KR102158995B1 - Nozzle structure for engine mount to improve buffering performance - Google Patents

Abstract

The present invention relates to a nozzle structure for an engine mount for improving buffering performance, further comprising an outer wall, an inner wall spaced apart from the outer wall, and a partition plate formed inside the inner wall and having a plurality of first fluid holes A nozzle body including a portion and a flow path formed between the outer wall and the inner wall; A nozzle cover covering the nozzle body and having a plurality of second fluid holes formed therein; And a decoupler accommodated inside the inner wall of the nozzle body and disposed between the diaphragm and the nozzle cover, wherein at least one fluid receiving groove is formed.
That is, the present invention secures fluidity of the fluid as much as the space of the fluid receiving groove by forming at least one fluid receiving groove in the decoupler to accommodate a portion of the fluid, and thereby reducing the dynamic stiffness and loss angle, resulting in NVH performance. And it is intended to propose a nozzle structure for engine mount that can improve the buffer performance.

Description

Nozzle structure for engine mount to improve buffering performance

The present invention secures fluidity of the fluid as much as the space of the fluid receiving groove by forming at least one fluid receiving groove in the decoupler to accommodate a portion of the fluid, thereby reducing the dynamic stiffness and loss angle to reduce the NVH performance and It relates to a nozzle structure for engine mount capable of improving the buffer performance.

In general, the engine of a vehicle has periodic changes in the center position due to the vertical movement of the piston and connecting rod, the inertia force of the reciprocating motion part generated in the axial direction of the cylinder, the inertia force caused by the connecting rod shaking left and right of the crankshaft, and the crankshaft applied The ground is structurally always generating vibration due to periodic changes in rotational force.

The various causes of the above-described vibration generation are not acting alone but acting in combination to generate vibrations in the up and down directions and the left and right directions of the engine.As such, the vibrations inevitably generated from the engine are transmitted through the vehicle body to the interior of the vehicle. If delivered to the vehicle, not only will the comfortable driving environment be impaired, but it will be possible to cause great discomfort to the passengers.

Therefore, it is common to install an engine mount between the engine and the vehicle body that blocks or cancels the transmission of the vibration of the engine generated during the power generation process to the vehicle body.

On the other hand, the fluid type engine mount is to block the vibration of the engine using the flow of fluid, unlike the vibration-proof mount of a general automobile. As shown in FIG. 7, the engine mounted on the upper engine mounting stopper 101 and the lower housing 102 Mounting bolts 103 and pins 104 are integrally formed to be fixed to the engine-side fixing frame 105 and the vehicle body 106 with nuts 107.

At this time, a vibration-proof rubber 108 is attached between the upper engine mounting stopper 101 and the lower housing 102, and an upper cap 109 is attached to the bottom surface of the engine mounting stopper 101.

In addition, a fluid moving space through which a fluid can move is formed under the vibration-proof rubber 108, and a fluid part 110 separated into upper and lower parts and each having a plurality of through holes 110a, and the fluid A decoupler 111 is inserted into the unit 110.

An orifice 112 is further formed in the circumferential direction at the edge of the fluid part 110 as a space through which fluid can move. At this time, the fluid film 113 is coupled to the lower end of the anti-vibration rubber 108 under the fluid part 110.

With this configuration, when the engine key with a vibration area of ±1.0mm is turned on and off, the vibration of the engine is transmitted to the vibration-proof rubber 108 and the vibration-proof rubber moves in the vertical direction, so that the fluid does not pass through the decoupler 111. Without attenuating the vibration through the orifice 112.

In the case of constant speed driving (1000rpm ~ 3500rpm area) with a vibration range of ±0.5 ~ ±0.1mm, the vibration of the engine is attenuated through the decoupler without passing through the orifice 112.

That is, the general vibration isolating rubber for automobiles has an insufficient effect of vibration due to increased rubber characteristics during driving, but the fluid type engine mount controls the increase in dynamic characteristics through the flow of fluid.

However, the fluid type engine mount exhibits higher performance than the general anti-vibration rubber for automobiles, but in the range of 3500rpm to 6000rpm, the dynamic characteristics are increased as the frequency is 100 to 350Hz, and the damping effect of vibration does not appear.

That is, in this region, the flow of the fluid is stopped and vibration is not converted into fluid resistance energy, which causes booming noise of the vehicle.

Korean Registered Patent No. 10-1134425 (registered on 2012.04.02.)

The present invention has been devised to solve the above problems,

By forming at least one fluid receiving groove in the decoupler, the fluid receiving groove accommodates a portion of the fluid to secure the fluidity of the fluid as much as the space of the fluid receiving groove, thereby reducing the dynamic stiffness and loss angle to improve NVH performance and buffering performance. One purpose is what you want to improve.

The engine mount nozzle structure for improving the buffering performance according to the present invention includes an outer wall, an inner wall spaced apart from the outer wall, a partition formed inside the inner wall, and a plurality of first fluid holes, A nozzle body including a flow path formed between the outer wall and the inner wall; A nozzle cover covering the nozzle body and having a plurality of second fluid holes formed therein; And a decoupler accommodated inside the inner wall of the nozzle body and disposed between the diaphragm and the nozzle cover, wherein at least one fluid receiving groove is formed.

The emulsion receiving groove of the decoupler according to the present invention is provided in plural, and is arranged to be symmetrical to each other at the edge of the decoupler.

An upper end of the inner wall of the nozzle body according to the present invention is provided with a protrusion and an insertion portion formed along an outer portion of the protrusion, and an edge surface of the decoupler circumscribes the inner surface of the protrusion, and the insertion portion has the nozzle cover It characterized in that the protrusion formed on the lower surface of the fitting is fitted.

A coupling protrusion is formed at the center of the partition plate according to the present invention, and first and second coupling holes into which the coupling protrusions of the partition plate are fitted are formed in the decoupler and the nozzle cover.

A fitting protrusion is formed on an upper end of the outer wall of the nozzle body according to the present invention, and a fitting groove corresponding to the fitting protrusion is formed on a lower surface of the nozzle cover.

The engine mount nozzle structure for improving the buffering performance according to the present invention forms at least one fluid receiving groove in the decoupler to accommodate a part of the fluid in the fluid receiving groove, thereby securing the fluidity of the fluid as much as the space of the fluid receiving groove, Through this, it is possible to improve the NVH performance and buffer performance by reducing the dynamic stiffness and loss angle.

In addition, according to the present invention, the reliability of the nozzle structure can be improved by preventing the damping effect of vibration from being canceled by forming a sealing structure for each coupling portion of the nozzle body, the nozzle cover, and the decoupler.

1 is an exploded perspective view showing a nozzle structure for an engine mount for improving buffering performance according to the present invention,
2 is a plan view showing the engine mount nozzle structure according to the present invention,
3 is a front cross-sectional view and a side cross-sectional view showing a nozzle structure for an engine mount according to the present invention,
4 is an exploded perspective view showing another embodiment of the engine mount nozzle structure according to the present invention,
5 and 6 are graphs showing the test results of the engine mount nozzle structure according to the present invention,
7 is a cross-sectional view showing a conventional nozzle structure.

In order to explain the present invention and the operational advantages of the present invention and the object achieved by the implementation of the present invention, the following describes a preferred embodiment of the present invention and looks at it with reference.

First, terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention, and expressions in the singular may include a plurality of expressions unless clearly differently in context. In addition, in the present application, terms such as "comprise" or "have" are intended to designate the presence of features, numbers, steps, actions, components, parts, or a combination thereof described in the specification, but one or more other It is to be understood that the presence or addition of features, numbers, steps, actions, components, parts, or combinations thereof, does not preclude in advance the possibility of being excluded.

In describing the present invention, when it is determined that a detailed description of a related known configuration or function may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

As shown in Figs. 1 to 4, the nozzle structure for engine mount for improving the buffering performance includes a nozzle body 10 having a flow path 17 formed thereon, a nozzle cover 30 covering the nozzle body 10, and a nozzle body ( 10) and the nozzle cover 30 is configured to include a decoupler 20 disposed between.

An upper liquid chamber (not shown) is disposed above the nozzle structure configured as described above, that is, above the nozzle cover 30, and a lower liquid chamber is disposed below the nozzle structure, that is, the lower part of the nozzle body 10, so that the fluid flows inside the engine mount. The upper liquid chamber and the lower liquid chamber flow through the flow path 17.

First, as shown in FIGS. 1 and 3, the nozzle body 10 according to the present invention includes an outer wall body 11, an inner wall body 13 spaced apart from the inner wall body 11, and the inner wall body 13 It is formed and includes a partition plate portion 15 in which a plurality of first fluid holes 15a are formed, and a flow path 17 formed between the outer wall body 11 and the inner wall body 13.

The outer wall 11 and the inner wall 13 of the nozzle body 10 according to the present invention have a lower end connected to form a flow path 17 therebetween, and a partition plate part in the horizontal direction at the inner upper part of the inner wall body 13 (15) is placed. A plurality of first fluid holes 15a are formed in the diaphragm 15, and a coupling protrusion 15b formed to protrude upward is formed in the center portion.

In this case, the inner wall body 13 has a protrusion 13c having an upper end higher than the partition 15 and is disposed in a form surrounding the upper part of the partition 15, and the inner wall 13 and the outer wall 11 A lower entrance hole 13d is formed for communication between the flow path 17 and the lower liquid chamber. In addition, a lower liquid chamber 13a is formed in a lower inner portion of the inner wall, that is, under the partition 15.

Next, as shown in FIGS. 1 to 3, the nozzle cover 30 according to the present invention has a plate shape, covers the nozzle body 10, and a plurality of second fluid holes 31 are formed.

In this case, both the nozzle body 10 and the nozzle cover 30 have a rectangular shape, and the first fluid holes 15a of the diaphragm 15 and the second fluid holes 31 of the nozzle body 10 Also, they are formed to correspond to each other within a certain area of a rectangular shape.

In addition, an upper entrance hole 39 is formed at one side of the second fluid hole 31 of the nozzle cover 30 so that the upper liquid chamber and the flow path 17 can communicate with each other.

As shown in Figs. 1 and 3, the decoupler 20 according to the present invention is a membrane made of a rubber material, and the edge surface is external to the inner surface of the protrusion 13c of the inner wall 13 so that the nozzle body 10 It is disposed between the partition plate 15 and the nozzle cover 30 of the. More precisely, the decoupler 20 according to the present invention is disposed between the first fluid holes 15a of the diaphragm 15 and the second fluid holes 31 of the nozzle body 10 so that the upper liquid chamber and the lower It is arranged in a form that partitions the liquid chamber 13a.

In this way, the decoupler 20 is disposed between the partition plate 15 of the nozzle body 10 and the nozzle cover 30, and the decoupler 20 is formed through the first fluid hole 15a and the second fluid hole 31. The pressure of the fluid is applied to the lower and upper surfaces of the. At this time, the first fluid hole 15a and the second fluid hole 31 are formed in a plurality as shown in the accompanying drawings so that the pressure applied to the decoupler 20 can be evenly distributed. It is desirable to be able to increase the durability performance. This suppresses the up-and-down behavior of the decoupler by evenly spraying the pressure of the fluid through a number of fluid holes disposed at the top and bottom of the decoupler when pressure of the fluid is applied to various parts of the decoupler. It is possible to increase durability by preventing pressure concentration.

In particular, at least one fluid receiving groove 21 is formed in the decoupler 20 according to the present invention, which is the case of a conventional decoupler, that is, in the case of a decoupler in which the fluid receiving groove according to the present invention is not formed, During driving, in a constant RPM range (3500rpm ~ 6000rpm), the frequency is 100 ~ 350Hz, and the dynamic stiffness increases, so that the damping effect of the vibration does not appear. There is a problem that causes booming. The frequency at which such booming occurs occurs at approximately 130 Hz as shown in FIGS. 5 and 6, and at this time, NVH performance may be reduced.

In the present invention, in order to solve such a conventional problem, an emulsion receiving groove 21 is formed in the decoupler 20, and the emulsion receiving groove 21 of the decoupler 20 is a region as described above when the vehicle is running. When the flow of the fluid is stopped, a part of the fluid is received. That is, the fluidity of the fluid can be secured as much as the space of the fluid receiving groove 21 of the decoupler 20, and the damping effect of vibration can be increased by reducing dynamic stiffness.

In addition, when the emulsion receiving groove 21 of the decoupler 20 is formed in a single location, it may be formed on one short side (or one long side) as in the left decoupler 20 of FIG. 4. When a plurality of emulsion receiving grooves 21 of the decoupler 20 are provided, more precisely, two locations are formed to be symmetrical to each other on both short sides like the decoupler 20 of FIG. 1, or the right decoupler of FIG. 4 As shown in (20), it may be formed to be symmetrical to each other on both long sides.

However, as described above, when considering the space margin, the fluid receiving groove 21 of the decoupler 20 is formed in plural as the decoupler 20 of FIG. 1 and the right decoupler 20 of FIG. It is desirable to increase the accommodating space of the fluid to increase the fluidity of the fluid to double the damping effect.

5 and 6 show a decoupler 20 in which a distribution groove is not formed, a decoupler 20 in which one fluid receiving groove 21 is formed, and a decoupler 20 in which two emulsion receiving grooves 21 are formed. ) Is a graph comparing the loss angle and dynamic stiffness.

In this case, FIG. 5 is a comparison of the decoupler 20 applied to the front wheel insulator engine mount of gasoline and diesel vehicles, and FIG. 6 is a comparison of the decoupler 20 applied to the four wheel insulator engine mount of gasoline and diesel vehicles. .

First, Table 1 is a test result of the decoupler 20 applied to the front insulator engine mount, and FIG. 5 is a graph showing the loss angle and dynamic stiffness accordingly.

Static characteristics (Ks)
Spec=19±10% Decoupler(20)
thickness Phase
Angle FREQ. Line color One 19.4 Kgf/mm t = 1.8 37.5 deg. 11 Hz blue 2 18.5 Kgf/mm t = 1.6 34.6 deg. 10 Hz Red 3 20.3 Kgf/mm 31.5 deg. 10 Hz yellow 4 17.9 Kgf/mm 32.5 deg. 11 Hz green 5 17.7 Kgf/mm t = 1.6 (single groove) 29.5 deg. 11 Hz Sky blue 6 17.6 Kgf/mm t = 1.6 (multiple grooves) 29.0 deg. 12 Hz White

5(a) shows the loss angle, and FIG. 5(b) shows the dynamic stiffness. As the thickness of the decoupler 20 decreases, the loss angle decreases, and in particular, the emulsion receiving groove 21 is formed. It can be seen that the loss angle decreases compared to the case where the case is not formed. In addition, even when the fluid receiving groove 21 is formed, it can be seen that the loss angle decreases and the frequency increases in the case where two locations are formed than in the case where one location is formed. That is, when two places are formed in the emulsion receiving groove 21, the phase difference is 24.3 deg. It is the minimum, and the frequency is 13 Hz, which indicates that the repulsive force of the decoupler 20 is reduced.

In addition, it can be seen that the dynamic stiffness decreases at about 130 Hz compared to the case where the fluid receiving groove 21 is not formed. Therefore, noise generation can also be reduced by booming.

Next, Table 2 is a test result of the decoupler 20 applied to the four-wheel insulator engine mount, and FIG. 6 is a graph showing the loss angle and dynamic stiffness accordingly.

Static characteristics (Ks)
Spec=19±10% Decoupler(20)
thickness Phase
Angle FREQ. Line color One 19.8 Kgf/mm t = 1.8 38.2 deg. 11 Hz blue 2 19.2 Kgf/mm t = 1.6 36.0 deg. 11 Hz Red 3 20.0 Kgf/mm 32.3 deg. 11 Hz Yellow 4 17.9 Kgf/mm t = 1.6 (single groove) 30.0 deg. 11 Hz Sky blue 5 18.1 Kgf/mm t = 1.6 (multiple grooves) 24.3 deg. 13 Hz White

Tables 2 and 6 are results applied to the four-wheel insulator engine mount, and the results of Tables 1 and 5 are slightly different in detail values in that they are the results applied to the front-wheel insulator engine mount, but the overall trend of the results is similar.

Accordingly, it can be seen that the results of Tables 2 and 6 also decrease the loss angle and dynamic stiffness when the fluid receiving groove 21 is formed in the decoupler 20, thereby improving the vibration damping effect.

In conclusion, in the case of the decoupler 20 according to the present invention, as shown in Tables 1 and 5, 2 and 6, the thickness is preferably 1.6 mm, and there is no significant difference in reducing the loss angle and dynamic stiffness. It is preferable to form two places where the fluid receiving groove 21 is formed at a position symmetrical to the decoupler 20.

Meanwhile, the coupling structure of the nozzle structure according to the present invention will be described in detail with reference to FIGS. 1 and 3.

First, as shown in FIGS. 1 and 3, a protrusion 13c and an insertion part 13d formed along the outer side of the protrusion 13c are provided at the upper end of the inner wall 13 of the nozzle body 10. At this time, the edge surface of the decoupler 20 is circumscribed to the inner surface of the protrusion 13c, and the protrusion 33 formed on the lower surface of the nozzle cover 30 is inserted into the insertion part 13d. That is, when the decoupler 20 is accommodated inside the inner wall 13 of the nozzle body 10, the edge surface of the decoupler 20 comes into contact with the protrusion 13c, and the nozzle body 10 and the nozzle cover 30 ), the protrusion 33 of the nozzle cover 30 is fitted and coupled to the insertion portion 13d of the inner wall 13.

In addition, a fitting protrusion 11a is formed on the upper end of the outer wall 11 of the nozzle body 10, and a fitting groove 35 corresponding to the fitting protrusion 11a is formed on the lower surface of the nozzle cover 30, so that the nozzle body 10 ) And the nozzle cover 30 are coupled, the fitting protrusion 11a of the nozzle body is inserted into the fitting groove 35 of the nozzle cover 30 and coupled.

In addition, a stepped portion 13e is formed under the protruding portion 13c on the inner surface of the inner wall 13 to support the lower surface of the edge portion of the decoupler 20.

In this way, when assembling the nozzle body 10, the decoupler 20, and the nozzle cover 30, the coupling structure can prevent the vibration damping effect from being canceled by maintaining airtightness at the coupling portions.

As described above, the present invention has been described with reference to an embodiment shown in the drawings, but this is only an example, and various modifications and other equivalent embodiments are possible from those of ordinary skill in the art. Will understand.

Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

10: nozzle body
11: outer wall 11a: fitting projection
13: inner wall 13a: lower liquid chamber
13b: lower entrance hole 13c: protrusion
13d: insertion portion 13e: stepped portion
15: partition plate 15a: first fluid hole
15b: coupling protrusion 17: flow path
19: lower entrance hole
20: decoupler
21: latex receiving groove 23: first coupling hole
30: nozzle cover
31: second fluid hole 33: protrusion
35: fitting groove 37: second coupling hole
39: upper entrance hole

Claims (5)

The outer wall body 11, the inner wall body 13 spaced apart from the outer wall body 11, and the partition plate 15 formed in the inner wall body 13 and in which a plurality of first fluid holes 15a are formed. ), and a nozzle body 10 including a flow path 17 formed between the outer wall 11 and the inner wall 13;
A nozzle cover 30 covering the nozzle body 10 and having a plurality of second fluid holes 31 formed therein; And
A decoupler (20) accommodated inside the inner wall (13) of the nozzle body (10) and disposed between the partition plate (15) and the nozzle cover (30), wherein at least one fluid receiving groove (21) is formed ); including,
A protrusion 13c and an insertion part 13d formed along the outer side of the protrusion 13c are provided at an upper end of the inner wall 13 of the nozzle body 10,
An edge surface of the decoupler 20 is circumscribed to the inner surface of the protrusion 13c,
A nozzle structure for engine mount for improving buffering performance, characterized in that a protrusion 33 formed on a lower surface of the nozzle cover 30 is fitted to the insertion part 13d.
The method of claim 1,
The fluid receiving groove 21 of the decoupler 20 is provided in plural,
Engine mount nozzle structure for improving buffering performance, characterized in that arranged to be symmetrical to each other on the edge of the decoupler (20).
delete The method of claim 1,
A coupling protrusion 15b is formed at the center of the partition 15,
The decoupler 20 and the nozzle cover 30 are provided with first and second coupling holes 23 and 37 into which the coupling protrusions 15b of the diaphragm 15 are fitted. Engine mount nozzle structure to improve performance.
The method of claim 1,
A fitting protrusion 11a is formed on the upper end of the outer wall 11 of the nozzle body 10,
An engine mount nozzle structure for improving buffering performance, characterized in that a fitting groove 35 corresponding to the fitting protrusion 11a is formed on a lower surface of the nozzle cover 30.

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