KR101305717B1 - Air damping mount having multiple damping structure - Google Patents

Abstract

The present invention relates to an air damping mount having a multi-damping structure, the present invention includes: an engine side fixing portion having one end fixed to the engine and the other end extending to form a bar-shaped rod; A first main rubber of rubber material coupled to a lower portion of the engine side fixing part and vertically flowing as vibration of the engine is transmitted; A first working chamber formed under the first main rubber and filled with air therein and having a first friction damping hole through which one side of the air is discharged to the outside; A second main rubber of rubber material installed in the first working chamber and connected to the rod to divide the first working chamber; And a second working chamber formed by being divided from the first working chamber by the second main rubber and filled with air, and having a second friction damping hole through which one side discharges air to the outside. It features.

Air Damping Mount, Working Chamber, Friction Reduction Hole, Main Rubber, Sub Rubber, Chamber Bulkhead

Description

Air damping mount having multiple damping structure

The present invention relates to an air damping mount having a multiple damping structure. More particularly, the present invention relates to an air damping mount having a multiple damping structure, which is advantageous in layout design and has a high degree of freedom in design, by reducing the mount radius and having a plurality of friction damping holes. It is about.

In general, the engine of a vehicle is applied to the periodic change of the center position by the vertical movement of the piston and the connecting rod, the inertial force of the reciprocating portion occurring in the axial direction of the cylinder, the inertia force of the connecting rod swinging from the left and right of the crank shaft, and the crank shaft. The vibration always occurs structurally due to the periodic change of the rotational force.

The causes of the vibrations are not acting alone but in combination to generate vibrations in the vertical and horizontal directions of the engine, and when such vibrations are transmitted to the interior through the vehicle body, they may damage the pleasant driving environment and cause discomfort to the occupants. Can be.

Therefore, an engine mount is installed between the engine and the vehicle body to block or offset the vibration of the engine generated during the power generation process to the vehicle body.

The engine mount is a rubber rubber engine mount, a fluid engine mount that fills the fluid to attenuate it, and an air damped mount that fills the air instead of the fluid to attenuate it. Etc.

Although rubber engine mounts are cheaper than fluid engine mounts, they have disadvantages in terms of attenuation characteristics. Fluid engine mounts have the advantage of insulating vibration and noise by the effect of attenuation on fluid mass, but they are expensive. .

Air damping mounts are disadvantageous over rubber engine mounts in terms of price, but are advantageous over fluid engine mounts, and are disadvantageous over fluid engine mounts in performance, but are advantageous over rubber engine mounts. When the size and shape of the working chamber of the air damping mount is similar to that of the fluid engine mount, the working fluid is air, so that the damping performance is low because the characteristics such as viscosity are lower than those of oil.

In order to solve this problem, the invention described in the cited patent WO2004 / 031608 adopts a method of increasing friction attenuation by increasing the amount of moving fluid between working chambers for the same excitation displacement, thereby increasing the mount diameter.

However, these conventional air damping mounts have disadvantages in terms of package layout design.

SUMMARY OF THE INVENTION An object of the present invention is to provide an air damping mount having a multiple damping structure having a design freedom by reducing the mount radius and facilitating package layout design and having multiple friction damping holes to diversify the tuning frequency.

In order to achieve the above object, the present invention includes: an engine side fixing part having one end fixed to the engine and the other end extending to form a bar-shaped rod; A first main rubber of rubber material coupled to a lower portion of the engine side fixing part and vertically flowing as vibration of the engine is transmitted; A first working chamber formed under the first main rubber and filled with air therein and having a first friction damping hole through which one side of the air is discharged to the outside; A second main rubber of rubber material installed in the first working chamber and connected to the rod to divide the first working chamber; And a second working chamber formed by being divided from the first working chamber by the second main rubber and filled with air, and having a second friction damping hole through which one side discharges air to the outside. An air damping mount having a multiple damping structure is provided.

Located between the first main rubber and the second main rubber, characterized in that it further comprises a rubber sub-rubber coupled to the rod.

And one end coupled to an end of the sub rubber and the other end coupled to a wall surface of the first working chamber to divide the first working chamber together with the sub rubber.

And a third working chamber which is divided from the first working chamber by the sub-rubber and the chamber partition wall to fill air therein, and has a third friction reducing hole for discharging air to one side. It is done.

As described above, the air damping mount having a multi-damping structure according to an embodiment of the present invention is easy to design the package layout by reducing the mount radius, and can be designed to diversify the tuning frequency by providing a plurality of friction damping holes There is a high degree of freedom.

Hereinafter, an air damping mount having a multiple damping structure according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic diagram showing the air damping mount of the cited invention, Figure 2 is a schematic diagram showing the air damping mount of the present invention.

As shown in FIG. 1, the air damping mount 10 of the cited invention is mainly composed of a main rubber 12 and an operation chamber 14 formed below the main rubber 12, and the working chamber 14. The friction damping hole 16 is formed therethrough.

The radius of the air damping mount 10 according to the cited invention is denoted by R1.

On the contrary, as shown in FIG. 2, the air damping mount 100 according to the present invention has a mount radius R2 smaller than the radius of the air damping mount 10 according to the cited invention, and a plurality of working chambers are provided. do.

For the same excitation displacement, the amount of air movement as the mount radius changes is proportional to the square of the mount radius ratio ((R2 / R1) ² ). Therefore, as the mount radius decreases, the amount of air movement decreases and the damping force decreases. However, in the case of the present invention, by providing a plurality of working chambers can be compensated for the loss of air movement due to the reduction in the mount radius.

Referring to Figure 2 in detail the structure of the air damping mount 100 according to an embodiment of the present invention.

The air damping mount 100 includes an engine side fixing part 170 having a rod 170a formed thereon, a first main rubber 110 coupled to the engine side fixing part 170, and a lower portion of the first main rubber 110. Is divided from the first working chamber 140 formed by the first working chamber 140, the second main rubber 120 installed inside the first working chamber 140, and the second main rubber 120. It is composed of a second working chamber 160 is formed.

In addition, the air damping mount 100 may include a sub-rubber 130 and a chamber partition wall 180 installed between the first main rubber 110 and the second main rubber 120, and a first working chamber ( And a third working chamber 150 which is divided from 140.

The engine-side fixing part 170 has one end fixed to the engine and the other end extending in the opposite direction to form a bar-shaped rod 170a. The first main rubber 110 is coupled to an end of the engine side fixing part 170 fixed to the engine, and the second main rubber 120 and the sub rubber 130 are fixed to the rod 170a.

The first main rubber 110 is made of a rubber material, is coupled to the lower portion of the engine-side fixing part 170 and serves to attenuate the vibration while flowing up and down as the vibration of the engine is transmitted.

The first working chamber 140 is formed at the lower portion of the first main rubber 110 and fills air therein to serve as vibration attenuation. 1 The friction damping hole 142 is formed through.

The first working chamber 140 is divided into a plurality of different chambers by the second main rubber 120, the sub rubber 130, and the chamber partition wall 180 to compensate for the loss of air movement due to the decrease in the mount radius. 2 illustrates an example in which the first working chamber 140 is divided into three chambers, but may be divided into a larger number of chambers by the addition of a rubber.

The second main rubber 120 is made of a rubber material, is installed in the lower side of the first working chamber 140 and connected to the end of the rod 170a, and divides the first working chamber 140 to the second walking. The chamber 160 is formed. Since the second main rubber 120 is connected to the rod 170a, the excitation displacement transmitted to the first working chamber 140 is simultaneously transmitted to the second working chamber 160.

The second working chamber 160 is formed by being divided from the first working chamber 140 by the second main rubber 120 and filled with air to act as vibration attenuation, and on one side, the air is compressed by vibration. The second friction damping hole 162 is formed to penetrate the outside.

The sub rubber 130 is made of a rubber material and is installed in the first working chamber 140 to be positioned between the first main rubber 110 and the second main rubber 120, and one end of the rod 170a. And the other end is fixed to the chamber partition wall 180. Since the sub-rubber 130 is connected to the rod 170a, the excitation displacement transmitted to the first working chamber 140 is simultaneously transmitted to the third working chamber 150 to be described later.

The chamber partition 180 has one end coupled to the end of the sub rubber 130 and the other end coupled to the wall surface of the first working chamber 140 to repartition the first working chamber 140 together with the sub rubber 130. The third working chamber 150 is formed. The first working chamber 140 and the third working chamber 150 are hermetically sealed by the sub rubber 130 and the chamber partition wall 180.

However, since the sub-rubber 130 is also coupled to the rod 170a, when the displacement occurs, the sub-rubber 130 also moves according to the displacement, and thus, the first working chamber 140 and the third working chamber 150 have an air movement amount. Losses may occur at

However, by setting the radius R3 of the subrubber 130 to be smaller than R2, the loss of air movement amount can be reduced, and this loss can be compensated by the plurality of working chambers.

The third working chamber 150 is formed by being divided from the first working chamber 140 by the sub-rubber 130 and the chamber partition wall 180 and filled with air to act as vibration attenuation, and on one side by vibration When compressed, the third friction damping hole 152 is formed to penetrate the air to the outside.

In the air damping mount 100 of the present invention having such a configuration, displacement occurs in the first main rubber 110 and the second main rubber 120 when an external force is applied to the mount, and accordingly, the first working chamber 140 ), And the volume change occurs in the third working chamber 150 and the second working chamber 160.

Due to the volume change of the working chambers, a pressure difference is generated between the working chambers and the outside of the mount, and the pressure change causes the air of the working chambers to escape through the respective friction damping holes.

Although the air damping mount of the present invention reduces the mount radius compared to the cited invention, the loss of air movement can be compensated by a plurality of working chambers, and the radius reduction can overcome the disadvantages in designing the package layout. .

In addition, since a plurality of friction damping holes can be configured, the tuning frequency can be diversified, thereby improving design freedom.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. And such changes are within the scope of the appended claims.

1 is a schematic diagram showing an air damping mount of the invention cited.

2 is a schematic diagram showing an air damping mount of the present invention.

DESCRIPTION OF THE REFERENCE NUMERALS

100: air damping mount 110: first main rubber

120: second main rubber 130: sub rubber

140: first working chamber 142: first friction reducing hole

150: third working chamber 152: third friction reducing hole

160: second working chamber 162: second friction reducing hole

170: engine side fixing portion 170a: rod

180: chamber bulkhead

Claims (8)

An engine side fixing part 170 having one end fixed to the engine and the other end extending to form a bar-shaped rod 170a; A first main rubber (110) made of a rubber material coupled to a lower portion of the engine side fixing part (170) and vertically flowing as the vibration of the engine is transmitted; A first working chamber 140 formed at a lower portion of the first main rubber 110 and filled with air therein and having a first friction damping hole 142 penetrating therethrough for discharging air to one side; One end is connected to the lower end of the first working chamber 140, the other end is coupled to the end of the rod 170a, the second main rubber of rubber material that flows up and down according to the vibration transmitted to the rod 170a 120; And A second working chamber 160 formed at a lower portion of the second main rubber 120 and filled with air, and having a second friction damping hole 162 through which one side discharges air to the outside. Air damping mount having a multiple damping structure, characterized in that. The method of claim 1, Located between the first main rubber 110 and the second main rubber 120, the rubber sub-rubber 130 is coupled to the rod (170a) and one end of the sub-rubber 130 Air damping mount having a multiple damping structure characterized in that it further comprises a chamber partition wall 180 coupled to the other end is coupled to the wall surface of the first working chamber (140). 3. The method of claim 2, The third rubber attenuation hole 152 is formed at the lower side of the sub-rubber 130 and the chamber partition wall 180 and the second working chamber 160 and filled with air, and discharges air to one side. Air damping mount having a multi-damping structure, characterized in that it further comprises a third working chamber (150) formed. 3. The method of claim 2, The radius R3 from the center of the rod 170a to the end of the sub rubber 130 is set smaller than the radius R2 from the center of the rod 170a to the end of the first main rubber 110. Air damping mount having a multiple damping structure, characterized in that. An engine side fixing part 170 having one end fixed to the engine and the other end extending to form a bar-shaped rod 170a; A first main rubber (110) made of a rubber material coupled to a lower portion of the engine side fixing part (170) and vertically flowing as the vibration of the engine is transmitted; A first working chamber 140 formed at a lower portion of the first main rubber 110 and filled with air therein and having a first friction damping hole 142 through which one side discharges air to the outside; A sub rubber 130 having a rubber material installed at a lower side of the first working chamber 140 and having one end coupled to the rod 170a; A chamber partition wall 180 having one end coupled to an end of the sub rubber 130 and the other end connected to a lower end of the first working chamber 140; And A third friction damping hole is formed in the lower portion of the first working chamber 140 to be located below the sub-rubber 130 and the chamber partition wall 180 and filled with air, and discharges air to one side. Air damping mount having a multi-damping structure, characterized in that it comprises a third working chamber (150) formed (152). The method of claim 5, One end is connected to the lower end of the first working chamber 140, the other end is coupled to the end of the rod 170a, the second main rubber of rubber material that flows up and down according to the vibration transmitted to the rod 170a Air damping mount having a multiple damping structure, characterized in that it further comprises (120). The method according to claim 6, The second working chamber 160 is formed below the second main rubber 120 and has air filled therein, and has a second friction damping hole 162 through which one side of the air is discharged to the outside. Air damping mount having a multiple damping structure comprising a. The method of claim 5, The radius R3 from the center of the rod 170a to the end of the sub rubber 130 is set smaller than the radius R2 from the center of the rod 170a to the end of the first main rubber 110. Air damping mount having a multiple damping structure, characterized in that.

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