KR100980501B1 - switchable hydre-engine mount - Google Patents

Abstract

According to the present invention, the first support 10 made of metal and the second support 12 made of metal, in which the mounting bolts 19 protrude in the axial direction, and the bracket 200 are circumferentially spaced apart by a predetermined distance, are opposed to each other. The rubber elastic body 14 is interposed between the first support body 10 and the second support body 12 so as to form a compression chamber C1 at a lower end thereof. In this state, the rubber elastic body 14 is disposed. ) Is a switchable hydro engine mount in which both supports 10 and 12 are coupled to the rubber elastic body 14 by being vulcanized, and the rubber elastic body 14 is circumscribed to the first support body 10. And a nozzle in the opening 12a of the second support 12, which is inscribed in the second support 12 and defines the compression chamber C1 in cooperation with the lower portion 14b of the rubber elastic body 14. Plate 30, bellows 40, switch spring 50 and cover cup 60 are intimately A vacuum switching module 300 mounted on and mounted as a module is mounted, and the cover cup 60 and the first and second supporting members 10 and 12 at the outermost side are fitted with these brackets to be coupled to each other. 200 is circumscribed, and the nozzle plate 30 and the cover cup 60 are elastically and femalely coupled to each other.

Nozzle Plate, Bellows, Switching Spring, Cover Cup

Description

Switchable hydre-engine mount

The present invention relates to a switchable hydro engine mount.

In general, the anti-vibration member, that is, the hydro engine mount, installed in a driving unit such as an automobile engine, has a role of structural support supporting the connection portion of the engine body, and uses shocks, vibrations, It absorbs the noise.

In general, such an engine mount is conventionally interposed between members constituting the vibration transmission system, and serves to control the transmission of vibration. The support of 2 is connected by the rubber elastic body interposed therebetween, and it is a structure made.

These engine mounts have recently been widely employed in liquid fluid-enclosed hydro engine mounts due to their vibration damping range and limited functionality.

In particular, a fluid-enclosed hydro engine mount that attenuates vibrations transmitted from the engine while driving has a liquid chamber inside a dustproof body formed of rubber material, and inside the liquid chamber is filled with an incompressible liquid fluid to determine a geometric orifice. The longitudinal vibration generated in the frequency band can be absorbed by the flow of the liquid.

In addition, the fluid-enclosed hydro engine mount is provided with a nozzle plate in addition to the orifice and selectively provided with a nozzle plate to attenuate transmission of vibration transmitted from the engine at high speed, low speed, idling and off-road driving to the vehicle body. It is provided with a vacuum switching part for flowing the fluid in the liquid chamber through the orifice or through the orifice in the space between the nozzle plate and the bellows by opening or closing the nozzle of the bellows by connecting or disconnecting to the vacuum source. .

However, the vacuum switch part causes an operation of mounting the nozzle plate, the bellows, the switch spring, and the cover cup into the openings provided in the liquid chamber of the fluid-enclosed hydro engine mount in a sequential order, bringing each other into a single position. There is a problem that the assembly efficiency of the hydro engine mount is lowered by making it work.

The present invention has a problem to be solved in solving the above problems.

This invention can achieve the said subject by making a nozzle plate, a bellows, a switch spring, and a cover cup as a vacuum switching module, and making it mountable in the opening provided in the liquid chamber at once.

By the means for solving the problems as described above, the present invention can reduce the assembly labor of the hydro engine mount by providing a modular vacuum switching unit to the switchable hydro engine mount.

Hereinafter, a switchable hydro engine mount of an embodiment according to the present invention will be described with reference to FIGS. 1 and 2.

1 discloses a switchable hydro engine mount of this embodiment.

The engine mount 100 includes a bracket 200 and a vacuum switching module 300.

The first support 10 and the second support 12 made of metal are disposed on the engine mount 100 so as to face each other at a predetermined distance. In addition, a rubber elastic body 14 is interposed between the first support 10 and the second support 12 so that the compression chamber C1 is formed at the lower end thereof.

The first support 10 is formed in a substantially crisscross shape, and an attachment bolt 19 protrudes in the axial direction and is planted in the first support 10.

The rubber elastic body 14 is circumscribed to the first support 10 as a whole and inscribed to the second support 12.

In addition, the nozzle plate 30, the bellows 40, and the switch spring are provided in the opening 12a of the second support 12, which forms the compression chamber C1 in cooperation with the lower portion 14b of the rubber elastic body 14. 50 and the cover cup 60 are mounted on the vacuum switching module 300, which is placed on the surface and coupled as a module. The cover cup 60 and the second support 12 on the outermost side are mounted. The bracket 200 fitted with these is external.

One side of the cover cup 60 is formed with a port 61 connected to the vacuum source through a valve (not shown).

The nozzle plate 30 has an orifice 31 at the edge and a nozzle 32 at the center, and a valve portion 40a for selectively opening and closing the nozzle 32 at the center of the bellows 40 is provided. It is.
The valve portion 40a closes the nozzle 32 by the elastic force of the switch spring 50, and the bellows with which the port 61 flows through a vacuum source to face the port 61 ( When a negative pressure is applied to the 40 side so that the switch spring 50 can be compressed, the switch spring 50 retreats to open the nozzle 32.
As the nozzle 32 is opened, the space C2 partitioned by the nozzle plate 30 and the bellows 40 is enlarged so that the fluid existing in the compression chamber C1 is transferred to the orifice 31. And enter the space C2 through the nozzle 32.

As illustrated in FIG. 2, a plurality of female receiving portions 33 having a stepped portion 33a are formed on the outer circumferential surface of the nozzle plate 30, and the nozzle is formed at an upper edge portion of the cover cup 60. Male elastic protrusions 62 protruding toward the plate 30 are formed in the same number as the female receiving portions 33.

The male protrusion 62 has a stepped portion 62a that can be male and female coupled to the stepped portion 33a on a radially inner side thereof.

Therefore, the bellows 40 is placed on the nozzle plate 30, the switch spring 50 is placed thereon, and the cover cup 60 is placed on the switch spring 50. ), The male elastic protrusion 62 of the cover cup 60 is accommodated toward the female receiving portion 33 of the nozzle plate 30, and the stepped portion 62a of the male elastic protrusion 62 is increased. The stepped portion 33a of the female accommodating portion 33 is elastically male and female coupled to each other to complete the assembly of the vacuum switching module 300.

After the assembly of the vacuum switching module 300 has been provided in advance, the vacuum switching module 300 is placed on the opening 12a of the second support 12 in the assembling process of the hydro engine mount. The assembly process of the hydro engine mount is simplified by fitting the first and second supports 10 and 12 coupled to each other and the cover cup 60 on the outermost side to the bracket 200.

1 is a cross-sectional view of this embodiment,

2 is a partially cutaway perspective view of the vacuum switching module of this embodiment.

Claims (3)

The first support 10 made of metal and the bracket 200 200 are fitted with the mounting bolt 19 protruding in the axial direction, and the second support 12 made of metal is spaced apart by a predetermined distance. In the switchable hydro-engine mount, which is disposed to face each other, and a rubber elastic body 14 is interposed between the first support 10 and the second support 12 so as to form a compression chamber C1 at a lower end thereof. The rubber elastic body 14 is circumscribed to the first support 10, inscribed in the second support 12, The nozzle plate 30, the bellows 40, and the switch spring 50 are formed in the opening 12a of the second support 12 which forms the compression chamber C1 in cooperation with the lower portion 14b of the rubber elastic body 14. ) And the cover cup 60 is mounted on the vacuum type switching module 300, which is placed on the surface and coupled as a module. In the outermost cover cup 60 and the second support 12, the bracket 200 is fitted to the outside and are externally The nozzle plate 30 and the cover cup 60 are elastically male and female coupled to each other, One side of the cover cup 60 is formed with a port 61 connected to the vacuum source through a valve so as to be flowable, The nozzle plate 30 is formed with an orifice 31 and a nozzle 32 in the center, respectively, In the center of the bellows 40 is provided with a valve portion 40a for selectively opening and closing the nozzle 32, The valve portion 40a closes the nozzle 32 by the elastic force of the switch spring 50, and the bellows with which the port 61 flows through a vacuum source to face the port 61 ( Switchable hydro engine mount, characterized in that when the negative pressure capable of compressing the switching spring (50) on the 40) side, the switch spring (50) retreats to open the nozzle (32). delete The method of claim 1, On the outer circumferential surface of the nozzle plate 30 is formed a plurality of female-type receiving portion 33 having a stepped portion 33a, and a male type protruding toward the nozzle plate 30 at the upper edge of the cover cup 60. The elastic protrusions 62 of the same number as the female receiving portion 33 is formed, The male projecting portion 62 is a switchable hydro engine mount, characterized in that the stepped portion (62a) that can be male and female with the stepped portion (33a) is formed on the radially inner surface.

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