JP3503288B2 - Fluid-filled vibration isolator - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fluid filled type vibration damping device which obtains a vibration damping effect by controlling the internal pressure of a main liquid chamber in which a fluid is sealed, and particularly utilizes the resonance action of the fluid. Accordingly, the present invention relates to a fluid filled type vibration damping device having a novel structure, which can obtain a vibration damping effect more effectively.

[0002]

2. Description of the Related Art Conventionally, as a type of a vibration-proof coupling body or a vibration-proof support body interposed between members constituting a vibration transmission system,
As disclosed in JP-A-59-1829, JP-A-61-2939, etc., of the wall portion of the main liquid chamber in which a part of the wall portion is composed of a main rubber as an elastic support. Another part is composed of a vibrating plate, and the vibrating plate is vibrated by an appropriate vibrating means to control the internal pressure of the main liquid chamber to obtain a desired vibration damping effect. An enclosed type vibration damping device has been proposed, and its application to automobile engine mounts, suspension bushes, body mounts, etc. is under consideration.

However, in such a fluid filled type vibration damping device, it is necessary to support the diaphragm so as to be displaceable and fluid-tight with respect to the mounting member. For this reason, for example, the diaphragm is supported via a support rubber elastic body. Will be connected to and supported by the mounting member, which inevitably absorbs fluctuations in the internal pressure of the pressure receiving chamber due to elastic deformation of the support rubber elastic body, and as a result, effective internal pressure of the main liquid chamber. There is a problem in that the control cannot be performed and a satisfactory vibration damping effect cannot always be obtained. In particular, in recent years, with the trend toward higher-grade automobiles and higher performance of engine engines, there is a demand for a further improvement in vibration damping effect, and further improvements have been desired.

On the other hand, in Japanese Utility Model Laid-Open No. 61-191543, a liquid chamber in which a vibrating plate is arranged is formed independently of the main liquid chamber, and internal pressure fluctuation due to vibration of the vibrating plate is passed through an orifice passage. A fluid filled type vibration damping device adapted to affect a main liquid chamber is disclosed. In such a structure, since the vibrating plate is not arranged in the main liquid chamber, absorption of the internal pressure fluctuation of the main liquid chamber by the support rubber elastic body or the like for supporting the vibrating plate is avoided.

However, in such a fluid filled type vibration damping device, when an initial load such as a supporting load is applied at the time of mounting like an engine mount, an increase in the internal pressure of the main liquid chamber due to the initial load cannot be avoided. Therefore, the durability of the main rubber may be adversely affected. Further, since the increase in the internal pressure due to the initial load is also exerted on the diaphragm through the orifice passage, the diaphragm is displaced by being pressed by the hydraulic pressure, and the output characteristics of the solenoid or the like that drives the diaphragm changes. As a result, there is a possibility that the desired vibration damping effect may not be obtained.

[0006]

The present invention has been made in view of the circumstances as described above, and the first problem to be solved is that the main liquid is applied even under the action of an initial load. It is an object of the present invention to provide a fluid filled type vibration damping device having a novel structure in which fluctuations in the internal pressure of a chamber can be effectively controlled and a desired vibration damping effect can be stably obtained.

Further, the present invention provides a fluid-filled type vibration damping device having an improved structure capable of obtaining an effective vibration damping effect against a plurality of input vibrations in a wide frequency range. , The second problem to be solved.

[0008]

In order to solve the first problem, the features of the present invention described in claim 1 are:
(A) a first mounting member and a second mounting member which are arranged at a predetermined distance from each other, (b) a main body rubber connecting the first mounting member and the second mounting member, and (c) A main liquid chamber in which an incompressible fluid is sealed, in which a part of a wall portion is constituted by the main body rubber and which causes an internal pressure fluctuation at the time of vibration input, and (d) the main liquid chamber, The partition member supported by the second mounting member is provided at a distance from the partition member, and a part of the wall portion is composed of a diaphragm that is displaceably supported with respect to the second mounting member. Pressure control chamber in which a volatile fluid is enclosed, (e) a vibrating means for vibrating the vibrating plate to cause internal pressure fluctuation in the pressure control chamber, and (f) the main liquid chamber and the pressure control It is provided independently from the chamber, and part of the wall is made of a flexible membrane that is easily deformable, and there is no pressure inside. A static pressure absorbing chamber sexual fluid is sealed,
(G) The resonance frequency of the fluid, which is formed across the main liquid chamber and the pressure control chamber and allows the fluid to flow between the two chambers and is made to flow through the inside, is for the purpose of vibration isolation. A first orifice passage tuned in accordance with a first vibration frequency range, and (h) is formed so as to straddle between the main liquid chamber and the static pressure absorption chamber, and between the two chambers. allowing fluid flow, but the micropores is substantially closed at the time of vibration input, Yes, and and said partition member, easily
Consists of a rigid bottomed cylindrical partition plate fitting that does not deform
And the first orifice passage is
Extends circumferentially inside the corner of the bottomed cylindrical shape of the metal plate
The fluid-filled type vibration damping device is formed as described above.

[0009]

Further, in order to solve the first and second problems, it is an aspect of the present invention described in claim 2, in addition to the configuration of the (a) ~ (h), (K) is formed across the main liquid chamber and the static pressure absorption chamber,
At the time of vibration input in the third vibration frequency range for the purpose of vibration isolation in a region higher than the first vibration frequency range, a pressure absorption flow path that allows fluid flow between the two chambers,
(L) A fluid filled type vibration damping device provided with a flow rate restricting unit that is disposed in the pressure absorbing channel so as to be displaced or deformable by a predetermined amount and that limits the amount of fluid flowing through the pressure absorbing channel. It is in.

In the fluid filled type vibration damping device having the structure according to the present invention, the pressure induced in the pressure control chamber by the vibration of the vibrating plate is passed through the fluid which is made to flow through the first orifice passage. Therefore, since the resonance frequency of the fluid that is made to flow through the first orifice passage is tuned in accordance with the first vibration frequency range for the purpose of vibration isolation, When the vibration plate is vibrated at the frequency corresponding to the vibration input in the first vibration frequency range, the pressure induced in the pressure control chamber is transmitted to the main liquid chamber very efficiently due to the resonance phenomenon of the fluid mass. Can be done.

Therefore, at the time of inputting the vibration in the first vibration frequency range, it is possible to cause a large internal pressure fluctuation in the main liquid chamber by merely applying a small driving force to the diaphragm by the vibrating means. Therefore, it is possible to effectively control the internal pressure of the main liquid chamber, adjust the mount anti-vibration characteristics, and obtain an effective anti-vibration effect.

Moreover, in the fluid filled type vibration damping device having the structure according to the present invention, even when the internal pressure is generated in the main liquid chamber by the initial load exerted under the mounted condition of the vibration damping device, By moving the fluid from the chamber to the static pressure absorption chamber through the micropores, the internal pressure of the main liquid chamber is eliminated, and therefore, the adverse effect on the vibration isolation characteristics due to such internal pressure can be avoided, and the vibration isolation characteristics can be avoided. Can be stabilized and durability can be improved.

[0014]

[0015]

[0016]

Furthermore, in the fluid filled type vibration damping device having the structure according to the present invention described in claim 2 , when the vibration input in the third vibration frequency range higher than the first vibration frequency is input, Even when the orifice passage of is substantially closed, the internal pressure fluctuation induced in the main liquid chamber is released to the static pressure absorption chamber through the pressure absorption flow path,
It is possible to reduce or eliminate the deterioration of the vibration damping performance due to an increase in the internal pressure of the main liquid chamber, and as a result, an effective vibration damping effect is exerted against the input vibration of a plurality of or a wide frequency range.

In the first preferred aspect of the present invention as set forth in claim 1 or 2 , the resonance frequency of the fluid that is made to flow through the inside of the first orifice passage is 5 to 40 Hz. The orifice passage is tuned so that

In such a fluid filled type vibration damping device having the structure according to the first preferred embodiment of the present invention, the first orifice passage is tuned to a low to medium frequency range of 5 to 40 Hz. The resonance phenomenon of the fluid circulated in the first orifice passage is more remarkably exhibited, whereby the intended vibration damping effect can be obtained more effectively. Especially when the present invention is applied to an automobile engine mount, an excellent vibration damping effect against idling vibration can be obtained by the action of the first orifice passage.

In a preferred second aspect of the present invention as set forth in claim 1 or 2 , the static pressure absorption chamber is formed inside the first mounting member.

In the fluid filled type vibration damping device having the structure according to the second preferred embodiment of the present invention, the space is effectively used and the vibration damping device is large in size when the static pressure absorbing chamber is provided. Can be suppressed.

Furthermore, in a preferred third aspect of the present invention as set forth in claim 1 or 2 , the diaphragm is supported by the second mounting member via a support rubber. Then, the displacement of the diaphragm is allowed based on the elastic deformation of the support rubber.

In the fluid filled type vibration damping device having the structure according to the third preferred embodiment of the present invention, the supporting mechanism for movably supporting the vibration plate with respect to the second mounting member is simple. It can advantageously be realized with a structure.

Further, in a preferred fourth aspect of the present invention as set forth in claim 1 or 2 , while the first attachment member is constituted by a rod-shaped support shaft member, the support shaft member The second mounting member is configured by a tubular member arranged so as to surround the periphery thereof with a predetermined distance.

In the fluid filled type vibration damping device having the structure according to the fourth preferred embodiment of the present invention, the FF
The present invention can be advantageously applied to a cylindrical type vibration damping device used for an engine mount for automobiles, suspension bushes, and the like.

[0026]

EXAMPLES Examples of the present invention will now be described in detail with reference to the drawings in order to clarify the present invention more specifically.

FIG. 1 shows an automobile engine mount as an embodiment of the present invention. The engine mount of this embodiment has a first mounting member 10 as a first mounting member and a second mounting member 12 as a second mounting member, which are arranged at a predetermined distance from each other. The first mounting member 10 and the second mounting member 12 are elastically connected by the main body rubber 14, and one of the first mounting member 10 and the second mounting member 12 is connected to the power unit side and the body. By being attached to the side,
The power unit is designed to support the body in a vibration-proof manner. In addition, in the engine mount of the present embodiment, when the power unit load is applied as an initial load in the substantially vertical direction in FIG. 1 when mounted on a vehicle, the main body rubber 14 is compressed and deformed by a predetermined amount, and
The main vibration to be isolated under such a mounting condition is shown in Fig. 1.
It will be input in a substantially vertical direction. In the following description, the terms “upper” and “lower” refer to “upper” and “lower” in FIG. 1 in principle.

More specifically, the first mounting member 10 has an upper metal member 20 and a lower metal member 22 each having a substantially bottomed cylindrical shape.
Are formed with a hollow structure by being axially superposed on each opening side and connected by bolts. A mounting bolt 24 protruding outward is fixed to the bottom wall portion of the upper metal fitting 20, and the upper metal fitting 20 is mounted on the power unit side or the body side by the mounting bolt 24. .

Further, a flexible film 26 made of a rubber film having a substantially thin disk shape is disposed inside the hollow of the first mounting member 10, and an outer peripheral edge portion is provided between the upper and lower fittings 20 and 22. It is pinched. As a result, the inside of the first mounting member 10 sandwiches the flexible film 26, and the upper mounting member 20 side and the lower mounting member 22.
The side is fluid-tightly divided into two parts. Therefore, the static pressure absorption chamber 18 in which the volume change is easily allowed due to the deformation of the flexible film 26 is formed inside the lower metal fitting 22. There is. The inner space of the upper fitting 20 is communicated with the outer space through a through hole 28 formed in the peripheral wall portion, and the flexible film 26
Is sufficiently tolerant of deformation. On the other hand, the bottom wall of the lower metal fitting 22 has a minute hole 30 with a minute diameter.
Are provided so as to penetrate through the inside and outside, and are communicated with the static pressure absorption chamber 18.

Further, the main body rubber 14 is vulcanized and adhered to the lower metal fitting 22. The main body rubber 14 has a substantially cylindrical shape with a taper, and the outer peripheral surface of the cylindrical wall portion of the lower metal fitting 22 is vulcanized and adhered to the opening end surface on the smaller diameter side. As a result, the small-diameter side opening of the body rubber 14 is fluid-tightly closed by the first mounting member 10, and the recess 34 that opens downward (larger diameter side) is formed inside the body rubber 14. ing.

A restraining ring 36 for preventing buckling deformation is vulcanized and bonded to the main body rubber 14 at an axially intermediate portion thereof, and the main body rubber 14 has an annular shape with respect to the opening end face on the large diameter side. The connecting metal fitting 38 is adhered by vulcanization. The orifice fitting 40 and the second mounting fitting 12 are axially overlapped and bolted to the connecting fitting 38, respectively.

The orifice fitting 40 integrally has an annular projecting portion 42 which projects inward in the radial direction from an annular outer peripheral portion which is superposed on the connecting fitting 38. , Is positioned so as to enter the large-diameter side opening of the main body rubber 14. In addition, the annular protrusion 4
2, a groove 44 that opens upward is formed in a circumferential direction with a predetermined length, and a partition plate metal fitting 46 that has a substantially shallow bottomed cylindrical shape with respect to the annular protrusion 42. It is covered and fixed. As a result, the center hole 48 of the orifice fitting 40 is closed by the partition fitting 46, and thus the opening of the recess 34 formed in the main body rubber 14 is covered to form the main liquid chamber 50. At the same time, the opening of the groove 44 is covered to form a first orifice passage 52 extending in the circumferential direction by a predetermined length. Both ends of the first orifice passage 52 in the circumferential direction are opened to one side in the axial direction of the orifice fitting 40 through the communication holes 51 and 53.

The second mounting member 12 has an annular shape, and a disc-shaped diaphragm having an outer diameter that is smaller by a predetermined dimension than the inner diameter of the central hole 54 in the central hole 54. 5
6 is provided, and a support rubber 58 having a substantially annular shape is interposed between the outer peripheral edge of the diaphragm 56 and the inner peripheral edge of the second mounting member 12. As a result, the diaphragm 56 is supported by the second mounting member 12 via the support rubber 58, and the displacement of the diaphragm 56 is allowed based on the elastic deformation of the support rubber 58. The center hole 54 of the second mounting member 12 is fluid-tightly closed by the vibrating plate 56 and the support rubber 58.

Between the orifice fitting 40 and the second mounting fitting 12, which are axially overlapped with each other as described above, a part of the wall is formed between the facing surfaces of the partition fitting 46 and the diaphragm 56. A pressure control chamber 60 composed of the diaphragm 56 is formed. That is, the pressure control chamber 60 is
It is independently positioned on the opposite side of the main liquid chamber 50 with the partition plate metal fitting 46 sandwiched therebetween, and communicates with the main liquid chamber 50 through a first orifice passage 52. Therefore, as is clear from this, in this embodiment, the partition plate metal fitting 46 constitutes a hard partition member that is not easily deformed.

Further, the main liquid chamber 50 and the pressure control chamber 60
Each is filled with incompressible fluid such as water, alkylene glycol, polyalkylene glycol, or silicone oil. It should be noted that, as the enclosed fluid, in order to more effectively obtain the vibration damping effect based on the resonance action of the fluid made to flow through the first orifice passage 52,
It is desirable to use a low-viscosity fluid having a viscosity of 1 Pa · s or less. Further, the fluid enclosing operation can be advantageously performed, for example, by assembling the orifice fitting 40 and the second mounting fitting 12 to the integrally vulcanized molded body rubber 14 in the fluid.

Furthermore, the main liquid chamber 50 communicates with the static pressure absorption chamber 18 formed inside the first mounting member 10 through the fine holes 30, and the static pressure absorption chamber 18 is connected to the static pressure absorption chamber 18. The non-compressible fluid similar to that of the main liquid chamber 50 is sealed in, so that the slow movement of the sealed fluid through the fine holes 30 is allowed between the main liquid chamber 50 and the static pressure absorption chamber 18. It has become so. That is, the fine holes 30 exert a great flow resistance against a fluid flow having a high flow velocity, and when a dynamic pressure fluctuation is induced in the main liquid chamber 50, the fine holes 30 are formed. It becomes a substantially closed state, the fluid flow through the fine holes 30 is not generated, and the main liquid chamber 50
The diameter of the fine holes 30 is set to be sufficiently small so that the static pressure of the main liquid chamber 50 is eliminated by the movement of the fluid through the fine holes 30 only when the pressure change due to the static load is induced in the. Is there.

In short, in the engine mount of this embodiment, when the power unit load is applied as a static load when the engine mount is mounted on an automobile, the main body rubber 14 is elastically deformed and the internal pressure of the main liquid chamber 50 is increased. , Main liquid chamber 5
On the basis of the pressure difference between 0 and the static pressure absorption chamber 18, the sealed fluid is gradually transferred from the main liquid chamber 50 to the static pressure absorption chamber 18 through the fine holes 30, so that the main liquid in the state where it is mounted on the automobile. The internal pressure of the chamber 50 is released.

Further, a coil case 62 having a bottomed cylindrical shape is axially superposed on the second mounting member 12, and a flange-shaped portion 64 formed on the peripheral edge of the opening is attached to the lower surface of the second mounting member 12. Overlaid and bolted. In this embodiment, the second mounting member 12 is attached to the body side or the power unit side via the coil case 62.

A solenoid coil 68 wound around a bobbin 66 is accommodated in the coil case 62 and the inner yoke member 7 having a reel shape as a whole.
0 and 72 are fixedly attached to the solenoid coil 68 so as to cover both sides in the axial direction through the inner hole of the solenoid coil 68. Then, the inner yoke member 70 is bolted to the bottom wall portion of the coil case 62, so that the solenoid coil 68 and the inner yoke members 70 and 72 have central axes in the vertical direction in the central portion of the coil case 62. It is arranged in an extended state. In the figure, 74 is a solenoid coil 68.
It is a lead wire for power supply to.

An outer yoke member 76 having an inverted cup shape is disposed inside the coil case 62, and an upper bottom portion of the outer yoke member 76 is superposed on the lower surface of the diaphragm 56 and fixed by bolts. As a result, the diaphragm 56 and the outer yoke member 76 can be integrally displaced. Then, the outer yoke member 76
Covers the inner yoke members 70 and 72 and the solenoid coil 68 from above, and covers the outer peripheral surfaces of the inner yoke members 70 and 72 and the solenoid coil 68 with a slight gap therebetween. ，
It is externally inserted and arranged so as to be relatively displaceable in the axial direction with respect to 72 and the solenoid coil 68.

Further, the inner yoke members 70, 72 and the outer yoke member 76 are both made of a ferromagnetic material such as iron, whereby the inner yoke members 70, 72 and the outer yoke member 76 are made. A magnetic path is formed around the solenoid coil 68. The length of the cylindrical wall portion of the outer yoke member 76 does not slightly reach the inner yoke member 72 that covers the axially lower end surface of the solenoid coil 68, so that the outer yoke 68 is energized. A suction force is applied to the member 76 in the axially downward direction,
As a result, the diaphragm 56 is displaced downward against the elastic force of the support rubber 58 as the outer yoke member 76 is displaced by the magnetic attraction force. An air vent hole 78 is provided in the upper bottom portion of the outer yoke member 76, and air is supplied to and discharged from the space between the inner yoke member 70 and the outer yoke member 76, so that when the outer yoke member 76 is displaced. The air spring action at is avoided. Further, the coil case 62 is preferably formed of a non-magnetic material in order to suppress the diffusion of magnetic flux.

Further, the central hole 80 of the inner yoke member 70.
A low-friction sliding sleeve 82 made of a suitable synthetic resin material or the like is inserted into and fitted and fixed in. The head of the bolt for fixing the outer yoke member 76 to the diaphragm 56 is a rod 84 having a circular cross section that extends in the axial direction and extends downward, and this rod 84 is the central hole of the inner yoke member 70. The sliding sleeve 82 is slidably inserted into the sliding sleeve 82. Then, the rod 84 is guided in the axial direction by the sliding sleeve 82, and the displacement of the rod 84 in the direction perpendicular to the axis is prevented, so that the diaphragm 56 is prevented from being irregularly displaced such as being tilted. 56 is stably displaced in the vertical direction, and the inner yoke members 70, 7 of the outer yoke member 76 are disposed.
2 is prevented from contacting or adsorbing, and a stable magnetic attraction force is generated. In this example,
Although the rod 84 is formed of a non-magnetic material, the rod 84 may be formed of a ferromagnetic material. In that case, the rod 84 has substantially the same axial length as the outer yoke member 76. The magnetic attraction force of the solenoid coil 68 can be exerted on the rod 84 by inserting it into the center hole 80 of the inner yoke member 70.

As a result, when a pulsating current or an alternating current is supplied to the solenoid coil 68, when the energizing current increases, the magnetic attraction force exerted on the outer yoke member 76 increases and the diaphragm 56 is supported. While the rubber 58 is displaced downward against the elastic force of the rubber 58, when the energizing current decreases, the magnetic attraction force exerted on the outer yoke member 76 decreases and the diaphragm 56 is stored in the support rubber 58. It is adapted to be displaced upward by an elastic force based on energy, and as a result, the diaphragm 56 is adapted to be vertically reciprocally displaced (vibrated) in response to power supply to the solenoid coil 68. Is there. In the present embodiment, since the magnetic attraction force is exerted on the outer yoke member 76 regardless of the direction of the magnetic poles in the solenoid coil 68, the vibration frequency of the diaphragm 56 is twice as high as the power supply frequency to the solenoid coil 68. Excitation force will be exerted. The amplitude and vibration frequency of the diaphragm 56 are
It can be changed by, for example, adjusting the magnitude or frequency of the current supplied to the solenoid coil 68.

By vibrating the vibrating plate 56 in this way, the internal pressure of the pressure control chamber 60 is changed, whereby the internal pressure difference between the pressure control chamber 60 and the main liquid chamber 50 is changed. When generated, a fluid flow is generated between the pressure control chamber 60 and the main liquid chamber 50 through the first orifice passage 52. As a result, the internal pressure of the main liquid chamber 50 is changed to adjust the mount anti-vibration characteristics, and by vibrating the diaphragm in consideration of the phase difference with the input vibration to the mount, It is possible to improve the damping effect or the vibration insulating effect by reducing the dynamic spring.

Here, in the present embodiment, the resonance phenomenon of the fluid mass flowing through the first orifice passage 52 is generated so as to occur in a medium frequency range (for example, about 30 Hz) corresponding to idling vibration or the like. The length and cross-sectional area of the first orifice passage 52 are set. As a result, in order to obtain a vibration insulation effect by lowering the dynamic spring based on the change in the internal pressure of the main liquid chamber 50, the vibration plate 56 is vibrated at a frequency corresponding to idling vibration, and the pressure control chamber 60 and the main liquid chamber 50 are vibrated. When a fluid flow is generated through the first orifice passage 52 between the two, a resonance phenomenon of the fluid occurs, and thus a larger power is exerted on the main liquid chamber 50 by the resonance phenomenon of the fluid, The effective internal pressure change is exerted on the liquid chamber 50.

Therefore, even when the vibrating plate 56 is vibrated by driving the vibrating means including the solenoid coil 68 and the yoke members 70, 72, 76, etc. with relatively small energy,
Since the power is amplified by the resonance action of the fluid mass that is caused to flow through the first orifice passage 52, the pressure of the main liquid chamber 50, and consequently the mount vibration isolation characteristic, can be effectively adjusted. The desired vibration isolation effect can be obtained very effectively.

Since the internal pressure of the main liquid chamber 50 due to the static load is absorbed by the static pressure absorption chamber 18 communicating with the main liquid chamber 50 through the fine holes 30, it is caused by the power unit load or the like. The mount anti-vibration characteristics are not hindered by the internal pressure of the main liquid chamber 50.
Further, since the fine holes 30 have a significantly large flow resistance against the internal pressure generated in the main liquid chamber 50 by vibration and are in a substantially closed state, the fine holes 30 from the main liquid chamber 50 pass through the fine holes 30. Due to the outflow of fluid, the main liquid chamber 50
The fluctuation of the internal pressure of the mount will not be absorbed and the mount anti-vibration property will not be disturbed.

Further, in such an engine mount, since effective vibration damping effect can be obtained with relatively small energy, power consumption can be suppressed and
There is also an advantage that the solenoid coil 68 and the like forming the vibrating means can be reduced in size and weight, and the manufacturing cost can be reduced.

Incidentally, in order to confirm the anti-vibration effect against the idling vibration in the engine mount having the above structure, an alternating current having a frequency of 15 Hz and a voltage of 25 V _PK is applied to the solenoid coil 68, and the vibration plate 56 is passed.
Table 1 below shows the results of measuring the vibration force exerted between the first mounting member 10 and the second mounting member 12 when the was excited at 30 Hz. Further, as shown in FIG. 2, the partition member does not define the pressure control chamber, and a part of the wall portion of the main liquid chamber 50 is constituted by the vibration plate 56, whereby the vibration plate 56 is added. A similar experiment was performed for a mount having a comparative example structure in which the internal pressure of the main liquid chamber 50 was directly controlled by shaking, and the measurement results are also shown in Table 1 as a comparative example. In addition, in the mount of the comparative example structure, as shown in the drawing, the static pressure absorption chamber 18 and the main liquid chamber 50 are
Orifice passage 8 tuned to idling vibration
6, the fluid flow through the orifice passage 86 is generated between the main liquid chamber 50 and the static pressure absorption chamber 18 at the time of vibration input. That is, in the mount of this comparative example structure, the static pressure absorbing chamber 18 not only absorbs the static pressure of the main liquid chamber 50, but also when the dynamic vibration is input.
It functions as an equilibrium chamber that allows the fluid flow through the orifice passage 86 between.
Further, in FIG. 2, for ease of understanding, the same reference numerals as those of the mount of the present embodiment are attached to the members and parts corresponding to the present embodiment.

[0050]

As is clear from the results shown in Table 1, the pressure due to the vibration of the diaphragm 56 is applied to the main liquid chamber 50 by utilizing the resonance phenomenon of the fluid mass due to the first orifice passage 52.
The engine mount having the structure of the present embodiment, which has the same structure as described above, has the same structure as that of the engine mount having the structure of the comparative example in which the pressure generated by the vibration of the diaphragm 56 is directly applied to the main liquid chamber 50. It is clear that the driving power can provide a large exciting force, and thus an effective anti-vibration effect. Further, according to the experiment, it is confirmed that the engine mount of the present embodiment structure can effectively suppress the generated vibration level in the unnecessary higher order frequency range as compared with the engine mount of the comparative example structure. There is.

In the engine mount having the above structure, the resonance frequency of the movable portion (including the diaphragm 56, the outer yoke member 76, the rod 84, etc.) which is excited by the energization of the solenoid coil 68 is set. It is also possible to tune to a frequency range intended for image stabilization, whereby the image stabilization effect can be obtained even more efficiently.

Next, FIG. 3 shows an engine mount as a second embodiment of the present invention. In addition, this embodiment is different from the engine mount of the first embodiment in that
It illustrates another specific example of the vibrating means, the members and parts having the same structure as the first embodiment, the same reference numerals as those in the first embodiment in the drawings, respectively. Therefore, detailed description thereof will be omitted.

That is, in this embodiment, a vibrating means utilizing an electromagnetic force is adopted. Specifically, instead of the coil case 62 in the first embodiment, a ferromagnetic material having a circular block shape is used. A yoke member 88 composed of is used and is bolted to the second mounting member 12,
The inner yoke 92 and the outer yoke 94 are formed by forming an annular recessed groove 90 continuously extending in the circumferential direction in the radially intermediate portion of the yoke member 88. A cylindrical permanent magnet 96 is provided along the outer peripheral surface of the inner yoke 92 at the opening of the groove 90, and both magnetic poles of the permanent magnet 96 are located on the inner peripheral side and the outer peripheral side. Are positioned so that the yoke member 88 (the inner yoke 92 and the outer yoke 94) is
Thus, an annular magnetic path is formed on the entire circumference in the circumferential direction.

Then, on this magnetic path, the permanent magnet 9
The solenoid coil 98 is inserted and arranged with a slight gap in a gap portion formed between the facing surfaces of the outer yoke 6 and the outer coil 94, and the solenoid coil 9
8 is fixed to a transmission member 100 having an inverted cup shape that is bolted to the vibration plate 56.

As a result, when the solenoid coil 98 arranged on the magnetic path is energized, the electromagnetic force produces a vertical exciting force corresponding to the energizing direction.
This exciting force is exerted on the diaphragm 56 to reciprocate (vibrate).
It is designed to be punished.

Therefore, even in the engine mount having such a structure, the same effects as those of the above-described embodiment can be effectively exhibited.

Next, FIG. 4 shows an engine mount as a reference example . Incidentally, this reference example shows one specific example of the engine mount of the first embodiment to which a vibration isolation mechanism for high-frequency vibration such as muffled sound is added, and the first embodiment Members and parts having the same structure are denoted by the same reference numerals as those in the first embodiment in the drawings, and detailed description thereof will be omitted.

That is, in the engine mount of this reference example , the structure of the partitioning member for partitioning the main liquid chamber 50 and the pressure control chamber 60 is different from that of the first embodiment. A vibration isolation mechanism against vibration is added.

More specifically, in this reference example , a substantially annular plate-shaped orifice fitting 10 fixed between the connecting fitting 38 and the second mounting fitting 12 and extending largely inward in the radial direction.
2 is adopted, and this orifice fitting 102
On the other hand, a substantially annular plate-shaped lid fitting 104 is assembled so as to cover from above, and the orifice fitting 102 and the lid fitting 104 constitute a partition member for partitioning the main liquid chamber 50 and the pressure control chamber 60. Has been done.

The orifice fitting 102 and the lid fitting 1
Between the overlapping surfaces of 04, a predetermined length in the circumferential direction,
A first orifice passage 52 communicating with each of the main liquid chamber 50 and the pressure control chamber 60 is formed at both ends, and the first orifice passage 5 is formed as in the first embodiment.
2 is tuned to a medium frequency range corresponding to idling vibration and the like.

In the center portion of the partition member, a second orifice passage 106 extending through the partition member in the axial direction is formed by the center holes of the orifice fitting 102 and the lid fitting 104. The second orifice passage 106 has a ratio of the flow passage cross-sectional area: A to the flow passage length: L:
The value of A / L is set larger than that of the first orifice passage 52, and is tuned to a high frequency range corresponding to muffled noise.

Further, the second orifice passage 106 is provided with a disk-shaped movable plate 108 made of a hard material such as hard rubber, synthetic resin or metal.
The outer peripheral edge portion 08 is inserted into a circumferentially extending groove 110 formed on the inner peripheral surface of the second orifice passage 106, so that the movable plate 108 partitions the second orifice passage 106. Thus, the groove 110 is disposed so as to be displaceable by a predetermined amount. In short, the movable plate 1
Since the inner dimension of the concave groove 110 is slightly larger than the thickness dimension of the outer peripheral edge portion of 08, backlash corresponding to the dimension difference is allowed as displacement of the movable plate 108. Therefore, this movable plate 1
Based on the displacement of 08, the fluid flow between the main liquid chamber 50 and the pressure control chamber 60 through the second orifice passage 106 is allowed.

As a result, when high-frequency vibration such as muffled sound is input, if the diaphragm 56 is vibrated at a high frequency corresponding to muffled sound, the flow resistance of the first orifice passage 52 is significantly increased. Although it is substantially closed, a resonance phenomenon occurs in the fluid flowing through the second orifice passage 106, and a larger power is exerted on the main liquid chamber 50 by the resonance phenomenon of the fluid, so that the main liquid chamber 50 receives the power. Since an effective internal pressure change is exerted, an effective vibration damping effect can be exerted even against high frequency vibration.

Although the second orifice passage 106 has a larger A / L ratio and a smaller flow resistance than the first orifice passage 52, generally, medium frequency vibration such as idling vibration is high frequency vibration such as muffled noise. Has a larger amplitude than
Since the flow rate of the fluid flowing through the second orifice passage 106 is limited by the movable plate 108 at the time of inputting the medium frequency vibration, the amount of fluid flowing through the first orifice passage 52 is secured, and the first orifice passage is secured. The effect of improving the vibration isolation performance based on the resonance action of the fluid flowing through 52 can be effectively exhibited.

Therefore, in the engine mount of this reference example , at the time of vibration input in the medium frequency range, the pressure transmission from the pressure control chamber 60 to the main liquid chamber 50 causes the resonance action of the fluid flowing through the first orifice passage 52. In addition, the pressure transmission from the pressure control chamber 60 to the main liquid chamber 50 is based on the resonance action of the fluid flowing through the second orifice passage 106 at the time of vibration input in the high frequency range. Since it can be efficiently done, the main liquid chamber 50 is not affected by the input vibration in any frequency range of medium frequency and high frequency.
Since it is possible to obtain an anti-vibration effect based on the pressure control described above, it is possible to exert an excellent anti-vibration effect against input vibration in a wider frequency range than the engine mount of the first embodiment. Becomes

In this reference example , the hard movable plate 1
Although the flow rate limiting means for limiting the fluid flow rate through the second orifice passage 106 by limiting the displacement amount of 08, the first orifice passage 52 is tuned as the flow rate limiting means. It is only necessary that the amount of fluid flow through the second orifice passage 106 can be limited to effectively secure the amount of fluid flow through the first orifice passage 52 at the time of inputting vibration in the frequency range. It is not limited to ones. For example, as shown in FIG. 5, a movable plate 114 having a plurality of elastic projections 112 on both sides is used, and the elastic projections 112 are provided between the orifice metal fitting 102 and the lid metal fitting 104 each having a substantially disc shape. The movable plate 114 is disposed so as to be sandwiched between the orifice metal fitting 102 and the lid metal fitting 104, and a plurality of through holes 116 are provided in the central portions of the metal fittings.
By connecting both sides of the movable plate 114 to one of the main liquid chamber 50 and the pressure control chamber 60, a predetermined amount of displacement of the movable plate 114 is allowed based on the elastic deformation of the elastic protrusions 112. It is also possible to employ limiting means.
Note that, in FIG. 5, for easy understanding, the same reference numerals are respectively attached to members and parts having the same structure as the third embodiment.

Further, FIG. 6 shows an automobile engine mount as a third embodiment of the present invention.
Incidentally, the present embodiment shows another specific example of the engine mount of the first embodiment provided with a vibration damping mechanism against high frequency vibration such as muffled noise. The members and parts having the same structure as those in FIG. 1 are assigned the same reference numerals as those in the first embodiment in the drawings, and detailed description thereof will be omitted.

That is, in the engine mount of this embodiment, the structure of the partition wall partitioning the main liquid chamber 50 and the static pressure absorption chamber 18 is different from that of the first embodiment. A vibration isolation mechanism against high frequency vibration is added.

More specifically, a large-diameter hole is provided in the center of the bottom wall of the lower fitting 22 constituting the first mounting fitting 10, and the central hole allows the main liquid chamber 50 and the A pressure absorption flow path 118 that communicates with the pressure absorption chamber 18 is configured.

A ring fitting 120 is fixed to the lower surface of the bottom wall of the lower fitting 22 by bolts.
A concave groove 122 that continuously extends in the circumferential direction on the inner peripheral surface of the pressure absorption channel 118 is formed. Furthermore, the pressure absorption channel 1
A disk-shaped movable plate 124 made of a hard material is disposed at 18, and the outer peripheral edge portion of the movable plate 124 has a groove 1.
When the movable plate 124 is inserted into the movable plate 124,
However, the groove 12 is formed by partitioning the pressure absorption flow path 118.
It is arranged so as to be displaceable by a predetermined amount within 2. In short, the groove 1 is larger than the thickness of the outer peripheral edge of the movable plate 124.
Since the inner dimension of 22 is slightly larger, the play of only the dimension difference is allowed as the displacement of the movable plate 124.
Based on the displacement of the movable plate 124, the pressure absorption flow path 11
The fluid flow between the main liquid chamber 50 and the static pressure absorption chamber 18 through 8 is allowed.

As a result, when a high-frequency vibration such as a muffled sound is input, the flow resistance of the first orifice passage 52 is significantly increased and the first orifice passage 52 is substantially closed, so that a large internal pressure is applied to the main liquid chamber 50. However, since the fluctuation of the internal pressure of the main liquid chamber 50 is reduced or absorbed by the fluid flow between the main liquid chamber 50 and the static pressure absorption chamber 18 through the pressure absorption passage 118, Therefore, the significant reduction of the vibration isolation performance due to the high dynamic spring due to the increase of the internal pressure of the main liquid chamber 50 is eliminated, and the effective vibration isolation effect can be exerted against the high frequency vibration.

Since the amount of fluid flow through the pressure absorption flow channel 118 is limited by the movable plate 124, the fluid flow through the pressure absorption flow channel 118 causes the first flow at the time of inputting a medium-frequency vibration having a large amplitude. Orifice passage 52
Main chamber 50 by vibrating the diaphragm 56
The internal pressure fluctuation is not absorbed, and the effect of improving the vibration isolation performance based on the resonance action of the fluid flowing through the first orifice passage 52 can be effectively exhibited.

Therefore, in the engine mount of this embodiment, the pressure control chamber 60 is used when the vibration in the medium frequency range is input.
The pressure transmission from the main liquid chamber 50 to the main liquid chamber 50 can be efficiently performed based on the resonance action of the fluid flowing through the first orifice passage 52, and the vibration damping effect based on the pressure control of the main liquid chamber 50 can be advantageously provided. At the same time, the fluid flow between the main liquid chamber 50 and the static pressure absorption chamber 18 through the pressure absorption flow path 118 is allowed at the time of vibration input in the high frequency region, and the main liquid chamber 50
It is possible to avoid a significant reduction in vibration damping performance due to an increase in internal pressure of the engine mount, thereby providing a better vibration damping effect against input vibration in a wider frequency range than the engine mount of the first embodiment. It can be demonstrated.

In this embodiment, the pressure absorption channel 118
However, it also serves as a fine hole that connects the static pressure absorption chamber 18 and the main liquid chamber 50, and the fluid flow through the gap between the concave groove 122 and the movable plate 124 allows the main liquid chamber to be subjected to a static load such as a power unit load. The increase in the internal pressure of 50 is eliminated.

Further, in the present embodiment, the hard movable plate 12 is used.
4 by limiting the displacement amount of 4
Although a flow rate limiting means for limiting the amount of fluid flow through 8 has been adopted, as the flow rate limiting means, when the vibration input of the frequency range in which the first orifice passage 52 is tuned is input, the flow rate limiting means of It is only necessary that the fluid flow can be restricted to effectively secure the amount of fluid flow through the first orifice passage 52, and the present invention is not limited to the above embodiment. For example, as shown in FIG. 7, a movable plate 128 having a plurality of elastic projections 126 provided on both sides is used, and a bottom wall portion of the lower metal fitting 22 and a disc-shaped lid superposed on the bottom wall portion are used. The movable plate 128 is disposed so as to be sandwiched between the metal plate 130 and the elastic projection 126, and a plurality of through holes 132 are provided in the bottom wall portion of the lower metal member 22 and the lid metal member 130, respectively. By connecting both surface sides to one of the main liquid chamber 50 and the static pressure absorption chamber 18, the movable plate 12 is elastically deformed based on elastic deformation of the elastic protrusion 126.
It is also possible to employ a fluid limiting means adapted to allow a predetermined amount of displacement of 8. In addition, in FIG.
For easy understanding, the same reference numerals are respectively attached to members and parts having the same structure as the third embodiment.

Although the embodiments of the present invention have been described in detail above, these are literal examples and the present invention is not construed as being limited to these specific examples.

For example, in the first orifice passage and the second orifice passage, by appropriately adjusting the flow passage cross-sectional area, length, etc., vibrations in various frequency ranges for the purpose of vibration isolation can be obtained. It is possible to tune it.
Then, for low-frequency vibration such as shaking, it is possible to obtain an effective damping effect by adjusting the phase of the vibration applied to the diaphragm with respect to the input vibration.

Also, the structure of the orifice passage may be various structures in consideration of the mount structure in order to secure the required length and cross-sectional area, and is not limited to that of the above embodiment. There is no such thing.

Further, the vibrating means for vibrating the vibrating plate is not limited to the exemplified one, but may be one using an electrostrictive element or a magnetostrictive element, a hydraulic or pneumatic actuator, or a linear actuator. It is also possible to employ an actuator or the like.

Further, the pressure absorption flow path is set so that the fluid flow is allowed at the time of vibration input in a frequency range higher than the second vibration frequency range in which the second orifice passage is tuned, and A flow rate limiting means disposed in the pressure absorption flow passage is provided so that the fluid flow through the pressure absorption flow passage is restricted at the time of vibration input in the vibration frequency range and the amount of fluid flow through the second orifice passage is secured. It is also possible to adjust, whereby it is possible to advantageously obtain the vibration damping effect based on the pressure control of the main liquid chamber by utilizing the resonance action of the fluid flowing through the first and second orifice passages, The high dynamic spring of the mount at the time of vibration input in a higher frequency range that substantially closes the second orifice passage can be avoided by the fluid flow through the pressure absorption flow passage. Next, it is the more it becomes possible to obtain excellent vibration damping effect against a wider frequency range of the input vibrations.

In addition, the present invention relates to US Pat. No. 4,690,903.
As disclosed in Japanese Patent No. 89, a FF type engine mount for an automobile, etc., in which a first mounting member and a second mounting member are constituted by a supporting shaft member and a tubular member arranged around the supporting shaft member. The present invention can also be applied to a vibration isolator having a cylindrical structure that is preferably used in the above.

Although not listed one by one, the present invention
Based on the knowledge of those skilled in the art, it can be implemented in various modified, modified, and improved modes, and
It goes without saying that all such embodiments are included in the scope of the present invention without departing from the spirit of the present invention.

[0084]

As is apparent from the above description, in the fluid filled type vibration damping device having the structure according to the present invention, the internal pressure generated in the main liquid chamber by the action of the static load such as the initial load is eliminated. Thus, the vibration damping effect based on the internal pressure control of the main liquid chamber by the vibration of the diaphragm is effectively and stably exhibited.

[0085]

Furthermore, in the fluid filled type vibration damping device having the structure according to the present invention as defined in claim 2 , the main liquid at the time of vibration input in the third vibration frequency range different from the first vibration frequency range Since the deterioration of the vibration isolation performance due to the increase of the internal pressure of the chamber is avoided, the excellent vibration isolation effect is exhibited against the input vibration in the wide frequency range.

Further, in the fluid filled type vibration damping device according to the first preferred aspect of the present invention described in claim 3 , the vibration damping effect by the first orifice passage can be effectively improved. .

Further, in the fluid filled type vibration damping device according to the second preferred aspect of the present invention described in claim 4 , the efficiency of the installation space of the static pressure absorption chamber can be improved.

Further, in the fluid filled type vibration damping device according to the third preferred aspect of the present invention described in claim 5 , a support mechanism for displaceably supporting the diaphragm with respect to the second mounting member. Can be advantageously realized with a simple structure.

Further, in the fluid filled type vibration damping device according to the fourth preferred aspect of the present invention described in claim 6 , a cylindrical type vibration damping used for an engine mount for an FF type automobile, a suspension bush or the like. The present invention can be advantageously applied to a device.

[Brief description of drawings]

FIG. 1 is an explanatory longitudinal sectional view showing an engine mount as a first embodiment of the present invention.

FIG. 2 is an explanatory longitudinal sectional view showing an engine mount as a comparative example.

FIG. 3 is a vertical cross-sectional explanatory view showing an engine mount as a second embodiment of the present invention.

FIG. 4 is a vertical cross-sectional explanatory view showing an engine mount as a reference example .

5 is an explanatory view of a main part showing another specific example of the flow rate limiting means that can be adopted in the engine mount shown in FIG.

FIG. 6 is an explanatory longitudinal sectional view showing an engine mount as a third embodiment of the present invention.

7 is an explanatory view of a main part showing another specific example of the flow rate limiting means that can be adopted in the engine mount shown in FIG.

[Explanation of symbols]

10 First mounting bracket 12 Second mounting bracket 14 Body rubber 18 Static pressure absorption chamber 26 Flexible Membrane 30 fine holes 46 Partition plate bracket 50 Main liquid chamber 52 Orifice passage 56 diaphragm 58 Support rubber 60 Pressure control room 68 solenoid coil 70,72 Inner yoke member 76 Outer yoke member 88 Yoke member 96 permanent magnet 98 solenoid coil 106 Second orifice passage 108, 114, 124, 128 movable plate 118 Pressure absorption channel

Continuation of the front page (56) Reference JP-A-6-64449 (JP, A) JP-A-6-10986 (JP, A) JP-A-3-107636 (JP, A) JP-A-61-31735 (JP , A) Japanese Unexamined Patent Publication No. 6-117478 (JP, A) Actually developed 61-191543 (JP, U) Actually developed 4-93535 (JP, U) (58) Fields investigated (Int.Cl. ⁷ , DB) Name) F16F 13/26

Claims (6)

(57) [Claims] 1. A first mounting member and a second mounting member, which are arranged at a predetermined distance from each other, a main body rubber connecting the first mounting member and the second mounting member, and the main body rubber. A main liquid chamber in which an incompressible fluid is sealed, in which a part of the wall portion is configured to cause an internal pressure fluctuation when a vibration is input, and the main liquid chamber is supported by the second mounting member. Pressure provided with a non-compressible fluid inside, which is provided with a partition member separated from the partition member, and a part of the wall portion is composed of a diaphragm that is displaceably supported with respect to the second mounting member. A control chamber, a vibrating means for vibrating the vibrating plate to generate an internal pressure fluctuation in the pressure control chamber, and a part of a wall portion provided independently of the main liquid chamber and the pressure control chamber. Is composed of a flexible membrane that is easily deformable, and an incompressible fluid is enclosed inside The resonance frequency of the fluid, which is formed across the pressure absorption chamber and between the main liquid chamber and the pressure control chamber and allows fluid flow between the two chambers, prevents vibration. A first orifice passage tuned according to a desired first vibration frequency range, and a fluid formed between the main liquid chamber and the static pressure absorption chamber and formed between them. While allowing the flow, and a micropore serving as a substantially closed state when the vibration input, possess, and the partition member is easily deformed without hard Yu
It consists of a bottom cylindrical partition plate fitting and
The first orifice passage is a bottomed cylindrical shape of the partition plate fitting.
Are formed so as to extend in the circumferential direction inside the corners
Fluid filled type vibration damping device, characterized in that there. 2. A third vibration frequency range which is formed so as to extend between the main liquid chamber and the static pressure absorption chamber, and which is for vibration isolation in a region higher than the first vibration frequency range. Even when the vibration is input, a pressure absorption flow passage that allows fluid flow between the chambers and a pressure absorption flow passage that is displaceable or deformable by a predetermined amount in the pressure absorption flow passage are provided. The fluid filled type vibration damping device according to claim 1, further comprising: a flow rate limiting unit that limits a fluid flow rate. Wherein the first as the resonance frequency of the fluid flowing through the interior of the orifice passage is 5～40Hz, fluid-filled anti according to claim 1 or 2 wherein the orifice passage has been tuned Shaking device. Wherein said static pressure absorbing chamber, the fluid filled type vibration damping device according to any one of claims 1 to 3 is formed in the interior of the first mounting member. 5. The vibrating plate is supported by the second mounting member via a supporting rubber so that displacement of the vibrating plate is allowed based on elastic deformation of the supporting rubber. The fluid filled type vibration damping device according to any one of claims 1 to 4 . 6. The rod-shaped supporting shaft member constitutes the first mounting member, and the first mounting member is constituted by a tubular member arranged so as to surround the supporting shaft member at a predetermined distance. fluid-filled vibration damping device according to any one of claims 1 to 5 second mounting member is formed.