The present invention relates to a muffler sound-insulation structure which insulates noise of a muffler.
Conventionally, there have been mufflers which reduce noise of fluids (for example, Patent Documents 1 and 2). In the techniques described in the Patent Documents 1 and 2, a cover is provided outside a pipe. There have also conventionally been those provided with a soundproof cover covering a muffler (a muffler sound-insulation structure) outside the muffler. According to this structure, noise of a muffler is insulated by the soundproof cover.
Patent Document 1: JP 2008-232053 A
Patent Document 2: JP 2011-074914 A
When an inspection, a repair or the like for a muffler sound-insulation structure is conducted, a soundproof cover may be detached from a muffler. After the inspection, the repair or the like, the soundproof cover may be attached to the muffler. In conventional muffler sound-insulation structures, the attachment or the detachment has been difficult in some cases, which has resulted in a concern that an ease of maintenance of a muffler sound-insulation structure is lowered.
Thus, the present invention has an object of providing a muffler sound-insulation structure capable of ensuring a sound insulation performance and the ease of maintenance.
The muffler sound-insulation structure of the present invention comprises a muffler having an axial direction, through which a fluid flows inside, and a soundproof cover which encloses the muffler in a state of non-contact to the muffler. The soundproof cover is formed so as to have a circumferential cross section when viewed from the axial direction, and is configured to be disassemblable. The soundproof cover comprises plural unit soundproof covers each constituting a portion of the circumferential cross section, and connecting parts which are provided on the periphery of the circumferential cross section, connecting the plural unit soundproof covers with one another in an attachable/detachable manner. Each of the plural unit soundproof covers is configured so as to be capable of being attached and detached relative to the muffler by being moved in a direction orthogonal to the axial direction of the muffler.
With the above structure, it is possible to ensure a sound insulation performance and an ease of maintenance.
A muffler sound-insulation structure 1 of a first embodiment will be described with reference to
The muffler sound-insulation structure 1 is a structure for insulating a noise made by a fluid F, as shown in
The muffler sound-insulation structure 1 may be provided, for example, on a side of exhaust of the compressor (a side of exhaust having a larger noise than a side of intake), and may be provided, for example, on a side of intake of the compressor. Hereinbelow described is a case where the muffler sound-insulation structure 1 is provided on a side of exhaust of the compressor. The muffler sound-insulation structure 1 comprises a pipe 10, a muffler 20, a soundproof cover 30; and putty 40 and rock wool tapes 51 (heat insulating material) which are shown in
The pipe 10 is a pipe through which the fluid F flows inside, as shown in
The upstream-side pipe 11 is linked to an upstream-side part (an end of the upstream-side or the vicinity of the end) of the muffler 20 (which will be described later). The upstream-side pipe 11 may be fixed, for example, to the upper end of the muffler 20, or for example, may be fixed to an end in an axial direction A (which will be described later) of the muffler 20 (not illustrated). The upstream-side pipe 11 is linked to a discharge port of the compressor. The link may be either indirect (via a pipe not illustrated) or direct. The upstream-side pipe 11 comprises an upstream-side flange 11a. The upstream-side flange 11a is a collar for a pipe link-up. The upstream-side flange 11a is provided in the most upstream-side part of the upstream-side pipe 11.
The downstream-side pipe 13 is linked to a downstream-side part (an end of the downstream-side or the vicinity of the end) of the muffler 20 (which will be described later). The downstream-side pipe 13 is fixed, for example, to an end in the axial direction A (which will be described later) of the muffler 20. The downstream-side pipe 13 comprises a downstream-side flange 13a. The downstream-side flange 13a is a collar for a pipe link-up. The downstream-side flange 13a is provided in the most downstream-side part of the downstream-side pipe 13.
The muffler 20 reduces energy of sound of the fluid F which flows inside the muffler 20. The muffler 20 reduces the energy of sound, for example, by enlarging and contracting an area of a cross section of a flow path of the fluid F (an area of a cross section orthogonal to a direction of the flow of the fluid F). The muffler 20 is linked to the compressor via the upstream-side pipe 11. As shown in
The muffler main body 23 has a circumferential cross section when viewed from the axial direction A (see
The end faces 23e are faces of the both end parts in the axial direction A (two faces), among the surfaces which constitute the muffler main body 23, as shown in
The side face 23s is the portion having a circumferential (circular, see
The soundproof cover 30 reduces (insulates) a noise emitted from the surface of the muffler 20. As shown in
The soundproof cover 30 is disposed such that a vibration of the muffler 20 is not propagated directly to the soundproof cover 30. Specifically, as shown in
The soundproof cover 30 is configured so as to be capable of sufficiently insulating a noise of the muffler 20 (so as to be capable of sufficiently ensuring the sound insulation performance). The sound insulation performance (sound-insulation amount) increases in proportion to weight of an insulation object (mass law). The thickness of the soundproof cover 30 in the cross section shown in
The soundproof cover 30 has an axial direction. A cover main body 33 (which will be described later) of the soundproof cover 30 is configured so as to comprise a circumferential cross sections 30s when viewed from the axial direction A (
The soundproof cover 30 is attachable/detachable relative to the muffler 20 (which will be described later). The soundproof cover 30 is configured so as to be disassemblable and comprises plural unit soundproof covers 31R, 31L. The soundproof cover 30 also comprises a cover main body 33 and connecting parts 35.
The unit soundproof covers 31R, 31L each constitute portions of the circumferential cross section 30s of the soundproof cover 30, as shown in
In the soundproof cover 30, the cover main body 33 is a portion having a columnar outer shape as shown in
The connecting parts 35 connect the plural unit soundproof covers 31R, 31L with one another in an attachable/detachable manner. As shown in
The projecting parts 35a are parts which are fastened by the fastening members 35b. As shown in
The fastening members 35b fasten (bond) the projecting parts 35a of the separate unit soundproof covers 31R, 31L to each other. Concretely, the fastening members 35b are bolts and nuts. The fastening members 35b are provided in plural numbers.
The putty 40 (putty material) fills the gap between the pipe 10 and the soundproof cover 30 (seals the gap, or fills up the gap). The putty 40 fills the gap(s) between the upstream-side pipe 11 and/or the downstream-side pipe 13 and the notch(es) 30a of the soundproof cover 30. The putty 40 is a heat-resistant putty durable in the surface temperature of the pipe 10 (which may become, for example, 200° C. to 300° C.). The putty 40 has a flexibility capable of suppressing a propagation of a vibration from the pipe 10 to the soundproof cover 30. In
The rock wool tapes 51 (porous material) are provided between the muffler 20 and the soundproof cover 30, as shown in
The rock wool tapes 51 are a porous material. The porous material is capable of suppressing a propagation of a vibration. Concretely, the rock wool tapes 51 are capable of suppressing a propagation of a vibration from the muffler 20 to the soundproof cover 30. The porous material has a sound absorbency. Concretely, the rock wool tapes 51 are capable of reducing a reflected sound between the outer surface of the muffler 20 and the inner surface of the soundproof cover 30. More particularly, as an air which conveys the reflected sound passes through the porous material, a friction is generated between the air and the porous material, and this friction dissipates energy of the sound. As a result, a noise from the inside of the soundproof cover 30, which leaks through the gap of the soundproof cover 30 to the outside of the soundproof cover 30 is suppressed. The above “gap of the soundproof cover 30”, concretely, is the gap between the two projecting parts 35a of the connecting parts 35.
The rock wool tapes 51 are a porous heat insulating material, and suppress a heat transfer from the muffler 20 to the soundproof cover 30. The rock wool tapes 51 comprise porous fibers. Incidentally, the rock wool tapes 51 may be substituted with another porous material (for example, other porous fibers, for example, a glass wool, or the like).
(Measurement of Sound Insulation Property of Soundproof Cover 30)
Sound insulation properties are compared between the muffler sound-insulation structure 1 of the present embodiment shown in
Results of the measurement are shown in
(Effect 1)
In the next place, effects of the muffler sound-insulation structure 1 shown in
[Structure 1-1]
The soundproof cover 30 encloses the muffler 20 in a state of non-contact to the muffler 20.
[Structure 1-2]
The soundproof cover 30 is formed so as to have the circumferential cross section 30s when viewed from the axial direction A (see
[Structure 1-3]
As shown in
[Structure 1-4]
The connecting parts 35 are provided on the circumference of the circumferential cross section 30s, and connect the plural unit soundproof covers 31R, 31L with one another in an attachable/detachable manner.
[Structure 1-5]
As shown in
The muffler sound-insulation structure 1 comprises the above [structure 1-1]. Therefore, a vibration is not directly propagated from the muffler 20 to the soundproof cover 30. Thus, it is possible to inhibit the soundproof cover 30 from violating, and accordingly, it is possible to inhibit the surface of the soundproof cover 30 from becoming a source of noise (an emission face of sound). As a result, it is possible to ensure the sound-insulation property of the muffler sound-insulation structure 1.
The muffler sound-insulation structure 1 comprises the above [structure 1-2] and the [structure 1-3]. Accordingly, it is possible to actualize the structure in which the soundproof cover 30 is disassemblable and encloses the muffler 20. Since the soundproof cover 30 encloses the muffler 20, it is possible to insulate a noise emitted from the muffler 20, and as a result, it is possible to ensure the sound-insulation property of the muffler sound-insulation structure 1.
In the muffler sound-insulation structure 1, the soundproof cover 30 is disassemblable (see the [structure 1-2]) and comprises the above [structure 1-4] and [structure 1-5]. Therefore, by fixing/unfixing the connecting parts 35, each of the plural unit soundproof covers 31R, 31L is easily attachable and detachable relative to the muffler 20. Thus, it is possible to ensure the ease of maintenance of the muffler sound-insulation structure 1.
(Effect 2)
As shown in
[Structure 2]
The putty 40 fills the gap between the pipe 10 and the soundproof cover 30.
With the above [structure 2], it is possible to insulate a sound leaked from the gap between the pipe 10 and the soundproof cover 30 to the outside of the soundproof cover 30. Thus, it is possible to improve the sound-insulation property of the muffler sound-insulation structure 1. The member which fills the gap between the pipe 10 and the soundproof cover 30 is the putty 40 (the [structure 2] above). Therefore, it is possible to suppress a vibration which is propagated from the pipe 10 to the soundproof cover 30 better than in a case where the gap is filled with a material which easily propagates the vibration compared to the putty 40 (a metal, etc.). Thus, it is possible to improve the sound-insulation property of the muffler sound-insulation structure 1.
(Effect 3)
As shown in
In this structure, a reflected sound between the muffler 20 and the soundproof cover 30 is reduced by the rock wool tapes 51 which are a porous material. Therefore, it is possible to inhibit the vibration of the reflected sound from being propagated to the soundproof cover 30. It is also possible to inhibit the reflected sound from leaking from the gap of the soundproof cover 30 (the gap of the connecting parts 35, specifically, the gap between the projecting parts 35a). Thus, it is possible to improve the sound-insulation property of the muffler sound-insulation structure 1.
In a case where the rock wool tapes 51 are contacted with the muffler 20 and the soundproof cover 30, the vibration which is propagated from the muffler 20 to the soundproof cover 30 is suppressed by the rock wool tapes 51 (the rock wool tapes 51 function as vibration damping material). Accordingly, the soundproof cover 30 is inhibited from vibrating. Thus, it is possible to improve the sound-insulation property of the muffler sound-insulation structure 1.
A muffler sound-insulation structure 201 of a second embodiment will be described with reference to
The ribs 225 support the soundproof cover 30 via the rock wool tapes 51, as shown in
(Effects by Rib 225)
As shown in
According to this structure, even in a case where the weight of the soundproof cover 30 is increased due to an increase of plate thickness (the width in the radial direction R) of the soundproof cover 30, or the like, the soundproof cover 30 is easily supported onto the muffler main body 23.
A muffler sound-insulation structure 301 of a third embodiment will be described with reference to
The soundproof cover 330 has a double structure of an inner wall 333i and an outer wall 333o which will be described later, as shown in
Each of the inner wall 333i and the outer wall 333o has a circumferential cross section similar to the circumferential cross section 30s (see
The connecting walls 333r connect the inner wall 333i and the outer wall 333o. The connecting walls 333r are provided so as to form the spaces inside-covers S330 which will be described in the followings. The connecting walls 333r connect the inner wall 333i and the outer wall 333o at the parts connecting the unit soundproof covers 31R and 31L with one another (in the vicinity of the connecting parts 35, specifically, inner side in the radial direction R of the connecting parts 35).
The spaces inside-covers S330 are formed between the inner wall 333i and the outer wall 333o. The spaces inside-covers S330 are a space surrounded by the inner wall 333i, the outer wall 333o, and the connecting walls 333r. The spaces inside-covers S330 are, for example, a sealed space, or for example, a substantially closed space. The spaces inside-covers S330 are formed such that a stuffing (porous material or granules) may be disposed inside.
The glass wool 361 (porous material) is provided inside the spaces inside-covers S330. The glass wool 361 is a porous material (the details described above), and a porous heat insulating material, and comprises porous fibers. The glass wool 361 reduces a reflected sound in the spaces inside-covers S330 (a reflected sound between the inner wall 333i and the outer wall 333o). The glass wool 361 is provided so as to be capable of imparting a vibration damping effect to the soundproof cover 330. Concretely, the glass wool 361 is in contact (is in close contact) with the inner wall 333i, the outer wall 333o, and the connecting walls 333r. The glass wool 361 may be substituted with another porous material (rock wool, or the like).
(Effect 4)
Effects by the muffler sound-insulation structure 301 shown in
[Structure 4]
The glass wool 361 is provided inside the spaces inside-covers S330.
With the above [Structure 4], it is possible to reduce the reflected sound inside the spaces inside-covers S330 by the glass wool 361. Thus, it is possible to improve the sound-insulation property of the soundproof cover 330, and accordingly, it is possible to improve the sound-insulation property of the muffler sound-insulation structure 301.
With the above [Structure 4], it is possible to leave the glass wool 361 in the spaces inside-covers S330 when the soundproof cover 330 is disassembled (when the plural unit soundproof covers 31R, 31L are disassembled). Therefore, the handling (disassembling/assembling operations, transportation, etc.) of the soundproof cover 330 or the glass wool 361 is easy. Thus, it is possible to improve the ease of maintenance of the muffler sound-insulation structure 301.
[Modification of Third Embodiment]
As described above, inside of the spaces inside-covers S330 was provided with the glass wool 361 which was a porous material. However, inside of the spaces inside-covers S330 may also be provided with granules 363 (granular material), instead of, or in addition to the glass wool 361. The granules 363 may be, for example, sands (such as river sands), or for example, lime.
(Effect 5)
[Structure 5]
The soundproof cover 330 comprises the granules 363 which are provided to the spaces inside-covers S330.
In the above [Structure 5], the weight of the soundproof cover 330 is increased, as compared with a case having no granules 363 in the spaces inside-covers S330. Therefore, the sound-insulation property of the soundproof cover 330 is improved according to the mass law referred above. In addition, the reflected sound in the spaces inside-covers S330 is reduced (sound absorbency) by the air passing through spaces between the granules 363 (for example, spaces between sand grains). The above sound-insulation property and the sound absorbency further improve the sound-insulation property in the muffler sound-insulation structure 301. It is noted that the heavier the granules 363, the more the sound-insulation property of the soundproof cover 330 is improved. The more there are spaces of the granules 363, the more the sound-insulation property in the granules 363 is improved.
In the [Structure 5] above, the granules 363 are provided inside the spaces inside-covers S330. Therefore, it is possible to leave the granules 363 in the spaces inside-covers S330 when the soundproof cover 330 is disassembled (the plural unit soundproof covers 31R, 31L are disassembled). Thus, the handling (disassembling/assembling operations, transportation, etc.) of the soundproof cover 330 or the granules 363 is easy. Thus, it is possible to further improve the ease of maintenance of the muffler sound-insulation structure 301.
A muffler sound-insulation structure 401 of a fourth embodiment will be described with reference to
The ribs 425 are members which facilitate disposing the bags 455 and the granules 457 on a surface (a side face 23s) of the muffler main body 23, as shown in
The bags 455 are provided with the granules 457 inside. The bags 455 are a sand bag, when the granules 457 are sands. The bags 455 are provided between the muffler 20 (the muffler main body 23) and the soundproof cover 30. The bags 455 are provided in plural numbers. The bags 455 are provided between the ribs 425 adjacent to each other. As shown in
The granules 457 are provided (stuffed, accommodated, or wrapped) inside the bags 455. The granules 457 are sands, or the like, similarly to the granules 363 of the third embodiment (see
(Effect 6)
Effects of the muffler sound-insulation structure 401 shown in
In this structure, the bags 455 and the granules 457 are attachable/detachable relative to the muffler 20, in the state that the bags 455 have the granules 457 provided inside. Thus, it is possible to further improve the ease of maintenance of the muffler sound-insulation structure 401.
A muffler sound-insulation structure 501 of a fifth embodiment will be described with reference to
The sealed spaces inside-covers S530 (sealed space) are provided (formed) between the outer face of the soundproof cover 330 (the outer face of the outer wall 333o, or the surface) and the muffler 20, as shown in
The valves 570 open and close flow paths (not illustrated) through which the inside of the sealed spaces inside-covers S530 communicates with the outside of the soundproof cover 330. The valves 570 are provided on the surface of the outer wall 333o (side face 33s). The valves 570 are opened when the inside of the sealed spaces inside-covers S530 is to be depressurized.
(Process of Depressurization)
A depressurization of the sealed spaces inside-covers S530 is carried out, for example, by the following process (a) to (d). This process allows the sealed spaces inside-covers S530 to be easily depressurized, even in a case where there is no depressurizing means (such as a vacuum pump) around a place where the muffler sound-insulation structure 501 is installed. (a) The soundproof cover 330 is disassembled into the plural unit soundproof covers 31R, 31L, and removed from the muffler 20. (b) The unit soundproof covers 31R, 31L are transported to the vicinity of a place where a depressurizing means is installed. (c) The sealed spaces inside-covers S530 of the respective unit soundproof covers 31R, 31L are depressurized by the depressurizing means. (d) The unit soundproof covers 31R, 31L are attached to the muffler 20.
(Relationship Between Pressure and Sound-Insulation Property)
The pressure in the sealed spaces inside-covers S530 was varied to research a relationship between noise level and frequency in the vicinity of the side face 33s of the soundproof cover 330. The results are shown in
(Effect 7-1)
Effects of the muffler sound-insulation structure 501 shown in
[Structure 7-1]
The pressure in the sealed spaces inside-covers S530 is depressurized relative to an air pressure outside the soundproof cover 330.
According to the above [Structure 7-1], a sound wave is hard to be transmitted in the sealed spaces inside-covers S530. Thus, it is possible to improve the sound-insulation property of the muffler sound-insulation structure 501.
(Effect 8-1)
The pressure in the sealed spaces inside-covers S530 is 0.05 MPa or less. In this structure, it is possible to surely improve the sound-insulation property by the sealed spaces inside-covers S530.
A muffler sound-insulation structure 601 of a sixth embodiment will be described with reference to
The partition walls 637 partition the sealed spaces inside-covers S530. The sealed space inside-covers S530 of one unit soundproof cover 31R (or 31L) is partitioned into plural spaces with the partition walls 637, preferably into 3 or more spaces with 2 or more partition walls 637. In
(Effect by Partition Wall 637)
Effect by the muffler sound-insulation structure 601 shown in
If it is assumed that the sealed space inside-covers S530 of one unit soundproof cover 31R (or 31L) (see
On the other hand, in the muffler sound-insulation structure 601, the sealed spaces inside-covers S530 are partitioned with the partition walls 637 as shown in
A muffler sound-insulation structure 701 of a seventh embodiment will be described with reference to
The sealed pipes 780 are a pipe, the inside of which are sealed, as shown in
(Effect 7-2)
Effects by the muffler sound-insulation structure 701 shown in
[Structure 7-2]
A pressure of the sealed spaces inside-pipe S780 is depressurized relative to an air pressure outside the soundproof cover 30.
According to the above [Structure 7-2], a sound wave is hard to be transmitted in the sealed spaces inside-pipe S780. Thus, it is possible to improve the sound-insulation property of the muffler sound-insulation structure 701.
(Effect 8-2)
Pressure inside the sealed spaces inside-pipe S780 is 0.05 MPa or less. In this structure, it is possible to surely improve the sound-insulation property by the sealed spaces inside-pipe S780.
(Other Effects by Sealed Pipe 780)
The sealing space (the sealed space inside-pipe S780) is formed inside each sealed pipe 780. According to this structure, it is possible to easily form the sealing space (the sealed space inside-pipe S780). More specifically, in order to form the sealed spaces inside-covers S530 of the fifth embodiment shown in
(Modification)
The above each embodiment may be variously modified. For example, a part of the each embodiment above may be combined to another.
For example, it is possible to appropriately combine the structures provided between the muffler main body portion 23 as described in
It is also possible, for example, to appropriately combine the soundproof cover 30 as shown in
It is also possible, for example, to appropriately combine the structure α and the structure β above.
Although the present invention has been described in detail and with reference to the specific embodiments, it is apparent for those skilled in the art that various modifications or alterations can be added thereto without departing from the spirit and the scope of the present invention.
The present application is based on the Japanese patent application (Patent Appl. No. 2013-097805) filed on May 7, 2013, the contents thereof being incorporated herein by reference.
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2013-097805 | May 2013 | JP | national |
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PCT/JP2014/058676 | 3/26/2014 | WO | 00 |
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WO2014/181596 | 11/13/2014 | WO | A |
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