JP4971032B2 - Scroll compressor - Google Patents

Description

The present invention relates to a scroll compressor.

A fixed scroll having a spiral body, a movable scroll having a spiral body and meshing with the fixed scroll to form a plurality of working spaces, a orbiting drive mechanism for the movable scroll, a rotation prevention mechanism for the movable scroll, a fixed scroll and a movable scroll And a housing that accommodates the swivel drive mechanism and the rotation prevention mechanism. The internal space of the housing is partitioned into a suction chamber and a discharge chamber by the fixed scroll, and the movable scroll, the swivel drive mechanism, and the rotation prevention mechanism are provided in the suction chamber. A scroll type compressor is disclosed in Patent Document 1 and the like, in which a communication passage that is housed and communicates with a lower portion of the discharge chamber and a lower portion of the suction chamber is formed in the lower portion of the fixed scroll, and an orifice is inserted and locked in the communication passage. ing.
In the conventional scroll compressor, the O-ring fitted in the circumferential groove formed in the orifice is pressed against the peripheral wall of the communication path, so that the orifice is locked to the communication path.
Japanese Utility Model Publication No. 1-010458

The conventional orifice locking method is not perfect, and the orifice may come out of the communication hole due to vibration during operation of the compressor.
The present invention has been made in view of the above problems, a fixed scroll having a spiral body, a movable scroll having a spiral body and meshing with the fixed scroll to form a plurality of working spaces, and a orbiting drive mechanism of the movable scroll. A movable scroll rotation prevention mechanism, and a fixed scroll, a movable scroll, a turning drive mechanism, and a housing that accommodates the rotation prevention mechanism. The fixed scroll divides the internal space of the housing into a suction chamber and a discharge chamber. A movable scroll, a turning drive mechanism, and an anti-rotation mechanism are housed in the room, and a communication path that connects the lower part of the discharge chamber and the lower part of the suction chamber is formed in the lower part of the fixed scroll, and an orifice is inserted and locked into the communication path. The scroll compressor is fully locked with the orifice in the communication hole, and the orifice is likely to come out of the communication hole. An object of the present invention is to provide a free scroll compressor.

In order to solve the above problems, in the present invention, a fixed scroll having a spiral body, a movable scroll having a spiral body and meshing with the fixed scroll to form a plurality of working spaces, a turning drive mechanism for the movable scroll, A movable scroll rotation prevention mechanism, a fixed scroll, a movable scroll, a swing drive mechanism, and a housing that houses the rotation prevention mechanism. The fixed scroll divides the internal space of the housing into a suction chamber and a discharge chamber, to be accommodated and the movable scroll swing drive mechanism and the rotation preventing mechanism, the communication passage for communicating the lower portion of the discharge chamber and the lower portion of the suction chamber is formed in the lower portion of the fixed scroll, an orifice is inserted into the communication passage, the orifice Is a filter having a metal orifice tube and a resin cylinder with one end of the orifice tube fixed The provided, is formed with projections or depressions in the resin tube of the filter, elastic either projections or depressions formed in the orifice, the other one of the projections or depressions formed in the communication passage The orifice is engaged and locked in the communication path, and an annular gap is formed between the discharge chamber side end peripheral wall of the communication path and the resin cylindrical portion outer peripheral surface of the filter. A scroll compressor is provided.

In the scroll compressor according to the present invention, either the protrusion or the recess formed in the orifice is elastically engaged with either the protrusion or the recess formed in the communication path, and the orifice is inserted into the communication path. Is locked, the orifice is completely locked into the communication hole, and there is no possibility that the orifice will come out of the communication hole.

By forming locking projections or recesses on the resin cylinder, the mounting operation can be facilitated by utilizing the elastic deformation in the radial direction of the resin cylinder when the orifice is mounted on the communication path. .
By forming an annular gap between the peripheral wall of the discharge chamber side end of the communication passage and the outer peripheral surface of the resin tube portion of the filter, the elastic bending deformation of the resin tube portion is used when the orifice is installed in the communication passage. Thus, the mounting work can be facilitated.

  According to the present invention, there is provided a scroll compressor in which the orifice is completely locked into the communication hole, and the orifice is not likely to come out of the communication hole.

A scroll compressor according to an embodiment of the present invention will be described.
As shown in FIG. 1, the scroll compressor according to this embodiment includes a fixed scroll 1 having an end plate 1a and a spiral body 1b, and a movable scroll 2 having an end plate 2a and a spiral body 2b. Yes. The fixed scroll 1 and the movable scroll 2 mesh with each other to form a plurality of pairs of working spaces 3.
The casing 4a is abutted and fixed to the front housing 4b, and forms the housing 4 in cooperation with the front housing 4b. The inner space of the housing 4 is partitioned into a suction chamber 5 and a discharge chamber 6 by the end plate 1a of the fixed scroll.
A suction port (not shown) formed in the housing 4 communicates with the suction chamber 5. The suction port is connected to the low pressure side of the external refrigerant circuit.
A discharge port (not shown) formed in the housing 4 communicates with the discharge chamber 6. The discharge port is connected to the high pressure side of the external refrigerant circuit.

A main shaft 7 is disposed in the suction chamber 5. The main shaft 7 is rotatably supported by the front housing 4b via radial bearings 8 and 9. One end of the main shaft 7 protrudes outside the front housing 4b.
The electromagnetic clutch 10 is rotatably supported by the front housing 4b via a radial bearing 11.
An eccentric pin 12 is fixed to the other end of the main shaft 7. A bush 13 is slidably fitted to the eccentric pin 12. The bush 13 is accommodated in a boss 2 c formed on the back surface of the end plate 2 a of the movable scroll 2 via a radial bearing 14.
A ball coupling 15 is disposed between the movable scroll 2 and the front housing 4b.

  A discharge hole 16 is formed in the center of the end plate 1a of the fixed scroll. The discharge hole 16 communicates with the discharge chamber 6 via a discharge valve 17 attached to the end plate 1a.

A baffle plate 18 is disposed in the discharge chamber 6 and below the discharge hole 16. A minute gap is formed between the baffle plate 18 and the end plate 1a of the fixed scroll. An oil storage chamber 6 a is formed in the lower portion of the discharge chamber 6 by the baffle plate 18.
A linear communication path 19 that allows communication between the lower portion of the oil storage chamber 6a and the lower portion of the suction chamber 5 is formed through the lower portion of the end plate 1a of the fixed scroll and the lower portion of the spiral body 1b. The communication path 19 has a large diameter portion 19a on the oil storage chamber 6a side and a small diameter portion 19b on the suction chamber 5 side. A large diameter portion 19c is formed at the end of the large diameter portion 19a on the oil storage chamber 6a side, and a concave portion 19d is formed in the large diameter portion 19c.

As shown in FIG. 2, an orifice 20 is formed by a metal orifice tube 20a and a filter 20b having a resin cylinder portion 20b ′ to which one end of the orifice tube 20a is fixed. A radial protrusion 20c is formed at an end portion of the resin cylinder portion 20b ′ that is separated from the orifice tube 20a. An O-ring 21 is attached to an end portion of the resin cylinder portion 20b ′ adjacent to the orifice tube 20a.
The orifice 20 is inserted into the communication path 19. The orifice tube 20a is fitted into the small diameter part 19b of the communication path, and the filter 20b is fitted into the large diameter part 19a of the communication path. An annular gap S is formed between the peripheral wall of the enlarged diameter portion 19c of the communication passage and the outer peripheral surface of the resin cylindrical portion 20b ′ of the filter. The orifice projection 20 c is elastically engaged with the recess 19 d of the communication path 19. The abutting portion between the resin cylindrical portion 20 b ′ of the filter and the large diameter portion 19 a of the communication path is sealed by an O-ring 21. The orifice 20 is locked to the communication path 19 by the O-ring 21 being pressed against the peripheral wall of the large-diameter portion 19a of the communication path and the projection 20c elastically engaging the recess 19d of the communication path.

In the scroll compressor according to this embodiment, the power of a drive source (not shown) is transmitted to one end of the main shaft 7 via the electromagnetic clutch 10, and the main shaft 7 is rotationally driven. With the rotation of the main shaft 7, the movable scroll 2 rotates and the refrigerant gas sucked into the suction chamber 5 through the suction port is taken into the working space 3. The ball coupling 15 prevents the movable scroll 2 from rotating.
The mist-like lubricating oil dispersed and suspended in the refrigerant gas is supplied to the main shaft 7, the eccentric pin 12, the bush 13, the radial bearings 8, 9 and 14, the ball coupling 15, the movable scroll 2 and the fixed scroll 1. Lubricate the sliding contact part.

The working space 3 moves toward the center of the fixed scroll 1 while reducing the volume, and the refrigerant gas in the working space 3 is compressed. The compressed refrigerant gas is discharged into the discharge chamber 6 through a discharge hole 16 and a discharge valve 17 formed in the end plate 1 a of the fixed scroll 1. The refrigerant gas collides with the surrounding wall of the discharge chamber 6. When the refrigerant gas collides with the surrounding wall of the discharge chamber 6, the mist-like lubricating oil dispersed and suspended in the refrigerant gas adheres to the surrounding wall of the discharge chamber 6 and is separated and removed from the refrigerant gas. It accumulates in the oil storage chamber 6a through a minute gap with the end plate 1a.
The refrigerant gas from which the lubricating oil has been separated and removed flows out to the high pressure side of the external refrigerant circuit via a discharge port (not shown). By separating and removing the lubricating oil from the refrigerant gas discharged from the discharge chamber to the external refrigerant circuit, the thermal efficiency of the external refrigerant circuit is improved.

Lubricating oil accumulated in the high-pressure oil storage chamber 6 a is pumped to the lower portion of the low-pressure suction chamber 5 through an orifice 20 inserted and locked in a communication passage 19 formed in the lower portion of the fixed scroll 1. When the lubricating oil passes through the filter 20b of the orifice 20, dust such as metal powder contained in the lubricating oil is removed. The pumping flow rate of the lubricating oil is regulated to an appropriate value by the orifice tube 20a. Lubricating oil pumped to the lower portion of the suction chamber 5 accumulates in the lower portion of the suction chamber 5 and is carried to the upper portion of the suction chamber 5 by the orbiting scroll 2, the bush 13, the rotating eccentric pin 12, and the like. Lubricating oil carried to the upper part of the suction chamber 5 flows downward, and the main shaft 7, the eccentric pin 12, the bush 13, the radial bearings 8, 9 and 14, the ball coupling 15, and the movable scroll 2 in the suction chamber 5. Lubricate the sliding contact portion with the fixed scroll 1.

In the scroll compressor according to the present embodiment, in addition to the O-ring 21 being pressed against the peripheral wall of the large-diameter portion 19a of the communication path, the protrusion 20c formed in the orifice 20 is formed in the communication path 19. Since the orifice 20 is elastically engaged with the recess 19 d and the orifice 20 is locked to the communication path 19, the orifice 20 is completely locked to the communication path 19, and there is no possibility that the orifice 20 comes out of the communication path 19.
By forming the protrusion 20c on the resin cylinder portion 20b ′, when the orifice 20 is mounted on the communication path 19, the protrusion 20c and the communication path 19 are formed using the elastic deformation in the radial direction of the resin cylinder portion 20b ′. Interference is reduced, and the mounting operation of the orifice 20 is facilitated.
When the orifice 20 is attached to the communication path 19 by forming the annular gap S between the peripheral wall of the end of the oil storage chamber 6a of the communication path 19 and the outer peripheral surface of the resin cylinder 20b ′ of the filter 20, FIG. As indicated by the one-dot chain line in (a), the interference between the projection 20c and the communication path 19 is mitigated by utilizing the elastic bending deformation of the resin cylindrical portion 20b ′, and the mounting operation of the orifice 20 is facilitated.

  In the above embodiment, the protrusion 20c formed on the orifice 20 is elastically engaged with the recess 19d formed on the communication path. However, the protrusion formed on the communication path 19 is elastically engaged with the recess formed on the orifice 20, so that the orifice 20 May be locked to the communication path 19.

1 is a side cross-sectional view of a scroll compressor according to an embodiment of the present invention. It is a partial expanded side sectional view of the scroll type compressor concerning the example of the present invention. (A) is the elements on larger scale of FIG. 1, (b) is a bb arrow line view of (a).

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Fixed scroll 1a End plate 1b Spiral body 2 Movable scroll 2a End plate 2b Spiral body 3 Working space 4 Housing 5 Suction chamber 6 Discharge chamber 6a Oil storage chamber 19 Communication path 19d Recess 20 Orifice 20c Protrusion

Claims (1)

A fixed scroll having a spiral body, a movable scroll having a spiral body and meshing with the fixed scroll to form a plurality of working spaces, a orbiting drive mechanism for the movable scroll, a rotation prevention mechanism for the movable scroll, a fixed scroll and a movable scroll And a housing that accommodates the swivel drive mechanism and the rotation prevention mechanism. The internal space of the housing is partitioned into a suction chamber and a discharge chamber by the fixed scroll, and the movable scroll, the swivel drive mechanism, and the rotation prevention mechanism are provided in the suction chamber. A communicating passage is formed in the lower portion of the fixed scroll, and communicates between the lower portion of the discharge chamber and the lower portion of the suction chamber. An orifice is inserted into the communicating passage, and the orifice is made of a metal orifice tube and one end of the orifice tube is fixed. And a filter having a resin-made cylindrical portion, and a protrusion or a recess in the resin-made cylindrical portion of the filter. There are formed, one of the projections or depressions formed in the orifice, the orifice is engaged into the communicating path resilient engagement with the other one of the communication passage formed projections or depressions A scroll compressor characterized in that an annular gap is formed between the discharge chamber side end peripheral wall of the communication passage and the resin cylindrical portion outer peripheral surface of the filter .

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