KR20130003749A - Switching engine mount apparatus - Google Patents

Abstract

PURPOSE: A switching engine mount device is provided to effectively attenuate engine vibration of different frequency bands by blocking or permitting vibration by using a vibration isolation member. CONSTITUTION: A switching engine mount device includes a orifice module(400), an air chamber(410), and a decoupler(420). A main fluid chamber(U) and a secondary fluid chamber(L) are divided by the orifice module and are connected with each other by an orifice passage(401). The volume of the main fluid chamber varies by a main rubber(200). The volume of the secondary fluid chamber varies by a secondary diaphragm(300). The air chamber is formed in the orifice module. The decoupler in the orifice module separates the main fluid chamber from the air chamber. One side of the decoupler is contacted with the fluid of the main fluid chamber and the other side is exposed to the air of the air chamber.

Description

Switching engine mount unit {SWITCHING ENGINE MOUNT APPARATUS}

The present invention relates to a switching engine mounting apparatus, and more particularly, to separate and partition a main liquid chamber whose volume is changed by a main rubber and an auxiliary liquid chamber whose volume is changed by an auxiliary diaphragm in communication with each other by an orifice passage. An orifice module is provided, and an air chamber is formed in the orifice module, and the air chamber is separated from the main liquid chamber by a decoupler that absorbs vibration, and the decoupler is blocked by vibration and contact with the vibration blocking member. To an acceptable switching engine mount device.

In the vehicle, the engine can be regarded as a kind of vibration generating source. Therefore, when the engine is mounted on the vehicle body, the vehicle is mounted using a medium called an engine mounting device to reduce the vibration generated by the engine and transmitted to the vehicle body, and thus the noise.

In general, a small gasoline engine vehicle mainly uses a rubber-type bush mount device, and a large gasoline engine vehicle and a diesel engine use a fluid-enclosed engine mount device with fluid inside. . However, these passive engine mounts were not able to reduce vibrations and noises in all structurally variable operating ranges.

In general, vibrations generated in an engine are differently generated in an idle state, a low speed operation state, and a high speed operation state. Therefore, dynamic stiffness of different engine mount devices is required in an idle state, a low speed operation state, and a high speed operation state. do. That is, low dynamic rigidity is required in the idle state, and low dynamic rigidity is required in the low speed driving state in which high speed travel and large vibrations are introduced.

In terms of the frequency of the vibration generated by the engine, it can be divided into a shake region in which low-frequency large displacement vibration occurs, an idle region in which medium-frequency medium displacement vibration occurs, and a booming region in which high-frequency urine vibration occurs. In order to achieve a better vibration damping effect, the engine mount device must have different dynamic rigidity according to each of these areas.

However, the bush type engine mount device or the fluid enclosed hydraulic type engine mount device as described above could not have a vibration damping function in all regions that are variable in structure. Therefore, in recent years, an active engine mount device (or a switching engine mount device) has been developed to enable the control of such variable engine vibration in all areas.

On the other hand, Korean Patent No. 10-0246665 "Attenuation-adjustable fluid-mounted engine mount" provides an auxiliary diaphragm between the upper liquid chamber and the air chamber to assist the air chamber when the vibration of the high frequency micro displacement is input to the engine mount. The diaphragm flows (ie vibrates) to absorb the pressure change in the upper liquid chamber.

In addition, Korean Patent Publication No. 10-2010-0124299 "Multi-stage switchable inertial track assembly" is a decoupler is freely vibrated to generate a decoupling state for low input displacement, or by switching to a vacuum port to vacuum the decoupler When this is done, the decoupler is thereby made unable to vibrate.

In the above, the auxiliary diaphragm or decoupler is referred to hereinafter as the decoupler, and the related arts are regarded as integrated herein.

In order to apply a vacuum to the decoupler in the same manner as in Korean Patent Publication No. 10-2010-0124299, a vacuum device must be provided outside the mounting apparatus, and a predetermined time is required to transfer the vacuum pressure from the vacuum device to the decoupler. As a result, it is difficult to have a fast reaction rate.

The present invention has been made to solve the above problems of the prior art, the main liquid chamber whose volume is changed by the main rubber, and the auxiliary liquid chamber whose volume is changed by the auxiliary diaphragm to communicate with each other by the orifice passage. An orifice module is provided for separating and partitioning. An orifice module is provided with an air chamber, and the air chamber is separated from the main liquid chamber by a decoupler that absorbs vibration. The decoupler is blocked or vibrated by a vibration blocking member. The present invention relates to a switching engine mount device capable of allowing this to effectively attenuate engine vibrations of various frequency bands.

In particular, the present invention allows the vibration of the decoupler in response to the change in the fluid pressure of the main liquid chamber, or to block the vibration of the decoupler in response to the fluid pressure change of the main liquid chamber, it is possible to control the various vibrations of the variable engine vibration In addition, the present invention seeks to provide a switching engine mount device having a very fast operating time.

In order to solve the above problems, the present invention provides an orifice module for separating and partitioning the main liquid chamber whose volume is changed by the main rubber and the auxiliary liquid chamber whose volume is changed by the auxiliary diaphragm so as to communicate with each other by the orifice passage. An air chamber is formed in the orifice module, and a decoupler is provided in the orifice module to separate the air chamber from the main liquid chamber, one side of which is in contact with the fluid of the main liquid chamber, and the other side of which is exposed to the air of the air chamber. An engine mount apparatus, comprising: a vibration blocking member contacting or spaced from the other surface of the decoupler and the vibration blocking member contacting or spaced apart from the decoupler to allow or block vibration of the decoupler. A drive for linearly moving the vibration blocking member And a further comprising characterized by comprising.

In the above, the drive unit may be an electric motor or a solenoid valve.

In the above, the drive unit may be operated by receiving a signal from the ECU of the vehicle to operate according to the vibration state of the engine.

In the above, it is preferable that the anti-shock rubber is mounted on the tip of the vibration blocking member, the vibration blocking member is in contact with the decoupler via the anti-shock rubber.

In the above, the orifice module has a pressure transmission opening is formed so that the fluid pressure of the main liquid chamber is transmitted to the decoupler and has a fixed plate for fixing the decoupler, the vibration blocking member is in contact with the other surface of the decoupler When one side of the decoupler is in contact with the top plate is preferably blocked vibration.

In the above, it is preferable that an atmospheric pressure connection path is formed in the orifice module so that the air chamber communicates with the external atmosphere, and a connection passage is formed in the vibration blocking member to form at least a part of the atmospheric pressure connection path.

As described above, the present invention provides an orifice module for separating and partitioning the main liquid chamber whose volume is changed by the main rubber and the auxiliary liquid chamber whose volume is changed by the auxiliary diaphragm so as to communicate with each other by the orifice passage. An air chamber is formed in the air chamber, and the air chamber is separated from the main liquid chamber by a decoupler that absorbs vibration. The decoupler effectively blocks engine vibration in various frequency bands by allowing the vibration to be blocked or allowed by the vibration blocking member. It provides a switching engine mount device that can attenuate.

In particular, the present invention allows the vibration of the decoupler in response to the change in the fluid pressure of the main liquid chamber, or to block the vibration of the decoupler in response to the fluid pressure change of the main liquid chamber, it is possible to control the various vibrations of the variable engine vibration In addition, it provides a switching engine mount device with a very fast operating time.

1 is a cross-sectional view of an engine mount apparatus according to an embodiment of the present invention;
2 is a view showing a state in which the vibration blocking member in contact with the decoupler in FIG.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention in the drawings, portions not related to the description are omitted, and like reference numerals are given to similar portions throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

1 is a cross-sectional view of an engine mount apparatus according to an embodiment of the present invention, Figure 2 is a view showing a state in which the vibration blocking member in contact with the decoupler in FIG.

As shown in FIG. 1, an engine mount apparatus according to an embodiment of the present invention has an internal space formed by coupling a main rubber 200 and an auxiliary diaphragm 300 to upper and lower sides of a hollow main frame 100, respectively. The fluid is encapsulated, and the orifice module 400 is mounted in the internal space so as to be separated and communicated with each other through the main liquid chamber U and the auxiliary liquid chamber L. In addition, the center bolt 201 is inserted and coupled to the main rubber 200 in the same manner as vulcanization bonding so as to be coupled to the engine.

That is, the main liquid chamber (U) may be changed in volume by the main rubber 200, and corresponds to a portion where vibration is input from the engine, and the auxiliary liquid chamber (L) is formed by the auxiliary diaphragm (300). Can be variable.

In addition, the orifice module 400 allows the main liquid chamber U and the auxiliary liquid chamber L to communicate with each other by the orifice passage 401, and the orifice module 400 connects the main liquid chamber U and the auxiliary liquid chamber L with each other. It is to separate and partition.

Since the configuration of the main liquid chamber (U), the auxiliary liquid chamber (L), the orifice module 400, the main rubber 200, the auxiliary diaphragm 300, etc. is a very general technique in the fluid-mounted engine mount, its detailed description will be described. The drawings shown in this embodiment are omitted and should be understood as an example, and the orifice passage 401 formed in the main liquid chamber U, the auxiliary liquid chamber L, the orifice module 400, and the orifice module 400 is omitted. The structure of the main rubber 200 and the auxiliary diaphragm 300 may be changed in various ways.

When the vibration is generated from the engine according to such a structure, while the deformation occurs in the main rubber 200 through the center bolt 201 is coupled to the engine, the fluid pressure of the main liquid chamber (U) changes, according to the pressure change The fluid enclosed in the main liquid chamber U flows through the orifice passage 401 to the auxiliary liquid chamber L, and the engine vibration is attenuated by the inertial resistance of the fluid generated at this time.

On the other hand, since the technical features of the present invention mean that the vibration of the decoupler can be prevented or allowed to respond to more various types of vibrations, the description of the orifice passage of the orifice module is omitted. However, according to the embodiment, a plurality of orifice passages may be configured to cope with even more various vibrations. Notwithstanding this aspect of the deformation of the orifice passage, if it switches the vibration of the decoupler, which is a technical feature of the present invention, it is within the scope of the present invention.

Meanwhile, an air chamber 410 is formed on the upper surface of the orifice module 400, specifically, the surface facing the main liquid chamber U.

In addition, the decoupler 420 is mounted to the orifice module 400 to separate the air chamber 410 from the main liquid chamber U.

The decoupler 420 separates the air chamber 410 from the main liquid chamber U, whereby one side of the decoupler 420 is in contact with the fluid of the main liquid chamber U, and the other side of the decoupler 420 is the air chamber ( 410 is exposed to the air.

Meanwhile, an atmospheric pressure connection path is formed in the orifice module 400 to communicate the air chamber 410 with the external atmosphere so as to smoothly generate the vibration of the decoupler 420. Therefore, the air inside the air chamber 410 may freely flow along the atmospheric pressure connection path according to the vibration of the decoupler 420.

Such a decoupler 420 mainly absorbs a change in the pressure in the main liquid chamber U when the vibration of the high frequency microdisplacement is input to the engine mount.

The decoupler 420 is preferably formed of a soft material such as rubber so as to absorb high frequency vibration due to the micro displacement.

On the other hand, when the vibration of the decoupler 420 is blocked, relatively high dynamic stiffness can be obtained as compared with the case where the vibration of the decoupler 420 is allowed.

To this end, the vibration blocking member 510 and the driving unit 520 are provided in this embodiment.

The driving unit 520 is a means for linearly moving the vibration blocking member 510 assembled to the orifice module 400, and may be an electric motor or a solenoid valve.

The vibration blocking member 510 provided in the driving unit 520 moves in a line according to the driving of the driving unit 520, and the tip thereof is in contact with the other surface of the decoupler 420 or spaced apart from the decoupler 420.

The vibration blocking member 510 blocks the vibration of the decoupler 420 when it comes into contact with the decoupler 420, and the decoupler 420 when the vibration blocking member 510 is spaced apart from the decoupler 420. Allow vibration of

In order to linearly move the vibration blocking member 510, a driving source for linear movement, such as a solenoid valve, may be used as the driving unit 520. It may be provided with a motion conversion unit for converting.

As described above, the driving unit 520 may contact the vibration blocking member 510 with the decoupler 420 as shown in FIG. 2 or the vibration blocking member 510 as shown in FIG. 1 according to the frequency of the engine vibration. Switching away from the drive can dampen various engine vibrations.

In addition, the driving unit 520 may be configured to be operated by receiving a signal from the ECU of the vehicle to be operated according to the frequency state of the engine vibration.

On the other hand, the vibration blocking member 510 is equipped with an anti-shock rubber 511 at the tip thereof, which is a decoupler via the anti-shock rubber 511 when the vibration blocking member 510 is in contact with the decoupler 420. The contact with the 420 is to prevent excessive impact on the decoupler 420 during the contact of the vibration blocking member 510 and to effectively block the vibration of the decoupler 420.

In addition, the orifice module 400 is provided with a fixing plate 430 to form the orifice passage 401, the fixing plate 430 is a pressure transmission opening (so that the fluid pressure of the main liquid chamber (U) is transmitted to the decoupler 420) 431 is formed.

In addition, the fixing plate 430 serves to fix the decoupler 420 to the orifice module 400.

When the pressure transmission opening 431 of the fixed plate 430 is formed to be somewhat smaller than the total area of the decoupler 420, the vibration blocking member 510 is pushed while contacting the decoupler 420, and the upper surface of the decoupler 420 is pushed. A portion of the fixed plate 430 may be in contact with the vibration of the decoupler 420 can be made more effectively.

On the other hand, the vibration blocking member 510 is formed with a connection passage 512 to form a part of the atmospheric pressure connection path.

In the present embodiment, when the vibration blocking member 510 is spaced apart from the decoupler 420 to allow vibration of the decoupler 420, the air chamber 410 is externally connected by an atmospheric pressure connection path including a connection passage 512. The state in communication with the atmosphere facilitates free vibration of the decoupler 420. Of course, in the present embodiment, the driving unit 520 is also formed with a hole forming a part of the atmospheric pressure connection path.

As described above, the engine mount apparatus according to the exemplary embodiment of the present invention can attenuate engine vibration in various frequency ranges and actively attenuate engine vibration by blocking / allowing vibration of the decoupler.

The foregoing description of the present invention is intended for illustration, and it will be understood by those skilled in the art that the present invention may be easily modified in other specific forms without changing the technical spirit or essential features of the present invention. will be. It is therefore to be understood that the embodiments described above are intended to be illustrative, but not limiting, in all respects. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: main frame
200: main rubber U: main liquid
300: auxiliary diaphragm L: auxiliary liquid chamber
400: orifice module 401: orifice passage
410: air chamber
420: decoupler 430: fixed plate
431 pressure transfer opening
510: vibration blocking member 520: driving part

Claims (6)

An orifice module is provided for separating and partitioning the main liquid chamber whose volume is changed by the main rubber and the auxiliary liquid chamber whose volume is changed by the auxiliary diaphragm in communication with each other by an orifice passage, and an air chamber is formed in the orifice module. In the orifice module, the engine chamber is provided with a decoupler is separated from the air chamber and the main liquid chamber and one side is in contact with the fluid of the main liquid chamber and the other side is exposed to the air of the air chamber,
The vibration blocking member which is in contact with or spaced apart from the other surface of the decoupler and the vibration blocking member is brought into contact with the decoupler or spaced apart from the decoupler so as to allow or block the vibration of the decoupler. Switching engine mounting apparatus characterized in that it further comprises a drive for moving.
The method of claim 1,
Switching engine mounting device, characterized in that the drive unit is an electric motor or a solenoid valve.
The method of claim 1,
And the driving unit is operated by receiving a signal from the ECU of the vehicle to operate according to the vibration state of the engine.
The method of claim 1,
The anti-shock rubber is mounted to the tip of the vibration blocking member, the vibration blocking member is switching engine mounting apparatus characterized in that the contact with the decoupler via the anti-shock rubber.
The method of claim 1,
The orifice module is provided with a pressure transmission opening is formed so that the fluid pressure of the main liquid chamber is delivered to the decoupler and has a fixed plate for fixing the decoupler, the decoupler when the vibration blocking member is in contact with the other surface of the decoupler One side of the switching engine mounting device, characterized in that the vibration is blocked while in contact with the top plate.
The method of claim 1,
And an atmospheric pressure connection path is formed in the orifice module so that the air chamber communicates with an external atmosphere, and a connection passage is formed in the vibration blocking member to form at least a part of the atmospheric pressure connection path.

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