JP3731412B2 - Fluid-filled vibration isolator and manufacturing method thereof - Google Patents

Description

[0001]
【Technical field】
The present invention relates to a fluid-filled vibration isolator that uses a fluid action of an incompressible fluid that flows through an orifice passage to obtain a vibration isolation effect, and a manufacturing method thereof. The present invention relates to a fluid filled type vibration damping device that can be controlled from the outside and an advantageous manufacturing method thereof.
[0002]
[Background]
Conventionally, as a type of vibration isolator such as an anti-vibration coupling body and an anti-vibration support body that are interposed between members to be anti-vibration coupled, the first mounting bracket and the second mounting bracket are conventionally made of a rubber elastic body. A fluid-filled vibration isolator that connects and forms a plurality of fluid chambers that are connected to each other by an orifice passage and obtains a vibration isolation effect based on the flow action of an incompressible fluid through the orifice passage. Are known. In order to achieve a higher level of anti-vibration effect, for example, in Japanese Patent Laid-Open Nos. 6-264958 and 11-22778, an orifice is inserted into the cylindrical portion of the second mounting bracket. There has been proposed a fluid-filled vibration isolator having a structure in which an anti-vibration characteristic can be controlled from the outside by incorporating a rotary valve for switching the orifice passage with respect to the orifice member forming the passage. JP-A-77642, JP-A-10-184770, and the like form a working air chamber in an orifice member that is inserted in the cylindrical portion of the second mounting bracket and forms an orifice passage. A fluid-filled vibration isolator has been proposed that controls the fluid flow through the orifice passage by controlling the pressure of the fluid to control the vibration isolation characteristics from the outside. There.
[0003]
By the way, in the vibration isolator incorporating the former rotary valve, it is necessary to form a drive shaft disposition hole that exerts a rotational driving force on the rotary valve, and the latter is provided with a working air chamber. In this case, it is necessary to form an air passage for applying air pressure to the working air chamber. These arrangement holes, air passages, etc., as described in the above publication, are generally provided in the orifice member with a control hole formed on the outer peripheral surface thereof as a second attachment. It is configured by opening and communicating with the outside through a through hole provided in the cylindrical portion of the metal fitting.
[0004]
However, in the fluid-filled vibration isolator having such a structure, the incompressible fluid sealed in the fluid chamber may leak through the through-hole provided in the cylindrical portion of the second mounting bracket. Take Penetrating It is important to ensure the sealing property of the sealed fluid in the through hole sufficiently stably.
[0005]
Therefore, for example, a thin seal rubber layer is formed on substantially the entire inner peripheral surface of the cylindrical portion of the second mounting bracket, and an orifice member is press-fitted into the cylindrical portion, and the space between the cylindrical portion and the orifice member is increased. Formed in the cylindrical part by narrowing the sealing rubber layer with Penetrating It is conceivable to ensure the sealing performance of the through holes. However, in such a method, in order to obtain sufficient sealing performance, if the narrow pressure on the sealing rubber layer between the cylindrical portion and the orifice member is set large, extremely high component dimensions accuracy In addition to making the manufacturing process cumbersome, the seal rubber layer is likely to be damaged during press-fitting, and the press-fitting work of the orifice member is difficult due to the spring back of the seal rubber layer. It was not an effective measure.
[0006]
Note that it is possible to obtain a large narrow pressure on the seal rubber layer between the cylindrical portion and the orifice member by drawing the cylindrical portion after inserting the orifice member. In addition to troublesome diameter reduction processing such as, the shape of the second mounting bracket is not necessarily an effective measure because the diameter reduction processing for the cylindrical portion may be extremely difficult depending on the structure. It was.
[0007]
[Solution]
Here, the present invention has been made against the background of the above-mentioned circumstances, and the problem to be solved thereof is a hole for arranging a drive shaft of a rotary valve, a hole for an air passage for air pressure control, and the like. Of the cylindrical part of the second mounting member used Penetrating To provide a novel fluid-filled vibration isolator and a method for manufacturing a fluid-filled vibration isolator that can sufficiently and stably ensure the sealing performance of the sealed fluid in a through hole with a simple structure. is there.
[0008]
[Solution]
Hereinafter, the aspect of this invention made | formed in order to solve such a subject is described. In addition, each aspect described below can be employed in any combination. The aspects and technical features of the present invention are not limited to those described below, but are described in the whole specification and drawings, or based on the inventive concept that can be grasped by those skilled in the art from these descriptions. It should be understood that
[0009]
First, according to a first aspect of the present invention relating to a fluid-filled vibration isolator, the first mounting member is disposed apart from the second mounting member provided with the cylindrical portion, and the first mounting member is disposed. The member and the second mounting member are connected by the main rubber elastic body, and an incompressible fluid is sealed, and a relative pressure difference is applied when vibration is input between the first mounting member and the second mounting member. A plurality of fluid chambers are formed, while an orifice member is inserted and disposed in the cylindrical portion of the second mounting member, and the outer peripheral surface of the orifice member is surrounded by the inner periphery of the cylindrical portion. The orifice member is fixed in close contact with the surface, and the orifice member communicates the plurality of fluid chambers with each other. A control hole is provided in the orifice member for controlling vibration isolation characteristics of the orifice passage from the outside. Of the second mounting member Through the through hole provided in the cylindrical portion, allowed opened 該制 patronized hole to the outside Flow In the body-encapsulated vibration isolator, a seal rubber layer is disposed between the orifice member and the cylindrical portion of the second mounting member, and the outer peripheral surface of the orifice member and the inner peripheral surface of the cylindrical portion are arranged. The The seal rubber layer is put in close contact with the entire circumference, and the compression ratio exerted on the seal rubber layer is changed in the circumferential direction between the orifice member and the cylindrical portion, and compressed in the radial direction where the through hole is located. The highest rate And a valve means for opening and closing the orifice passage is incorporated in the orifice member, and a drive shaft of the valve means is disposed through the control hole of the orifice member and the through hole of the cylindrical portion. This is a feature.
[0010]
In the fluid-filled vibration isolator having the structure according to this aspect, the clamping pressure exerted on the seal rubber layer between the orifice member and the cylindrical portion (second mounting member) is uniform over the entire circumference. However, in the vicinity of the through hole of the cylindrical portion where fluid tightness is a problem, the compression rate in the seal rubber layer is maximized and a large clamping pressure is exerted. Therefore, the compressibility of the seal rubber layer is maximized in the vicinity of the through-hole of the cylindrical part where the fluid sealability becomes a problem, and an excellent sealability can be stably obtained.
[0011]
In addition, by reducing the compression rate with respect to the seal rubber layer at the part of the cylindrical part that is out of the through hole, for example, even when the orifice member is pressed into the cylindrical part and assembled, By securing the escape space, it is effective to apply a large clamping pressure to the seal rubber layer in the vicinity of the through-hole of the cylindrical portion while avoiding damage to the seal rubber layer and deterioration of the press-fitting operation due to springback. A sealing property can be obtained. In addition, for example, even if it is extremely difficult to draw the cylindrical portion because the shape of the second mounting member is complicated, the processing is performed in the through hole of the cylindrical portion. Therefore, it is possible to easily obtain excellent sealing performance without any problems.
[0012]
In this first aspect, the compression ratio exerted on the seal rubber layer is relative to the radial free length dimension (thickness free dimension) of the seal rubber layer before the orifice member is assembled to the cylindrical portion. The ratio of the radial dimension (thickness change dimension) in which the seal rubber layer is compressed by assembling the orifice member. In addition, various configurations can be adopted as a specific configuration for changing the compression rate exerted on the seal rubber layer in the circumferential direction to maximize the compression rate in the radial direction where the through hole is located. In this embodiment, the second mounting member having a cylindrical portion whose inner diameter is not constant in the circumferential direction, a seal rubber layer whose inner diameter is not constant in the circumferential direction, and an orifice member whose outer diameter is not constant in the circumferential direction. By adopting at least one of the above, it can be advantageously realized. That is, by adopting at least one of such a second mounting member, a seal rubber layer, and an orifice member, the through hole can be formed only by assembling the orifice member into the cylindrical portion of the second mounting member by press fitting or the like. A configuration in which the compression rate of the seal rubber layer is set to be the largest in the radial direction in which the seal rubber layer is located can be advantageously realized.
[0013]
In the fluid-filled vibration isolator having the structure according to the first aspect, the seal rubber layer is formed by bonding to, for example, at least one of the outer peripheral surface of the orifice member and the inner peripheral surface of the cylindrical portion, The seal rubber layer can be easily and stably disposed and positioned between the cylindrical portion and the pressure contact portion of the orifice member.
[0014]
Therefore, the second aspect of the present invention relating to the fluid-filled vibration isolator is characterized in that such a seal rubber layer is formed by adhesion on the inner peripheral surface of the cylindrical portion of the second mounting member. According to this aspect, the seal rubber layer can be formed more easily. For example, the seal rubber layer and the main rubber elastic body are integrally formed and bonded to the second mounting bracket, respectively. Thus, it becomes possible to improve the manufacturability.
[0015]
Accordingly, a third aspect of the present invention is the fluid-filled type vibration damping device having the structure according to the first or second aspect, wherein the outer peripheral surface of the orifice member passes through the through hole of the cylindrical portion. A large-diameter protrusion that protrudes outward toward at least one side in the radial direction is formed.
[0016]
According to a fourth aspect of the present invention, there is provided a fluid-filled vibration isolator having a structure according to any one of the first to third aspects, wherein the seal rubber layer is provided on an inner peripheral surface of the cylindrical portion. In addition to forming an adhesive, on the inner peripheral surface of the seal rubber layer, a small-diameter protrusion projecting radially inward is formed on at least one side of both side portions opposed to each other in the radial direction passing through the through hole of the cylindrical portion. It is a feature. In forming such a small-diameter protrusion, a cylindrical portion having an inner diameter dimension that is substantially constant over the entire circumference is adopted, and the thickness dimension of the seal rubber layer provided on the inner circumferential surface thereof is changed in the circumferential direction. Alternatively, the thickness of the sealing rubber layer may be substantially constant over the entire circumference, and the inner diameter of the cylindrical portion may be changed in the circumferential direction.
[0017]
That is, according to the third or fourth aspect, the configuration in which the compression rate exerted on the seal rubber layer is changed in the circumferential direction and the compression rate is maximized in the radial direction where the through hole is located is advantageously realized. To get.
[0018]
In the third aspect, more preferably, a pair of large-diameter protrusions are formed on the outer peripheral surface of the orifice member so as to protrude outwardly toward both sides in the radial direction passing through the through hole of the cylindrical portion. . In the fourth aspect, more preferably, on the inner peripheral surface of the sealing rubber layer provided in the cylindrical portion, a pair that protrudes inward toward both sides in the radial direction where the through holes of the cylindrical portion are located. Are formed. As a result, a more effective clamping pressure can be more stably applied to the seal rubber layer located in the vicinity of the through hole of the cylindrical portion. Furthermore, when these large-diameter projections and internal-diameter projections are formed on the through hole side of the cylindrical portion, they are formed over a larger range than the through hole so as to cover the periphery of the through hole. However, when it is formed on the opposite side opposite to the through hole in the radial direction, it is not necessarily larger than the through hole as long as an effective clamping force can be exerted on the seal rubber layer around the through hole.
[0019]
According to a fifth aspect of the present invention, in the fluid-filled vibration isolator having the structure according to any one of the first to fourth aspects, the seal rubber layer is disposed between the orifice member and the cylindrical portion. The compression ratio exerted is such that the maximum value at the both sides in the radial direction where the through-holes are located is 35% to 65%, and the minimum value at the both sides in the radial direction perpendicular thereto is 4% to 10%. It is characterized by setting. In this embodiment, even better sealing performance around the through hole can be secured more stably, and even when the orifice member is assembled into the cylindrical portion by press fitting, The press-fitting work can be easily performed. It is more preferable that the compression rate of 35% to 65% is exerted on the seal rubber layer over the entire region including the through hole and larger than the through hole at both radial side portions where the through hole is located. The compression rate is set to 4% to 10% with respect to the seal rubber layer throughout the other region.
[0020]
Also The first aspect of the present invention According to this, a fluid filled type vibration damping device capable of controlling the vibration damping characteristics by opening / closing or switching the orifice passage can be advantageously realized with an excellent sealing property of the filled fluid. As the valve means, for example, a rotary valve that opens and closes the orifice passage by turning around the central axis of the drive shaft disposed in the control hole is preferably employed. Further, in order to advantageously secure the assembling property of the orifice member to the cylindrical portion, the valve means is desirably assembled so as not to protrude outward from the outer peripheral surface of the orifice member. For example, after the orifice member is assembled to the cylindrical portion, the orifice member can be disposed by being inserted from the outside through the through hole of the cylindrical portion and connected to the valve means. Furthermore, in this embodiment, for example, the valve means opens and closes one orifice passage, adjusts the amount of opening, and is formed across a plurality of fluid chambers and tuned differently from each other. A structure in which one orifice passage and a second orifice passage are provided and the both orifice passages are selectively communicated with each other by valve means can be advantageously employed.
[0021]
Also, the first aspect of the present invention relating to a fluid-filled vibration isolator Six The first to the second aspects Five In the fluid-filled vibration isolator having the structure according to any one of the first aspect, the first fluid chamber in which a part of the wall part is configured by the main rubber elastic body, and the elasticity in which a part of the wall part is deformable A plurality of fluid chambers are formed including a second fluid chamber formed of a membrane and provided in the orifice member, and the first fluid chamber and the second fluid chamber communicate with each other. The orifice passage is configured to include the first orifice passage, while the working air chamber is formed on the opposite side of the second fluid chamber across the elastic membrane, and by the control hole of the orifice member, An air passage for controlling the air pressure of the working air chamber is configured. According to this embodiment, the vibration damping characteristic is controlled by adjusting the tuning frequency of the first orifice passage by controlling the air pressure of the working air chamber and emphasizing the rigidity of the wall spring of the second fluid chamber. By directly controlling the internal pressure of the fluid chamber according to the vibration to be vibrated by actively exerting air pressure fluctuations on the working air chamber, An active type fluid-filled vibration damping device or the like that actively controls vibration-proof characteristics can be advantageously realized with excellent sealing performance of the sealed fluid. In order to advantageously secure the assembly of the orifice member to the cylindrical portion, it is desirable that the control hole constituting the air passage be formed without protruding from the outer peripheral surface of the orifice member. In this case, for example, after assembling the orifice member to the cylindrical portion, the separate air conduit is inserted into the control hole from the outside through the through hole of the cylindrical portion and fixed, etc. It can be done advantageously.
[0022]
In addition, the first of the present invention Seven The first to the second aspects Six In the fluid-filled vibration isolator configured according to any one of the aspects, the first mounting member is disposed opposite to the one opening side in the axial direction of the cylindrical portion of the second mounting member, The first mounting member and the cylindrical portion are elastically connected to each other by the main rubber elastic body, whereby one axial side opening of the cylindrical portion is fluid-tightly closed and the cylindrical shape is The other opening side in the axial direction of the part is fluid-tightly closed by a lid member at least partially made of a flexible film, while the orifice member is formed into a substantially circular block shape and is inserted into the cylindrical part. A pressure receiving chamber in which a part of the wall is made of the rubber elastic body of the main body and an internal pressure fluctuation is generated at the time of vibration input on both sides in the axial direction across the arranged orifice member, and a part of the wall is allowed to be Equilibrium chamber made of flexible membrane and variable volume Forming the plurality of fluid chambers including the pressure receiving chamber and the equilibrium chamber, and forming a second orifice passage for communicating the pressure receiving chamber and the equilibrium chamber with each other by the orifice member, The orifice passage is configured to include the orifice passage. In such a mode, the orifice member also acts as a partition member that partitions the plurality of fluid chambers, and particularly exhibits an effective anti-vibration effect against vibration input in the axial direction of the cylindrical portion. For example, a fluid-filled vibration isolator of a type suitably used for, for example, an FR engine (front engine, rear drive type) automobile engine mount or the like is advantageously realized.
[0023]
Furthermore, the present invention Eight The first to the second aspects Five In the fluid-filled vibration isolator having a structure according to any of the above aspects, the first mounting member is substantially rod-shaped, and the entire second mounting member is configured by the cylindrical portion. The second mounting member is disposed to be spaced outward in the direction perpendicular to the axis of the first mounting member, and the main body rubber is disposed on the opposing surface in the direction perpendicular to the axis of the first mounting member and the second mounting member. While the elastic body is interposed, the plurality of fluid chambers are formed between the first and second mounting members facing each other in the direction perpendicular to the axis, and the orifice member has a substantially cylindrical shape. The orifice passage is formed so as to extend in the circumferential direction along the inner peripheral surface of the second attachment member by the orifice member inserted and arranged in the attachment member. In this embodiment, the anti-vibration effect that is particularly effective against vibration input in a direction perpendicular to the axis of the cylindrical portion can be exhibited. For example, FF type (front engine, front drive type) automobile engine mount, etc. A cylindrical-type fluid-filled vibration isolator that is preferably employed in the present invention is advantageously realized. In this aspect, for example, a configuration in which a plurality of fluid chambers are disposed so as to be opposed to both sides sandwiching the first mounting member in the direction perpendicular to the axis is suitably employed, whereby the plurality of fluid chambers are adopted. A fluid-filled cylindrical vibration isolator capable of exhibiting an effective anti-vibration effect with respect to vibrations input in a radial direction opposite to each other is advantageously realized.
[0024]
On the other hand, one aspect of the present invention relating to a manufacturing method of a fluid filled type vibration damping device is the first to the second Eight When manufacturing a fluid-filled vibration isolator having a structure according to any one of the above-mentioned embodiments, the seal rubber layer is bonded to the inner peripheral surface of the cylindrical portion of the second mounting member, and then the orifice member Is pressed and fixed in the axial direction with respect to the cylindrical portion, thereby changing the compression ratio exerted on the seal rubber layer between the orifice member and the cylindrical portion in the circumferential direction, and the diameter at which the through hole is located. The feature is that the compression ratio is maximized in the direction.
[0025]
According to such a method of the present aspect, the compression ratio exerted on the seal rubber layer is not required by special drawing processing or the like only by press-fitting and assembling the orifice member into the cylindrical portion of the second mounting member. Can be set to be the largest in the radial direction in which the through hole is located, so that fluid tightness in the through hole can be easily and advantageously ensured.
[0026]
The present invention according to each of the above embodiments can selectively open or close two or three or more orifice passages in addition to opening and closing one orifice passage or adjusting the opening degree by rotating the rotary valve. Can be advantageously applied to a fluid-filled vibration isolator whose opening is adjusted. Further, apart from the orifice passage where opening / closing and opening adjustment by the rotary valve are performed, it is also possible to form an orifice passage which is always in communication between the fluid chambers. By adopting such an orifice structure, it is possible to obtain an effective vibration isolation effect against a wider variety of input vibrations. It should be noted that, as the orifice passage that is always in a communication state, preferably, an orifice passage that is tuned to a lower frequency range than the orifice passage that is opened and closed by a rotary valve can be suitably employed, and thereby the orifice passage can be opened and closed. Therefore, the orifice passage that is always in communication and the orifice passage that is opened and closed by the rotary valve can be selectively operated without requiring any special switching means other than the rotary valve.
[0027]
In the fluid filled type vibration damping device according to the present invention, it is possible to provide a plurality of control holes in the orifice member and a plurality of through-holes in the cylindrical portion in the second mounting member. The control hole and the through hole are formed to open at substantially the same position on the circumference. Further, two control holes and a through hole are provided, and the first control hole and the through hole are provided with respect to the first control hole and the through hole. one According to the embodiment, the drive shaft of the valve means is arranged, and the other control hole and the through hole Six It is also possible to configure an air passage according to the above aspect.
[0028]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, in order to clarify the present invention more specifically, embodiments of the present invention will be described in detail with reference to the drawings.
[0029]
1 to 4 show an FR-type automobile engine mount 10 according to a first embodiment of the present invention. The engine mount 10 includes a first mounting member 12 as a first mounting member and a second mounting member 14 as a second mounting member that are spaced apart from each other and disposed between opposing surfaces. It is elastically connected by the interposed main rubber elastic body 16. The engine mount 10 is configured such that one of the first mounting bracket 12 and the second mounting bracket 14 is fixedly mounted on the power unit side and the other is mounted on the body side. It is designed to support vibration isolation. Further, under such a mounted state, the power of the power unit is exerted on the engine mount 10 in a substantially vertical direction in FIG. 1 which is a substantially opposing direction of the first mounting bracket 12 and the second mounting bracket 14. The main rubber elastic body 16 is elastically deformed in a direction in which the first mounting bracket 12 and the second mounting bracket 14 approach each other, and the first mounting bracket 12 and the second mounting bracket 14 are substantially opposed to each other. The main vibration to be damped is input. In the following description, the vertical direction means the vertical direction in FIG. 1 in principle.
[0030]
More specifically, the first mounting bracket 12 has a substantially disc shape, and the second mounting bracket 14 protrudes radially outward at one location on the outer periphery of the first mounting bracket 12. A stopper protrusion 18 is integrally formed with the tip portion bent in a hook shape while being bent and extended toward the side. Further, a substantially cup-shaped support fitting 20 is overlapped and welded at the center of the lower surface of the first attachment fitting 12 at the opening. Furthermore, a mounting bolt 22 that protrudes upward is fixed at the center of the first mounting bracket 12, and the first mounting bracket 12 is used as a power unit of an automobile (not shown) by the mounting bolt 22. It can be attached.
[0031]
On the other hand, the second mounting bracket 14 is formed by a cylindrical bracket 24 as a cylindrical portion having a large-diameter substantially cylindrical shape and a bottom bracket 26 having a large-diameter shallow bottom and a substantially bottomed cylindrical shape. The cylindrical metal fitting 24 has a taper portion 28 whose upper end in the axial direction expands upward, while a stepped portion 30 that extends radially outward is formed at the lower end in the axial direction. A large-diameter cylindrical caulking portion 32 extending downward in the axial direction from the outer peripheral edge portion of the stepped portion 30 is integrally formed. In addition, an abutting protrusion 36 that protrudes radially outward and is reinforced by a reinforcing metal fitting 34 is integrally formed at an opening peripheral edge portion of the tapered portion 28 in the cylindrical metal fitting 24 at one location on the circumference. On the other hand, a flange-like portion 38 that extends outward in the radial direction is integrally formed at the opening peripheral edge of the bottom metal fitting 26. Then, the bottom metal fitting 26 is overlapped with the lower opening of the cylindrical metal fitting 24, and the caulking portion 32 of the cylindrical metal fitting 24 is caulked and fixed to the flange-like portion 38 of the bottom metal fitting 26. The mounting bracket 14 is formed with a substantially bottomed cylindrical shape having a deep bottom as a whole. A mounting bolt 40 protruding downward is fixed at the bottom center of the bottom metal fitting 26, and the second mounting metal 14 is attached to the body of an automobile (not shown) by this mounting bolt 40. It has become.
[0032]
The second mounting bracket 14 is disposed so as to open upward in the axial direction, and is spaced apart from the opening of the second mounting bracket 14 so that the first mounting bracket 12 is The second mounting bracket 14 is disposed on substantially the same central axis. Thus, the main rubber elastic body 16 is disposed between the first mounting metal 12 and the second mounting metal 14, and the main rubber elastic body 16 allows the first mounting metal 12 and the second mounting metal 12 to be connected to each other. Are attached elastically. The main rubber elastic body 16 has a generally frustoconical shape as a whole, the first mounting bracket 12 is superimposed on the end surface on the small diameter side, and the support bracket 20 is inserted in the axial direction from the end surface on the small diameter side to be embedded. In the inserted state, the first mounting bracket 12 and the support bracket 20 are vulcanized and bonded to the main rubber elastic body 16. Further, on the outer peripheral surface of the large-diameter side end portion of the main rubber elastic body 16, the inner peripheral surface of the tapered portion 28 in the cylindrical metal fitting 24 constituting the second mounting metal fitting 14 is overlapped and vulcanized and bonded. In short, in this embodiment, as shown in FIG. 5 and FIG. 6, the main rubber elastic body 16 is an integral vulcanized molded product 45 including the first mounting bracket 12, the support bracket 20, and the cylindrical bracket 24. The opening on the upper side in the axial direction of the cylindrical fitting 24 is closed fluid-tightly by the main rubber elastic body 16.
[0033]
In this integrally vulcanized molded product 45, the tapered outer peripheral surface of the support fitting 20 on the first attachment fitting 12 side and the tapered portion 28 of the tubular fitting 24 on the second attachment fitting 14 side are spaced apart from each other. The main rubber elastic body 16 is interposed between the opposing surfaces so that a load such as a power unit weight can be effectively applied to the main rubber elastic body 16 as a compressive force. Has been. Further, in the integrally vulcanized molded product 45, a large-diameter recess 42 is formed on the large-diameter side end face of the main rubber elastic body 16 and is opened in the cylindrical metal fitting 24. On the inner peripheral surface, there is a thin seal rubber layer 43 that extends over substantially the entire surface, and an annular seal rubber protrusion 53 that protrudes in the axial direction on the stepped portion 30, respectively, integrally with the main rubber elastic body 16. Is formed. Furthermore, a shock absorbing rubber 44 is formed on the surface of the contact projection 36 of the second mounting bracket 14, and the stopper projection of the first mounting bracket 12 covers the contact projection 36. Part 18 is aligned. When the first mounting bracket 12 and the second mounting bracket 14 are largely displaced relative to each other by an input vibration load or the like, the stopper projection 18 is brought into contact with the abutment projection 36 via the buffer rubber 44. The stopper function of limiting the relative displacement amount of the first mounting bracket 12 and the second mounting bracket 14 and the elastic deformation amount of the main rubber elastic body 16 is exhibited. Yes.
[0034]
Here, in particular, in such an integrally vulcanized molded product 45, the cylindrical metal fitting 24 has a substantially circular shape with an inner diameter: D1 (see FIG. 6), and an axially intermediate portion that occupies most of the cylindrical fitting 24. The seal rubber layer 43 that is vulcanized and bonded to substantially the entire inner peripheral surface of the cylindrical metal fitting 24 is also made to have a substantially constant thickness over the entire surface, so that the inner peripheral surface of the seal rubber layer 43 extends over the entire circumference in the circumferential direction. The shape is a perfect circle having a substantially constant inner diameter dimension D2 (see FIG. 6). Further, as described above, the axially intermediate portion of the tubular fitting 24, which has a substantially constant inner diameter dimension throughout, is located substantially at the center in the axial direction and penetrates the tubular fitting 24 and the seal rubber layer 43. One circular through-hole 47 is formed in the inner and outer peripheral surfaces.
[0035]
Furthermore, a partition member 46 and a diaphragm 48 as an easily deformable flexible film are sequentially inserted and fitted into the integrally vulcanized molded product 45 from the lower opening in the axial direction of the tubular fitting 24, and the second The mounting bracket 14 is fixedly assembled. The partition member 46 as an orifice member has a substantially circular block shape having an outer peripheral surface slightly smaller in diameter than the cylindrical metal member 24. Further, the outer peripheral edge at the lower end in the axial direction of the partition member 46 extends in a cylindrical shape downward in the axial direction, and the protruding tip is bent outward in the radial direction, whereby the flange-shaped portion 50 is integrated. Is formed. The partition member 46 is inserted into the tubular fitting 24, the outer peripheral surface thereof is in close contact with the tubular fitting 24 via the seal rubber layer 43, and the flange-shaped portion 50 is overlapped with the stepped portion 30 of the tubular fitting 24. Then, it is fixedly attached to the second mounting member 14 by being caulked and fixed by the caulking portion 32 together with the flange-like portion 38 of the bottom metal fitting 26. The diaphragm 48 is formed of a thin rubber film that can be easily deformed. The center portion is slack so that it can be easily deformed, and the outer peripheral edge portion is fixed in a substantially annular plate shape. The metal fitting 52 is vulcanized and bonded. The diaphragm 48 is inserted into the tubular fitting 24, and the fixing fitting 52 is superimposed on the stepped portion 30 of the tubular fitting 24, and is caulked and fixed together with the flange-like portion 38 of the bottom fitting 26. The lower opening of the mounting bracket 14 is attached in a state of covering the fluid tightly. In addition, between the fixing bracket 52 and the stepped portion 30 of the second mounting bracket 14, the seal rubber protrusion 53 is clamped and the caulking fixing portion is fluid-tightly sealed.
[0036]
As a result, the opening portions on both sides of the cylindrical metal member 24 are fluid-tightly covered with the main rubber elastic body 16 and the diaphragm 48 to form a fluid storage chamber 54 in which an incompressible fluid is sealed. As the incompressible fluid to be enclosed, for example, water, alkylene glycol, polyalkylene glycol, silicone oil or the like can be employed. In particular, in order to effectively obtain a vibration isolation effect based on the resonance action of the fluid described later, 0 A low-viscosity fluid of 1 Pa · s or less is preferably employed. The incompressible fluid can be injected at the same time as the formation of the fluid storage chamber 54 by, for example, assembling the partition member 46 and the diaphragm 48 to the integrally vulcanized molded product in the fluid. In this embodiment, after the partition member 46 and the diaphragm 48 are assembled to the integrally vulcanized molded product in the atmosphere, the vacuum is passed through the injection hole 56 drilled in the fixing bracket 52 vulcanized and bonded to the diaphragm 48. The incompressible fluid is injected into the fluid storage chamber 54 by utilizing pulling or the like as necessary, and then the injection hole 56 is sealed with a blind rivet 58 to fill the incompressible fluid. .
[0037]
Further, the fluid storage chamber 54 is fluid-divided into two by a partition member 46 disposed in the axially intermediate portion of the cylindrical metal member 24, so that a part of the wall portion is above the partition member 46. A pressure receiving chamber 60 as a first fluid chamber constituted by the main rubber elastic body 16 is formed. On the lower side of the partition member 46, a second wall portion is constituted by a diaphragm 48. An equilibrium chamber 62 is formed as a fluid chamber. The partition member 46 is made of a hard material such as an aluminum alloy or a synthetic resin. That is, in the pressure receiving chamber 60, when a vibration is input between the first mounting bracket 12 and the second mounting bracket 14, a vibration is input based on the elastic deformation of the main rubber elastic body 16 to cause a pressure change. On the other hand, the balance chamber 62 is designed to absorb and avoid the change in pressure because the volume change is easily allowed by the deformation of the diaphragm 48. An air chamber 64 is formed on the side opposite to the equilibrium chamber 62 across the diaphragm 48 and is positioned between the diaphragm 48 and the bottom metal fitting 26 and allows the diaphragm 48 to be deformed.
[0038]
Further, the partition member 46 that partitions the pressure receiving chamber 60 and the equilibrium chamber 62 communicates with the pressure receiving chamber 60 and the equilibrium chamber 62 to allow fluid flow between the chambers 60 and 62. 66, the medium frequency orifice passage 68 and the high frequency orifice passage 70 are formed substantially independently of each other. Then, based on the pressure difference generated between the pressure receiving chamber 60 and the equilibrium chamber 62 at the time of vibration input, fluid flow through these orifice passages 66, 68, 70 is generated, so that each of the orifice passages 66, The anti-vibration effect based on the resonance action of the fluid is exhibited against the input vibration in the frequency range corresponding to the tunings 68 and 70, respectively. In the present embodiment, these three orifice passages 66, 68, 70 are all formed as second orifice passages that allow the pressure receiving chamber 60 and the equilibrium chamber 62 to communicate with each other.
[0039]
Specifically, first, the partition member 46 is provided with a concave groove 112 that opens to the upper surface and extends an outer peripheral portion with a length of a little less than one circumference in the circumferential direction, and a thin wall is formed on the upper surface of the partition member 46. A disc-shaped lid fitting 78 is overlapped over the entire surface, and the concave groove 112 is covered with the lid fitting 78. One end portion in the circumferential direction of the concave groove 112 is opened to the pressure receiving chamber 60 through a communication hole 114 penetrating the lid fitting 78, while the other end portion in the circumferential direction of the concave groove 112 is formed in the partition member 46. The balance chamber 62 is opened through a connection hole 116 penetrating in the axial direction. Accordingly, the low frequency that includes the concave groove 112, the communication hole 114, and the connection hole 116, extends across the pressure receiving chamber 60 and the equilibrium chamber 62, and allows fluid flow between the chambers 60 and 62. An orifice passage 66 is formed. In the present embodiment, the low-frequency orifice passage 66 is always formed in a communicating state.
[0040]
In this embodiment, the low-frequency orifice passage 66 can exhibit an effective anti-vibration effect (attenuation effect) against, for example, shake vibration, based on the resonance action of the fluid that flows inside the low-frequency orifice passage 66. It has been tuned to. In particular, in the present embodiment, the low-frequency orifice passage 66 flows even with idling low-frequency vibration such as idling primary vibration that has a frequency close to that of the shake vibration and slightly higher than the shake vibration. The low frequency orifice passage 66 is tuned in consideration of the effective vibration isolation effect (low spring effect) based on the resonance action of the fluid to be damped. In this tuning, for example, considering the wall spring rigidity of the pressure receiving chamber 60 and the equilibrium chamber 62, the density of the sealed fluid, and the like, the cross-sectional areas of the concave groove 112, the communication hole 114, and the connection hole 116: A1 and the length. : L1 ratio: It can be performed by adjusting A1 / L1.
[0041]
In addition, an upper recess 72 and a lower recess 74 are formed in the central portion of the upper surface and the lower surface of the partition member 46, and the first rubber film as the first flow restriction means is formed in the lower recess 74. 82 is disposed. The first rubber film 82 has a circular plate shape, and a substantially annular fixed plate fitting 84 is vulcanized and bonded to the outer peripheral edge, and the fixed plate fitting 84 is formed in the lower recess 74. In a state where the first rubber film 82 is separated from the bottom surface of the lower recess 74 by a predetermined distance and fluidly covers the opening of the lower recess 74 by being superimposed on the bottom surface and fixed with the fixing bolt 85. The support plate 84 is supported by the fixed plate metal member 84 and arranged in a stretched state. Under such an arrangement state, the first rubber film 82 is allowed to be elastically deformed and its lower surface is directly exposed to the equilibrium chamber 62.
[0042]
On the other hand, the upper recess 72 is covered with a lid fitting 78, and opening windows 80 and 80 for opening the upper recess 72 into the pressure receiving chamber 60 are formed in the lid fitting 78. The upper recess 72 is provided with a second rubber film 76 as a second flow restriction means. The second rubber film 76 has a circular plate shape that is thicker than the first rubber film 82, and the outer peripheral edge of the thick annular rib shape is the outer peripheral portion of the recess 72. , The central portion of the second rubber film 76 is disposed in the upper recess 72 so as to be elastically deformable by being sandwiched between the bottom surface of the recess 72 and the lid fitting 78. Thereby, the inside of the upper recess 72 is fluid-divided into the bottom side and the opening side by the second rubber film 76, and the pressure receiving chamber is formed with respect to the upper surface of the second rubber film 76. The internal pressure of 60 is exerted through the opening windows 80 and 80.
[0043]
Here, in the present embodiment, the central portion of the second rubber film 76 is thickened, and the displacement is regulated by being substantially in contact with the bottom surface of the upper recess 72 of the partition member 46 and the lid fitting 78. At the same time, the first rubber film 82 has a smaller wall thickness and a larger free length than the second rubber film 76. Thereby, the first rubber film 82 has a smaller spring constant than the second rubber film 76, and elastic deformation is easily allowed. Further, the first rubber film 82 and the second rubber film 76 are designed so that the amount of displacement accompanying deformation is limited mainly by their own spring stiffness, and when the same pressure is applied, A larger displacement is generated with respect to the first rubber film 82 than with the second rubber film 76.
[0044]
Further, the partition member 46 is formed with a radial hole 90 as an internal passage extending linearly through an axially intermediate portion in a substantially rectangular cross section in the diameter direction. That is, the radial hole 90 is linearly formed inside the partition member 46 in a direction substantially orthogonal to the opposing direction of the pressure receiving chamber 60 and the equilibrium chamber 62, and both end openings of the radial hole 90 are cylindrical. A metal fitting 24 covers the fluid tightly. Further, near the both ends in the radial direction of the radial hole 90, connection holes 92 and 94 that branch from the radial hole 90 and extend in the opposite axial directions are formed. One end portion side of the radial hole 90 is opened to the pressure receiving chamber 60 through the connection hole 92 from the window portion 96 formed in the lid fitting 78, and the other end portion side of the radial hole 90 is opened. The lower recess 74 is opened through the connection hole 94. As a result, the radial hole 90, the connection holes 92 and 94, and the lower recess 74 are extended across the pressure receiving chamber 60 and the equilibrium chamber 62, and based on the elastic deformation of the first rubber film 82. A medium frequency orifice passage 68 that allows fluid flow between the two chambers 60 and 62 is formed. In particular, in the present embodiment, the medium frequency orifice passage 68 exhibits an effective anti-vibration effect against idling high-order vibrations such as the idling tertiary based on the resonance action of the fluid that flows inside. Tuned to be able to. Such tuning is performed in the same manner as the low-frequency orifice passage 66, for example, considering the wall spring rigidity of the pressure receiving chamber 60 and the equilibrium chamber 62, the spring rigidity of the first rubber film 82, the density of the sealed fluid, and the like. This can be done by adjusting the ratio of the cross-sectional area A2 and the length L2 of the radial hole 90 and the connection holes 92 and 94: A2 / L2. Further, the amount of fluid flow through the medium frequency orifice passage 68 is limited by the elasticity of the first rubber film 82. In the present embodiment, the value of A2 / L2 in the medium frequency orifice passage 68 is set to satisfy A1 / L1 <A2 / L2 with respect to the value of A1 / L1 in the low frequency orifice passage 66. Thus, the tuning characteristics as described above are advantageously realized.
[0045]
Furthermore, the partition member 46 is formed with an axial hole 86 extending linearly with a substantially rectangular cross section on the central axis, and both sides of the axial hole 86 are formed with an upper recess 72 and a lower recess 74. Opened at each center. As a result, it includes the axial hole 86 and the upper and lower recesses 72 and 74, extends between the pressure receiving chamber 60 and the equilibrium chamber 62, and is based on the elastic deformation of the first and second rubber films 82 and 76. Thus, a high-frequency orifice passage 70 that allows fluid flow between the two chambers 60 and 62 is formed. In particular, in the present embodiment, such a high-frequency orifice passage 70 can exhibit an effective anti-vibration effect against high-frequency vibrations such as running-up noise based on the resonance action of the fluid that flows inside. It has been tuned. The tuning is similar to the low-frequency orifice passage 66, for example, the wall spring stiffness of the pressure receiving chamber 60 and the equilibrium chamber 62, the spring stiffness of the first and second rubber films 82 and 76, the density of the sealed fluid, and the like. In consideration of the above, it can be performed by adjusting the ratio of the cross-sectional area: A3 and the length: L3 of the axial hole 86: A3 / L3. Further, the amount of fluid flow through the high-frequency orifice passage 70 is limited by the elasticity of the first and second rubber films 82 and 76, particularly the elasticity of the second rubber film 76 having a large spring constant. ing. In the present embodiment, the value of A3 / L3 in the high-frequency orifice passage 70 is set such that A1 / L1 <A3 / L3 with respect to the value of A1 / L1 in the low-frequency orifice passage 66. Thereby, the tuning characteristics as described above are advantageously realized.
[0046]
Further, in the partition member 46, the medium-frequency orifice passage 68 and the high-frequency orifice passage 70 intersect each other at an approximately central portion in the length direction of each passage. A valve mounting hole 100 is formed as a valve assembly hole that extends linearly through the partition member 46 in the radial direction orthogonal to both the second and high-frequency orifice passages 68 and 70. A rotary valve 102 as a rotary valve is inserted into the valve mounting hole 100 and assembled. The rotary valve 102 is formed of a hard material such as a metal such as an aluminum alloy or a synthetic resin material, and has a hollow bottomed cylindrical shape, and protrudes outward in the axial direction at the bottom side center. A driving shaft 105 is integrally formed. Then, the partition member 46 is fitted in a valve mounting hole 100 as an assembly hole extending in the radial direction and installed in an inserted state. The valve mounting hole 100 has an inner diameter that is slightly larger than the outer diameter of the hollow cylindrical portion of the rotary valve 102, and has an inner diameter that is slightly larger than that of the drive shaft 105 by reducing one end in the axial direction. On the other hand, the other end portion in the axial direction is increased in a tapered shape to form a valve insertion portion 107. The rotary valve 102 is inserted into the valve mounting hole 100 in the axial direction from the valve insertion portion 107 side, and the valve pressing plate 103 is press-fitted and fixed to the valve insertion portion 107 after the insertion. Thus, the rotary valve 102 is assembled in the valve mounting hole 100 so that it cannot be pulled out in the axial direction and is rotatable around the central axis. The drive shaft 105 of the rotary valve 102 is fitted with an O-ring. The O-ring provides a fluid-tight seal between the outer peripheral surface of the drive shaft 105 and the inner peripheral surface of the valve mounting hole 100. ing.
[0047]
The cylindrical wall portion of the rotary valve 102 is formed with substantially rectangular communication holes 104 and 104 penetrating inward and outward through a portion opposed in one radial direction, and according to the rotational position of the rotary valve 102. These communication holes 104, 104 are alternatively positioned and communicated with either the opening of the radial hole 90 on the inner peripheral surface of the valve mounting hole 100 or the opening of the axial hole 86. It is supposed to be squeezed.
[0048]
Further, of the valve mounting hole 100 of the partition member 46, the opening end portion of the rotary valve 102 into which the drive shaft 105 is incorporated is enlarged in diameter in a predetermined length in the axial direction, and is formed on the outer peripheral surface of the partition member 46. The opening 109 is an opening. A drive shaft 105 of the rotary valve 102 is projected into the recess 109 from the center of the bottom surface of the recess 109. Further, the through hole 47 of the second mounting bracket 14 (tubular bracket 24) is aligned with the opening portion of the recess 109, and the recess 109 is opened to the external space through the through hole 47. In addition, a stepping motor 106 is disposed outside the through hole 47 on the outer peripheral surface of the second mounting bracket 14, and the second mounting bracket is interposed via the bracket 108. 14 (tube fitting 24). The output shaft 110 of the stepping motor 106 is inserted into the concave portion 109 of the partition member 46 through the through hole 47 provided in the cylindrical metal member 24 and is coaxially connected to the drive shaft 105 of the rotary valve 102. ing. As a result, the rotary valve 102 is rotated by the stepping motor 106 to communicate the intermediate frequency orifice passage 68 and the high frequency orifice passage 70 with the high frequency orifice passage 70. It is alternatively positioned at a rotational position (the rotational position shown in FIGS. 1 and 2) that blocks the medium frequency orifice passage 68. Note that the operation of the stepping motor 106 is controlled based on a signal (for example, a speed signal, a shift position signal, or the like) corresponding to the driving state of the automobile, for example, according to the input state of vibration to be shaken. It has become.
[0049]
Therefore, in the engine mount 10 having the structure as described above, the mount vibration isolation characteristics can be changed by switching the rotational position of the rotary valve 102. As shown in the figure, the high-frequency orifice passage 70 is communicated with the pair of communication holes 104 and 104 so as to open at both sides in the axial direction of the partition member 46, and the medium-frequency orifice passage 68. While the vehicle is stopped (idling), the rotary valve 102 is rotated 90 degrees from the illustrated position in any circumferential direction around the central axis. The orifice passage 68 for communication is communicated, and the high-frequency orifice passage 70 is held at a rotational position where it is shut off.
[0050]
As a result, under a vehicle running condition, an effective anti-vibration effect (vibration insulation effect) against high-frequency vibrations such as running-over noise is exhibited based on the resonance action of the fluid that flows through the high-frequency orifice passage 70. At the same time, based on the resonance action of the fluid that can flow through the low-frequency orifice passage 66, an effective anti-vibration effect (attenuation effect) against low-frequency vibration such as a shake is obtained according to the tuning of the low-frequency orifice passage 66. It is demonstrated. The low-frequency orifice passage 66 has a larger fluid flow resistance than the high-frequency orifice passage 70, but the flow rate of the fluid in the high-frequency orifice passage 70 is limited by the second rubber film 76, so The fluid flow rate through the orifice passage 66 can also be advantageously ensured.
[0051]
On the other hand, when the vehicle is stopped, fluid flow through the medium frequency orifice passage 68 is allowed between the pressure receiving chamber 60 and the equilibrium chamber 62. As a result, an effective anti-vibration effect against idling vibration is exhibited based on the resonance action of the fluid flowing through the medium frequency orifice passage 68. In the present embodiment, the low-frequency orifice passage 66 is always in a communicating state, and the fluid flow amount through the medium-frequency orifice passage 68 is limited by the first rubber film 82, thereby reducing the low-frequency orifice passage 66. The amount of fluid flow through the frequency orifice passage 66 is also advantageously ensured. In particular, in the present embodiment, an effective anti-vibration effect is exhibited against idling high-frequency vibration such as idling tertiary vibration based on the resonance action of the fluid flowing through the medium-frequency orifice passage 68. Based on the resonance action of the fluid that flows through the low-frequency orifice passage 66, an effective anti-vibration effect is exhibited against idling low-frequency vibration such as idling primary vibration.
[0052]
In the engine mount 10 of the present embodiment, the first rubber film 82 is disposed on the lower surface side of the partition member 46, and the second rubber film 76 is disposed on the upper surface side of the partition member 46. Therefore, the thickness and area (free length) of the first and second rubber films 82 and 76 can be advantageously ensured without increasing the size of the partition member 46, and the like. In addition, it is possible to advantageously achieve both a degree of freedom in tuning of the high-frequency orifice passages 68 and 70 and compactness.
[0053]
The low-frequency orifice passage 66 is always in communication, but is tuned to a lower frequency region than the frequency region in which the anti-vibration effect by the second and high-frequency orifice passages 68 and 70 is exhibited. In addition, when the vibration in the tuning frequency range of the high-frequency orifice passages 68 and 70 is inputted, the flow resistance of the low-frequency orifice passage 66 is remarkably increased. Therefore, the vibration isolation effect based on the medium-frequency and high-frequency orifice passages 68 and 70 is effective. Can be demonstrated. In addition, since the fluid flow amount through the medium frequency orifice passage 68 is limited by the upper and lower rubber films 82 and 76, the fluid flow amount through the low frequency orifice passage 66 during traveling is sufficiently ensured and low. The anti-vibration effect based on the frequency orifice passage 66 can also be effectively exhibited.
[0054]
By the way, in the engine mount 10 having such a structure, it is important to stably secure sufficient fluid tightness in order to stably obtain the desired vibration isolation effect based on the fluid flow action. Become. Therefore, in the present embodiment, since the through hole 47 is formed in the cylindrical metal member 24 in order to exert a rotational driving force on the rotary valve 102, the fluid tightness caused by fluid leakage through the through hole 47 or the like. Degradation tends to be a problem. In particular, in the present embodiment, the taper portion 28, the stepped portion 30, the caulking portion 32, and the like are formed on the cylindrical metal fitting 24, and the mounting metal fitting 111 for attaching the bracket metal fitting 108 is provided on the outer peripheral surface thereof. Since it is difficult to improve the sealing performance by drawing the cylindrical fitting 24 after press-fitting the member 46, there is a concern that it is difficult to ensure the sealing performance between the outer peripheral surface of the partition member 46 and the inner peripheral surface of the cylindrical fitting 24. It is.
[0055]
Therefore, in the engine mount 10 of the present embodiment, the following seal structure is specially adopted in order to ensure sufficient fluid tightness in the vicinity of the through hole 47.
[0056]
That is, as shown in FIG. 7 and FIG. 8, the partition member 46 is a cylindrical outer peripheral surface having an outer diameter dimension: D 3, and is pressed against the tubular fitting 24 via the seal rubber layer 43. On the outer peripheral surface, a pair of large-diameter protrusions 120 and 120 that protrude outward in the radial direction are integrally formed. The pair of large-diameter protrusions 120, 120 are opposed to each other in the radial direction of the partition member 46 that serves as the rotation center axis of the rotary valve 102, and is larger than the opening width of the recess 109 provided in the partition member 46. The partition member 46 is formed over the entire axial length with a large circumferential width. As a result, the periphery of the concave portion 109 of the partition member 46 is a large-diameter protrusion 120 throughout, and the outer diameter of the partition member 46 is the largest in the radial direction that serves as the rotation center axis of the rotary valve 102. Is set.
[0057]
In short, in the present embodiment, in the partition member 46, the outer diameter dimension D4 in the radial direction that becomes the rotation center axis of the rotary valve 102 is set larger than the outer diameter dimension D3 in the other radial directions. In addition, the inner diameter dimension D1 of the cylindrical fitting 24 and the inner diameter dimension D2 of the seal rubber layer 43 in the second mounting bracket 14 are set so as to satisfy the following expression.
D2 ≦ D3 <D4 <D1
[0058]
The partition member 46 having such a structure is assembled by being press-fitted from below in an axially formed integrally vulcanized molded product 45 as shown in FIGS. It has been. 1 to 4, the pair of large-diameter protrusions 120 and 120 are formed on the outer peripheral surface of the partition member 46, so that the partition member 46 and the cylindrical metal member 24 are not separated from each other. The clamping pressure exerted on the seal rubber layer 43 is varied in the circumferential direction of the seal rubber layer 43. Specifically, the compression rate in the seal rubber layer 43 is maximized at the portion where the large diameter protrusions 120 and 120 are formed on the partition member 46, and the large diameter protrusions 120 and 120 are formed on the partition member 46. In this region, a larger clamping pressure is exerted on the seal rubber layer 43 than in a region where they are not formed.
[0059]
Therefore, in the engine mount 10 having the above-described structure, the pair of large-diameter protrusions 120 and 120 are formed at specific positions corresponding to the through holes 47 of the cylindrical fitting 24 in the partition member 46, and By reducing the compressibility with respect to the seal rubber layer 43 in a portion away from the through hole 47 in the circumferential direction, a large clamping force can be stably applied to the seal rubber layer 43 particularly in the vicinity of the through hole 47. Therefore, stabilization of sealing performance and improvement of reliability can be advantageously achieved.
[0060]
In addition, in the portion of the tubular fitting 24 that is circumferentially removed from the through hole 47, the compression ratio with respect to the seal rubber layer 43 is reduced, so that even when the partition member 46 is press fitted into the tubular fitting 24 and assembled, The clearance space of the seal rubber layer 43 can be advantageously ensured at a portion where the compression rate with respect to the seal rubber layer 43 is reduced without forming 120, and therefore, when the partition member 46 is press-fitted into the cylindrical metal fitting 24 and assembled. The damage of the seal rubber layer 43 and the deterioration of the press-fitting operation due to the spring back are advantageously avoided, and the partition member 46 can be easily press-fitted and set at the intended assembly position. Therefore, the partition member 46 can be placed around the through-hole 47 provided in the tubular fitting 24 by a simple operation of press-fitting and assembling the partitioning member 46 into the tubular fitting 24. In addition, a large clamping force can be effectively and stably applied to the seal rubber layer 43, so that extremely effective sealing performance can be stably obtained in the vicinity of the through-hole 47 and hence in the fluid storage chamber 54. Is possible.
[0061]
In particular, in this embodiment, in the region where the large-diameter protrusions 120, 120 are formed in the partition member 46, the value of the compression ratio Pa in the seal rubber layer 43 (see the following formula) satisfies the following conditional formula (a). In the region where the partition member 46 is out of the large-diameter projections 120, 120, the compression ratio Pb of the seal rubber layer 43 (see the following formula) satisfies the following conditional expression (b). It is set to be satisfied.
Pa = (((φD1-φD2) / 2) − ((φD1-φD4) / 2)) / ((φD1-φD2) / 2)
Pb = (((φD1-φD2) / 2)-((φD1-φD3) / 2)) / ((φD1-φD2) / 2)
35% ≦ Pa ≦ 65% Conditional expression (a)
4% ≦ Pb ≦ 10% Conditional expression (b)
[0062]
That is, by satisfying such a conditional expression, the seal rubber layer 43 is firmly clamped around the through-hole 47 while advantageously ensuring the assembly workability by press-fitting the partition member 46 into the cylindrical fitting 24, Therefore, it is possible to easily and stably obtain a more excellent fluid tightness. In particular, in the present embodiment, by providing the partition member 46 with the large-diameter protrusion 120 larger than the through hole 47, the conditional expression (a) is satisfied within a sufficiently large range around the through hole 47. A satisfactory compression rate can be set in the seal rubber layer 43, whereby a more excellent fluid tightness can be obtained.
[0063]
By the way, when manufacturing the engine mount 10 having the above-described structure, for example, the following manufacturing method is preferably employed.
[0064]
That is, with the first mounting bracket 12 and the second mounting bracket 14 set in the molding die of the main rubber elastic body 16, the molding die is filled with a rubber material and vulcanized and molded. An integrally vulcanized molded product 45 of the main rubber elastic body 16 having the first and second mounting brackets 12 and 14 is manufactured. Separately, the rotary valve 102, the first and second rubber films 82, 76, and the like are assembled to the separately manufactured partition member 46, and the lid member 78 is mounted in an overlapping manner, thereby providing the partition member. To obtain an assembly.
[0065]
Subsequently, as described above, the assembly of the partition member 46 is press-fitted from the lower side in the axial direction into the tubular metal member 24 of the integrally vulcanized molded product 45 and integrally assembled. At this time, the cylindrical metal member 24 and the partition member 46 are aligned with each other in the circumferential direction so that the concave portion 109 of the partition member 46 opens through the through hole 47 of the cylindrical metal member 24. Further, the axially press-fitting position of the partition member 46 with respect to the tubular metal member 24 is such that the outer peripheral edge of the upper surface of the partition member 46 abuts on the lower end surface of the main rubber elastic body 16 and is a flange shape integrally formed with the partition member 46 The portion 50 is set by contacting the stepped portion 30 of the tubular metal member 24.
[0066]
Further, after the fixing metal fitting 52 is press-fitted into the caulking portion 32 of the cylindrical metal fitting 24 and the diaphragm 48 is assembled, an incompressible fluid is injected and filled through the injection hole 56 of the fixing metal fitting 52, and then the injection hole 56 is blind riveted. 58 is sealed.
[0067]
Thereafter, the bottom metal fitting 26 is assembled to the outside of the diaphragm 48, and the flange-like portion 38 of the bottom metal fitting 26 is caulked together with the flange-like portion 50 of the partition member 46 and the fixing metal fitting 52 at the caulking portion 32 of the cylindrical metal fitting 24. By fixing, the target engine mount 10 can be obtained. Further, prior to mounting on the automobile, a stepping motor 106 is mounted on the engine mount 10 by being fixed to the second mounting bracket 14 via a bracket 108, and the output shaft of the stepping motor 106 is mounted. 110 is inserted inward through the through-hole 47 of the cylindrical metal fitting 24, and the output shaft 110 with respect to the drive shaft 105 of the rotary valve 102 protruding from the bottom of the recess 109 in the recess 109 of the partition member 46. Will be connected.
[0068]
In addition to filling the incompressible fluid into the fluid storage chamber 54, for example, in the incompressible fluid to be sealed, the fixing fitting 52 having the diaphragm 48 is caulked by the cylindrical fitting 24 in addition to the injection hole 56 as described above. Press-fit into the portion 32 and press the fixing fitting 52 against the stepped portion 30 of the cylindrical fitting 24 with the seal rubber projection 53 interposed therebetween, thereby filling and enclosing the incompressible fluid simultaneously with the formation of the sealed fluid enclosure region. Is also possible.
[0069]
By the way, in said 1st embodiment, by forming the large diameter protrusions 120 and 120 in the outer peripheral surface of the partition member 46, the seal rubber between the partition member 46 and the cylindrical metal fitting 24 (the second mounting member 14). Although the compression rate for the layer 43 was changed in the circumferential direction, the compression rate for the seal rubber layer 43 can be changed in the circumferential direction by adopting a specific configuration in the cylindrical metal fitting 24 and the seal rubber layer 43. Is also possible. Specific examples of the structure are shown in FIGS. 9, 10, and 11 as cross-sectional views corresponding to FIG.
[0070]
That is, in the other first specific example shown in FIG. 9, as the cylindrical metal fitting 24, a true cylindrical shape whose inner diameter is constant over the entire circumference is adopted as in the first embodiment. However, the thickness of the sealing rubber layer 43 formed with the inner diameter dimension D2 on the inner peripheral surface thereof is changed in the circumferential direction, and the through-hole 47 is formed in the part where the through-hole 47 is formed and the part opposite to the radial direction. A pair of small-diameter projections 122, 122 extending over the entire length in the axial direction with a larger circumferential width are formed, so that the radial inner diameter dimension D5 where the through-hole 47 is located in the seal rubber layer 43 is The inner diameter dimension in the radial direction: smaller than D2.
[0071]
Further, in another second specific example shown in FIG. 10, the inner peripheral surface of the seal rubber layer 43 has a true cylindrical shape whose inner diameter is constant in the circumferential direction. A pair of small-diameter projections 124, 124 extending in the axial direction length with a larger circumferential width than the through-hole 47 are formed at the site where the through-hole 47 is formed and the site facing the radial direction. Thus, the inner diameter dimension D6 in the radial direction where the through-hole 47 is located is smaller than the inner diameter dimension D1 in the other radial directions.
[0072]
Furthermore, in the other third specific example shown in FIG. 11, a pair of small-diameter projections 124, 124 are formed on the tubular metal member 24 and the through hole 47 is located, as in the second specific example. The inner diameter dimension D6 in the radial direction is smaller than the inner diameter dimension D1 in the other radial direction, and the seal rubber layer 43 has a substantially constant thickness on the inner peripheral surface of the tubular fitting 24 throughout. It is formed with dimensions.
[0073]
That is, the diameter at which the through-hole 47 is positioned can be obtained by press-fitting the partition member 46 in the axial direction by adopting the cylindrical metal fitting 24 and the seal rubber layer 43 shown in any of the first to third specific examples. In the direction position direction, the compression ratio with respect to the seal rubber layer 43 can be set larger than that in the other radial directions, whereby the same effect as in the first embodiment can be effectively obtained, and the through hole Therefore, it is possible to stably ensure the excellent sealing performance at 47. The configurations shown in these first to third specific examples are employed in combination with a partition member 46 having a pair of large-diameter projections 120, 120 as shown in the first embodiment. It is also possible to use a partition member having a truly cylindrical outer peripheral surface that does not have the large-diameter projections 120. Even when such a partition member is used, the cylindrical fitting as described above can be used. By adopting a specific configuration in 24 and the seal rubber layer 43, the compressibility with respect to the seal rubber layer 43 can be changed in the circumferential direction, and an effective sealing performance can be obtained at the site where the through hole 47 is formed.
[0074]
Next, FIGS. 12 and 13 show a cylindrical mount 208 used as an engine mount for an FF type automobile as a second embodiment of the present invention.
[0075]
In these drawings, reference numerals 210 and 212 denote an inner cylinder fitting and an outer cylinder fitting as a first attachment member and a second attachment member, respectively, which are arranged eccentrically by a predetermined amount and are interposed between them. These are connected to each other by a rubber elastic body 214 as a main rubber elastic body.
[0076]
In such an engine mount, the inner cylinder fitting 210 and the outer cylinder fitting 212 are attached to each one of the vehicle body side and the power unit side including the engine, and are interposed between them, whereby the power unit Is to be supported against vibration against the vehicle body. Further, in such an engine mount, the weight of the power unit is exerted between the inner and outer cylindrical fittings 210 and 212 in such a mounted state, and the rubber elastic body 214 is deformed, so that both the fittings 210 and 212 are In addition to being positioned on substantially the same axis, vibration to be damped is input mainly in the direction of eccentricity (vertical direction in the figure) of the inner and outer cylindrical fittings 210 and 212. .
[0077]
In more detail, the inner tube fitting 210 is formed in a hollow rod shape or a thick cylindrical shape, and a metal sleeve 216 having a substantially thin cylindrical shape is disposed at a predetermined distance on the outer side in the radial direction. It is arranged with heart. A rubber elastic body 214 is interposed between the inner cylinder fitting 210 and the metal sleeve 216, and the rubber elastic body 214 is connected to the outer circumference surface of the inner cylinder fitting 210 and the inner circumference surface of the metal sleeve 216. In addition, each is formed as an integrally vulcanized molded product bonded by vulcanization.
[0078]
Further, the rubber elastic body 214 is formed with a hollow portion 218 penetrating in the axial direction over a substantially half circumference in the portion where the radial separation distance between the inner cylinder fitting 210 and the metal sleeve 216 is small. ing. Thereby, the tensile stress induced in the rubber elastic body 214 is reduced by the weight of the power unit exerted under the mounting state as described above.
[0079]
Furthermore, a first pocket portion 220 that opens radially outward is formed at a portion of the rubber elastic body 214 where the radial separation distance between the inner tube fitting 210 and the metal sleeve 216 is large, and the metal sleeve 216 is formed. It is opened through a first window 222 provided in the.
[0080]
On the other hand, a portion having a small radial separation distance between the inner cylinder fitting 210 and the metal sleeve 216 that is opposed to the first pocket portion 220 in the radial direction across the inner cylinder fitting 210 has a diameter. A second pocket portion 224 that opens outward in the direction is formed, and is opened through a second window portion 226 provided in the metal sleeve 216. Further, in the second pocket portion 224, the bottom wall portion 228 is thinned by the thinned portion 218, and is configured as a flexible film that is easily elastically deformed.
[0081]
Further, the metal sleeve 216 has a small central portion in the axial direction, and a circumferential groove 230 extending in the circumferential direction is formed in the central portion in the axial direction. The circumferential groove 230 allows the first window 222, which is the opening of the first pocket 220, and the second window 226, which is the opening of the second pocket 224, to have both side edges in the circumferential direction. The parts are connected to each other.
[0082]
Then, in the integrally vulcanized molded product having such a structure, if necessary, the metal sleeve 216 is subjected to diameter reduction processing and pre-compression is applied to the rubber elastic body 214, respectively. First and second orifice halves 232 and 234 having a substantially semi-cylindrical shape are assembled from opposite sides of the first and second pocket portions 220 and 224, whereby a generally thick cylinder as a whole. An orifice member 236 having a shape is formed and is fitted into the circumferential groove 230 of the metal sleeve 216.
[0083]
As shown in FIGS. 14 to 17, the orifice member 236 includes a first concave groove 238 that is bent on the outer peripheral surface and extends in the circumferential direction by a length of approximately two and a half rounds. The second groove 244 is formed independently of each other with a cross-sectional area larger than that of the groove 238 and extending in the circumferential direction by a length of approximately a half circumference. Then, under the assembled state of the orifice member 236 with respect to the integrally vulcanized molded product, both end portions of the first concave groove 238 pass through the bottom wall portion and the first pocket portion through the through holes 240 and 242 provided. 220 and the second pocket portion 224, while both end portions of the second groove 244 pass through the through holes 246 and 248 provided through the bottom wall portion, the first pocket portion 220 is opened. The second pocket 224 is opened.
[0084]
Further, the first orifice half 232 disposed on the first pocket portion 220 side has a thickened central portion in the circumferential direction. In the thick portion 250, the first concave groove 238 is provided. The second groove 244 is formed with a tunnel structure extending through the first orifice half 232 in the circumferential direction.
[0085]
Further, a flat mounting seat 252 is formed on the outer peripheral surface of the thick portion 250 of the first orifice half 232, and the central portion of the mounting seat 252 extends inward. A circular valve assembly hole 254 communicating with the first concave groove 238 having a tunnel structure is formed.
[0086]
And in the integral vulcanization molded product in which such an orifice member 236 is assembled, as shown in FIGS. 12 and 13, it is press-fitted and fixed to the outer cylinder fitting 212, and the integral vulcanization molding is performed. The outer cylinder fitting 212 is fitted and fixed to the metal sleeve 216 and the orifice member 236 constituting the product, and the outer cylinder fitting 212 is further reduced in diameter and fixed more firmly and fixed as necessary. . Here, in this embodiment, the second mounting member is constituted by the cylindrical outer shell metal fitting 212 itself. In other words, the entire second mounting member is a cylindrical portion. This is the outer tube fitting 212. The outer cylinder fitting 212 is provided with a thin seal rubber layer 256 over substantially the entire inner peripheral surface, and the sealing surface of the metal sleeve 216 and the outer cylinder fitting 212 is provided by the seal rubber layer 256. And between the orifice member 236 and the outer tube fitting 212 are fluid-tightly sealed.
[0087]
That is, by the external fitting of the outer cylinder fitting 212, the first pocket portion 220 and the second pocket portion 224 are opened, and further, the first groove 238 and the second groove 244 provided in the orifice member 236. Are each covered.
[0088]
The first pocket portion 220 encloses a predetermined incompressible fluid, and a pressure receiving chamber in which a variation in internal pressure is caused based on elastic deformation of the rubber elastic body 214 when vibration is input between the inner and outer cylindrical fittings 210 and 212. On the other hand, the second pocket portion 224 forms an equilibrium chamber 260 that encloses a predetermined incompressible fluid and allows a volume change based on deformation of the bottom wall portion 228. Furthermore, a low-frequency orifice passage 262 that connects the pressure receiving chamber 258 and the equilibrium chamber 260 to each other is formed by the first concave groove 238, and the low-frequency orifice is formed by the second concave groove 244. A high-frequency orifice passage 264 that connects the pressure receiving chamber 258 and the equilibrium chamber 260 with a larger cross-sectional area / length ratio than the passage 262 is formed. In the present embodiment, these two orifice passages 262 and 264 are both formed as a second orifice passage that allows the pressure receiving chamber and the equilibrium chamber to communicate with each other.
[0089]
As the incompressible fluid sealed in the pressure receiving chamber 258 and the equilibrium chamber 260, water, alkylene glycol, polyalkylene glycol, silicone oil or the like is generally used as in the sealed fluid in the first embodiment. It is done. Also, such fluid encapsulation can be advantageously done, for example, by performing assembly of the mount in fluid.
[0090]
Further, an opening window 266 as a through hole is formed in the outer cylinder fitting 212 at a portion where the mounting seat 252 of the first orifice half 232 is located. A valve assembly 268 is fixed to the mounting seat 252.
[0091]
The valve assembly 268 includes a housing 274 that is integrally formed of a metal material or a resin material by die casting or injection molding. The housing 274 has a substantially bottomed cylindrical shape in which a valve mounting hole 276 having a circular cross section is provided in the central portion, and a mounting portion 278 is integrally provided on the opening side thereof. In addition, a pair of communication holes 282 and 282 are formed in the peripheral wall portion of the housing 274 at positions facing each other in the direction perpendicular to the axis.
[0092]
A rotary valve 284 is inserted and arranged in the valve mounting hole 276 of the housing 274. The rotary valve 284 includes a circular short columnar head portion 288 formed with a valve hole 286 penetrating in a direction perpendicular to the axis, and a rod-like leg portion 290 formed to protrude on one side of the head portion 288 in the axial direction. It consists of and. Then, it is fitted into the valve mounting hole 276 of the housing 274 from the head 288 side, and is held by the presser ring 292 so as to be rotatable about the axis. That is, by rotating the rotary valve 284 in the housing 274, the communication holes 282 and 282 formed in the housing 274 are communicated with each other or blocked through the valve hole 286. . The sliding surface between the outer peripheral surface of the rotary valve 284 and the inner peripheral surface (sliding contact surface) of the valve mounting hole 276 is close enough to prevent fluid flow therethrough.
[0093]
Further, the drive motor 300 is fixed to the mounting portion 278 of the housing 274, and the output shaft 302 of the rotary valve 284 that protrudes outward through an opening window 266 provided in the outer cylinder fitting 212. The leg 290 is engaged. The drive motor 300 allows the rotary valve 284 to be rotated around one axis that is the central axis thereof.
[0094]
Such a valve assembly 268 is inserted into a valve assembly hole 254 provided in the orifice member 236 (first orifice half 232), and the communication holes 282 and 282 are formed in the high-frequency orifice passage 264. In a state where they are in communication, they are fixed and assembled with bolts 306.
[0095]
In the engine mount 208 having the above-described structure, the high-frequency orifice passage 264 is controlled to open and close by the rotation of the rotary valve 284 about one axis. 12 and 13 show a state where the high-frequency orifice passage 264 is blocked by the rotary valve 284. FIG.
[0096]
When the medium frequency orifice passage 264 is “closed”, the fluid flow between the pressure receiving chamber 258 and the equilibrium chamber 260 is generated exclusively through the low frequency orifice passage 262. The anti-vibration effect (high damping effect) against low-frequency vibration such as shake or bounce is exhibited based on the resonance action.
[0097]
On the other hand, when the high-frequency orifice passage 264 is set to “open”, the flow of fluid between the pressure receiving chamber 258 and the equilibrium chamber 260 mainly has a low flow resistance than the low-frequency orifice passage 262. As a result of being generated through the orifice passage 264, an anti-vibration effect (low dynamic spring effect) against medium to high-frequency vibrations such as a booming noise is exhibited based on the resonance action of the fluid.
[0098]
By the way, in the engine mount 208 having such a structure, it is important to stably secure sufficient fluid tightness in order to stably obtain the desired vibration isolation effect based on the fluid flow action. Become. Therefore, in this embodiment, since the opening window 266 is formed in the outer tube fitting 212 in order to exert a rotational driving force on the rotary valve 284, the fluid tightness caused by fluid leakage through the opening window 266 or the like. This is likely to be a problem.
[0099]
Therefore, in the engine mount 208 of the present embodiment, the following seal structure is specially employed in order to sufficiently secure the fluid tightness near the opening window 266.
[0100]
That is, as shown in FIGS. 14 to 17, the orifice member 236 has a cylindrical outer peripheral surface having an outer diameter dimension: D 10, and is pressed against the outer tube fitting 212 via the seal rubber layer 256. On the outer peripheral surface, a pair of large-diameter protrusions 310 and 310 that protrude outward in the radial direction are integrally formed. The pair of large-diameter projections 310 and 310 are opposed to each other in one radial direction of the orifice member 236 serving as the rotation center axis of the rotary valve 284, and a valve assembly hole 254 provided in the orifice member 236. The orifice member 236 is formed over the entire length in the axial direction with a circumferential width larger than the opening width of the orifice member, particularly with a circumferential width larger than the mounting seat 252 provided in the orifice member 236 in this embodiment. Accordingly, the periphery of the valve assembly hole 254 and the mounting seat 252 of the orifice member 236 is a large-diameter protrusion 310 over the entire circumference, and the outer diameter dimension of the orifice member 236 is the rotation center axis of the rotary valve 284. Is set to be the largest in the radial direction.
[0101]
In short, in the present embodiment, in the orifice member 236, the outer diameter dimension D11 in the radial direction serving as the rotation center axis of the rotary valve 284 is set larger than the outer diameter dimension D10 in other radial directions. In addition, the inner diameter dimension D12 of the outer cylinder fitting 212 and the inner diameter dimension D13 of the seal rubber layer 256 in a state where no load is applied are set so as to satisfy the following expression.
D13 ≦ D10 <D11 <D12
In this embodiment as well, as in the first embodiment, it is more desirable to set each value of D10 to 13 so as to satisfy the compression ratio according to the following conditional expression.
Pa = (((φD12−φD13) / 2) − ((φD12−φD11) / 2)) / ((φD12−φD13) / 2)
Pb = (((φD12−φD13) / 2) − ((φD12−φD10) / 2)) / ((φD12−φD13) / 2)
35% ≤ Pa ≤ 65%
4% ≤ Pb ≤ 10%
[0102]
The orifice member 236 having such a structure is assembled by being press-fitted in the axial direction with respect to the outer tube fitting 212 having a seal rubber layer 256 attached to the inner peripheral surface thereof. In this case, since the pair of large-diameter protrusions 310 and 310 are formed on the outer peripheral surface of the orifice member 236, the clamping pressure exerted on the seal rubber layer 256 between the orifice member 236 and the outer tubular fitting 212 is reduced. It is made to differ in the circumferential direction of 256. Specifically, the compression rate in the seal rubber layer 256 is maximized at the portion where the large diameter protrusions 310 and 310 are formed on the orifice member 236, and the large diameter protrusions 310 and 310 are formed on the orifice member 236. In this region, a greater clamping pressure is exerted on the seal rubber layer 256 than in a region where they are not formed.
[0103]
Therefore, in the engine mount 208 having the above-described structure, the pair of large-diameter projections 310 and 310 are formed at specific positions corresponding to the opening windows 266 of the outer cylinder fitting 212 in the orifice member 236, and the outer cylinder fitting 236 is formed. By reducing the compressibility with respect to the sealing rubber layer 256 in the portion of the 212 that is away from the opening window 266 in the circumferential direction, a large clamping force can be stably applied to the sealing rubber layer 256 particularly near the opening window 266. Therefore, as with the engine mount 10 in the first embodiment, stabilization of the sealing performance and improvement of the reliability can be advantageously achieved.
[0104]
Moreover, even when the orifice member 236 is press-fitted into the outer cylinder fitting 212 and assembled at the portion of the outer cylinder fitting 212 that is separated from the opening window 266 in the circumferential direction, the compression rate of the seal rubber layer 256 is reduced. The clearance space of the seal rubber layer 256 can be advantageously ensured at the portion where the compression rate of the seal rubber layer 256 is reduced without the protrusion 310 being formed. Therefore, the orifice member 236 is press-fitted into the outer cylinder fitting 212. Thus, damage to the seal rubber layer 256 and deterioration of the press-fitting operation due to the spring back are advantageously avoided, and the orifice member 236 can be easily press-fitted and set at the intended assembly position. In addition, the simple operation of simply press-fitting and assembling the orifice member 236 to the outer tube fitting 212 A large pinching force can be effectively and stably applied to the seal rubber layer 256 around the opening window 266 provided in the outer cylinder fitting 212, so that the vicinity of the opening window 266, and hence the fluid chamber, can be applied. In the pressure receiving chamber 258 and the equilibrium chamber 260, extremely effective fluid tightness can be stably obtained.
[0105]
In such an engine mount 208, after the integrally vulcanized molded product of the rubber elastic body 214 to which the orifice member 236 is assembled is press-fitted into the outer cylinder fitting 212, the outer cylinder fitting 212 is further contracted by, for example, eight-way drawing. It is possible to further improve the fluid tightness by making the diameter, and after inserting the integrally vulcanized molded product of the rubber elastic body 214 and the orifice member 236 into the outer tube fitting 212, the eight-way drawing process is performed. The diameter of the outer cylinder fitting 212 is reduced by, for example, and the outer cylinder fitting 212 is fitted and fixed to the orifice member 236 or the metal sleeve 216, so that the radial direction of the orifice member 236 or the metal sleeve 216 and the outer cylinder fitting 212 is reduced. It is also possible to sandwich the seal rubber layer 256 therebetween.
[0106]
Next, FIG. 19 shows an FR-type automobile engine mount 318 as a third embodiment of the present invention. In addition, in this embodiment, about the member and site | part made into the structure similar to said 1st embodiment, those detailed description is given by attaching | subjecting the same code | symbol as 1st embodiment in a figure. Omitted.
[0107]
That is, in the engine mount of the present embodiment, the partition member 320 does not include valve means for selectively communicating a plurality of orifice passages. Instead, a part of the wall portion is provided inside the partition member 320. Is formed of a rubber elastic plate 322, and a sub liquid chamber 324 and a working air chamber 326 formed on the opposite side of the sub liquid chamber 324 with the rubber elastic plate 322 interposed therebetween are provided. Anti-vibration characteristics of the mount are controlled by causing the air pressure to vary with respect to 326 through the air communication path 328.
[0108]
More specifically, the partition member 320 includes a thick disk-shaped partition member body 330 formed of a metal such as an aluminum alloy or a rigid material such as a synthetic resin material. The partition member main body 330 is caulked and fixed by the caulking portion 32 of the tubular metal fitting 24 at the flange-shaped portion 332 integrally formed at the outer peripheral edge portion at the lower end in the axial direction, like the partition member 46 in the first embodiment. Thus, it is fixedly attached to the second mounting bracket 14. Further, an annular locking projection 334 having an outer dimension smaller than the outer dimension of the partition member main body 330 is provided on the upper end surface in the axial direction of the partition member 320, and an outer periphery of the locking projection 334 is provided. A locking groove 336 extending continuously in the circumferential direction is formed on the surface. A cylindrical vertical wall portion 338 that protrudes upward in the axial direction is integrally formed on the inner peripheral edge portion of the locking projection 334.
[0109]
In addition, an inner lid fitting 340 and an outer lid fitting 342 are sequentially stacked and assembled integrally with the partition member main body 330 from the upper side in the axial direction. The inner lid fitting 340 has an inverted bottomed cylindrical shape that opens downward, and a locking portion 344 that is bent inward in the radial direction is integrally formed at the periphery of the opening. In addition, an annular stepped portion 348 connected in the circumferential direction is provided in the axially intermediate portion of the cylindrical wall portion 346. The large diameter cylindrical portion 350 is located on the opening side and the upper bottom side is sandwiched between the stepped portions 348. The small-diameter protrusion 352 is used. The inner lid fitting 340 is overlapped with the partition member main body 330 from above in the axial direction, and the locking portion 344 enters the locking groove 336 of the partition member main body 330 and is locked. Is assembled. Further, the step portion 348 of the inner lid metal fitting 340 is overlapped with the protruding front end surface of the vertical wall portion 338 of the partition member main body 330. A lower annular passage 354 extending in the circumferential direction is formed, and a large central space 356 is formed in the central portion. Further, the outer lid fitting 342 has an inverted bottomed cylindrical shape having a slightly larger diameter than the inner lid fitting 340, and the outer lid fitting 342 has a larger diameter cylindrical portion 350 than the inner lid fitting 340. The outer lid fitting 342 is integrally assembled with the inner lid fitting 340 and thus the partition member main body 330 by the peripheral wall portion 358 being press-fitted and fixed by external fitting. Further, the assembled state, the bottom wall portion of the inner lid fitting 340 and the bottom wall portion of the outer lid fitting 342 are closely overlapped. As a result, an upper annular passage 360 is formed between the inner lid fitting 340 and the outer lid fitting 342 so as to continuously extend the outer peripheral portion in the circumferential direction. A lower annular passage 354 formed between the partition member main body 330 and the inner lid fitting 340 and an upper annular passage 360 formed between the inner lid fitting 340 and the outer lid fitting 342 are provided at one place on the circumference. The upper annular passage 360 is communicated with the pressure receiving chamber 60 at other portions on the circumference, and the lower annular passage 354 is communicated with the partition member body 330 at the other portions on the circumference. It communicates with the equilibration chamber 62 through a connection hole 355 that penetrates the inside in the axial direction. The lower and upper annular passages 354 and 360 constitute a low-frequency orifice passage 362 as a second orifice passage that allows the pressure receiving chamber 60 and the equilibrium chamber 62 to communicate with each other.
[0110]
On the other hand, in the central space 356 formed between the partition member main body 330 and the inner lid fitting 340, the rubber elastic plate 322 as an elastic film is accommodated. The rubber elastic plate 322 has a disk shape formed of a rubber elastic body, and a small-diameter reverse cup-shaped connecting fitting 364 is vulcanized and bonded to the central portion thereof, and its outer peripheral edge. An adhesive fitting 366 having an annular shape with an L-shaped cross section is vulcanized and bonded to the portion. The fitting metal fitting 366 is press-fitted and fixed to the vertical wall portion 338 of the partition member main body 330, so that it is accommodated and disposed in the central space 356 so as to expand in the direction perpendicular to the mount center axis. The rubber elastic plate 322 is formed of a wall thickness and a material that exerts an elastic force sufficient to restore the initial shape in a stretched state against an external force.
[0111]
The central space 356 is fluid-divided into two fluid-tight by the rubber elastic plate 322. Therefore, a sub liquid chamber filled with an incompressible fluid is filled between the rubber elastic plate 322 and the inner lid fitting 340. 324 is formed. On the other hand, a working air chamber 326 is formed between the rubber elastic plate 322 and the partition member main body 330 with the rubber elastic plate 322 interposed therebetween and positioned on the opposite side of the sub liquid chamber 324. In addition, a leaf spring 368 is accommodated in the auxiliary liquid chamber 324 so as to be spaced apart from the rubber elastic plate 322 by a predetermined distance and spread in a direction perpendicular to the axis. The outer peripheral edge of the leaf spring 368 is fixedly supported by narrow pressure between the fitting and the step 348 of the 366 inner lid 340. On the other hand, the upper bottom portion of the connection fitting 364 vulcanized and bonded to the rubber elastic plate 322 is caulked and fixed to the central portion of the leaf spring 368. That is, the restoring force of the rubber elastic plate 322 to the initial state is assisted by the elastic force of the leaf spring 368. The leaf spring 368 is appropriately formed with a hollow hole having an appropriate shape in order to adjust the spring coefficient. One sub-liquid chamber 324 is formed substantially on both the upper and lower sides of the leaf spring through these holes.
[0112]
The auxiliary liquid chamber 324 communicates with the pressure receiving chamber 60 through the upper annular passage 360. In other words, in the present embodiment, the upper annular passage 360 forms a high-frequency orifice passage 372 as a first orifice passage that allows the pressure receiving chamber 60 and the sub liquid chamber 324 to communicate with each other. Further, the partition member main body 330 is formed with the air communication path 328 extending inward in the radial direction from the outer peripheral surface and being in open communication with the working air chamber 326 at the inner end. An opening portion of the air communication passage 328 in the partition member main body 330 is aligned with a through hole 47 provided in the cylindrical metal fitting, and is opened to the outer peripheral surface of the cylindrical metal fitting 24 through the through hole 47. In addition, a connection pipe body 374 that is press-fitted from the outside through a through hole 47 provided in the cylindrical metal fitting 24 is fixed to the air communication path 328, and the external air pipe line 376 is connected via the connection pipe body 374. Is connected.
[0113]
Further, the external air pipe line 376 connected to the connection pipe body 374 is selectively switched between the atmosphere and the negative pressure source by the switching valve 378 and connected. According to the switching operation, the atmospheric pressure and the negative pressure are selectively exerted on the working air chamber 326. That is, in the engine mount 318 having such a structure, for example, the switching valve 378 is switched according to the vibration to be vibrated, thereby causing the air pressure variation in the working air chamber 326 and the rubber elasticity. By vibrating and deforming the plate 322, an active fluid pressure difference is generated between the sub liquid chamber 324 and the pressure receiving chamber 60, and the active action is performed using the resonance action of the fluid that flows through the high-frequency orifice passage 372. It is possible to obtain an effective vibration isolation effect. Alternatively, the wall valve stiffness of the auxiliary liquid chamber 324 can be increased by switching the switching valve 378 in accordance with the vibration to be isolated and selectively switching the air pressure exerted on the working air chamber 326 between the atmospheric pressure and the negative pressure. It is also possible to adjust the tuning frequency range of the high-frequency orifice passage 372 according to vibration.
[0114]
In the engine mount 318 according to the present embodiment having the above-described structure, the partition member main body 330 is large on both sides in the radial direction where the opening of the air communication path 328 is located, as in the first embodiment. A radial protrusion 380 is formed. Thereby, an effective compressive force is applied to the seal rubber layer 43 on both radial sides where the opening of the air communication passage 328 is located. Therefore, also in the engine mount 318 in this embodiment, as in the first embodiment, a large narrow pressure can be stably applied to the seal rubber layer 43 in the vicinity of the through-hole 47, As a result, leakage of the sealed fluid through the through hole 47 can be effectively prevented, and stabilization of the sealing performance and improvement of the reliability can be advantageously achieved.
[0115]
In addition, the engine mount 318 of this embodiment can be manufactured according to the same process as that of the first embodiment, and can be easily assembled by press-fitting the partition member 320 into the cylindrical fitting 24. During assembly, damage to the seal rubber layer 43 and assembly failure due to springback can be advantageously avoided, and thus excellent manufacturability and stable quality are ensured, and the fluid sealing region has excellent sealing performance. The intended engine mount 318 can be advantageously manufactured.
[0116]
As mentioned above, although embodiment of this invention was explained in full detail, these are illustrations to the last, Comprising: This invention is not limited at all by the specific description in this embodiment.
[0117]
For example, the number, structure, and the like of the orifice passages that communicate a plurality of fluid chambers are appropriately determined according to the required vibration isolation characteristics and the like, and are not limited at all. For example, one or four or more orifice passages can be formed, and only one orifice passage can be opened / closed by a rotary valve, or three or more orifice passages can be selectively communicated / blocked, Alternatively, the opening amount of these orifice passages can be controlled. For example, by providing a plurality of valve holes in one rotary valve, a plurality of orifice passages can be controlled to open and close simultaneously.
[0118]
In the above-described embodiment, the two fluid chambers are constituted by the pressure receiving chambers 60 and 258 in which a pressure change is generated when vibration is input, and the variable volume equilibrium chambers 62 and 260. However, the specific configuration of the fluid chamber is described. The number and the like are not limited. For example, as a plurality of fluid chambers, a pair of pressure receiving chambers in which substantially opposite pressure changes (pressure changes whose phases are shifted by 180 degrees) are generated when vibration is input, or one or a plurality of pressure receiving chambers are used. It is also possible to configure the fluid chamber by a plurality of equilibrium chambers.
[0119]
Furthermore, in the above-described embodiment, in the partition members 46 and 320 and the orifice member 236, a pair of large diameters are provided on both sides in the radial direction where the cylindrical fitting 24 as the cylindrical portion, the through hole 47 of the outer cylindrical fitting 212 and the opening window 266 are located. The protrusions 120, 120, 310, 310 and 380, 380 are formed, but the large-diameter protrusions 120, 310, 380 are provided only on one side of the partition member 46 or the orifice member 236 in the radial direction. May be.
[0120]
In addition, in the cylindrical engine mount 208 according to the second embodiment, in addition to providing the large-diameter protrusion 310 on the orifice member 236 as in the engine mount 10 according to the first embodiment, or the orifice member In place of providing the large-diameter protrusion 310 on 236, the outer cylinder fitting 212 including the seal rubber layer 256 including the small-diameter protrusion 122 and the small-diameter protrusion 124 according to the configuration shown in FIGS. It is also possible to adopt.
[0121]
Furthermore, in addition to the large-diameter protrusion in the orifice member, the small-diameter protrusion in the cylindrical portion and the seal rubber layer does not need to be formed integrally with each member, and can be formed by fixing other members. It is.
[0122]
In addition, in the said embodiment, although the specific example of what applied this invention to the engine mount for motor vehicles was shown, other than this, this invention is various anti-vibration other than for motor vehicle differential mounts, body mounts, etc. Of course, the present invention can be similarly applied to apparatuses and the like.
[0123]
In addition, although not enumerated one by one, the present invention can be carried out in a mode to which various changes, modifications, improvements and the like are added based on the knowledge of those skilled in the art. It goes without saying that all are included in the scope of the present invention without departing from the spirit of the present invention.
[0124]
【The invention's effect】
As is clear from the above description, in the fluid-filled vibration isolator having the structure according to the present invention, the fluid tightness can be easily reduced by the through-hole formed in the cylindrical portion of the second mounting member. It is effectively prevented by the structure, so that the sealing performance of the sealed fluid can be ensured extremely advantageously and stably, and the intended vibration proofing effect is advantageously exhibited with excellent durability. is there.
[0125]
Further, according to the method of the present invention, even when the through hole as described above is formed in the cylindrical portion of the second mounting member, simple assembly by simply press-fitting the orifice member or the partition member into the cylindrical portion. According to the operation, it is possible to advantageously and easily ensure fluid tightness in the through hole.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view showing an automobile engine mount as a first embodiment of the present invention, and corresponds to a cross section taken along line II in FIG.
2 is a longitudinal sectional view of the engine mount shown in FIG. 1, and corresponds to a section taken along line II-II in FIG. 4;
3 is a sectional view taken along line III-III in FIG.
4 is a cross-sectional view taken along line IV-IV in FIG.
5 is a longitudinal sectional view showing an integrally vulcanized molded product constituting the engine mount shown in FIG. 1. FIG.
6 is a cross-sectional view taken along line VI-VI in FIG.
FIG. 7 is a plan view showing a partition member constituting the engine mount shown in FIG.
FIG. 8 is a view taken along arrow VIII-VIII in FIG.
9 is a cross-sectional view corresponding to FIG. 6 and showing another specific example of a cylindrical fitting that can be employed in the engine mount shown in FIG. 1;
10 is a cross-sectional view corresponding to FIG. 6, showing still another specific example of a cylindrical metal fitting that can be employed in the engine mount shown in FIG.
11 is a cross-sectional view corresponding to FIG. 6, showing still another specific example of a cylindrical fitting that can be employed in the engine mount shown in FIG.
FIG. 12 is a transverse sectional view showing a cylindrical engine mount for automobiles as a second embodiment of the present invention.
13 is a longitudinal sectional view of the engine mount shown in FIG.
14 is a cross-sectional view showing an orifice member used in the engine mount shown in FIG.
15 is a transverse cross-sectional view showing an outer cylinder fitting and a seal rubber layer used in the engine mount shown in FIG.
16 is a bottom view in FIG. 14. FIG.
17 is a left side view in FIG.
18 is a right side view in FIG.
FIG. 19 is a longitudinal sectional view showing an automobile engine mount as a third embodiment of the present invention.
20 is a sectional view taken along line XX-XX in FIG.
[Explanation of symbols]
10 Engine mount
12 First mounting bracket
14 Second mounting bracket
16 Body rubber elastic body
24 Tube fitting
43 Seal rubber layer
45 Integrated vulcanized molded product
46 Partition member
47 Through hole
60 Pressure receiving chamber
62 Equilibrium room
66 Orifice passage for low frequency
68 Orifice passage for medium frequency
70 Orifice passage for high frequency
105 Drive shaft
110 Output shaft
106 Stepping motor
120 Large diameter protrusion
122 Small diameter protrusion
210 Inner tube bracket
212 Outer tube bracket
214 Rubber elastic body
236 Orifice member
254 Valve assembly hole
258 pressure chamber
260 equilibrium room
262 Orifice passage for low frequency
H.264 Orifice passage for medium frequency
266 Open window
268 Valve assembly
274 housing
276 Valve mounting hole
284 Rotary valve
318 engine mount
320 Partition member
324 Secondary liquid chamber
328 Air communication path
362 Orifice passage for low frequency
372 Orifice passage for high frequency
380 Large diameter protrusion

Claims (9)

The first mounting member is spaced apart from the second mounting member having a cylindrical portion, and the first mounting member and the second mounting member are connected by the main rubber elastic body and are not compressed. A plurality of fluid chambers in which a relative pressure difference is generated when vibration is input between the first mounting member and the second mounting member. An orifice member is inserted and disposed in the cylindrical portion, and the outer peripheral surface of the orifice member is closely fixed to the inner peripheral surface of the cylindrical portion over the entire circumference, and the plurality of fluid chambers communicate with each other by the orifice member. Forming an orifice passage, and providing a control hole in the orifice member for controlling vibration isolation characteristics by the orifice passage from the outside, through a through hole provided in the cylindrical portion of the second mounting member, Open the control hole to the outside In the fluid-filled vibration damping device allowed,
A seal rubber layer is disposed between the orifice member and the cylindrical portion of the second mounting member, and the outer peripheral surface of the orifice member and the inner peripheral surface of the cylindrical portion are disposed over the entire circumference with the seal rubber layer interposed therebetween. with closely allowed to Te, by changing the compression ratio exerted on the seal rubber layer between them orifice member and the cylindrical portion in the circumferential direction, the penetrations holes is the largest compression ratio in the radial direction is located, and, The valve means for opening and closing the orifice passage is incorporated in the orifice member, and the drive shaft of the valve means is disposed through the control hole of the orifice member and the through hole of the cylindrical portion. Fluid-filled vibration isolator.   The fluid-filled vibration isolator according to claim 1, wherein the seal rubber layer is formed by bonding to an inner peripheral surface of a cylindrical portion of the second mounting member.   The fluid-filled type according to claim 1 or 2, wherein a large-diameter protrusion is formed on the outer peripheral surface of the orifice member so as to protrude outward in at least one side in a radial direction passing through the through hole of the cylindrical portion. Anti-vibration device.   The seal rubber layer is bonded and formed on the inner peripheral surface of the cylindrical portion, and at least one side of the inner peripheral surface of the seal rubber layer facing both sides in the radial direction passing through the through-hole of the cylindrical portion. The fluid-filled vibration isolator according to any one of claims 1 to 3, wherein a small-diameter projecting portion projecting radially inward is formed. The compression ratio exerted on the sealing rubber layer between said orifice member and the cylindrical portion, next to 35 percent to 65 percent maximum in the radial direction both side portions where the penetrations holes are located, radially to and perpendicular thereto The fluid-filled vibration isolator according to any one of claims 1 to 4, wherein the minimum value at both side portions is set to 4% to 10%. Including a pressure receiving chamber in which a part of the wall portion is configured by the main rubber elastic body, and a sub liquid chamber in which a part of the wall portion is configured by an elastic film that is deformable and provided in the orifice member; While constituting the plurality of fluid chambers and including the first orifice passage that communicates the pressure receiving chamber and the sub liquid chamber with each other, the orifice passage is configured, while the elastic membrane is sandwiched, the opposite of the sub liquid chamber and forming a working air chamber on the side, the orifice by the control hole of the member, the fluid-filled anti according to any one of claims 1 to 5 constitute an air passage for controlling the air pressure of said working air chamber Shaker. The first mounting member is disposed opposite to one opening side in the axial direction of the cylindrical portion of the second mounting member, and the first mounting member and the cylindrical portion are connected to the main rubber elastic body. By elastically connecting with each other, one axial direction opening side of the cylindrical part is fluid-tightly closed, and at least a part of the axial direction other opening side of the cylindrical part is flexible. One end of the wall portion is formed on both sides in the axial direction sandwiching the orifice member inserted into the cylindrical portion with the orifice member having a substantially circular block shape while being fluid-tightly closed by a lid member made of a membrane. A pressure receiving chamber in which a portion is constituted by the main rubber elastic body and an internal pressure variation is generated at the time of vibration input, and an equilibrium chamber in which a part of the wall portion is constituted by the flexible film and the volume thereof is variable, The plurality of fluid chambers are configured including the pressure receiving chamber and the equilibrium chamber. Rutotomoni, said by the orifice member to form a second orifice passage communicating with each other equilibrium chamber with pressure receiving chamber, one of claims 1 to 6 constituting said orifice passage comprises said second orifice passage The fluid-filled vibration isolator described in 1. The first mounting member has a substantially rod shape, and the entire second mounting member is formed by the cylindrical portion, and is spaced apart outward in the direction perpendicular to the axis of the first mounting member. Two mounting members are disposed, and the main rubber elastic body is interposed between the first mounting member and the second mounting member in the direction perpendicular to the axial direction, while the first mounting member and the second mounting member are disposed. The plurality of fluid chambers are formed between opposing surfaces in the direction perpendicular to the axis of the member, and the second mounting member is formed by the orifice member having a substantially cylindrical shape and inserted into the second mounting member. The fluid-filled vibration isolator according to any one of claims 1 to 5 , wherein the orifice passage is formed so as to extend in a circumferential direction along an inner peripheral surface of the member. In the production of fluid-filled vibration damping device according to any one of claims 1 to 8,
The fluid is characterized in that, after the sealing rubber layer is bonded and formed on the inner peripheral surface of the cylindrical portion of the second mounting member, the orifice member is press-fitted and fixed to the cylindrical portion in the axial direction. Manufacturing method of enclosed vibration isolator.

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