DE112020006484T5 - DEVICE FOR REDUCING PIPE NOISE - Google Patents

Abstract

The present disclosure relates to a pipe noise reducing device, wherein a draining member is fixed to a reducing member that becomes thinner in a direction of expansion to thereby concentrate and drain vibration generated by a pipe.

Description

[Technical Field]

The present disclosure relates to a pipe noise reduction device, and more particularly to a device for reducing vibration and noise generated by coolant flowing through a pipe.

[State of the art]

An air conditioner is a device that transfers thermal energy between an indoor unit and an outdoor unit to make an air-conditioning space comfortable. As a medium for transmitting the thermal energy, a refrigerant is used, which is compressed, condensed, expanded, and vaporized while circulating between the indoor unit and the outdoor unit to form a cycle. In this regard, a compressor is used as a component for pressing and compressing the refrigerant, and vibration and noise are induced when the compressor is driven. Therefore, the compressor is generally installed in the outdoor unit.

Inside the compressor there is a rotating body rotating at a predetermined frequency, which causes the vibration and noise. In particular, when the refrigerant flows through a pipe inserted into the compressor before being pressed, the vibration and the noise may increase.

Also, as the pipe through which the refrigerant flows, a copper pipe is generally used, so that the vibration and noise generated by the refrigerant are inevitably transmitted to the pipe itself. Therefore, even if the compressor is generally installed in the outdoor unit, it is necessary to reduce the vibration and noise generated from the pipe.

Regarding 1 a first conventional device 10 will be described. The first conventional device 10 is formed into a ring shape to reduce the vibration and noise generated by the tube.

Specifically, the first conventional device 10 is annular and includes an inner peripheral surface 11 and an outer peripheral surface 15, and further includes a cushioning portion 13 for connecting the inner peripheral surface 11 and the outer peripheral surface 15 to each other to provide a predetermined thickness. In addition, one side of the first conventional device 10 is opened to define an opening 17 which is coupled to the tube.

Therefore, depending on a volume of the cushioning portion 13 formed between the inner peripheral surface 11 and the outer peripheral surface 15, the vibration and noise generated from the pipe could be reduced.

However, there is a case where the cushioning portion 13 extending from the inner peripheral surface 11 to the outer peripheral surface 15 cannot be enlarged sufficiently. In a case of a suction pipe 3 connecting a compressor 5 to an accumulator 1, bent portions 3a and 3b are formed, so that a position where the first conventional device 10 is installed on the suction pipe 3 is inevitably limited.

For example, the first conventional device 10 cannot be installed adjacent to the bent portions 3a and 3b. This is because the cushioning portion 13 and the bent portions 3a and 3b may come into contact with each other.

In addition, when a degree of expansion of the damping portion 13 extending from the inner peripheral surface 11 to the outer peripheral surface 15 is reduced to install the first conventional device 10 adjacent to the bent portions 3a and 3b, the vibration and noise, generated from the suction pipe 3 cannot be reduced sufficiently. As described above, this is because a degree to which the first conventional device 10 reduces the vibration and noise generated from the pipe is proportional to the volume of the cushioning portion 13 .

According to Korean Patent Application Publication KR20130056743A Furthermore, a pipe noise reduction device (hereinafter abbreviated as a second conventional device) is formed in an annular shape so as to surround the pipe. The second conventional device includes a first damper and fixes the pipe and the pipe noise reduction device of the publication. In addition, a second damper coupled to an outer peripheral surface of the first conventional device in a direction away from an inner peripheral surface is included to dissipate the vibration transmitted through the first damper.

The second conventional device does not reduce the noise and vibration of the pipe in proportion to a volume of the second conventional device, but several second dampers should be included to reduce the vibration and noise generated by the tube.

Therefore, a shape of the device inevitably becomes complicated and its manufacture becomes difficult. Also, in the case of the pipe having the bent portions 3a and 3b described above, since the device is formed in the annular shape and installed so as to surround the pipe, the installation may be limited.

Consequently, a pipe noise reduction device with a new shape is required.

[Epiphany]

[Technical problem]

An embodiment of the present disclosure is to provide a pipe noise reduction device that efficiently reduces a high-frequency noise equal to or higher than 1 kHz generated from a pipe.

An embodiment of the present disclosure is to provide a pipe noise reduction device that can be installed regardless of a shape of a pipe.

An embodiment of the present disclosure is to provide a pipe noise reduction device that concentrates and diverts vibration and noise generated from a pipe.

An embodiment of the present disclosure is to provide a pipe noise reduction device that eliminates vibration and noise generated from a pipe by collision.

[Technical Solutions]

An embodiment of the present disclosure can use a dynamic absorber principle and a shock absorber principle to achieve the above objects.

An embodiment of the present disclosure can provide a pipe noise reduction device having an ABH shape to achieve the above objects. The vibration and noise generated from the pipe can be concentrated at one end of the pipe noise reduction device by the ABH shape.

In order to achieve the above purpose, an embodiment of the present disclosure may provide an apparatus for reducing noise of a pipe including a bracket coupled to the pipe, a guide assembly extending along a longitudinal direction of the pipe from the bracket and from the pipe is spaced to transmit the vibration of the tube, a reducing portion extending along the longitudinal direction of the tube from the guide assembly, and a drain member fixed to the reducing portion to compensate for the vibration of the tube, the reducing portion decreases in thickness along the extending direction of the reduction portion.

The reducing portion may include a first surface consisting of a flat surface and a second surface spaced from the first surface to form the thickness with the first surface and consisting of a curved surface.

One of the first surface and the second surface may be located in a position facing the tube.

The drain member can be coupled to the first surface and can be spaced from the tube.

The reduction portion may increase in width along the extending direction of the reduction portion.

The guide arrangement may include a first guide extending along a first direction from the support and a second guide extending along a second direction opposite to the first direction from the support, and the first guide and the second guide may be separated from each other be spaced to define a space therebetween for a coupling member for fixing the bracket to the pipe to be coupled to the bracket.

In order to achieve the above purpose, an embodiment of the present disclosure may provide an apparatus for reducing noise of a pipe having a bracket coupled to the pipe, a guide assembly extending from the bracket in a direction perpendicular to a longitudinal direction of the pipe to transmit a vibration of the tube, a reducing portion extending in the direction perpendicular to the longitudinal direction of the tube from the guide assembly, and a derivative member fixed to the reducing portion to compensate for the vibration of the tube, wherein the Reducing portion decreases in thickness along the extending direction of the reducing portion.

The bracket may include a coupling portion recessed toward the tube from the bracket so that a coupling member for fixing the bracket to the tube can be coupled to the bracket.

A degree of decrease in thickness of the reduction portion can be reduced along the extending direction of the reduction portion.

The discharge element can be made of rubber.

The guide assembly may include a third guide extending along a third direction from the support and a fourth guide extending along a fourth direction opposite to the third direction from the support, and the reduction portion may include a third reduction portion extending along extending in the third direction from the third guide, and a fourth reduction portion extending along the fourth direction from the fourth guide.

The dissipating member may include a housing fixed to the reducing portion and defining an accommodating space therein, and a plurality of collision members disposed in the accommodating space to dissipate the vibration from the pipe.

The housing may include a first housing fixed to the third reduction portion and a second housing fixed to the fourth reduction portion, and the drain member may further include a connection portion for connecting the first housing and the second housing to each other and to the pipe is coupled include.

The connection portion may be arranged between the bracket and the pipe.

[Beneficial Effects]

According to an embodiment of the present disclosure, even when the tube is bent, the device can be coupled to the tube to dissipate the vibration and noise generated by the tube.

According to an embodiment of the present disclosure, the vibration and noise generated by the pipe can be concentrated and dissipated.

According to an embodiment of the present disclosure, the vibration and the noise generated from the pipe can be dissipated by the impact.

character list

• 1 Fig. 12 is a view showing a first conventional device.
• 2 is a conceptual diagram of an ABH shape.
• 3 14 is a perspective view according to an embodiment of the present disclosure.
• 4 12 is a view showing a state in which a pipe noise reduction device according to an embodiment of the present disclosure is attached to a pipe.
• 5 12 is a front view of a pipe noise reduction device according to an embodiment of the present disclosure.
• 6 14 is a perspective view of a pipe noise reduction device according to an embodiment of the present disclosure.
• 7 12 is a perspective view showing a drain member according to an embodiment of the present disclosure.

[Best Kind]

Hereinafter, a preferred embodiment of the present disclosure and conventional drawings for understanding the present disclosure, which can specifically achieve the above objects, will be described with reference to the accompanying drawings.

In this process, sizes, shapes or the like of components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms specifically defined in consideration of a configuration and an operation of the present disclosure may vary depending on a user's and an operator's intentions or habits.

In one example, terms such as For example, first and/or second may be used to describe different components, but the components are not limited to the terms. The first component can be named as the second component and likewise the second component can also be named as the first component only for the purpose of distinguishing one component from other components, for example within the scope of protection that does not differ from the scope of protection of rights based on the concept differs from the present disclosure.

Definitions of such terms should be made on the basis of content throughout this specification.

Various embodiments of the present disclosure may include an ABH Form S, and the ABH Form S may concentrate the vibration and noise generated by a pipe.

The ABH form S is about 2 defined and 2 shows a state in which a medium M is divided into a plurality of areas to represent the ABH shape S.

The medium M includes a first area 20, a second area 30 and a third area 40. An order from the first area 20 to the third area 40 may be the same as an order in which a wave propagating through the medium M proceeds .

The wave may maintain a speed thereof in the first region 20 and may decrease in speed in the second region 30 and third region 40 . This is because the speed of the wave is proportional to a square root of a thickness of the medium.

In one example, in order to reduce the speed of the wave propagating through the second area 30 and the third area 40 more efficiently, it is preferable that the second area 30 and the third area 40 have a shape based on the effect of a acoustic black hole (hereinafter abbreviated as ABH form).

According to the acoustic black hole effect, when a shape of the medium is a shape corresponding to a power function, the speed of the wave traveling through the medium can be effectively reduced. Hereinafter, the form of the power function based on the acoustic black hole effect is defined as ABH-form S.

The ABH shape S includes a shape in which the thickness of the medium decreases along a propagation direction of the wave. In addition, it is preferable that a degree in which the thickness of the medium is reduced becomes smaller along the propagation direction of the wave.

In other words, the thickness of the medium with the ABH shape S is reduced along the propagation direction of the wave, but a decreasing width can be reduced along the propagation direction of the wave.

Therefore, when moving the same distance in the second region 30 and third region 40 along the direction of propagation of the wave, a reduced thickness of the medium M in the second region 30 can be larger than a reduced thickness of the medium M in the third region 40.

In an example, each of the second area 30 and the third area 40 may include one surface consisting of a flat surface and the other surface consisting of a curved surface, and the ABH shape S may be formed on the curved surface be. That is, when cross sections of the second portion 30 and the third portion 40 are formed in a direction parallel to the propagation direction of the wave, the ABH shape S can be formed on the curved surfaces of the second portion 30 and the third portion 40 .

Eventually, as the wave propagates along the medium M and reaches an end of the third region 40, the speed of the wave may be zero. However, since this is only theoretically possible and in practice the thickness of the medium M cannot converge to zero, various embodiments of the present disclosure further comprise a fourth region 50.

The fourth region 50 may be coupled to the second region 30 where propagation of the wave is concentrated to derive the concentrated wave.

Therefore, the wave propagating through the first region 20 can maintain the velocity thereof by the constant thickness of the first region 20 as well as the direction of propagation thereof to the second region 30 can be guided. Thereafter, after the wave is concentrated by the ABH shape S formed in the second region 30, the wave concentrated by the fourth region 50 can be derived.

Hereinafter, an embodiment of the present disclosure having the ABH form will be referred to with reference to FIG 3 until 4 described.

3 FIG. 12 is a perspective view according to an embodiment of the present disclosure and FIG 4 is a view that has a state 12 shows a pipe noise reduction device coupled to a pipe according to an embodiment of the present disclosure.

An embodiment of the present disclosure may include a bracket 100 coupled to a pipe p, a guide assembly 200 receiving vibration from the pipe p and guiding the vibration, and a reducing portion 300 receiving the vibration from the guide assembly 200 and the vibration focused, encompass.

The support 100 includes a contact surface 110 in contact with the tube p and a spaced surface 120 spaced from the contact surface 110 in a direction away from the tube p.

The contact surface 110 may have a shape corresponding to that of the tube p and may be seated on the tube p. Additionally, the spaced surface 120 may be spaced from the contact surface 110 by a predetermined distance to form a thickness of the support 100 along with the contact surface 110 . As will be described later, a drain member 400 may be arranged to be spaced from the pipe p when the thickness of the bracket 100 is formed.

The guide assembly 200 includes a first guide 210 and a second guide 220 extending from the bracket 100 along a longitudinal direction of the pipe p.

It is preferable that the first guide 210 and the second guide 220 extend from the support 100 in opposite directions. Assuming that the first guide 210 extends in a first direction D1 along the longitudinal direction of the pipe p, the second guide 220 may extend in a second direction D2 opposite to the first direction D1 along the longitudinal direction of the pipe p.

That is, the first direction D1 and the second direction D2 may refer to directions that are on a straight line but away from each other.

In addition, the guide assembly 200 is preferably extended along the longitudinal direction of the tube p and spaced from the tube p. Consequently, the guide assembly 200 can extend along the longitudinal direction of the tube p at the spaced surface 120 .

In addition, the guide assembly 200 is preferably extended along the longitudinal direction of the pipe p while maintaining a predetermined thickness. That is, it is preferable that the guide assembly 200 extends along the first direction D1 and the second direction D2, but the thickness thereof does not changes.

This is because the guide assembly 200 needs to receive the vibrations generated from the pipe p in various directions from the bracket 100 and transmit the vibration to the reduction portion 300 . This is because when the thickness of the guide assembly 200 is changed along the extending direction of the pipe p, the vibration generated from the pipe p cannot be transmitted to the reduction portion 300 efficiently.

The reduction portion 300 includes a first reduction portion 310 and a second reduction portion 320 extending from the guide assembly 200 along the longitudinal direction of the pipe p.

The first reduction portion 310 may extend from the first guide 210 along the longitudinal direction of the pipe p. Also, the first reduction portion 310 may extend from the first guide 210 along the first direction D1.

The second reduction portion 320 may extend from the second guide 220 along the second direction D2.

However, it is preferable that a thickness t of the reducing portion 300 is gradually reduced along the extended direction. Accordingly, the thickness t of the first reduction portion 310 may decrease when the first reduction portion 310 extends from the first guide 210 along the first direction D1. Also, the thickness t of the second reduction portion 320 may decrease when the second reduction portion 320 extends from the second guide 220 along the second direction D2.

In an example, the first reduction portion 310 may include a first surface 311 consisting of a flat surface and a second surface 313 consisting of a curved surface.

The first surface 311 and the second surface 313 may be spaced apart to form the thickness t. That is, the thickness t of the reduction portion 300 can be defined as a distance between the first surface 311 and the second surface 313 .

In an example, the first surface 321 consisting of the flat surface, and the second surface 323 consisting of the curved surface may also be formed in the second reduction portion 320.

The ABH shape S may be formed on the second surfaces 313 and 323 . Consequently, in the second surfaces 313 and 323, the thickness t can decrease along the extending direction of the reducing portion 300 as well as a degree of decrease of the thickness t along the extending direction of the reducing portion 300 can be gradually reduced.

That is, a cross section in the extended direction of the reduction portion 300 may include the ABH-S shape.

Therefore, the vibration generated from the pipe p can be transmitted to the bracket 100, and the vibration transmitted to the bracket 100 can be guided to the reduction portion 300 through the guide assembly 200. FIG. In addition, a speed of the vibration of the pipe p moving through the reducing section 300 can be reduced by the ABH shape S formed in the reducing section 300 . Therefore, the vibration generated from the pipe p can be concentrated in the reduction portion 300. FIG.

In order to dissipate the vibration concentrated in the reducing portion 300, the dissipating member 400 may be coupled to the reducing portion 300. FIG. In addition, as described above, since the support 100 forms the thickness by including the contact surface 110 and the spaced surface 120 , the drain member 400 can be spaced from the pipe p and can be coupled with the reduction portion 300 .

The dissipation member 400 may include a first dissipation member 410, and the first dissipation member 410 may be fixed to the reducing portion 300 to dissipate the concentrated vibration. The first dissipation member 410 has bubbles or tubular holes defined in a surface and an interior thereof like a porous sound absorbing material, so that the first dissipation member 410 can convert sound energy into thermal energy and absorb the thermal energy. In addition, the first dissipation member 410 can dissipate the concentrated vibration by vibrating a plate such as a plate-shaped sound absorbing material. In addition, the first derivative element 410 can be made of rubber.

The first dissipation element 410 may be coupled to at least one of the first surfaces 311 and 321 and the second surfaces 321 and 323, but the first dissipation element 410 is preferably formed on the first surfaces 311 and 321.

This is because the ABH shape S is formed on the second surfaces 321 and 323 as described above, and the ABH shape S concentrates the vibration transmitted from the pipe p. Therefore, when the first dissipation member 410 is coupled to the second surfaces 321 and 323, the vibration generated from the pipe p can be less concentrated.

In one example, the first guide 210 and the second guide 220 may be extended to be spaced apart from each other. The first guide 210 may extend from one side of the pillar 100 along the first direction D1 and the second guide 220 may extend from the other side of the pillar 100 along the second direction D2. Thus, in a space between the first guide 210 and the second guide 220, a coupling portion C in which a coupling member for coupling the bracket 100 to the pipe p is coupled to the bracket 100 can be defined.

Thus, the coupling portion C may be defined by the first guide 210, the second guide 220, and the spaced surface 120. FIG.

In one example, the coupling element may be in the form of a cord made of nylon. Consequently, the spaced surface 120 can have a shape corresponding to that of the pipe p in the same way as the contact surface 110 .

In one example, multiple devices for reducing noise from pipe p may be coupled to pipe p according to an embodiment of the present disclosure.

According to an embodiment of the present disclosure described above, the devices may be coupled to the pipe p by the guide assembly 200 extending along the longitudinal direction of the pipe p regardless of the shape of the pipe p. Even if the tube p is formed to be bent, as long as the support 100 is coupled to the tube p, since the guide assembly 200 extends from the support 100 but is spaced from the tube p, there may be less restriction. which is caused by the shape of the pipe p.

In addition, since the vibration generated from the pipe p is concentrated and dissipated, the noise generated from the pipe p can be reduced more efficiently.

(a) in 5 12 is a view showing a state where positions of the first surface 311 and the second surface 313 are changed according to an embodiment of the present disclosure, and (b) in FIG 5 12 is a view showing a state in which a width w of the first reduction portion 310 is widened according to an embodiment of the present disclosure.

With reference to (a) in 5 For example, the first surface 311 may extend along the extending direction of the pipe p from one side of the guide assembly 200 to face the pipe p. Consequently, the first derivative element 410 coupled to the first surface 311 may be coupled to the first surface 311 in a position facing the pipe p.

In addition, the second surface 313 may extend along the extending direction of the pipe p from the other side of the guide assembly 200 to face the pipe p.

With reference to (b) in 5 For example, the first necking portion 310 may have a larger width w along the extended direction of the first necking portion 310 . Consequently, areas of the first surface 311 and the second surface 321 can increase as the width w of the reduction portion 300 increases along the extended direction of the reduction portion 300 .

That is, the thickness t of the first reduction portion 310 may mean a distance between the first surface 311 and the second surface 313, and the width of the first reduction portion 310 may be related to the areas of the first surface 311 and the second surface 313. Consequently, the thickness t of the first reduction portion 310 can be independent of the areas of the first surface 311 and the second surface 313 .

Consequently, an area of the first derivative element 410 coupled to the first surface 311 can be increased. In addition, a volume of the first derivative element 410 coupled to the first surface 311 can be increased. Therefore, when the first reducing portion 310 has a larger width along the extending direction of the first reducing portion 310, the vibration generated from the pipe p can be dissipated more efficiently.

In one example, the was about 5 Although the above description related to the first guide 210 and the first reduction portion 310, it can equally be applied to the second guide 220 and the second reduction portion 320. That is, the width w of the second reduction portion 320 may increase along the second direction D2.

6 12 is a view showing a perspective view of the device for reducing noise from pipe p according to an embodiment of the present disclosure.

Regarding 6 and excluding the redundant description, the guide assembly 200 of the device for reducing the noise from pipe p according to an embodiment of the present disclosure includes a third guide 230 extending in a third direction D3 and a fourth guide 240 extending in a fourth direction D4 extends from the support 100.

The third direction D3 and the fourth direction D4 may be defined as directions perpendicular to the longitudinal direction of the pipe p. Specifically, the third guide 230 and the fourth guide 240 extending along the third direction D3 and the fourth direction D4, respectively, may form the same flat surface as the spaced surface 120. That is, a surface of the third guide 230 and a surface of the fourth guide 240 extending along the third direction D3 and the fourth direction D4 from the spaced surface 120, respectively, may form the same flat surface.

The reducing portion 300 may include a third reducing portion 330 extending from the third guide 230 in the third direction D3 and a fourth reducing portion 340 extending from the fourth guide 240 in the fourth direction D4.

The third reduction portion 330 may include a first surface 331 consisting of a flat surface and a second surface 333 consisting of a curved surface, and the fourth reduction portion 340 may also have a first surface 341 and a second surface 343 in the same manner include. In addition, the ABH shape S may be formed on the second surfaces 333 and 343 .

Thus, the first dissipation member 410 may be fixed to the first surface 331 of the third reduction portion 330 to dissipate the vibration concentrated in the third reduction portion 330 .

In addition, the first derivative element 410 can be attached to the first surface 341 of the fourth verrin reduction section 340 to dissipate the vibration concentrated in the fourth reduction section 340.

In one example, the bracket 100 may have a space in which the coupling portion C is defined by extending in the first direction D1 and the second direction D2.

Consequently, the contact surface 110 may also extend in the first direction D1 and the second direction D2 to increase an area coupled to the pipe p. In addition, the spaced surface 120 may also be extended in the first direction D1 and the second direction D2 to correspond to the contact surface 110 to form the thickness of the contact surface 110 .

When the bracket 100 extends in the first direction D1 and the second direction D2, a plurality of coupling portions C may be defined in the bracket 100. FIG. That is, the bracket 100 may include the coupling portion C recessed from the spaced surface 120 extending in the first direction D1 to the contact surface 110 extending in the first direction D1. In addition, the support 100 may include the coupling portion C recessed from the spaced surface 120 extending in the second direction D2 to the contact surface 110 extending in the second direction D2.

As described above, when the third reduction portion 330 and the fourth reduction portion 340 extend along the third direction D3 and the fourth direction D4, respectively, the plural coupling portions C may be defined in the bracket 100 arranged in the first direction D1 and the second direction D2 is extended.

When the multiple coupling portions C are defined, the bracket 100 can be coupled to the pipe p via multiple coupling members, so that the coupling between the bracket 100 and the pipe p can become more robust.

In this case, a contact area between the bracket 100 and the pipe p is widened, and in the end, a volume of the medium in which the vibration generated from the pipe p flows increases, so that the bracket 100 absorbs the vibration from the pipe p can receive better.

Finally, since a degree of concentration of the vibration from the pipe p in the third reduction portion 330 and the fourth reduction portion 340 is increased, the vibration generated from the pipe p can be dissipated more efficiently.

This is because, considering that a frequency of the noise generated from the pipe p is a high frequency in a range from 1 kHz to 4 kHz, a strengthening of the coupling between the pipe p and the bracket 100 and a Broadening of the contact area between the pipe p and the bracket 100 can act as an important factor in the degree to which the vibration is concentrated in the reduction section 300.

7 12 is a view showing a second derivative element according to an embodiment of the present disclosure.

Regarding 7 and excluding the redundant description, the second dissipation member 420 can dissipate the concentrated vibration by absorbing a shock.

For this purpose, the second derivation element 420 can comprise a housing 421 and a collision element 423 .

The housing 421 may be hollow to define an accommodation space. Consequently, the collision member 423 can be arranged in the accommodation space inside the case 421 to absorb the vibration.

Multiple collision elements 423 may be positioned within housing 421 and may be arranged to have a predetermined space within housing 421 . Accordingly, when the vibration is transmitted to the case 421, the plurality of collision members 423 within the case 421 can receive the vibration and collide with each other to dissipate the received vibration.

The collision member 423 may be a sphere having a spherical shape, and may be made of iron or plastic. However, the present disclosure may not be limited thereto as long as the collision members 423 are made of a material and have a shape for canceling vibration energy by collision therebetween.

In one example, the second derivative element 420 is preferably coupled to the pipe noise reduction device according to an embodiment of the present disclosure in a symmetrical manner since it has a predetermined volume and mass.

For this purpose, the housing 421 can comprise a first housing 421a and a second housing 421b.

The first housing 421a may be coupled to the third guide 230 and the third reduction portion 330 . In particular, the first housing 421a may be coupled to the first surface 331 forming the flat surface of the third reduction portion 330 to be coupled more firmly.

In addition, the second housing 421b may be coupled to the fourth guide 240 and the first surface 341 of the fourth reduction portion 340 .

Accordingly, the case 421 may have a flat surface on one surface thereof to be firmly coupled to the guide assembly 200 and the reduction portion 300 .

In addition, the first housing 421a and the second housing 421b are preferably connected to each other. This is because when the vibration is transmitted to the case 421 , the vibration can be transmitted between the first case 421 a and the second case 421 b and can be dissipated by the collision member 423 .

Accordingly, the second derivative member 420 may include a connecting portion 425 for connecting the first housing 421a and the second housing 421b to each other.

The connecting portion 425 may have a surface where the first housing 421a contacts the third guide 230 and the third reduction portion 330 and a surface where the second housing 421b contacts the fourth guide 240 and the fourth reduction portion 340 , connect to each other.

In addition, the connecting portion 425 may extend in the first direction D1 and the second direction D2 to conform to the shape of the contact surface 110 .

Thus, the second derivative member 420 can be coupled to the pipe p and the support 100 can be coupled to the second derivative member 420 . That is, the second dissipation member 420 may be interposed between the bracket 100 and the pipe p to dissipate the vibration transmitted from the pipe p.

When the second dissipating member 420 described above is coupled to the pipe p, the vibration having a specific frequency can be dissipated more efficiently. This is because a distance between the collision elements 423 in the case of shock absorption is related to the frequency of the vibration to be discharged.

In addition, the second derivative member 420 contacts the reduction portion 300 as well as the support 100 and the guide assembly 200 to form a wider contact surface. Therefore, the vibration can be dissipated from the pipe p more efficiently since the vibration can be received and dissipated from a wider contact area.

The present disclosure is not limited to the embodiment described above and, as can be identified from the appended claims, modifications are possible by those skilled in the art to which the present disclosure pertains, and such modifications are considered within the scope of the present disclosure considered.

QUOTES INCLUDED IN DESCRIPTION

This list of the documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• KR 20130056743 A [0011]

Claims (15)

A device for reducing the noise of a pipe, the device comprising: a support coupled to the tube; a guide assembly extending along a longitudinal direction of the tube from the support and spaced from the tube to transmit vibration of the tube; a reduction portion extending along the longitudinal direction of the tube from the guide assembly; and a dissipation member attached to the reduction portion to compensate for the vibration of the tube, wherein the reduction portion decreases in thickness along the extending direction of the reduction portion. device after claim 1 wherein the reducing portion comprises: a first surface consisting of a flat surface; and a second surface spaced from the first surface to form the thickness with the first surface and composed of a curved surface. device after claim 2 wherein the first surface is located in a position facing the tube. device after claim 2 wherein the second surface is located in a position facing the tube. Device according to one of claims 3 until 4 wherein the drain member is coupled to the first surface and is spaced from the tube device after claim 1 , wherein the reduction portion increases in width along the extending direction of the reduction portion. device after claim 1 wherein the guide assembly comprises: a first guide extending along a first direction from the support; and a second guide extending from the bracket along a second direction opposite to the first direction, the first guide and the second guide being spaced from each other to define a space therebetween for a coupling member for fixing the bracket to the pipe such that it is coupled to the support. A device for reducing the noise of a pipe, the device comprising: a support coupled to the tube; a guide assembly extending from the bracket in a direction perpendicular to a longitudinal direction of the pipe to transmit vibration of the pipe, a reduction portion extending from the guide assembly in the direction perpendicular to the longitudinal direction of the pipe; and a dissipation member attached to the reduction portion to compensate for the vibration of the tube, wherein the reduction portion decreases in thickness along the extending direction of the reduction portion. device after claim 8 wherein the bracket includes a coupling portion recessed toward the tube from the bracket so that a coupling member for fixing the bracket to the tube can be coupled to the bracket. device after claim 8 , wherein a degree of decrease in thickness of the reduction portion is reduced along the extending direction of the reduction portion. device after claim 8 , whereby the discharge element consists of rubber. device after claim 8 wherein the guide assembly comprises: a third guide extending along a third direction from the support; and a fourth guide extending along a fourth direction opposite to the third direction from the support, wherein the reduction portion includes: a third reduction portion extending along the third direction from the third guide; and a fourth reduction portion extending along the fourth direction from the fourth guide. device after claim 12 wherein the drain member comprises: a housing fixed to the reduction portion and defining an accommodation space therein; and a plurality of collision members arranged in the receiving space to derive the vibration from the pipe. device after Claim 13 wherein the housing comprises: a first housing fixed to the third reduction portion; and a second housing fixed to the fourth reduction portion, wherein the drain member further comprises a connecting portion for connecting the first housing and the second housing to each other and coupled to the pipe. device after Claim 14 , wherein the connecting portion is arranged between the bracket and the tube.

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