JP2007077959A - Scroll compressor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a scroll compressor improving suction efficiency of the compressor. <P>SOLUTION: A compression unit 38 having a fixed scroll 46 and a movable scroll 40 includes one refrigerant intake 72, which is formed at an outer circumferential end of one spiral lap 44 and sucks refrigerant from a low pressure side path of a refrigeration circuit, and another refrigerant intake 73, which is formed at an outer circumferential end of another spiral lap 50 and sucks the refrigerant from the low pressure side path. A compression casing 16 receiving the compression unit includes a suction port 68 connecting the low pressure side path and the one refrigerant intake and another suction port 69 connecting the low pressure side path and the other refrigerant intake. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a scroll compressor, and more particularly to a scroll compressor suitable for being incorporated in a refrigeration circuit of an air conditioning system.

This type of scroll compressor includes a compression unit that performs a series of processes of refrigerant suction, compression, and discharge, that is, a scroll unit. Specifically, the scroll unit includes a fixed scroll and a movable scroll, and each of the fixed scroll and the movable scroll has spiral wraps that mesh with each other. The movable scroll revolves around the axis of the fixed scroll without rotating. Thereby, the volume of the space formed by each scroll is reduced, and the above-described series of processes is performed. And the scroll unit which made the refrigerant | coolant intake port each formed in the outer peripheral end of each said spiral wrap is disclosed (for example, refer patent document 1, 2).
JP 2003-286976 A JP 2003-320992 A

By the way, in the compressor of the above-mentioned patent document, one suction port is formed in the housing, and the refrigerant from the low-pressure side path of the refrigeration circuit is branched from the suction port toward the two refrigerant intake ports. .
However, the refrigerant intake port arranged on the side close to the suction port is introduced while maintaining the pressure and temperature of the refrigerant from the low-pressure side path, while being arranged farther from the suction port. Since the refrigerant intake port is introduced via the back side of the fixed scroll, that is, through the periphery of the discharge port, it is difficult to maintain the pressure and temperature of the refrigerant from the low-pressure side path. There is a problem of lowering.

Here, it is conceivable to increase the cross-sectional area of the suction port. In this case, however, the diameter of the pipe connected to the low-pressure side path is increased, and the strength of the pipe needs to be improved. There is concern that this will lead to an increase in size.
The present invention has been made in view of such problems, and an object of the present invention is to provide a scroll compressor capable of improving the suction efficiency of the compressor.

  In order to achieve the above object, a scroll compressor according to claim 1 includes a drive casing, a housing having a compression casing that is airtightly fitted to the drive casing, and a rotary shaft that is rotatably supported in the drive casing. A movable scroll housed in a compression casing and driven by a rotating shaft to revolve around the axis of the fixed scroll to perform a series of processes of refrigerant suction, compression and discharge in cooperation with the fixed scroll. The compression unit is formed at the outer peripheral end of the spiral wrap standing on the fixed scroll and the movable scroll, respectively, and the refrigerant is sucked from the low-pressure side path of the refrigeration circuit. The other refrigerant intake port and the other spiral wrap are formed at the outer peripheral end, and the refrigerant from the low pressure side path is sucked in. The compression casing includes one suction port that connects the low-pressure side path and the one refrigerant intake port, and another suction port that connects the low-pressure side path and the other refrigerant intake port. It is characterized by that.

  Further, in the scroll compressor according to claim 2, the compression casing is formed on the outer peripheral side surface of the compression unit, one suction port connecting the low pressure side path, the one refrigerant intake port and the other refrigerant intake port, It is characterized by including a communication path connecting the suction port and another refrigerant intake port.

  Therefore, according to the scroll compressor of the first aspect of the present invention, two refrigerant intake ports are formed at the outer peripheral end of each spiral wrap, and the intake ports are individually arranged with respect to the individual refrigerant intake ports. Yes. That is, since the suction port corresponding to each refrigerant intake port is provided, the refrigerant from the low-pressure side path is less affected by the flow path resistance than in the prior art, and overheating of the refrigerant is avoided. As a result, the suction efficiency of the compressor is improved.

  According to the scroll compressor of claim 2, the communication path is formed inside the compression casing and branched from one suction port on the outer peripheral side surface of the compression unit, and the refrigerant from the suction port is It moves along the outer peripheral side surface of the compression unit, not the back side of the fixed scroll, and reaches the other refrigerant intake port. Therefore, the refrigerant from the suction port is also prevented from being overheated as compared with the prior art, and contributes to improvement of the suction efficiency of the compressor.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows a scroll compressor according to this embodiment. The compressor 10 is incorporated in a refrigeration circuit of a gas engine driven heat pump system. This refrigeration circuit has a circulation path through which refrigerant, which is a working gas, circulates, and the compressor 10 sucks refrigerant from the return path (low pressure side path) of the circulation path, compresses this refrigerant, and forwards the circulation path (high pressure side) Discharge toward the route).

  The compressor 10 includes a housing 12. The housing 12 is formed of a front housing (drive casing) 14 and a rear housing (compression casing) 16, and the front housing 14 has a stepped cylindrical shape with a large diameter toward the rear housing 16, and both open ends are provided. Have. On the other hand, the rear housing 16 has a cup shape that opens toward the large-diameter end of the front housing 14, and this open end is airtightly fitted to the large-diameter end of the front housing 14 via an O-ring 18. . The housings 14 and 16 are connected to each other via a plurality of connecting bolts 20.

  A rotary shaft 22 is disposed in the front housing 14, and the rotary shaft 22 has a small diameter shaft portion 24 located on the small diameter end side of the front housing 14 and a large diameter shaft portion 26 located on the rear housing 16 side. The small-diameter shaft portion 24 is rotatably supported by the front housing 14 via a ball bearing 28 and the large-diameter shaft portion 26 via a needle bearing 30. Further, a seal unit 32 is disposed between the ball bearing 28 and the needle bearing 30, and the inside of the front housing 14 is airtightly partitioned.

  The small diameter shaft portion 24 protrudes from the front housing 14, and a driving pulley 36 incorporating an electromagnetic clutch 34 is attached to the protruding end. The driving pulley 36 is rotatably supported by the front housing 14 via a bearing 37. Yes. The power of the gas engine is transmitted to the drive pulley 36 via a drive belt (not shown), and the rotation of the drive pulley 36 can be transmitted to the rotary shaft 22 via the electromagnetic clutch 34. Therefore, when the electromagnetic clutch 34 is turned on during driving of the gas engine, the rotating shaft 22 rotates integrally with the drive pulley 36.

On the other hand, a scroll unit (compression unit) 38 is accommodated in the rear housing 16.
Specifically, the scroll unit 38 includes a movable scroll 40 and a fixed scroll 46, and the movable scroll 40 includes a substrate 42, and a spiral extending toward the substrate 48 of the fixed scroll 46 is provided on one end side of the substrate 42. A wrap (one spiral wrap) 44 is integrally formed. On the other hand, a spiral wrap (another spiral wrap) 50 extending toward the substrate 42 of the movable scroll 40 is also integrally formed on the substrate 48 of the fixed scroll 46. The spiral wraps 44 and 50 cooperate with each other to form a compression chamber 74, and the compression chamber 74 is centered from the outer peripheral side in the radial direction of the spiral wraps 44 and 50 by the revolving motion of the movable scroll 40 with respect to the fixed scroll 46. The volume is reduced at this time.

  In order to impart a turning motion to the movable scroll 40 described above, the other end side of the substrate 42 of the movable scroll 40 is rotatably supported by an eccentric bush 54 via a needle bearing 52. The eccentric bush 54 is connected to a crank pin 56 that protrudes eccentrically from the large-diameter shaft portion 26. Note that reference numeral 58 in FIG. 1 indicates a counterweight, and this counterweight 58 is attached to the eccentric bush 54.

  Further, the rotation of the movable scroll 40 is prevented by the ball coupling 60. That is, the ball coupling 60 is supported by the other end of the base plate 42 and the large-diameter end of the front housing 14, respectively, and a pair of ring plates 62 having annular races at equal intervals in the circumferential direction; And a ball 64 sandwiched between the annular races of the ring plate 62.

  On the other hand, the fixed scroll 46 is bolted to the rear housing 16, and the substrate 48 cooperates with the O-ring 66 to partition the rear housing 16 between the compression chamber 74 side and the discharge chamber 76 side in an airtight manner. Further, a discharge hole 78 communicating with the compression chamber 74 is formed in a substantially central portion of the substrate 48 so as to penetrate the substrate 48, and the discharge hole 78 is opened and closed by a reed valve 80 as a discharge valve. . The reed valve 80 is bolted together with the plate 82 on the back side of the substrate 48.

Incidentally, in the scroll unit 38 of the present embodiment, two refrigerant intake ports are formed by the movable scroll 40 that is prevented from rotating as described above and the fixed scroll 46 that revolves around the axis of the movable scroll 40. Has been.
Specifically, as shown in FIG. 2, the spiral wrap 44 of the movable scroll 40 reaches the discharge hole 78 in the state of the figure, while the outer peripheral end portion is the spiral wrap 50 of the fixed scroll 46. A refrigerant intake port (one refrigerant intake port) 72 is formed between the outer wall portion and the outer wall portion. On the other hand, the spiral wrap 50 of the fixed scroll 46 has its tip portion positioned on the periphery of the discharge hole 78, and its outer peripheral end portion is located between the outer wall portion of the spiral wrap 44 and other refrigerant intake ports (other refrigerant intakes). Mouth) 73 is formed.

  In addition, two suction ports are formed on the peripheral wall of the rear housing 16 of the present embodiment. Specifically, a suction port (one suction port) 68 is formed in the vicinity of the refrigerant intake port 72, and the refrigerant from the low-pressure side path described above passes through the intake port 68 and the suction chamber 70, and the refrigerant intake port 72. And is compressed in the compression chamber 74 to reach the discharge hole 78.

On the other hand, a suction port (another suction port) 69 is also formed in the vicinity of the refrigerant intake port 73, and the refrigerant from the low-pressure side path is introduced from the refrigerant intake port 73 via the intake port 69 and the suction chamber 70, and Similarly, the discharge hole 78 is reached through the compression chamber 74.
According to the compressor 10 described above, the movable scroll 40 performs a turning motion without rotating as the rotary shaft 22 rotates. Such swiveling motion of the movable scroll 40 leads to the steps of sucking, compressing and discharging the refrigerant into the compression chamber 74 from the suction ports 68 and 69 through the refrigerant intake ports 72 and 73, and the high-pressure compressed refrigerant is compressed into the compression chamber. The ink is discharged from 74 through the discharge hole 78 into the discharge chamber 76. The compressed refrigerant in the discharge chamber 76 is supplied to the high-pressure side path.

As described above, the present invention focuses on improving the efficiency of the scroll compressor 10.
And two refrigerant | coolant intake ports 72 and 73 are formed in the outer peripheral end of each spiral wrap 44,50, and each suction port 68,69 corresponding to each refrigerant | coolant intake port 72,73 is arrange | positioned. Therefore, the refrigerant from the low-pressure side path is introduced into the scroll unit 38 with its pressure and temperature being substantially maintained without contacting the back side of the substrate 48 of the fixed scroll 46, so that the refrigerant flows compared to the conventional case. It becomes difficult to be affected by the path resistance, and overheating of the refrigerant due to heat transfer on the back side of the substrate 48 is also avoided. As a result, the suction efficiency of the compressor 10 can be improved.

Further, an increase in diameter and strength of the pipe connected to the low-pressure side path can be avoided, and an increase in the size of the apparatus can be avoided.
The description of one embodiment of the present invention is finished above, but the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit of the present invention.
For example, although two suction ports are provided in the above embodiment, it is possible to arrange one suction port corresponding to two refrigerant intake ports.

  Specifically, as shown in FIG. 3, the rear housings 16 </ b> A and 16 </ b> B are respectively connected to a low-pressure side path, a refrigerant intake port (one refrigerant intake port) 72, and a refrigerant intake port (other refrigerant intake port) 73. One suction port 68A to be connected and communication passages 68B and 68C formed on the outer peripheral side surface of the scroll unit 38 and connecting the suction port 68A and the refrigerant intake port 73 are configured. That is, the communication paths 68B and 68C are branched from the suction port 68A inside the rear housing 16B, and the refrigerant from the low-pressure side path is not in the back side of the substrate 48 of the fixed scroll 46 but in the scroll unit 38. It moves on the outer peripheral side surface and reaches the refrigerant intake port 73. Therefore, the refrigerant from the suction port 68A also avoids overheating due to heat transfer and compression leakage as compared with the case where it passes through the back side of the substrate 48, and contributes to the improvement of the suction efficiency of the compressor as compared with the conventional case.

  Moreover, the compressor of the present invention may be used in an air conditioning system for automobiles, and can be applied to both variable capacity type and fixed capacity type scroll compressors.

It is a longitudinal section of a scroll compressor concerning one embodiment of the present invention. FIG. 2 is a cross-sectional view taken along the line II-II in FIG. 1. It is sectional drawing of the scroll compressor by another Example.

Explanation of symbols

10 Scroll compressor 12 Housing 14 Drive casing (front housing)
16, 16A, 16B Compression casing (rear housing)
22 Rotating shaft 38 Scroll unit (compression unit)
40 movable scroll 44 spiral wrap (one spiral wrap)
46 fixed scroll 50 spiral wrap (other spiral wrap)
68 Suction port (one suction port)
68A Suction port 68B, 68C Communication path 69 Suction port (other suction ports)
72 Refrigerant intake (one refrigerant intake)
73 Refrigerant intake port (other refrigerant intake port)

Claims (2)

A housing having a drive casing and a compression casing that is airtightly fitted to the drive casing;
A rotating shaft rotatably supported in the drive casing;
A movable housing that is housed in the compression casing and is driven by the rotating shaft and revolves around the axis of the fixed scroll to perform a series of refrigerant suction, compression, and discharge processes in cooperation with the fixed scroll. A compression unit having a scroll,
The compression unit is formed in a spiral wrap standing on each of the fixed scroll and the movable scroll, and an outer peripheral end of one spiral wrap, and one refrigerant intake for sucking refrigerant from a low-pressure side path of the refrigeration circuit An inlet and another refrigerant intake port formed at the outer peripheral end of another spiral wrap and into which the refrigerant from the low-pressure side path is sucked,
The compression casing includes one suction port that connects the low-pressure side path and the one refrigerant intake port, and another suction port that connects the low-pressure side path and the other refrigerant intake port. A featured scroll compressor. A housing having a drive casing and a compression casing that is airtightly fitted to the drive casing;
A rotating shaft rotatably supported in the drive casing;
A movable housing that is housed in the compression casing and is driven by the rotating shaft and revolves around the axis of the fixed scroll to perform a series of refrigerant suction, compression, and discharge processes in cooperation with the fixed scroll. A compression unit having a scroll,
The compression unit is formed in a spiral wrap standing on each of the fixed scroll and the movable scroll, and an outer peripheral end of one spiral wrap, and one refrigerant intake for sucking refrigerant from a low-pressure side path of the refrigeration circuit An inlet and another refrigerant intake port formed near the outer peripheral end of the other spiral wrap and into which the refrigerant from the low-pressure side path is sucked,
The compression casing is formed at one suction port connecting the low-pressure side path to the one refrigerant intake port and the other refrigerant intake port, and on an outer peripheral side surface of the compression unit. A scroll compressor including a communication path connecting the refrigerant intake port.

Images