JPH09144805A - Liquid-sealed type mount - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an excellent vibration isolating property against input vibration of a specified frequency region in such a state that excess deformation of a resilient body due to a heavy load is regulated. SOLUTION: A high frequency orifice E to intercommunicate main and auxiliary liquid chambers A and B is formed at a partition plate 15 and a valve member 17 comprising a valve element 171 having a protrusion 172 protruded in a main liquid chamber A; a coil spring 173 to energize the valve element 171 into the closed state of the high frequency orifice E; and a stopper 174 made of an elastomer vulcanized and adhered to the under surface of the valve element 171 is arranged at the interior of the high frequency orifice. When an agitating plate 16 displaced downward along with deformation of a resilient body 13 due to a heavy load presses down the protrusion 172, the valve element 171 releases the orifice E to realize a low dynamic spring constant.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid-filled mount used as a vibration isolating support means for an automobile engine or the like.

[0002]

2. Description of the Related Art A typical conventional technique of a liquid-filled mount for supporting an automobile engine with vibration isolation is disclosed in, for example, Japanese Patent Laid-Open No. 6-2.
It is disclosed in Japanese Patent No. 88423.

In this liquid-filled mount, a stirring plate that is vibrated and displaced by a vibration input is arranged in a liquid chamber that undergoes a volume change due to the deformation of an elastic body caused by a vibration input. Liquid column resonance is caused in the enclosed liquid that is repeatedly moved in the gap between the elastic body and the input liquid in a predetermined frequency range to be absorbed / damped. Further, the stirring plate, the load applied to the elastic body by the load from the engine side is a supported body,
It also has a function as a stopper for preventing excessive deformation of the elastic body in the case where the elastic body is greatly increased due to acceleration or the like.

[0004]

That is, according to the above-mentioned prior art, as shown in FIG. 4, the dynamic spring constant is applied during normal traveling when the load due to the load of the engine at a gravitational acceleration of 1 G is applied to the elastic body. The vibration resistance is low and a good vibration damping function is achieved by liquid column resonance in a predetermined frequency range. However, when a large load is applied due to acceleration significantly exceeding 1 G due to acceleration traveling, deformation of the elastic body Since the agitating plate that has largely displaced due to the pressure is in pressure contact with the partition plate of the liquid chamber, excessive deformation of the elastic body is prevented, but there is almost no change in the dynamic spring constant due to frequency, and in the specific frequency range The only way to lower the dynamic spring constant is to lower the dynamic spring constant in the entire region by providing the stirring plate with cushioning properties.

The present invention has been made under the circumstances as described above, and its technical problem is to provide a specific frequency range in which excessive deformation of an elastic body is restricted by a large load. It is an object of the present invention to provide a liquid-filled mount capable of exhibiting excellent vibration insulation against the input vibration of.

[0006]

As a means for effectively solving the above-mentioned technical problems, a liquid-filled mount according to the present invention is provided integrally between a mount case and a boss and is arranged in a circumferential direction. Elastic body made of continuous elastomer, a diaphragm made of sheet-like elastomer integrally provided in the mount case, a main liquid chamber on the elastic body side and the diaphragm side provided on the inner circumference of the mount case. A partition plate provided with a high-frequency orifice for partitioning between the sub-liquid chamber and the liquid chamber, the stirring plate connected to the boss in the main liquid chamber, and the high-frequency orifice. And a valve member which is arranged so as to be openable and closable so as to be normally biased in the valve closing direction, and the valve member is opened by the abutment of the agitating plate displaced beyond a predetermined displacement amount. It is intended.

In the above structure, when the elastic body is subjected to a normal load due to the load of the supported body, the stirring plate in the main liquid chamber vibrates and displaces integrally with the boss due to the vibration input,
Along with this, the enclosed liquid is repeatedly moved within the gap between the elastic body. In the predetermined frequency range, the repetitive movement of the enclosed liquid in the gap is resonated to remarkably reduce the dynamic spring constant, so that the vibration in the predetermined frequency range is effectively absorbed and damped.

Further, when an excessive load is applied to the elastic body, the agitating plate is largely displaced toward the partition plate side due to the deformation of the elastic body, and the valve member closing the high frequency orifice is opened. Therefore, when vibration is input in this state, the enclosed liquid in the main liquid chamber repeatedly flows between the auxiliary liquid chamber and the opened high frequency orifice, and in a certain frequency range, the enclosed liquid in the high frequency orifice is Since the repetitive movement is performed resonantly, the dynamic spring constant is remarkably reduced, and the vibration insulation is improved.

Further, in the present invention, more preferably, the valve member is provided with a stopper made of an elastomer, and the displacement amount of the valve member in the valve opening direction is regulated by the contact between the stopper and the inner wall of the high frequency orifice. To do. In this case, excessive deformation of the elastic body is restricted by the valve member having the stopper and the stirring plate pressed against the valve member.

[0010]

1 shows a preferred embodiment of a liquid-filled mount according to the present invention. That is, the liquid-filled mount 10 has a substantially circular truncated cone shape that continuously connects in the circumferential direction, which elastically connects a metal-made substantially cylindrical mount case 11 and a metal boss 12 arranged on the inner peripheral side of the upper part thereof. An elastic body 13 made of thick elastomer,
And a diaphragm 14 made of an elastomer in the form of a thin sheet, which is arranged on the lower side thereof. Mount case 1
A liquid-filled space between the elastic body 13 and the diaphragm 14 is provided on the inner periphery of the main liquid chamber A on the elastic body 13 side (upper side).
A partition plate 15 is fixed to the sub-liquid chamber B on the diaphragm 14 side (lower side).

The mount case 11 includes a substantially cylindrical upper case member 111, an inner case member 112 arranged on the inner circumference of the upper case member 111, and a lower case member 1.
13 are assembled by crimping each other, of which the extension 113a of the lower case member 113 is fixed to the vehicle body (not shown) side of the automobile, and the boss 12 has an engine (not shown) via a bolt 121. It is fixed on the side. The elastic body 13 is formed such that the outer diameter portion and the inner diameter portion are integrated with the inner case member 112 and the boss 12 of the mount case 11. On the upper part of the upper case member 111 in the mount case 11,
A stopper portion 111a extending to a position above the boss 12 is formed so as to surround the upper side of the elastic body 13, while
The boss 12 has an outer diameter portion of the elastic body 13 (the inner case member 1
12) and the stopper portion 111a are provided with a stopper plate 122 having a cushioning member 123 made of an elastomer formed on an outer peripheral portion thereof.
The relative displacement between the mount case 11 and the boss 12 at the time of vibration input is limited to prevent the elastic body 13 from excessive tensile deformation in the vertical direction and excessive deformation in the lateral direction at the time of vibration input.

At the upper part of the main liquid chamber A, the upper surface is an elastic body 13.
Stirring plate 16 formed in a tapered shape substantially corresponding to the inner surface of the
Are arranged, and the central portion thereof is fixed to the lower end of the boss 12. In the normal state shown in the drawing in which the load due to the engine load at the gravitational acceleration 1G is applied to the elastic body 13 via the boss 12, a gap A ′ is formed between the stirring plate 16 and the inner surface of the elastic body 13. The size of the gap A ′ is set so that the liquid column resonance frequency of the enclosed liquid interposed therein is in a predetermined high frequency region.

In the mount case 11, the inner case member 112 is in close contact with the upper surface of the outer peripheral edge of the partition plate 15.
Has an inverted U-shaped cross-sectional shape in which its inner peripheral portion 112a once extends upward and is folded back downward.
A shock orifice C extending in a substantially C shape in the circumferential direction is formed between the outer peripheral edge portion of the partition plate 15 and a part of the elastic body 13 which is wrapped around the V-shaped cross section and attached. The shock orifice C has one end in the circumferential direction opened to the main liquid chamber A through an opening C _{A formed} in the inner peripheral portion 112a of the inner case member 112, and the other end in the partition plate 15
It is opened to the sub liquid chamber _B through the opening C _B opened in the main liquid chamber A and the sub liquid chamber B is always in communication with each other. Since the shock orifice C is a channel that is long and narrow in the circumferential direction, a large flow resistance is generated when the enclosed liquid flows at high speed inside the shock orifice C.

The partition plate 15 comprises a lower side plate 151 and an upper side plate 152 superposed on the upper side thereof, and in addition to the opening C _B of the shock orifice C mentioned above, the idle orifice D
And a plurality of high frequency orifices E are formed. Of these, the idle orifice D is formed so as to penetrate vertically through the central portion of the partition plate 15, and has a sufficiently short flow path length and a large flow path cross section as compared with the shock orifice C. The flow resistance when flowing is small. A switching valve 141 made of an elastomer is closely arranged on the outer peripheral portion of the lower end opening of the idle orifice D. The switching valve 141 is integrally formed on the upper surface of the central portion of the diaphragm 14 by the elastomer. On the other hand, the high frequency orifice E extends vertically through the lower plate 151 and
2 has a substantially L-shaped bent shape consisting of a portion opened to the main liquid chamber A, and a portion radially extending through the lower plate 151 to be opened from the outer peripheral surface of the lower plate 151 to the auxiliary liquid chamber B. The flow resistance when the enclosed liquid flows through this is set to be small.

A valve member 17 is arranged inside each of the high-frequency orifices E, which is open to the main liquid chamber A. The valve member 17 includes a valve body 171 having a protrusion 172 protruding into the main liquid chamber A and a lower surface of an opening of the high frequency orifice E in the upper side plate 152 of the partition plate 15 for urging the valve body 171 upward. The coil spring 173 is brought into close contact with a predetermined load, and the stopper 174 made of an elastomer vulcanized and bonded to the back surface (lower surface) of the valve body 171. The protrusions 172 vertically oppose the lower end surface of the stirring plate 16 at an appropriate distance, and when the valve body 171 is displaced downward until the stopper 174 contacts the lower end of the high frequency orifice E, the high frequency orifice is formed. It has a protruding height that does not completely sink into E.

A negative pressure actuator 20 is integrally provided under the liquid-filled mount 10. The negative pressure actuator 20 includes an actuator case 21, a retainer 22 movably arranged in the actuator case 21, and an outer peripheral edge portion and an inner peripheral portion integrally provided on the actuator case 21 and the retainer 22. It has a drive diaphragm 23, and a coil spring 24 which is interposed between the retainer 22 and the bottom of the actuator case 21 in a properly compressed state. The upper flange of the actuator case 21 is attached to the caulked portion of the mount case 11, the outer peripheral edge portion of the partition plate 15, and the diaphragm 14.
Is integrally caulked together with the outer peripheral edge of the drive diaphragm 23 at the bottom of the actuator case 21 from a negative pressure source (not shown) such as an intake pressure by a piston of the engine or a pump is used. A nozzle 25 for introducing a negative pressure into the negative pressure chamber F between the lower member 213 and the lower member 213 is opened. Also, the retainer 11 is
Core material 14 of switching valve 141 formed on diaphragm 14
It is connected integrally with 2. An atmospheric pressure chamber G is formed between the diaphragm 14 and the drive diaphragm 23.

In other words, the negative pressure actuator 20 introduces a negative pressure into the negative pressure chamber F, so that the retainer 22 compresses the coil spring 24 and reduces the negative pressure chamber F together with the drive diaphragm 23. When the retainer 22 is displaced and the negative pressure is released, the retainer 22 is displaced upward by the biasing force of the coil spring 24. The switching valve 141 formed on the diaphragm 14 of the mount body 10 is vertically displaced integrally with the retainer 22, and is brought into contact with and separated from the outer peripheral edge of the lower end opening of the idle orifice D on the lower surface of the lower plate 151 of the partition plate 15. Opens and closes the idle orifice D.

In the above embodiment, in the normal state, the elastic body 13 is compressed by the load of the engine at the gravitational acceleration of 1 G via the boss 12,
In this state, the stirring plate 16 provided at the lower end of the boss 12
172 of the valve body 171 on the lower end face of the valve and the valve member 17
Face each other with a sufficient distance in the vertical direction. For this reason, the mount case 11 and the boss 12 can be freely displaced relative to each other in the vertical direction while the elastic body 13 is deformed by vibration input from the engine side or the vehicle body side.

During normal traveling of the vehicle by the normal operation of the engine, the negative pressure in the negative pressure chamber F in the negative pressure actuator 20 is released to close the idle orifice D by the switching valve 141. The shock orifice C always connects the main liquid chamber A and the sub liquid chamber B, but in this state, if continuous small amplitude vibration in the high frequency range due to engine vibration of the engine is input, the shock orifice C The enclosed liquid in C hardly flows due to the inertia of the liquid column. on the other hand,
The filled liquid repeatedly moves in the radial direction of the stirring plate 16 in the gap A ′ between the elastic body 13 that undergoes repeated deformation in small increments corresponding to the direction of the vibration displacement and the stirring plate 16 fixed to the boss 12. In the predetermined frequency region, the liquid filled in the gap A ′ repeatedly moves due to liquid column resonance, so that the dynamic spring constant of the liquid-filled mount 10 decreases and the small-amplitude vibration in the high frequency region is transmitted. Effectively reduce the rate.

When a large amplitude vibration that causes a large change in hydraulic pressure in the main liquid chamber A, such as a shock due to a bouncing of the vehicle body, is input during the above normal running, the idle orifice D is closed, so that the filled liquid is closed. Is forced to repeatedly flow between the main liquid chamber A and the sub liquid chamber B through the shock orifice C. Therefore, high damping is generated due to the flow resistance at this time, good shock absorbing property against shock input is obtained, and its vibration is suppressed in a short time.

Further, when the engine is idling, by applying a negative pressure to the negative pressure chamber F of the negative pressure actuator 20, the switching valve 141 is separated downward from the lower end surface of the partition plate 15 and the idle orifice D is opened. . When idle vibration is input in this state, the main liquid chamber A and the sub liquid chamber B
The movement of the enclosed liquid between and is short-circuited via the idle orifice D. For this reason, the flow resistance is reduced, the change in hydraulic pressure in the main liquid chamber A is effectively absorbed, and the dynamic spring constant is reduced, so that excellent vibration insulation against idle vibration is exhibited.

The operation described above is performed in the normal state in which the elastic body 13 is loaded by the load of the engine at the gravitational acceleration of 1 G. For example, when the automobile is accelerated, the elastic body 13 is The load applied to 13 increases and the amount of compressive deformation increases, and accordingly, the stirring plate 16 is displaced downward from the position shown in FIG. 1 to the partition plate 15 side. When the displacement exceeds a predetermined amount, the lower end surface of the stirring plate 16 causes the protrusion 1 of the valve body 171 of the valve member 17 to move.
As it contacts 72 and presses it downwards, it is shown in FIG.
As shown in, the valve body 171 is displaced downward from the upper side plate 152 of the partition plate 15 against the biasing force of the coil spring 173, and the high frequency orifice E is opened. The stirring plate 16
A lower end surface of the mount 10 has a required radial width so that the stirring plate 16 can be brought into contact with the protrusion 172 even if the stirring plate 16 is eccentric to the partition plate 15 by applying a lateral load to the mount 10. Have.

In this state, when a continuous small-amplitude vibration in a relatively high frequency region due to engine vibration of the engine is input, the main liquid chamber A and the sub-liquid chamber B are moved between the main liquid chamber A and the sub liquid chamber B in the opened high frequency orifice E. The enclosed liquid is repeatedly flowed corresponding to the vibration displacement. Therefore, by setting the liquid column resonance frequency in the high frequency orifice E in an appropriate frequency range, as shown in FIG. 3, the dynamic spring constant in a specific frequency range at the time of a large load load is reduced, and the vibration insulation property is reduced. Can be improved.

When the agitating plate 16 pushes the valve body 171 of the valve member 17 further downward by further increasing the load applied to the elastic body 13, as shown in FIG. Since the stopper 174 made of an elastomer vulcanized and bonded to the lower surface of the stirrer plate contacts the lower end surface of the high-frequency orifice E, the downward displacement of the stirring plate 16 is restricted thereby. Therefore, the boss 1
Since the downward displacement of 2 is also restricted, excessive deformation of the elastic body 13 is prevented.

The present invention is not limited to the embodiment shown in the drawings, and various liquid-filled mounts, for example, those in which the opening / closing mechanism of the idle orifice D by the negative pressure actuator 20 and the switching valve 141 is not provided. Is applicable to.

[0026]

According to the liquid-filled mount of the present invention,
When a large load is applied to the elastic body, the valve member opens the high frequency orifice of the partition plate by the stirring plate in the main liquid chamber, so the dynamic spring constant in the specific frequency range is reduced by the repeated flow of the enclosed liquid in the high frequency orifice. It is possible to achieve good vibration insulation. Further, since the displacement amount of the stirring plate is regulated by the valve member having the stopper, it is possible to prevent the elastic body from being excessively deformed.

[Brief description of the drawings]

FIG. 1 is a sectional view showing a preferred embodiment of a liquid-filled mount according to the present invention.

FIG. 2 is an explanatory diagram showing an operation according to the above embodiment.

FIG. 3 is an explanatory diagram showing characteristics according to the embodiment.

FIG. 4 is an explanatory diagram showing characteristics of a conventional liquid-filled mount.

[Explanation of symbols]

 10 Liquid-filled mount 11 Mount case 111 Upper case member 112 Inner case member 113 Lower case member 12 Boss 121 Bolt 122 Stopper plate 123 Buffer body 13 Elastic body 14 Diaphragm 141 Switching valve 15 Partition plate 151 Lower plate 152 Upper plate 16 Stirring Plate 17 Valve member 171 Valve body 172 Protrusion 173 Coil spring 174 Stopper 20 Negative pressure actuator 21 Actuator case 22 Retainer 23 Drive diaphragm 24 Coil spring 25 Nozzle A Main liquid chamber B Sub liquid chamber C Shock orifice D Idle orifice E High frequency orifice F Negative Pressure chamber G Atmospheric pressure chamber

Claims (2)

[Claims] 1. A mount case (11) and a boss (12)
An elastic body (13) integrally formed between the elastic body (13) and a circumferentially continuous elastomer, and a diaphragm (14) integrally formed in the mount case (11) and made of a sheet-like elastomer, The main liquid chamber (A) on the elastic body (13) side and the diaphragm (1) are provided on the inner circumference of the mount case (11).
A partition plate (15) provided with a high-frequency orifice (E) for partitioning the sub liquid chamber (B) on the side 4) and communicating the liquid chambers (A, B) with each other; A stirring plate (16) arranged in A) and connected to the boss (12), and a valve member (17) arranged to be openable and closable with respect to the high-frequency orifice (E) and always biased in a valve closing direction. A liquid-filled mount, characterized in that the valve member (17) is opened by the abutment of the stirring plate (16) displaced beyond a predetermined displacement amount. 2. The stopper (17) according to claim 1, wherein the valve member (17) is made of an elastomer.
4) is provided, and the displacement amount of the valve member (17) in the valve opening direction is regulated by the contact between the stopper (174) and the inner wall of the high frequency orifice (E).