DE202016104624U1 - Resonator for a vehicle - Google Patents

Abstract

A resonator for a vehicle that reduces the air movement noise, the resonator comprising: - an outer tube that forms the appearance of the resonator; An inner tube partially inserted into the outer tube and having a plurality of slots formed therein serving as an air movement channel; A barrier projecting from an outer surface of the inner tube to the outer tube and contacting an inner surface of the outer tube; and a plurality of resonance chambers configured to respectively communicate with the plurality of slots and divided by the barrier to form a plurality of suction noise reduction regions, wherein a horizontal portion extending in the same direction as the extending direction of the inner tube, and a stepped portion that is curved from the horizontal portion to the resonance chambers, alternately formed on the inner surface of the outer tube, so that the plurality of resonance chambers is formed with different widths.

Description

Technical area

This invention relates to a resonator for a vehicle having a plurality of resonance chambers for reducing the air movement noise, and more particularly to a resonator for a vehicle which seals the resonance chambers more effectively, so that the resonator provides a more efficient noise reduction performance.

State of the art

In summary, a vehicle intake system includes an air cleaner, a turbocharger, an intercooler, an air duct, and an engine manifold, and the outside air flowing through the intake system into an engine undergoes cycles of expansion and contraction to produce the intake pulsation. This intake pulsation generates a noise due to the change of the air pressure and, in particular, generates a greater noise due to the resonance of the air on the vehicle body or in the interior of the vehicle.

In order to suppress this suction noise, a resonator for tuning the intake system noise to a specific frequency is arranged at a rear end of the turbocharger or at a suction hose at the rear end of the turbocharger.

In summary, a known resonator has an outer tube that forms the appearance and an inner tube that is inserted into the outer tube, and a resonance chamber is formed between the outer tube and the inner tube to absorb the intake noise by adjusting the air frequency to reduce. In addition, an inlet serving as an air introduction passage and an outlet serving as an air outlet passage are formed on both sides of the inner tube. Therefore, the air flowing through the inlet into the inner tube is partially moved to the resonance chamber, and the air moved to the resonance chamber undergoes a frequency adjustment for reducing the intake noise depending on the resonance.

However, in the known resonator, the number of resonance chambers is limited, and therefore, the work of tuning the frequency for the outside air can not be done over a wide bandwidth.

To solve this problem, the unexamined Korean Patent Publication 2012-0037150 a muffler for a vehicle having a barrier that extends in the vertical direction from an outer surface of an inner tube so that the resonance chamber is divided into a plurality of regions. The muffler is made by inserting the inner tube with the barrier into an outer tube and then mounting both.

However, in the assembly of the known muffler, one end of the barrier moves into contact with the inner surface of the outer tube and thereby causes abrasion in the contact region, and thus the resonance chambers may not be effectively sealed. In addition, when the muffler is used in practice, some parts of the muffler may break by contact or impact of one end of the barrier and an inner surface of the outer tube.

Further, due to an assembly tolerance in inserting the inner tube into the outer tube, a predetermined gap between the barrier of the inner tube and the inner surface of the outer tube inevitably generates, thereby greatly impairing the sealing ability of the resonance chambers.

In order to solve this mounting tolerance problem, in an existing technique, after inserting the inner tube into the outer tube, the barriers are welded to the inner surface of the outer tube to mount a muffler. Nevertheless, although this method is common, abrasion damage inevitably arises while the barriers are welded to the inner surface of the outer tube because the muffler is made of plastic, and therefore, it is difficult to ensure the sealing ability of the resonance chambers.

RELATED LITERATURE

patent literature

• (Patent Literature 1) Unexamined Korean Patent Publication 2012-0037150 (published April 19, 2012).

epiphany

Technical problem

The object of this invention is to overcome the limitations and problem of the existing art, and the present invention is directed to providing a resonator for a vehicle capable of improving the sealing performance of a plurality of resonance chambers existing between an outer pipe and an inner tube are formed.

Technical solution

In a general aspect, this invention provides a resonator for a vehicle that reduces airmoving noise, the resonator comprising: an outer tube that forms the appearance of the resonator; an inner tube partially inserted into the outer tube and having a plurality of slots formed therein serving as an air movement passage; a barrier protruding from an outer surface of the inner tube to the outer tube and contacting an inner surface of the outer tube; and a plurality of resonance chambers configured to communicate respectively with the plurality of slits and divided by the barrier to form a plurality of suction noise reduction regions, a horizontal portion extending in the same direction like the extending direction of the inner tube, and a stepped portion curved from the horizontal portion to the resonance chambers are formed alternately on the inner surface of the outer tube so that the plurality of resonance chambers having different widths are formed.

In a further aspect, the invention provides a resonator for a vehicle that reduces the noise of the air moving from an inlet formed at one of its sides to an outlet formed at the other side thereof, the resonator comprising: an outer one Tube that forms the appearance of the resonator; an inner tube partially inserted into the outer tube and having a plurality of slots formed therein serving as an air movement passage; a barrier protruding from an outer surface of the inner tube to the outer tube and contacting an inner surface of the outer tube; and a plurality of resonant chambers configured to communicate with the plurality of slots, respectively, and shared by the barrier to form a plurality of regions for reducing intake noise, the barrier being a blocking member extending from the outer surface of the inner tube protrudes toward the outer tube, and has an extended portion integrally formed with the blocking member and having one end contacting the inner surface of the outer tube, and wherein the extended portion is elastically transformable.

Advantageous effects

According to the present invention, the sealing performance of the resonance chamber is improved because a plurality of stepped portions are formed on the inner surface of the outer tube and a plurality of barriers are in close contact with the plurality of stepped portions to divide the resonance chambers.

In addition, when the resonator is mounted, it is possible to prevent wear of the end of the barrier, since the inner tube in the state in which the ends of the plurality of barriers are not in contact with the inner surface of the outer tube Tube is used.

In addition, since the barrier and the stepped portion are not joined by welding, but are closely adhered to each other in an area where they overlap, so that the resonance chambers are divided when the resonator is mounted, the frequency of welding between the outside Tube and the inner tube are minimized.

In addition, since the barrier portion of the inner tube, which is in contact with the inner surface of the outer tube, is made of flexibly bendable material, the outer tube and the inner tube can be easily connected, and the assembly tolerance can be greatly reduced.

In addition, when the inner tube is mounted in the outer tube, the barrier portion of the inner tube is curved to have a predetermined bend and move along the inner surface of the outer tube in this state, and thus it is possible to prevent that components interfere with each other and thereby destroyed.

In addition, since the barrier is made relatively long as compared with a gap between the inner tube and the outer tube, the barrier can fully seal the plurality of resonance chambers divided by the barrier, thereby improving the performance in reducing the air movement noise ,

Description of the drawings

1 FIG. 12 is a diagram schematically showing an intake system for a vehicle. FIG.

2 FIG. 12 is a perspective view showing an entire resonator for a vehicle according to an embodiment of the present invention. FIG.

3 is a cross-sectional view along the line II 'of 2 ,

4 is an enlarged view showing section A of 3 shows.

5 FIG. 15 is a diagram illustrating the process of mounting a resonator for a vehicle according to an embodiment of the present invention. FIG.

6 FIG. 15 is a perspective view showing an overall configuration of a resonator for a vehicle according to another embodiment of the present invention. FIG.

7 is an enlarged view showing section B of FIG 6 shows.

8th FIG. 10 is a cross-sectional view showing an internal configuration of a resonator for a vehicle according to still another embodiment of the present invention. FIG.

9 is an enlarged view showing section C of FIG 8th shows.

10 FIG. 15 is a diagram illustrating the process of assembling a resonator for a vehicle according to still another embodiment of the present invention.

Best embodiment

Hereinafter, an embodiment of the present invention will be described with reference to the drawings. Although the present invention has been described based on the embodiment shown in the drawings, this is only an example, and the essential configuration and operation of the present invention are not limited thereto.

1 FIG. 12 is a diagram schematically showing an intake system for a vehicle. FIG.

As in 1 shown has an inlet system 1 a vehicle a turbocharger 30 installed to charge the intake air supplied to an engine. In operation, the turbocharger generates 30 an intake noise, and thus affects the turbocharger 30 Operating noise generated the vehicle ride comfort of the driver, which reduces the overall marketability of the vehicle. Therefore, a resonator 100 at the rear end of the turbocharger 30 installed as a noise suppressor to reduce this noise.

In addition, the inlet system 1 an engine 20 for energy supply, an air purifier 10 for filtering impurities in the intake air coming from the engine 20 is fed, and an intercooler 40 to cool off the turbocharger 30 charged intake air and for supplying the cooled intake air to the engine 20 on.

The resonator 100 is between the tubes 51 . 52 installed with the intercooler 40 connected to the working noise of the turbocharger 30 and is used to reduce this noise problem by reducing pulsation pressure during air intake.

The following is the configuration of the resonator 100 described in detail.

2 FIG. 15 is a perspective view showing the entire resonator for a vehicle according to an embodiment of the present invention; and FIG 3 is a cross-sectional view along the line II 'of 2 ,

As in 2 and 3 shown, the resonator 100 According to one embodiment of the present invention, an outer tube 200 which forms its appearance, and an inner tube 300 on that in the outer tube 200 is used. An outer coupling plate 201 is at one end of the outer tube 200 provided, and an inner clutch plate 301 connected to the outer clutch plate 201 can be connected, is on the inner tube 300 intended. In other words, the resonator 100 be prepared by the outer coupling plate 201 and the inner clutch plate 301 get connected.

The inner tube 300 has a body 304 with a cylindrical shape and at least one barrier 321 . 322 on, which is an outer surface of the body 304 surrounds and from the outer surface of the body 304 protrudes outwards. The barrier is from the inner clutch plate 301 spaced apart by a predetermined distance, and a first barrier 321 and a second barrier 322 are installed sequentially along an air movement direction.

slots 331 . 332 . 333 , which serve as an air movement channel, are on the body 304 educated. In addition, the slots can communicate with the resonance chamber 500 communicate to reduce the air movement noise. In particular, the slots comprise a first slot 331 that with a first resonance chamber 501 communicates a second slot 332 that with a second resonance chamber 520 communicates, and a third slot 333 that with a third resonance chamber 530 communicates, according to a direction from an air intake 70 to an air outlet 80 ,

The first resonance chamber 510 and the second resonance chamber 520 are areas that are from the first barrier 321 be shared and completely sealed, except for the first slot 331 and the second slot 332 to reduce the intake noise. In addition, the second resonance chamber 520 and the third resonance chamber 530 through the second barrier 322 divided. Also the third resonance chamber 530 is completely sealed, except for the third slot 333 to reduce the intake noise.

In other words, the first resonance chamber 510 , the second resonance chamber 520 and the third resonance chamber 530 are ranges for tuning air of different frequencies, so that both high-frequency air movement noise and low-frequency air movement noise can be suitably tuned. For an efficient execution of the noise reduction function, the resonance chambers should 500 be completely sealed, except for the slots 331 . 332 . 333 as described above. The sealing performance of the resonance chambers 500 is very different, depending on the degree of adhesion between the barriers 321 . 322 that the room in the resonance chamber 500 divide, and the inner surface of the outer tube 200 , The following is a method of sealing each of the resonance chambers 510 . 520 . 530 described when the outer tube 200 and the inner tube 300 be assembled.

4 is an enlarged view showing section A of 3 shows that shows the barriers 321 . 322 close to the inner surface of the outer tube 200 be liable.

As in 4 are a horizontal portion that is in the same direction as the extending direction of the inner tube 300 extends, and a stepped portion extending from the horizontal portion to the resonance chamber 500 curves, alternately on the inner surface of the outer tube 200 educated. In other words, the inner surface of the outer tube 200 is designed to have a stepped shape.

More specifically, according to the air movement direction, a first horizontal section 511 that attaches to the outer clutch plate 201 adjoins and a surface of the first resonance chamber 510 forms, a first stepped section 512 that extends from the first horizontal section 511 extends and between the first resonance chamber 510 and the second resonance chamber 520 is arranged, a second horizontal section 521 which is a surface of the second resonance chamber 520 forms, a second stepped section 522 extending from the second horizontal section 521 extends and between the second resonance chamber 520 and the third resonance chamber 530 is arranged, and a third horizontal section 531 , which is a surface of the third resonance chamber 530 forms on the inner surface of the outer tube 200 formed in succession.

The first stepped section 512 and the second stepped section 522 are curved to a direction perpendicular to the extending direction of the horizontal portions 511 . 521 . 531 is. If the outer tube 200 and the inner tube 300 In addition, the first stepped section is liable 512 close to the first barrier 321 , and the second tiered section 522 adheres closely to the second barrier 322 , In other words, since the first barrier 321 close to the first stepped section 512 sticks, can the first resonance chamber 510 and the second resonance chamber 520 and each resonant chamber can also maintain its sealing performance. Because the second barrier 322 close to the second stepped section 522 adheres, in a similar way, the second resonance chamber 520 and the third resonance chamber 530 can be shared, and each resonance chamber can maintain its sealing performance.

To perform the above performance, the first barrier has 321 a length between a width W of the first resonance chamber 510 and a width of the second resonance chamber 520 , Similarly, the second barrier 322 a length between the width of the second resonance chamber 520 and a width of the third resonance chamber 530 ,

In addition, a surface of the third resonance chamber 530 through a partition plate 532 of the outer tube 200 formed at one point opposite the second barrier 322 is trained. In other words, the partition plate 532 extends perpendicularly from the third horizontal section 531 so that they have a surface of the third resonance chamber 530 forms.

A hooking projection 533 who is close to a contact end 305 of the inner tube 300 is at one end of the partition plate 532 educated. In detail, the contact end extends 305 from the body 304 of the inner tube and is enlarged so that it has a larger diameter compared to the body 304 has, so it's close to the hooking projection 533 adheres to the separating plate 532 extends. In other words, if the outer tube 200 and the inner tube 300 are mounted, the contact end occurs 305 so in contact with the Einhakvorsprung 533 that it is on the hooking tab 533 presses, leaving the third resonance chamber 530 maintain their sealing performance.

As described above, since the horizontal portions and the stepped portions are alternately arranged, the inner surface of the outer tube 200 be curved in a stepped shape according to the air movement direction. Similarly, on an outer surface of the outer tube 200 outer horizontal sections and outer stepped portions are alternately arranged so as to conform to the shape of the inner surface of the outer tube 200 correspond.

Specifically, the outer surface of the outer tube 200 composed of a first outer horizontal section 513 , the first horizontal section 511 corresponds to a first outer stepped portion 514 , the first stepped section 512 corresponds to a second outer horizontal section 523 , the second horizontal section 521 corresponds to a second outer stepped portion 524 , the second stepped section 522 corresponds, and a third outer horizontal section 525 , the third horizontal section 531 equivalent. In other words, the outer surface of the outer tube 200 is curved in a stepped shape, similar to the inner surface of the outer tube 200 ,

In addition, there is a rib 205 (S. 2 ) on the outer surface of the outer tube 200 installed to the thickness of the outer tube 200 to increase. In other words, the rib 205 is used to prevent the curved outer tube in a stepped shape 200 damaged, and the rib 205 can be between the outer clutch plate 201 and the first outer horizontal section 513 and between the first outer stepped portion 514 and the second outer horizontal section 523 be installed.

The following is the process of mounting the outer tube 200 and the inner tube 300 described.

5 FIG. 13 is a diagram illustrating the process of mounting the resonator for a vehicle.

As in 5 represented, stand the outer clutch plate 201 and the inner clutch plate 301 in contact with each other when the inner tube 300 in the outer tube 200 is used, in a state where there are small gaps between the first barrier 321 and the first stepped portion 512 , between the second barrier 322 and the second stepped portion 522 as well as between the contact end 305 and the hooking projection 533 are formed. In this state, the outer clutch plate 201 and the inner clutch plate 301 connected by welding, whereby the outer tube 200 and the inner tube 300 get connected. Due to the heat generated during welding, a contact surface of the outer clutch plate becomes at this time 201 and the inner clutch plate 301 gradually melted so that its thickness is reduced. Accordingly, the first barrier sticks 321 close to the first stepped section 512 , the second barrier 322 adheres tightly to the second stepped portion 522 , and the contact end 305 of the inner tube pushes the hooking projection 533 of the outer tube in a horizontal direction.

Therefore, in the present invention, the seal line of the resonance chamber 500 be maintained when the resonator 100 is mounted while the frequency of welding between the outer tube 200 and the inner tube 300 is minimized.

6 FIG. 16 is a perspective view showing an overall configuration of the resonator for a vehicle according to another embodiment of the present invention; and FIG 7 is an enlarged view showing section B of FIG 6 shows.

The in 6 and 7 The resonator shown is substantially identical to that of the previous embodiment, except for the shape of the outer surface of the outer tube, the shape of the barrier and the dimensions of the inner tube, and the following description focuses only on the different features.

As in 6 and 7 shown has a resonator 101 for a vehicle according to this embodiment, an outer tube 200 , which forms its appearance, a turbocharger connection unit 400 partially into a front section of the outer tube 200 is inserted, and an inner tube 300 partly into a rear section of the outer tube 200 is used.

The turbocharger connection unit 400 may be a component of a turbocharger that supplies air. In other words, an end portion of the turbocharger may extend into an inner portion of the outer tube 200 extend. As another example, the turbocharger port unit 400 a separate component connected to one end of the turbocharger.

As the turbocharger connection unit 400 directly into the outer tube 200 is used, in this embodiment has a first resonance chamber 610 an enlarged space compared to the previous embodiment, whereby an efficient noise reduction is ensured.

The resonance chamber 600 can by means of a first barrier 360 and a second barrier 370 , which are installed along the air movement direction, in a first resonance chamber 610 , a second resonance chamber 620 and a third resonance chamber 630 to be grouped. In addition, a stepped section is attached to the inner surface of the outer tube 200 is formed from a first stepped portion 551 who is close to the first one barrier 360 liable, and a second stepped section 552 who is close to the second barrier 370 liable, composed. The first stepped section 551 and the second stepped section 552 are inclined so that they extend to the direction of extension of the horizontal section, on the inner surface of the outer tube 200 is formed to form an acute angle.

Because of the inclination of the stepped portion, the thickness of the outer tube is 200 in an area of the first resonance chamber 610 forms, compared to an area of the second resonance chamber 620 forms, relatively smaller, and the thickness of the outer tube 200 is an area that houses the second resonance chamber 620 forms, compared to an area of the third resonance chamber 630 forms relatively less.

Therefore, the length of the first barrier 360 that fits closely to the first stepped section 551 adheres, relatively larger than the length of the second barrier 370 that fits closely to the second stepped section 552 liable. In addition, the first barrier 360 and the second barrier 370 Have edges that are inclined at a predetermined angle so that they are aligned with the first stepped portion 551 or the second stepped portion 552 stay in contact.

In addition, a width W1 of the first resonance chamber 610 greater than a width W2 of the second resonance chamber 620 , and the width W2 of the second resonance chamber 620 is larger than a width W3 of the third resonance chamber 630 ,

Furthermore, the outer surface of the outer tube extends 200 flat along the same direction as the extending direction of the inner tube 300 , Therefore, in this embodiment, it is not necessary to have a separate rib 205 to install (s. 2 ) to the thickness of the outer tube 200 to increase, unlike the previous embodiment.

The resonator 101 according to this embodiment is prepared as follows. If the inner tube 300 in the outer tube 200 is used, first occurs in a state where small gaps between the first barrier 360 and the first stepped portion 551 , between the second barrier 370 and the second stepped portion 552 as well as between the contact end 305 and the hooking projection 533 are formed, an end 402 the turbocharger in contact with one end 202 of the outer tube. In this state will be the end 402 the turbocharger and the end 202 the outer tube connected by welding. At this time, due to the heat generated during welding, a contact surface of the end melts 402 the turbocharger and the end 202 of the outer tube so that its thickness is reduced. Accordingly, the first barrier is liable 360 close to the first stepped section 551 , the second barrier 370 adheres tightly to the second stepped portion 552 , and the contact end 305 of the inner tube presses on the hooking projection 533 of the outer tube.

If the resonator 101 According to this embodiment, therefore, the sealing performance of the resonance chamber 600 while maintaining the frequency of welding between the outer tube 200 and the inner tube 300 is minimized.

8th FIG. 10 is a cross-sectional view showing an internal configuration of a resonator for a vehicle according to still another embodiment of the invention. FIG.

As in 8th shown has a resonator 102 according to this embodiment, an outer tube 200 which forms its appearance, and an inner tube 300 on that in the outer tube 200 is used, similar to the previous embodiment. An outer coupling plate 201 is at one end of the outer tube 200 provided, and an inner clutch plate 301 connected to the outer clutch plate 201 can be connected, is on the inner tube 300 intended. In other words, the resonator 102 can by connecting the outer clutch plate 201 and the inner clutch plate 301 getting produced.

The inner tube 300 has a body 304 with a cylindrical shape and a barrier 380 on, which is an outer surface of the body 304 surrounds and from the outer surface of the body 304 protrudes outwards. The barrier 380 is arranged so that it from the inner clutch plate 301 is spaced by a predetermined distance, and when the inner tube 300 in the outer tube 200 is used, the barrier becomes 380 Flexibly bent so that they fit with the inner surface of the inner tube 300 in contact.

slots 331 . 332 , which serve as an air movement channel, are on the body 304 educated. In addition, the slots can 331 . 332 with a resonance chamber 700 communicate to reduce the air movement noise. In particular, the slots comprise a first slot 331 that with a first resonance chamber 710 communicates, and a second slot 332 that with a second resonance chamber 720 communicates according to a direction from the air inlet 70 to the air outlet 80 ,

The first resonance chamber 710 is an area passing through the outer clutch plate 301 , a part of the outer tube 200 , the barrier 380 and a part of the body 304 is completely sealed, except for the first slot 331 to reduce the intake noise. Similarly, the second resonance chamber 720 by means of a curved section 206 coming from a surface of the outer tube 200 protrudes and extends outwardly therefrom, another portion of the outer tube 200 , the barrier 380 and part of the body 304 completely sealed, except for the second slot 332 to reduce the intake noise.

A prominent section 303 is at one end of the inner tube 300 formed so that it has a step, and a recessed section 203 which has a reverse step corresponding to the above-mentioned step is at a side of the curved section 206 designed so that it can be mounted on the above stage. In other words, the second resonance chamber 720 can be sealed by the above section 303 in the recessed section 203 is fitted.

In addition, the first resonance chamber 710 and the second resonance chamber 720 Tuning air at different frequencies so that both high frequency air movement noise and low frequency air movement noise can be properly tuned.

The areas of the first resonance chamber 710 and the second resonance chamber 720 are through the barrier 380 divided. In other words, the barrier 380 extends from a point between the first slot 331 and the second slot 332 to the inner surface of the outer tube 200 , The following is the configuration of the barrier 380 described in detail.

9 is an enlarged view showing a section C of FIG 8th shows and illustrates that the barrier comes into contact with the inner surface of the outer tube.

As in 9 shown, indicates the barrier 380 a blocking element 381 on the outside of the body 304 to the inner surface of the outer tube 200 protrudes, making it the first resonance chamber 710 and the second resonance chamber 720 separates each other. One side of the blocking element 381 is tight with the outer surface of the body 304 connected, and the other end is from the inner surface of the outer tube 200 spaced apart by a predetermined distance. In other words, the blocking element 381 and the inner surface of the outer tube 200 are according to 9 provided with a gap P.

At the gap P is an extended section 382 installed so that it is from one side of the blocking element 381 protrudes outwards and with the inner surface of the outer tube 200 comes into contact. The extended section 382 is integral with the blocking element 381 produced.

In addition, the extended section 382 made of a material which is bendable with a predetermined curvature. For example, the extended section 382 be made of flexible plastic with predetermined spring force.

Before the outer tube 200 and the inner tube 300 also has the extended section 382 a length L that is relatively longer than the distance P between the end of the blocking element 381 and the inner surface of the outer tube 200 is. If the inner tube 300 in the outer tube 200 is used, therefore, the extended section occurs 382 with the inner surface of the outer tube 200 in contact, in a state of being bent or compressed with a predetermined curvature.

In addition, an angle is between an upper surface of the blocking element 381 and one side of the extended portion 382 an obtuse angle, leaving the extended section 382 slightly along the inner surface of the outer tube 200 can move.

A predetermined gap is created by mounting tolerance or long-term use of the resonator between the barrier and the inner surface of the outer tube, and thereby the entire area of the resonance chamber except the slot is not completely sealed. However, in the present invention, the extended portion is 382 formed so that its length L is relatively greater than the distance P between the end of the blocking element 381 and the inner surface of the outer tube 200 is, and the extended section 382 is made of flexible plastic material so that the resonance chamber except the slot can be completely sealed.

The following is an operation of assembling the resonator for a vehicle with reference to FIG 10 described.

As in 10 As shown, a user moves in a state where the inner surface of the outer tube 200 with the extended section 382 is in contact, the extended section 382 from the inlet 70 to the outlet 80 , Accordingly, the extended section moves 382 in a curved condition along the inner surface of the outer tube 200 to achieve a predetermined bend. At the same time, the bend of the extended section 382 greater than a limit, the extended section 382 can lose elasticity or any component can be damaged. Therefore, the diameter of the body should be 304 , the length of the blocking element 381 and the length of the extended section 382 be suitably adjusted so that the bend of the extended portion does not exceed a predetermined limit.

If the extended section 382 is completely moved and thus the preceding section 303 of the inner tube 300 completely in the recessed section 203 of the outer tube 200 is fitted, the outer tube 200 and the inner tube 300 temporarily linked together. Subsequently, the outer coupling plate 201 of the outer tube 200 and the inner clutch plate 301 of the inner tube 300 completely welded together by welding or the like, so that the outer tube 200 and the inner tube 300 be completely connected.

As described above, in the present invention, the inner tube 300 easily into the outer tube 200 be used without components interfere with each other, since the made of flexible material extended section 382 at the end of the barrier 380 is trained.

In addition, because the resonance chamber through the extended section 382 With the exception of the slot can be completely sealed, the air movement noise can be efficiently reduced.

While exemplary embodiments have been shown and described, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of this invention as defined in the appended claims. In addition, many modifications may be made to adapt a particular situation or material to the teachings of this invention without departing from the essential scope thereof. Therefore, this invention should not be construed as limited to the particular exemplary embodiments which are considered to constitute the best mode for carrying out the invention, but the invention is intended to embrace all embodiments falling within the scope of the appended claims.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• KR 2012-0037150 [0006]

Claims (16)

A resonator for a vehicle that reduces airmoving noise, the resonator comprising: An outer tube forming the appearance of the resonator; An inner tube partially inserted into the outer tube and having a plurality of slots formed therein serving as an air movement channel; A barrier projecting from an outer surface of the inner tube to the outer tube and contacting an inner surface of the outer tube; and A plurality of resonance chambers configured to communicate respectively with the plurality of slots and divided by the barrier so as to form a plurality of suction noise reduction areas, Wherein a horizontal portion extending in the same direction as the extending direction of the inner tube and a stepped portion curved from the horizontal portion to the resonance chambers are alternately formed on the inner surface of the outer tube so that the plurality of Resonance chambers is formed with different widths. Resonator for a vehicle according to claim 1, Wherein the resonance chambers are divided into a first resonance chamber, a second resonance chamber, and a third resonance chamber by means of a first barrier and a second barrier installed along an air movement direction, Wherein the stepped portion comprises a first stepped portion adhered closely to the first barrier and a second stepped portion closely adhered to the second barrier, and - wherein the first stepped portion and the second stepped portion are curved in a direction perpendicular to the extending direction of the horizontal portion. Resonator for a vehicle according to claim 2, - wherein the first barrier has a length between a width of the first resonance chamber and a width of the second resonance chamber, and - wherein the second barrier has a length between a width of the second resonance chamber and a width of the third resonance chamber. Resonator for a vehicle according to claim 2, Wherein the horizontal portion comprises a first horizontal portion forming a surface of the first resonance chamber, a second horizontal portion forming a surface of the second resonance chamber, and a third horizontal portion forming a surface of the third resonance chamber, and - Wherein the first stepped portion between the first horizontal portion and the second horizontal portion is formed, and the second stepped portion between the second horizontal portion and the third horizontal portion is formed. Resonator for a vehicle according to claim 2, Wherein the first resonance chamber is formed as an outer clutch plate formed at one end of the outer tube and as an inner clutch plate formed at an opposite position of the second barrier with the first barrier interposed therebetween, and - Wherein the outer clutch plate and the inner clutch plate are joined together by welding, whereby the outer tube and the inner tube are interconnected. A resonator for a vehicle according to claim 5, - wherein the third resonance chamber has a surface which is formed by a partition plate of the outer tube, which is arranged at a position opposite to the second barrier, and - Wherein a hooking projection, which can adhere closely to a contact end of the inner tube, is formed at one end of the partition plate. The resonator for a vehicle according to claim 6, wherein, when the outer tube and the inner tube are mounted, the first stepped portion adheres closely to one side of the first barrier, the second stepped portion adheres closely to one side of the second barrier, and the contact end of the second barrier inner tube pushes the hooking projection of the outer tube in a horizontal direction. The resonator for a vehicle according to claim 2, wherein an outer horizontal portion and an outer stepped portion are alternately formed on the outer surface of the outer tube to correspond to the shape of the inner surface of the outer tube. The resonator for a vehicle according to claim 8, wherein a rib is installed on the outer surface of the outer tube to increase the thickness of the outer tube. The resonator for a vehicle according to claim 1, wherein the resonance chambers are divided into a first resonance chamber, a second resonance chamber and a third resonance chamber by a first barrier and a second barrier installed along an air movement direction, wherein the stepped portion is a first resonance chamber a stepped portion which adheres closely to the first barrier, and a second stepped portion which adheres closely to the second barrier, and - Wherein the first stepped portion and the second stepped portion are inclined so as to form an acute angle to the extension direction of the horizontal portion. A resonator for a vehicle according to claim 10, Wherein a length of the first barrier closely adhered to the first stepped portion is greater than a length of the second barrier closely adhered to the second stepped portion, and - wherein a width of the first resonance chamber is greater than a width of the second resonance chamber and the width of the second resonance chamber is greater than a width of the third resonance chamber. The resonator for a vehicle according to claim 10, wherein the outer surface of the outer tube extends flat along the same direction as the horizontal portion. A resonator for a vehicle that reduces the noise of air moving from an inlet formed on one of its sides to an outlet formed on the other side thereof, the resonator comprising: An outer tube forming the appearance of the resonator; An inner tube partially inserted into the outer tube and having a plurality of slots formed therein serving as an air movement channel; A barrier projecting from an outer surface of the inner tube to the outer tube and contacting an inner surface of the outer tube; and A plurality of resonance chambers configured to communicate with the plurality of slots, respectively, and shared by the barrier so as to form a plurality of areas for reducing the intake noise, - wherein the barrier comprises a blocking element which projects from the outer surface of the inner tube to the outer tube, and an extended portion which is integrally formed with the blocking element and one end of which comes into contact with the inner surface of the outer tube, and - wherein the extended portion is elastically transformable. The resonator for a vehicle according to claim 13, wherein the extended portion has a length greater than a distance between an end of the blocking member and the inner surface of the outer tube. The resonator for a vehicle according to claim 13, wherein an angle between an upper surface of the blocking member and a side surface of the extended portion is an obtuse angle. A resonator for a vehicle according to claim 13, Wherein the resonance chambers comprise a first resonance chamber adjacent to the inlet and a second resonance chamber adjacent to the outlet, Wherein the first resonance chamber is formed as an outer clutch plate formed at one end of the outer tube and as an inner clutch plate arranged to be spaced a predetermined distance from the barrier and from a surface of the barrier inner tube projecting outwardly, wherein these are interconnected, and - wherein the second resonance chamber is formed as a protruding portion formed at one end of the inner tube and having a predetermined step, and a recessed portion formed on one side of the outer tube and a step in an opposite direction to the step of the projecting portion, wherein these are in engagement with each other.

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