JP2006112588A - Liquid-sealed vibration control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid-sealed vibration control device capable of suppressing generation of abnormal noise while securing low dynamic spring characteristics at the time of input of vibration with relatively small amplitude and high damping characteristics at the time of input of vibration with relatively large amplitude. <P>SOLUTION: At the time of input of vibration with relatively large amplitude, high damping characteristics can be obtained by regulating displacement of elastic diaphragms 15 by displacement regulating ribs 17b of a first sandwiching member 17. Since only the four displacement regulating ribs 17b are radially extended and provided, opening areas of opening parts 17a are made sufficiently large and low dynamic spring characteristics can be more securely obtained. Since respective displacement regulating projections 51 of the elastic diaphragms 15 are arranged in positions corresponding to the respective displacement regulating ribs 17b, generation of abnormal noise can be securely suppressed. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a liquid-filled vibration isolator, and in particular, noise generation while ensuring a low dynamic spring characteristic when a relatively small amplitude vibration is input and a high damping characteristic when a relatively large amplitude vibration is input. The present invention relates to a liquid filled type vibration isolator capable of suppressing the above.

  A liquid-filled vibration isolator is known as a vibration isolator that supports and fixes an automobile engine and prevents the engine vibration from being transmitted to a vehicle body frame.

  In the liquid-filled vibration isolator, generally, a first attachment attached to the engine side and a second attachment attached to the body frame side are connected by a vibration isolation base made of a rubber-like elastic body. A liquid sealing chamber is formed between the diaphragm attached to the fixture and the vibration-proof base. The liquid sealing chamber is partitioned into a first liquid chamber and a second liquid chamber by a partition body, and the first and second liquid chambers communicate with each other through an orifice.

  According to this liquid-filled vibration isolator, the vibration damping function and the vibration insulating function can be achieved by the fluid flow effect between the first and second liquid chambers by the orifice and the vibration damping effect of the vibration isolating substrate.

As such a liquid-filled type vibration isolator, an elastic partition film is further disposed between the first and second liquid chambers, and a hydraulic pressure fluctuation (hydraulic pressure difference) between the two liquid chambers is reciprocally deformed by the elastic partition film. So-called elastic membrane structure that obtains a low dynamic spring characteristic at the time of small amplitude input (Patent Document 1), a displacement regulating member is provided on both sides of the elastic partition membrane, and the displacement of the elastic partition membrane is There is also known a so-called movable membrane structure configured to improve damping characteristics at the time of inputting a large amplitude by regulating the amount from both sides to increase membrane rigidity (Patent Document 2).
JP 2001-27277 A (Fig. 12 etc.) Patent No. 2875723 (FIG. 4 etc.)

  However, in the case of the elastic membrane structure, the problem of abnormal noise described later does not occur, but since the rigidity of the elastic partition membrane is constant regardless of the amplitude, an attempt is made to obtain a low dynamic spring characteristic at the time of small amplitude input. When a large amplitude is input, the hydraulic pressure difference between the two liquid chambers is easily relaxed by the elastic partition film. For this reason, the fluid flow effect cannot be fully exhibited, and there is a problem in that the attenuation characteristics are significantly reduced.

  On the other hand, in the case of the movable membrane structure, the opening area for transmitting the fluid pressure fluctuation of the first or second fluid chamber to the elastic partition membrane is narrowed by the amount of the displacement regulating member. Therefore, the hydraulic pressure fluctuation between the two liquid chambers cannot be efficiently transmitted to the elastic partition membrane, and it becomes difficult to reduce the hydraulic pressure difference by the elastic partition membrane, so that it is difficult to obtain low dynamic spring characteristics. was there.

  Furthermore, in the case of the movable membrane structure, the elastic partition membrane is in contact with the displacement restricting member. Therefore, the displacement restricting member vibrates at the time of contact, and the vibration is transmitted to the vehicle body frame. There was a problem that abnormal noise was generated.

  The present invention has been made to solve the above-mentioned problems, while ensuring a low dynamic spring characteristic at the time of relatively low amplitude vibration input and a high damping characteristic at the time of relatively high amplitude vibration input, An object of the present invention is to provide a liquid-filled vibration isolator capable of suppressing the generation of abnormal noise.

  In order to achieve this object, the liquid-filled vibration isolator according to claim 1 connects a first mounting tool, a cylindrical second mounting tool, and the second mounting tool and the first mounting tool. And a vibration isolating base composed of a rubber-like elastic body, a diaphragm attached to the second fixture to form a liquid sealing chamber between the anti-vibration base, and the liquid sealing chamber as the vibration isolating base. Partitioning means for partitioning the first liquid chamber on the side and the second liquid chamber on the diaphragm side, and an orifice for communicating the first liquid chamber and the second liquid chamber, wherein the partitioning means is a rubber-like elastic body. An elastic partition membrane, a cylindrical member that accommodates the elastic partition membrane, and a pair of clamping members that restrict displacement of the elastic partition membrane accommodated in the cylindrical member from both sides. The pair of clamping members are both substantially circular. An opening formed, and four displacement restriction ribs extending radially from the substantially central position of the opening toward the peripheral edge of the opening, and each of the displacement restriction ribs Arranged at substantially equal intervals in the circumferential direction, one clamping member of the pair of clamping members is integrally formed on the inner peripheral surface side of the cylindrical member, and the other clamping member is an inner circumference of the cylindrical member The elastic partition membrane is press-fitted into the surface side, and the elastic partition membrane is formed in a substantially disc shape having a larger diameter than the opening of the clamping member, and the main membrane from the substantially central portion of the main membrane portion And four displacement restricting protrusions that extend in a radial straight line toward the peripheral edge of the main body and project from each side of the main body film part, and the displacement restricting protrusions are arranged at substantially equal intervals in the circumferential direction. The displacement restricting protrusion is disposed at a height at which the top thereof can abut against the displacement restricting rib. The projection width on the top side is narrower or substantially equal to the projection width on the base side, and the projection width on the base side is wider than the rib width of the displacement regulating rib. In the assembled state of the partition means, the peripheral edge portion of the main body film portion is held and held by the holding member from both sides over the entire circumference, and the displacement restricting protrusions correspond to the displacement restricting ribs. Respectively.

  The liquid-filled vibration isolator according to claim 2 is the liquid-filled vibration isolator according to claim 1, wherein the displacement restricting protrusion is formed such that the protrusion width on the top side is wider than the rib width of the displacement restricting rib. Has been.

  The liquid-filled vibration isolator according to claim 3 is the liquid-filled vibration isolator according to claim 1 or 2, wherein the cylindrical member includes a projecting portion projecting toward an inner peripheral surface thereof, and the elasticity. The partition film and the other holding member include a recess that is formed by notching an outer peripheral edge of the partition film and that can be fitted to the projection, and the projection is fitted into the recess when the partition means is assembled. By combining, the relative rotational direction positions of the pair of sandwiching members and the elastic partition film are positioned, and the displacement restricting protrusions are respectively disposed at positions corresponding to the displacement restricting ribs. It is configured.

  The liquid-filled vibration isolator according to claim 4 is the liquid-filled vibration isolator according to any one of claims 1 to 3, wherein the displacement regulating protrusion is provided on at least one surface side of the main body film portion. An auxiliary protrusion protrudes from the remaining portion, and the auxiliary protrusion is configured to have a protrusion height lower than the displacement restricting protrusion and a protrusion width narrower.

  According to the liquid-filled vibration isolator of claim 1, when a relatively small amplitude vibration is input, the elastic partition film is reciprocally displaced to reduce (absorb) the hydraulic pressure difference between the first and second liquid chambers. Therefore, there is an effect that the dynamic spring value can be reduced and low dynamic spring characteristics can be obtained.

  In particular, according to the liquid-filled type vibration isolator of the present invention, since only four displacement regulating ribs extend radially in the opening of each clamping member, the opening area of the opening Can be made sufficiently wide to efficiently transmit the hydraulic pressure difference between the first and second liquid chambers to the elastic partition membrane. As a result, there is an effect that the hydraulic pressure difference can be effectively relaxed and the low dynamic spring characteristics can be obtained more reliably.

  On the other hand, when relatively large amplitude vibration is input, the displacement of the elastic partition membrane can be regulated by the displacement regulating ribs of the clamping member, and the rigidity of the elastic partition membrane as a whole can be increased. There is an effect that attenuation characteristics can be obtained.

  In particular, according to the liquid-filled vibration isolator of the present invention, the entire periphery of the peripheral edge of the elastic partition membrane (main body membrane) is configured to be clamped and held from both sides by a pair of clamping members. Between the second liquid chambers, it is possible to avoid the liquid from flowing through the path through the opening of the holding member, and to flow only through the path through the orifice. Therefore, there is an effect that the fluid flow effect can be efficiently exhibited and high attenuation characteristics can be obtained.

  Further, since each of the four displacement restricting ribs is arranged at substantially equal intervals in the circumferential direction, when restricting the displacement of the elastic partition film, the deformation of the elastic partition film is not partially biased. , Can be deformed more evenly. Therefore, there is an effect that the membrane rigidity of the elastic partition membrane can be efficiently increased and high damping characteristics can be obtained with certainty.

  Furthermore, by arranging the four displacement restricting ribs at substantially equal intervals in the circumferential direction, the crossing angle of the displacement restricting ribs is sufficiently increased, and the distortion of the elastic partition film is near the intersection of the respective displacement restricting ribs. You can avoid concentrating on. As a result, there is an effect that the durability of the entire elastic partition film can be improved.

  In other words, when there are more than four displacement restricting ribs (that is, five or more), the crossing angle of the displacement restricting ribs becomes small (72 ° or less), so that the elastic partition membrane is caused by a hydraulic pressure difference. When reciprocating displacement occurs, there is a problem that deformation (strain) of the elastic partition film concentrates near the intersection of each displacement regulating rib, resulting in damage such as film breakage.

  In addition, in the conventional liquid-filled vibration isolator, in addition to the radial linear displacement restriction ribs, a large number of annular displacement restriction ribs are provided. Damage due to concentration of deformation (strain) has been a problem.

  On the other hand, according to the liquid-filled vibration isolator of the present invention, since four radial linear displacement regulating ribs are provided at equal intervals in the circumferential direction in the circular opening, the crossing angle of each displacement regulating rib Can be made sufficiently large (90 °), and since there is no annular displacement regulating rib, when the elastic partition membrane is reciprocally displaced due to a hydraulic pressure difference, its deformation (strain) is totally reduced. And the occurrence of breakage such as film breakage can be effectively suppressed.

  Here, in the assembled state of the partition means, each displacement restricting protrusion of the elastic partition film is disposed only at a position corresponding to each displacement restricting rib of the clamping member, and the top of the displacement restricting protrusion is the displacement restricting rib. Since the height dimension is set so as to allow contact, there is an effect that the generation of abnormal noise can be reliably suppressed.

  That is, if the displacement restricting protrusion is not provided at a position corresponding to the displacement restricting rib, a large gap is generated between the displacement restricting rib and the elastic partition film (main body film part). Where the (main body film part) collides with the displacement restricting rib and causes abnormal noise, each displacement restricting projection is arranged at a position corresponding to each displacement restricting rib, and the top of the displacement restricting projection is the displacement restricting. If it is in contact with the rib, it is possible to avoid the occurrence of abnormal noise by avoiding the collision of the elastic partition film (the main body film portion and the displacement regulating projection) with the displacement regulating rib.

  In addition, when the displacement regulating projection is not provided at a position corresponding to the displacement regulating rib, and the gap is generated, the displacement regulating rib requires a rigidity strength to catch the collision of the elastic partition film (main body film part). However, if each displacement restricting protrusion is arranged corresponding to each displacement restricting rib, the load acting on each displacement restricting rib is reduced, and the durability of the clamping member (displacement restricting rib) is correspondingly reduced. There is an effect that improvement can be achieved.

  And if the load which acts on each displacement control rib can be reduced, since a required rigid strength can be made low, the rib width of a displacement control rib can be comprised narrow by that much. As a result, since the opening area of the opening of the holding member can be increased by the amount of the narrowed rib width, the transmission efficiency for transmitting the hydraulic pressure difference between the first and second liquid chambers to the elastic partition membrane can be improved. As a result, the hydraulic pressure difference can be reduced more efficiently. Therefore, a low dynamic spring characteristic can be obtained more reliably.

  Here, the displacement regulating projection of the elastic partition film is formed such that the projection width on the top side is narrower or substantially equal to the projection width on the base side (main body membrane side), and the projection width on the base side is displacement regulated. It is formed wider than the rib width of the rib.

  That is, since the displacement restricting projection is configured so that at least the width of the protrusion on the base side is wider than the rib width of the displacement restricting rib, when a relatively large amplitude vibration is input and the elastic partition film is reciprocally displaced. However, there is an effect that the elastic partition film can be prevented from colliding with the displacement regulating rib, and the generation of abnormal noise can be suppressed.

  In particular, even if the displacement restricting protrusion is displaced in the circumferential direction with respect to the displacement restricting rib due to the dimensional tolerance of each part or the assembly tolerance during assembly work, the protrusion width on the base side of the displacement restricting protrusion is displaced. If it is made wider than the rib width of the regulating rib, the collision between the displacement regulating rib and the elastic partition film can be moderated, and the generation of noise due to the collision can be effectively suppressed.

  In addition, according to the liquid-filled vibration isolator of the present invention, since one of the pair of clamping members is integrally formed on the inner peripheral surface side of the cylindrical member, there is no need to perform complicated assembly work. Therefore, there is an effect that the work cost at the time of assembly can be reduced. Furthermore, since the other holding member is configured to be press-fitted into the inner peripheral surface side of the cylindrical member, the other holding member can be firmly fixed. Therefore, the distance between the opposing surfaces between the clamping member and the elastic partition membrane and the relative position of the displacement regulating rib with respect to the elastic partition membrane (displacement regulating projection) can be set accurately, and further noise reduction can be achieved. There is an effect that can be.

  According to the liquid-filled vibration isolator according to claim 2, in addition to the effect exhibited by the liquid-filled vibration isolator according to claim 1, the displacement restricting protrusion has a protrusion width on the top side of the displacement restricting rib. Since it is formed wider than that, there is an effect that it is possible to suppress the occurrence of air accumulation at the top of the displacement restricting projection. Therefore, there is an effect that it is possible to suppress a decrease in dynamic characteristics due to residual air pockets (bubbles). Furthermore, after the assembly work of the partition means is performed outside the liquid tank, the assembled product can be mounted on the inner peripheral side of the second fixture in the liquid tank, thus simplifying the assembly work process and There is an effect that the cost can be significantly reduced.

  That is, as described above, the displacement restricting protrusion is formed so that the protrusion width on the base side is wider than the rib width of the displacement restricting rib in order to suppress the generation of abnormal noise. Therefore, if the projection width on the top side is made narrower than the rib width of the displacement regulating rib, a constricted space that becomes narrower toward the heel side is formed near the top of the displacement regulating projection.

  If air pockets (bubbles) are generated in the liquid chamber, it will not be possible to perform the vibration isolation function based on the liquid flow effect. Therefore, it is necessary to remove the bubbles, but the bubbles remaining in the space of this shape are removed. This is extremely difficult and causes a significant increase in operating costs. For this reason, in the conventional liquid-filled vibration isolator, it is necessary to assemble the partition means in the liquid tank, and the assembly process becomes complicated, so that there is a problem that the operation cost increases.

  According to the liquid-filled vibration isolator according to claim 3, in addition to the effect exhibited by the liquid-filled vibration isolator according to claim 1 or 2, the elastic partition film and the other holding member are recessed at the outer peripheral edge. By fitting a convex portion projecting to the inner peripheral surface side of the cylindrical member into the concave portion, the relative rotational direction position of the pair of clamping members and the elastic partition film is positioned, and each displacement regulating projection is There is an effect that each can be arranged with high accuracy at a position corresponding to the displacement regulating rib. As a result, there is an effect that it is possible to suppress a problem that the dynamic characteristics vary from product to product due to variations in the contact state between the displacement regulating protrusion and the displacement regulating rib.

  In addition, since the projecting portion is configured to project to the inner peripheral surface side of the cylindrical member, it is possible to suppress the increase in the diameter of the cylindrical member and increase its weight, and to reduce the size of the liquid-filled vibration isolator as a whole. There is an effect that the weight can be reduced. That is, if the concave portion is formed on the inner peripheral surface side of the cylindrical member, it is necessary to ensure the thickness of the barrel portion of the cylindrical member by the amount of the concave portion. This causes an increase in weight, and accordingly, increases the size and weight of the liquid-filled vibration isolator as a whole.

  According to the liquid-filled vibration isolator according to claim 4, in addition to the effect of the liquid-filled vibration isolator according to any one of claims 1 to 3, the elastic partition film is provided with an auxiliary projection. Therefore, there is an effect that the durability of the elastic partition film can be improved by suppressing the breakage of the elastic partition film due to the displacement at the time of inputting the large amplitude. Furthermore, since the auxiliary protrusion is configured so that the protrusion height is lower than the displacement restricting protrusion and the protrusion width is narrow, the increase in rigidity of the entire elastic partition film is suppressed, and a small amplitude input is performed. There is an effect that the low dynamic spring characteristic at the time can be maintained.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the invention will be described with reference to the accompanying drawings. FIG. 1 is a cross-sectional view of a liquid-filled vibration isolator 100 according to an embodiment of the present invention.

  The liquid-filled vibration isolator 100 is a vibration isolator for supporting and fixing an automobile engine so that the engine vibration is not transmitted to the vehicle body frame, and is attached to the engine side as shown in FIG. A first mounting bracket 1, a cylindrical second mounting bracket 2 that is mounted on the vehicle body frame side below the engine, and a vibration-proof base 3 that is connected to the first mounting bracket 1 and is made of a rubber-like elastic body.

  The first mounting bracket 1 is formed in a substantially cylindrical shape from a metal material such as an aluminum alloy. As shown in FIG. 1, a female thread portion 1a is recessed in the upper end surface. Further, a substantially flange-shaped protruding portion is formed on the outer peripheral portion of the first mounting portion 1, and the protruding portion abuts against the stabilizer fitting so that a stopper action at the time of large displacement can be obtained. ing.

  The second mounting bracket 2 includes a cylindrical metal fitting 4 on which the vibration-proof base 3 is vulcanized and a bottom metal fitting 5 attached to the lower side of the cylindrical metal fitting 4. The cylindrical metal fitting 4 is formed in a cylindrical shape having an opening extending upward, and the bottom metal fitting 5 is formed in a cup shape having an inclined bottom portion from a steel material or the like. A mounting bolt 6 projects from the bottom of the bottom metal fitting 5.

  The vibration isolator base 3 is formed in a truncated cone shape from a rubber-like elastic body, and is vulcanized and bonded between the lower surface side of the first mounting bracket 1 and the upper end opening of the cylindrical bracket 4. Further, a rubber film 7 covering the inner peripheral surface of the cylindrical metal fitting 4 is connected to the lower end portion of the vibration isolating base 3, and the rubber film 7 has orifice forming walls 22 and 23 ( 2 and FIG. 3) are brought into close contact with each other, and the orifice 25 is formed.

  The diaphragm 9 is formed in a rubber film shape having a partial spherical shape from a rubber-like elastic body, and is vulcanized and bonded to a mounting plate 10 having a donut shape when viewed from above. As shown in FIG. 1, the diaphragm 9 is attached to the second mounting bracket 2 by fixing the mounting plate 10 between the tubular bracket 4 and the bottom bracket 5. As a result, a liquid sealing chamber 8 is formed between the diaphragm 9 and the lower surface of the vibration isolating substrate 3.

  The liquid enclosure 8 is filled with an antifreeze liquid (not shown) such as ethylene glycol. In addition, the liquid enclosure chamber 8 is divided into two chambers, a first liquid chamber 11A on the vibration isolation base 3 side and a second liquid chamber 11B on the diaphragm 9 side, by a partition body 12 which will be described later.

  The partition body 12 includes an elastic partition film 15 configured in a substantially disk shape from a rubber film, and an orifice member 16 in which the elastic partition film 15 is accommodated on the inner peripheral surface side and the first clamping member 17 is integrally formed. And a lattice disk-shaped second sandwiching member 18 that is press-fitted from an opening below the orifice member 16 (lower side in FIG. 1).

  In addition, the partition body 12 is the 2nd attachment metal fitting 2 (cylindrical metal fitting 4) in the state which carried out the compression deformation of the outer peripheral part of the diaphragm 9, and the step part 57 of the vibration-proofing base | substrate 3, respectively in an axial direction (FIG. 1 up-down direction). ) And is held in the liquid sealing chamber 8 by the elastic restoring force of the diaphragm 9 (outer peripheral portion) and the vibration-proof base 3 (stepped portion 57).

  Further, an orifice 25 is formed between the outer peripheral surface of the orifice member 16 and the rubber film 7 covering the inner peripheral surface of the second mounting bracket 2 as shown in FIG. The orifice 25 is an orifice channel for communicating the first liquid chamber 11A and the second liquid chamber 11B, and for allowing the liquid to flow between the two liquid chambers 11A and 11B, and around the axis O of the orifice member 16. Is formed approximately one round.

  Note that the entire circumference of the outer peripheral portion of the elastic partition film 15 is held with no gap between the first and second holding members 17 and 18. Therefore, the liquid in the liquid enclosure 8 does not leak (leak) in the first and second liquid chambers 11A and 11B through openings 17a and 18a described later, and the liquid in the liquid enclosure 8 passes through the orifice 25. Only between the first liquid chamber 11A and the second liquid chamber 11B.

  Next, the orifice member 16 constituting the partition body 12 will be described with reference to FIG. 2 and FIG. FIG. 2A is a top view of the orifice member 16, and FIG. 2B is a side view of the orifice member 16. 3A is a bottom view of the orifice member 16, and FIG. 3B is a cross-sectional view of the orifice member 16 taken along line IIIb-IIIb in FIG. 2A.

  As shown in FIGS. 2 and 3, the orifice member 16 is formed in a substantially cylindrical shape having a shaft core O from a metal material such as an aluminum alloy. At the upper and lower ends of the orifice member 16 in the axial direction, substantially flange-shaped orifice forming walls 22 and 23 are formed so as to project in the radial direction, and an orifice flow path is formed between the opposing surfaces of the orifice forming walls 22 and 23. Is done.

  As described above, the orifice forming walls 22 and 23 are in close contact with the rubber film 7 covering the inner periphery of the cylindrical metal fitting 4 to form the orifice 25 having a substantially rectangular cross section (see FIG. 1). Further, as shown in FIG. 2B, the orifice member 16 includes a vertical wall 24 that connects the upper and lower orifice forming walls 22 and 23, and the orifice 25 (see FIG. 1) is formed by the vertical wall 24. Divided in the circumferential direction.

  As shown in FIG. 3 (b), the lower orifice forming wall 23 has a step portion and is formed so as to protrude in the radial direction from the upper orifice forming wall 22. The orifice forming wall 23 is formed of a cylinder. The orifice member 16 is attached to the second mounting bracket 2 by being caulked and fixed between the shaped bracket 4 and the bottom bracket 5 (see FIG. 1).

  As shown in FIGS. 2 and 3, a cutout 55 is cut out in the upper orifice forming wall 22, and one end of an orifice flow path (orifice 25, see FIG. 1) is formed through the cutout 55. It communicates with the first liquid chamber 11A. An opening 58 is formed in the body of the orifice member 16, and the other end of the orifice channel (orifice 25, see FIG. 1) is connected to the second liquid chamber 11B via the opening 58. Communicated.

  As shown in FIG. 3, the orifice member 16 includes a convex portion 56 that projects to the inner peripheral surface side. The convex portions 56 are fitted into concave portions 59 and 54 of the second sandwiching member 18 and the elastic partition film 15 described later, and the second sandwiching member 18 and the elastic partition film 15 with respect to the orifice member 16 (first sandwiching member 17). It is a site | part for positioning the relative rotational direction position.

  Further, as shown in FIGS. 2 and 3, a substantially disc-shaped first clamping member 17 is integrally formed on the inner peripheral surface side of the orifice member 16. The first clamping member 17 includes an opening 17a that is formed in a substantially circular shape, and four displacement regulating ribs 17b that extend radially from the substantially center position of the opening 17a toward the peripheral edge. It is configured with.

  The opening 17a transmits the hydraulic pressure fluctuation in the liquid sealing chamber 8 (first liquid chamber 11A) to the elastic partition film 15, and avoids a collision with the elastic partition film 15 displaced by the hydraulic pressure fluctuation. It is an opening provided as an escape portion (see FIG. 1), and is opened in a shape in which a circle is divided into three equal parts by a displacement regulating rib 17b.

  The displacement restricting rib 17b is a rib for restraining the elastic partition film 15 (restricting displacement) by contacting a later-described displacement restricting protrusion 51 (see FIG. 5 and the like) of the elastic partition film 15 as shown in FIGS. As shown in FIG. 3, four are formed in a radial straight line with respect to the axis O of the orifice member 16.

  Each displacement regulating rib 17b is formed so that its rib width and rib thickness are substantially the same as the other displacement regulating ribs 17b. Further, the displacement restricting ribs 17b are arranged at substantially equal intervals (approximately 90 ° intervals) in the circumferential direction, and the intersection angle between the displacement restricting ribs 17b is approximately 90 °.

  As shown in FIGS. 2 and 3, a substantially circular strain suppressing portion 17 c is formed at the intersecting portion of each displacement regulating rib 17 b (the center portion of the opening portion 17 a). The strain suppression portion 17c is a portion having a function of making the deformation state of the elastic partition film 15 uniform, and suppresses concentration of the deformation amount (strain) of the elastic partition film 15 in the vicinity of the intersection of each displacement regulating projection 17b. Thus, the durability of the elastic partition film 15 is improved.

  As shown in FIG. 3, a locking wall portion 17 d is provided on the lower surface side of the first clamping member 17 at a position along the peripheral edge portion of the opening portion 17 a. The locking wall portion 17d is a portion for locking the inclined surface of the elastic partition film 15 (the sandwiched portion 50a) and positioning the elastic partition film 15 in the radial direction.

  Thereby, in the assembly process of the partition body 12, the elastic partition film 15 can be easily positioned to reduce the operation cost, and the positioning accuracy (the position of the displacement restricting projection 51 with respect to the displacement restricting rib 17b) can be reduced. Accuracy) can be improved, and variations in dynamic characteristics among products can be reduced.

  In addition, as shown to Fig.3 (a), the locking wall part 17d is formed in four places of the circumferential direction, and is not formed in the position corresponding to the displacement control rib 17b. As a result, the contact area between the displacement regulating rib 17b and the displacement regulating projection 51 is ensured to improve the dynamic characteristics (maintaining high damping characteristics while maintaining low dynamic spring characteristics).

  Next, with reference to FIG. 4, the second clamping member 18 constituting the partition body 12 will be described. 4A is a top view of the second holding member 18, and FIG. 4B is a cross-sectional view of the second holding member 18 taken along line IVb-IVb in FIG. 4A.

  The second clamping member 18 is a member for clamping the elastic partition film 15 together with the above-described first clamping member 17 and restraining the elastic partition film 15 (regulating displacement), as shown in FIG. It is formed in a substantially disc shape having an axis O from a metal material such as an aluminum alloy.

  As shown in FIG. 4, the second holding member 18 has an opening 18 a that is formed in a substantially circular shape, and four that extend in a radial straight line from a substantially center position of the opening 18 a toward the peripheral edge. The displacement restricting rib 18b.

  The opening 18a, the displacement restricting rib 18b, the strain suppressing portion 18c, and the locking wall 18d are the same pattern as the opening 17a, the displacement restricting rib 17b, etc. (see FIGS. 2 and 3) of the first clamping member 17 described above. (In other words, since the position, size, range, and the like are the same), the description thereof is omitted.

  As shown in FIG. 4, the second holding member 18 includes a recess 59 formed by notching the outer peripheral edge. The concave portion 59 is a portion for fitting the convex portion 56 of the orifice member 16 described above to position the relative rotational direction position of the second clamping member 18 with respect to the orifice member 16 (first clamping member 17). is there.

  That is, the second clamping member 18 is inserted from the lower opening of the orifice member 16 in the assembling step of the partition body 12 and is press-fitted into the inner peripheral surface side of the orifice member 16 (see FIG. 7). In this case, the concave portions 59 are fitted into the convex portions 56 of the orifice member 16 so that the displacement regulating ribs 18b of the second clamping member 18 correspond to the displacement regulating ribs 17b of the orifice member 16 (first clamping member 17). In other words, it can be positioned to the position overlapping in the axial direction view.

  Note that the positioning of the second clamping member 18 in the depth direction with respect to the orifice member 16, that is, the distance between the opposing surfaces of the first clamping member 17 and the second clamping member 18 is formed on the inner peripheral side of the orifice member 16. This is done by bringing the upper end of the second clamping member 18 into contact with the stepped portion (see FIG. 3).

  Next, the elastic partition film 15 constituting the partition body 12 will be described with reference to FIGS. 5 and 6. FIG. 5A is a top view of the elastic partition film 15, and FIG. 5B is a bottom view of the elastic partition film 15. 6A is a cross-sectional view of the elastic partition film 15 taken along the line VIa-VIa in FIG. 5A, and FIG. 6B is an elastic partition taken along the line VIb-VIb in FIG. 5A. 2 is a cross-sectional view of a film 15. FIG.

  The elastic partition film 15 is a rubber film configured in a substantially disk shape from a rubber-like elastic body. As described above, the elastic partition film 15 is accommodated in the partition body 12 and is displaced by the first and second clamping members 17 and 18. Is exerted to relieve the hydraulic pressure difference between the first and second liquid chambers 11A and 11B.

  As shown in FIGS. 5 and 6, the elastic partition film 15 includes a substantially disc-shaped main body film portion 50, a displacement restricting protrusion 51 and an auxiliary protrusion 52 that protrude from both upper and lower surfaces of the main body film portion 50. It is mainly prepared.

  The main body film portion 50 is provided with a sandwiched portion 50a and a strain suppressing portion 50b on the upper and lower surfaces. The sandwiched portion 50a and the strain suppressing portion 50b are portions that are sandwiched and held from both sides by the first and second sandwiching members 17 and 18 described above, and the sandwiched portion 50a is provided at the peripheral portion of the main body film portion 50. The strain suppression part 50 b is formed in an annular shape at a substantially central part of the main body film part 50 in a circular shape.

  The top heights of these portions 50 a and 50 b are set to be approximately the same height as the top height of the displacement regulating projection 51. Further, the strain suppression portion 50b is formed in a circular shape that is concentric with the first and second clamping portions 17 and 18 and has a diameter equal to or larger than the same. Thereby, concentration of deformation (strain) of the elastic partition film 15 is suppressed to improve its durability, and collision between the elastic partition film 15 and the first and second clamping members 17 and 18 is avoided. Thus, the generation of abnormal noise can be suppressed.

  As shown in FIG. 5, the elastic partition film 15 includes a recess 54 formed by notching the outer peripheral edge of the main body film portion 50 (the sandwiched portion 50 a). The concave portion 59 is fitted to the convex portion 56 of the orifice member 16 in the same manner as the second sandwiching member 18 (see FIG. 4) described above, and the elastic partition film 15 with respect to the orifice member 16 (first sandwiching member 17). This is a part for positioning a relative rotational direction position.

  In the assembling process of the partition body 12, the concave portion 54 is fitted to the convex portion 56, thereby positioning the rotational direction position, and holding each displacement regulating projection 51, which will be described later, of the elastic partition film 15 first and second. The members 17 and 18 can be positioned at positions corresponding to the displacement restricting ribs 17b (that is, positions overlapping when viewed in the axial direction).

  Further, in this case, the inclined surface of the sandwiched portion 50a is latched by the latching wall portions 17d and 18d of the first and second sandwiching members 17 and 18, and elasticity against the first and second sandwiching members 17 and 18 is achieved. Positioning of the partition film 15 in the radial direction is performed.

  The displacement restricting protrusion 51 is a rib-like protrusion that is brought into contact with the displacement restricting ribs 17b and 18b of the first and second clamping members 17 and 18, and in the assembled state of the partition body 12, the displacement restricting ribs 17b and 18b It arrange | positions in a corresponding position (Namely, the displacement control protrusion 51 and the displacement control ribs 17b and 18b overlap in the axial direction view).

  Specifically, as shown in FIG. 5, four displacement restricting projections 51 are arranged in a radial straight line with respect to the axis O of the elastic partition film 15, and at substantially equal intervals in the circumferential direction (approximately 90). By being arranged at intervals of (°), it corresponds to the arrangement of the displacement regulating ribs 17b and 18b.

  The displacement restricting protrusions 51 are arranged symmetrically on the upper and lower surfaces of the elastic partition film 15 (that is, disposed so that the upper and lower displacement restricting protrusions 51 overlap each other when viewed in the axial direction), and the displacement restricting protrusions 51 are arranged. The protrusion width and the protrusion height are substantially the same for all the displacement restricting protrusions 51.

  As shown in FIG. 6, the protrusion height of each displacement restricting protrusion 51 is set to substantially the same height as the sandwiched portion 50a and the strain suppressing portion 50b, and in the assembled state of the partition body 12 (FIG. 7). The top portion is set so as to contact the displacement regulating ribs 17b and 18b in a slightly compressed state.

  Therefore, no gap is generated between the displacement restricting projection 51 and the displacement restricting ribs 17b and 18b, and even if the elastic partition film 15 is displaced with the input of a large amplitude, the top of the displacement restricting protrusion 51 remains at the displacement restricting rib. 17b and 18b do not collide. As a result, it is possible to avoid the occurrence of abnormal noise due to the collision between the displacement restricting protrusion 51 and the displacement restricting ribs 17b and 18b, and the noise can be further reduced accordingly.

  Here, as shown in FIG. 6B, the displacement regulating projection 51 is set such that the projection width Wr1 on the top side is narrower than the projection width Wr2 on the base side (main body film portion 50 side) (Wr1). <Wr2) and the protrusion width Wr1 on the top side is formed to be slightly wider than the rib widths of the displacement regulating ribs 17b and 18b (see FIG. 8).

  As a result, the elastic partition film 15 can be prevented from colliding with the displacement regulating ribs 17b and 18b, and the generation of abnormal noise can be suppressed. In particular, even when the displacement restricting protrusion 51 is displaced in the circumferential direction (for example, the left and right direction in FIG. 8) with respect to the displacement restricting ribs 17b and 18b due to the dimensional tolerance of each part or the assembling tolerance at the time of assembly work. If the protrusion width Wr2 on the base side of the displacement restricting protrusion 51 is wider than the rib width of the displacement restricting ribs 17b, 18b, the collision between the displacement restricting ribs 17b, 18b and the elastic partition film 15 (main body film portion 50). The generation of abnormal noise due to the collision can be effectively suppressed.

  The auxiliary protrusions 52 are rib-shaped protrusions for preventing the elastic partition film 15 from being damaged such as film breakage. As shown in FIGS. 5 and 6, the auxiliary protrusions 52 are formed with respect to the axis O of the elastic partition film 15. A radial linear portion and an annular portion are combined. The projection height and the projection width of each auxiliary projection 52 are the same.

  As shown in FIG. 6, the auxiliary protrusion 52 is set so that the protrusion width is narrower than the displacement restricting protrusion 51 and the protrusion height is lower, so that the rigidity of the elastic partition film 15 as a whole is increased. It is possible to maintain the low dynamic spring characteristic at the time of small amplitude input by suppressing the rise.

  Next, the assembled state of the partition 12 will be described with reference to FIGS. 7 and 8. Fig.7 (a) is a top view of the partition body 12, FIG.7 (b) is sectional drawing of the partition body 12 in the VIIb-VIIb line | wire of Fig.7 (a). FIG. 8 is a cross-sectional view of the partition 12 taken along line VIII-VIII in FIG.

  In the assembled state of the partition 12, as described above, the displacement regulating ribs 17 b of the first clamping member 17 and the displacement regulating ribs 18 b of the second clamping member 18 are viewed in the axial direction shown in FIG. And the displacement regulating ribs 17b, 18b coincide with the rotational position of each displacement regulating projection 51 of the elastic partition film 15. In this case, as shown in FIG. 8, the tops of the displacement restricting protrusions 51 are in contact with the displacement restricting ribs 17b and 18b in a slightly compressed state.

  As a result, according to the liquid-filled vibration isolator 100 of the present invention, when a small amplitude is input, the hydraulic pressure difference between the first and second liquid chambers 11A and 11B is reduced by the elastic partition film 15 as in the conventional elastic film structure. Can be effectively relaxed and the dynamic spring value can be reduced. On the other hand, when a large amplitude is input, the displacement regulating ribs 17b and 18b regulate the displacement of the elastic partition film 15, and the rigidity of the elastic partition film 15 as a whole can be increased, thereby improving the damping characteristics accordingly. Can do. Further, since the displacement restricting ribs 17b and 18b are provided only at positions corresponding to the displacement restricting protrusions 51, the contact between the elastic partition film 15 and the first and second holding members 17 and 18 is avoided. Sound can be greatly reduced.

  Next, the results of a characteristic evaluation test that examines the relationship between the number of the displacement regulating ribs 17b and 18b (displacement regulating projections 51) and the dynamic characteristics will be described.

  Here, in the liquid filled type vibration isolator 100, when idling or when inputting a small amplitude such as a booming sound region (generally, frequency: 20 Hz to 40 Hz, amplitude: ± 0.05 mm to ± 0.1 mm). Low dynamic spring characteristics, large amplitude input such as cranking vibration, etc. (generally, frequency: 10 Hz to 20 Hz, amplitude: ± 1 mm to ± 2 mm), and input of intermediate amplitude between them It is required to achieve a high attenuation characteristic in a shake area or the like.

  Therefore, in the characteristic evaluation test, the liquid-filled vibration isolator 100 of the present invention described in the above embodiment (hereinafter referred to as “the product of the present invention”) and the displacement regulating ribs 17b and 18b for the product of the present invention. The number of liquid-filled vibration isolator (hereinafter referred to as “two-type product”) in which the number of (displacement restricting protrusions 51) is reduced to two and the number of displacement restricting ribs 17b and 18b (displacement restricting protrusions 51) are as follows. The product of the present invention under the condition that the dynamic spring value at idling (at the time of small amplitude input) is the same using a liquid filled type vibration isolator (hereinafter referred to as “three type product”) reduced to three. The maximum attenuation value obtained with each of the two-type product and the three-type product was measured.

  In the product of the present invention, the four displacement restricting ribs 17b and 18b (displacement restricting protrusions 51) are arranged at intervals of about 90 ° in the circumferential direction, whereas in the two type products, at intervals of about 180 ° in the circumferential direction. The three-type products are arranged at intervals of approximately 120 ° in the circumferential direction. In addition, these two-type products and three-type products differ from the present invention only in the number (displacement in the circumferential direction) of the displacement regulating ribs 17b and 18b (displacement regulating projections 51), and the materials of the other members. The shape and dimensions are all the same.

  In the characteristic evaluation test, first, tuning is performed so that the dynamic spring values at the time of idling (frequency: 30 Hz, amplitude: ± 0.05 mm) are the same for the present invention product, the two type product, and the three type product. (For example, adjusting the rubber hardness of the elastic partition film 15), and then continuously inputting the amplitude (± 0.5 mm) in the shake region to the present invention product, the two-type product, and the three-type product. The maximum (peak) value of the attenuation characteristic obtained by changing the frequency was measured.

  As a result, the maximum attenuation characteristic of the product of the present invention is approximately 1.2 times the value of the three type product, while being approximately 1.8 times the value of the two type product, which is extremely excellent. It was confirmed that the damping characteristics can be obtained. That is, in the present invention, it was confirmed that both the low dynamic spring characteristic and the high damping characteristic can be achieved.

  Here, when a predetermined vibration (frequency: 15 Hz, amplitude: ± 1 mm) is input from the engine side (first mounting bracket 1 side), acceleration output from the vehicle body frame side (second mounting bracket 2 side) An abnormal noise evaluation test was also performed in which the value was measured as an abnormal noise index. As a result, the noise index value of the present invention product, the two-type product, and the three-type product is almost 0, which can significantly reduce the noise compared to the conventional movable membrane structure and has an elastic membrane structure. As a result, extremely good results were obtained.

  The present invention has been described above based on the embodiments. However, the present invention is not limited to the above embodiments, and various improvements and modifications can be made without departing from the spirit of the present invention. It can be easily guessed.

  For example, in the above-described embodiment, the case where the auxiliary protrusion 52 protrudes from the elastic partition film 15 has been described. However, the present invention is not necessarily limited to this, and the protrusion of the auxiliary protrusion 52 may be omitted. Is possible.

  In the above embodiment, in the assembled state of the partition body 12, the protrusion height is set so that the top of the displacement restricting protrusion 51 comes into contact with the displacement restricting ribs 17b and 18b in a slightly compressed state. This is not necessarily limited to this, and the height of the protrusions may be set so as to abut the displacement restricting ribs 17b and 18b without compressing the top.

  In the above-described embodiment, the elastic partition membrane 15 is vulcanized and molded, and the elastic partition membrane 15 is sandwiched between the first and second sandwiching members 17 and 18. However, the present invention is not limited to this. Of course, the elastic partition film 15 may be vulcanized and bonded to one of the first and second holding members 17 and 18.

  In each of the above embodiments, the case where the present invention is applied to a so-called single-orifice type liquid-filled vibration isolator 100 in which the first liquid chamber 11A and the second liquid chamber 11B are communicated by a single orifice 25. Although described above, the present invention is not necessarily limited to this, and it is naturally possible to apply the present invention to a so-called double orifice type liquid-filled vibration isolator.

  The double orifice type liquid-filled vibration isolator includes a main liquid chamber, two first and second sub liquid chambers, and the first and second sub liquid chambers and the main liquid chamber, respectively. It is configured to include two first and second orifices that communicate with each other.

1 is a cross-sectional view of a liquid-filled vibration isolator in one embodiment of the present invention. (A) is a top view of an orifice member, (b) is a side view of an orifice member. (A) is a bottom view of the orifice member, and (b) is a cross-sectional view of the orifice member taken along line IIIb-IIIb in FIG. 2 (a). (A) is a top view of a 2nd clamping member, (b) is sectional drawing of the 2nd clamping member in the IVb-IVb line | wire of Fig.4 (a). (A) is a top view of an elastic partition membrane, (b) is a bottom view of the elastic partition membrane. (A) is sectional drawing of the elastic partition film in the VIa-VIa line of Fig.5 (a), (b) is sectional drawing of the elastic partition film in the VIb-VIb line of Fig.5 (a). (A) is a top view of a partition body, (b) is sectional drawing of the partition body in the VIIb-VIIb line | wire of Fig.7 (a). It is sectional drawing of the partition body in the VIII-VIII line of FIG.

Explanation of symbols

100 Liquid-sealed vibration isolator 1 First mounting bracket (first mounting bracket)
2 Second mounting bracket (second mounting bracket)
3 Anti-vibration base body 8 Liquid enclosure chamber 11A First liquid chamber 11B Second liquid chamber 9 Diaphragm 12 Partition body (partition means)
15 Elastic partition membrane 50 Main body membrane portion 51 Displacement restricting projection 52 Auxiliary projection 54 Recess 16 Orifice member (tubular member)
56 convex part 17 1st clamping member (one of a pair of clamping members)
17a opening 17b displacement regulating rib 18 second clamping member (the other of the pair of clamping members)
59 Recess 18a Opening 18b Displacement restricting rib 25 Orifice Wr1 Projection width Wr2 on the top side of the displacement restricting protrusion Protrusion width on the base side of the displacement restricting protrusion

Claims (4)

A first mounting tool, a cylindrical second mounting tool, a vibration isolating base that connects the second mounting tool and the first mounting tool and is formed of a rubber-like elastic body, and the second mounting tool. A diaphragm which is attached and forms a liquid enclosure chamber with the vibration isolating substrate; and a partitioning means for partitioning the liquid enclosure chamber into a first liquid chamber on the vibration isolating substrate side and a second liquid chamber on the diaphragm side And an orifice for communicating the first liquid chamber and the second liquid chamber,
A pair of the partitioning means for restricting displacement of the elastic partition film housed in the tubular member from both sides, an elastic partition film composed of a rubber-like elastic body, a tubular member housing the elastic partition film, A liquid-filled vibration isolator configured to include a holding member of
Each of the pair of clamping members includes an opening formed in a substantially circular shape, and four displacement regulating ribs extending radially from the center of the opening toward the peripheral edge of the opening. And each of these displacement regulating ribs is arranged at substantially equal intervals in the circumferential direction,
One clamping member of the pair of clamping members is integrally formed on the inner peripheral surface side of the cylindrical member, and the other clamping member is press-fitted on the inner peripheral surface side of the cylindrical member,
The elastic partition membrane radiates from a main body film portion formed in a substantially disk shape having a larger diameter than the opening of the clamping member, and from a substantially central portion of the main body film portion toward a peripheral portion of the main body film portion. And four displacement restricting protrusions that extend in a straight line and project on each side of the main body film part, and the displacement restricting protrusions are arranged at substantially equal intervals in the circumferential direction.
The displacement restricting protrusion is set to a height dimension that allows the top portion to abut against the displacement restricting rib, the protrusion width on the top side is narrower or substantially equal to the protrusion width on the base side, and , The protrusion width on the base side is formed wider than the rib width of the displacement regulating rib,
In the assembled state of the partition means, the peripheral edge portion of the main body film portion is held and held from both sides by the holding member over the entire circumference, and the displacement restricting projections are located at positions corresponding to the displacement restricting ribs. A liquid-filled vibration isolator characterized by being arranged respectively.   The liquid-filled vibration isolator according to claim 1, wherein the displacement restricting protrusion has a protrusion width on the top side wider than a rib width of the displacement restricting rib. The cylindrical member includes a convex portion projecting to the inner peripheral surface side, and the elastic partition film and the other clamping member are formed by notching an outer peripheral edge thereof and can be fitted to the convex portion. With a recess,
In the assembled state of the partition means, the protrusions are fitted into the recesses, whereby the relative rotational direction positions of the pair of sandwiching members and the elastic partition film are positioned, and the displacement restricting projections The liquid-filled type vibration damping device according to claim 1, wherein each is disposed at a position corresponding to each of the displacement regulating ribs.   At least one surface side of the main body film portion is provided with an auxiliary protrusion protruding from the remaining portion where the displacement restricting protrusion is protruded, and the auxiliary protrusion has a protrusion height lower than at least the displacement restricting protrusion, and the protrusion 4. The liquid filled type vibration damping device according to claim 1, wherein the liquid filled type vibration damping device is configured to be narrow.

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