall and the contact surfaces decreases, whereby the spring constant increases and the resonance frequency and thus also the frequency minimal transmission to higher frequencies.

Regarding the state of the art, reference should also be made to the following publications:

DE-OS 18 00 376 the teaching can be removed with regard to the subject matter of the invention, a To connect vibration-stimulating internal combustion engine elastically with an intermediate mass, which in turn is elastically connected to a foundation.

The US-PS 28 19 775 teaches the feature, the resonance frequency of a hydraulically operating To change the vibration damper by changing the hydraulic pressure.

The US-PS 29 19 883 finally shows a hydraulic Vibration damper with throttle openings.

The bearing according to the invention eigtiet for use in all applications in which the Bearing targeted the transmission of vibrations of certain frequency ranges (see F i g. 2 and F i g. 5) should suppress, for example for the storage of electric motors, pumps, etc.

The invention is illustrated in the following with the aid of a schematic Drawings for example and explained with further details. It shows

F i g. 1 a bearing which contains a damper mass arranged between two springs.

Fig. 2 shows the transfer function of the bearing according to Fig. 1.

3 shows a hydraulic / pneumatic bearing based on the principle of the bearing of FIG.

4 shows a bearing with two springs and a damper mass with an additional damper spring,

Fig. 5 shows the transfer function of the bearing according to

P i σ Λ

ι ο

6 a rubber / metal bearing based on the principle of Fi g. 4 with hydraulic / pneumatic damper mass,

F i g. 7 shows an embodiment of the bearing, which properties of the bearing, which properties of the 3 with those of the bearing according to FIG F i g. 6 united and

8 shows a further development of the bearing according to FIG. 7 with additional cushioning.

According to FIG. 1, a first helical spring 5 and 5 is between a bearing core 1 and a damper mass 3 A second helical spring 9 is provided between the damper mass 3 and an abutment 7.

F i g. 2 shows the power transmission characteristics of the bearing according to FIG. 1. This is on the ordinate The relationship between the force acting on the abutment 7 and the deflection of the bearing core is plotted. the The abscissa indicates the frequency. The dashed line shows the static case for frequency zero. Here are the two forces are equal, d. H. the ratio is 1. The diagram shows that the power transmission reached a maximum at the natural frequency ωο and from frequencies above y'2 · ωο is smaller than that static power transmission. When using such a bearing for mounting an internal combustion engine In motor vehicles, the structure-borne noise transmission from the internal combustion engine into the body is for Frequencies greater than j / 2 · ωο reduced.

The system of the camp according to FIG. 1 was previously viewed only in the direction perpendicular to FIG. 1. Of course the system has natural oscillations also in the horizontal direction, the resonance frequency of which depends on the one shown in FIG. 2 differs.

A clear behavior, i. H. a single resonance excitation frequency, is achieved with the camp of FIG. Here the bearing core 1 is via a membrane 11 with a cylindrical metal body 13 connected, which is supported on the abutment 7 via an annular flange 15. Another membrane 17 connects the metal body 13 to the damper mass 3.

When the membrane 11 is flexible, is about the When the core 1 is deflected, the membrane 11 does not transmit any force directly to the metal body 13. If the diaphragm 17 has a certain amount of shear drag, it takes on the function of the second helical spring 9 of the bearing according to FIG. 1. The function of the first helical spring 5 is controlled by the content of the system Space 19 (liquid or gas) and volume stiffness of the membranes 11 and 17 taken so that the Function of the bearing of FIG. 3 corresponds to that of the bearing of FIG. 1 with the exception that one Transfer of motion from the bearing core 1 to the damper mass 3 only when the bearing core 1 is deflected in the vertical according to FIG. 3 takes place.

The pressure in space 19 can be changed via a connection, not shown, whereby the Spring constant and thus the transmission behavior of the bearing is changed.

If the membranes H, 16 do not have the stiffnesses mentioned, but, for example, both as Rubber or steel diaphragms are formed, the transmission behavior of the bearing changes somewhat because then no longer the exact equivalent circuit of FIG. 1 ■? U meets.F i g. 4 shows a modified embodiment of the bearing according to FIG. 1. Here the damper mass 3 is not directly between the two coil springs 5 and 9, but is via a damper spring 21 at the connection point between the two coil springs 5 and 9 supported.

F i g. 5 shows the transmission behavior of the bearing according to FIG. 4. As can be seen from this, the Power transmission at a damper frequency ωι zero above the resonance frequency ωο. d. H. it will no vibrations of this frequency are transmitted from the bearing core 1 to the abutment 7.

F i g. 6 shows one according to the principle of FIG. 4 working embodiment of a warehouse:

The bearing core 1 is supported on the abutment 7 via conical rubber elements 23 and 25. Between the Rubber elements 23 and 25 is a cup-shaped carrier

26 vulcanized in, which carries a membrane 27, preferably made of rubber, on which in turn a Container 29 is attached to a ground 31 with a mass. The container 29 has a connection 33 provided, through which liquid or gas can be introduced. The upper edge of the container 29 has furthermore a conical contact surface 35, against which the membrane 27 rises when the pressure in the Container 29 is increasingly applying.

With regard to the function of the bearing according to FIG. 4, the rubber elements 23 and 25 correspond to the Coil springs 5 and 9. The membrane 27 corresponds to the damper spring 21 and the mass of the container 29 including the liquid or the gas filling Γ corresponds to the damper mass 3.

The function of the bearing according to FIG. 6 is the following:
When the bearing core 1 is compressed, the movement is transferred via the rubber elements 23 and 25 to the carrier 26 and thereby via the membrane serving as a damper spring

27 transferred to the container 29 serving as a damper mass. By applying more or less Pressure via the connection 33 to the interior of the container 29, the membrane 23 receives a bias, which determines the extent to which the membrane 27 rests against the contact surface 35. The further the Membrane 27 rests against the contact surface 35, the less it is available for the suspension standing surface, d. H. the greater the spring rate

'> te. Since the damper frequency ωι according to F i g. 5 depends on the spring constant, this change in pressure in the container 29 allows the damper frequency to be adapted to the most disruptive, speed-dependent engine excitation frequencies. The spring constant of the

ι «damper spring can also be influenced by the fact that the container 29 or a damper mass with the carrier 26 via a magnetic core and a spring is connected, which magnetic core is located in a coil also connected to the carrier, which is supplied with a variable current.

F i g. 7 shows an embodiment of a bearing, the features of the bearing according to FIG. 3 with those of the Bearing according to FIG. 6. The carrier 26 'is here connected to the membrane 17 of the bearing according to FIG.

2 »The bearing according to FIG. 8 forms the bearing according to 7 further to the effect that the cylindrical metal body 13 'is here by a further metal body 37 is surrounded, which is supported on the abutment 7. In the wall of the metal body 13 'is a throttle opening

- '■ "' opening 39 formed, which in a between the Metal body 37 and the metal body 13 'formed annular space 41 leads, the top of a elastic membrane 43 is closed. With these additional features it is achieved that when

Jf compression of the bearing core 9, especially if this Compression occurs with a low frequency and a large amplitude. Fluid through throttle orifice 39 flows through it, whereby kinetic energy is destroyed and the movement of the bearing core 1 is damped.

For this purpose 3 sheets of drawings

Claims (8)

1 claims: 1. Elastic bearing, in particular for mounting an internal combustion engine in a motor vehicle, with a bearing core, an abutment and one arranged between the bearing core and the abutment Spring element, which is adjacent to a space filled with liquid and / or gas, which is a » Movement transmission between the spring element and a damper mass forms, thereby characterized in that the damper mass (3) attached to an elastic element (membrane 17) is, which is adjacent to the liquid and / or gas-filled space (19). 2. Bearing according to claim 1, characterized in that the pressure of the liquid and / or gas filled space (19) is changeable. 3. Warehouse according to claim! or 2, characterized in that the liquid and / or Gas-filled space (19) has a wall formed with a throttle opening (39) which adjoins another space bounded at least partially by an elastic wall (membrane 43) (41) is adjacent (Fig. 8). 4. Bearing according to one of claims 1 to 3, characterized in that the damper mass (3; 29) is connected to the spring element (5,9; 23,25; 11,17,19) via a Tiiger spring (21; 27). 5. Bearing according to claim 4, characterized in that the weight of the damper mass (container 29) and / or the spring constant of the damper spring (membrane 27) can be changed. 6. Bearing according to claim 5, characterized in that the damper mass with a liquid and / or gas-filled container (29) which is surrounded by a movable wall (membrane 27) is completed, to which a core (26; 26 ') connected to the spring element (23, 25; 17) is attached. 7. Bearing according to claim 6, characterized in that the pressure in the container (29) is variable. 8. Bearing according to claim 7, characterized in that a contact surface (35) is provided to which the movable wall (membrane 27) increases with increasing pressure in the container (29) applies.