JP2006207629A - Vibration control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To effectively absorb input vibration by vibration of a movable plate arranged in a partitioning member for partitioning a main liquid chamber and an auxiliary liquid chamber from each other and prevent occurrence of abnormal sound due to collision of the movable plate and the partitioning member when inputting vibration having predetermined frequency. <P>SOLUTION: Since the whole movable plate 92 comes into contact with a top plate part 77 after only a part on one end side in the radial direction of the movable plate 92 comes into contact with the top plate part 77 at initial abutting time when the movable plate 92 vibrates in a storage chamber 80 when inputting vibration into an inner cylinder fitting 12 or an outer cylinder fitting 14 of the vibration control device 10 and the movable plate 92 is abutted on the top plate part 77 in synchronization with the input vibration, it is possible to let kinetic energy that the movable plate 92 has act on the top plate part 77 while dispersing it in time series over the whole period from the initial abutting time of the movable plate 92 on the top plate part 77 to the time of abutting completion when the movable plate 92 collides against the top plate part 77. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a vibration isolator that is applied to, for example, automobiles and general industrial machines and absorbs and attenuates vibrations transmitted from a vibration generating unit such as an engine to a vibration receiving unit such as a vehicle body.

  In an automobile, an engine mount as a vibration isolator is usually disposed between the engine and the vehicle body (frame). This engine mount absorbs vibration energy by elastic deformation of a rubber elastic body, thereby attenuating vibration from the engine and suppressing vibration transmission to the frame. In addition, as such an engine mount, there is a so-called liquid-sealed type equipped with a main liquid chamber, a secondary liquid chamber, and an orifice for connecting these liquid chambers inside, and in this liquid-filled engine mount, When the vibration is input, the liquid is circulated between the main liquid chamber and the sub liquid chamber through the orifice, and the resonance phenomenon (liquid column resonance) of the liquid is generated in the orifice, thereby damping the vibration of the elastic body itself. In addition, vibration can be effectively damped and absorbed by the viscous resistance of the liquid.

  As an example of the above-described liquid-filled vibration isolator, there is a liquid-filled mount device disclosed in Patent Document 1, for example. In the mounting device disclosed in Patent Document 1, a liquid chamber space sealed from the outside is formed by an outer cylinder, a rubber elastic body, and a diaphragm. The main liquid chamber is partly divided into a sub liquid chamber having a diaphragm as a part of the partition wall, and the main liquid chamber and the sub liquid chamber are connected by an orifice which is a restriction passage.

  Here, the main liquid chamber, the sub liquid chamber and the orifice are filled with a liquid such as ethylene glycol or silicon oil. The partition member is provided with an orifice which is a restricting passage for communicating the main liquid chamber and the sub liquid chamber on the outer peripheral side, and a storage chamber which is a cylindrical space on the inner peripheral side thereof. The internal space of the storage chamber communicates with the main liquid chamber and the sub liquid chamber through openings formed in the bottom plate portion and the top plate portion of the partition member, respectively. A disc-shaped movable plate is accommodated in the storage chamber, and this movable plate can vibrate within a predetermined amplitude (movable range) along the amplitude direction of the input vibration in the storage chamber.

  In the vibration isolator configured as described above, the elastic body, which is the main body of vibration absorption, is elastically deformed when vibration is input, so that vibration is attenuated and absorbed by the vibration absorbing action of the elastic body. At this time, when the frequency of the input vibration is lower than a predetermined value and the amplitude of the input vibration is equal to or greater than the movable range of the movable plate, the movable plate is in close contact with the peripheral edge of the opening of the partition member when the vibration is input. Therefore, the liquid does not substantially flow between the main liquid chamber and the sub liquid chamber through the storage chamber, and the liquid flows between the main liquid chamber and the sub liquid chamber only through the orifice. As a result, a resonance phenomenon (liquid column resonance) occurs in the liquid flowing through the orifice, so that the input vibration can be effectively damped by the action of the liquid column resonance.

On the other hand, in the vibration isolator as described above, when the frequency of the input vibration is high frequency vibration higher than a predetermined value and the amplitude of the input vibration is smaller than the movable range of the movable plate, the orifice is clogged. This makes it difficult for the liquid to flow into the orifice, but the movable plate vibrates in synchronization with the input vibration in the storage chamber, so that the liquid flows through the storage chamber between the main liquid chamber and the sub liquid chamber. The increase of the dynamic spring constant accompanying the increase of the hydraulic pressure in the main liquid chamber can be suppressed, and the dynamic spring constant of the elastic body can be kept low even when such high frequency vibration is input, and the elastic body can be elastically deformed, etc. Vibration can be absorbed effectively.
JP-A-1-193425

  However, in the vibration isolator as described above, the movable plate vibrates along the amplitude direction of the input vibration when high-frequency vibration is input, and the input plate vibrates in the bottom plate portion and the top plate portion facing each other along the amplitude direction of the partition member. Collide alternately with a period corresponding to the frequency of. Thereby, in a vehicle to which the above-described vibration isolator is applied, when the hitting sound resulting from the collision between the movable plate and the partition member in the vibration isolator is input with high-frequency vibration, specifically, for example, It may occur during idling or just after getting over the protrusion, and this hitting sound may be transmitted as abnormal noise through the vehicle body.

  The object of the present invention is to take account of the above facts when the vibration having a predetermined frequency is input by the vibration of the movable plate arranged in the partition member that divides the main liquid chamber and the sub liquid chamber. It is an object of the present invention to provide a vibration isolator capable of effectively absorbing vibration and preventing abnormal noise caused by the collision between the movable plate and the partition member.

  In order to solve the above-described problem, a vibration isolator according to claim 1 of the present invention includes a first mounting member connected to one of the vibration generating unit and the vibration receiving unit, and the other of the vibration generating unit and the vibration receiving unit. A second mounting member to be connected, an elastic body arranged between the first mounting member and the second mounting member, and a liquid are sealed, and the elastic body is used as a part of the partition wall to A main liquid chamber whose internal volume changes with deformation of the body, a liquid is enclosed, and at least a part of the partition wall is formed by a diaphragm, and the internal volume can be expanded and contracted by the diaphragm; Partitioning between the main liquid chamber and the sub liquid chamber, a partition member provided with a hollow storage chamber inside, and a bottom surface and a top surface in the storage chamber, respectively, and opening the storage chamber First and second openings communicating with the main liquid chamber and the sub liquid chamber And a restriction passage that allows the liquid to flow between the main liquid chamber and the sub liquid chamber, and the main liquid chamber and the sub liquid chamber to communicate with each other, and the storage chamber. A gap having a predetermined size is formed between the bottom surface portion and the top surface portion in the storage chamber, and the front surface portion and the back surface portion are bottom surfaces in the storage chamber in synchronization with the input vibration to the first or second mounting member. And a movable plate that is brought into contact with and away from the top surface portion, and an interval along the amplitude direction from the surface portion of the movable plate to the bottom surface portion of the storage chamber is set at a distance of the movable plate. While continuously increasing from one end side to the other end side along the radial direction, the interval along the amplitude direction from the back surface portion of the movable plate to the top surface portion of the storage chamber is set to the diameter of the movable plate. It is characterized by being continuously reduced from one end side along the direction to the other end side.

  In the vibration isolator according to the first aspect, when the elastic body is elastically deformed when vibration is input, the vibration is attenuated and absorbed by the elastic body, and the amplitude that changes according to the frequency of the input vibration is greater than or equal to a predetermined value. The movable plate is in a state of being in close contact with the bottom surface portion and the top surface portion in the storage chamber of the partition member, and the liquid substantially flows between the main liquid chamber and the sub liquid chamber through the storage chamber. Since the liquid flows between the main liquid chamber and the sub liquid chamber only through the restriction passage, a resonance phenomenon (liquid column resonance) occurs in the liquid flowing through the restriction passage. The action can effectively attenuate the input vibration.

  Further, in the vibration isolator according to the first aspect, when the amplitude that changes according to the frequency of the input vibration is smaller than the predetermined value, the restriction passage is clogged and liquid does not easily flow through the restriction passage. Since the plate vibrates in synchronization with the input vibration in the storage chamber, liquid can flow into and out of the storage chamber through the first opening and the second opening. Because the liquid flows between the main liquid chamber and the sub liquid chamber, the increase of the dynamic spring constant associated with the increase of the liquid pressure in the main liquid chamber can be suppressed. Also, the dynamic spring constant of the elastic body is kept low, and vibrations can be effectively absorbed by elastic deformation of the elastic body.

  In the vibration isolator according to claim 1, the interval along the amplitude direction from the surface portion of the movable plate to the bottom surface portion of the storage chamber is directed from one end side to the other end side along the radial direction of the movable plate. By continuously increasing, the movable plate vibrates in the storage chamber at the time of vibration input to the first or second mounting member, and in synchronization with this input vibration, the movable plate abuts against the bottom surface portion in the storage chamber ( When a collision occurs, only the vicinity of one end of the movable plate comes into contact with the bottom surface of the storage chamber at the initial contact, and the contact area of the movable plate with the bottom surface of the storage chamber is changed from one end to the other side. When the abutment is completed, the entire movable plate comes into contact with the bottom surface in the storage chamber, so when the movable plate collides with the bottom surface in the storage chamber, the movement of the movable plate Energy from the initial contact point to the bottom of the movable plate until the contact point While time series dispersed throughout between, it can be applied to the bottom portion of the storage room.

  As a result, the distance from the movable plate to the bottom surface of the storage chamber is constant at an arbitrary site, and the entire movable plate contacts the bottom surface of the storage chamber within a very short time (instantaneously) during vibration input. Compared with the vibration device, the impact force generated between the movable plate and the bottom surface can be effectively reduced at the moment when the one end of the movable plate contacts the bottom surface of the storage chamber. Since the impact force generated during the period from the contact to the bottom surface to the entire movable plate can be maintained at a sufficiently low level, the movable plate vibrates in the storage chamber when vibration is input to the first or second mounting member. In addition, it is possible to effectively reduce the hitting sound generated when the movable plate comes into contact with the bottom surface of the storage chamber in synchronization with this vibration.

  Furthermore, in the vibration isolator according to claim 1, the interval along the amplitude direction from the back surface portion of the movable plate to the top surface portion of the storage chamber is directed from one end side to the other end side along the radial direction of the movable plate. Due to the continuous reduction, the movable plate and the top surface portion are brought into contact with the top surface portion of the storage chamber at the moment when the other end portion of the movable plate contacts the top surface portion of the storage chamber, as in the case where the movable plate contacts the bottom surface portion of the storage chamber. Since the impact force generated between the other end of the movable plate contacts the top surface portion and the impact plate generated during the period from the time when the entire movable plate contacts the top surface portion can be maintained at a sufficiently low level, When the vibration is input to the first or second mounting member, the movable plate vibrates in the storage chamber, and the sound generated when the movable plate comes into contact with the top surface portion of the storage chamber in synchronization with the vibration can be effectively reduced. .

  The vibration isolator according to claim 2 of the present invention is the vibration isolator according to claim 1, wherein the movable plate is spaced from the surface portion of the movable plate to the bottom surface portion of the storage chamber along the amplitude direction. Is continuously increased from one end side to the other end side along the radial direction, and the interval along the amplitude direction from the back surface portion of the movable plate to the top surface portion portion of the storage chamber is along the radial direction. It is characterized in that it is stored in the storage chamber while being held in an elastically deformed state so as to continuously shrink from one end side to the other end side.

  The vibration isolator according to claim 3 of the present invention is the vibration isolator according to claim 1 or 2, wherein a plurality of concave or convex dimple portions are respectively formed on the front surface portion and the back surface portion of the movable plate, The dimple portion is arranged so as to be separated from the outer peripheral end of the movable plate toward the inner peripheral side.

  A vibration isolator according to claim 4 of the present invention is the vibration isolator according to claim 1, 2, or 3, wherein the first and The rib-like seal projections projecting toward the two opening portions are integrally formed.

  A vibration isolator according to claim 5 of the present invention is the vibration isolator according to any one of claims 1 to 4, wherein each of the bottom surface and the top surface in the storage chamber has a thin plate shape having viscoelasticity. A cushioning material is pasted.

  The vibration isolator according to claim 6 of the present invention is the vibration isolator according to claim 5, wherein the shock absorber attached to at least one of the bottom surface portion and the top surface portion in the storage chamber is concave or convex. A plurality of dimple portions are formed.

  As described above, according to the vibration isolator of the present invention, when a vibration having a predetermined frequency is input, the movable plate arranged in the partition member that partitions the main liquid chamber and the sub liquid chamber vibrates. Therefore, it is possible to effectively absorb the input vibration and to prevent the generation of noise due to the collision between the movable plate and the partition member.

  Hereinafter, a vibration isolator according to an embodiment of the present invention will be described with reference to the drawings.

(Configuration of the embodiment)
FIG. 1 shows a vibration isolator according to an embodiment of the present invention. The vibration isolator 10 is applied as an engine mount that supports an engine that is a vibration generating unit in an automobile on a vehicle body that is a vibration receiving unit. 1 indicates the axis of the apparatus, and the following description will be given with the direction along the axis S as the axial direction of the apparatus.

  As shown in FIG. 1, the vibration isolator 10 is disposed substantially coaxially on the inner cylinder fitting 12 formed in a substantially thick cylindrical shape connected to the engine side and on the outer peripheral side of the inner cylinder fitting 12. A substantially cylindrical outer cylinder fitting 14 connected to the vehicle body side, and a rubber elastic body 16 which is disposed between the inner cylinder fitting 12 and the outer cylinder fitting 14 and serves as a main vibration absorber. The inner cylinder fitting 12 has an upper end inserted into the outer cylinder fitting 14 and a lower end protruding through the opening on the lower end side of the outer cylinder fitting 14 to the lower side of the outer cylinder fitting 14. The outer tube fitting 14 is formed with an enlarged diameter portion 20 having a diameter larger than that of the lower end portion at the upper end portion with respect to the step portion 18 provided at the axially intermediate portion thereof. In addition, the outer cylindrical metal fitting 14 is formed with a tapered portion 22 whose diameter is tapered downward at the lower end portion thereof, and is caulked at the upper end portion of the enlarged diameter portion 20 toward the inner peripheral side when the apparatus is assembled. A caulking portion 24 to be formed is formed.

  The vibration isolator 10 includes a substantially cup-shaped connecting tube 26 in which the lower end side of the outer tube fitting 14 is fitted and fixed, and a substantially bottomed cylindrical holder fitting 28 in which the lower end side of the connecting tube 26 is fitted and fixed. Is provided. The outer cylinder fitting 14 is inserted into the connecting cylinder 26 until the lower end thereof is in contact with the bottom plate portion of the connecting cylinder 26. In addition, a plurality of leg portions 30 are fixed to the outer peripheral surface of the holder fitting 28 by welding or the like, and a holder (not shown) is inserted through a connecting hole 32 formed on the distal end side of the leg portion 30. The metal fitting 28 is fastened and fixed to the vehicle body side. As a result, the outer cylinder fitting 14 is connected and fixed to the vehicle body via the connection cylinder 26 and the holder fitting 28.

  The lower end side of the inner cylinder fitting 12 protrudes to the lower side of the connection cylinder 26 through an opening 27 formed in the bottom plate portion of the connection cylinder 26, and the lower end portion of the inner cylinder fitting 12 is connected to the engine by a bolt 34. The base end portion of the bracket 36 is fastened and fixed. The bracket 36 extends to the outer peripheral side through an opening (not shown) formed in the side surface portion of the holder metal 28, and an engine (not shown) is fastened and fixed to the front end side of the bracket 36 by a bolt or the like. Is done. Further, a stopper rubber 38 formed in a substantially rectangular tube shape is covered on the base end portion of the bracket 36, and the upper surface portion of the stopper rubber 38 is in pressure contact with the bottom plate portion of the connecting cylinder 26. Thereby, an excessive displacement along the axial direction of the bracket 36 is prevented, and generation of a loud collision sound is prevented even when the bracket 36 collides with the connecting cylinder 26 or the holder fitting 28 due to an input of a large load. .

  A bottom plate portion of an extension fitting 40 formed in a substantially cup shape that opens upward is fixed to the upper end surface of the inner cylinder fitting 12 by welding or the like. The extension fitting 40 has a tapered shape whose side plate portion is enlarged in diameter from the bottom plate side toward the upper end side, and a ring-shaped flange member 42 is fixed to the upper end portion of the side plate portion by welding or the like. It extends from the upper end of the extension fitting 40 to the inner peripheral side. In addition, a plurality of runner holes 44 for filling the extension metal fitting 40 with vulcanized rubber which is a molding material of the elastic body 16 are formed in the side plate portion of the extension metal fitting 40.

  The elastic body 16 is vulcanized and bonded to the upper end side of the inner cylinder fitting 12 inserted into the outer cylinder fitting 14 and the extension fitting 40, and is vulcanized and bonded to the lower end side of the outer cylinder fitting 14, The tube fitting 12 and the outer tube fitting 14 are connected elastically. Here, the elastic body 16 is vulcanized and bonded to the outer peripheral surface of the inner cylindrical metal member 12 and the outer peripheral surface of the extension metal member 40, and filled into the inner peripheral side of the extension metal member 40 through the runner hole 44. The inner peripheral surface and bottom surface of the metal fitting 40 and the lower surface of the flange member 42 are also vulcanized and bonded. Further, the elastic body 16 is integrally formed with a thin covering portion 46 extending upward from the outer peripheral portion, and this covering portion 46 is vulcanized on the upper end side on the inner peripheral surface of the outer cylinder fitting 14. It is bonded and covers the inner peripheral surface of the outer cylinder fitting 14.

  A partition member 48 that is formed in a substantially disc shape as a whole and a substantially hat-shaped lid member 50 that is in close contact with the upper surface portion of the partition member 48 are inserted into the outer cylindrical member 14 above the step portion 18. The outer peripheral portion of the lower surface of the partition member 48 is in contact with the step portion 18 through the covering portion 46. A ring-shaped support cylinder 52 is fitted into the outer cylinder fitting 14 above the partition member 48 and the lid fitting 50, and the lower end portion of the support cylinder 52 abuts on the outer periphery of the lid fitting 50. Yes. In the outer cylinder fitting 14 into which the partition member 48, the lid fitting 50 and the support cylinder 52 are inserted, the caulking portion 24 is caulked in a tapered shape toward the inner peripheral side. Thereby, the partition member 48, the lid fitting 50 and the support cylinder 52 are fixed between the stepped portion 18 and the caulking portion 24 in the outer cylinder fitting 14. Here, an outer peripheral portion of a rubber diaphragm 54 formed in a convex cup shape on the inner peripheral surface of the support cylinder 52 is vulcanized and bonded over the entire periphery.

  In the vibration isolator 10, a space (liquid chamber space) sealed from the outside is formed by the outer cylinder fitting 14, the elastic body 16, and the diaphragm 54. The liquid chamber space includes the partition member 48 and the lid fitting 50. Thus, the main liquid chamber 56 having the elastic body 16 as a part of the partition and a sub liquid chamber 58 having the diaphragm 54 as a part of the partition are partitioned. In the vibration isolator 10, the outside of the diaphragm 54 that forms a part of the partition wall of the sub liquid chamber 58 is an atmospheric space, so that the diaphragm 54 responds to changes in the liquid pressure in the sub liquid chamber 58. The liquid chamber 58 is elastically deformable so as to expand and contract the internal volume. The main volume of the main liquid chamber 56 expands and contracts with the elastic deformation of the elastic body 16.

  The partition member 48 is provided with a concave groove 60 extending in the circumferential direction on the outer peripheral surface thereof. As shown in FIG. 2, the groove portion 60 extends along the circumferential direction centering on the axis S, and the partition member 48 has a lower side of the groove portion 60 extending downward from one end portion of the groove portion 60. The communication port 62 is formed by being cut out, and the communication port 64 is formed by cutting the upper side of the groove portion 60 upward from the other end of the groove portion 60. As shown in FIG. 1, the groove portion 60 is closed on the outer peripheral side thereof by the inner peripheral surface of the outer cylinder fitting 14 via the covering portion 46, thereby restricting the communication between the main liquid chamber 56 and the sub liquid chamber 58. An orifice 66 which is a passage is formed.

  Here, the main liquid chamber 56, the sub liquid chamber 58, and the orifice 66 are filled with a liquid such as water, ethylene glycol, or silicone oil, and the liquid passes through the orifice 66 and the main liquid chamber 56 and the sub liquid chamber 58. It is possible to circulate between. The orifice 66 is set (tuned) so that its path length and cross-sectional area match the amplitude and frequency of the shake vibration.

  As shown in FIG. 4, a rubber cushioning material 68 formed in the shape of a thin disk is attached to the center of the upper surface of the partition member 48, and a lid fitting 50 is attached to the outer peripheral side of the cushioning material 68. A plurality (six in this embodiment) of positioning protrusions 70 projecting to the side are provided. Further, the partition member 48 is formed with a circular concave relief portion 72 having a diameter larger than that of the cushioning material 68 at the center of the lower surface thereof. As a result, the partition member 48 is formed with a bottom plate portion 74 having a substantially constant thickness at the upper portion of the relief portion 72 and having the cushioning material 68 attached to the upper surface side.

  As shown in FIG. 1, the upper end portions of the extension fitting 40 and the elastic body 16 are inserted into the escape portion 72 while leaving a gap with the bottom plate portion 74 along the axial direction. Here, the gap between the bottom plate portion 74, the extension fitting 40, and the elastic body 16 is such that the engine is coupled to the bracket 36, and the load caused by the weight of the engine is applied to the bracket 36, as compared to the illustrated state. Therefore, even if vibration is input, the extension fitting 40 and the elastic body 16 do not contact the bottom plate portion 74.

  As shown in FIG. 5, the lid fitting 50 is formed with a circular convex holder portion 76 projecting toward the secondary liquid chamber 58 at the center portion facing the bottom plate portion 74 of the partition member 48. An annular flange portion 78 extending from the lower end portion of the portion 76 to the outer peripheral side is integrally formed. A plurality of positioning holes 79 corresponding to the plurality of positioning protrusions 70 in the partition member 48 are formed in the flange portion 78.

  In the vibration isolator 10, the lid fitting 50 brings the flange portion 78 into contact with the outer peripheral portion of the upper surface of the partition member 48, and the partition member 48 inserts the positioning projection 70 into the positioning hole 79 of the lid fitting 50. . In this state, the lid fitting 50 is fixed to the partition member 48 by caulking the tip end portion of the positioning projection 70 protruding from the positioning hole 79.

  By fixing the lid member 50 to the partition member 48, as shown in FIG. 3, the main liquid chamber 56 and the auxiliary liquid chamber are provided between the bottom plate portion 74 of the partition member 48 and the holder portion 76 of the lid member 50. A storage chamber 80, which is a space partitioned from 58, is formed. Here, the top plate portion 77 which is a partition wall portion on the upper end side of the holder portion 76 is parallel to the bottom plate portion 74 of the partition member 48, so that the wall thickness along the axial direction of the storage chamber 80 is the diameter. It is substantially constant at any part along the direction.

  A thin-walled rubber cushioning material 82 is attached to the top plate portion 77 of the holder portion 76 so as to cover the inner portion facing the inside of the storage chamber 80. As shown in FIG. 5B, the cushioning material 82 has a large number of convex dimple portions 84 formed on the surface thereof. These dimple portions 84 are each formed in a substantially conical shape that is flat along the height direction, and are arranged in a lattice pattern at a substantially constant pitch in a region excluding the peripheral portions of openings 88 and 89 described later.

  As shown in FIG. 2A, the lid 50 is formed with a notch 86 cut out in a substantially rectangular shape from the outer peripheral end of the flange portion 78 toward the inner peripheral side. The communication port 64 of the orifice 66 is communicated with the auxiliary liquid chamber 58 through 86. In addition, as shown in FIG. 2B, the lid 50 has a plurality of slot-like slot openings 90 (in this embodiment) extending from the inner peripheral portion toward the outer peripheral side in the top plate portion 77. 6) and circular circular openings 91 are formed between a pair of slot openings 90 adjacent to each other. The storage chamber 80 communicates with the sub liquid chamber 58 through the slot opening 90 and the circular opening 91. Here, a plurality of slot openings 90 and circular openings 91 (hereinafter collectively referred to as “openings 90, 91”) are in one direction with respect to the axis S of the apparatus (in the right direction in FIG. 2B). ) Are arranged radially (point-symmetric) around the center of opening CPu decentered by a predetermined distance.

  2C, the bottom plate portion 74 of the partition member 48 is also provided with a plurality (six) of slot openings 88 and circular openings 89 in the lid fitting 50, and these slot openings are provided. 88 and the circular opening 89 (hereinafter collectively referred to as “openings 88 and 89”) have the same shape and opening area as the openings 90 and 91 of the lid fitting 50, and the openings 90 and 91. In the same manner as described above, they are arranged radially (point-symmetrically) about the opening center CP1 decentered by a predetermined distance in the other direction (leftward in FIG. 2B) with respect to the axis S of the apparatus.

  However, the eccentric distance of the opening center CP1 from the axis S is equal to the opening center CPu of the lid fitting 50, but the eccentric direction of the opening center CPl from the axis S is opposite to the opening center CPu. That is, the openings 90 and 91 and the openings 88 and 89 are symmetrically arranged along the eccentric direction of the opening center CPl and the opening center CPu.

  As shown in FIG. 3, a rubber movable plate 92 is disposed in the storage chamber 80. As shown in FIG. 6A, the movable plate 92 is formed in a thin disk shape as a whole, and its outer diameter is slightly smaller than the inner diameter of the storage chamber 80. A substantially cylindrical fitting protrusion 98 is integrally formed on the center side of the surface portion 94 which is a lower surface portion of the movable plate 92, and the center of the fitting protrusion 98 is shown in FIGS. As shown in C), it substantially coincides with the opening center CPu of the lid fitting 50. Further, a substantially cylindrical fitting protrusion 100 is integrally formed on the center side also on the back surface portion 94 which is the upper surface portion of the movable plate 92. The center of the fitting protrusion 100 is shown in FIG. As shown in (C), it substantially coincides with the opening center CP1 of the partition member 48.

  As shown in FIG. 6, the movable plate 92 is integrally formed with a convex pressed portion 102 that extends from the vicinity of the axis S to the fitting projection 100 side on the back side on the surface portion 94. Has been. The pressed portion 102 extends to the outer peripheral side from the fitting protrusion 100 of the back surface portion 94 along the eccentric direction. Also, the movable plate 92 is integrally formed with a convex pressed portion 104 that extends from the vicinity of the axis S to the fitting projection 98 side of the back surface portion 94. The pressed portion 104 also extends to the outer peripheral side from the fitting projection 98 on the lower surface portion along the eccentric direction. On the other hand, as shown in FIG. 4A, the cushioning material 68 disposed on the bottom plate portion 74 has a pair of pressing convex portions 120 so as to face the pressed portion 102 on the surface side of the movable plate 92. As shown in FIG. 5A, the cushioning material 82 disposed on the top plate portion 77 has a pair of pressing convex portions so as to face the pressed portion 104 on the back surface side of the movable plate 92. 122 is formed.

  Here, an interval PI (see FIG. 6B) along the axial direction between the lower end surface of the pressed portion 102 and the upper end surface of the pressed portion 104 is the upper end surface of the pressing convex portion 120 and the pressing convex portion 122. It is longer by a predetermined length than the interval along the axial direction with the lower end surface.

  The movable plate 92 has a plurality of convex dimple portions 106 formed on the front surface portion 94 and the back surface portion 94 thereof. Similar to the dimple portion 84 of the cushioning material 82, these dimple portions 106 are each formed in a substantially conical shape that is flat along the height direction, and the fitting protrusions 98, 100 and the pressed portion on the movable plate 92 are formed. 102 and 104 and the region excluding the outer peripheral edge are arranged in a lattice pattern at a substantially constant pitch. Further, the movable plate 92 is integrally formed with a rib-like seal projection 108 that protrudes toward the bottom plate 74 on the outer peripheral edge of the front surface portion 94, and the outer peripheral edge of the back surface portion 94. A rib-like seal projection 110 that projects toward the top plate 77 is also integrally formed over the entire circumference. The outer surfaces in the axial direction of the seal projections 108 and 110 are located substantially on the same plane as the apex portions of the dimple portions 106 formed on the front surface portion 94 and the back surface portion 94, respectively.

  The movable plate 92 has a thickness PT (see FIG. 6B) of the outer peripheral edge portion that is shorter than the dimension ST along the axial direction of the storage chamber 80 by a predetermined dimension. Specifically, for example, the difference between the thickness PT of the movable plate 92 and the thickness ST of the storage chamber 80 is shorter than the amplitude of the shake vibration that is a relatively low frequency vibration of the input vibration, and the relative In particular, it is set to be longer than the amplitude of the idle vibration that is a high-frequency vibration. Thereby, in the storage chamber 80, a gap having a width corresponding to the amplitude difference between the low frequency vibration and the high frequency vibration is formed between the movable plate 92 and the bottom plate portion 74 and the top plate portion 77 along the axial direction. .

  As shown in FIG. 2C, the movable plate 92 is a single slot opening 88 having a fitting projection 98 formed in the bottom plate portion 74 in a state where the movable plate 92 is stored in the storage chamber 80. As shown in FIG. 2 (B), the fitting protrusion 100 is inserted into one slot opening 90 formed in the top plate portion 77. At this time, the slot opening 88 into which the fitting protrusion 98 is inserted faces the opening center CPu of the top plate portion 77, and the fitting protrusion 98 has a part of the outer peripheral surface of the inner periphery of the slot opening 88. Abut against the end of the side. The slot opening 90 into which the fitting protrusion 100 is inserted is opened facing the opening center CPI of the bottom plate portion 74, and the fitting protrusion 100 has a part of the outer peripheral surface on the inner peripheral side of the slot opening 90. Touch to the end. As a result, the movable plate 92 is limited in displacement in the rotation direction within the storage chamber 80.

  Further, the movable plate 92 is pressed toward the top plate portion 77 by the pressing convex portion 120 projecting from the bottom plate portion 74 while being stored in the storage chamber 80 as shown in FIG. The pressed portion 104 is pressed toward the bottom plate portion 74 by the pressing convex portion 122 protruding from the top plate portion 77. As a result, the movable plate 92 has a portion (curved top 112 shown in FIG. 6A) located near the extension line of the pressed portion 102 on the back surface side that extends to the outer peripheral side starting from the vicinity of the axis S. A portion that is deformed (elastically deformed) so as to be close to the top plate portion 77 and that is located near the extension line of the pressed portion 104 on the surface side that extends from the vicinity of the axis S to the outer peripheral side (FIG. The curved top 114) is elastically deformed so as to be close to the bottom plate 74. Further, the movable plate 92 is elastically deformed so that an intermediate portion along the circumferential direction between the curved top portion 112 and the curved top portion 114 is gently twisted.

  Therefore, as shown in FIG. 3, in the vibration isolator 10, the distance along the axial direction from the back surface portion 96 to the top plate portion 77 of the movable plate 92 is the narrowest at the curved top portion 112 and the widest at the curved top portion 114. Become. At this time, the thickness of the movable plate 92 including the seal projections 108 and 110 and the dimple portion 106 is constant on the outer peripheral side of the fitting projections 98 and 100 and the pressed portions 102 and 104. The distance along the axial direction from the surface portion 94 to the bottom plate portion 74 is the reverse of the surface portion 94 and becomes the largest at the curved top portion 112 and the narrowest at the curved top portion 114.

Here, as shown in FIG. 3, the distance from the curved top portion 112 to the top plate portion 77 and the distance from the curved top portion 114 to the bottom plate portion 74 are D _MIN , respectively, and the distance from the curved top portion 112 to the bottom plate portion 74 is curved Assuming that the distances from the top 114 to the top plate 77 are D _MAX , the D _MIN and D _MAX change their appropriate values depending on the rigidity of the elastic body 16 and the magnitude of the load applied from the outside. It is necessary to change the setting according to the matter.

(Operation of the embodiment)
Next, the operation of the vibration isolator 10 according to the embodiment of the present invention configured as described above will be described.

  In the vibration isolator 10 according to the present embodiment, when the vibration is input from the engine or the vehicle body side, the elastic body 16 is elastically deformed and the hydraulic pressure in the main liquid chamber 56 is changed in synchronization with the vibration input. Along with this change in liquid pressure, the liquid flows between the main liquid chamber 56 and the sub liquid chamber 58 through the orifice 66, and the movable plate 92 stored in the storage chamber 80 communicating with the main liquid chamber 56. The fluid pressure (pressure wave) that periodically changes in synchronization with the input vibration acts. As a result, the fitting protrusions 98 and 100 of the movable plate 92 and the outer peripheral portions of the pressed parts 102 and 104 are bent upward and downward along the axial direction in synchronization with the change in the hydraulic pressure in the main liquid chamber 56. The operation of abutting and separating from the bottom plate portion 74 of the partition member 48 and the top plate portion 77 of the lid fitting 50 is repeated at a period corresponding to the frequency of the input vibration.

  In the vibration isolator 10, as described above, when the movable plate 92 bends and deforms downward due to a change in the hydraulic pressure in the main liquid chamber 56 and comes into contact with the bottom plate portion 74, the surface plate 94 of the movable plate 92 causes the bottom plate portion 74 to contact the bottom plate portion 74. When the openings 88 and 89 to be opened are closed and the movable plate 92 is separated upward from the bottom plate portion 74, the openings 88 and 89 are opened. Further, in the vibration isolator 10, when the movable plate 92 is bent upward and deformed due to a change in the hydraulic pressure in the main liquid chamber 56 and comes into contact with the top plate portion 77, the opening that opens to the top plate portion 77 by the back surface portion 94 of the movable plate 92. When 90 and 91 are closed and the movable plate 92 is spaced downward from the top plate portion 77, the openings 90 and 91 are opened. In the vibration isolator 10, when one of the openings 88 and 89 and the openings 90 and 91 is closed by the movable plate 92, the liquid flows through the storage chamber 80 between the main liquid chamber 56 and the sub liquid chamber 58. Is substantially prevented.

  At this time, in the vibration isolator 10, the seal projections 108 and 110 are formed on the front surface portion 94 and the back surface portion 94 of the movable plate 92, respectively, so that the movable plate 92 contacts the bottom plate portion 74 and the top plate portion 77. In this case, the front end surfaces of the seal projections 108 and 110 arranged along the outer peripheral edge of the movable plate 92 are in close contact with the outer peripheral portions of the bottom plate portion 74 and the top plate portion 77, respectively, and the entire movable plate 92 is Compared with the case where the bottom plate portion 74 and the top plate portion 77 are pressed against each other, the pressure contact force (surface pressure) when the seal protrusions 108 and 110 are pressed against the outer peripheral portions of the bottom plate portion 74 and the top plate portion 77 can be increased. The sealing performance with respect to the openings 88 and 89 by the movable plate 92 when the 92 abuts against the bottom plate portion 74 can be improved, and the seal against the openings 90 and 91 with the movable plate 92 when the movable plate 92 abuts against the top plate portion 77. It can improve the sex.

  In the vibration isolator 10, basically, the elastic body 16 that is the main body of vibration absorption is elastically deformed when vibration is input, so that the vibration is attenuated and absorbed by the vibration absorbing action of the elastic body 16 itself.

  Further, in the vibration isolator 10, when the amplitude of vibration that changes according to the frequency of the input vibration is equal to or greater than a predetermined value, the movable plate 92 is alternately placed on the bottom plate portion 74 of the partition member 48 and the top plate portion 77 of the lid fitting 50. The liquid does not substantially flow between the main liquid chamber and the sub liquid chamber through the storage chamber 80 in the close contact state, and the main liquid chamber 56 and the sub liquid chamber 58 are only passed through the orifice 66. Liquid flows between each other.

  Specifically, in the vibration isolator 10, when the frequency of the input vibration is equal to or less than the frequency of the shake vibration (for example, 8 to 12 Hz) and the amplitude is large (for example, about 0.5 mm to 1 mm), The movable plate 92 is brought into close contact with one of the bottom plate portion 74 of the partition member 48 and the top plate portion 77 of the lid fitting 50, and one of the openings 88 and 89 and the openings 90 and 91 is closed. Thus, when shake vibration is input, the liquid does not substantially flow between the main liquid chamber 56 and the sub liquid chamber 58 through the storage chamber 80, and the main liquid chamber 56 and the sub liquid chamber 56 are connected only through the orifice 66. Liquid flows between the liquid chamber 58 and each other. Here, the orifice 66 is tuned so that its path length and cross-sectional area are adapted to shake vibration. As a result, in the vibration isolator 10, when the input vibration is particularly shake vibration, a resonance phenomenon (liquid column resonance) occurs in the liquid flowing through the orifice 66, and the input vibration is effectively reduced by the action of the liquid column resonance. Can be attenuated.

  In the vibration isolator 10, when the frequency of the input vibration is higher than the frequency of the shake vibration and the amplitude is small, for example, the input vibration is idle vibration (for example, 20 to 30 Hz) and the amplitude is 0.1 mm to 0. In the case of about 2 mm, the orifice 66 tuned to match the shake vibration becomes clogged, and it becomes difficult for the liquid to flow through the orifice 66, but the movable plate 92 is synchronized with the input vibration in the storage chamber 80. By vibrating up and down, a gap is formed between the movable plate 92 and the bottom plate portion 74 and the top plate portion 77 at the time of vibration input, so that the openings 88 and 89, the storage chamber 80 and the openings 90 and 91 pass through. Since the liquid flows between the main liquid chamber 56 and the sub liquid chamber 58, an increase in the dynamic spring constant accompanying an increase in the liquid pressure in the main liquid chamber 56 can be suppressed, and such a high-frequency vibration can be achieved. Even maintaining the dynamic spring constant of the elastic body 16 low input, can frequency vibration effectively absorbing idle vibration or the like by an elastic deformation of the elastic body 16.

  Further, in the vibration isolator 10, the distance along the axial direction from the back surface portion 96 to the top plate portion 77 of the movable plate 92 is the narrowest at the one curved top portion 112 and the widest at the other curved top portion 114. When the movable plate 92 vibrates in the storage chamber 80 when vibration is input to the tube fitting 12 or the outer tube fitting 14, and the movable plate 92 contacts (collises) with the top plate portion 77 in synchronization with the input vibration, After only one curved top portion 112 of the movable plate 92 contacts the top plate portion 77 at the time of the initial contact, the contact area of the movable plate 92 with the top plate portion 77 moves from one curved top portion 112 to the other curved top portion 114 side. When the movable plate 92 collides with the top plate portion 77, the kinetic energy of the movable plate 92 is reduced when the movable plate 92 collides with the top plate portion 77. Initial contact of movable plate 92 with top plate 77 While time series dispersed throughout the period up to the time of contact completion from the time, it can be applied to the top plate portion 77.

  As a result, the distance from the surface portion of the movable plate to the top surface portion of the storage chamber is constant at any part, and the entire movable plate contacts the bottom surface portion of the storage chamber within a very short time (instantaneously) when vibration is input. Compared with the conventional vibration isolator, the impact force generated between the movable plate 92 and the bottom plate portion 74 at the moment when one curved top portion 112 of the movable plate 92 contacts the top plate portion 77 can be effectively reduced, and The impact force generated during the period from when the curved top portion 112 of the movable plate 92 contacts the top plate portion 77 to when the entire movable plate 92 contacts the top plate portion 77 can be maintained at a sufficiently low level, or the generation of the impact force can be prevented. The movable plate 92 vibrates in the storage chamber 80 when vibration is input to the inner tube fitting 12 or the outer tube fitting 14, and the sound generated by the movable plate 92 coming into contact with the top plate portion 77 in synchronism with this vibration is effective. Can be reduced.

  Further, in the vibration isolator 10, the distance along the axial direction from the surface portion 94 to the bottom plate portion 74 of the movable plate 92 is the smallest at the other curved top portion 114 and the largest at the one curved top portion 112. Similarly to the case where the plate 92 abuts against the top plate portion 77, the impact force generated between the movable plate 92 and the bottom plate portion 74 at the moment when the other curved top portion 114 of the movable plate 92 abuts against the bottom plate portion 74 is effective. The impact force generated during the period from when the other curved top portion 114 of the movable plate 92 contacts the bottom plate portion 74 until the entire movable plate 92 contacts the bottom plate portion 74 can also be maintained at a sufficiently low level, or the impact force Therefore, the movable plate 92 vibrates in the storage chamber 80 when a vibration is input to the inner cylinder fitting 12 or the outer cylinder fitting 14, and the movable plate 92 contacts the bottom plate portion 74 in synchronization with the vibration. Caused by The sound can be effectively reduced.

  Further, in the vibration isolator 10, the opening centers CPu of the openings 88 and 89 radially disposed on the bottom plate portion 74 shift to the curved top portion 112 side with respect to the axis S and are radially disposed on the top plate portion 77. Since the opening center CP1 of the openings 90 and 91 is shifted to the curved top 114 side with respect to the axis S, the liquid pressure in the main liquid chamber 56 is greater than the liquid pressure in the sub liquid chamber 58 at the time of vibration input. If the pressure rises, the pressure wave transmitted into the storage chamber 80 through the openings 88 and 89 preferentially acts on the portion of the movable plate 92 on the side of the curved top 112 with respect to the axis S. When the fluid pressure in the fluid chamber 58 rises higher than the fluid pressure in the main fluid chamber 56, the pressure wave transmitted through the openings 90 and 91 into the storage chamber 80 is applied to the axis S in the movable plate 92. This preferentially acts on the portion on the curved top 114 side. Here, the pressure wave acting preferentially means acting at an earlier timing in time and acting so that the intensity distribution of the pressure wave becomes higher.

  As a result, in the vibration isolator 10, the liquid pressure in the main liquid chamber 56 rises higher than the liquid pressure in the sub liquid chamber 58 when vibration is input, and the movable plate 92 contacts the top plate portion 77 in synchronization with this input vibration. At this time, it is possible to reliably generate a phenomenon in which only one of the curved top portions 112 of the movable plate 92 is brought into contact with the top plate portion 77 at the time of the initial contact, and the liquid pressure in the auxiliary liquid chamber 58 is increased when vibration is input. When the movable plate 92 comes into contact with the bottom plate portion 74 in synchronism with the input vibration and rises above the hydraulic pressure in the main liquid chamber 56, only the one curved top portion 114 of the movable plate 92 is removed from the bottom plate at the initial contact time. Since the phenomenon of abutting against the portion 74 can be generated with certainty, the impact when the movable plate 92 collides with the bottom plate portion 74 or the top plate portion 77 is compared with the case where the pressure wave acts uniformly on the entire movable plate. The effect of dispersing force in time series can be obtained more reliably, and the bay can be Since only the top 112, 114 limiting can be contacted to the top plate portion 77 and the bottom plate portion 74, the dispersion effect of the impact force can be improved.

  However, in the vibration isolator 10, since the distance from the curved top portion 112 to the top plate portion 77 is relatively short and the distance from the curved top portion 114 to the top plate portion 77 is relatively long, the entire movable plate 92 is disposed on the top plate portion 77. In order to contact the curved top portion 114, the deformation amount toward the top plate portion 77 near the curved top portion 114 must be larger than the deformation amount of the curved top portion 112.

  For this reason, only the hydraulic pressure (pressure wave) supplied from the main liquid chamber 56 through the openings 88 and 89 formed in the bottom plate portion 74 causes the deformation amount of the movable plate 92 near the curved top portion 114 to be insufficient or curved. The pressure contact force when the vicinity of the top portion 114 is in contact with the top plate portion 77 may be insufficient. Similarly, only the hydraulic pressure (pressure wave) supplied from the sub liquid chamber 58 through the openings 90 and 91 formed in the top plate portion 77 causes the deformation amount of the movable plate 92 near the curved top portion 112 to be insufficient or curved. The pressure contact force when the vicinity of the top portion 112 is in contact with the bottom plate portion 74 may be insufficient.

  Therefore, in the vibration isolator 10, as shown in FIG. 7, an auxiliary opening 116 is drilled in a portion shifted to the curved top portion 114 side with respect to the axis S of the bottom plate portion 74 as needed, and the top plate Auxiliary opening 118 is drilled as necessary in a portion shifted to the curved top portion 112 side with respect to the axis S of the portion 77, so that the liquid is supplied from the main liquid chamber 56 to the storage chamber 80 through the auxiliary opening 116. The hydraulic pressure may be directly applied to the vicinity of the curved top portion 114, and the hydraulic pressure supplied from the sub liquid chamber 58 to the storage chamber 80 through the auxiliary opening 118 may be directly applied to the vicinity of the curved top portion 112.

  In the vibration isolator 10 according to the present embodiment, the rubber cushioning materials 68 and 82 are attached to the upper surface side of the bottom plate portion 74 and the lower surface side of the top plate portion 77, respectively. Since the shock-absorbing action also reduces the impact force when the movable plate 92 abuts against the bottom plate portion 74 and the top plate portion 77, the striking caused by the movable plate 92 abutting against the bottom plate portion 74 and the top plate portion 77 during vibration input. Sound can be reduced more effectively.

  Further, in the vibration isolator 10 according to the present embodiment, a large number of dimple portions 106 are formed on the front surface portion 94 and the back surface portion 94 of the rubber movable plate 92, respectively, and the rubber-made vibration plate attached to the top plate portion 77. Since a large number of dimple portions 84 are also formed on the surface of the cushioning material 82, when the movable plate 92 abuts against the bottom plate portion 74 and the top plate portion 77 during vibration input, the dimple portion 106 and the cushioning material 82 of the movable plate 92 are provided. The dimple portions 84 partially form gaps between the surface portion 94 and the bottom plate portion 74 of the movable plate 92 and between the back surface portion 94 and the top plate portion 77 of the movable plate 92, respectively. Since the entire portion 94 is prevented from being completely adhered to the bottom plate portion 74, and the entire back surface portion 94 of the movable plate 92 is prevented from being completely adhered to the top plate portion 77, the movable plate 92 and the cushioning material 82 are prevented. Compared to the case where the dimple portions 84 and 106 are not formed, the distribution of the impact load generated when the movable plate 92 abuts against the bottom plate portion 74 and the top plate portion 77 is the distance from the dimple portions 84 and 106. The load distribution at the contact portion between the movable plate 92 and the bottom plate portion 74 and the top plate portion 77 becomes non-uniform, and the movable plate 92 does not contact the bottom plate portion 74 and the top plate portion 77 in a surface contact state. Therefore, also by the action of the dimple portions 84 and 106, the sound pressure of the hitting sound generated when the movable plate 92 collides with the bottom plate portion 74 and the top plate portion 77 at the time of vibration input can be effectively reduced.

  In the vibration isolator 10 according to the present embodiment, the convex dimple portion 106 is formed on the movable plate 92 and the convex dimple portion 84 is also formed on the cushioning material 82. Even if the dimple portion formed on one or both of the cushioning materials 82 is concave, the same functions and effects as those obtained when the convex dimple portions 84 and 106 are formed can be obtained. In addition, the dimple portion 84 is formed only on the buffer material 82 attached to the top plate portion 77 and the dimple portion is not formed on the buffer material 68 attached to the bottom plate portion 74 from the main liquid chamber 56 side. The hydraulic pressure transmitted to the movable plate 92 is higher than the hydraulic pressure transmitted to the movable plate 92 from the sub liquid chamber 58 side, and the impact force when the movable plate 92 collides with the top plate portion 77 collides with the bottom plate portion 74. This is because it is larger than the impact force. Of course, such a dimple portion may be formed in the buffer material 68 attached to the bottom plate portion 74 in addition to the buffer material 82 attached to the top plate portion 77.

It is sectional drawing which shows the structure of the vibration isolator which concerns on embodiment of this invention. It is the perspective view, top view, and bottom view which show the structure of the partition member and lid metal fitting which accommodated the movable plate shown by FIG. It is a side part figure which shows the structure of the partition member and lid metal fitting which accommodated the movable plate shown by FIG. It is the perspective view and side sectional drawing which show the structure of the partition member shown by FIG. It is the perspective view and side sectional drawing which show the structure of the cover member shown by FIG. It is the perspective view and side sectional drawing which show the structure of the movable plate shown by FIG. It is the perspective view, top view, and bottom view which show the structure at the time of adding auxiliary opening to the partition member and lid metal fitting which are shown in FIG. 1, respectively.

Explanation of symbols

10 Anti-vibration device 12 Inner tube bracket (mounting member)
14 Outer cylinder fitting (mounting member)
16 Elastic body 48 Partition member 50 Lid (partition member)
56 Main liquid chamber 58 Sub liquid chamber 66 Orifice (restricted passage)
68 Buffer material 74 Bottom plate (bottom)
77 Top plate (bottom)
80 Storage chamber 82 Buffer material 84 Dimple part 88 Slot opening (opening part)
89 Circular opening (opening)
90 slot opening (opening)
91 Circular opening (opening)
92 Movable plate 106 Dimple part 108 Seal projection part
3 110 Seal protrusion

Claims (6)

A first attachment member coupled to one of the vibration generator and the vibration receiver;
A second attachment member coupled to the other of the vibration generating portion and the vibration receiving portion;
An elastic body disposed between the first mounting member and the second mounting member;
A main liquid chamber in which a liquid is enclosed, and the internal volume changes with deformation of the elastic body with the elastic body as a part of the partition;
A liquid is enclosed, and at least a part of the partition wall is formed of a diaphragm, and the inner volume can be expanded and contracted by the diaphragm;
Partitioning between the main liquid chamber and the sub liquid chamber, and a partition member provided with a hollow storage chamber inside,
First and second openings that open to the bottom surface and the top surface of the storage chamber, respectively, and communicate the storage chamber with the main liquid chamber and the sub liquid chamber;
A restriction passage that allows the main liquid chamber and the sub liquid chamber to communicate with each other, and allows the liquid to flow between the main liquid chamber and the sub liquid chamber;
In addition to being disposed in the storage chamber, a gap of a predetermined dimension is formed between the bottom surface portion and the top surface portion in the storage chamber, and in synchronization with the input vibration to the first or second mounting member, A movable plate for moving a front surface portion and a back surface portion toward and away from a bottom surface portion and a top surface portion in the storage chamber,
The distance along the amplitude direction from the surface portion of the movable plate to the bottom surface portion of the storage chamber is continuously increased from one end side to the other end side along the radial direction of the movable plate, and the movable plate is moved. The distance along the amplitude direction from the back surface of the plate to the top surface of the storage chamber is continuously reduced from one end side to the other end side along the radial direction of the movable plate. Anti-vibration device.   The interval along the amplitude direction from the surface portion of the movable plate to the bottom surface portion of the storage chamber is continuously increased from one end side along the radial direction to the other end side of the movable plate, The elastically deformed state so that the distance along the amplitude direction from the back surface portion of the movable plate to the top surface portion of the storage chamber continuously decreases from one end side to the other end side along the radial direction. The anti-vibration device according to claim 1, wherein the vibration isolator is stored in the storage chamber while being held in the storage chamber.   A plurality of concave or convex dimple portions are formed on the front surface portion and the back surface portion of the movable plate, respectively, and the dimple portions are arranged so as to be separated from the outer peripheral end of the movable plate toward the inner peripheral side. The vibration isolator according to claim 1 or 2.   The rib-like seal projections respectively projecting toward the first and second opening portions along the outer peripheral edge are integrally formed on the front surface portion and the back surface portion of the movable plate, respectively. The vibration isolator according to 1, 2 or 3.   The vibration isolator according to any one of claims 1 to 4, wherein a thin plate-like cushioning material having viscoelasticity is attached to each of a bottom surface portion and a top surface portion in the storage chamber.   6. The vibration isolator according to claim 5, wherein a plurality of concave or convex dimple portions are formed on the cushioning material attached to at least one of a bottom surface portion and a top surface portion in the storage chamber.

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