KR20040018720A - Ring Type Cap Of Spiral Tuner For Reducing Pressure Ripple In High Pressure Hose - Google Patents

Abstract

PURPOSE: A ring-type spiral cap in a high-pressure hose for damping pulse is provided to improve stable pulse-damping performance in the high-pressure hose and improve noise reduction performance. CONSTITUTION: A ring-type spiral cap in a high-pressure hose for damping pulse comprises a hose forming a first space part(11) in the axial line direction; connecting pipes(12) combined to one end and the other end of the hose; a spiral tuner(20) spirally forming a steel band along the periphery; and a spiral tuner cap(30) axially combined to the other side of the spiral tuner. The spiral tuner has a diameter relatively smaller than the first space part so that one side of the spiral tuner is axially combined to one of the connecting pipes and the other side of the spiral tuner is positioned to the first space part of the hose.

Description

Ring Type Spiral Tuner For Reducing Pressure Ripple In High Pressure Hose

The present invention relates to a ring-shaped cap in a spiral tuner used for a pulsation reduction hose, and a power pump for a vehicle, a fire hose for a fire engine, as well as a vane pump. It can be widely applied to pulsation reduction of high pressure hose used for piping of pump) and other hydraulic equipment.

Hereinafter, a high pressure hose for pulsation reduction using a conventional spiral tuner will be described with reference to the accompanying drawings.

1 is a first schematic diagram of a high-pressure hose for pulsation reduction using a conventional spiral tuner.

As shown in FIG. 1, the coupling pipe 3 is fitted to both sides of the pulsation reducing high pressure hose 1, and a spiral tuner 5 is inserted into the coupling pipe 3 on one side.

The high pressure hose 1 having such a structure is formed with an annular chamber 7 between the spiral tuner 5 and the hose 1 based on the branch pipe theory, thereby inducing the generation of echo waves and interfering with the wavelength. The pulsation pressure is reduced by using the interference / offset of the wave due to the phase difference between the generated echo and the tuner 5 generated in the sections L1 and L2.

In addition, the tuner 5 acts as a tuning pipe to the pulsation in the high pressure hose 1 based on the quarter-wavelength lambda principle.

That is, when the length of the tuner 5 is one quarter of the pulsation pressure wavelength λ , the phase of the echo wave generated in the annular chamber 7 is equal to the pressure wave passing through the tuner 5 and π ( Phase difference).

Therefore, since the pressure wave and the echo wave encountered in the wavelength interference section L2 cancel each other, the high-pressure hose 1 using the spiral tuner 5 serves to reduce the pulsation pressure of a specific wavelength or a specific frequency.

2 is a second schematic diagram of a high-pressure hose for pulsation reduction using a conventional spiral tuner.

As shown in FIG. 2, the pulsation reducing high pressure hose 1 is fitted with three connecting pipes 3 at both sides and a central portion, respectively, and two spirals at the connecting pipe 3 at one side and the central portion. The tuner 5 is a double spiral structure in which the tuner 5 is inserted in the axial direction.

This structure is used in the structure of the long length of the high pressure hose 1, and the pulsation pressure is reduced by canceling the echo wave and the input wave generated in the first annular space 7 and the reduced pulsation pressure is reduced. The pulsation pressure can be reduced more efficiently by re-compensating with the echo generated in the other second annular space 7a.

As described above, the cancellation of the pulsating pressure is determined according to L1 length, that is, the length of the spiral tuner.

In addition, the length of the wavelength interference section L2 greatly affects the generation of the echo wave in the propagation path of the pulsating pressure wave and in the annular spaces 7, 7a.

Therefore, the pulsation reduction performance and noise reduction performance of the pulsation reducing high pressure hose (1) using the spiral tuner (5) can be improved by appropriately setting the length of the wavelength interference interval.

Accordingly, the present invention has been made in view of the above-described conventional problems, and a first object of the present invention is to provide a ring-type spiral cap in a high-pressure hose for pulsation reduction that can improve a more stable pulsation reduction performance into the high-pressure hose. To provide.

The second object of the present invention is to connect the spiral cap having a radiation plate to the other end of the spiral tuner, so that the pulsation reduction performance and the noise reduction performance can be improved by appropriately setting the length of the wavelength interference section. It is to provide an inner ring type spiral cap.

Objects of the present invention, the hose 10 is formed with a first space portion 11 of a predetermined diameter along the axial direction;

A connection pipe 12 coupled to one end and the other end of the hose 10;

One side is axially coupled to any one of the connecting pipe 12 is selected and the other side has a relatively smaller diameter than the first space 11 to be located in the first space 11 of the hose (10) Spiral tuner 20 having a strip steel spirally along the outer circumference; And

It is achieved by a ring-type spiral cap in the high-pressure hose for pulsation reduction, characterized in that it comprises a spiral tuner cap 30 is axially coupled to the other side of the spiral tuner 20.

In addition, the spiral tuner 20 may further include a second space portion 22 having a predetermined inner diameter along the axial direction.

In addition, the cap 30 is connected to the other end of the spiral tuner 20 in the shape corresponding to the connection portion 31,

A reflection plate 32 positioned at a predetermined interval along the axial direction toward the other side of the connecting portion 31;

Located between the reflecting plate 32 and the connecting portion 31, one side is connected to the other end of the connecting portion 31 and the other side comprises a support portion 33 is connected to one side of the reflecting plate 32 It is preferable.

The connection part 31 may further include a third space part 31a which is connected to the second space part in the spiral tuner 20.

In addition, the inner diameter of the reflecting plate 32 is preferably 0.7 times to 1.5 times the inner diameter of the second space part 22.

The outer diameter of the reflecting plate 32 is preferably 0.7 times to 0.95 times the inner diameter of the first space 11.

In addition, the length of the support 33 is preferably 2mm to 12mm.

Other objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and the preferred embodiments associated with the accompanying drawings.

1 is a first schematic diagram of a high-pressure hose for pulsation reduction using a conventional spiral tuner;

2 is a second schematic diagram of a high-pressure hose for pulsation reduction using a conventional spiral tuner;

3 is a configuration diagram showing a state in which the spiral cap is coupled to the high-pressure hose for pulsation reduction according to the present invention,

4 is a partially enlarged view according to A of FIG. 3;

5 is a perspective view of a spiral cap according to the present invention,

Figure 6 is a simplified diagram of a high-pressure hose for pulsation reduction in accordance with the present invention.

<Short Description of Main Reference Signs>

1: hose 3: connector

5: spiral tuner 7: space part of the first ring

7a: second annular space portion 10: hose

11: first space part 12: connector

20: spiral tuner 21: band steel

22: second space part 30: spiral tuner cap

31: connecting portion 31a: third space portion

32: reflector 33: support

Next, the ring type spiral cap in the high-pressure hose for pulsation reduction according to the present invention will be described with reference to the accompanying drawings.

3 is a configuration diagram showing a spiral cap coupled to the high-pressure hose for pulsation reduction according to the present invention, Figure 4 is a partial enlarged view according to A of Figure 3, Figure 5 is a spiral cap of the present invention Perspective view.

3, 4 and 5, the pulsation reducing high pressure hose 10 is a circular first space portion 11 formed along the axial direction, one end and the other end of the hose 10 Inserted into and fixed to the connecting pipe 12 and the fitting pipe 12 is fitted to one side of the hose 10, the other side is on the first space portion 11 of the hose 10 Spiral tuner 20 is located in, and the spiral tuner cap 30 is coupled to the other end of the spiral tuner 20 in the axial direction.

In this case, the hose 10 is a fluid flowing tube, and may be used in gold, copper, nickel, brass, and bronze, in addition to the rubber material described in the embodiments, and may be made of natural rubber, silicone, and plastic, such as acrylic resin and epoxy. The resin, polyvinyl resin, polypropylene resin may also be included in the present invention.

The hose 10 has a first space portion 11 is formed along the axial direction to flow the fluid having a pulsating pressure.

At this time, the both ends of the hose 10, the connecting pipe 12 for supporting the hose 10 is fitted in the axial direction corresponding to the fitting, this connecting pipe 12 is made of a strong corrosion resistance alloy consist of.

In addition, a spiral tuner 20 having a spiral band 21 formed along the outer circumference in the axial direction is inserted into and connected to the connection pipe 12 fitted to one side of the hose 10, wherein the spiral tuner ( 20 has a relatively smaller diameter than the first space 11 so that a predetermined gap is formed when inserted into the first space 11 formed in the hose 10.

In addition, the tuner 20, like the hose 10, the second space portion 22 is formed along the axial direction.

The second space portion 22 is formed along the axial direction to the other end of the connecting pipe 12 coupled to one side of the hose 10 and the tuner 20 coupled to the connecting pipe 12. .

At this time, the tuner 20 is coupled to the spiral tuner cap 30 along the axial direction of the other end.

Wherein the cap 30 is divided into three parts, the cylindrical connecting portion 31 is connected in a shape corresponding to the other end of the spiral tuner 20, and the predetermined interval in the other axis direction of the connecting portion 31 It consists of an annular reflection plate 32 which is placed and positioned, and four support parts 33 positioned and supported between the reflection plate 32 and the connecting portion 31.

In addition, the connection part 31 is connected to the other end of the tuner 20, and at this time, a third space part connected to the second space part 22 so that fluid flows along the axial direction of the connection part 31 ( 31a) is formed.

The third space portion 31a serves as an inlet to allow fluid having a pulsating pressure to flow into the second space portion 22, and the third space portion 31a is a second space in an embodiment. It may be the same as the inner diameter of the part 22 but may be larger or smaller than the inner diameter of the second space part 22.

In addition, the reflecting plate 32 is located at a predetermined distance from the connecting portion 31, the interval is achieved by the support portion 33 for coupling the connecting portion 31 and the reflecting plate 32 to each other.

The outer diameter of the reflecting plate 32 is preferably 0.7 times to 0.95 times the inner diameter of the first space portion 11, and the inner diameter is preferably 0.7 times to 1.5 times the second space portion 22.

In addition, the support 33 has a rectangular bar shape, one side is coupled to the other end portion of the connecting portion and the other side is coupled to one side portion of the reflecting plate 32 so that the connecting portion 31 and the reflecting plate 32. To support and connect with each other.

Therefore, the distance between the reflecting plate 32 and the connecting portion 31 is achieved by the support 33, the length of the support 33 is preferably 2mm to 12mm.

The reflecting plate 32 will be described in detail below, but has an annular space formed between the spiral tuner 20 and the lake 10 and a second echo reciprocating through one side section of the reflecting plate 32. It serves to reflect the wave.

Hereinafter, the pulsation reduction effect will be described.

Figure 6 is a simplified diagram of a high-pressure hose for pulsation reduction in accordance with the present invention.

Prior to the description, the pressure generated by inducing the generation of echo waves and penetrating the echo waves and the tuner by forming an annular chamber between the spiral tuner and the hose based on the branch pipe theory described in the prior art, based on the branch pipe theory. It has been described that the pulsation pressure is reduced by using the interference / offset of the wave due to the phase difference of the wave.

As shown in FIG. 6, it is assumed that the length of the spiral tuner 30 inserted into the hose 10 and the other end of the connecting portion 31 of the spiral tuner cap 30 is L1, and the support 33 It is assumed that the distance from one side of the reflecting plate 32 to one end of the connection pipe 12 fitted to the other side of the hose 10 after subtracting L2 (wavelength interference interval length).

At this time, an annular space (Chamber) is formed between the spiral tuner 20 and the hose 10.

It is assumed that the pulsating pressure reciprocating the annular space portion is the first echo wave.

In addition, it is assumed that the pulsating pressure reciprocating between the annular space portion and one side section of the reflecting plate is the second echo wave.

The pulsating pressure passing through the spiral tuner is assumed to be a pressure wave.

If the assumption is made as described above, by reflecting the second reflection wave from the reflecting plate 32 located at a short distance from the end of the spiral tuner 20, the phase difference between the first reflection wave and the second reflection wave is reduced, so the spiral tuner The pulsation reduction performance of (20) can be improved at the pulsation reduction target frequency.

By reflecting the second echo wave from the reflector 32, the phase difference between the first echo wave and the pulsation pressure is reduced, so that the pulsation reduction performance at the target pulsation reduction target frequency of the spiral tuner 20 can be improved.

In addition, by arbitrarily adjusting the support portion 33 connecting the reflecting plate 32 and the connecting portion 31, L2 (wavelength interference section length) can be determined within a certain range irrespective of the length of the hose 10, and also the The camouflage difference with respect to the pressure wave of the two echoes can be adjusted.

By maximizing the length of L2 (wavelength interference section length) within a certain range, the range of the pulsation reduction target frequency can be extended.

By connecting the reflector plate 32 to the existing first edge spiral structure with the support 33, the effects of the double edge spiral structure described in the related art can be provided.

As described above, in addition to the annular reflection plate 32 that can improve the pulsation reduction performance in the ring type spiral cap 100 in the high-pressure hose for pulsation reduction, a spiral type and a cone type may also be included. have.

In addition, the length of the support part 33 supporting the reflector plate 32 and the connection part 31 may be arbitrarily changed according to the length of the hose 10, the length of the L2 (wavelength interference section), and the length of the spiral tuner 20. have.

As described above, according to the ring type spiral cap in the pulsation reducing high pressure hose according to the present invention, the length of the wavelength interference interval which has been overlooked during the design of the pulsation reducing high pressure hose using the spiral tuner may be defined. By properly selecting the support, the pulsation reduction performance of the high pressure hose for pulsation reduction using a spiral tuner can be improved.

In addition, by appropriately setting the length of the wavelength interference interval, it is possible to improve the pulsation reduction performance of the high-pressure hose for pulsation reduction and to improve the noise reduction performance.

In addition, it has the same effect as optimizing the length of the wavelength interference interval through the addition of the middle nipple (Nipple) of the high-pressure hose for pulsation reduction using a spiral tuner has the effect of reducing the cost by replacing the nipple.

In addition, in automotive power steering, the interior noise of a vehicle can be significantly reduced by optimizing the length of the wavelength interference section.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, various other modifications and variations may be made without departing from the spirit and scope of the invention. Accordingly, it is intended that the appended claims cover such modifications and variations as fall within the true scope of the invention.

Claims (7)

A hose 10 having a first space 11 having a predetermined diameter along an axial direction; A connection pipe 12 coupled to one end and the other end of the hose 10; One side is axially coupled to any one of the connecting pipe 12 is selected and the other side has a relatively smaller diameter than the first space 11 to be located in the first space 11 of the hose (10) Spiral tuner 20 having a strip steel spirally along the outer circumference; And Ring type spiral cap in the high-pressure hose for pulsation reduction, characterized in that it comprises a spiral tuner cap 30 is axially coupled to the other side of the spiral tuner (20). The method of claim 1, The spiral tuner 20 is a ring type spiral cap in the high-pressure hose for pulsation reduction, characterized in that the second space portion 22 having a predetermined inner diameter is further formed along the axial direction. The method of claim 1, The cap 30 is connected to the other end of the spiral tuner 20 in the shape corresponding to the connection portion 31, A reflection plate 32 positioned at a predetermined interval along the axial direction toward the other side of the connecting portion 31; Located between the reflecting plate 32 and the connecting portion 31, one side is connected to the other end of the connecting portion 31 and the other side comprises a support portion 33 is connected to one side of the reflecting plate 32 A ring type spiral cap in a high pressure hose for reducing pulsation. The method of claim 3, The connection portion 31 is a ring type spiral cap in the high-pressure hose for pulsation reduction, characterized in that further comprises a third space portion 31a which is connected to the second space portion in the spiral tuner (20). The method of claim 3, The inner diameter of the reflection plate 32 is a ring type spiral cap in the high-pressure hose for pulsation reduction, characterized in that 0.7 to 1.5 times the inner diameter of the second space portion (22). The method of claim 3, The outer diameter of the reflector 32 is a ring type spiral cap in the high-pressure hose for reducing pulsation, characterized in that 0.7 to 0.95 times the inner diameter of the first space (11). The method of claim 3, Ring type spiral cap in the high-pressure hose for pulsation reduction, characterized in that the length of the support 33 is 2mm ~ 12mm.