JP2008111485A - Liquid-filled vibration isolator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid-filled vibration isolator capable of improving vibration isolating performance while preventing generation of noise. <P>SOLUTION: It is composed such that first to sixth outer side openings 24c1-24c6 are arranged in an order from those with smaller opening areas to those with larger opening areas, and an arrangement direction is in the same direction as a flowing direction of a liquid flowing in a first liquid chamber, the liquid having flowed into the first liquid chamber from a second liquid chamber. Thereby, resonance frequencies of portions corresponding to the openings 24a-24c6 can be respectively dispersed, and concentration to a specific resonance frequency can be suppressed even if elastic partition films are composed with a uniform thickness, and dynamic characteristics (the vibration isolating performance) can be improved. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a liquid-filled vibration isolator, and more particularly to a liquid-filled vibration isolator that can improve vibration-proof performance while preventing the generation of abnormal noise.

  As a liquid-filled vibration isolator, for example, a vibration isolator base composed of a rubber-like elastic body and connecting a first fixture, a cylindrical second fixture, the second fixture and the first fixture. And a diaphragm which is attached to the second fixture and forms a liquid sealing chamber between the vibration isolating substrate and the liquid sealing chamber is divided into a first liquid chamber on the vibration isolating substrate side and a second liquid chamber on the diaphragm side A partition body, and an orifice formed between an outer peripheral side of the partition body and an inner peripheral side of the second fixture, the first liquid chamber and the second liquid chamber communicating with each other, and the partition body is a rubber-like elastic material An elastic partition membrane configured in a disc shape, and a pair of regulating plate members that are provided with openings and that are opposed to both sides of the elastic partition membrane and restrict the displacement of the elastic partition membrane by the remainder of the openings. What is composed is known.

This type of liquid-filled vibration isolator is provided, for example, between an automobile engine and a vehicle body frame. When vibration with a relatively large amplitude occurs due to unevenness on the road surface, the liquid is absorbed. The fluid flows between the first and second liquid chambers via the orifice, and the vibration is attenuated by the fluid flow effect. On the other hand, when vibration with a relatively small amplitude occurs, the liquid does not flow between the two liquid chambers, and the fluid pressure fluctuation between the first and second liquid chambers is absorbed by the reciprocating displacement of the elastic partition film. The vibration is attenuated (Patent Document 1).
JP 2003-184942 A (paragraph number [0029, 0031] etc.)

  By the way, since this type of liquid-filled vibration isolator has a structure in which the elastic partition film is brought into contact with the regulating member, the regulating member vibrates at the time of the contact, and the vibration is transmitted to the vehicle body frame. There is a problem that abnormal noise occurs.

  Therefore, in the above-described conventional liquid-filled vibration isolator, the regulation member (first and second support members) is connected by an elastic link and the attenuation due to the flexibility is used to generate abnormal noise. To prevent. However, this conventional liquid-filled vibration isolator has a problem that the dynamic characteristics cannot be sufficiently obtained and the vibration isolating performance is insufficient.

  The present invention has been made to solve the above-described problems, and an object thereof is to provide a liquid-filled vibration isolator capable of improving the vibration isolating performance while preventing the generation of abnormal noise. Yes.

  In order to achieve this object, a liquid-filled vibration isolator according to claim 1 connects a first fixture, a cylindrical second fixture, the second fixture, and the first fixture. And a vibration isolating base composed of a rubber-like elastic body, a diaphragm attached to the second fixture to form a liquid sealing chamber between the anti-vibration base, and the liquid sealing chamber as the vibration isolating base. A partition body partitioning into a first liquid chamber on the side and a second liquid chamber on the diaphragm side, and formed between the outer peripheral side of the partition body and the inner peripheral side of the second fixture, and An orifice that allows the second liquid chamber to communicate with each other, and the partition body includes an elastic partition film that is formed in a disk shape from a rubber-like elastic material, an opening, and is disposed opposite to both sides of the elastic partition film The displacement of the elastic partition membrane is regulated by the remaining part of the opening A plurality of outer openings formed by radially dividing an annular hole along the inner periphery of the second fixture. Each of the plurality of outer openings is configured to have an opening area of a size different from that of the other outer openings, and is arranged in order of the size of the opening area, and the plurality of outer openings are The arrangement direction when the openings are arranged in order from the smallest to the largest is that the liquid flowing from the second liquid chamber into the first liquid chamber via the orifice enters the inner periphery of the second fixture. The flow direction is the same as the flow direction in the first liquid chamber.

  The liquid filled vibration isolator according to claim 2 is the liquid filled vibration isolator according to claim 1, wherein the liquid filled vibration isolator is arranged inside the plurality of outer openings and has an annular shape along the inner periphery of the second fixture. A plurality of inner openings formed by radially dividing the holes, each of the plurality of inner openings having an opening area having a size different from that of the other inner openings; The plurality of inner openings are arranged in order of size of the opening area, and the arrangement direction when the plurality of inner openings are arranged in order from the smallest opening area to the largest is that the plurality of outer openings are from the smallest opening area. The direction is the same as the direction in which the large ones are arranged in order.

  The liquid-filled vibration isolator according to claim 3 is the liquid-filled vibration isolator according to claim 2, wherein each of the plurality of outer openings and the plurality of inner openings includes another outer opening and an inner opening. The opening area has a size different from that of the portion.

  The liquid-filled vibration isolator according to claim 4 is the liquid-filled vibration isolator according to any one of claims 1 to 3, wherein the orifice has an inlet / outlet on the first liquid chamber side as the second fixture. Are formed in the shape of a long hole that curves along the inner periphery thereof, and the end portion on the orifice channel side that is the longitudinal end portion of the long hole shape has the largest opening area in the plurality of outer opening portions. It is located on the area | region which extended the outer side 1st rib formed between what becomes and becomes the minimum.

  The liquid-filled vibration isolator according to claim 5 is the liquid-filled vibration isolator according to claim 4, wherein the end of the elongated hole in the longitudinal direction opposite to the orifice channel is The opening area of the plurality of outer openings is positioned outside the outer opening that is the second smallest.

  A liquid-filled vibration isolator according to claim 6 is the liquid-filled vibration isolator according to any one of claims 1 to 3, wherein the opening area of the plurality of inner openings is maximized and minimized. The first inner rib formed between the first and second ribs is disposed at the same circumferential position as the first outer rib.

  The liquid-filled vibration isolator according to claim 7 is the liquid-filled vibration isolator according to claim 6, wherein the ratio between the number of the inner openings and the number of the outer openings is 1: 2. And all of the ribs respectively formed between the plurality of inner openings are the same as any one of the ribs formed between the plurality of outer openings. It is arranged at a circumferential position.

  The liquid-filled vibration isolator according to claim 8 is the liquid-filled vibration isolator according to claim 2 or 3, wherein the orifice has an elongated hole shape in which an inlet / outlet on the first liquid chamber side is curved in an arc shape. And the ring shape formed by the arrangement of the plurality of outer openings and the ring shape formed by the arrangement of the plurality of inner openings have the same axis. Configured.

  According to the liquid-filled vibration isolator according to claim 1, the partition body is provided with an elastic partition film configured in a disk shape from a rubber-like elastic material and an opening, and is disposed opposite to both surfaces of the elastic partition film. And a pair of regulating plate members that regulate the displacement of the elastic partition film by the remaining portion of the opening, and the opening includes a plurality of outer openings, each of the plurality of outer openings being the other outside Since the opening area has a size different from that of the opening, the hydraulic pressure distribution acting on the elastic partition film can be dispersed through each outer opening. As a result, even when the elastic partition film is configured to have a uniform film thickness, it is possible to suppress the concentration of resonance frequencies at portions corresponding to the respective outer openings to be concentrated at a predetermined resonance frequency. Therefore, there is an effect that the dynamic characteristics can be improved.

  Furthermore, the plurality of outer openings are arranged in order of size of the opening area, and the arrangement direction when the plurality of outer openings are arranged in order from the smallest opening area to the largest one is determined from the second liquid chamber. Since the liquid flowing into the first liquid chamber via the orifice is configured to be in the same direction as the flow direction in which the liquid flows in the first liquid chamber along the inner periphery of the second fixture, for example, with vibration input When the liquid in the first liquid chamber flows into the second liquid chamber, the liquid can flow in the direction in which the opening area of the outer opening decreases in the first liquid chamber. As a result, even when the elastic partition film is configured to have a uniform film thickness, the resonance frequencies of the portions corresponding to the respective outer openings are more effectively dispersed and suppressed from being concentrated at a predetermined resonance frequency. Therefore, there is an effect that the dynamic characteristics can be further improved.

  On the other hand, when the orifice is clogged at the time of vibration input and the liquid does not flow between the two liquid chambers, as described above, the plurality of outer openings are arranged in order of the size of the opening area, The hydraulic pressure distribution acting on the elastic partition membrane through the opening can be dispersed more continuously along the circumferential direction. As a result, even when the elastic partition film is configured to have a uniform film thickness, the resonance frequencies of the portions corresponding to the respective outer openings are more efficiently distributed and suppressed from being concentrated at a predetermined resonance frequency. Therefore, there is an effect that the dynamic characteristics can be further improved.

  Note that, for example, even when configured with different opening areas, a plurality of openings each having a different opening area is set as one unit, and the opening group of one unit is repeatedly arranged in the circumferential direction (for example, When the opening groups are arranged at three locations in the circumferential direction), if only the inside of each opening group is viewed, the hydraulic pressure distribution acting on the elastic partition membrane through these openings changes along the circumferential direction. However, since the hydraulic pressure distribution acting on the elastic partition film is the same in one opening group and the other opening group as a whole, the resonance frequency of the part corresponding to each opening group Cannot be dispersed, and the resonance frequency of the elastic partition film concentrates on a predetermined value. On the other hand, in the present invention, as described above, each of the plurality of outer openings has an opening area having a size different from that of the other outer openings, and the plurality of outer openings are defined as opening areas. Therefore, the distribution of the hydraulic pressure acting on the elastic partition film can be reliably and continuously dispersed along the circumferential direction, and the concentration of the resonance frequency can be suppressed.

  Here, since the plurality of outer openings are formed by radially dividing an annular hole along the inner circumference of the second fixture, the liquid flows along the inner circumference of the second fixture. In such a case, the liquid will flow over the outer opening where the width dimension (dimension in the direction substantially perpendicular to the flow direction) is constant and the length dimension (dimension in the flow direction) changes sequentially. . Thereby, for example, compared with the case where the opening is formed of a circle, an ellipse, a polygon, etc., the hydraulic pressure distribution acting on the elastic partition membrane is continuously dispersed along the circumferential direction, and the resonance frequency is reduced. There is an effect that the effect of suppressing concentration can be surely exhibited. As a result, the dynamic characteristics can be further improved.

  Further, in this way, the shape of the outer opening is formed by radially dividing the annular hole along the inner periphery of the second fixture, so that the remaining part of the outer opening (for example, the annular opening) The shape of each of the ribs and the radial ribs can be made uniform. Therefore, variation in the rigidity strength of each part can be suppressed and the rigidity strength of the entire partition body can be improved, and as a result, the durability of the partition body can be improved.

  According to the liquid-filled vibration isolator according to claim 2, in addition to the effect exhibited by the liquid-filled vibration isolator according to claim 1, the liquid-filled vibration isolator has a plurality of inner openings, each of the plurality of inner openings. Is configured to have an opening area having a size different from that of the other inner openings, so that the hydraulic pressure distribution acting on the elastic partition membrane can be dispersed through each inner opening. As a result, even when the elastic partition film is configured to have a uniform film thickness, it is possible to suppress the concentration of resonance frequencies at portions corresponding to the respective inner openings to be concentrated at a predetermined resonance frequency. Therefore, there is an effect that the dynamic characteristics can be improved.

  Further, the plurality of inner openings are arranged in order of the size of the opening area, and the arrangement direction when the plurality of inner openings are arranged in order from the smallest opening area to the larger one is determined from the second liquid chamber. Since the liquid flowing into the first liquid chamber via the orifice is configured to be in the same direction as the flow direction in which the liquid flows in the first liquid chamber along the inner periphery of the second fixture, for example, with vibration input When the liquid in the first liquid chamber flows into the second liquid chamber, the liquid can flow in the direction in which the opening area of the inner opening decreases in the first liquid chamber. As a result, even when the elastic partition film is configured to have a uniform film thickness, the resonance frequencies of the portions corresponding to the respective inner openings are more effectively dispersed and are prevented from concentrating on the predetermined resonance frequency. Therefore, there is an effect that the dynamic characteristics can be further improved.

  On the other hand, when the orifice is clogged when vibration is input and the liquid does not flow between the two liquid chambers, as described above, a plurality of inner openings are arranged in the order of the size of the opening area. The hydraulic pressure distribution acting on the elastic partition membrane through the opening can be dispersed more continuously along the circumferential direction. As a result, even when the elastic partition film is configured to have a uniform film thickness, the resonance frequencies of the portions corresponding to the respective inner openings are more efficiently distributed and suppressed from being concentrated at a predetermined resonance frequency. Therefore, there is an effect that the dynamic characteristics can be further improved.

  According to the present invention, since the arrangement direction of the inner opening and the arrangement direction of the outer opening are the same direction, the above-described effect is not canceled by the inner opening and the outer opening. The two openings provide a synergistic effect and can effectively improve the dynamic characteristics.

  Here, since the plurality of inner openings are formed by radially dividing an annular hole along the inner circumference of the second fixture, the liquid flows along the inner circumference of the second fixture. In such a case, the liquid flows on the inner opening where the width dimension (dimension in the direction substantially perpendicular to the flow direction) is constant and the length dimension (dimension in the flow direction) sequentially changes. . Thereby, for example, compared with the case where the opening is formed of a circle, an ellipse, a polygon, etc., the hydraulic pressure distribution acting on the elastic partition membrane is continuously dispersed along the circumferential direction, and the resonance frequency is reduced. There is an effect that the effect of suppressing concentration can be surely exhibited. As a result, the dynamic characteristics can be further improved.

  In addition, in this way, the shape of the inner opening is formed by radially dividing the annular hole along the inner periphery of the second fixture, so that the remaining part of the inner opening (for example, the annular opening) The shape of each of the ribs and the radial ribs can be made uniform. Therefore, variation in the rigidity strength of each part can be suppressed and the rigidity strength of the entire partition body can be improved, and as a result, the durability of the partition body can be improved.

  Further, the shape of the inner opening is formed by radially dividing the annular hole along the inner periphery of the second fixture in the same manner as the shape of the outer opening, so that the remaining part of both openings There is an effect that the shapes of (for example, annular ribs and radial ribs) can be configured more uniformly. As a result, the rigidity and strength of the entire partition body can be improved more reliably, and the durability of the partition body can be further improved.

  According to the liquid-filled vibration isolator of claim 3, in addition to the effects exhibited by the liquid-filled vibration isolator of claim 2, each of the outer opening and the inner opening is replaced with another outer opening and an inner opening. Since the opening area has a size different from that of all of the portions, there is an effect that the hydraulic pressure distribution acting on the elastic partition membrane can be reliably dispersed through the outer opening and the inner opening. . As a result, even when the elastic partition film is configured to have a uniform film thickness, it is ensured that the resonance frequencies of the portions corresponding to the outer opening and the inner opening are dispersed and concentrated at a predetermined resonance frequency. Since it can suppress, there exists an effect that the further improvement of a dynamic characteristic can be aimed at.

  According to the liquid-filled vibration isolator of claim 4, in addition to the effect exhibited by the liquid-filled vibration isolator according to any one of claims 1 to 3, the inlet / outlet on the first liquid chamber side of the orifice is (2) It is formed into a long hole shape that curves along the inner periphery of the fixture, and the end of the long hole shape in the longitudinal direction, which is the end on the orifice channel side, has an opening area within the plurality of outer openings. Since the outer first rib formed between the largest and smallest is positioned on the extended region, an orifice is provided between the first and second liquid chambers in response to vibration input. For example, when the liquid flows into the first liquid chamber from the inlet / outlet of the orifice (or the liquid in the first liquid chamber flows out to the inlet / outlet of the orifice) in the first liquid chamber, Pass the smallest opening area of the outer opening first Become such that the last (or, conversely, as those opening area of the smallest initially passes through the largest one is the last) in turn can flow the liquid. Thereby, there exists an effect that the continuity at the time of disperse | distributing continuously the hydraulic pressure distribution which acts on an elastic partition film through an outer side opening part in the circumferential direction can be maintained. As a result, even when the elastic partition film is configured to have a uniform film thickness, the resonance frequencies of the portions corresponding to the respective outer openings are more effectively dispersed and are prevented from concentrating on the predetermined resonance frequency. Therefore, there is an effect that the dynamic characteristics can be further improved.

  In addition, according to the present invention, as described above, since the inlet / outlet on the first liquid chamber side of the orifice is formed in a long hole shape that curves along the inner periphery of the second fixture, Accordingly, the liquid flows between the first and second liquid chambers through the orifice, and for example, the liquid flows into the first liquid chamber from the inlet / outlet of the orifice (or the liquid in the first liquid chamber flows into the inlet / outlet of the orifice). The liquid in the first liquid chamber can flow along the inner periphery of the second liquid chamber, that is, along the arrangement of the outer openings. As a result, the effect of arranging the outer openings in the order of the size of the opening areas can be effectively exhibited.

  According to the liquid-filled vibration isolator according to claim 5, in addition to the effect exhibited by the liquid-filled vibration isolator according to claim 4, the longitudinal end of the long hole shape (entrance of the orifice on the first liquid chamber side) And the end opposite to the orifice channel is positioned outside the outer opening having the second smallest opening area among the plurality of outer openings. There is an effect that the dynamic characteristics can be improved while downsizing the vibration isolator.

  That is, if the end opposite to the long hole-shaped orifice channel is positioned outside the third and smaller openings, the liquid flows into the first liquid chamber from the inlet / outlet of the orifice. (Or when the liquid in the first liquid chamber flows out to the inlet / outlet of the orifice), the liquid does not flow over the outer opening which has the smallest opening area and the second smallest opening, The effect of arranging in order of size of the opening area cannot be fully exhibited.

  On the other hand, if the end opposite to the long hole-shaped orifice channel is positioned outside the one having the smallest opening area, the length in the longitudinal direction of the long hole shape (orifice entrance / exit) is shortened. Therefore, in order to secure the opening area of the orifice entrance / exit, it is necessary to enlarge the width dimension of the long hole shape. In this case, if only the width dimension of the elongated hole shape is enlarged, the width of the rib formed between the outer opening and the outer opening is also reduced, so that sufficient rigidity and strength cannot be secured. The diameter needs to be increased, and accordingly, the liquid-sealed vibration isolator is increased in size.

  On the other hand, according to the present invention, as described above, the end portion on the opposite side of the orifice channel of the elongated hole shape (the inlet / outlet on the first liquid chamber side of the orifice) has the second smallest opening area. Since the liquid flows on the outer opening having the smallest opening area, the outer opening is arranged in the order of the opening area. As well as being able to fully demonstrate, it is possible to secure the opening area of the orifice entrance and exit without increasing the outer diameter of the partition, so that the dynamic characteristics are improved and the liquid-filled vibration isolator is downsized. Can be achieved.

  According to the liquid-filled vibration isolator according to claim 6, in addition to the effect exhibited by the liquid-filled vibration isolator according to any one of claims 1 to 3, the opening area among the plurality of inner openings is maximum. The first inner rib formed between the first and second minimum ribs is disposed at the same circumferential position as the first outer rib described above, that is, a long hole shape (first orifice liquid) The end of the chamber in the longitudinal direction and the end on the orifice channel side between the one with the largest opening area and the one with the smallest opening area (the inner first ribs) The liquid flows through the orifice between the first and second liquid chambers in accordance with the vibration input. For example, the liquid flows from the inlet / outlet of the orifice to the first liquid chamber. (Or the liquid in the first liquid chamber flows out to the inlet / outlet of the orifice) In the first liquid chamber, the one having the smallest opening area of the inner opening first passes and the largest one comes last (or conversely, the one having the largest opening area starts first. The liquid can be made to flow in order (so that the smallest one is the last). Thereby, there is an effect that continuity can be maintained when the hydraulic pressure distribution acting on the elastic partition membrane via the inner opening is continuously dispersed in the circumferential direction. As a result, even when the elastic partition film is configured to have a uniform film thickness, the resonance frequencies of the portions corresponding to the respective inner openings are more effectively distributed, and the concentration on the predetermined resonance frequency is suppressed. Therefore, there is an effect that the dynamic characteristics can be further improved.

  Further, according to the present invention, the arrangement direction of the inner opening and the arrangement direction of the outer opening are set to the same direction and the circumferential position is matched. There is an effect that the dynamic characteristics can be improved more efficiently by synergistically exhibiting both the openings without canceling with the openings.

  According to the liquid-filled vibration isolator of claim 7, in addition to the effect exhibited by the liquid-filled vibration isolator of claim 6, the ratio between the number of inner openings and the number of outer openings. And one of the ribs respectively formed between the plurality of outer openings, and any one of the ribs respectively formed between the plurality of outer openings. Since it is configured to be arranged at the same circumferential position, the rib formed between the inner openings and the rib formed between the outer openings are arranged in a radial straight line to ensure the rigidity strength of the entire partition body There is an effect that can be done. In addition, by arranging the ribs in a radial straight line, for example, when the partition body is manufactured by casting, injection molding, or the like, there is an effect that it is possible to ensure moldability and improve yield. .

  According to the liquid-filled vibration isolator according to claim 8, in addition to the effect of the liquid-filled vibration isolator according to claim 2 or 3, the inlet / outlet on the first liquid chamber side of the orifice is curved in an arc shape. It is formed in a long hole shape, and the circular shape formed by the arc of the long hole shape, the arrangement of the plurality of outer openings, and the ring shape formed by the arrangement of the plurality of inner openings have the same axis. Since it is a configuration, an annular rib formed between the inlet / outlet on the first liquid chamber side of the orifice and the outer opening, and an annular rib formed between the outer opening and the inner opening, It can be formed with a constant rib width in the circumferential direction, and as a result, there is an effect that the rigidity strength of the entire partition body can be ensured. In particular, when the outer and inner openings are configured to have different opening areas as in the present invention, the opening balance of the partition becomes uneven and it is difficult to ensure the rigidity and strength. This configuration is particularly effective.

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

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

  The first mounting bracket 1 is formed in a substantially cylindrical shape from an aluminum alloy or the like, and as shown in FIG. 1, a mounting bolt 4 projects upward from a substantially central portion thereof. Further, a positioning convex portion 1 a is provided on the side of the mounting bolt 4. Further, the lower part of the first mounting bracket 1 is formed so as to project in a flange shape in the outer diameter direction, and this projecting part is embedded in the vibration isolation base 3.

  The second mounting bracket 2 includes a cylindrical metal fitting 6 on which the vibration-proof base 3 is vulcanized and a bottom metal fitting 7 attached to the lower side of the cylindrical metal fitting 6. As shown in FIG. 1, the cylindrical metal fitting 6 is formed in a cylindrical shape having an opening extending upward, and the bottom metal fitting 7 is formed in a cup shape.

  The cylindrical fitting 6 is made of a steel material, and the bottom fitting 7 is made of an aluminum alloy. A mounting bolt 5 is projected from the bottom of the bottom fitting 7 and a positioning projection 7a is projected.

  As shown in FIG. 1, the anti-vibration base 3 is formed from a rubber-like elastic body in a substantially truncated cone shape, and is vulcanized between the lower surface side of the first mounting bracket 1 and the upper end opening of the cylindrical fitting 6. It is glued. Further, a rubber film 3a covering the inner peripheral surface of the cylindrical metal fitting 6 is connected to the lower end portion of the vibration isolating base 3. The rubber film 3a includes an orifice metal fitting 16 and a partition plate member 17 described later. The outer periphery is in close contact.

  As shown in FIG. 1, the upper end portion (upper side in FIG. 1) of the vibration isolating base 3 is provided with a covering portion 3 b that covers the protruding portion of the first mounting bracket 1, and this covering portion 3 b is attached to the stabilizer fitting 8. By contacting, it is configured to obtain a stopper action at the time of large displacement. The stabilizer fitting 8 is caulked and fixed to the end of the cylindrical fitting 6. A cover member 13 made of a rubber-like elastic body is attached to the upper surface side of the stabilizer fitting 8.

  The diaphragm 9 is formed from a rubber-like elastic body into a rubber film shape having a partial spherical shape. As shown in FIG. 1, the diaphragm 9 is attached to the second attachment fitting 2 (between the tubular fitting 6 and the bottom fitting 7). It is attached. As a result, a liquid sealing chamber 11 is formed between the upper surface side of the diaphragm 9 and the lower surface side of the vibration isolation base 3.

  The liquid enclosure 11 is filled with an antifreeze liquid (not shown) such as ethylene glycol. As shown in FIG. 1, the liquid enclosure chamber 11 is divided into a first liquid chamber 11A on the side of the vibration isolating base 3 (upper side in FIG. 1) and a second on the diaphragm 9 side (lower side in FIG. 1) by a partition body 12 described later. It is partitioned into two chambers, the liquid chamber 11B.

  The diaphragm 9 is vulcanized and bonded to a donut-shaped mounting plate 10 as viewed from above, and the mounting plate 10 is caulked and fixed between the cylindrical metal fitting 6 and the bottom metal fitting 7 as shown in FIG. Thus, the second mounting bracket 2 is attached.

  As shown in FIG. 1, the partition 12 includes an elastic partition film 15 configured from a rubber-like elastic body into a substantially disc-like rubber film shape, and a lattice on the inner peripheral surface side that accommodates the elastic partition film 15. An orifice fitting 16 received by a wall-like wall portion, and a disk-like partition plate member 17 that covers an opening on one end side (upper side in FIG. 1) of the orifice fitting 16 in the axial direction.

  The partition plate member 17 is provided with a lattice-like wall portion similarly to the orifice fitting 16 and receives the elastic partition film 15. The elastic partition film 15 is accommodated between the opposing surfaces of the wall portion of the partition plate member 17 and the wall portion of the orifice fitting 16, and its displacement is restricted from both sides. By this displacement restriction, when a vibration having a relatively large amplitude is input, the film rigidity can be increased and the damping characteristic can be improved (high damping characteristic). When a vibration with a relatively small amplitude is input, the elastic partition film 15 is reciprocally deformed to absorb the hydraulic pressure, thereby improving the dynamic characteristics (lowering the dynamic spring).

  As shown in FIG. 1, an orifice 25 is formed on the outer peripheral surface side of the orifice metal fitting 16 between the rubber film 3 a covering the inner peripheral surface of the second mounting metal fitting 2 (tubular metal fitting 6). The orifice 25 is an orifice channel that communicates the first liquid chamber 11A and the second liquid chamber 11B.

  As shown in FIG. 1, the partition body 12 is clamped and fixed in the axial center O direction (vertical direction in FIG. 1) of the second mounting bracket 2 by the partition body receiving portion 3 c provided on the vibration isolation base 3 and the clamping member 18. Has been. The holding member 18 has a second cylindrical portion 44 (see FIG. 7) fitted into the inner peripheral portion of the orifice fitting 16 at the other end side in the axis O direction (lower side in FIG. 1), and the outer peripheral side flat plate portion. 41 (see FIG. 7) is caulked and fixed to the second mounting bracket 2 (between the cylindrical bracket 6 and the bottom bracket 7).

  Here, the partition body receiving portion 3c is formed as a stepped portion over the entire circumference on the lower surface side of the vibration isolating base 3, and the upper end surface of the partitioning body 12 is locked at the stepped portion as shown in FIG. In the assembled state of the liquid filled type vibration isolator 100, the partition body receiving portion 3c is compressed and deformed, and the elastic restoring force of the partition body receiving portion 3c acts on the partition body 12 as a holding force. Thereby, the partition body 12 can be clamped and fixed firmly and stably.

  As shown in FIG. 1, the second cylindrical portion 44 of the clamping member 18 is press-fitted into the inner peripheral portion on the lower end side of the orifice fitting 16, and the outer peripheral side flat plate portion 41 of the clamping member 18 is second-attached. Since it is caulked and fixed to the metal fitting 2 (between the cylindrical metal fitting 6 and the bottom metal fitting 7), the holding member 18 and the partition body 12 can be firmly held. As a result, even when a large amplitude or high frequency amplitude is input, chattering of each member can be suppressed, thereby avoiding the influence on the dynamic characteristics due to positional deviation or resonance of each member. Can do.

  Next, referring to FIGS. 2 to 4, the orifice fitting 16 constituting the partition 12 will be described. 2A is a top view of the orifice fitting 16, and FIG. 2B is a cross-sectional view of the orifice fitting 16 taken along line IIb-IIb in FIG. 2A. 3 is a side view of the orifice fitting 16, and FIG. 4 is a top view of the orifice fitting 16. As shown in FIG.

  As shown in FIGS. 2 to 4, the orifice fitting 16 is made of an aluminum alloy and has an axial center O and a substantially cylindrical shape having a hollow inner periphery, and one end side in the axial center O direction is closed by a wall portion. Has been. As shown in FIGS. 2 to 4, the fitting wall 21 is arranged in the radial direction (axial center) on the outer periphery of one end side of the orifice fitting 16 in the axial center O direction (for example, the upper side in FIG. 2B or FIG. 3). A direction that is substantially perpendicular to O. For example, it is formed so as to protrude in the left-right direction in FIG. An outer fitting cylinder portion 31 of the partition plate member 17 is fitted into the fitting wall 21 (see FIG. 1).

  As shown in FIGS. 2 to 4, a cutout portion 21 a is formed in a part of the fitting wall 21 in the circumferential direction, and this cutout portion 21 a and an opening portion 32 (to be described later) of the partition plate member 17 ( One end of the orifice 25 is communicated with the first liquid chamber 11A (see FIG. 1). As will be described later, a part of the orifice forming wall of the orifice channel is formed by the clamping member 18 (intermediate side flat plate portion 43) (see FIG. 1). Further, the notch 21a is formed to be curved in a circular arc shape concentric with the axis O of the orifice fitting 16 in a top view of the orifice fitting 16 shown in FIG.

  As shown in FIGS. 2 to 4, a vertical wall 23 extending in the direction of the axis O of the orifice fitting 16 (for example, the vertical direction in FIG. 3) is connected to one end of the fitting wall 21. The vertical wall 23 is a portion that divides the orifice channel (orifice 25) in the circumferential direction, and is formed so as to protrude in the radial direction of the orifice fitting 16, and as shown in FIG. It extends to the lower side of FIG.

  As shown in FIGS. 2 to 4, the wall portion of the orifice fitting 16 has a plurality of openings (a central opening 24a on the center side, and two rows in the circumferential direction of the wall portion) drilled in the thickness direction. The inner opening 24b and the outer opening 24c are arranged side by side, and a plurality of central annular ribs 16a1 and the like and first to third inner radial ribs 16b1 to 16b3 and the like are provided along the peripheral edges of the openings 24a to 24c. Is formed.

  In this embodiment, as shown in FIG. 2 or 4, the shape of the central opening 24 a is formed in a substantially circular shape concentric with the axis O of the orifice fitting 16. The shape of the inner opening 24b is formed by radially dividing an annular hole along the outer circumference of the orifice fitting 16 (the inner circumference of the second mounting fitting 2). That is, the inner opening 24b is divided by three first to third inner radial ribs 16b1 to 16b2 extending radially with respect to the axis O so that each of the inner openings 24b has a different opening area. The first to third inner openings 24b1 to 24b3 are provided.

  Similarly, as shown in FIG. 2 or 4, the shape of the outer opening 24c is an annular hole along the outer periphery of the orifice fitting 16 (the inner periphery of the second mounting fitting 2), and the inner opening described above. It is formed by radially dividing an annular hole located outside of 24b. In other words, the outer opening 24c is divided into six annular holes by the six first to sixth outer radial ribs 16c1 to 16c6 extending radially with respect to the axis O, so that each has a different opening area. The first to sixth outer openings 24c1 to 24c6 are provided.

  Here, as will be described later, the first to third inner openings 24b1 to 24b3 are arranged in the order of the size of the opening area, and the arrangement direction when arranging in order from the smallest opening area to the larger one is as follows. The flow direction in which the liquid flowing into the first liquid chamber 11A from the second liquid chamber 11B through the orifice 25 flows in the first liquid chamber 11A along the inner periphery of the second mounting bracket 2 (tubular bracket 6) ( (Clockwise in FIG. 4). Similarly, the arrangement direction when the first to sixth outer openings 24c1 to 24c6 are arranged in order from the small opening area to the large opening area is the same as the above-described flow direction (clockwise in FIG. 4). ing.

  The central annular rib 16a1, the inner annular rib 16a2 and the outer annular rib 16a3 are formed by concentric rings with respect to the axis O of the orifice fitting 16, as shown in FIG. 2 or FIG. The annular rib 16a2 is connected by first to third inner radial ribs 16b1 to 16b3, and the inner annular rib 16a2 and outer annular rib 16a3 are connected by first to sixth radial ribs 16c1 to 16c6, respectively.

  As shown in FIG. 2 or FIG. 4, the central annular rib 16a1 and the inner annular rib 16a2 are each configured to have a constant rib width over the entire circumference, so that the first to third inner radial ribs 16b1 to 16b3 The rib length (that is, the opening width of the inner opening 24b) is also configured to be the same length. Similarly, since the outer annular rib 16a3 is also configured with a constant rib width over the entire circumference, the rib lengths of the first to sixth outer radial ribs 16c1 to 16c6 (that is, the opening width of the outer opening 24c) are also respectively set. It is composed of the same length.

  However, in this embodiment, as will be described later, the opening width of the inner opening 24b is set so that the opening areas of the ten openings 24a, 24b1 to 24b3, 24c1 to 24c6 are all different from each other. It is narrower than the opening width of the opening 24c.

  As shown in FIG. 4, the first to third inner radial ribs 16b1 to 16b3 and the first to sixth outer radial ribs 16c1 to 16c6 extend radially from the axis O of the orifice fitting 16, In the present embodiment, the opening angle α (rib width) of each radial rib 16b1 to 16b3, 16c1 to 16c6 is set to α = 10 °.

  As shown in FIG. 4, the three first to third inner radial ribs 16b1 to 16b3 are each one of the outer radial ribs 16c1, every other one of the six first to sixth outer radial ribs 16c1 to 16c6. 16c3 and 16c5 are arranged so that their positions in the circumferential direction coincide with each other.

  Thereby, as shown in FIG. 4, one first inner opening is provided between the first inner radial rib 16b1 and the first outer radial rib 16c1, and the second inner radial rib 16b2 and the third outer radial rib 16c3. A portion 24b1 and two first and second outer openings 24c1 and 24c2 are located, and a second outer radial rib 16c2 is provided between the two first outer openings 24c1 and the second outer opening 24c2. Is located. In the present embodiment, the opening angle θ1 of the first outer opening 24c1 is set to θ1 = 20 °, and the opening angle θ2 of the second outer opening 24c2 is set to θ2 = 30 °. The opening angle of one inner opening 24b1 is 60 ° (= θ1 + α + θ2).

  Further, as shown in FIG. 4, one second inner opening is provided between the second inner radial rib 16b2 and the third outer radial rib 16c3, and the third inner radial rib 16b3 and the fifth outer radial rib 16c5. 24b2 and two third and fourth outer openings 24c3 and 24c4 are located, and a fourth outer radial rib 16c4 is disposed between the two third outer openings 24c3 and the fourth outer opening 24c4. To position. In the present embodiment, the opening angle θ3 of the third outer opening 24c3 is set to θ3 = 40 °, and the opening angle θ4 of the fourth outer opening 24c4 is set to θ4 = 50 °. 2 The opening angle of the inner opening 24b2 is 100 ° (= θ3 + α + θ4).

  Further, as shown in FIG. 4, one third inner opening is provided between the third inner radial rib 16b3 and the fifth outer radial rib 16c5 and the first inner radial rib 16b1 and the first outer radial rib 16c1. 24b3 and two fifth and sixth outer openings 24c5 and 24c6 are located, and a sixth outer radial rib 16c6 is disposed between the two fifth outer openings 24c5 and the sixth outer opening 24c6. To position. In the present embodiment, the opening angle θ5 of the fifth outer opening 24c5 is set to θ5 = 60 °, and the opening angle θ6 of the sixth outer opening 24c6 is set to θ6 = 100 °. 3 The opening angle of the inner opening 24b3 is 170 ° (= θ5 + α + θ6).

  Here, a notch 21a (a portion serving as an inlet / outlet on the first liquid chamber 11A side (see FIG. 1) of the orifice 25 through an opening 32 of a partition plate member 17 described later, see FIG. 8) and an outer opening. The positional relationship with 24c is set as follows. That is, the end 21a1 in the longitudinal direction of the notch 21a and the end 21a1 on the orifice channel side is a region formed by extending the first outer radial rib 16c1 (ie, a region formed by extending the opening angle α). Located on top). In the present embodiment, as shown in FIG. 4, the end 21a1 of the notch 21a is positioned on the boundary line (virtual line L1) between the first outer radial rib 16c1 and the sixth outer opening 24c6. It is set to be.

  Further, the end portion 21a2 that is the longitudinal end portion of the notch portion 21a and that is opposite to the orifice flow path is on the region that is outside the second outer opening portion 24c2 (that is, by extending the opening angle θ2). Located on the region to be formed). In the present embodiment, as shown in FIG. 4, the end 21a2 of the notch 21a is located outside the second outer opening 24c2 and on the side close to the third outer opening 24c3. Is set to

  Next, the partition plate member 17 constituting the partition body 12 will be described with reference to FIG. 5A is a top view of the partition plate member 17, and FIG. 5B is a cross-sectional view of the partition plate member 17 taken along the line Vb-Vb in FIG. 5A.

  As shown in FIG. 5, the partition plate member 17 is formed in a substantially disc shape having an axis O from a steel material or the like. As shown in FIG. 5, the wall portion (plate surface) of the partition plate member 17 has a plurality of openings (a central opening 34 a on the center side and 2 in the circumferential direction of the wall portion) drilled in the plate thickness direction. An inner opening 34b and an outer opening 34c) arranged in a row, and along the periphery of each of the openings 34a to 34c, a central annular rib 17a1 and the like and first to third inner radial ribs 17b1 to 17b3 and the like A plurality of are formed.

  The central opening 34a on the central side and the inner opening 34b and the outer opening 34c arranged in two rows in the circumferential direction of the wall are the central opening 24a on the central side of the orifice fitting 16 and the periphery of the wall. Configured in the same manner as the inner openings 24b and the outer openings 24c arranged in two rows in the direction (that is, configured to have the same position, size, range, and the like, and have the same outer shape in the axial direction view) Accordingly, the annular ribs 17a1 to 17a3 and the radial ribs 17b1 to 17b3 and 17c1 to 17c6 are also configured in the same manner as the annular ribs 16a1 to 16a3 and the radial ribs 16b1 to 16b3 and 16c1 to 16c6 of the orifice fitting 16. Therefore, the description thereof is omitted.

  As shown in FIG. 5, an outer fitting cylindrical portion 31 is erected on the outer peripheral portion of the partition plate member 17 at substantially the same height over the entire circumference. The partition plate member 17 is assembled to the orifice fitting 16 by fitting the outer fitting cylindrical portion 31 on the outer periphery on the one end side in the axial direction of the orifice fitting 16 described above, that is, on the fitting wall 21 of the orifice fitting 16. (See FIG. 1).

  In the partition plate member 17, an opening 32 is formed in the plate thickness direction outside the outer annular rib 17 b 3. As described above, the opening 32 is an opening through which the orifice channel (orifice 25) and the first liquid chamber 11A communicate with each other via the notch 21a (see FIGS. 2 to 4) of the orifice fitting 16. is there.

  As shown in FIG. 5A, the opening 32 is formed in a substantially long hole shape that is curved along the circumferential direction. The circumferential length of the opening 32 is set to be longer than the notch 21 a of the orifice fitting 16. Therefore, when the partition plate member 17 is assembled to the orifice fitting 16, it is possible to prevent the flow path cross-sectional area of the orifice 25 from being reduced even if the assembly position is slightly shifted in the circumferential direction.

  Next, the elastic partition film 15 constituting the partition body 12 will be described with reference to FIG. 6A is a top view of the elastic partition film 15, and FIG. 6B is a cross-sectional view of the elastic partition film 15 taken along the line VIb-VIb in FIG. 6A. In FIG. 6 (a), the arrangement of the rib groups (radial lips 15a and annular lips 15b to 15d) is schematically illustrated using a one-dot chain line in order to simplify the drawing and facilitate understanding. Yes.

  As described above, the elastic partition membrane 15 is accommodated in the partition body 12 (between the opposing surfaces of the wall portion of the orifice fitting 16 and the wall portion of the partition plate member 17), and the first and second liquid chambers 11A and 11B. It is effective to relieve the hydraulic pressure difference between them, and is formed in a substantially disk shape having a uniform film thickness and an axis O from a rubber-like elastic body.

  On the upper and lower surfaces (one surface side 15x1 and the other surface side 15x2) of the elastic partition film 15, protruding ribs are provided in a protruding manner. In the present embodiment, the pattern of the rib group on the upper surface side is the same as the pattern of the rib group on the lower surface side. In other words, the upper and lower rib groups are configured to be plane-symmetric with respect to a virtual plane (not shown) located in the middle of the elastic partition film 15 in the thickness direction (the vertical direction in FIG. 6B). .

  As shown in FIG. 6, the rib group is arranged in a circular shape concentric with the radial lip 15 a arranged radially with respect to the axis O of the elastic partition film 15 and the axis O of the elastic partition film 15. And annular lips 15b to 15d. Thirty-two radial lips 15a are distributed at regular intervals of approximately 11.25 degrees in the circumferential direction. On the other hand, a total of three annular lips 15b to 15d are arranged at positions corresponding to the respective annular ribs 16a1 to 16a3 (see FIGS. 2 and 5).

  Here, in the present embodiment, in the assembled state of the partition body 12 (see FIG. 8), the tops of the radial lips 15a and the annular lips 15b to 15d are the orifice fitting 16 and the partition plate member 17 (the respective radial ribs 16b1 to 17c6 and The height dimension is set so as to be in contact with each of the annular ribs 16a1 to 17a3). Thereby, collision with the orifice member 16 and the partition member 17 can be suppressed, and generation | occurrence | production of unusual noise can be aimed at.

  Further, the cross-sectional shape of the radial lip 15a is set such that the lip width is smaller than the lip width of the annular lips 15b to 15d. As a result, the radial lip 15a can be easily deformed, and the rigidity of the elastic partition film 15 as a whole can be prevented from becoming too high, so that a low dynamic spring characteristic at the time of relatively small amplitude vibration input can be obtained. You can also.

  Next, the clamping member 18 will be described with reference to FIG. Fig.7 (a) is a top view of the clamping member 18, FIG.7 (b) is sectional drawing of the clamping member 18 in the VIIb-VIIb line | wire of Fig.7 (a).

  The sandwiching member 18 is a member for sandwiching and holding the partition 12 with the vibration isolating base 3 (see FIG. 1), and as shown in FIG. It is formed in a disk shape.

  As shown in FIG. 7, the clamping member 18 presses the outer peripheral side flat plate portion 41, the first cylindrical portion 42 that is in close contact with the lower end portion of the rubber film 3 a, and the lower end portion of the orifice fitting 16. The intermediate portion side flat plate portion 43 and a second cylindrical portion 44 fitted into the inner peripheral portion on the other axial end side of the orifice fitting 16 are provided. In addition, an opening for avoiding interference with the diaphragm 9 is formed at the center of the clamping member 18.

  The intermediate portion side flat plate portion 43 is configured to also serve as an orifice forming wall (see FIG. 1). That is, the orifice fitting 16 described above has an outer diameter dimension at its lower end portion smaller than an outer diameter dimension of the intermediate portion side flat plate portion 43 (see FIG. 1). An orifice forming wall of the orifice 25 (orifice channel) is also used as an overhanging portion that protrudes in the radial direction from the lower end of the orifice fitting 16.

  As shown in FIG. 7A, the middle flat plate 43, that is, the orifice forming wall has a substantially oval opening 46 extending in the circumferential direction in the thickness direction (FIG. 7A). (Perpendicular direction). The orifice 25 (orifice flow path) communicates with the second liquid chamber 11B through the opening 46 (see FIG. 1).

  Next, the assembly of the partition body 12 and the clamping member 18 will be described with reference to FIG. FIG. 8A is a top view of the partition body 12 and the sandwiching member 18, and FIG. 8B is a cross-sectional view of the partition body 12 and the sandwiching member 18 taken along line VIIIb-VIIIb of FIG. 8A. .

  In assembling the partition body 12 and the clamping member 18, first, the elastic partition film 15 is placed on the wall portion of the orifice fitting 16, and the external fitting cylinder portion 31 of the partition plate member 17 is placed on the fitting wall 21 of the orifice fitting 16. Fits outside. As a result, as shown in FIG. 8, the elastic partition film 15 is accommodated between the opposing surfaces of the wall portions of the orifice fitting 16 and the partition plate member 17, and the displacement of the elastic partition film 15 is reduced to one side 15 x 1 of the elastic partition film 15 and It is regulated from both surfaces (FIG. 7B, upper and lower) of the other surface side 15x2 (see FIG. 5B).

  Next, the assembly of the partition body 12 and the clamping member 18 is completed by press-fitting the second cylindrical portion 44 of the clamping member 18 into the inner peripheral portion of the orifice fitting 16. Alternatively, the partition plate member 17 may be externally fitted into the orifice fitting 16 after the clamping member 18 is fitted into the orifice fitting 16. Further, when the partition plate member 17 is externally fitted to the orifice fitting 16, the orifices 24c1 and the like of the orifice fitting 16 and the openings 34c1 and the like of the partition plate member 17 are aligned with each other in the circumferential direction. The relative positions of the metal fitting 16 and the partition plate member 17 are aligned.

  Next, with reference to FIG. 9, a test result about the dynamic load test of the liquid-filled vibration isolator 100 will be described. The dynamic load is an acceleration expressed as a reaction force generated from the liquid filled type vibration isolator 100 when the liquid filled type vibration isolator 100 is vibrated under a predetermined condition. It is possible to make it difficult to transmit a hitting sound or the like by the elastic partition film 15 and suppress the generation of abnormal noise.

  In this dynamic load test, the liquid-filled vibration isolator 100 (hereinafter referred to as “invention product”) and the inner openings 24b and 34b and the outer openings 24c and 34c in the liquid-filled vibration isolator 100 are described. Two types were measured and compared with those of which only the shape was changed (hereinafter referred to as “conventional product”).

  In the conventional product, only the arrangement positions of the first to third inner radial ribs 16b1 to 16b3, 17b1 to 17b3 and the first to sixth outer radial ribs 16c1 to 16c6 and 17c1 to 17c6 are changed with respect to the invention. The three first to third inner radial ribs 16b1 to 16b3, 17b1 to 17b3 are arranged at equal intervals of 120 ° in the circumferential direction, and the six first to sixth outer radial ribs 16c1 to 16c6 and 17c1 to 17c6 are arranged. They are arranged at regular intervals of 60 ° in the circumferential direction. Therefore, the total opening area of the inner openings 24b and 34b and the outer openings 24c and 34c is equal between the conventional product and the invention.

  In the dynamic load test, the same load as in the engine support state is applied to the liquid-filled vibration isolator 100, and in that state, a predetermined vibration (frequency: 19 Hz, amplitude: ± 0.4 mm) is applied to the liquid-filled vibration isolator 100. This was done by frequency analysis of the reaction force waveform when the vibration was input to and applied.

  FIG. 9 shows the test result of the dynamic load test, where the vertical axis indicates the dynamic load (dB) and the horizontal axis indicates the frequency (Hz). Note that 0 dB corresponds to 1N. FIG. 9 shows a dynamic load in a state in which vibration in the direction in which the liquid flows from the first liquid chamber 11A to the second liquid chamber 11B is input.

  As shown in FIG. 9, in the invention, as described above, the arrangement of the inner openings 24b and 34b and the outer openings 24c and 34c is arranged in the order of the size of the opening area, so that compared with the conventional product, It can be understood that the dynamic load level in the frequency range from 200 Hz to 250 Hz can be reduced by about 5 dB at the maximum.

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

  The numerical values (for example, the number, size, angle, etc. of each component) given in the above embodiment are examples, and other numerical values can naturally be adopted.

  For example, in the above embodiment, there are cases where three first to third inner radial ribs 16b1 to 16b3, 17b1 to 17b3 and six first to third outer radial ribs 16c1 to 16c6 and 17c1 to 17c6 are provided. Although described, it is not necessarily limited to this number, and it is naturally possible to adopt other numbers. For example, two inner radial ribs and four outer radial ribs may be used. Alternatively, the inner radial ribs may be four or more and the outer radial ribs may be eight or more.

  Moreover, although the case where the opening angle α of the inner and outer radial ribs 16a1 to 17c6 is set to α = 10 ° has been described in the above embodiment, the present invention is not necessarily limited to this angle, and other angles are adopted. Also good. Similarly, other angles may be adopted for the opening angles θ1 to θ6 of the first to sixth outer openings 24c1 to 24c6, 34c1 to 34c6.

It is sectional drawing of the liquid filled type vibration isolator in one embodiment of this invention. (A) is a top view of the orifice fitting, and (b) is a cross-sectional view of the orifice fitting taken along line IIb-IIb in FIG. 2 (a). It is a side view of an orifice metal fitting. It is a top view of an orifice metal fitting. (A) is a top view of a partition plate member, (b) is sectional drawing of the partition plate member in the Vb-Vb line | wire of Fig.5 (a). (A) is a top view of an elastic partition membrane, (b) is a cross-sectional view of the elastic partition membrane taken along line VIb-VIb in FIG. 6 (a). (A) is a top view of a clamping member, (b) is sectional drawing of the clamping member in the VIIb-VIIb line | wire of Fig.7 (a). (A) is a top view of a partition body and a clamping member, (b) is sectional drawing of the partition body and clamping member in the VIIIb-VIIIb line | wire of Fig.8 (a). It is a figure which shows the result of a dynamic load test.

Explanation of symbols

100 Liquid-sealed vibration isolator 1 First mounting bracket (first mounting bracket)
2 Second mounting bracket (second mounting bracket)
6 Cylindrical metal fittings (part of second fixture)
7 Bottom bracket (part of second fixture)
3 Antivibration Base 11 Liquid Filling Chamber 11A First Liquid Chamber 11B Second Liquid Chamber 9 Diaphragm 12 Partition 15 Elastic Partition Membrane (Part of Partition)
15 × 1 One side of elastic partition membrane 15 × 2 Other side of elastic partition membrane 16 Orifice member (part of partition)
16a1 Central annular rib (part of the regulating plate member)
16a2 inner annular rib (a part of the regulating plate member)
16a3 outer annular rib (part of regulating plate member)
16b1 to 16b3 first to third inner radial ribs (a part of the regulating plate member)
16b1 first inner radial rib (inner first rib)
16c1-16c6 1st-6th outside radial rib (a part of regulation board member)
16c1 1st outside radial rib (outside 1st rib)
21a Notch (opening on the first liquid chamber side)
21a1 end (end on the orifice channel side)
21a2 end (end opposite to orifice flow path)
24a Center opening (part of opening)
24b Inner opening (part of opening)
24b1-24b3 1st-3rd inner side opening part (a part of inner side opening part)
24c Outside opening (part of opening)
24c1-24c6 1st-6th outside opening (a part of outside opening)
17 Partition member (part of partition)
17a1 Central annular rib (part of the regulating plate member)
17a2 Inner annular rib (part of regulating plate member)
17a3 Outer annular rib (part of regulating plate member)
17b1 to 17b3 First to third inner radial ribs (a part of the regulating plate member)
17b1 first inner radial rib (inner first rib)
17c1-17c6 1st-6th outside radial rib (a part of regulation board member)
17c1 first outer radial rib (outer first rib)
34a Center opening (part of opening)
34b Inner opening (part of opening)
34b1-34b3 1st-3rd inner side opening part (a part of inner side opening part)
34c Outer opening (part of opening)
34c1-34c6 1st-6th outer side opening part (a part of outer side opening part)
25 Orifice O shaft center

Claims (8)

A first fixture, a cylindrical second fixture, a vibration isolating base that connects the second fixture and the first fixture and is made of a rubber-like elastic body, and the second fixture. A diaphragm that is attached to form a liquid sealing chamber between the vibration isolating substrate and a partition that partitions the liquid sealing chamber into a first liquid chamber on the vibration isolating substrate side and a second liquid chamber on the diaphragm side; An orifice formed between the outer peripheral side of the partition and the inner peripheral side of the second fixture, and communicating the first liquid chamber and the second liquid chamber with each other,
The partition body is provided with an elastic partition film formed in a disk shape from a rubber-like elastic material, and an opening, and is disposed opposite to both sides of the elastic partition film, and the elastic partition film is displaced by the remaining part of the opening. In a liquid-filled vibration isolator configured to include a pair of regulating plate members that regulate
The opening includes a plurality of outer openings formed by radially dividing an annular hole along the inner periphery of the second fixture,
Each of the plurality of outer openings is configured to have an opening area having a size different from that of the other outer openings, and is arranged in order of the opening area.
The arrangement direction when the plurality of outer openings are arranged in order from the smallest opening area to the largest one is that the liquid flowing from the second liquid chamber to the first liquid chamber through the orifice is the first. 2. A liquid-filled vibration isolator having the same direction as the flow direction in the first liquid chamber along the inner periphery of the fixture. A plurality of inner openings formed inside the plurality of outer openings and formed by radially dividing an annular hole along the inner periphery of the second fixture;
The plurality of inner openings are each configured to have an opening area having a size different from that of the other inner openings, and are arranged in the order of the opening area,
The arrangement direction when the plurality of inner openings are arranged in order from the smallest opening area to the largest one is that when the plurality of outer openings are arranged in order from the smallest opening area to the largest one. The liquid-filled vibration isolator according to claim 1, wherein the liquid-filled vibration isolator is in the same direction as the arrangement direction.   The plurality of outer openings and the plurality of inner openings are each configured to have an opening area having a size different from that of the other outer openings and the inner openings. Liquid-filled vibration isolator.   The orifice is formed in an elongated hole shape in which the inlet / outlet on the first liquid chamber side is curved along the inner periphery of the second fixture, and is the longitudinal end portion of the elongated hole shape on the orifice channel side Is located on a region where the first outer rib formed between the one having the maximum opening area and the one having the smallest opening area among the plurality of outer opening portions is extended. The liquid-filled vibration isolator according to any one of claims 1 to 3.   The end portion in the longitudinal direction of the elongated hole shape that is opposite to the orifice channel is located outside the outer opening portion having the second smallest opening area in the plurality of outer opening portions. The liquid-filled type vibration damping device according to claim 4, wherein:   The inner first rib formed between the one having the largest opening area and the smallest opening area among the plurality of inner opening portions is disposed at the same circumferential position as the outer first rib. The liquid-filled vibration isolator according to any one of claims 1 to 3.   The ratio between the number of the inner openings and the number of the outer openings is 1: 2, and all of the ribs formed between the plurality of inner openings are The liquid filled type vibration damping device according to claim 6, wherein the liquid filled type vibration damping device is disposed at the same circumferential position as any one of the ribs respectively formed between the plurality of outer openings. The orifice is formed in an elongated hole shape in which an inlet / outlet on the first liquid chamber side is curved in an arc shape,
The elongated hole-shaped arc, the ring shape formed by the array of the plurality of outer openings, and the ring shape formed by the array of the plurality of inner openings have the same axis. The liquid-filled vibration isolator according to claim 2 or 3.

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