JP2022079138A - Vibration damping body - Google Patents

Abstract

To facilitate, when a grip part for gripping a mass body such as an electric pump is integrated with a base part, the vibration of the grip part relative to the base part to enhance vibration absorbing performance in each direction of the grip part, and to heighten the vibration frequency of the grip part to reduce the amount of displacement involved in the vibration of the mass body.SOLUTION: The vibration damping body includes a grip part 11 for gripping an electric pump 30, a base part 13 via which the grip body 11 is mounted to an engine (40), and a pair of connection parts 12 for connecting a pair of joint portions 11d of the grip part 11 to the base part 13 in an elastically deformable manner. Between the pair of connection parts 12, the grip part 11 is isolated from the base part 13. The grip part 11 includes a connection part 11a for connecting a ring in such a manner that the ring can be cut off in the middle, and the connection part 11a is at an asymmetrical position unequally distant from the pair of joint portions 11d while being deviated on the ring of the grip part 11 to any side with respect to a symmetrical position equally distant from the pair of joint portion 11d.SELECTED DRAWING: Figure 2

Description

The technique disclosed herein relates to a vibration damping body that suppresses vibration of a mass body such as an electric pump.

When the water pump is mounted on the vehicle body, the vibration of the water pump is suppressed from being transmitted to the vehicle body to suppress noise. In addition, the vibration of the vehicle body is suppressed from being transmitted to the water pump, and the durability of the water pump is suppressed from being lowered. Therefore, a rubber bracket is used for the attachment portion of the water pump to the vehicle body (see Patent Document 1).

Japanese Unexamined Patent Publication No. 2015-129480

However, the conventional bracket has a problem that the vibration absorption performance is directional due to its structure, and the vibration isolation performance in a specific direction is insufficient. That is, the grip portion that grips the water pump has a cylindrical shape that wraps the outer circumference of the water pump, and the base portion that serves as a mounting portion to the vehicle body is integrated with this cylindrical grip portion. Therefore, while the vibration in the central axis direction of the cylinder is easily absorbed, the vibration absorption in the radial direction of the cylinder is insufficient.

The technical subject disclosed in the present specification is a vibration damping body that suppresses vibration of a mass body such as an electric pump attached to a vibrating body such as a vehicle body or an engine, which is a vibration source, based on a grip portion that grips the mass body. The purpose is to improve the vibration absorption performance of the grip portion in each direction by facilitating the swing of the grip portion with respect to the base portion when integrated into the portion. Moreover, by increasing the vibration frequency of the grip portion, the amount of displacement due to the vibration of the mass body is reduced.

In order to solve the above problems, the vibration damper disclosed in the present specification takes the following measures.

The first means is a vibration damping body that suppresses the vibration of a mass body such as an electric pump attached to a vibrating body such as a vehicle body or an engine which is a vibration source, and surrounds the outer periphery of the body of the mass body in an annular shape. At least a pair of connections that elastically and deformably connect a grip portion to be gripped, a base portion to which the grip portion is attached to the vibrating body, and a pair of coupling portions located at positions separated from each other on the outer periphery of the grip portion. The grip portion is separated from the base portion between the pair of connecting portions, and the grip portion is an elastic body and includes a connecting portion that is detachably connected in the middle of the ring. The connecting portion is biased to either side with respect to a symmetrical position at an equal distance from the pair of connecting portions on the ring of the grip portion, and is at an asymmetric position at an unequal distance from the pair of connecting portions.

In the first means, the mass body is not limited to the electric pump as long as it vibrates in response to the vibration from the vibrating body. Further, the vibrating body is not limited to the vehicle body and the engine, and is not specified as long as it generates vibration.

According to the first means, the grip portion and the base portion are connected only by a pair of elastically deformable connecting portions. Therefore, the grip portion easily swings in each direction with respect to the base portion, and can absorb the vibration in each direction. Further, the connecting portion connecting the grip portions in an annular shape is set to an asymmetrical position equidistant from the pair of connecting portions. Therefore, the resonance frequency of the grip portion is different on both sides of the connection portion, the vibration frequency when the grip portion swings in the radial direction becomes high, and the displacement amount can be reduced. Therefore, deterioration of the grip portion can be suppressed. Moreover, since the displacement amount of the mass body is small, it is possible to suppress interference with surrounding members.

It is an external perspective view which shows one Embodiment. It is an exploded perspective view of one Embodiment. It is a front view of one Embodiment. FIG. 3 is a cross-sectional view taken along the line IV-IV of FIG. It is a perspective view of the vibration damping body 10 in one embodiment. It is a perspective view of the vibration damping body 10 in one embodiment, and is seen from a different angle from FIG. It is a perspective view of the vibration damping body 10 in one embodiment, and is seen from a different angle from FIGS. 5 and 6. It is a perspective view of the bracket 20 in one embodiment. It is sectional drawing corresponding to FIG. 4 which shows the other embodiment.

<Overall configuration of one embodiment>
1 to 4 show one embodiment. In this embodiment, the electric pump 30 as a mass body is gripped by the vibration damping body 10 and attached to the engine 40 (corresponding to the vibrating body) by the bracket 20. As shown by the arrows X, Y, and Z in FIGS. 1 to 4, the directions of the electric pump 30, the vibration dampener 10 and the bracket 20 are in the X direction (or X1, X2 side) and in the Y direction (or Y1, Y2). This will be described as the side) and the Z direction (or the Z1 and Z2 sides). Here, the Z direction is the direction of gravity. It should be noted that these directions are the same in the figures after FIG.

As shown in FIGS. 1 to 4, the center of gravity 30a of the body of the electric pump 30 is gripped by the grip portion 11 of the rubber vibration damping body 10 (see FIG. 4). Further, the base portion 13 of the vibration damping body 10 is integrated with the bracket 20 by press-fitting the press-fitting portion 22 of the steel plate bracket 20 into the slit 13c thereof. The fixing portion 21 of the bracket 20 is fastened and fixed to the engine 40 by bolts and nuts (not shown) (see FIG. 4). The electric pump 30, the vibration damping body 10 and the bracket 20 are arranged so as to receive the gravity of the electric pump 30 and the vibration damping body 10 on the support surface 22a which is the upper surface of the press-fitting portion 22 of the bracket 20. That is, the electric pump 30 and the vibration damping body 10 are arranged above the press-fitting portion 22 of the bracket 20 (Z1 side). Moreover, the center of gravity 30a of the electric pump 30 is located on the vertical line 22b of the support surface 22a of the bracket 20.

Here, the electric pump 30 pumps the evaporated fuel adsorbed on the canister (not shown) to the intake passage of the engine 40 in order to purge it. The electric pump 30 includes a motor side portion 31 including an electric motor and a control circuit, and a pump side portion 32 including a pressure feed pump, and has a certain weight. Therefore, when the vibration of the engine 40 is transmitted to the electric pump 30, the electric pump 30 also vibrates, which adversely affects the durability of the electric pump 30, and when the electric pump 30 resonates and the swing width becomes large, the electric pump 30 is electrically operated. The pump 30 may interfere with surrounding members and damage the electric pump 30 itself or surrounding members. The vibration damping body 10 suppresses the vibration of such an electric pump 30.

<Structure of vibration damping body>
5 to 7 show the vibration damping body 10 in a state where the bracket 20 is integrated. The vibration damping body 10 includes a grip portion 11 that grips the electric pump 30, a base portion 13 that is fixed to the bracket 20, and a pair of connecting portions 12 that connect the grip portion 11 to the base portion 13.

The grip portion 11 has a cylindrical shape whose dimensions in the central axis direction (X direction) are shorter than the diameter as a whole, and is wound around the body portion of the electric pump 30 as described above. The cylindrical ring is separated at one point to form a connecting portion 11a. In the connecting portion 11a, the grip portion 11 is bent to the outside of the ring to form a pair of flange portions 11e, and the pair of flange portions 11e are separably connected by bolts 14a and nuts 14b. As shown in FIG. 2, the nut 14b has a sleeve, and the bolt 14a integrally includes a washer. Therefore, when the bolt 14a is fastened to the nut 14b, the tip of the sleeve of the nut 14b comes into contact with the washer of the bolt 14a so that the fastening force of the bolt 14a and the nut 14b does not act between the pair of flange portions 11e. ing.

When the grip portion 11 is wound around the body portion of the electric pump 30, the connecting portion 11a is disconnected, and after the winding is completed, the connecting portion 11a is connected by the bolt 14a and the nut 14b. Here, the connection portion 11a is biased toward the Y1 side with respect to the symmetrical position 11f equidistant from the pair of binding sites 11d in the grip portion 11, and is set to an asymmetric position equidistant from the pair of binding sites 11d. (See FIGS. 5 and 6). The pair of binding sites 11d is a site to which the pair of connecting portions 12 are bonded in the grip portion 11. Therefore, the grip portion 11 has a short piece 11b on the Y1 side of the connecting portion 11a and a long piece 11c on the Y2 side of the connecting portion 11a.

The base portion 13 has a shape that wraps the press-fit portion 22 of the bracket 20, and is arranged on the lower side (Z2 side) of the grip portion 11. The pair of binding sites 11d of the grip portion 11 are connected to the base portion 13 by the pair of connecting portions 12. The grip portion 11 is separated from the base portion 13 between the pair of connecting portions 12. Therefore, a cavity 15 is formed in the region surrounded by the pair of connecting portions 12, the grip portion 11, and the base portion 13. Further, the pair of connecting portions 12 are bulged and curved to the outside (Y1 side and Y2 side) opposite to the surfaces facing each other.

On both sides (X1 side and X2 side) of the base portion 13 in the X direction, contact portions 13a and 13b are bases at positions protruding from the grip portion 11 in the central axial direction (X direction) of the cylindrical shape of the grip portion 11. It is integrally formed with the portion 13. The contact portion 13a is formed as a recess in which the upper surface 13d of the base portion 13 is recessed (see FIG. 5). Further, the contact portion 13b is formed with a step slightly lowered from the upper surface 13d of the base portion 13 to the lower side (Z2 side) (see FIG. 6). A convex portion 32a on the outer periphery of the pump side portion 32 of the electric pump 30 is fitted and abuts on the abutting portion 13a (see FIGS. 1, 3 and 4). The contact portion 13b has a shape in which the outer periphery of the motor side portion 31 of the electric pump 30 abuts (see FIGS. 1 and 4). The convex portion 32a on the outer periphery of the pump side portion 32 and the outer periphery of the motor side portion 31 correspond to a portion protruding from the grip portion 11 on the outer circumference of the electric pump 30 (mass body).

The grip portion 11, the base portion 13, and the pair of connecting portions 12 constituting the vibration damping body 10 are integrally formed of rubber. The rubber is supposed to have the ability to attenuate the vibration from the engine 40, the durability against the vibration, and the heat resistance against the high temperature in the engine room.

<Bracket configuration>
FIG. 8 shows the bracket 20 alone. The bracket 20 is formed by bending a single plate-shaped body at a right angle to form a fixing portion 21 and a press-fitting portion 22. An appropriate number (two in this case) through holes 21a are formed in the fixing portion 21, and can be fastened and fixed to a predetermined portion of the engine 40 by bolts and nuts (not shown).

The press-fitting portion 22 is formed with facing surfaces 23 by bending both sides (Y1 side and Y2 side) ends in the Y direction downward (Z2 side) by about 60 degrees. The facing surface 23 forms a surface facing the pair of connecting portions 12 in a state where the press-fitting portion 22 is press-fitted into the slit 13c of the base portion 13. Further, in the press-fitting portion 22, a pair of locking portions 24 are formed on the X2 side of each facing surface 23. Each locking portion 24 is curved so that its tip portion extends outward from the facing surface 23. As a result, each locking portion 24 is configured to be locked to the outer wall surface 13e on the X2 side of the base portion 13 in a state where the press-fitting portion 22 is press-fitted into the base portion 13. Each locking portion 24 is locked to the outer wall surface 13e of the base portion 13 so that the press-fitting portion 22 does not come off from the base portion 13 even if it receives engine vibration.

As shown in FIGS. 2 and 3, the slit 13c of the base portion 13 into which the press-fitting portion 22 is press-fitted is shaped to receive the press-fitting portion 22 provided with the facing surface 23. When the press-fitting portion 22 is press-fitted into the slit 13c, the locking portion 24 is also press-fitted into the slit 13c, so that the slit 13c is deformed to receive the locking portion 24. Then, when the press-fitting portion 22 into the slit 13c is completed, the locking portion 24 penetrates the slit 13c, exits, and is locked to the outer wall surface 13e of the base portion 13. The locking portion 24 is formed so as to be in surface contact with the outer wall surface 13e in a state where the locking portion 24 is locked to the outer wall surface 13e (see FIGS. 6 and 7).

The outer wall surface 13e of the base portion 13 through which the locking portion 24 penetrates the slit 13c and exits is flat around the locking portion 24 so that the operator can easily see the locking portion 24 that has exited through the slit 13c. It is said to be a face. Therefore, the operator who press-fits the press-fit portion 22 of the bracket 20 into the base portion 13 confirms that the press-fit portion 22 has been press-fitted by seeing that the entire locking portion 24 is exposed on the outside of the outer wall surface 13e. Can be done.

Further, a convex portion 25 is formed so as to protrude from the X2 side end portion of the press-fitting portion 22. As shown in FIG. 4, the convex portion 25 is configured to be located on the lower side (Z2 side) of the contact portion 13b when the press-fit portion 22 is press-fitted into the slit 13c. Therefore, the convex portion 25 suppresses the contact portion 13b from being deformed by the gravity of the electric pump 30. The contact portion 13a is supported by the press-fitting portion 22. Therefore, the press-fitting portion 22 and the convex portion 25 form a surface that supports the contact portions 13a and 13b.

<Action and effect of one embodiment>
In the above embodiment, the electric pump 30 is supported by the support surface 22a of the bracket 20 via the contact portions 13a and 13b of the base portion 13. On the other hand, when the electric pump 30 vibrates due to the vibration of the engine 40, the load due to the vibration is supported by the pair of connecting portions 12 via the grip portion 11. The grip portion 11 is separated from the base portion 13 and is connected only via the pair of connecting portions 12. Therefore, it is possible to suppress the transmission of the vibration to the electric pump 30 and the grip portion 11 against the vibration of the base portion 13 in all directions. Further, it is possible to suppress the vibration generated by the electric pump 30 from being transmitted to the engine 40 side. Moreover, the pair of connecting portions 12 are formed in a curved shape. Therefore, the spring constant of the connecting portion 12 can be reduced, and the required vibration absorption performance of the connecting portion 12 can be ensured even if the cross-sectional area of the connecting portion 12 is increased to ensure durability. Further, the vibration absorption performance and the resonance frequency can be adjusted by adjusting the spring constant by adjusting the degree of curvature of the connecting portion 12.

When the electric pump 30 and the grip portion 11 vibrate, the electric pump 30 is in contact with the contact portions 13a and 13b. Moreover, the contact portions 13a and 13b are arranged adjacent to the grip portion 11 toward the outer periphery of the electric pump 30. Therefore, the vibration of the grip portion 11 in each direction is suppressed by the outer periphery of the electric pump 30 coming into contact with the contact portions 13a and 13b, and is converted into a seesaw motion with the contact portions 13a and 13b as fulcrums. That is, the pair of connecting portions 12 flex and vibrate alternately. As a result, the vibration in which the pair of connecting portions 12 sway greatly in the same direction in synchronization is suppressed, and the low-frequency vibration having a large amplitude in the grip portion 11 can be suppressed. Therefore, deterioration of the connecting portion 12 can be suppressed. Moreover, since the electric pump 30 does not vibrate significantly, it is possible to suppress interference with surrounding members.

The contact portions 13a and 13b are supported by the press-fitting portion 22 and the convex portion 25 of the bracket 20 toward the outer periphery of the motor side portion 31 and the pump side portion 32 of the electric pump 30. Further, the pair of connecting portions 12 are supported by a pair of facing surfaces 23 of the bracket 20. Therefore, it is possible to more reliably support the electric pump 30 by the contact portions 13a and 13b. Further, it is possible to stabilize the support of the pair of connecting portions 12 on the base portion 13 and facilitate the design of the vibration absorption performance by the pair of connecting portions 12. Further, it is possible to suppress the deformation of the base portion 13 and improve the durability.

The connecting portion 11a that connects the grip portion 11 in an annular shape is set to an asymmetric position at an unequal distance from the pair of connecting portions 11d. Therefore, the resonance frequency of the grip portion 11 is different on both sides of the connection portion 11a, the vibration frequency when the grip portion 11 swings in the radial direction (Y direction) becomes high, and the displacement amount can be reduced. Therefore, deterioration of the grip portion 11 can be suppressed. Moreover, since the displacement amount of the electric pump 30 can be reduced, interference with the peripheral members of the electric pump 30 can be suppressed.

<Other embodiments>
Although the technique disclosed in the present specification has been described for a specific embodiment, it can be implemented in various other embodiments. For example, in the above embodiment, the electric pump 30 for pumping the evaporated fuel to the engine 40 is a mass body, but the mass body may be another pump such as a water pump or something other than a pump. .. Further, in the above embodiment, the electric pump 30 as a mass body is fixed to the engine 40, but it may be fixed to another vibrating body such as a vehicle body.

In the above embodiment, the connecting portions 12 are paired, but two or more pairs may be used. Further, in the above embodiment, the grip portion 11 has a cylindrical shape, but may have another shape such as a square cylinder shape. Further, in the above embodiment, the contact portion 13a is made a concave portion so that the convex portion 32a of the pump side portion 32 of the electric pump 30 abuts, but the portion of the pump side portion 32 other than the convex portion 32a abuts. It may be shaped.

In the above embodiment, two contact portions (13a, 13b) are provided on both sides of the grip portion 11, but as shown in FIG. 9, only one contact portion 13f may be provided. In that case, the center of gravity 33 is provided on the outer periphery of the body of the electric pump 30 corresponding to the center of gravity 30a, and the contact portion 13f is provided on the base portion 13 so as to abut on the center of gravity 33. The grip portion 11 is divided into two portions on both sides (X1 side and X2 side) of the center of gravity portion 33 to form grip portions 11G and 11H, each of which is connected to the base portion 13 by a pair of connecting portions 12. In FIG. 9, the same parts as those in the above embodiment are designated by the same reference numerals.

In the above embodiment, the press-fitting portion 22 of the bracket 20 is arranged below the electric pump 30 (Z2 side) and supports the center of gravity 30a of the electric pump 30, but the arrangement is not limited to this. For example, the support surface 22a of the bracket 20 is arranged above (Z1 side) with respect to the center of gravity 30a of the electric pump 30, or is inclined in each direction (X direction or Y direction) with respect to the vertical direction (Z direction). It may be arranged separately. Even in such an arrangement, the center of gravity 30a is located on the vertical line 22b of the support surface 22a of the bracket 20, so that the vibration in the direction along the vertical line 22b is supported by the bracket 20 via the contact portions 13a and 13b. It can be received in front of the surface 22a, absorb the vibration by the elasticity of the contact portions 13a and 13b, and suppress the vibration entering the electric pump 30. At the same time, the vibration in the direction slightly deviated from the direction along the perpendicular line 22b can be absorbed by the elastic deformation of the pair of connecting portions 12 to suppress the vibration of the electric pump 30.

In the above embodiment, the connection portion 11a of the grip portion 11 is set to an asymmetric position equidistant from the pair of binding sites 11d, but may be provided at a symmetrical position 11f equidistant from the pair of binding sites 11d. Further, when the connecting portion 11a is set to an asymmetric position, in the above embodiment, the connecting portion 11a is deviated from the symmetrical position 11f to the Y1 side, but may be deviated to the Y2 side. Further, although the pair of flange portions 11e of the connecting portion 11a are fixed by the bolts 14a and the nuts 14b, they may be fixed by other fixing means.

10 Vibration damping body 11, 11G, 11H Grip part 11a Connection part 11b Short piece 11c Long piece 11d Bonding part 11e Flange part 11f Symmetrical position 12 Connection part 13 Base part 13a, 13b, 13f Contact part 13c Slit 13d Top surface 13e Outer wall surface 14a Bolt 14b Nut 15 Cavity 20 Bracket 21 Fixing part 21a Through hole 22 Press-fitting part 22a Support surface 22b Vertical line 23 Facing surface 24 Locking part 25 Convex part 30 Electric pump (mass body)
30a Center of gravity 31 Motor side 32 Pump side 32a Convex 33 Center of gravity 40 Engine (vibrating body)

Claims (1)

A vibration damping body that suppresses the vibration of a mass body such as an electric pump attached to a vibrating body such as a vehicle body or an engine that is a vibration source.
A grip portion that surrounds and grips the outer circumference of the body of the mass body in an annular shape,
A base portion for attaching the grip portion to the vibrating body and a base portion
It is provided with at least a pair of connecting portions for elastically deformably connecting a pair of connecting portions located on the outer periphery of the grip portion at positions separated from each other to the base portion.
The grip portion is separated from the base portion between the pair of connecting portions.
The grip portion is an elastic body and includes a connection portion that is detachably connected in the middle of the ring.
The connection portion is a vibration damped body that is biased to either side with respect to a symmetrical position equidistant from the pair of binding sites on the ring of the grip portion and is located at an asymmetric position equidistant from the pair of binding sites. ..

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