JP6145734B2 - Electric compressor - Google Patents

Description

  The present invention relates to an electric compressor provided with a housing incorporating a compression mechanism section, an electric motor section that drives the compression mechanism section, and an inverter section that drives the electric motor section.

  In recent years, there has been proposed an electric compressor in which an inverter unit that drives and controls an electric motor unit is fixed integrally with a compression mechanism unit and the electric motor unit (see, for example, Patent Document 1).

JP 2002-191153 A

  In such an electric compressor, as one of means for preventing the exposure of the high voltage portion against an impact load caused by a vehicle collision or the like, increasing the strength of the electric compressor itself by increasing the thickness of the casing or changing the material. Are known.

  However, increasing the thickness of the housing or changing the material increases the weight, outer shape, and cost of the electric compressor itself, leading to a reduction in product power.

  The present invention solves the above-described problems, and provides an electric compressor capable of preventing exposure of a high-voltage portion against an impact load without causing an increase in the weight, outer shape, and cost of the electric compressor. Objective.

  In order to solve the above-described conventional problems, the electric compressor of the present invention includes an impacted portion that receives an external impact on the surface of the housing, and the impacted portion includes the electric motor portion. This is provided only in the portion other than the portion and the portion incorporating the inverter portion.

  Thereby, it is possible to prevent the exposure of the high voltage portion based on the impact load without increasing the weight, the outer shape, and the cost of the electric compressor.

  The electric compressor of the present invention can prevent the exposure of the high voltage portion based on the impact load without causing an increase in the weight, outer shape, and cost of the electric compressor.

Sectional drawing of the compressor in Embodiment 1 of this invention External view of the compressor in Embodiment 1 of this invention External view of the compressor in Embodiment 2 of this invention

DESCRIPTION OF SYMBOLS 1 Electric compressor 2 Mounting leg 3 Main container 3a Compression mechanism part side opening part 3b Electric motor side opening part 3c End part wall 3d Impacted part 4 Compression mechanism part 5 Electric motor 5a Stator 5b Rotor 5c Lead wire 6 Suction sub Container 7 Discharge secondary container 8 Inverter 9 Filter
DESCRIPTION OF SYMBOLS 10 Fixed scroll 10a Concave part 11 Orbiting scroll 11a Orbiting scroll end plate 11b Restriction 11d Tube part 12 Compression space 13 Drive shaft 13a Eccentric shaft 14 Suction port 15 Discharge port 16 Liquid storage part 17 Lubricating oil 18 Gear pump 19 Oil supply path 20 Liquid reservoir 21 Back Pressure chamber 22 Main bearing 23 Sub bearing 24 Eccentric bearing 25 Main bearing member 26 Pump plate 27 Oil reservoir chamber 28 Oil suction passage 29 Oldham ring 30 Bush 31 Connection passage 40 Terminal 41 Metal terminal 42 Cluster block

  According to a first aspect of the present invention, there is provided an electric compressor including a casing including a compression mechanism section, an electric motor section that drives the compression mechanism section, and an inverter section that drives the electric motor section. It is provided on the surface of the body, and the impacted part is provided only in a part other than the part in which the electric motor part is incorporated and the part in which the inverter part is incorporated. Even if the container outside the region of the high voltage part is damaged, exposure of the high voltage part can be prevented.

  According to a second invention, in the first invention, the impacted portion is configured in a boss shape, whereby an increase in weight can be further suppressed.

  In a third aspect based on the first aspect, the housing includes a main container that houses the compression mechanism section and the electric motor section, and a sub-container section that houses the inverter section.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments.
(Embodiment 1)
FIG. 1 shows a cross-sectional view of an electric compressor according to a first embodiment of the present invention. In FIG. 1, one example of a horizontal electric compressor installed sideways by a mounting leg 2 around the trunk of the electric compressor 1 is shown.

  The electric compressor 1 has a compression mechanism section 4 and an electric motor 5 that drives the compression mechanism section 4 in its main container 3. The suction sub-container 6 and the discharge sub-container 7 are mounted on the compression mechanism section side opening 3a and the electric motor side opening 3b of the main container 3 so as to face the openings 3a and 3b, respectively, thereby forming a sealed container. . An inverter 8 that drives the electric motor 5 is built in the suction sub-container 6. The discharge sub-container 7 is provided with an oil sump chamber 27 that supplies liquids for lubrication of the sliding portions including the compression mechanism portion 4, the main bearing 22, the sub-bearing 23, and the eccentric bearing 24.

  The refrigerant to be handled is a gas refrigerant. A liquid such as the lubricating oil 17 is used as a liquid to be used for lubrication of the sliding portions and the bearings 22, 23, and 24 and a seal of the sliding portion of the compression mechanism portion 4. The lubricating oil 17 is compatible with the refrigerant.

  The compression mechanism unit 4 of the electric compressor 1 according to the present embodiment is of a scroll type as an example, and a compression space 12 is formed by meshing the fixed scroll 10 and the orbiting scroll 11 as shown in FIG. Has been. The orbiting scroll 11 is revolved by the electric motor 5 via the drive shaft 13 with respect to the fixed scroll 10 and the volume of the compression space 12 is changed, whereby the refrigerant returning from the external cycle is sucked and compressed. Then, the discharge to the external cycle is performed through the suction port 14 provided in the suction sub-container 6 and the discharge port 15 provided in the discharge sub-container 7.

  At the same time, the lubricating oil 17 stored in the liquid storage part 16 of the discharge sub-container 7 drives the gear pump 18 or the like with the drive shaft 13 or uses the differential pressure in the main container 3. Then, the oil is introduced into the oil sump chamber 27. Then, as the orbiting scroll 11 is driven to rotate through the oil supply passage 19 of the drive shaft 13 through the filter 9, it is supplied to the liquid reservoir 20 on the back surface of the orbiting scroll 11. The part is supplied to the back pressure chamber 21 opposite to the lap on the outer peripheral part of the orbiting scroll 11 through the orbiting scroll end plate 11a based on a predetermined restriction by the diaphragm 11b or the like. Further, by supplying through a communication hole (not shown) provided in the orbiting scroll 11 to the recess 10a provided in the fixed scroll 10, the back pressure is adjusted to a predetermined amount, and the orbiting scroll 11 is pressed and backed up for lubrication. Oil 17 is supplied between the fixed scroll 10 and the orbiting scroll 11 to achieve sealing and lubrication between the fixed scroll 10 and the orbiting scroll 11. Further, another part of the lubricating oil 17 supplied to the liquid reservoir 20 is lubricated while passing through the eccentric bearing 24 and the main bearing 22, then flows out to the electric motor 5 side and is collected in the liquid storage unit 16.

  Further, a main bearing member 25 having a sub bearing 23, an electric motor 5, and a main bearing 22 is arranged from the end wall 3 c side of the electric motor side opening 3 b in the main container 3. An oil reservoir chamber that houses the gear pump 18 on the outer surface of the end wall 3c and holds the gear pump 18 with a pump plate 26 attached by bolts (not shown) and communicates with the liquid storage section 16 inside the discharge sub-container 7. 27 is formed so as to communicate with the liquid storage section 16 through the oil suction passage 28.

  The sub-bearing 23 is supported by the end wall 3c and supports the side of the drive shaft 13 connected to the gear pump 18. The electric motor 5 fixes the stator 5 a to the inner periphery of the main container 3 by bolts or shrink fitting, and the drive shaft 13 can be rotationally driven by the rotor 5 b fixed around the drive shaft 13. . The main bearing member 25 is inserted or press-fitted into the main container 3, and the compression mechanism portion 4 side of the drive shaft 13 is supported by the main bearing 22. The fixed scroll 10 is attached to the outer surface of the main bearing member 25 with a bolt or the like (not shown), and the orbiting scroll 11 is sandwiched between the main bearing member 25 and the fixed scroll 10 to constitute a scroll compressor.

  An Oldham ring 29 is provided between the main bearing member 25 and the orbiting scroll 11 to prevent the orbiting scroll 11 from rotating and to orbit. An eccentric shaft 13a is integrally formed on the end surface of the drive shaft 13, and a bush 30 is fitted and supported on the eccentric shaft 13a. The orbiting scroll 11 is supported on the bush 30 via an eccentric bearing 24 so as to be capable of orbiting movement so as to face the fixed scroll 10. A cylindrical portion 11d protrudes from the rear surface of the orbiting scroll end plate 11a of the orbiting scroll 11, and the eccentric bearing 24 is accommodated in the cylindrical portion 11d. The inner ring of the eccentric bearing 24 is fitted into the bush 30 and the outer ring of the eccentric bearing 24 is fitted into the cylindrical portion 11d.

  The compression mechanism unit 4 is covered with a suction sub-container 6 which is fixed to a main container 3 and openings by a bolt (not shown). The compression mechanism unit 4 is located between the suction port 14 of the suction sub-container 6 and the discharge port 15 of the discharge sub-container 7, and its own suction hole (not shown) is connected to the suction port 14 of the suction sub-container 6 through the suction passage. A discharge hole (not shown) opens into the discharge chamber via a reed valve. The discharge chamber communicates with the electric motor 5 between the compression mechanism portion 4 and the end wall 3c through the fixed scroll 10 and the main bearing member 25 or a communication passage 31 formed between them and the main container 3. The lead wire 5c of the electric motor 5 is drawn out to the side of the suction sub-container 6 through the fixed scroll 10 and the main bearing member 25 or the communication passage 31 formed between them and the main container 3, and is connected to the end of the lead wire 5c. The block 42 is connected to the metal terminal 41 of the terminal 40 penetrating the suction sub container 6. Further, the terminal 40 is connected to the inverter 8 in the suction sub container 6.

  As described above, a high voltage is supplied from the vehicle to the inverter 8 via a connector (not shown) and the like, and is further driven by being supplied to the electric motor 5 by the terminal 40 and the metal terminal 41 connected to the terminal 40. The compression mechanism unit 4 is swung through the shaft 13. At this time, the compression mechanism section 4 is supplied with the lubricating oil 17 of the liquid storage section 16 by the gear pump 18 and is provided with the suction port 14 of the suction sub-container 6 and the fixed scroll 10 while receiving the lubrication, sealing and pressing action. The return refrigerant from the refrigeration cycle is sucked through a suction hole (not shown), compressed, and discharged from the discharge hole (not shown) to the discharge chamber. At this time, the inverter 8 is cooled by the return refrigerant. Further, the refrigerant discharged into the discharge chamber enters the electric motor 5 through a communication passage (not shown), and discharges while cooling the electric motor 5 and further separating the lubricating oil 17 by performing gas-liquid separation such as collision and throttling. It is discharged from the discharge port 15 of the sub container 7.

  Since the electric compressor 1 according to the present embodiment is installed sideways on the vehicle by the mounting legs 2 around the trunk portion, the main container 3 or the suction sub-container 6 as viewed from the front side in FIG. 1 or FIG. The surface becomes the impacted portion 3d when the vehicle collides.

  Here, in the present embodiment, as shown in FIG. 2, in particular, the impacted portion 3 d that is provided on the surface of the main container 3 or the suction sub-container 6 and receives impact from the outside, It is provided only in a portion other than the portion in which the inverter 8 is built. As a result, the impact load on the electric compressor 1 is applied outside the area of the high voltage part such as the inverter part or the electric motor part, and even if the container outside the high voltage part is damaged, the high voltage part is exposed. Can be prevented. The impacted part 3d may be made of the same material as that of the housing, or may be made of a material different from that of the housing.

(Embodiment 2)
FIG. 3 is an external view of the electric compressor according to the second embodiment of the present invention. The cross-sectional view of the electric compressor 1 in the second embodiment of the present invention is the same as that showing the first embodiment. In FIG. 3, the impacted portion 3d is formed in a boss shape in the first embodiment.

  About the electric compressor 1 comprised as mentioned above, the effect | action is demonstrated below. In the electric compressor 1 configured as in the first embodiment, the impact load on the electric compressor 1 at the time of a vehicle collision or the like is accommodated in the inverter 8 accommodated in the suction sub-container 6 or the main container 3. Further, since the electric motor 5 and the like are applied outside the region of the high voltage portion, the high voltage portion can be prevented from being exposed even if the container outside the region of the high voltage portion is damaged.

  Furthermore, in the electric compressor 1 configured as in the second embodiment, the impacted portion 3d is formed of a boss, so that further increase in weight can be suppressed.

  In the present invention, the description has been given using the electric compressor 1 in which the main container 3 includes the compression mechanism section 4 and the electric motor section, and the inverter 8 is included in the suction sub-container 6. However, the present invention is not limited to this. Also, the present invention can be applied to the electric compressor 1 in which the compression mechanism portion 4, the electric motor portion, and the inverter 8 are accommodated in the main container 3.

  The present invention can be applied to an electric motor compressor having a compression mechanism section, an electric motor section, and an inverter section in a casing.

Claims (3)

A casing having a compression mechanism section, an electric motor section that drives the compression mechanism section, and an inverter section that drives the electric motor section, and is installed sideways by mounting legs around the trunk section of the casing In the electric compressor
The compression mechanism part and the electric motor part are built in the main container.
A suction sub-container is mounted on the compression mechanism side opening of the main container so as to face the opening,
The suction sub-container includes the inverter part , and an impacted part is provided on a surface around the body part of the casing, and the impacted part is the suction part including the inverter part. An electric compressor provided only in the main container part including the compression mechanism part other than the main container part including the sub container part and the electric motor part.   The electric compressor according to claim 1, wherein the impacted part is a boss provided on the surface of the casing.   2. The electric compressor according to claim 1, wherein the casing includes the main container including the compression mechanism and the electric motor, and the suction sub-container including the inverter.