This application claims priority on British Application No. GB0806073.3, filed Apr. 3, 2008.
1. Field of the Invention
The present invention relates to a hydraulically damped mounting device. Such a device usually has a pair of chambers for hydraulic fluid, connected by suitable passageway, and damping is achieved due to the flow of fluid through that passageway.
2. Summary of the Prior Art
EP-A-0115417 and EP-A-0172700 discussed two different types of hydraulically damped mounting devices for damping vibration between two parts of a piece of machinery, e.g. a car engine and a chassis. EP-A-0115417 disclosed various “cup and boss” type of mounting devices, in which a “boss”, forming one anchor part to which one of the pieces of machinery was connected, was itself connected via a deformable (normally resilient) wall to the mouth of a “cup”, which was attached to the other piece of machinery and formed another anchor part. The cup and the resilient wall then defined a working chamber for hydraulic fluid, which was connected to a compensation chamber by a passageway (usually elongate) which provided the damping orifice. The compensation chamber was separated from the working chamber by a rigid partition, and a flexible diaphragm was in direct contact with the liquid and, together with the partition formed a gas pocket.
In EP-A-0172700 the mounting devices disclosed were of the “bush” type. In this type of mounting device, the anchor part for one part of the vibrating machinery is in the form of a hollow sleeve with the outer anchor part in the form of a rod or tube extending approximately centrally and coaxially of the sleeve. In EP-A-0172700 the tubular anchor part was connected to the sleeve by resilient walls, which defined one of the chambers in the sleeve. The chamber was connected via a passageway to a second chamber bounded at least in part by a bellows wall which was effectively freely deformable so that it could compensate for fluid movement through the passageway without itself resisting that fluid movement.
In the hydraulically damped mounting devices disclosed in the specifications discussed above, there was a single passageway. It is also known, from other hydraulically damped mounting devices, to provide a plurality of independent passageways linking the chambers for hydraulic fluid.
In EP-A-0115417, there was a single diaphragm, which was configured to give a specific influence on the vibration characteristics of the hydraulically damped mounting device. Those characteristics depended on the stiffness of the diaphragm, by which is meant the change in applied pressure needed to cause unit change in the volume displaced by the diaphragm. Furthermore, the surface of the diaphragm which is in contact with the fluid in the working chamber may be covered by a snubber plate, with openings therein for fluid communication therethrough between the upper surface of the diaphragm and the rest of the working chamber, and it has been found that the size of those openings also affects the characteristics of the mount.
In GB-A-2282430, a mounting device was disclosed of the “cup and boss” type, with two diaphragms. The two diaphragms were arranged to have different characteristics, such as different stiffnesses or different effective stiffnesses, due to the shape of the openings by which fluid reaches those diaphragm parts from the working chamber. GB-A-2282430 also disclosed that either or both of the diaphragms may be convoluted.
One issue when producing a mount of the “cup and boss” type is to ensure that the characteristics of the passageway are appropriate. Normally, the passageway is formed in a rigid partition separating the working and compensation chambers, and thus there is limited space available within that partition for the passageway. In general, in the arrangements disclosed in EP-A-0115417 and GB-A-2282430, the passageway was formed as a spiral within the partition.
The present invention, at its most general, seeks to modify such passageway arrangements, and, in a first aspect, proposes that at least part of the passageway is formed within a cavity in the partition in which there are projections which are arranged to overlap, and so define a convoluted path for the hydraulic fluid around the projections.
Thus, according to the first aspect, there may be provided a hydraulically damped mounting device comprising two anchor parts connected by a deformable wall; a working chamber enclosed between the deformable wall and a partition rigidly associated with a first one of the anchor parts, the working chamber containing hydraulic fluid; a compensation chamber for the hydraulic fluid, the compensation chamber being at least partially bounded by a second deformable wall; a passageway between the chambers to allow fluid communication between them; and a flexible diaphragm part acting as a barrier between the hydraulic fluid and at least one gas chamber, wherein the passageway is formed in a rigid partition separating the working and compensation chambers, the partition has a hollow cavity therein having opposed surfaces defining part of the passageway therebetween, each of the opposed surfaces having a projection extending therefrom towards the other of the opposed surfaces, the free end of each projection being spaced from the surface towards which it extends, the free end of each projection being closer to the surface towards which it extends then the free end of the projection extending from the surface, whereby the projections overlap and define a convoluted path for the passageway around the projections.
In the first aspect, therefore, the projections form convolutions in the passageway linking the working and compensation chambers. However, similar ideas may be applied to other fluid parts in the mounting device. For example, they may be used in a path from the working and/or compensation chamber to a diaphragm part, or to one or more diaphragm parts where there are multiple diaphragm parts.
Thus, according to a second aspect, at its most general, a duct to a diaphragm part is at least partially formed by a cavity within the partition, which cavity has cylindrical projections arranged one within the other and overlapping to form a convoluted path for hydraulic fluid.
Thus, according to this second aspect, there may be provided a hydraulically damped mounting device comprising two anchor parts connected by a deformable wall; a working chamber enclosed between the deformable wall and a partition rigidly associated with a first one of the anchor parts, the working chamber containing hydraulic fluid; a compensation chamber for the hydraulic fluid, the compensation chamber being at least partially bounded by a second deformable wall; a passage way between the chambers to allow fluid communication between them; and a flexible diaphragm part acting as a barrier between the hydraulic fluid and at least one gas chamber, wherein there is a duct for hydraulic fluid formed in a rigid partition separating the working and compensation chambers, and supporting the diaphragm part, the partition having a hollow cavity therein having opposed surfaces defining part of the duct therebetween, each of the opposed surfaces having a projection extending therefrom towards the other of the opposed surfaces, the free end of each projection being spaced from the surface towards which it extends, the free end of each projection being closer to the surface towards which it extends then the free end of the projection extending from the surface, the duct extending to said diaphragm part from said working or compensation chamber, the duct extending through said cavity, whereby said duct is convoluted around the projections.
A third possibility is for the passageway linking the working and compensation chambers, and the duct for hydraulic fluid from the working and/or compensation chamber to the diaphragm part be linked together. In such an arrangement, the duct to the diaphragm part may be a branch in the passageway linking the working and compensation chambers. Then, in a third aspect of the invention, that branch may be made convoluted, by causing it to pass through the cavity containing the cylindrical projections.
Thus, according to a third aspect of the invention, there may be provided a hydraulically damped mounting device comprising two anchor parts connected by a deformable wall; a working chamber enclosed between the deformable wall and a partition rigidly associated with a first one of the anchor parts, the working chamber containing hydraulic fluid; a compensation chamber for the hydraulic fluid, the compensation chamber being at least partially bounded by a second deformable wall; a passage way between the chambers to allow fluid communication between them; and a flexible diaphragm part acting as a barrier between the hydraulic fluid and at least one gas chamber, wherein the passageway is formed in a rigid partition separating the working and compensation chambers, the partition has a hollow cavity therein having opposed surfaces, each of the opposed surfaces having a projection extending therefrom towards the other of the opposed surfaces, the free end of each projection being spaced from the surface towards which it extends, the free end of each projection being closer to the surface towards which it extends then the free end of the projection extending from the surface, wherein said passageway has a branch extending therefrom into said cavity, and from said cavity to said diaphragm part, whereby said branch of said passageway is convoluted around said projections.
Thus, in all of the above aspects, fluid passing through the cavity has to flow around the projections. In normal operation, where the mounting device vibrates vertically, it is convenient if the flow through the cavity is in the radial (horizontal) directions with the upwardly extending projection acting as a weir, and the downwardly extending projection acting as an underfall, for the fluid flow. Moreover, the discussion of the three aspects of the invention above refers to one projection extending from each opposed surface bounding the cavity, there may be additional projections extending from either or both of those surfaces. In such case, the projections form a series of weirs and underfalls for the fluid flow.
Where, as in the first aspect, the cavity is part of the passageway between the working and compensation chambers, it may be convenient for the inlet from the working or compensation chamber within a radial or central position within that cavity, and for the outlet (to the compensation chamber or working chamber) to be at the periphery of the cavity. In such an arrangement, it may be then convenient if projections are cylindrical, one within the other. However, such an arrangement is not limited to the case where such cylinders are circular in cross-section. Other cross-sectional shapes may be possible, such as square, rectangular, or oval. Preferably, the cylindrical projections are concentric, although this is not essential. Moreover, although we have referred to the projections being cylindrical, their walls need not be parallel to their axes so that the projections are inclined to the surfaces from which they extend. In further alternatives, the projection may be linear or curved walls within the cavity.
In a similar way, where the cavity is part of a duct or branch leading to a diaphragm, the opening from the cavity to that diaphragm may be at a central part of the cavity, and the inlet to the cavity be at a peripheral part. Again, in such an arrangement, it may be convenient to use cylindrical projections to define weirs and underfalls although the other shapes of projection discussed above may also be used.
To form the cavity, it may be possible to use selective laser sintering to form a one-piece partition with the cavity therein. However, for ease of manufacture, it may be preferable for the partition to comprise at least two partition parts, with the cavity being formed between those partition parts.
As was discussed above, in all three aspects of the invention, the diaphragm part acts a barrier between hydraulic fluid and a gas chamber. Means, such as a vacuum source, may be connected to that gas chamber to allow the gas therefrom to be evacuated. This forces the diaphragm against a wall of the vacuum chamber, and prevents the diaphragm from vibrating. Under such conditions, the hydraulic fluid in the duct or branch leading to that diaphragm part also cannot move, and the branch or duct is effectively blocked off. Thus, by application of vacuum to the gas chamber, the effect of the fluid movement in the duct or branch, and the vibration of the diaphragm, may be turned on and off.
Moreover, in the second and third aspects of the invention, where the diaphragm part terminates the duct or branch, a further diaphragm part may be provided, preferably on the partition, which acts as a barrier between the fluid in the working chamber and a further gas pocket. Again, means such as a vacuum source may be connected to that further gas pocket, to allow it to be evacuated. In such an arrangement, by selectively applying a vacuum to the gas pocket or further gas pocket, the characteristics if the mounting device may be changed.
In all the aspects discussed above, the or any diaphragm part may be annular. Such an annular diaphragm may be an incomplete annulus similar to a horse shoe, with a gap therein, to enable other components such as the passageway, to be in the gap of the annulus.
Where, as in the first aspect of the invention, the passageway is convoluted around the projections, the inlet to that passageway may be provided within the innermost cylindrical projection, and the outlet lie outside the outermost cylindrical projection. Where, as in the second or third aspect, the convolutions are in a duct or branch to the diaphragm part, the inlet to that duct or branch may be outside the outermost cylindrical projection, and the outlet to the diaphragm part be within the innermost cylindrical projection.
Embodiments of the present invention will now be described in detail, by way of example, with reference to the accompanying drawings, in which:
A first embodiment of the present invention will now be described with reference to
Referring first to
A working chamber 9 is defined within the mounting device, bounded by the resilient spring 6 and the partition 7. Moreover, within the cup 4, there is a compensation chamber 10 bounded by a flexible wall 11. The working chamber 9 and the compensation chamber 10 are connected by a passageway 11 within the partition 7. The configuration of that passageway 11 will be described in more detail later.
Thus, when the boss 1 vibrates relative to cup 4 (in the vertical direction in
In addition, the partition 7 supports an annular diaphragm 13, one side of which is in contact with the hydraulic fluid in the working chamber 9, and the other bounds a gas pocket 14.
The above structure is generally similar to that described in EP-A-0115417, and the manner of operation is similar.
The structure of the partition 7 is illustrated in more detail in
Moreover, in this embodiment the flow of fluid is different from in e.g. EP-A-0115417. In that document, the passageway between the chambers is a spiral, so that the fluid flows circumferentially around the axis of vibration of the mount, as it flows outwardly. However, in the embodiment of
A second embodiment of the invention will now be described with reference to
A diaphragm 60 is mounted on the body 51, lying above the central opening 57. Thus, one side of that diaphragm 60 (the lower side in
The bore 58a which communicates with the working chamber 9 at opening 58, also communicates with a passageway 62 extending around the partition 7, and leading to the compensation chamber.
That passageway 62 is shown more clearly in
However, as mentioned, there is a duct 61 leading from the gas space between the diaphragm 60 and the upper plate 52, and that duct is connected to a vacuum source. When a vacuum is applied to the duct 61, the diaphragm 60 is forced against the upper plate 52, so that it is locked. The fluid in the cavity 53 therefore cannot move. As a result, if the boss 1 moves relative to the cup 2, any liquid flow must be through the passageway 62 to the compensation chamber 10. The branch from the passageway 62 to the diaphragm 60 is thus locked off when the vacuum is applied to the duct 61. Thus, the characteristics of the mounting device may be varied by applying a vacuum to that duct 61.
This may be used, for example, when the mounting device is used to damp vibration between an engine and a chassis of a vehicle. In this case, when the engine is in its “idle” state, the constant frequency low amplitude vibrations generated in that state may be absorbed by the diaphragm 60. When the engine is running to drive the vehicle, however, that idle state can be locked off, by the application of a vacuum for the duct 61.
Note that, as can be seen from
A third embodiment of the invention will now be described with reference to
In this third embodiment, the partition 7 has a main body 80, with a central bore 81 therein. In that bore, a cylindrical projection 82 extends upwardly, spaced from the outer walls 83 of that bore. An upper cap 84 is fitted over that bore 81, with a downward cylindrical projection 85 extending in the space between the walls 83 of the bore and the projection 82. The upper cap 84 has openings 85 therein (visible in
Thus, again, the effect of the diaphragm 86 may be locked off by applying a vacuum to the duct 89. As in the second embodiment, there is also a passageway 90 extending between the working and compensation chambers 9, 10, defined between the body 80 and the lower plate 87. An opening in the wall 83 of the bore 81 (the opening not being visible is
Thus, the behaviour of the third embodiment is similar to that of the second embodiment, and thus will not be described in more detail now.
A fourth embodiment will now be described with reference to
In the second and third embodiments, the fluid path to the diaphragm 60 was in a branch from the passageway 62, 90 between the working and compensation chambers 9, 10. In this fourth embodiment, the duct to the diaphragm is separate from the passageway between the working and compensation chambers 9, 10, but the duct to the diaphragm is convoluted in a similar way to the third embodiment.
Thus, referring to
The main body 120 has a central bore 126 therein, with a cylindrical projection 127 extending apparently in the bore 126. An upper cap 128 is fitted over that bore 126 with openings 129 which communicate with the working chamber 9. A cylindrical projection 130 extends downwardly from the upper cap 128. Thus, the convoluted path is defined from the working chamber 9 to the diaphragm 122, via the openings 129, and around the cylindrical walls 127, 130, to the centre of the bore 126. The bore 126 communicates via openings 131 with the upper surface of the diaphragm 122.
The arrangement is thus similar to the arrangement shown in
Note that in
Number | Date | Country | Kind |
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0806073.3 | Apr 2008 | GB | national |