JP2011214634A - Vibration control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress the performance deterioration and reduced service life of an elastic body, and also to prevent slipping-out of a body member from a bracket.SOLUTION: This vibration control device 1 includes: the bracket 2 attached to one of a vibration generating portion and a vibration receiving portion; and the body member 3 with the elastic body joined to a mounting portion 4 mounted to the other of the vibration generating portion and vibration receiving portion. The elastic body is provided with extensible legs 53 arranged on one side of the mounting portion 4 in a vertical direction and projecting toward the bracket 2, and fitting portions 54 provided at the ends of the legs 53. The bracket 2 is provided with fitting recessed portions 26 arranged on the one side of the mounting portion 4 in the vertical direction and fitting the fitting portions 54, and a stopper 25 arranged on the other side of the mounting portion 4 in the vertical direction and limiting the displacement of the mounting portion 4 to the other side in the vertical direction. The body member 3 is assembled to the bracket 2 with the body member sandwiched in the vertically direction by at least the stopper member 25 and fitting recessed portions 26 and compression force applied to the legs 53.

Description

  The present invention relates to a vibration isolator that is used when mounting a vibration generating unit such as an automobile engine on a vibration receiving unit such as a vehicle body.

  As this type of vibration isolator, conventionally, for example, as shown in Patent Document 1 below, a bracket (second mounting member) attached to either one of a vibration generating part and a vibration receiving part, and vibration generation There is known a vibration isolator including a main body member in which an elastic body (elastic leg) is joined to an attachment portion (first attachment member) attached to any one of the first portion and the vibration receiving portion. The above-described elastic body includes a leg main body portion that includes an extendable leg portion protruding toward the bracket and a fitting portion provided at the tip of the leg portion. In the lower part of the mounting portion, it is arranged in a C shape. A fitting concave portion (press-fit concave portion) into which the fitting portion described above is fitted is formed at the lower end portion of the side plate portion of the bracket described above. Moreover, the stopper part (arch part) which restrict | limits the upward displacement of an above-described attachment part is provided in the upper end part of the above-mentioned bracket.

  In the conventional vibration isolator having the above-described configuration, the main body member is assembled inside the bracket by press-fitting the tip end portion (fitting portion) of the leg main body portion into the fitting recess portion of the bracket. And in the state by which the main body member was assembled | attached inside the bracket, the clearance gap is opened between the upper end part (upper stopper part) of an attaching part, and the above-mentioned stopper part.

  In the vibration isolator described above, for example, when a bracket is attached to the vibration receiving portion, a vibration generating portion is attached to the attaching portion, and vibration from the vibration generating portion is input, the vibration is absorbed by the elastic body and is received by the vibration receiving portion. The transmitted vibration is reduced. Further, when the vibration generating portion vibrates with a large amplitude in the vertical direction, the upper end portion of the attachment portion collides with the stopper portion at the time of rebound, and the upward displacement of the attachment portion is restricted. Thereby, the tensile force which acts on the leg part of an elastic body is restrict | limited, and the damage (crack etc.) of an elastic body by an excessive tensile force (extension) can be prevented.

JP 2003-74630 A

  However, in the above-described conventional vibration isolator, a gap is formed between the upper end portion of the mounting portion and the stopper portion in a state where the main body member is assembled inside the bracket. When displaced upward from the position before load input (position at the time of assembly), a tensile force acts on the legs of the elastic body. For this reason, when vibration is repeatedly input over a long period of time, there is a problem that cracks and the like occur in the leg portions of the elastic body due to the above-described tensile force, thereby reducing the performance and life of the vibration isolator. In particular, when the vibration isolator is used as an engine mount, the tensile force acts on the leg of the elastic body under the high temperature environment due to the heat of the engine, so the leg will creep under the high temperature environment due to the heat from the engine. The root R becomes small, and this becomes the starting point of the crack, and the performance and life of the elastic body are likely to decrease.

Further, in the conventional vibration isolator described above, when the leg main body is pulled upward during rebound as described above, the distal end surface of the fitting portion of the elastic body is separated from the fitting concave portion of the bracket, and the fitting is performed. The frictional force between the joint and the fitting recess is reduced. Therefore, when the vibration is input in the axial direction (the axial direction of the bracket) together with the large vibration in the vertical direction, the body member may come out from the inside of the bracket in the axial direction due to the reduction of the frictional force. Further, when the leg main body is pulled upward at the time of rebound, the fitting portion may be detached from the fitting recess.
Moreover, in order to prevent the above-mentioned problem, there is a method in which the fitting portion of the elastic body is formed integrally with the leg portion with hard rubber, but the cost becomes high.

  The present invention has been made in consideration of the above-described conventional problems, and provides a vibration isolator capable of suppressing a drop in performance and life of an elastic body and preventing a main body member from coming out of a bracket. It is an object.

  The vibration isolator according to the present invention is elastic to a bracket attached to either one of the vibration generating part and the vibration receiving part, and to a mounting part attached to any one of the vibration generating part and the vibration receiving part. A body member joined to the elastic body, and a telescopic leg portion disposed on one side in the vertical direction of the mounting portion and projecting toward the bracket, and the leg. A fitting recess provided in the bracket on the one side in the vertical direction of the mounting portion, and the fitting portion being fitted to the bracket, and the mounting portion And a stopper part that restricts displacement of the mounting part to the other side in the vertical direction, and the main body member is fitted at least with the stopper part. Sandwiched vertically with the recess It is characterized by being assembled to the bracket in a state where compressive force is applied to the leg.

  With such a feature, in a state where the main body member is assembled to the bracket, the attachment portion is pressed against the stopper portion, and the leg portion is compressed. Subsequently, when either one of the vibration generating portion and the vibration receiving portion is attached to the bracket, and when either the vibration generating portion or the vibration receiving portion is attached to the mounting portion, the static load (support load) is applied. The attachment portion is displaced toward one side in the vertical direction relative to the bracket, and a gap is formed between the attachment portion and the stopper portion. And if the vibration from the above-mentioned vibration generating part is inputted, vibration absorbed by the elastic body and transmitted to the vibration receiving part is reduced. At this time, the mounting part is displaced relative to the bracket, but the body member is assembled to the bracket in a state where the leg part is compressed. The compression force is applied to the legs. Even if the attachment portion is relatively displaced until it comes into contact with the stopper portion at the time of rebound, the leg portion is hardly pulled and the leg portion is compressed. Therefore, even when rebounding, the fitting portion is not separated from the fitting recess, and the fitting portion is always in pressure contact with the fitting recess. Even when a large displacement is repeatedly input to the rebound side, the leg portion is always compressed. When the leg portion creeps in a high temperature environment due to heat from the engine, the root R becomes small, which becomes the starting point of the crack, but since it is always in a compressed state, the occurrence of the crack can be suppressed.

Further, in the vibration isolator according to the present invention, the bracket is formed with a cylindrical portion that extends horizontally and the body member is fitted inside, and is formed at an end portion of the cylindrical portion in the axial direction. It is preferable that a retaining portion for pressing the fitting portion from the outside in the axial direction is provided.
Thereby, the movement to the axial direction outer side relative to the fitting concave part of the fitting part is restricted by the retaining part, and the main body member is prevented from slipping out from the inner side of the bracket to the outer side in the axial direction.

In addition, since the above-mentioned leg portion expands and contracts at the time of vibration input, if the leg portion is scratched, the scratch easily develops. It becomes a factor.
Therefore, in the vibration isolator according to the present invention, it is preferable that an edge portion of the retaining portion is in contact with the fitting portion.
As a result, when the leg is compressed, its surface bulges outward in the axial direction, but even if the surface of the leg swells, it is not pressed against the edge of the retaining part, and the edge of the retaining part This prevents the leg surface from being damaged.

In the vibration isolator according to the present invention, it is preferable that the fitting portion protrudes outward in the axial direction from the leg portion, and a step is formed between the fitting portion and the leg portion.
Thereby, even if the surface of the fitting portion is damaged by the edge portion of the retaining portion, the damage does not easily propagate to the leg portion.

Further, it is assumed that the bracket is formed by joining two parts by caulking or the like, and the main body member is sandwiched between these two parts and joined together, whereby the main body member is assembled to the bracket. In this case, a joining process for joining two parts is necessary, and the assembly process is complicated. In addition, since the bracket is composed of two parts, the number of parts increases accordingly. Further, in order to fix the two parts by caulking and fixing, it is necessary to form portions that overlap each other, and this overlapping portion increases the weight of the bracket.
Therefore, in the vibration isolator according to the present invention, it is preferable that the bracket is made of a single component, and the main body member is press-fitted inside the bracket.
As a result, the joining process as described above is unnecessary, the number of components is reduced, and the above-described overlapping portion is not required.

According to the vibration isolator which concerns on this invention, even if it is a case where a big displacement is repeatedly input into the rebound side, a leg part will always be in the state compressed. The base R is reduced by creeping the leg under high temperature environment due to heat from the engine, and this is the starting point of the crack, but since it is always in a compressed state, the occurrence of the crack can be suppressed, and elasticity It is possible to suppress a decrease in body performance and a decrease in life.
In addition, even when the mounting portion is greatly displaced to the rebound side, the fitting portion is always in pressure contact with the fitting recess, so that a frictional force is generated between the fitting portion and the fitting recess. The frictional force can prevent the main body member from coming out of the bracket. Therefore, even if vertical vibration is input and the mounting portion is displaced relative to the bracket in the axial direction, the main body member is difficult to come out of the bracket, and the main body member and the bracket are separated. Can be prevented.

It is a front view of the vibration isolator for demonstrating embodiment of this invention. It is a disassembled perspective view of the vibration isolator for demonstrating embodiment of this invention.

DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments of a vibration isolator according to the present invention will be described with reference to the drawings.
In the vibration isolator of the present embodiment, the lower side in FIG. 1 is the bounce side, that is, the direction in which a static load (support load) is input when the vibration isolator 1 is installed. The side is the rebound side, that is, the side opposite to the static load input direction. In the following description, the bound side is referred to as “lower side”, the rebound side is referred to as “upper side”, and the bound-rebound direction (Z direction shown in FIG. 2) is referred to as “vertical direction”. Further, in the present embodiment, the axial direction (Y direction shown in FIG. 2) of the bracket 2 and the mounting portion 4 to be described later is the vehicle left-right direction, and is hereinafter referred to as “axial direction”. Further, the horizontal direction (X direction shown in FIG. 2) orthogonal to the axial direction is the vehicle front-rear direction, and is hereinafter referred to as “width direction”.

  The vibration isolator 1 is a vehicle engine mount for mounting an unillustrated engine (corresponding to a vibration generating portion in the present invention) on a not-shown vehicle body (corresponding to a vibration receiving portion in the present invention). This is a device for reducing vibration transmitted from the engine to the vehicle body. As shown in FIGS. 1 and 2, the vibration isolator 1 includes a bracket 2 attached to a vehicle body (not shown), and a main body member 3 assembled inside the bracket 2. The main body member 3 has a configuration in which an elastic body 5 held by the bracket 2 is joined to an attachment portion 4 attached to an engine (not shown) via an engine bracket (not shown).

  The attachment portion 4 is a cylindrical metal fitting whose both ends are open, and is an inner cylinder disposed inside the bracket 2. The mounting portion 4 is disposed in a direction parallel to the axis of the bracket 2 and extends along the axial direction. Further, a fastening member such as a bolt (not shown) for fastening to an engine bracket (not shown) is inserted inside the mounting part 4, and the engine bracket is connected to an end of the mounting part 4.

  The elastic body 5 is a rubber elastic body made of a rubber material such as natural rubber, styrene-butadiene rubber (SBR), butadiene rubber (BR), or the like, and is attached to the mounting portion 4 by vulcanization molding together with the mounting portion 4 described above. It is adhered to the outer peripheral surface of. The elastic body 5 includes a bounce buffer 50 disposed below the mounting portion 4, a rebound buffer 51 disposed above the mounting portion 4, and both sides of the mounting portion 4 in the width direction. Side buffer portions 52, 52 provided, a pair of leg portions 53, 53 projecting toward the bracket 2, and fitting portions 54, 54 provided at the tips of the leg portions 53, 53, respectively. Is provided.

  The bound buffer portion 50 is a rubber body that covers the lower surface of the attachment portion 4 and is formed in a substantially triangular shape that is gradually reduced in width as viewed in the arrow direction from the axial direction. The rebound buffer portion 51 is a rubber body that covers the upper surface of the attachment portion 4, and has an arc shape formed along the upper surface of the attachment portion 4 when viewed from the axial direction. The side buffer parts 52, 52 are rubber bodies that cover the side surfaces of the attachment part 4, and protrude toward the outer side in the width direction.

  The leg portion 53 is a support portion that is disposed on the lower side (one side in the vertical direction) of the mounting portion 4 and supports the mounting portion 4, and is disposed at a position that is compressed when a static load is applied. . Further, the pair of leg portions 53 and 53 are disposed symmetrically with respect to the central vertical line of the attachment portion 4. More specifically, the pair of leg portions 53 and 53 protrude obliquely downward from the bound buffer portion 50, are arranged close to the lower side of the attachment portion 4, and are viewed from the axial direction. In FIG.

  The fitting portion 54 is a fixed portion that is fixed to the bracket 2, and protrudes outward in the width direction from the lower end of the leg portion 53. More specifically, the fitting portion 54 is formed in a substantially rectangular parallelepiped shape, and the fitting portion 54 includes an upper surface 54 a that protrudes outward in the width direction from the lower end of the inclined outer surface 53 a of the leg portion 53, and A side surface 54b extending downward in the vertical direction from the tip of the upper surface 54a and a lower surface 54c extending horizontally from the lower end of the side surface 54a toward the inner side in the width direction are formed. Further, the surfaces 54d on both sides in the axial direction of the fitting portion 54 protrude outward in the axial direction from the surface 53b (the surface facing outward in the axial direction) of the leg portion 53, and both sides in the axial direction of the fitting portion 54 A step 55 is formed between the surface 54 d of the leg and the surface 53 b of the leg 53.

  The bracket 2 is a metal fitting that surrounds the main body member 3 and holds the main body member 3. More specifically, the bracket 2 includes a lower plate 20 that extends along the width direction, and an upper plate 21 that is bent in a substantially U-shape and disposed in an open downward direction. . In the bracket 2, lower ends on both sides of the upper plate 21 are placed on the upper surface of the lower plate 20, and lower ends on both sides of the upper plate 21 are welded to the upper surface of the lower plate 20. Both axial ends of the side plates on both sides are welded to rib plates 28 described later. Thereby, the bracket 2 is formed with a rectangular tubular portion 22 that extends in the axial direction and into which the main body member 3 is fitted, and the bracket 2 described above includes a bound stopper portion 23 described later. The side stopper part 24, the rebound stopper part 25, and the fitting recessed part 26 become a single part integrally formed.

  Both end portions of the lower plate 20 are protruded outward from the upper plate 21 (tubular portion 22) and extended outward in the width direction. Bolt holes 27 through which bolts (not shown) for fastening to a vehicle body (not shown) are inserted are formed at both ends of the lower plate 20. In addition, rib plates 28 extending vertically are respectively provided on both side portions of both ends of the lower plate 20.

  In addition, a bound stopper portion 23 that restricts the downward displacement of the mounting portion 4 is formed on the lower surface portion of the cylindrical portion 22, that is, the central portion in the length direction of the lower plate 20. The bound stopper 23 abuts against the bound buffer 50 described above when the mounting portion 4 is displaced vertically downward to a certain position relative to the bracket 2, and the downward displacement of the mounting portion 4. It is a part that regulates. More specifically, the bound stopper portion 23 is a convex portion protruding upward, and is disposed between the pair of leg portions 53 and 53 (fitting portions 54 and 54) and bound. It is arranged below the buffer part 50 with an interval.

  Further, side portions on both sides of the cylindrical portion 22, that is, side portions on both sides of the upper plate 21, are side stopper portions 24 that restrict displacement of the mounting portion 4 to the outside in the width direction. The side stopper portion 24 comes into contact with the side buffer portion 52 described above when the mounting portion 4 is displaced outward in the width direction to a certain position relative to the bracket 2, and the side stopper portion 24 moves outward in the width direction of the mounting portion 4. It is a portion that regulates displacement, and is disposed at an interval on the outer side in the width direction of the side buffer portion 52.

  Also, the lower corners on both sides of the cylindrical portion 22, that is, the lower ends on both sides of the upper plate 21, are fitted below the fitting portion 4 and are fitted with the fitting portions 54. A fitting recess 26 is formed. The fitting recess 26 is a recess that is recessed outward in the radial direction. More specifically, the fitting recess 26 includes an upper surface 26a that protrudes axially outward from the lower end of the side stopper portion 24, and a side surface 26b that hangs downward from an axially outer end of the upper surface 26a. The horizontal lower surface 26c is formed between the lower end of the side surface 26b and the bound stopper portion 23 described above. The upper surface 26a of the fitting recess 26 is in close contact with the upper surface 54a of the fitting portion 54, and the side surface 26b of the fitting recess 26 is in close contact with the side surface 54b of the fitting portion 54, Further, the lower surface 26 c of the fitting recess 26 is in close contact with the lower surface 54 c of the fitting portion 54 described above.

  Further, the upper surface portion of the cylindrical portion 22, that is, the upper end portion of the upper plate 21, corresponds to a rebound stopper portion 25 (a stopper portion in the present invention) that restricts the displacement of the mounting portion 4 in the vertical direction. ). The rebound stopper portion 25 abuts on the above-described rebound buffer portion 51 when the attachment portion 4 is displaced upward in the vertical direction to a certain position relative to the bracket 2, so that the attachment portion 4 is displaced upward. It is a part to be regulated and is in pressure contact with the rebound buffer 51.

  Further, at both end portions in the axial direction of the tubular portion 22 described above, a retaining portion 29 for pressing the fitting portion 54 from the outside in the axial direction is provided. The retaining portion 29 is a plate portion erected along the vertical direction from side end portions on both sides in the axial direction of the lower surface portion of the cylindrical portion 22, and is formed flush with and integrally with the rib plate 28 described above. ing. Further, the retaining portion 29 is formed in a substantially U-shape (concave shape) when viewed from the axial direction, and an edge portion thereof is directed to the surface 54d (outward in the axial direction) of the fitting portion 54. The surface).

  The main body member 3 is assembled to the bracket 2 by press-fitting the main body member 3 from the outside in the axial direction of the bracket 2 to the inside of the bracket 2 (cylindrical portion 22). At this time, the main body member 3 is compressed and sandwiched between the lower surface of the rebound stopper portion 25 and the lower surfaces 26c and 26c of the fitting recesses 26 and 26, and the fitting recesses 26 and 26 on both sides. The side surfaces 26b and 26b are compressed and sandwiched in the width direction, whereby a compression force is applied to the leg portions 53 and 53 described above.

  That is, the overall height molding dimension (vertical dimension from the lower surface 54 c of the fitting portion 54 to the upper surface of the rebound buffer portion 51) of the main body member 3 in the unloaded state before being assembled to the bracket 2 is the inner side of the cylindrical portion 22. It is larger than the height dimension (the vertical dimension from the lower surface 26c of the fitting recess 26 to the lower surface of the rebound stopper portion 25), and the molding dimension of the full width of the main body member 3 in an unloaded state (of one fitting portion 54). The horizontal dimension from the side surface 54b to the side surface 54b of the other fitting portion 54) is the width dimension between the fitting concave portions 26, 26 on both sides (from the side surface 26b of one fitting concave portion 26 to the side surface of the other fitting concave portion 26). The horizontal dimension up to 26b). And the main body member 3 is arrange | positioned inside the cylindrical part 22 in the state which reduced the elastic body 5 to the vertical direction and the width direction, respectively with the jig etc. which are not shown in figure. At this time, the leg portions 53 and 53 are compressed in the protruding direction, and the protruding length is shortened. Thereafter, by removing the jig described above, the elastic body 5 expands due to the elasticity of the elastic body 5, and the lower surfaces 54c, 54c of the fitting portions 54, 54 are pressed against the lower surfaces 26c, 26c of the fitting recesses 26, 26. At the same time, the upper surface of the rebound buffer 51 is pressed against the lower surface of the rebound stopper 25, and the side surfaces 54b, 54b of the fitting portions 54, 54 of the elastic body 5 are pressed against the side surfaces 26b, 26b of the fitting recesses 26, 26. In addition, a compressive force is applied to the leg portions 53 and 53 described above.

  Next, the operation of the vibration isolator 1 having the above configuration will be described.

  First, the bracket 2 is attached to a vehicle body (not shown) and attached to the engine (not shown) via the engine bracket (not shown) to the attachment portion 4. As a result, an engine load (static load) (not shown) acts on the mounting portion 4, and the mounting portion 4 is displaced downward relative to the bracket 2. As a result, the legs 53 and 53 are compressed and shortened, and the rebound buffer 51 is separated from the rebound stopper 25 and a predetermined gap is formed between the upper surface of the rebound buffer 51 and the lower surface of the rebound stopper 25. Is formed.

  Next, when vibration of an engine (not shown) is input to the mounting portion 4 via an engine bracket (not shown), the mounting portion 4 is displaced relative to the bracket 2. At this time, the vibration is absorbed by the elastic body 5 and the vibration transmitted to the vehicle body (not shown) via the bracket 2 is reduced. Further, since the main body member 3 is assembled in the cylindrical portion 22 of the bracket 2 in a state where the legs 53 and 53 are compressed, a tensile force does not act on the legs 53 and 53 even when rebounding, and the legs are always The parts 53 and 53 are in a compressed state. Therefore, even when rebounding, the fitting portion 54 is pressed against the fitting recess 26, and the side surface 54b and the lower surface 54c of the fitting portion 54 are not separated from the side surface 26b and the lower surface 26c of the fitting recess 26, The side surface 54 b and the lower surface 54 c of the fitting portion 54 are in a state of being pressed against the side surface 26 b and the lower surface 26 c of the fitting recess 26.

  Further, when the engine (not shown) vibrates with a large amplitude in the vertical direction and the mounting portion 4 is greatly displaced downward, the bound buffer portion 50 of the elastic body 5 contacts the bound stopper portion 23. On the contrary, when the attachment portion 4 is largely displaced upward, the rebound buffer portion 51 of the elastic body 5 contacts the rebound stopper portion 25. Thereby, the displacement of the attachment portion 4 in the vertical direction is restricted, and the expansion / contraction deformation of the leg portions 53 and 53 due to the large vibration is restricted. Further, as described above, even if the leg portions 53 and 53 are extended as the rebound buffer portion 51 comes into contact with the rebound stopper portion 25, a compressive force is always applied to the leg portions 53 and 53 without applying a tensile force. Thus, the side surface 54b and the lower surface 54c of the fitting portion 54 are in pressure contact with the side surface 26b and the lower surface 26c of the fitting recess 26.

  Further, for example, when the vehicle suddenly accelerates or decelerates suddenly, an engine (not shown) is displaced in the width direction (vehicle front-rear direction), and the mounting portion 4 is largely displaced in the width direction relative to the bracket 2. At this time, the side buffer portions 52, 52 of the elastic body 5 abut against the side stopper portion 24. Thereby, the displacement to the width direction of the attaching part 4 is controlled, and the expansion-contraction deformation of the leg parts 53 and 53 accompanying the vibration of the width direction is restrict | limited. At this time, no tensile force acts on the above-described leg portions 53, 53, and the leg portions 53, 53 are always compressed, and the side surface 54 b and the lower surface 54 c of the fitting portion 54 are formed on the fitting recess 26. It will be in the state press-contacted to the side surface 26b and the lower surface 26c.

  Further, for example, when the vehicle suddenly curves, the engine (not shown) may be displaced in the axial direction (the vehicle left-right direction), and the mounting portion 4 may be displaced in the axial direction relative to the bracket 2. At this time, the movement of the fitting portion 54 to the outside in the axial direction relative to the fitting concave portion 26 is restricted by the retaining portion 29. Thereby, it is prevented that the main body member 3 slips out from the inner side of the bracket 2 (tubular portion 22) to the outer side in the axial direction.

As described above, when the leg portion 53 is compressed, the surface 53b bulges outward in the axial direction, but the edge portion of the retaining portion 29 is in contact with the surface 54d of the fitting portion 54. Therefore, even if the surface 53b of the leg portion 53 swells, it is not pressed against the edge portion of the retaining portion 29, and the surface 53b of the leg portion 53 is prevented from being damaged by the edge portion of the retaining portion 29.
In addition, the surface 54d of the fitting portion 54 protrudes outward in the axial direction from the surface 53b of the leg portion 53, and a step 55 is formed between the surface 54d of the fitting portion 54 and the surface 53b of the leg portion 53. Therefore, even if the surface 54 d of the fitting portion 54 is damaged by the edge portion of the retaining portion 29, the damage does not easily propagate to the leg portion 53.

  According to the vibration isolator 1 described above, the leg portion 53 is always compressed even when a large displacement is repeatedly input to the rebound side. The root portion R is reduced by creeping the leg portion 53 in a high temperature environment caused by heat from an engine (not shown), and this is the starting point of the crack, but since it is always in a compressed state, the crack generation is suppressed. It is possible to suppress deterioration in performance and lifetime of the elastic body 5.

  Further, even when the mounting portion 4 is greatly displaced to the rebound side, the fitting portion 54 is always in pressure contact with the fitting recess 26, so that the gap between the fitting portion 54 and the fitting recess 26 is A frictional force is generated, and the main body member 3 can be prevented from coming out of the bracket 2 by the frictional force. Therefore, even if vertical vibrations are input and the mounting portion 4 is displaced in the axial direction relative to the bracket 2, the main body member 3 becomes difficult to come out of the bracket 2, and the main body member 3. And the bracket 2 can be prevented from being separated.

  Further, since the movement of the fitting portion 54 to the outer side in the axial direction relative to the fitting concave portion 26 is restricted by the retaining portion 29, the main body member 3 can be reliably prevented from coming out from the inner side of the bracket 2. .

Further, since the edge portion of the retaining portion 29 is in contact with the surface 54d of the fitting portion 54 and the edge portion of the retaining portion 29 is not pressed against the surface 53b of the leg portion 53, the edge portion of the retaining portion 29 It is possible to prevent the surface 53b of the leg portion 53 from being damaged, and to suppress the performance deterioration and the life reduction of the elastic body 5.
Furthermore, a step 55 is formed between the surface 54d of the fitting portion 54 and the surface 53b of the leg portion 53. Even if the edge 54 of the retaining portion 29 is damaged on the surface 54d of the fitting portion 54, Since the scratch does not easily propagate to the leg portion 53, it is possible to prevent the leg portion 53 from being cracked, and to suppress the performance reduction and the life reduction of the elastic body 5.

  Further, in the vibration isolator 1 described above, the bracket 2 is composed of a single part, and the main body member 3 is assembled to the bracket 2 by press-fitting the main body member 3 inside the bracket 2, thereby reducing the number of assembly steps and the number of parts. can do. Furthermore, since it is not necessary to form an overlapping portion on the bracket 2, the bracket 2 can be reduced in weight and the vibration isolator 1 can be reduced in weight.

As mentioned above, although the embodiment of the vibration isolator according to the present invention has been described, the present invention is not limited to the above-described embodiment, and can be appropriately changed without departing from the gist thereof.
For example, in the above-described embodiment, the bound stopper portion 23 and the side stopper portions 24, 24 are formed on the bracket 2. However, in the present invention, the bound stopper portion 23 and the side stopper portion 24 may be omitted. Is possible.

  In the above-described embodiment, the elastic body 5 is provided with the bounce buffer 50, the rebound buffer 51, and the side buffer portions 52, 52 on both sides. It can be omitted. For example, a buffer portion may be provided on the inner peripheral surface of the cylindrical portion 22 and the mounting portion 4 may be in direct contact with the buffer portion.

  Moreover, in the above-described embodiment, the bracket 2 having the rectangular tube-shaped cylindrical portion 22 is provided, but the present invention can be a bracket in which the cylindrical portion 22 is not formed, For example, it is possible to use a U-shaped bracket in cross section, and it is also possible to use other shapes of brackets.

  In the embodiment described above, the bracket 2 is connected to the vehicle body (vibration receiving portion) and the mounting portion 4 is connected to the engine (vibration generating portion). However, in the present invention, the bracket 2 is connected to the engine (vibration generating portion). The attachment portion 4 may be connected to the vehicle body (vibration receiving portion).

Further, in the above-described embodiment, the elastic body 5 is provided with a pair of leg portions 53, 53 disposed symmetrically with respect to the vertical center line, and the pair of leg portions 53, 53 is the attachment portion 4. The leg portion in the present invention is a position where it is compressed when a static load is applied. The orientation of the legs can be changed. For example, when a vibration generating part such as an engine is attached to the bracket 2 and a vibration receiving part such as a vehicle body is attached to the attachment part 4, the leg part is arranged close to the upper part of the attachment part 4. Legs are arranged in a substantially V shape. Furthermore, when increasing the rigidity in the vehicle front-rear direction, the legs can be arranged in a substantially X shape.
In the present invention, one or three or more legs may be provided, and the plurality of legs 53 may not be arranged symmetrically.

  Further, the vibration isolator according to the present invention is not limited to the engine mount of the vehicle, but can be applied to the vibration isolator other than the engine mount. For example, the present invention can be applied to a mount of a generator mounted on a construction machine, or can be applied to a mount of a machine installed in a factory or the like.

  In the above-described embodiment, the lower plate 20 and the upper plate 21 are integrally welded, the bracket 2 is made of a single part, and the main body member 3 is press-fitted inside the bracket 2 (tubular portion 22). However, in the present invention, it is also possible to assemble a plurality of parts to form a bracket. For example, a bracket formed by joining two parts (the lower plate 20 and the upper plate 21) by caulking or the like may be used. In this case, the main body member 3 is sandwiched between these two parts and these are caulked. The main body member 3 can be assembled to the bracket 2 by fixing.

  In the above-described embodiment, the step 55 is formed between the surface 54d of the fitting portion 54 and the surface 53b of the leg portion 53. However, the present invention has a configuration in which the step 55 is not formed. It is also possible, and the surface 54d of the fitting portion 54 and the surface 53b of the leg portion 53 may be formed flush with each other.

In the above-described embodiment, the edge of the retaining portion 29 is in contact with the surface 54d of the fitting portion 54. However, in the present invention, the edge of the retaining portion 29 contacts the surface 54d of the fitting portion 54. For example, the edge of the retaining portion 29 may protrude above the fitting portion 54.
Further, in the present invention, the retaining portion 29 described above can be omitted.

  In addition, in the range which does not deviate from the main point of this invention, it is possible to replace suitably the component in above-mentioned embodiment with a well-known component, and you may combine the above-mentioned modification suitably.

DESCRIPTION OF SYMBOLS 1 Vibration isolator 2 Bracket 3 Main body member 4 Attachment part 5 Elastic body 22 Cylindrical part 25 Rebound stopper part (stopper part)
26 fitting recess 29 retaining portion 53 leg portion 54 fitting portion 55 step

Claims (5)

A bracket attached to either one of the vibration generator and the vibration receiver;
A main body member in which an elastic body is joined to an attachment portion attached to any one of the vibration generating portion and the vibration receiving portion;
With
The elastic body includes an extendable leg portion that is disposed on one side in the vertical direction of the mounting portion and protrudes toward the bracket, and a fitting portion provided at a tip of the leg portion. And
A fitting recess provided on the bracket on one side in the vertical direction of the mounting portion and fitted with the fitting portion, and a vertical direction of the mounting portion on the other side in the vertical direction of the mounting portion. In the vibration isolator provided with a stopper portion that restricts displacement to the other side,
The anti-vibration device according to claim 1, wherein the main body member is sandwiched between at least the stopper portion and the fitting concave portion in a vertical direction and is attached to the bracket in a state where a compression force is applied to the leg portion. The vibration isolator according to claim 1,
The bracket is formed with a cylindrical portion that extends horizontally and the body member is fitted inside,
An anti-vibration device according to claim 1, wherein an end portion in the axial direction of the cylindrical portion is provided with a retaining portion for pressing the fitting portion from the outside in the axial direction. The vibration isolator according to claim 2,
An anti-vibration device, wherein an edge of the retaining portion is in contact with the fitting portion. The vibration isolator according to claim 3,
The anti-vibration device according to claim 1, wherein the fitting portion protrudes outward in the axial direction from the leg portion, and a step is formed between the fitting portion and the leg portion. In the vibration isolator as described in any one of Claim 1 to 4,
The vibration isolator, wherein the bracket is made of a single component, and the main body member is press-fitted inside the bracket.

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