KR100571148B1 - Tuning device for pulsating wave reduction - Google Patents

Abstract

The present invention relates to a tuning device for pulsating wave reduction, which is installed at an inlet side of a pipe and has an eccentric nipple having an eccentric flow path formed therein, and an annular reflection connected between the eccentric nipple and the pipe and extending radially inwardly. Consists of a reflecting nipple equipped with a jaw, it can significantly improve the productivity of the product, can be easily installed in the pipe of small diameter, can be used easily by adjusting the length according to the wavelength of the pulsating pressure .

Description

Tuning device for reducing pressure ripple}             

1 is a cross-sectional view of a tuning apparatus equipped with a conventional spiral tube.

2 is a cross-sectional view of a tuning device according to a first embodiment of the present invention.

3 is a cross-sectional view of a tuning device according to a second embodiment of the present invention.

-Explanation of symbols for the main parts of the drawings-

1: piping 2: resonator

10: eccentric nipple 20: reflective nipple

21: reflection jaw 30: inner tube

31: shaft diameter portion 35: hole

40: appearance 45: resonance room

The present invention relates to a tuning device for pulsating wave reduction, and more particularly, can be easily assembled by connecting in series to a high-pressure pipe, thereby significantly improving the productivity of the product, and can be easily installed in a small diameter pipe. In addition, the present invention relates to a tuning device for pulsating wave reduction that can be used interchangeably by easily adjusting the length according to the wavelength of the pulsating pressure.

Like a hydraulic steering device of a vehicle, a tuner for reducing pulsation is installed in a pipe of a pneumatic device that can generate pulsation waves. In the conventional tuner, as shown in FIG. 1, a spiral tube 50 is provided at the inlet side of the high pressure pipe 1, and an annular chamber 55 is provided between the spiral tube 50 and the high pressure pipe 1. In this case, the echo wave is induced in the annular chamber 55 to reduce the pulsation wave.

That is, in the tuner, in the wavelength interference section L located between the end of the spiral tube 50 and the end of the high-pressure pipe 1, the echo wave and the input wave interfere with each other by the phase difference, and the pulsation pressure is reduced. .

Therefore, such a tuner can reduce the pulsation pressure for a specific frequency by adjusting the length of the spiral tube 50. In addition, one such spiral tube 50 may be provided, or two or more spiral tubes 50 may be arranged in series by being spaced apart by a predetermined distance.

However, this tuning method requires assembling the spiral tube 50 in a narrow inner space of the high-pressure pipe 1, and thus, the assembly process is complicated, and the productivity of the product is lowered. There are various problems such as the difficulty of controlling the length of 50). Nevertheless, there is a problem that can not be mounted on the small diameter pipe (1).

The present invention has been made to solve the above problems, the object of the present invention can be easily assembled by connecting in series to a high-pressure pipe, it is possible to significantly improve the productivity of the product, easy to install in small diameter pipe The present invention provides a tuning device for pulsating wave reduction that can be easily used by easily adjusting the length according to the wavelength of the pulsating pressure.

A first feature of the present invention for realizing the above object of the present invention is a tuning device for reducing a pulsation wave transmitted to a pipe (1), which is provided at the inlet side of the pipe (1) The reflection nipple having an eccentric nipple 10 having an eccentric flow path 11 and an annular reflection jaw 21 connected between the eccentric nipple 10 and the pipe 1 and extending radially inwardly ( It characterized in that it comprises a 20).

In the above, the reflective nipple 20 is helically coupled to the circumference of the eccentric nipple 10 is characterized in that it is possible to adjust the distance between the eccentric flow path 11 and the reflection jaw (21).

The flow path 11 of the eccentric nipple 10 is characterized in that formed in an eccentric position to face one surface of the reflective jaw 21 of the reflective nipple 20.

The flow path 11 of the eccentric nipple 10 is characterized in that the diameter is formed of 25 to 40% of the outer diameter of the eccentric nipple 10.

According to a second aspect of the present invention, a shaft diameter portion 31 is provided around the central portion of the pipe 1, and the shaft portion 31 has a plurality of holes 35 communicating with an internal flow path. The inner tube 30 is formed, and the outer tube 40 is coupled to be spaced apart a predetermined interval around the shaft diameter portion 31 of the inner tube 30 so that the resonance chamber 45 is formed between the shaft diameter portion 31. Resonator 2 is characterized in that at least one or more installed in the pipe (1).

The hole 35 of the resonator is characterized in that less than 0.5mm.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. In addition, this embodiment does not limit the scope of the present invention, but is presented by way of example only and the same parts as in the conventional configuration using the same reference numerals and names.

2 is a cross-sectional view of a tuning device according to a first embodiment of the present invention. As shown, the first embodiment has an eccentric nipple 10 installed at the inlet side of the pipe 1 and having an eccentric flow path 11 formed therein, and connected to the eccentric nipple 10 and extending radially inwardly. It is composed of a reflective nipple 20 provided with an annular reflective jaw 21.

The eccentric nipple 10 is connected to a hydraulic source such as a hydraulic pump, there is formed a flow path 11 eccentrically to one side and a threaded portion 13 is formed around the reflective nipple on the threaded portion (13) 20 are combined.

In addition, the diameter of the flow path 11 is formed to be 25 to 40% of the outer diameter of the eccentric nipple 10 so that the flow path 11 can face the reflecting jaw 21 of the reflecting nipple 20. Preferably, the diameter of the flow path 11 is about 1/3 of the outer diameter of the eccentric nipple 10.

The reflective nipple 20 is installed at the rear end of the eccentric nipple 10, the rear end is provided with an annular reflective jaw 21 extending radially inward. The reflection jaw 21 reflects the pulsating wave toward the eccentric nipple 10, and preferably extends to face the flow path 11 of the eccentric nipple 10.

In addition, the reflective nipple 20 is coupled to the threaded portion 13 of the eccentric nipple 10 is configured to adjust the distance between the flow path 11 and the reflection jaw 21 of the eccentric nipple 10 in accordance with the rotation. . In addition, the first embodiment may be provided with a plurality of predetermined intervals in the middle of the pipe (1).

Referring to the operation and effect of the first embodiment by the above configuration is as follows.

Pulsating pressure generated from a hydraulic source such as a hydraulic pump flows into the reflection nipple 20 through the flow path 11 of the eccentric nipple 10, and a part thereof hits the reflection jaw 21, thereby causing the eccentric nipple 10 again. It is reflected toward and superimposed with a new pulsation wave supplied through the flow path 11 of the eccentric nipple 10. Therefore, the tuning device adjusts the distance between the flow path 11 of the eccentric nipple 10 and the reflecting jaw 21 of the reflecting nipple 20 to 1/2 of the pulsation wave wavelength. Freezes overlap and disappear.

Therefore, in the first embodiment, since the reflective nipple 20 is spirally coupled to the eccentric nipple 10, the distance between the flow path 11 and the reflective jaw 21 can be freely adjusted, so that the pulsating pressure of various wavelengths is provided. Not only can be used interchangeably, but also the pulsation pressure reduction efficiency can be improved by adjusting to the most effective attenuation length. In addition, since the first embodiment only needs to connect the reflective nipples 20 to the eccentric nipples 10 in series, it is very easy to assemble and can be easily coupled to the small diameter pipe 1.

3 is a cross-sectional view of a tuning device according to a second embodiment of the present invention. According to the second embodiment, the resonator 2 is installed in series at the inlet side of the pipe 1 or in the middle of the pipe 1, and the resonator 2 has a shaft diameter around its central part. An inner tube 30 having a plurality of holes 35 communicating with an internal flow path is provided in the shaft diameter portion 31, and the shaft diameter portion 31 is spaced a predetermined distance around the shaft diameter portion 31 of the inner tube 30. It is composed of an appearance 40 to be coupled to the resonance chamber 45 is formed between the shaft diameter portion 31.

The inner tube 30 is connected in series to the pipe 1, and the shaft portion 31 is provided on the center circumferential surface thereof, and the screw portion having a larger diameter than the shaft diameter portion 31 is provided in front and rear of the shaft diameter portion 31. (33) is provided and is configured to couple the exterior (40) to the screw (33). In addition, a plurality of holes 35 are formed in the shaft diameter portion 31 at predetermined intervals along the circumferential direction. At this time, it is advantageous that the hole 35 has a diameter of 0.5 mm or less to reduce the low frequency.

The outer tube 40 is a pipe-shaped member that surrounds the shaft portion 31 of the inner tube 30 so that the resonance chamber 45 is formed between the shaft portion 31 and the screw portion of the inner tube 30. 33) are coupled to the spiral.

Referring to the operation and effect of the second embodiment by the above configuration is as follows.

Pulsating pressure generated from a hydraulic source such as a hydraulic pump is introduced into the pipe 1 through the inner tube 30, wherein a plurality of holes 35 communicating with the resonance chamber 45 are formed in the central portion of the inner tube 30. It is formed to vibrate the thin oil layer in the hole (35). At this time, the thin oil layer in the hole 35 and the circumferential resonance chamber 45 constitute one resonant system having a mass and a spring as one Helmholtz resonator, to wash the thin oil layer in the hole 35 area. By vibrating, the pulsating pressure is converted into heat energy by friction and absorbed.

Therefore, in the second embodiment, since the resonators 2 are connected to the pipe 1 in series, the assembling work is very easy and can be easily combined with the pipe 1 having a small diameter. In addition, such a resonator 2 is small in size and easy to assemble so that a plurality of resonators 2 having holes 35 and resonance chambers 45 corresponding to pulsating pressures of various wavelengths are placed in the middle of the pipe 1. When mounted in series, the pulsation pressure of various wavelengths can be reduced, which is effective.

The present invention as described above, the assembly is completed just by connecting the tuning device in series with the pipe, the assembly properties can be improved to significantly improve the productivity of the product, can be easily combined and used in small diameter pipes.                     

In addition, in the case of the first embodiment, since the reflection nipple exposed to the outside can be easily adjusted to adjust the length of the pulsation pressure reflection section, it can be used interchangeably for pulsation pressures of various wavelengths. In addition, the resonator of the second embodiment is small in size and easy to assemble, and when a series of resonators having holes and resonance chambers corresponding to pulsating pressures of various wavelengths are installed in series in the middle of the pipe, pulsating pressures of various wavelengths can be reduced. It can be effective.

Claims (6)

In the tuning device for reducing the pulsating wave transmitted to the pipe, And an eccentric nipple having an eccentric flow path formed therein, and a reflective nipple connected between the eccentric nipple and the pipe and having an annular reflecting jaw extending radially inwardly. Tuning device for pulsating wave reduction. The pulsating wave reduction tuning device of claim 1, wherein the reflection nipple is coupled to a circumference of the eccentric nipple to adjust a distance between the eccentric flow path and the reflection jaw. The pulsating wave reduction tuning device of claim 1, wherein the flow path of the eccentric nipple is formed at an eccentric position to face one surface of the reflective jaw of the reflective nipple. The pulsating wave reduction tuning device according to claim 1, wherein the flow path of the eccentric nipple has a diameter of 25 to 40% of an outer diameter of the eccentric nipple. In the tuning device for reducing the pulsating wave transmitted to the pipe, It is connected to the pipe in series and is provided with a shaft diameter portion around the central portion, the shaft portion has an inner tube formed with a plurality of holes communicating with the internal flow path, and the shaft diameter portion is coupled to be spaced apart around the shaft diameter portion of the inner tube and Tuning device for pulsating wave reduction, characterized in that at least one or more resonators are formed in the pipe so that the resonance chamber is formed between the. The tuning device for pulsating wave reduction according to claim 5, wherein the hole of the resonator is 0.5 mm or less.

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