FR2495718A1 - Absorbent mounting for vehicle IC engine - uses intermediate mass and hydraulic cylinder interposed by rubber mountings with force taken to cylinder via mountings - Google Patents

Abstract

THE INVENTION CONCERNS A SHOCK ABSORBER SUPPORT, IN PARTICULAR FOR AN INTERNAL COMBUSTION ENGINE OF A MOTOR VEHICLE. LEDIT SUPPORT INCLUDES A CLOSED HYDRAULIC SHOCK ABSORBER 4 WHICH, INTERCALED BETWEEN RIGID CONNECTION ELEMENTS 1, IS CONNECTED TO SAID ELEMENTS 1 ONLY BY ELASTIC PARTS 6, 12, IN ORDER TO PREVENT THE TRANSMISSION OF STRUCTURAL NOISE. APPLICATION TO MOUNTING SYSTEMS FOR INTERNAL COMBUSTION ENGINES OF MOTOR VEHICLES.

Description

The present invention relates to a damping support, in particular for an internal combustion engine of a motor vehicle, in which, on the path of the force between rigid connection elements, there is at least one intermediate mass interposed between elastic parts in a rubber-like material, as well as at least one damper containing a hydraulic damping fluid. Supports of this type, in which the intermediate mass partially consists of metallic components also fulfilling other functions, are described in large numbers in the patent literature of class F16F 13/00, for example in patent applications DAS 2,616,258 or
DOS 2 935 879 and 2 652 501.

 The object of the invention is to improve supports of the aforementioned type, so that the damping effect which they exert is increased without practically any additional complication. If we consider the preferred application case according to the invention, that is to say the support of the engine of a motor vehicle, this means that, compared to known embodiments of supports, the amplitudes of the vibrations generated by the internal combustion engine must be further reduced in the area where they are transmitted to the bodywork.

 According to the essential characteristic of the shock absorber support of the invention, the shock absorber is connected to the connection elements only by elastic parts.

 When we examine once again the documents mentioned above, in order to explain the invention, they have in common the characteristic that the shock absorber, which can also be formed by chambers formed in the elastic parts and filled with hydraulic fluid, is directly connected each time to at least one of the connection elements of the support. On the equivalent diagram of this support, the damper is then parallel to the elastic part interposed between the intermediate mass and the element of connection considered and, as evidenced by research carried out within the framework of the invention, there is a transmission of vibrations or noises by the hydraulic damping fluid, so that the damper ultimately constitutes a "bridge" taken by the vibrations and parallel to said elastic part.

 In the embodiments illustrated in the figures of the aforementioned application by breszet D.kQ 2,616,258, the connection element of the support located on the body side is, of course, not directly irrigated by the damping fluid, but it is embedded in the material of an elastic part; however, between this connection element and the damping hydraulic fluid, there is similarly only a thin film of material constituting this elastic part, so that, here again, it is clear that it is practically a connection direct between the damping fluid and the connection element located on the body side.

According to other advantageous embodiments and improvements according to the invention
the intermediate mass surrounds a first rod-shaped connection element occupying a substantially horizontal position when the support is in the assembled state, delimiting an intermediate cavity housing a first elastic part; this intermediate mass is also surrounded by a casing secured to a second connecting element, delimiting another intermediate cavity in which there is a second elastic part, in which case the material constituting one of said elastic parts has a hardness greater than that of the material of which the other elastic part is made; and the damper is engaged with said intermediate mass
- Said damper consists of a jack whose piston rod is directly connected to the intermediate or additional mass, and whose cylinder is supported on the casing by means of a third elastic part; and
- Said cylinder is held in place in a region of the bowl-shaped casing and oriented downwards.

 In another exemplary embodiment, having the additional advantage of generating equal damping forces in practically all directions situated in a vertical plane, several dampers are formed, in the first and / or second elastic parts, by chambers filled with damping fluid, communicating with each other and contiguous to the intermediate mass; said chambers communicate with each other by means of grooves in the form of channels formed in the surface of the intermediate mass adjacent to said chambers, the latter being distributed at the periphery of the intermediate mass, essentially in symmetry of revolution .

According to other characteristics according to the invention
- the first and second elastic parts are designed to absorb almost entirely the static charge of the support
- the first elastic part is subdivided by another intermediate mass
- This other intermediate mass surrounds the first connecting element and it is surrounded by the intermediate mass mentioned first; and
- the two intermediate masses are concentric.

 All these embodiments have in common the characteristic that the elastic parts are stressed for the most part by pressure and not by thrust.

The invention will now be described in more detail with reference to the accompanying drawings by way of non-limiting examples and in which
Figure 1 is a vertical section of a first embodiment of the damping support according to the invention
Figure 2 is a schematic half-view of said support of Figure 1
Figure 3 is a vertical section of a second embodiment of said support;
Figure 4 is a cross section of said support along line IV-IV of Figure 3;
Figures S and 6 are equivalent diagrams corresponding to the aforementioned exemplary embodiments
Figure 7 is a vertical section of a third embodiment of said support; and
FIG. 8 is a cross section of said support, along the line VIII-tZIII of FIG. 7.

 If we first observe the embodiment shown in Figures 1 and 2, and if we admct that it is a support for the engine of a motor vehicle, the element of connection of this support, located on the motor side, consists of a part 1 in the form of a rod or tube, occupying a substantially horizontal position in the assembled state; the connection element located on the body side consists of bolts or nuts in the lower region 2, in the form of a plate, of a casing 3 which sensitively surrounds the other components of the support in the manner of a stirrup, except d a shock absorber 4. An essential component of the support is a cylindrical intermediate mass 5 which, in turn, concentrically surrounds the connection element 1 situated on the motor side, delimiting an intermediate cavity which houses a first elastic part 6. The latter t consisting of a relatively hard rubber-like material, for example butyl, comprises an annular region 6 'and protrusions 6 "in the form of branches, by which it bears against the internal face of the intermediate mass 5.

 A second elastic part 7, inserted between the external face of the intermediate mass 5 and the internal face of the casing 3, consists of a material of the soft rubber type, for example also butyl, the hardness of which is less than that of the material constituting the first elastic part 6. The short characteristic of this second elastic part 7 can be influenced in the desired direction by recesses 8 and 9, formed in the region of the internal face of the wall of the casing 3 and close to the lower plate-shaped region 2, respectively.

 In the example considered, the damper 4 consists of a jack whose rod 10 of the piston is subject to the intermediate mass 5, while its cylinder 11- is supported in a region 13 in the form of a bowl of the casing 3, by l 'through a third elastic part 12.This damper 4 is thus isolated from vibrations with respect to the two connection elements, that is to say with respect to the element 1 located on the motor side, by the first elastic part 6 , and relative to the element located on the body side and subject to the casing 3, by the third elastic part.

 This is also clearly highlighted by the equivalent diagram of this support, illustrated in FIG. 5. In this figure, the members represented in FIGS. 1 and 2 are given the same reference numbers.

It can be seen in this figure that a member resistant to vibrations and constituted by the first elastic part 6 is interposed between the connection element 1 situated on the motor side and the intermediate mass 5; it can also be seen that this mass 5 is only connected to the connection element located on the body side, and formed in this case by the region 2 in the form of a plate of the casing 3, only by vibration-resistant members and formed by the second elastic part 7 or by the third elastic part 12 on which the damper 4 is supported.

The second elastic part 7 is parallel to the damper 4 (the mass of which is then highlighted) and to the third elastic part 12, arranged in series.

Under these conditions, the damper 4 cannot form between the intermediate mass 5 and the connection element located on the body side, a "sound bridge" shorting the second elastic part 7.

Whereas, in the embodiment example according to FIGS. 1 and 2, the shock absorber consists of an additional cylinder, the embodiment example according to FIGS. 3 and 4 comprises several shock absorbers communicating with each other and formed by chambers which are provided in the first and / or second elastic parts
A first connection element 20 again consists of a rod or tube-shaped part occupying a horizontal position in the assembled state and a second connection element 21 consists of a threaded sleeve inserted in a housing 22. detailed realization of these connecting elements plays no role for the invention.
Also in this exemplary embodiment, an additional cylindrical mass 23 surrounds the connection element 20 located on the motor side, delimiting an intermediate cavity housing a first elastic part 24 which, in a relatively hard material, comprises an annular region 24 ′ and projections 24 ". The mass 23 is in turn surrounded by a second elastic part 25, which again has recesses formed in an appropriate manner, in order to present a determined characteristic curve.

 Chambers 26, constituting the shock absorbers and filled with hydraulic damping fluid, are interposed between the projections 24 "of the first elastic part 24 and they communicate with each other by means of a groove 27 forming a channel and hollowed out in the internal face of the wall of the intermediate mass 23. Since these chambers 26 are distributed in a symmetry of revolution, the support has practically the same damping properties in all directions and within the limits of the plane of the drawing.

 Other chambers 28 of this type, filled with hydraulic damping fluid, can be provided selectively or in addition in the second elastic part 25.

These chambers are then contiguous to the external face of the wall of the intermediate mass 23, in which a groove 29 is hollowed out ensuring communication by fluid between said chambers.

 As shown in Figure 6, this embodiment according to the invention also avoids a direct connection, therefore transmitting noise, between the connecting elements and the damper or the intermediate mass.

Indeed, between the connecting element 20 located on the motor side, on the one hand, and the chambers 26 constituting the shock absorbers, on the other hand, there is a vibration-resistant member and formed by the annular region 24 'of the first elastic part 24. The vibration-resistant member and constituted by the protrusions 24 ′, in the form of branches, of this elastic part, is parallel to the damping chambers 26, while however being mounted in series with the intermediate mass 23, so that it also uncouples the latter from the connection element 20 'located on the motor side.

 Between the intermediate mass 23, on the one hand, and the connecting element 21 located on the body side, on the other hand, a vibration-resistant member is interposed and formed by the second elastic part 25, the material of which is again softer than that constituting the first elastic part 24.

 In the case where the embodiment according to Figures 3 and 4 simply comprises the damping chambers 28, the diagram of Figure 6 must be reversed.

 The third embodiment illustrated in FIGS. 7 and 8 differs from that of FIGS. 3 and 4 by the fact that a first elastic part 30, also surrounded by an intermediate mass 32 by delimiting a passage 31 for the oil, is subdivided by an additional intermediate mass 33. A first connecting element 34 in the form of a rod, as well as the two intermediate masses 32 and 33, are concentric. The additional intermediate mass 33 also forms an oil passage 35, ensuring communication with chambers 36 filled with a hydraulic damping fluid. For the rest, the embodiment corresponds to that of FIGS. 3 and 4. The use of several intermediate masses uncoupled from one another as well as connecting elements by elastic parts makes it possible to further accentuate the damping effect. .

 As the description of the embodiments shows, the solution provided by the invention to the problem posed above, that is to say an improvement in the damping effect of the support, requires in all cases a low complication of the realization.

 The choice of materials of different hardnesses to produce the first and second elastic parts has the advantage of taking into account the requirements relating to the movement dynamics (by means of the first elastic part) and to soundproofing (by the the second elastic part).

 It has been found that the type of embodiment according to the invention makes it possible to obtain an engine support whose damping effect is considerably improved over the entire frequency range considered.

 I1 goes without saying that many modifications can be made to the shock absorber support described and shown, without departing from the scope of the invention.

Claims (11)

 1. Shock absorber support, in particular for an internal combustion engine of a motor vehicle, in which at least one intermediate mass interposed between elastic parts made of a rubber-like material, as well as at least one shock absorber containing a hydraulic damping fluid, lie between rigid connection elements on the path of the support force characterized in that said damper (4) is connected to said connection elements (1) only by elastic parts (6, 12).  2. Support according to claim 1, characterized in that the intermediate mass (5) surrounds a first connecting element (1) in the form of a rod occupying a substantially horizontal position when said support is in the assembled state, delimiting a intermediate cavity in which there is a first elastic part (6); by the fact that said intermediate mass (5) is also surrounded by a casing (3) secured to a second connection element, delimiting another intermediate cavity housing a second elastic part (7), one (6) of said elastic parts consisting of a material whose hardness is greater than that of the material constituting the other elastic part (7); and by the fact that the damper (4) is engaged with said intermediate mass (5).  3. Support according to claim 2, characterized in that the damper (4) is a jack, whose rod (10) of the piston is directly connected to the intermediate or additional mass (5), and whose cylinder (11 ) is supported on the casing (3) by means of a third elastic part (12).  4. Support according to claim 3, characterized in that the cylinder (11) is held in place in a region (13) of the housing (3), cup-shaped and oriented downwards.  5. Support according to claim 2, characterized in that several dampers consist of chambers (26,28) which, formed in the first and, optionally or alternatively, second elastic parts (24, 25), are filled with the fluid damping, communicate with each other and are contiguous to the intermediate mass (23).  6. Support according to claim 5, characterized in that the chambers (26,28) communicate with each other by means of grooves (27, 29) in the form of channels, which are hollowed out in the surface of the intermediate mass (23 ) adjoining said chambers.  7. Support according to one of claims 5 and 6, characterized in that the chambers (26, 28) are distributed essentially in symmetry of revolution on the intermediate mass (23).  8. Support according to any one of claims 2 to 7, characterized in that the first and second elastic parts (6, 7) are designed to absorb almost entirely the static charge of said support.  9. Support according to any one of claims 2 to 8, characterized in that the first elastic part (30) is subdivided by an additional intermediate mass (33).  10. Support according to claim 9, characterized in that the additional intermediate mass (33) surrounds the first connecting element (34) and is surrounded by the intermediate mass (32).  11. Support according to claim 10, characterized in that the two intermediate masses (32,33) are concentric.