阅读说明：本技术 汽车用空调装置的压缩机 (Compressor of air conditioner for automobile ) 是由 渡边保德 萩田贵幸 药师寺俊辅 冈部良次 佐保日出夫 于 2020-02-28 设计创作，主要内容包括：压缩机(100)具备：压缩机主体(10)；配管(20),与压缩机主体(10)连接；及声学罩,配置于压缩机主体(10)的周围。声学罩(30)具有用于插入配管(20)且与配管(20)紧贴的插入孔(31),并且呈内表面(30A)沿着压缩机主体(10)的外表面(10A)的形状。通过该结构,能够实现声学罩(30)的小型化及轻型化,同时能够使用更简单的结构的声学罩(30)来降低汽车用空调装置的压缩机(100)的噪声。(A compressor (100) is provided with: a compressor main body (10); a pipe (20) connected to the compressor body (10); and an acoustic cover disposed around the compressor body (10). The acoustic cover (30) has an insertion hole (31) for inserting the pipe (20) and is in close contact with the pipe (20), and has an inner surface (30A) that is shaped to follow the outer surface (10A) of the compressor body (10). With this configuration, the acoustic cover (30) can be made smaller and lighter, and the noise of the compressor (100) of the automotive air conditioning apparatus can be reduced by using the acoustic cover (30) having a simpler configuration.)

1. A compressor for an automotive air conditioning system, comprising:

a compressor main body;

a pipe connected to the compressor main body; and

an acoustic cover disposed around the compressor main body,

the acoustic cover has an insertion hole for inserting the pipe and closely contacting the pipe, and has an inner surface along an outer surface of the compressor body.

2. The compressor for an air conditioner for an automobile according to claim 1,

the acoustic enclosure is a porous foam material.

3. The compressor for an air conditioner for a vehicle according to claim 2,

the acoustic cover has at least one dividing portion formed on a wall portion along a short side direction.

4. The compressor for an air conditioner for a vehicle according to claim 3,

the acoustic cover has an overlapping portion where half portions divided by the dividing portion overlap each other at the position of the dividing portion.

5. The compressor for an air conditioner for a vehicle according to claim 4,

the overlapping portion is a fitting portion that fits the half portions to each other.

6. The compressor for an air conditioner for a vehicle according to claim 4,

the acoustic enclosure has a protrusion from an outer surface at the location of the overlap.

7. The compressor for an air conditioner for a vehicle according to claim 4,

the acoustic enclosure has an embedded resin material at the location of the overlap.

8. The compressor for an air conditioner for a vehicle according to claim 4,

the compressor body has a protrusion protruding from the outer surface,

the overlapping portion of the acoustic cover abuts the convex portion.

9. The compressor for an automotive air conditioning apparatus according to claim 4,

the overlapping portion is a catching portion that catches the half portions to each other,

the locking part has a 1 st locking part arranged on one half part and a 2 nd locking part arranged on the other half part and locked with the 1 st locking part, and a plurality of locking surfaces which are opposite surfaces of the 1 st locking part and the 2 nd locking part are formed,

the plurality of retaining surfaces includes at least:

a 1 st locking surface which abuts against the 1 st locking part and the 2 nd locking part when the 1 st locking part and the 2 nd locking part move relatively in a direction of approaching each other; and

and a 2 nd locking surface which abuts when the 1 st locking part and the 2 nd locking part move relatively in a direction of separating from each other.

10. The compressor for an air conditioner for an automobile according to claim 1,

the acoustic enclosure is a honeycomb sandwich panel having a plurality of honeycomb cells with a plurality of openings formed in an inner surface corresponding to the plurality of honeycomb cells.

11. The compressor for an automotive air conditioner according to claim 10, characterized in that the acoustic cover has at least one partition formed in a wall portion along a short-side direction.

Technical Field

The present invention relates to a compressor of an air conditioner for an automobile.

Background

Conventionally, a technique for reducing noise generated by a compressor (compressor r) of an air conditioning apparatus mounted on an automobile is known. For example, patent document 1 discloses a sound insulating device for an electric compressor, which covers the periphery of an electric compressor used in, for example, an air conditioning device for an electric vehicle with a sound insulating cover. The soundproof cover has an insertion hole for inserting a discharge pipe for refrigerant extending from the electric compressor, and a buffer material made of an elastic material such as rubber is disposed around the discharge pipe, whereby a housing of the electric compressor is supported by the soundproof cover via the discharge pipe.

Prior art documents

Patent document

Patent document 1: japanese laid-open patent publication No. 8-61234

Disclosure of Invention

Technical problem to be solved by the invention

Compressors of automotive air conditioners are required to be lightweight and compact in acoustic covers. Therefore, unlike a normal air conditioner, it is not preferable to use a cover having a high sound absorption performance and heavy weight such as rubber. However, the heavier the material used, the more the acoustic enclosure can improve sound insulation performance, and thus the desired sound insulation performance may not be obtained by merely lightening the acoustic enclosure. In particular, if a gap exists between the acoustic cover and a pipe extending from the compressor, there is a possibility that sound leaks from the gap. In the acoustic hood (sound-proof hood) described in patent document 1, a buffer material is disposed around the discharge pipe in order to support the casing of the compressor while suppressing vibration of the casing, but a gap between the acoustic hood and the discharge pipe is not explicitly described. Further, even if the cushion material is supposed to suppress the leakage of sound from the gap between the acoustic cover and the discharge pipe, the structure becomes complicated.

The present invention has been made in view of the above circumstances, and an object of the present invention is to reduce noise of a compressor of an automotive air conditioner by using an acoustic cover having a simpler structure while achieving downsizing and weight reduction of the acoustic cover.

Means for solving the technical problem

In order to solve the above problems and achieve the object, the present invention includes: a compressor main body; a pipe connected to the compressor main body; and an acoustic cover disposed around the compressor body, the acoustic cover having an insertion hole for inserting the pipe and being in close contact with the pipe, and having an inner surface shaped to follow an outer surface of the compressor body.

With this configuration, the inner surface of the acoustic cover is formed into a shape along the outer surface of the compressor main body, and therefore, a gap can be prevented from being formed between the acoustic cover and the compressor main body as much as possible. As a result, the formation of unnecessary portions in the acoustic cover can be suppressed, and the acoustic cover can be made smaller and lighter. Further, since the insertion hole formed in the acoustic cover and into which the pipe connected to the compressor is inserted is in close contact with the pipe, leakage of sound from the gap between the acoustic cover and the pipe can be suppressed. Therefore, according to the present invention, it is possible to reduce the noise of the compressor of the automobile air conditioner by using the acoustic cover having a simpler structure while achieving the reduction in size and weight of the acoustic cover.

Also, the acoustic enclosure is preferably a porous foam material. With this structure, the weight of the acoustic cover can be reduced, and noise generated by the compressor main body can be absorbed by the porous foam material.

Further, the acoustic cover preferably has at least one divided portion formed on a wall portion along the short side direction. With this configuration, in the case of forming the acoustic cover by foam molding, the face provided with the draft angle drawn out from the mold can be made the short side direction side of the acoustic cover. As a result, the length of the surface provided with the draft angle can be shortened, and the formation of an extra space between the compressor and the acoustic cover can be suppressed. Therefore, the acoustic cover can be made smaller and lighter.

Also, the acoustic cover preferably has an overlapping portion where half portions divided by the dividing portion overlap each other at the position of the dividing portion. With this configuration, the half portions can be brought into close contact with each other at the divided portion, and therefore, the sound leakage from the divided portion can be suppressed.

Also, the overlapping portion is preferably a fitting portion that fits the half portions to each other. With this configuration, the half portions can be stably connected to each other and can be brought into close contact with each other, and leakage of sound from the divided portion can be suppressed.

Also, the acoustic cover preferably has a protruding portion protruding from an outer surface at the position of the overlapping portion. With this configuration, the rigidity in the vicinity of the overlapping portion can be increased, and deformation when the acoustic cover is assembled to the compressor main body can be suppressed, so that the assemblability can be improved.

Also, the acoustic cover preferably has an embedded resin material at the position of the overlapping portion. With this configuration, the rigidity in the vicinity of the overlapping portion can be increased, and deformation when the acoustic cover is assembled to the compressor main body can be suppressed, so that the assemblability can be improved.

Also, the compressor main body preferably has a convex portion protruding from the outer surface, and the overlapping portion of the acoustic cover abuts against the convex portion. With this structure, when the acoustic cover is assembled to the compressor main body, the overlapping portion is pressed to the convex portion of the compressor main body, whereby deformation of the overlapping portion can be suppressed. As a result, the assembling property can be improved.

Preferably, the overlapping portion is a locking portion for locking the half portions, and a plurality of locking surfaces are formed on surfaces of the locking portions facing each other, the plurality of locking surfaces including at least: a 1 st locking surface which abuts when the locking parts move relatively in a direction of approaching each other; and a 2 nd locking surface which abuts when the locking parts move relatively in a direction of separating from each other. With this configuration, for example, even when the locking portions are separated from or moved closer to each other by vibration, the 1 st locking surface and the 2 nd locking surface can suppress the formation of a gap between the locking portions.

Also, the acoustic cover is preferably a honeycomb sandwich panel having a plurality of honeycomb cells, which has a plurality of openings formed in the inner surface corresponding to the plurality of honeycomb cells. With this configuration, the weight of the acoustic cover can be reduced, and noise generated by the compressor main body can be absorbed by the plurality of honeycomb chambers. Further, since the honeycomb core has a plurality of openings, noise of a plurality of frequencies can be absorbed by adjusting the opening diameter.

Further, the acoustic cover preferably has at least one divided portion formed on a wall portion along the short side direction. With this configuration, in the case of forming the acoustic cover by foam molding, the face provided with the draft angle drawn out from the mold can be made the short side direction side of the acoustic cover. As a result, the length of the surface provided with the draft angle can be shortened, and the formation of an extra space between the compressor and the acoustic cover can be suppressed. Therefore, the acoustic cover can be further miniaturized and lightened.

Drawings

Fig. 1 is a sectional view showing a compressor according to a first embodiment.

Fig. 2 is an enlarged cross-sectional view showing an example of a structure in the vicinity of a connection portion of a pipe connected to a compressor main body.

Fig. 3 is an enlarged cross-sectional view showing an acoustic cover according to a modification of the first embodiment.

Fig. 4 is a sectional view showing a compressor according to a second embodiment.

Fig. 5 is a sectional view showing a state in which the acoustic cover is attached to the compressor according to the second embodiment.

Fig. 6 is a cross-sectional view showing a compressor as a comparative example.

Fig. 7 is an enlarged cross-sectional view showing an example of the structure in the vicinity of the dividing portion.

Fig. 8 is an enlarged cross-sectional view showing an example of the structure in the vicinity of the dividing portion.

Fig. 9 is an enlarged cross-sectional view showing an example of the structure in the vicinity of the dividing portion.

Fig. 10 is an enlarged cross-sectional view showing an example of the structure in the vicinity of the dividing portion.

Fig. 11 is an enlarged cross-sectional view showing an example of the structure in the vicinity of the dividing portion.

Fig. 12 is an enlarged cross-sectional view showing an example of the structure in the vicinity of the dividing portion.

Fig. 13 is an enlarged cross-sectional view showing an example of the structure in the vicinity of the dividing portion.

Fig. 14 is an enlarged cross-sectional view showing an example of the structure in the vicinity of the dividing portion.

Fig. 15 is an explanatory diagram illustrating an acoustic cover according to a modification of the second embodiment.

Fig. 16 is a plan view showing an acoustic cover according to the third embodiment.

Fig. 17 is a sectional view taken along line a-a of fig. 16.

Fig. 18 is an enlarged sectional view showing the vicinity of an insertion hole of an acoustic cover according to the third embodiment.

Fig. 19 is an enlarged cross-sectional view showing an example of the structure in the vicinity of the dividing section in the third embodiment.

Detailed Description

Hereinafter, embodiments of a compressor of an automotive air conditioner according to the present invention will be described in detail with reference to the accompanying drawings. The present invention is not limited to the present embodiment.

[ first embodiment ]

Fig. 1 is a sectional view showing a compressor according to a first embodiment. The compressor 100 according to the embodiment is a compressor (compressor) for an automotive air conditioner mounted on an automotive air conditioner (not shown). The compressor 100 includes a compressor body 10, a plurality of pipes 20, and an acoustic cover 30. Fig. 1 shows a cross section taken along the longitudinal direction of compressor body 10. The longitudinal direction of the compressor body 10 is the longitudinal direction of the acoustic cover 30, and the short-side direction of the compressor body 10 is the short-side direction of the acoustic cover 30. In the following description, the longitudinal direction of the compressor body 10 and the acoustic cover 30 is simply referred to as "longitudinal direction L1", and the short-side direction of the compressor body 10 and the acoustic cover 30 is simply referred to as "short-side direction L2".

The compressor body 10 is an electric compressor, and a compression mechanism (not shown) such as an electric motor, a fixed scroll, and a movable scroll is housed in a casing. The compressor body 10 compresses the low-pressure refrigerant gas sucked into the casing by the compression mechanism, and discharges the compressed gas to the outside as high-temperature high-pressure gas. The compressor body 10 is disposed in an engine room of an automobile, and is fastened and fixed to a body of the automobile by a bolt, which is a fastening member, at a body mounting portion, not shown.

The plurality of pipes 20 are connected to the outer surface 10A of the compressor main body 10. The piping 20 is, for example, a suction pipe for sucking the refrigerant gas, a discharge pipe for discharging the refrigerant gas, or the like. In fig. 1, only one pipe 20 is shown as an example. Fig. 2 is an enlarged cross-sectional view showing an example of a structure in the vicinity of a connection portion of a pipe connected to a compressor main body. As shown in the drawing, the compressor body 10 is formed with a connection hole 12 communicating with the inside of the pipe 20 at a connection portion 11 of the connection pipe 20. A flange portion 13 protruding from the outer surface 10A is formed around the connection hole 12. The tip of the pipe 20 is fitted to the stepped portion of the flange 13. A connecting block 25 is fixed around the pipe 20, and the connecting block 25 is fastened to the flange portion 13 by a bolt 26. Thus, the pipe 20 is attached to the compressor body 10.

The acoustic cover 30 is disposed around the compressor main body 10. In the first embodiment, the acoustic enclosure 30 is formed of a porous foam material. The acoustic cover 30 is formed by foam molding using the inside of a mold not shown. The acoustic cover 30 reduces noise by converting acoustic energy of noise generated by the compressor main body 10 into thermal energy in a plurality of hollow portions included in the porous foam material, thereby suppressing noise leakage to the outside.

The acoustic cover 30 covers the outer surface 10A of the compressor body 10 in addition to a vehicle body mounting portion, not shown, of the compressor body 10 and a connection portion of a pipe 20, which will be described later. Hereinafter, the outer surface 10A of the compressor body 10 will be described as the outer surface of the portion other than the vehicle body mounting portion of the compressor body 10 and the connection portion of the pipe 20, which are not shown. The acoustic cover 30 is fastened and fixed to the compressor body 10 at a body mounting portion not shown, for example, by bolts.

As shown in fig. 1, the acoustic cover 30 has an inner surface 30A that follows the shape of the outer surface 10A of the compressor body 10. In other words, the inner surface 30A of the acoustic cover 30 is formed in the same shape as the outer surface 10A of the compressor main body 10 in such a size as to cover the outer surface 10A. As a result, the gap S1 formed between the inner surface 30A of the acoustic cover 30 and the outer surface 10A of the compressor main body 10 can be reduced as much as possible. Further, the inner surface 30A of the acoustic cover 30 may be brought into contact with the outer surface 10A of the compressor body 10 to prevent the gap S1 from being formed. Like the inner surface 30A, the outer surface 30B of the acoustic cover 30 has a shape along the outer surface 10A of the compressor body 10. The outer surface 30B may be designed to reduce the weight of the compressor main body 10 to which the acoustic cover 30 is attached and to avoid interference with components disposed around the compressor main body 10.

As shown in fig. 1, the acoustic cover 30 has an insertion hole 31 into which the pipe 20 connected to the compressor body 10 is inserted. The insertion hole 31 is formed at all positions corresponding to the pipe 20, although not shown, similarly to the pipe 20. As shown in fig. 2, the acoustic cover 30 has an annular inclined portion 32 extending toward the insertion hole 31 toward the inside (the compressor body 10 side) of the acoustic cover 30 around the insertion hole 31. The inner peripheral surface 31A of the insertion hole 31 is the inner peripheral surface of the annular inclined portion 32. In the annular inclined portion 32, the inner peripheral surface 31A of the insertion hole 31 is fitted to the flange portion 13 provided in the connecting portion 11 and the connecting block 25. That is, the inner circumferential surface 31A of the insertion hole 31 is indirectly in close contact with the pipe 20 via the flange portion 13 and the connecting block 25. This can prevent a gap from being formed between the insertion hole 31 and the pipe 20. As shown in fig. 2, an inner surface 30A of the terminal end portion of the annular inclined portion 32 abuts against an outer surface 10A of the compressor main body 10. This allows the acoustic cover 30 to be stably attached to the periphery of the pipe 20 (the periphery of the connection portion 11).

Fig. 3 is an enlarged cross-sectional view showing an acoustic cover according to a modification of the first embodiment. The acoustic cover 40 according to the modification includes a cylindrical portion 42 instead of the annular inclined portion 32 of the acoustic cover 30. Other structures of the acoustic cover 40 are the same as those of the acoustic cover 30, and therefore, descriptions of the same structures are omitted and the same reference numerals are given. The cylindrical portion 42 of the acoustic cover 40 protrudes cylindrically toward the inside of the acoustic cover 40 (the compressor body 10 side) and the outside of the acoustic cover 40 (the side opposite to the compressor body 10) around the insertion hole 31. The inner peripheral surface 31A of the insertion hole 31 is the inner peripheral surface of the cylindrical portion 42. As in the example shown in fig. 2, the inner peripheral surface 31A of the insertion hole 31 is fitted to the flange 13 provided in the connecting portion 11 and the connecting block 25. That is, the inner circumferential surface 31A of the insertion hole 31 is indirectly in close contact with the pipe 20 via the flange portion 13 and the connecting block 25. This can prevent a gap from being formed between the insertion hole 31 and the pipe 20. As shown in fig. 3, the inner surface 30A of the cylindrical portion 42 abuts against the outer surface 10A of the compressor main body 10. This allows the acoustic cover 30 to be stably attached to the periphery of the pipe 20 (the periphery of the connection portion 11).

As described above, the compressor 100 according to the first embodiment includes: a compressor main body 10; a pipe 20 connected to the compressor body 10; and an acoustic cover 30 disposed around the compressor body 10, wherein the acoustic cover 30 has an insertion hole 31 into which the pipe 20 is inserted and which is in close contact with the pipe 20, and has an inner surface 30A that is shaped to follow the outer surface 10A of the compressor body 10.

With this configuration, since the inner surface 30A of the acoustic cover 30 is formed in a shape along the outer surface 10A of the compressor main body 10, the formation of the gap S1 between the acoustic cover 30 and the compressor main body 10 can be prevented as much as possible. As a result, the formation of unnecessary portions in the acoustic cover 30 can be suppressed, and the acoustic cover 30 can be reduced in size and weight. Further, since the insertion hole 31 formed in the acoustic cover 30 and into which the pipe 20 connected to the compressor body 10 is inserted is in close contact with the pipe 20, leakage of sound from the gap between the acoustic cover 30 and the pipe 20 can be suppressed as indicated by the solid arrow in fig. 2. Therefore, according to the first embodiment, the acoustic cover 30 can be made smaller and lighter, and the noise of the compressor 100 of the automotive air conditioner can be reduced using the acoustic cover 30 having a simpler structure.

In the present embodiment, as shown in fig. 2 and 3, the pipe 20 is fixed to the compressor body 10 at the connecting portion 11 by the flange portion 13 and the connecting block 25, and the insertion hole 31 of the acoustic cover 30 indirectly comes into close contact with the pipe 20 via the flange portion 13 and the connecting block 25. However, the method of fixing the pipe 20 to the compressor body 10 is not limited to this, and the insertion hole 31 of the acoustic cover 30 may be directly in close contact with the pipe 20.

Also, the acoustic enclosure 30 is a porous foam material. With this structure, the acoustic cover 30 can be made lightweight, and noise generated by the compressor main body 10 can be absorbed by the porous foam material.

[ second embodiment ]

Next, a compressor 200 according to a second embodiment will be described. Fig. 4 is a sectional view showing a compressor according to a second embodiment, fig. 5 is a sectional view showing a state where an acoustic cover is attached to the compressor according to the second embodiment, and fig. 6 is a sectional view showing a compressor as a comparative example.

The compressor 200 according to the second embodiment includes the acoustic cover 50 instead of the acoustic cover 30 of the compressor 100. The compressor 300 as a comparative example includes the acoustic cover 60 instead of the acoustic cover 30 of the compressor 100. Since other configurations of the compressors 200 and 300 are the same as those of the compressor 100, the same configurations will be omitted from description and the same reference numerals will be given. In addition, as in fig. 1, fig. 4 to 6 show a cross section taken along the longitudinal direction L1. In fig. 4 to 6, although the pipe 20 is not shown, the insertion hole for inserting the pipe 20 is directly or indirectly in close contact with the pipe 20 in the acoustic covers 50 and 60, as in the first embodiment.

As shown in fig. 4 and 5, the acoustic cover 50 is divided into two halves 51 and 52 by the dividing portions 50A and 50B. As shown in fig. 5, the half portions 51 and 52 are disposed around the compressor body 10 so as to face each other, and are fastened to each other near the divided portions 50A and 50B by, for example, bolts. As shown in the drawing, the divided portions 50A and 50B are provided on a wall portion along the short side direction L2 of the acoustic cover 30. In other words, the divided portions 50A and 50B extend in the direction along the longitudinal direction L1. Further, "extending along the longitudinal direction L1" may mean being inclined with respect to the longitudinal direction L1. In the present embodiment, the divided parts 50A and 50B are formed at positions aligned in the short side direction L2, but the divided parts 50A and 50B may be formed at positions distant from each other in the short side direction L2.

As shown in fig. 4, half portion 51 of acoustic cover 50 has inclined portion 511 extending outward (opposite side to compressor body 10) of acoustic cover 50 as it goes toward divided portion 50A. Half portion 51 has inclined portion 512 extending outward of acoustic cover 50 (opposite side to compressor body 10) as it goes toward divided portion 50B. Similarly, as shown in fig. 4, half portion 52 of acoustic cover 50 has inclined portion 521 extending outward (opposite side to compressor body 10) of acoustic cover 50 as it goes toward divided portion 50A. Half portion 52 has inclined portion 522 extending outward of acoustic cover 50 (opposite side to compressor body 10) as it goes toward divided portion 50B.

The inclined portions 511, 512, 521, 522 provided in the half portions 51, 52 are formed at an angle of a draft angle θ for drawing the half portions 51, 52 out of a mold not shown when the acoustic cover 30 is foam-molded. That is, the inclined portions 511, 512, 521, and 522 extend obliquely at the draft angle θ with respect to the short side direction L2. The draft angle θ of the inclined portions 511, 512, 521, and 522 may be set to a value that allows the half portions 51 and 52 to be drawn out from the mold and reduces the gap S2 described later as much as possible, and may be different for each of the inclined portions 511, 512, 521, and 522. The divided parts 50A, 50B that divide the half parts 51, 52 are provided in the wall portion along the short side direction L2 of the acoustic cover 30, and therefore the inclined portions 511, 512, 521, 522 are also provided in the wall portion along the short side direction L2 of the acoustic cover 30.

Here, as shown in fig. 6, in the acoustic cover 60 included in the compressor 300 of the comparative example, the split portions 50A and 50B that split the half portions 51 and 52 are provided in the wall portion along the longitudinal direction L1 of the acoustic cover 60. That is, in the acoustic cover 60, the inclined portions 511, 512, 521, and 522 are formed in the wall portion along the longitudinal direction L1. Other structures of the acoustic cover 60 are the same as those of the acoustic cover 50, and therefore, descriptions of the same structures are omitted and the same reference numerals are given.

As shown in fig. 4 and 6, the inclined portions 511, 512, 521, and 522 of the acoustic cover 50 provided on the wall portion along the short side direction L2 are shorter than the acoustic cover 60 in length. Thus, the gap S2 between the acoustic cover 50 and the compressor main body 10 in the compressor 200 according to the second embodiment is smaller than the gap S3 between the acoustic cover 60 and the compressor main body 10 in the compressor 300 according to the comparative example. Therefore, it is possible to suppress the formation of an extra space between the compressor body 10 and the acoustic cover 50, and to achieve the reduction in size and weight of the acoustic cover 50 as compared with the acoustic cover 60 of the comparative example.

Next, the structure of the dividing portions 50A and 50B will be described with reference to fig. 7 to 11. Fig. 7 to 11 are enlarged cross-sectional views showing an example of the structure in the vicinity of the dividing portion. In the example shown in fig. 7, the half portions 51, 52 have overlapping portions 53 that overlap each other side by side in the direction along the longitudinal direction L1 at the positions of the divided portions 50A, 50B. With this configuration, the half portions 51 and 52 can be brought into close contact with each other at the divided portions 50A and 50B, and therefore, the sound leakage from the divided portions 50A and 50B can be suppressed.

In the example shown in fig. 8, the above-described overlapping portion 53 becomes a fitting portion 54 that fits the half portions 51, 52 to each other. With this configuration, the half portions 51 and 52 can be stably connected to each other, and the half portions 51 and 52 can be brought into close contact with each other, whereby sound leakage from the divided portions 50A and 50B can be suppressed.

In the example shown in fig. 9, the half parts 51, 52 have a projection 55 projecting from the outer surface at the position of the overlap 53. With this configuration, the rigidity in the vicinity of the overlapping portion 53 can be increased, and deformation when the acoustic cover 50 is assembled to the compressor body 10 can be suppressed, so that the assemblability can be improved.

In the example shown in fig. 10, the half portions 51, 52 have an embedded resin material 56 at the position of the overlapping portion 53. With this configuration, the rigidity in the vicinity of the overlapping portion 53 can be increased, and deformation when the acoustic cover 50 is assembled to the compressor body 10 can be suppressed, so that the assemblability can be improved.

In the example shown in fig. 11, the overlapping portion 53 of the half portions 51, 52 is provided at a position abutting against the convex portion 15 formed on the compressor main body 10. The projection 15 is a portion protruding from the outer surface 10A of the compressor body 10. With this structure, when the acoustic cover 50 is assembled to the compressor main body 10, the overlapped part 53 is pressed to the convex part 15 of the compressor main body 10 from the state shown in fig. 11, whereby deformation of the overlapped part 53 can be suppressed. As a result, the assembling property of the acoustic cover 50 can be improved.

In the example shown in fig. 12, the above-mentioned overlapping portion 53 becomes a catching portion that catches the half portions 51, 52 to each other. The locking part has a 1 st locking part 57 provided on one side (upper side) half part 51 and a 2 nd locking part 58 provided on the other side (lower side) half part 52. The 1 st locking portion 57 and the 2 nd locking portion 58 are aligned in the direction along the longitudinal direction L1 and overlap each other. The 1 st locking portion 57 is located outside the acoustic cover 50 with respect to the 2 nd locking portion 58. In other words, the 2 nd locking portion 58 is located inside the acoustic cover 50 with respect to the 1 st locking portion 57. The 2 nd locking portion 58 is locked to the 1 st locking portion 57. The 1 st locking portion 57 and the 2 nd locking portion 58 have a plurality of locking surfaces 60 formed on the surfaces of the 1 st locking portion 57 and the 2 nd locking portion 58 facing each other.

The plurality of locking surfaces 60 includes a 1 st locking surface 60a and a 2 nd locking surface 60 b. The 1 st locking surface 60a is a locking surface 60 which abuts when the 1 st locking part 57 and the 2 nd locking part 58 move relatively in a direction to approach each other. The 1 st locking surface 60a is formed at a position located on both sides in the longitudinal direction L1. The 1 st locking surface 60a is a surface along the longitudinal direction L1. The first locking surface 60a on the inner side of the acoustic cover 50 is formed at a position on the half 51 side (upper side) in the short direction L2, and the first locking surface 60a on the outer side of the acoustic cover 50 is formed at a position on the half 52 side (lower side) in the short direction L2.

The 2 nd locking surface 60b is a locking surface 60 which abuts when the 1 st locking part 57 and the 2 nd locking part 58 are relatively moved in a direction away from each other. The 2 nd locking surface 60b is formed at a position between the 1 st locking surfaces 60a on both sides in the longitudinal direction L1. The 2 nd locking surface 60b is a surface along a direction in which the 1 st locking portion 57 and the 2 nd locking portion 58 face each other. Both sides of the 2 nd engaging surface 60b are connected to the 1 st engaging surfaces 60a on both sides, respectively. The 2 nd locking surface 60b is inclined inward in the longitudinal direction L1 from the 1 st locking portion 57 toward the 2 nd locking portion 58.

The surface of the 1 st locking part 57 facing the 2 nd locking part 58 is a continuous surface in which the 1 st locking surface 60a and the 2 nd locking surface 60b on both sides are continuous, and has a Z-shaped cross section. The surface of the 1 st locking part 57 facing the 2 nd locking part 58 may be a discontinuous surface in which the 1 st locking surface 60a and the 2 nd locking surface 60b are discontinuous. That is, the connecting portion between the 1 st locking surface 60a and the 2 nd locking surface 60b may be curved.

In the example shown in fig. 12, when the 1 st locking part 57 and the 2 nd locking part 58 are relatively moved in the direction of approaching each other, the 1 st locking surfaces 60a on both sides in the longitudinal direction L1 abut on each other to close the gap between the half parts 51 and 52. On the other hand, when the 1 st locking portion 57 and the 2 nd locking portion 58 are relatively moved in the direction of separating from each other, the 2 nd locking surface 60b at the center in the longitudinal direction L1 abuts against each other to close the gap between the half portions 51 and 52. With this configuration, even when the half portions 51 and 52 vibrate with each other, it is possible to suppress the formation of a gap between the half portions 51 and 52 and to suppress the leakage of sound from the divided portions 50A and 50B.

In the example shown in fig. 13, the 1 st locking part 57 and the 2 nd locking part 58 in the example shown in fig. 12 are different in shape. That is, in fig. 13, the plurality of locking surfaces 63 formed on the surfaces of the 1 st locking portion 57 and the 2 nd locking portion 58 facing each other are different from those in fig. 12.

The plurality of locking surfaces 63 include a 1 st locking surface 63a and a 2 nd locking surface 63 b. As in fig. 12, the 1 st locking surface 63a is a locking surface 63 which the 1 st locking part 57 and the 2 nd locking part 58 abut against when they are relatively moved in a direction in which they approach each other. The 1 st locking surface 63a is formed at a position located on both sides in the longitudinal direction L1. The 1 st locking surface 63a is a surface along the longitudinal direction L1. The first locking surface 63a on the inner side of the acoustic cover 50 is formed at a position on the half 51 side (upper side) in the short direction L2, and the first locking surface 63a on the outer side of the acoustic cover 50 is formed at a position on the half 52 side (lower side) in the short direction L2.

Similarly to fig. 12, the 2 nd locking surface 63b is a locking surface 63 which abuts when the 1 st locking part 57 and the 2 nd locking part 58 are relatively moved in a direction to separate from each other. The 2 nd locking surface 63b is formed at a position between the 1 st locking surfaces 63a on both sides in the longitudinal direction L1. The 2 nd locking surface 63b is a surface along the longitudinal direction L1. The 2 nd locking surface 63b is formed at a position between the 1 st locking surfaces 63a on both sides in the direction in which the 1 st locking portion 57 faces the 2 nd locking portion 58. Therefore, the 2 nd locking surface 63b is a surface parallel to the 1 st locking surface 63a on both sides. Both sides of the 2 nd locking surface 63b are connected to the 1 st locking surfaces 63a on both sides via connecting surfaces, respectively.

The surface of the 1 st locking part 57 facing the 2 nd locking part 58 is a discontinuous surface with discontinuous 1 st locking surface 63a, 2 nd locking surface 63b and connecting surface on both sides, and has a rectangular cross section.

In the example shown in fig. 13, when the 1 st locking part 57 and the 2 nd locking part 58 are relatively moved in the direction of approaching each other, the 1 st locking surfaces 63a on both sides in the longitudinal direction L1 abut on each other to close the gap between the half parts 51 and 52. On the other hand, when the 1 st locking part 57 and the 2 nd locking part 58 are moved relatively in a direction away from each other, the gap between the half parts 51 and 52 is closed by the center 2 nd locking surface 63b in the longitudinal direction L1 coming into contact with each other. With this configuration, even when the half portions 51 and 52 vibrate with each other, it is possible to suppress the formation of a gap between the half portions 51 and 52 and to suppress the leakage of sound from the divided portions 50A and 50B.

In the example shown in fig. 14, the 1 st locking part 57 and the 2 nd locking part 58 in the example shown in fig. 12 are different in shape. That is, in fig. 14, the plurality of locking surfaces 65 formed on the surfaces of the 1 st locking portion 57 and the 2 nd locking portion 58 facing each other are different from those in fig. 12.

The plurality of locking surfaces 65 include a 1 st locking surface 65a and a 2 nd locking surface 65 b. The 1 st locking surface 65a is the same as the 1 st locking surface 60a in fig. 12, and therefore, the description thereof is omitted.

Similarly to fig. 12, the 2 nd locking surface 65b is a locking surface 65 which the 1 st locking part 57 and the 2 nd locking part 58 abut against when they are relatively moved in a direction to separate from each other. The 2 nd locking surface 65b is a surface continuous with the 1 st locking surface 65a formed on the 1 st locking portion 57 side. The 2 nd locking surface 65b and the 1 st locking surface 65a which are continuous are partially continuous surfaces having a semicircular cross section. The 2 nd locking surface 65b is connected to the 1 st locking surface 65a formed on the 2 nd locking portion 58 side via a connecting surface.

The surface of the 1 st locking portion 57 facing the 2 nd locking portion 58 is a continuous surface in which the 1 st locking surface 65a and the 2 nd locking surface 65b on the 1 st locking portion 57 side are continuous so as to have a semicircular shape in cross section, and is a discontinuous surface in which the connecting surface and the 1 st locking surface 65a on the 2 nd locking portion 58 side are discontinuous so as to have an L-shaped cross section.

In the example shown in fig. 14, when the 1 st locking part 57 and the 2 nd locking part 58 are relatively moved in the direction of approaching each other, the 1 st locking surfaces 65a on both sides in the longitudinal direction L1 abut on each other to close the gap between the half parts 51 and 52. On the other hand, when the 1 st locking part 57 and the 2 nd locking part 58 are relatively moved in a direction away from each other, the 2 nd locking surface 65b having a semicircular cross section abuts on each other to close the gap between the half parts 51 and 52. With this configuration, even when the half portions 51 and 52 vibrate with each other, it is possible to suppress the formation of a gap between the half portions 51 and 52 and to suppress the leakage of sound from the divided portions 50A and 50B.

Fig. 15 is an explanatory diagram illustrating an acoustic cover according to a modification of the second embodiment. As shown in the drawing, in the acoustic cover 70 according to the modification of the second embodiment, the half portions 51 and 52 are not completely divided. The acoustic cover 70 has a divided portion 50A in a wall portion along the short side direction L2 on one side, but has a cutout portion 50C and a joint portion 50D in place of the divided portion 50B in a wall portion along the short side direction L2 on the other side. The notch 50C is provided on the inner surface 30A side of a wall portion along the other short side direction L2. The half portions 51 and 52 are connected to each other at a joint portion 50D on the side of the cutout portion 50C.

The acoustic cover 70 can be deformed so that the half portions 51 and 52 open on the side of the divided portion 50A with the joining portion 50D located at the side of the cutout portion 50C as a base point. Therefore, as shown in fig. 15, in a state where the half portions 51 and 52 are open on the side of the divided part 50A, for example, the half portion 52 is disposed around the compressor body 10, and then the half portion 51 is disposed around the compressor body 10 so as to close the divided part 50A, the acoustic cover 70 can be attached to the compressor body 10. In the acoustic cover 70, the inclined portions 511, 512, 521, and 522 are also provided in the wall portion along the short side direction L2. Therefore, like the acoustic cover 50 shown in fig. 4, the gap S2 between the acoustic cover 70 and the compressor main body 10 can be made smaller than the gap S3 between the acoustic cover 60 and the compressor main body 10 in the compressor 300 of the comparative example. Therefore, it is possible to suppress the formation of an extra space between the compressor body 10 and the acoustic cover 70, and to achieve the reduction in size and weight of the acoustic cover 70 as compared with the acoustic cover 60 of the comparative example.

[ third embodiment ]

Next, the acoustic cover 80 provided in the compressor according to the third embodiment will be described. The compressor according to the third embodiment has the same configuration as the first and second embodiments except that the compressor includes the acoustic cover 80 instead of the acoustic covers 30, 40, 50, and 70, and therefore, illustration and description of the parts other than the acoustic cover 80 are omitted. In the first and second embodiments, the acoustic covers 30, 40, 50, 70 are formed of a porous foam material. In the third embodiment, the acoustic cover 80 is formed of a honeycomb sandwich panel. Fig. 16 is a plan view showing the acoustic cover according to the third embodiment, and fig. 17 is a cross-sectional view taken along the line a-a of fig. 16.

As shown in fig. 17, the acoustic cover 80 has a surface sheet 81, a back sheet 82, and a plurality of honeycomb walls 83. The front sheet 81, the back sheet 82, and the honeycomb walls 83 can be formed by press molding, for example, a plastic material using a press die, not shown. The front sheet 81 and the back sheet 82 are disposed to face each other. The surface sheet 81 forms an inner surface 80A of the acoustic cover 80. Also, the back sheet 82 forms an outer surface 80B of the acoustic cover 80. A plurality of honeycomb walls 83 extend between the surface sheet 81 and the back sheet 82. As shown in fig. 16, the plurality of honeycomb walls 83 form partition walls having a hexagonal cross section between the front sheet 81 and the back sheet 82.

Thus, the front sheet 81, the honeycomb walls 83, and the back sheet 82 define a plurality of honeycomb cells 85 as hexagonal columnar spaces. An opening 85A is formed in the top sheet 81 at a position corresponding to the center of each honeycomb cell 85. The opening 85A is a through-hole penetrating the surface sheet 81. With this configuration, air vibration of sound generated by the compressor main body 10 proceeds inside the honeycomb chamber 85 through the opening 85A, and the air vibration resonates at a predetermined resonant frequency f (see the following expression (1)), whereby pressure fluctuation is attenuated, and noise is absorbed.

Openings provided in the respective honeycomb chambers 8585A is determined by the following equation (1) based on the Helmholtz equation. In the formula (1), "f" represents a resonance frequency, "c" represents a sound velocity, "V" represents a volume of the honeycomb chamber, and "t" represents a volume of the honeycomb chamber_s"is the thickness of the surface sheet 81. Therefore, if the value of the desired resonance frequency f to be attenuated is determined, the aperture radius a can be obtained from equation (1). In addition, the value of the desired resonance frequency f may be determined according to the frequency of noise generated by, for example, a scroll provided to the compressor body 10. In other words, by adjusting the opening radius a for each of the plurality of openings 85A, noise at a plurality of frequencies can be absorbed.

f＝c/2π·SQRT(πa²/V(t_s+0.6a))……(1)

In the third embodiment, as in the first and second embodiments, the insertion hole 31 for inserting the pipe 20 in the acoustic cover 80 is also in direct or indirect contact with the pipe 20. Fig. 18 is an enlarged sectional view showing the vicinity of an insertion hole of an acoustic cover according to the third embodiment. The acoustic cover 80 is a honeycomb sandwich panel, and therefore, compared with the case of the porous foam material, no face is formed at the end where the insertion holes 31 are formed. Therefore, in the third embodiment, as shown in fig. 18, the contact member 91 forming the contact surface is disposed at the end portion where the insertion hole 31 is formed. That is, the abutment member 91 forms the inner circumferential surface 31A of the insertion hole 31. The contact member 91 is, for example, a vibration damping sheet. Thus, as in the first and second embodiments, the insertion hole 31 for inserting the pipe 20 can be indirectly brought into close contact with the pipe 20.

In the third embodiment, as long as the acoustic cover 80 is also divided into the two half portions 51 and 52 (see fig. 4) by the dividing portions 50A and 50B (see fig. 4) and the inclined portions 511, 512, 521, and 522 (see fig. 4) are also provided in the wall portion along the short side direction L2, it is possible to suppress the formation of an extra space between the compressor body 10 and the acoustic cover 80, as in the second embodiment. This makes it possible to reduce the size and weight of the acoustic cover 80 as compared with the acoustic cover 60 of the comparative example. In addition, in the third embodiment, since the acoustic cover 80 is manufactured by press molding, the inclined portions 511, 512, 521, 522 are formed to have the draft angle θ drawn out from the die.

However, the acoustic cover 80 is a honeycomb sandwich panel, and therefore it is not easy to provide the overlapping portion 53 as shown in fig. 7 to 14 at the divided portions 50A, 50B. Therefore, the acoustic cover 80 is connected to the divided portions 50A and 50B by the structure described below. Fig. 19 is an enlarged cross-sectional view showing an example of the structure in the vicinity of the dividing section in the third embodiment. As shown in the drawing, the acoustic cover 80 has, at the divided portions 50A and 50B, contact members 92 disposed between the front sheet 81 and the back sheet 82 of the half portion 51 and the front sheet 81 and the back sheet 82 of the half portion 52. The contact member 92 is, for example, a vibration damping sheet. This enables the half portions 51 and 52 to be brought into close contact with each other at the divided portions 50A and 50B, and thus, leakage of sound from the divided portions 50A and 50B can be suppressed.

In the first and second embodiments, the acoustic covers 30, 40, 50, 70 are formed of a porous foam material, and in the third embodiment, the acoustic cover 80 is formed of a honeycomb sandwich panel having a plurality of honeycomb cells 85. However, it is also possible to form one part of the acoustic enclosure from a cellular foam material and the other part from a honeycomb sandwich panel. Accordingly, if the structure of the acoustic cover is appropriately selected according to the type of noise generated by the compressor body 10, a plurality of noises can be absorbed more appropriately. For example, a honeycomb sandwich panel may be disposed near the scroll of the compressor body 10, and a porous foam material may be disposed in other portions. Thereby, fluid sound (mainly low frequency) generated by the scroll can be absorbed well by adjusting the desired resonance frequency f with the honeycomb sandwich panel, and other sliding sound or sound (mainly high frequency) generated by the electric motor can be absorbed by the porous foam material.

Description of the symbols

10-compressor body, 10A-outer surface, 11-connecting part, 12-connecting hole, 13-flange part, 15-convex part, 20-piping, 25-connecting block, 26-bolt, 30, 40, 50, 60, 70, 80-acoustic cover, 30A, 80A-inner surface, 30B, 80B-outer surface, 31-insertion hole, 31A-inner peripheral surface, 32-annular inclined part, 42-cylindrical part, 50A, 50B-dividing part, 50C-notch part, 50D-joining part, 51, 52-half part, 53-overlapping part, 54-fitting part, 55-protruding part, 56-resin material, 57-1 st locking part, 58-2 nd locking part, 60, 63, 65-locking surface, 81-surface sheet, 82-back sheet, 83-honeycomb walls, 85-honeycomb cells, 85A-openings, 91, 92-abutment member, 100, 200, 300-compressor, 511, 512, 521, 522-ramp, S1, S2, S3-gap.