DE2947018A1 - Vibration damping flexible engine mounting assembly - includes pressurised chamber between membrane mounting points - Google Patents

Abstract

A flexible car engine mounting includes an anchor face (1) to which the engine is attached. The anchor (1) is mounted on a flexible membrane (11) which is attached to a fixing frame (13,15), on the car chassis (7). A second membrane (17) on the opposite side of the frame (13), locates a damper mass (3) at its centre. The space between the two flexible membranes (11,17) is pressurised by hydraulic or pneumatic means (19), in order to transmit some of the vibrations between the membranes.

Description

Elastic bearing, especially for the storage of a fire

engine in a motor vehicle The invention relates to an elastic Bearings, in particular for mounting an internal combustion engine in a motor vehicle, according to the preamble of claim 1.

A problem that arises in the storage of internal combustion engines in particular in motor vehicles is that the stimulated by the internal combustion engine Vibrations for reasons of interior noise have little effect on the vehicle structure should be transferred. Conventional rubber-metal bearings or with liquid and / or gas-filled bearings are only able to do this to a limited extent because of movement the internal combustion engine is transmitted directly relative to the vehicle structure via the bearing and to changes in the transmitted forces, at least in accordance with the static ones Elasticity of the bearing leads.

The invention is based on the object of providing an elastic bearing create that at higher excitation frequencies of the bearing core, for example when excited by an internal combustion engine mounted in a motor vehicle body, these suggestions are only slightly transferred to the abutment, this transfer property is retained even in long-term operation.

This object is achieved with the features of claim 1.

The absorber mass provided according to the invention is set in the event of vibrations of the bearing core against the abutment is also excited to vibrate. the Power transmission from the bearing core to the abutment is then no longer solely from the Vibration amplitude of the bearing core and the spring constant of the spring element dependent, but rather strongly depends on the frequency. For lower frequencies there is a transmission behavior, which largely corresponds to that without the absorber mass. With increasing frequencies it increases the power transmission up to the natural frequency of the damper mass also increases, then increases but constantly from, so that a power transmission is achieved at sufficiently high frequencies which is below the value determined by the static spring constant.

When using the bearing according to the invention for storing a Internal combustion engine in a motor vehicle body are the spring constants and the size of the Tilaermasse chosen so that the natural frequency, ei of the power transmission is amplified from the day core to the abutment, in a frequency range less Suggestion lies. The higher lying, interfering motor excitation frequencies are then hardly transferred to the body.

The transmission of movement between the spring element and the damper mass can take place in different ways, for example directly mechanically, electromagnetically etc.

With the features of claim 2, in which the transmission of motion takes place hydraulically and / or pneumatically, it is achieved that the damper mass with the spring element or the bearing core is only coupled to transmit movement, if the movement of the bearing core or the spring element takes place in one direction, which leads to pressure changes in the space filled with liquid and / or gas. In this way, only one natural frequency of the damper mass is excited.

With the features of claim 3, the transmission behavior influence between spring element and damper mass and different operating conditions adjust.

With the features of claim 4, a damping is in particular low-frequency vibrations or vibrations with a very large amplitude achieved, as they occur due to the excitation from the vehicle.

Claim 5 characterizes an embodiment of the camp, its Transmission above the resonance frequency theoretically decreases to zero and then increases again slightly with increasing frequencies.

With the features of claim 6, the transmission behavior of the the latter bearing in an advantageous manner to the respective operating conditions be adjusted.

The claims 7 to 9 characterize a simple embodiment of the the latter bearing, its transfer characteristics to the respective operating conditions is customizable. The pressure in the container can, for example, correspond to the oil pressure of the internal combustion engine, which changes with the speed, corresponding to a mechanical signal, etc. derived from centrifugal force. All in all can be the transmission minimum 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 done with the help of an electromagnet adjacent to a line connected to the interior of the container can be changed, which is charged with a speed-dependent current.

This is particularly simple in the embodiment of Bearing according to claim 9 possible, in which the effective size of the damper spring forming movable wall with increasing pressure in the container due to increasing system the movable wall on the contact surfaces decreases, whereby the spring constant increases and the resonance frequency and thus also the frequency of minimum transmission shifts to higher frequencies.

The bearing according to the invention is suitable for use in all applications in which the bearing is specifically designed to transmit vibrations in certain frequency ranges (see Fig. 2 and Fig. 5) is intended to suppress, for example for the storage of electric motors, Pumps etc.

The invention is illustrated below with reference to schematic drawings, for example and explained with further details.

It shows: Fig. 1 a bearing, which one between two springs contains arranged damper mass, Fig. 2 shows the transfer function of the bearing according to Fig. 1, Fig. 3 shows a hydraulic / pneumatic bearing according to the principle of the bearing of Fig. 1, Fig. 4 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 FIGS. 4, 6 Rubber / metal bearings according to the principle of Fig. 4 with hydraulic / pneumatic damper mass, Fig. 7 shows an embodiment of the bearing which shows properties of the bearing according to FIG combined with those of the bearing according to FIG. 6 and FIG. 8 shows a further development of the bearing 7 with additional damping.

Gnaß Fig.1 is between a bearing core 1 and a damper mass 3 a first coil spring 5 and between the damper mass 3 and an abutment 7 a second helical spring 9 is provided.

Fig. 2 shows the power transmission characteristics of the bearing according to Fig. 1. On the ordinate is the ratio between acting on the abutment 7 Force and deflection of the bearing core applied. The abscissa gives the frequency at.

The dashed line shows the static case for the frequency Zero. Here the two forces are equal, i.e. the ratio is 1. The The diagram shows that the power transmission reaches a maximum at the natural frequency tO and from frequencies above # 2. # 0 is smaller than the static force-0 transmission. When using such a bearing for mounting an internal combustion engine in motor vehicles the transmission of structure-borne noise from the internal combustion engine into the body for frequencies greater # 2. # 0 decreased.

The system of the bearing according to FIG. 1 was previously only used in the one according to FIG. 1 viewed perpendicular direction. Of course, the system has its own vibrations also in the horizontal direction, the resonance frequency of which differs from that according to FIG.

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

When the membrane 11 is flexible, the membrane 11 is at a The deflection of the core 1 does not transmit any force directly to the metal body 13. With a certain shear stiffness of the membrane 17, it takes over the function the second helical spring 9 of the bearing according to FIG. 1. The function of the first helical spring 5 is determined by the system content of space 19 (liquid or gas) and volume stiffness of the membranes 11 and 17 taken over, so that the function of the bearing of Fig. 3 of of the camp of FIG. 1 corresponds with the exception that a motion transmission from the bearing core 1 to the damper mass 3 only when the bearing core 1 is deflected in the Perpendicular according to FIG. 3 takes place.

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

If the membranes 11, 16 do not have the stated stiffnesses, but rather for example, both are designed as rubber or steel membranes, changes the transfer behavior of the bearing somewhat, because then no longer the exact equivalent circuit diagram 1 applies.

Fig. 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 arranged, but is via a damper spring 21 at the connection point between the two coil springs 5 and 9 supported.

FIG. 5 shows the transmission behavior of the bearing according to FIG. 4.

As can be seen from this, the power transmission is at an above the Resonance frequency # 0 lying damper frequency 6 $ 1 zero, i.e.

there are no vibrations of this frequency from the bearing core 1 the abutment 7 transferred.

FIG. 6 shows an embodiment which works according to the principle of FIG of a warehouse: The bearing core 1 is supported by conical rubber elements 23 and 25 on the abutment 7. Between the rubber elements 23 and 25 is a cup-shaped carrier 26 vulcanized in, the one preferably made of rubber Membrane 27 carries on which in turn a container 29 with a bulk base 31 is attached. The container 29 is provided with a connection 33 through which the liquid or gas can be introduced. The upper edge of the container 29 also has a conical contact surface 35, against which the membrane 27 increases with increasing Pressure in the container 29 increasingly applies.

With regard to the function of the bearing according to FIG. 4, the rubber elements correspond 23 and 25 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 corresponds to the absorber mass 3.

The function of the bearing according to Fig. 4 is as follows: When the Bearing core 1 is the movement via the rubber elements 23 and 25 on the carrier 26 and as a result, the diaphragm 27 serving as a damper spring on the damper mass Container 29 outperformed Jen. By applying more or less pressure across the connection 33 to the interior of the container 29, the membrane 23 receives a bias determines the extent to which the membrane 27 rests against the contact surface 35 applies. The further the membrane 27 rests against the contact surface 35, the smaller it is the area available for the suspension, i.e. the greater the spring constant. Since the damper frequency g according to FIG. 5 depends on the spring constant, it can through this change in the pressure in the container 29, the damper frequency is the most disruptive, speed-dependent motor excitation frequencies are adapted. The spring constant the damper spring can also be influenced by the fact that the container 29 or

a filgermasse over a magnetic core and a spring with the carrier 26 is connected, which magnetic core is also connected to the carrier Coil is located to which a variable current is applied.

Fig. 7 shows an embodiment of a bearing, the features of Bearing according to FIG. 3 combined 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.

The bearing according to FIG. 8 further forms the bearing according to FIG. 7 to the effect that that the cylindrical metal body 13 'is surrounded by a further metal body 37 here which is supported on the abutment 7. In the wall of the metal body 13 'is a throttle opening 39 is formed, which is 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 will achieved that the compression of the bearing core 9, especially when this compression with low frequency and high amplitude occurs, liquid through the throttle opening 39 flows through it, whereby kinetic energy is destroyed and the movement of the bearing core 1 is attenuated.

Claims (9)

Elastic bearing, in particular for mounting an internal combustion engine in a motor vehicle Patent claims: 1. Elastic bearing, in particular for storage an internal combustion engine in a motor vehicle, with a bearing core and an abutment as well as at least one spring element arranged between the bearing core and the abutment, d u r c h g e k e n n n z e i c h n e t that the spring element (5, 9; 11,17,19) motion-transmitting connected to an oscillatory damper mass (3; 29) is. 2. Bearing according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the damper mass (3) attached to an elastic element (membrane 17) which is adjacent to a space (19) filled with liquid and / or gas, the movement transmission between the spring element connected to the bearing core (1) (Diaphragm 11) and the damper mass forms (Fiq. 3, 7 and 8). 3. Bearing according to claim 2, d a d u r c h g e k e n n -z e i c h n e t that the pressure of the liquid and / or gas-filled space (19) is variable is. 4. Bearing according to claim 2 or 3, d a d u r c h g e -k e n n z e i c h n-e t that the liquid and / or gas-filled space (19) one with a Has throttle opening (39) formed wall, which at least at a further partially bounded by an elastic wall (membrane 43) space (41) (Fig. 8). 5. Bearing according to one of claims 1 to 4, d a d u r c h g e k e n n z e i c h n e t that the damper mass (3; 29) via a damper spring (21; 27) with the spring element (5, 9; 23, 25; 11,17,19) is connected. 6. Bearing according to claim 5, d a d u r c h g e k e n n -z e i c h n e t that the weight of the damper mass (container 19) and / or the spring constant of the Damper spring (membrane 27) can be changed. 7. Bearing according to claim 6, d a d u r c h g e k e n n -z e i c h n e t that the (absorber mass is filled with liquid and / or casc, i Boh.ilt (r (29) which is closed off by a movable wall (membrane 27), to which a core (26; 26 ') connected to the spring element (23, 25; 17) is attached is. 8. Bearing according to claim 7, d a d u r c h g e k e n n -z e i c h n e t that the pressure in the container (29) can be changed. 9. Bearing according to claim 8, d a d u r c h g e k e n n -z e i c h n e t that a contact surface (35) is provided on which the movable wall (membrane 27) increasingly applies with increasing pressure in the container (29).