KR20110053648A - Air damping mount having open and close unit for air hole - Google Patents

Abstract

PURPOSE: An air damping mount with an air-hole opening/closing unit is provided to remove the need for a separate power supply unit to drive an air-hole opening/closing unit since the air-hole opening/closing unit opens/closes the air hole while moving up and down by induced current. CONSTITUTION: An air damping mount with an air-hole opening/closing unit comprises a coupling bolt(100), a lower support unit(200), a housing(300) and an air-hole opening/closing unit. The lower support unit is coupled to the lower part of the coupling bolt and supports the coupling bolt. The housing fixes the lower support unit. The housing forms a damping chamber with a space spaced from the bottom of the lower support unit. The opening/closing unit is arranged in the coupling bolt. A space is formed in the coupling bolt to load the air-hole opening/closing unit and an air hole is formed on the side of the coupling bolt. The air-hole opening/closing unit comprises an electromagnetic induction unit and a solenoid valve unit.

Description

Air Damping Mount having Open and Close Unit for Air hole}

The present invention relates to an air damping mount, and more particularly, to the air hole formed in the air damping mount is opened under the excitation of the set amplitude or frequency, and closed under the excitation other than the set amplitude or frequency, The present invention relates to an air damping mount having an air hole opening and closing unit for reducing vibration and noise generated and having a maximum air damping value greater than that of a conventional air damping mount.

In general, the engine of the vehicle always generates vibration and noise by the movement of the piston and the connecting rod as its components.

Vibration and noise of the engine as described above is generated by a variety of causes acting on the engine, these causes, for example, by the vertical movement of the piston and connecting rod constituting the engine Periodic change of the center position, inertial force due to the reciprocating motion generated in the cylinder axial direction, inertia force generated by the left and right flow of the connecting rod and the rotational force applied to the crank shaft can be a periodic change.

When the vibration and noise of the engine are transmitted to the inside of the vehicle through the vehicle body, the driver of the vehicle may cause great discomfort and may damage the comfortable driving environment. Therefore, a means for blocking or offsetting transmission and vibration of the engine generated in the power generation process to the vehicle body is typically used between the engine and the vehicle body.

In other words, a power plant including an engine or an engine and a transmission of an automobile is typically using a mount as a means for suppressing the occurrence of vibration and thus noise.

As such mounts, liquid-sealed mounts, which are generally used to enclose a fluid having a viscosity, are generally used to efficiently dust and soundproof the engine or power plant.

The liquid encapsulation mount has a configuration in which a liquid chamber wrapped in a high-rubber plate and a bellows is divided into an upper liquid chamber and a lower liquid chamber by a plate including a movable plate and an annular passage.

When vibration is transmitted from the engine fixed by using the liquid filling mount, the upper plate is deformed and the volume of the upper liquid chamber is changed, and fluid corresponding to the changed volume is moved from the upper liquid chamber to the lower liquid chamber. The fluid then flows along the annular passageway or between the free gaps of the movable plate. If the amount of fluid corresponding to the deformation volume of the non-rubber plate is greater than the free gap displacement of the movable plate, ie if low frequency large displacement vibration is transmitted from the engine, the fluid will not flow through the gap between the movable plates and flow along the annular passage. At this time, the fluid in the annular passage at a specific frequency causes resonance, and a large damping force is transmitted to the engine to attenuate vibration and noise.

However, the above-mentioned liquid-filled mounts have the disadvantages of high cost and high weight used for manufacturing. Therefore, recently, in order to solve the above disadvantages, air damping mounts having relatively low cost and weight as shown in FIG. 1 have been developed.

The air damping mount functions to attenuate vibration and noise by energy loss generated by the flow of air through the air hole. However, the known air damping mount as described above has a disadvantage in that it is difficult to design freely because the magnitude of vibration attenuation and the frequency at which maximum attenuation occurs simultaneously vary according to the size of an air hole (air hole through which air flows). That is, the maximum damping value of the air damping mount increases as the size of the air hole becomes smaller, whereas the frequency decreases as the size of the air hole becomes smaller, thus tuning the air hole to the frequency so that the maximum damping appears at the desired frequency. If the maximum attenuation value is determined according to the size of the set air hole, on the contrary, if the air hole is designed to the desired level, the maximum attenuation frequency is determined accordingly, so that the maximum attenuation cannot appear in the desired vibration band. There was this.

In addition, air damping appears only when the amplitude of the disturbance is large, and air damping does not appear when the amplitude is small. In the conventional air damping mount, the maximum attenuation frequency is shifted to the high frequency band as the disturbance amplitude is small. .

The present invention was devised to solve the above problems, and the air hole formed in the air damping mount is opened under excitation of a set amplitude or frequency, and closed under excitation other than the set amplitude or frequency. The purpose is to provide a larger air damping mount than the air damping mount.

According to an aspect of the present invention,

An air damping mount comprising: a coupling bolt; A lower support unit penetratingly coupled to a lower portion of the coupling bolt to support the coupling bolt; A housing configured to fix the lower support unit and to form a damping chamber by a space spaced from a bottom surface of the lower support unit; And an air hole opening / closing unit disposed in the coupling bolt, wherein the coupling bolt forms an empty space for loading the air hole opening / closing unit and an air hole formed on the side thereof, and the air hole opening / closing unit vibrates. An electromagnetic induction unit generating a current when applied thereto; It characterized in that it comprises a solenoid valve unit for opening and closing the valve when a current is applied.

In addition, the air hole opening and closing unit, any one of a low pass filter (Low Pass Filter), a high pass filter (High Pass Filter) band pass filter in order to rectify the current generated through the electromagnetic induction unit It further comprises.

In addition, the air hole opening and closing unit is formed in the empty space therein, characterized in that it further comprises a body portion for forming a hole corresponding to the air hole on one side.

In addition, the electromagnetic induction part is characterized in that it comprises a permanent magnet and a coil.

In addition, the electromagnetic induction unit is characterized in that it comprises a plate spring so that the permanent magnet generates resonance by vibration.

The present invention having the configuration as described above,

Since the air hole formed in the air damping mount is closed only at a predetermined amplitude or frequency by the air hole opening / closing unit, there is an effect that the air damping occurs only at the set amplitude or frequency.

In addition, the air hole opening and closing unit opens and closes the air hole while moving up and down by the induced current generated by the vertical movement, there is an effect that does not need to connect a separate power source for driving the air hole opening and closing unit.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 shows an air damping mount having an air hole opening and closing unit according to a preferred embodiment of the present invention, Figure 3 shows an air damping mount having an air hole opening and closing unit according to a preferred embodiment of the present invention.

Referring to the drawings, the air damping mount having the air hole opening and closing unit of the present invention includes a coupling bolt 100, the lower support unit 200, the housing 300, the air hole opening and closing unit 400.

The coupling bolt 100 is connected to the engine of the vehicle and functions to couple the engine of the vehicle to the inside of the vehicle body. The coupling bolt 100 forms an empty space, that is, an air hole opening and closing unit 400 chamber therein, so that the air hole opening and closing unit 400 to be described later can be loaded therein.

The air hole 110 formed in the coupling bolt 100 is preferably formed to be connected to the air hole opening and closing unit chamber formed in the coupling bolt 100. Therefore, the air stored in the damping chamber is passed through the air hole 110 through the air hole opening and closing unit 400 chamber of the coupling bolt 100, or the air entered through the air hole 110 Is configured to be injected into the damping chamber via the air hole opening and closing unit chamber.

The lower support unit 200 is formed by forming a hole corresponding to the shape and size of the lower end of the coupling bolt 100 to insert the lower end of the coupling bolt 100 in the center, and thus, the coupling bolt ( 100) is coupled to the top to support the function.

In addition, the lower support unit 200 is formed so that the center portion of the lower support unit 200 is relatively protruded relative to the edge, so that the lower surface of the lower support unit 200 and the inner bottom surface of the housing 300 to be described later It is made to form a damping chamber in which air can be stored by being formed at a predetermined distance.

The housing 300 functions to fix the coupling bolt 100 and the lower support unit 200. The housing 300 is made to surround the outer surface of the coupling bolt 100 coupled to the lower support unit 200 and the lower support unit 200, the coupling bolt 100 and the lower support portion Function to keep the bond

Air hole opening and closing unit 400 is disposed inside the coupling bolt 100 to function to open and close the air hole 110 formed in the coupling bolt 100, details will be described with reference to FIG. .

4 is a perspective view showing the air hole opening and closing unit 400 according to a preferred embodiment of the present invention.

Referring to the drawings, the air hole opening and closing unit 400 of the present invention includes an electromagnetic induction part 410, a solenoid valve part 420, and a body part 430.

As shown, the electromagnetic induction part 410 is disposed above the air hole opening and closing unit 400, and includes a permanent magnet 411 and a coil 412. In other words, the electromagnetic induction part 410 is configured such that an induction current can be generated by the movement of the permanent magnet 411 by arranging the permanent magnet 411 at the center and surrounding the side with the coil 412. .

In addition, the electromagnetic induction part 410 may further include a plate spring disposed above the permanent magnet 411. The plate spring functions to support the permanent magnet 411, and when the permanent magnet 411 moves up and down by the vibration of the engine, resonance occurs due to the rigidity of the plate supporting the permanent magnet 411. It is configured to.

Preferably, as described above, the resonance generated by the mass of the permanent magnet 411 and the stiffness of the plate spring supporting the permanent magnet 411 is the frequency of the engine shake frequency (or the frequency to be controlled) Design the mass of the permanent magnet 411 and the rigidity of the plate spring to match.

The solenoid valve unit 420 is configured to include a known solenoid valve. The solenoid valve is an electronic valve and is configured to function to open and close the valve by an applied current.

According to a preferred embodiment of the present invention, the solenoid valve part 420 is configured to apply a current generated from the electromagnetic induction part 410.

Therefore, when the current generated from the electromagnetic induction unit 410 is applied to the solenoid valve unit 420, the solenoid valve unit 420 opens the valve 421 in accordance with the applied power, accordingly the air stored in the damping chamber Is configured to exit or close the valve 421 to block movement of air.

Meanwhile, in another embodiment of the present invention, a known filter may be applied to the current generated through the electromagnetic induction part 410 to be transmitted to the solenoid valve part 420. The filter may be, for example, a known RC low pass filter, and the current generated through the coil 412 from the movement of the magnet of the electromagnetic induction part 410 is transferred to the desired frequency range through the RC low pass filter. Only current can be delivered. In other words, the present invention uses electromagnetic induction by the movement of the permanent magnet constituting the electromagnetic induction part 410 according to the vibration of the engine, in which case a large electromagnetic induction is generated not only in the resonant frequency region but also in the high frequency band. . However, since this area is not an area requiring large attenuation, it is possible to reduce the induced current value by using the RC low pass filter as described above. However, the present invention is not limited thereto, and an appropriate filter such as a known band pass filter or high pass filter capable of filtering the frequency of the current can be used. Therefore, it is possible to generate a current only at a desired frequency or amplitude through such filters.

The body part 430 is disposed between the electromagnetic induction part 410 and the solenoid valve part 420, and forms a hole corresponding to the air hole 110 formed in the coupling bolt 100 on one side. In addition, the body portion 430 preferably forms an empty space as shown therein, so that the air can move smoothly. In addition, the body portion 430 has a built-in means for flowing a known current so that the current generated in the electromagnetic induction portion 410 can be transmitted to the solenoid valve portion 420 through the body portion 430 Can be done.

5 and 6 show the solenoid valve portion 420 of the present invention.

The solenoid valve unit 420 is a commonly used electric magnetic valve, and serves to block the air stored in the damping chamber from exiting or to block the flow of air into the damping chamber.

In the conventional solenoid valve, when electricity is supplied to the solenoid coil 412 composed of the core, the inside of the rod portion fitted to the coil 412 is changed into an electromagnet, which is connected to the seat (diaphragm) blocking the flow path portion of the valve. The fronter (the iron rod in the center bar of the coil 412) is lifted by the magnetic force. As a result, the seat (diaphragm) connected with the plunger is raised, which causes the valve flow path to be opened.

The solenoid valve portion 420 constituting the air damping mount having the air hole opening / closing unit of the present invention has a function of opening the valve 421 constituting the solenoid valve portion 420 when a current is applied, similarly to a conventional solenoid valve. Do it.

When no current is applied to the solenoid valve part 420, as shown in FIG. 5, the valve 421 constituting the solenoid valve part 420 is made open by a plate spring. Air in the damping chamber which is configured to be sealed by the solenoid valve part 420 can be moved smoothly, so there is little attenuation by the air damping mount.

However, as described above, even when the engine shake or the like occurs due to the vibration of the vehicle body, or the engine vibration frequency is large enough to operate the solenoid valve unit 420 in the electromagnetic induction unit 410 even if the engine shake frequency is not large. Is generated and applied to the solenoid valve unit 420, as shown in FIG. 6, the yoke 422 constituting the solenoid valve unit 420 becomes magnetic while the plunger 423 moves downward. Accordingly, the valve 421 blocks the air hole to block the flow of air. Therefore, since the air in the damping chamber is sealed by the solenoid valve portion 420, a large pressure is induced and this pressure interferes with the engine vibration, resulting in a large damping.

Although the preferred embodiment of the air damping mount having the air hole opening and closing unit of the present invention has been described in detail, this is merely presented a specific example to help the understanding of the present invention, to limit the scope of the present invention It is not. In addition to the embodiments disclosed herein, it is apparent to those skilled in the art that other modifications based on the technical idea of the present invention may be implemented.

1 shows a conventional air damping mount.

Figure 2 shows an air damping mount having an air hole opening and closing unit according to a preferred embodiment of the present invention.

Figure 3 is a perspective view showing an air damping mount having an air hole opening and closing unit according to a preferred embodiment of the present invention.

4 is a perspective view showing the air hole opening and closing unit 400 according to a preferred embodiment of the present invention.

5 and 6 show the solenoid valve portion 420 of the present invention.

* Explanation of Signs of Major Parts of Drawings *

100: coupling bolt 110: air hole

200: lower support unit 300: housing

400: air hole opening and closing unit 410: electromagnetic induction part

420: solenoid valve portion 430: body portion

411: permanent magnet 412: coil

421: valve 422: yoke

423: plunger

Claims (5)

In the air damping mount, Coupling bolt 100; A lower support unit 200 penetratingly coupled to the lower portion of the coupling bolt 100 to support the coupling bolt 100; A housing 300 which fixes the lower support unit 200 and forms a damping chamber by a space spaced from a bottom surface of the lower support unit 200; An air hole opening and closing unit disposed in the coupling bolt 100; Including; The coupling bolt 100 has an empty space for loading the air hole opening and closing unit 400 therein and forms an air hole formed on the side, The air hole opening and closing unit An electromagnetic induction unit 410 generating a current when vibration is applied; Air damping mount having a solenoid valve unit 420 for opening and closing the valve when the current is applied. The method of claim 1, The air hole opening / closing unit 400 includes a low pass filter, a high pass filter, and a band pass filter to rectify the current generated through the electromagnetic induction part 410. Air damping mount having an air hole opening and closing unit characterized in that it further comprises any one of). The method of claim 1, The air hole opening and closing unit An air damping mount having an air hole opening and closing unit further comprising a body portion 430 forming an empty space therein and forming a hole corresponding to the air hole on one side thereof. The method of claim 1, The electromagnetic induction unit 410 is an air damping mount having an air hole opening and closing unit, characterized in that it comprises a permanent magnet (411) and the coil (412). The method of claim 4, wherein The electromagnetic induction unit 410 is an air damping mount having an air hole opening and closing unit, characterized in that it comprises a plate spring so that the permanent magnet 411 to generate resonance by vibration.

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