JP2021038680A - Scroll compressor - Google Patents

Abstract

To supply oil into radially inside and outside spaces as compared to a movable scroll in a compression space.SOLUTION: A scroll compressor includes a suction pipe (12) including a large diameter part (12a), a small diameter part (12b) and a diameter reduction part (12c). The diameter reduction part (12c) is provided between the large diameter part (12a) and the small diameter part (12b) and the outside diameter thereof is gradually reduced. The small diameter part (12b) has an outside diameter that is smaller than an inside diameter of an upstream end of a suction port (64), therefore, oil flowing through an internal space (23) flows into the suction port (64) passing through a clearance between the small diameter part (12b) of the suction pipe (12) and the suction port (64).SELECTED DRAWING: Figure 2

Description

The present disclosure relates to a scroll compressor.

Patent Document 1 describes a first operation in which only the fixed side oil groove and the movable side oil groove of the fixed side oil groove, the movable side oil groove, and the compression chamber (fluid chamber) communicate with each other, and the movable side oil after the first operation. A scroll type compressor is disclosed in which the groove is configured to perform a second operation in which both the fixed side oil groove and the compression chamber communicate with each other at the same time.

Japanese Unexamined Patent Publication No. 2016-160816

In the invention of Patent Document 1, since the movable oil groove is communicated with the space radially outside the movable scroll in the compression chamber, it is difficult for oil to be supplied to the space inside the movable scroll in the compression chamber. It has become.

An object of the present disclosure is to enable oil to be supplied to the inner and outer spaces in the radial direction of the movable scroll in the compression chamber.

A first aspect of the present disclosure is between a casing (20) to which a suction tube (12) is connected, a fixed scroll (60) housed in the casing (20), and the fixed scroll (60). It is intended for scroll compressors equipped with a movable scroll (70) that forms a compression chamber (S). An internal space (23) through which an oil-containing refrigerant flows is provided inside the casing (20), and the fixed scroll (60) includes the internal space (23) and the compression chamber (S). The suction pipe (12) is provided on the large diameter portion (12a) and on the downstream side of the large diameter portion (12a) from the large diameter portion (12a). Also has a small diameter portion (12b) with a small outer diameter and a reduced diameter portion (12c) provided between the large diameter portion (12a) and the small diameter portion (12b) and the outer diameter gradually decreases. The downstream end of the small diameter portion (12b) is arranged at a position overlapping the upstream end of the suction port (64) when viewed from the axial direction, and the outer diameter of the small diameter portion (12b) is the suction port (64). It is smaller than the diameter of the upstream end of.

In the first aspect, the suction tube (12) has a large diameter portion (12a), a small diameter portion (12b), and a reduced diameter portion (12c). The reduced diameter portion (12c) is provided between the large diameter portion (12a) and the small diameter portion (12b), and the outer diameter is gradually reduced. Further, the outer diameter of the small diameter portion (12b) is smaller than the inner diameter of the upstream end of the suction port (64), and the oil flowing through the internal space (23) is with the small diameter portion (12b) of the suction pipe (12). It flows into the suction port (64) through a gap with the suction port (64).

As a result, oil can be supplied to the inner and outer spaces in the radial direction of the movable scroll (70) in the compression chamber (S).

In the second aspect of the present disclosure, in the first aspect, a tapered portion (64a) is provided on the peripheral portion on the upstream side of the suction port (64) in the fixed scroll (60).

In the second aspect, by providing the tapered portion (64a), the opening width on the upstream side of the suction port (64) is widened. This facilitates the flow of oil along the tapered portion (64a) and allows the oil to efficiently flow into the suction port (64).

In a third aspect of the present disclosure, in the first or second aspect, the downstream end of the suction pipe (12) is the same as the opening surface (60a) of the suction port (64) in the fixed scroll (60). It is arranged on a plane or at a position distant from the opening surface (60a) in the axial direction.

In the third aspect, the downstream end of the suction pipe (12) is flush with the opening surface (60a) of the suction port (64) in the fixed scroll (60) or axially outside the opening surface (60a). It is placed at a distant position.

As a result, the oil flowing through the internal space (23) easily flows into the suction port (64) through the gap between the downstream end of the suction pipe (12) and the opening surface (60a).

FIG. 1 is a vertical cross-sectional view showing the configuration of the scroll compressor according to the first embodiment. FIG. 2 is a diagram showing a positional relationship between the suction pipe and the suction port. FIG. 3 is a cross-sectional view showing the configuration of a fixed scroll and a movable scroll. FIG. 4 is a view corresponding to FIG. 2 showing the configuration of the scroll compressor according to the first modification of the first embodiment. FIG. 5 is a view corresponding to FIG. 2 showing the configuration of the scroll compressor according to the second modification of the first embodiment. FIG. 6 is a view corresponding to FIG. 2 showing the configuration of the scroll compressor according to the second embodiment.

<< Embodiment 1 >>
The first embodiment will be described.

As shown in FIG. 1, the scroll compressor (10) includes a casing (20), an electric motor (30) and a compression mechanism (40) housed in the casing (20). The casing (20) is formed in a vertically long cylindrical shape and is configured in a closed dome type.

The scroll compressor (10) is provided in the refrigerant circuit of the vapor compression refrigeration cycle. In the refrigerant circuit, the refrigerant compressed by the scroll compressor (10) is condensed by the condenser, depressurized by the depressurizing mechanism, evaporated by the evaporator, and sucked into the scroll compressor (10).

The electric motor (30) includes a stator (31) fixed to a casing (20) and a rotor (32) arranged inside the stator (31). The rotor (32) is fixed to the drive shaft (11).

An oil reservoir (21) for storing oil is formed at the bottom of the casing (20). A suction pipe (12) is connected to the upper part of the casing (20). A discharge pipe (13) is connected to the central portion of the casing (20).

A housing (50) is fixed to the casing (20). The housing (50) is located above the electric motor (30). A compression mechanism (40) is arranged above the housing (50). The inflow end of the discharge pipe (13) is located between the electric motor (30) and the housing (50).

The drive shaft (11) extends vertically along the central axis of the casing (20). The drive shaft (11) has a spindle portion (14) and an eccentric portion (15) connected to the upper end of the spindle portion (14).

The lower part of the spindle portion (14) is rotatably supported by the casing (20) and the lower bearing (22). The lower bearing (22) is fixed to the inner peripheral surface of the casing (20). The upper portion of the spindle portion (14) extends through the housing (50) and is rotatably supported by the upper bearing (51) of the housing (50).

The compression mechanism (40) includes a fixed scroll (60) and a movable scroll (70). The fixed scroll (60) is fixed to the top surface of the housing (50). The movable scroll (70) is located between the fixed scroll (60) and the housing (50).

The housing (50) is formed with an annular portion (52) and a recess (53). The annular portion (52) is provided on the outer peripheral portion of the housing (50). The recess (53) is formed in the upper center of the housing (50), and the center thereof is formed in a concave dish shape. An upper bearing (51) is provided below the recess (53).

The housing (50) is fixed to the inside of the casing (20) by press fitting. The inner peripheral surface of the casing (20) and the outer peripheral surface of the annular portion (52) of the housing (50) are in close contact with each other in an airtight manner over the entire circumference. The housing (50) divides the inside of the casing (20) into an upper space (23) (internal space) in which the compression mechanism (40) is accommodated and a lower space (24) in which the electric motor (30) is accommodated. ing.

The fixed scroll (60) has a fixed side end plate (61), a substantially tubular outer wall (63) standing on the outer edge of the lower surface of the fixed side end plate (61), and an outer wall (61) on the fixed side end plate (61). It is equipped with a spiral fixed side wrap (62) that stands inside 63).

The fixed-side end plate (61) is located on the outer peripheral side and is formed continuously with the fixed-side wrap (62). The tip surface of the fixed side wrap (62) and the tip surface of the outer peripheral wall (63) are formed substantially flush with each other. Further, the fixed scroll (60) is fixed to the housing (50).

The movable scroll (70) is formed on the movable side end plate (71), the spiral movable side wrap (72) formed on the upper surface of the movable side end plate (71), and the central portion of the lower surface of the movable side end plate (71). It is equipped with a boss part (73).

The boss portion (73) is connected to the drive shaft (11) by inserting the eccentric portion (15) of the drive shaft (11). An Oldham joint (46) is provided at the top of the housing (50). The Oldham fitting (46) prevents the movable scroll (70) from rotating.

In the compression mechanism (40), a compression chamber (S) into which the refrigerant flows is formed between the fixed scroll (60) and the movable scroll (70). The movable scroll (70) is arranged so that the movable side lap (72) meshes with the fixed side lap (62) of the fixed scroll (60). Here, the lower surface of the outer peripheral wall (63) of the fixed scroll (60) is the surface facing the movable scroll (70). Further, the upper surface of the movable end plate (71) of the movable scroll (70) serves as a surface facing the fixed scroll (60).

As shown in FIG. 2, an suction port (64) communicating with the compression chamber (S) is formed on the outer peripheral wall (63) of the fixed scroll (60). The suction port (64) extends vertically through. On the upstream side of the suction port (64), a suction pipe (12) extending in the vertical direction is arranged.

The suction tube (12) is connected to the top of the casing (20). At the downstream end of the suction pipe (12), a part of the outer peripheral portion is cut out over the entire circumference. As a result, the suction pipe (12) has a large diameter portion (12a), a small diameter portion (12b), and a reduced diameter portion (12c).

The small diameter portion (12b) is provided on the downstream side of the large diameter portion (12a) and has a smaller outer diameter than the large diameter portion (12a). The outer diameter of the small diameter portion (12b) is formed to be smaller than the inner diameter of the suction port (64). The reduced diameter portion (12c) is provided between the large diameter portion (12a) and the small diameter portion (12b), and the outer diameter is gradually reduced.

The downstream end of the suction pipe (12) overlaps the upstream side of the suction port (64) when viewed from the axial direction. In the example shown in FIG. 2, the suction pipe (12) is arranged so as to be coaxial with the suction port (64). The downstream end of the suction tube (12) penetrates inward of the opening surface (60a) of the suction port (64) in the fixed scroll (60).

As a result, there is a ring between the outer peripheral portion of the downstream end of the suction pipe (12) (the outer peripheral portion of the small diameter portion (12b)) and the inner peripheral portion of the upstream end of the suction port (64) when viewed from the axial direction. There is a gap that opens in a shape. The suction port (64) communicates with the upper space (23) and the compression chamber (S) through a ring-shaped opening.

A refrigerant containing oil droplets (25) is flowing in the upper space (23). The refrigerant containing the oil droplets (25) flowing through the upper space (23) is sucked into the suction port (64) through the ring-shaped opening. In the example shown in FIG. 2, the suction pipe (12) is arranged so as to be coaxial with the suction port (64), but the flow of the refrigerant passing through the opening toward the suction port (64) is allowed to flow. It may be arranged with a slight shift as long as it does not interfere.

As shown in FIG. 3, the compression chamber (S) is divided into an outer chamber (S1) radially outside the movable scroll (70) and an inner chamber (S2) radially inside the movable scroll (70). It is partitioned. Specifically, when the inner peripheral surface of the outer peripheral wall (63) of the fixed scroll (60) and the outer peripheral surface of the movable side wrap (72) of the movable scroll (70) are substantially in contact with each other, the outer peripheral surface of the movable scroll (70) is sandwiched between the contact portions. The room (S1) and the inner room (S2) are separated.

As shown in FIG. 1, a discharge port (65) is formed in the center of the fixed side end plate (61) of the fixed scroll (60). A high-pressure chamber (66) through which the discharge port (65) opens is formed on the upper surface of the fixed-side end plate (61) of the fixed scroll (60). The high pressure chamber (66) communicates with the lower space (24) via a passage (not shown) formed in the fixed side end plate (61) and the housing (50) of the fixed scroll (60). The high-pressure refrigerant compressed by the compression mechanism (40) flows out to the lower space (24).

Inside the drive shaft (11), a refueling hole (16) extending in the vertical direction from the lower end to the upper end of the drive shaft (11) is formed. The lower end of the drive shaft (11) is immersed in the oil reservoir (21). The oil supply hole (16) supplies the oil from the oil reservoir (21) to the lower bearing (22) and the upper bearing (51), and also supplies the oil to the gap between the boss portion (73) and the drive shaft (11). The oil filler hole (16) opens on the upper end surface of the drive shaft (11) to supply oil above the drive shaft (11).

The recess (53) of the housing (50) communicates with the fuel filler hole (16) of the drive shaft (11) via the inside of the boss portion (73) of the movable scroll (70). By supplying high-pressure oil to the recess (53), a high-pressure pressure corresponding to the discharge pressure of the compression mechanism (40) acts. The movable scroll (70) is pressed against the fixed scroll (60) by the high pressure of the recess (53).

An oil passage (55) is formed inside the housing (50) and the fixed scroll (60). The inflow end of the oil passage (55) communicates with the recess (53) of the housing (50). The outflow end of the oil passage (55) is open to the opposite surface of the fixed scroll (60). The oil passage (55) supplies the high-pressure oil in the recess (53) to the facing surface of the movable side end plate (71) of the movable scroll (70) and the outer peripheral wall (63) of the fixed scroll (60).

As shown in FIG. 3, a refueling groove (80) is formed on the facing surface of the outer peripheral wall (63) of the fixed scroll (60). The refueling groove (80) is formed on the outer peripheral wall (63) of the fixed scroll (60) facing the movable side end plate (71) of the movable scroll (70). The refueling groove (80) extends in a substantially arc shape along the inner peripheral surface of the outer peripheral wall (63) of the fixed scroll (60). An oil passage (55) communicates with the oil passage (80), and oil is supplied from the oil passage (55) to the oil passage (80).

A plurality of notches (68) are provided on the outer peripheral portion of the fixed scroll (60). The notch (68) communicates with the upper space (23). The oil supplied to the refueling groove (80) flows toward the upper space (23) through the notch (68).

-Driving operation-
The basic operation of the scroll compressor (10) will be described. As shown in FIG. 1, when the electric motor (30) is operated, the movable scroll (70) of the compression mechanism (40) is rotationally driven. Since the movable scroll (70) is prevented from rotating by the Oldham joint (46), only the eccentric rotation is performed around the axis of the drive shaft (11).

As shown in FIG. 3, when the eccentric rotation of the movable scroll (70) rotates, the compression chamber (S) is divided into an outer chamber (S1) and an inner chamber (S2). A plurality of inner chambers (S2) are formed between the fixed side lap (62) of the fixed scroll (60) and the movable side lap (72) of the movable scroll (70). When the movable scroll (70) rotates eccentrically, these inner chambers (S2) gradually approach the center (discharge port (65)), and the volume of these inner chambers (S2) becomes smaller. As a result, the refrigerant is compressed in the inner chamber (S2).

When the inner chamber (S2) having the smallest volume communicates with the discharge port (65), the high-pressure gas refrigerant in the inner chamber (S2) is discharged to the high-pressure chamber (66) through the discharge port (65). The high-pressure refrigerant gas in the high-pressure chamber (66) flows out to the lower space (24) via the passages formed in the fixed scroll (60) and the housing (50). The high-pressure gas refrigerant in the lower space (24) is discharged to the outside of the casing (20) via the discharge pipe (13).

-Refueling operation-
Next, the oil refueling operation in the scroll compressor (10) will be described in detail with reference to FIGS. 1 to 3.

When a high-pressure gas refrigerant flows out into the lower space (24) of the scroll compressor (10), the lower space (24) becomes a high-pressure atmosphere, and the oil in the oil reservoir (21) also becomes a high-pressure state. The high-pressure oil in the oil reservoir (21) flows upward through the oil supply hole (16) of the drive shaft (11), and from the opening at the upper end of the eccentric part (15) of the drive shaft (11), the movable scroll (70) It flows out to the inside of the boss part (73).

The oil supplied to the boss portion (73) is supplied to the gap between the eccentric portion (15) and the boss portion (73) of the drive shaft (11). As a result, the recess (53) of the housing (50) becomes a high-pressure atmosphere corresponding to the discharge pressure of the compression mechanism (40). The high pressure of the recess (53) presses the movable scroll (70) against the fixed scroll (60).

The high-pressure oil accumulated in the recess (53) flows through the oil passage (55) and flows out to the oil supply groove (80). As a result, high-pressure oil corresponding to the discharge pressure of the compression mechanism (40) is supplied to the oil supply groove (80). The oil in the refueling groove (80) is used to lubricate the opposite surfaces of the fixed scroll (60) and the movable scroll (70).

The oil supplied to the opposite surface of the fixed scroll (60) flows outward in the radial direction due to the relative rotation of the movable scroll (70) with respect to the fixed scroll (60), and the cutout (68) is formed. It is discharged to the upper space (23) through it.

The refrigerant containing the oil droplets (25) discharged into the upper space (23) collides with the outer peripheral portion of the suction pipe (12). At this time, oil adheres to the outer peripheral surface of the suction pipe (12). Here, the oil adhering to the large diameter portion (12a) of the suction pipe (12) flows along the inclined surface of the reduced diameter portion (12c) and then smoothly flows toward the small diameter portion (12b).

As described above, even in the suction pipe (12) having the large diameter portion (12a) and the small diameter portion (12b), the reduced diameter portion (12c) is between the large diameter portion (12a) and the small diameter portion (12b). ), The oil adhering to the outer peripheral surface of the suction pipe (12) can be smoothly flowed down.

The oil flowing down along the outer peripheral surface of the suction pipe (12) is supplied to the suction port (64) through the gap between the suction pipe (12) and the suction port (64). The oil sucked into the suction port (64) is distributed to the outer chamber (S1) radially outside the movable side wrap (72) of the movable scroll (70) and to the inner chamber (S2) radially inside. (See the arrow line in FIG. 3). Thereby, the oil sealability of the outer chamber (S1) and the inner chamber (S2) can be enhanced.

-Effect of Embodiment 1-
The scroll compressor (10) of the first embodiment has a casing (20) to which the suction pipe (12) is connected, a fixed scroll (60) housed in the casing (20), and a fixed scroll (60). It is equipped with a movable scroll (70) that forms a compression chamber (S) between them. An upper space (23) (internal space) through which an oil-containing refrigerant flows is provided inside the casing (20), and the fixed scroll (60) has an upper space (23) and a compression chamber (S). The suction pipe (12) is provided on the downstream side of the large diameter portion (12a) and the large diameter portion (12a) and has an outer diameter larger than that of the large diameter portion (12a). It has a small diameter portion (12b) with a small diameter and a reduced diameter portion (12c) provided between the large diameter portion (12a) and the small diameter portion (12b) and the outer diameter gradually decreases, and the small diameter portion (12b). ) Is arranged at a position overlapping the upstream end of the suction port (64) when viewed from the axial direction, and the outer diameter of the small diameter portion (12b) is smaller than the diameter of the upstream end of the suction port (64).

In the first embodiment, the suction pipe (12) has a large diameter portion (12a), a small diameter portion (12b), and a reduced diameter portion (12c). The reduced diameter portion (12c) is provided between the large diameter portion (12a) and the small diameter portion (12b), and the outer diameter is gradually reduced. Further, the outer diameter of the small diameter portion (12b) is smaller than the inner diameter of the upstream end of the suction port (64), and the oil flowing through the internal space (23) is with the small diameter portion (12b) of the suction pipe (12). It flows into the suction port (64) through a gap with the suction port (64).

As a result, oil can be supplied to the inner and outer spaces in the radial direction of the movable scroll (70) in the compression chamber (S).

Specifically, the oil supplied to the facing surface of the fixed scroll (60) flows outward in the radial direction due to the relative rotation of the movable scroll (70) with respect to the fixed scroll (60), and the notch portion. It is discharged to the upper space (23) through (68).

The refrigerant containing the oil droplets (25) discharged into the upper space (23) is supplied to the suction port (64) through the gap between the suction pipe (12) and the suction port (64). After that, the oil is distributed to the inner and outer spaces in the radial direction of the movable scroll (70) in the compression chamber (S). Thereby, the oil sealing property of the inner and outer spaces can be improved.

Further, by continuously connecting the large diameter portion (12a) and the small diameter portion (12b) with the reduced diameter portion (12c), the oil adhering to the outer peripheral surface of the suction pipe (12) can be removed from the small diameter portion (12b). ) To the suction port (64).

Specifically, when the suction pipe (12) is not provided with the reduced diameter portion (12c), the oil flowing along the outer peripheral surface of the large diameter portion (12a) flows between the large diameter portion (12a) and the small diameter portion. It will fall as it is at the step with (12b). In this case, the oil does not flow from the large diameter portion (12a) to the small diameter portion (12b), and the oil cannot flow from the small diameter portion (12b) to the suction port (64).

On the other hand, in the present embodiment, the oil flowing along the outer peripheral surface of the large diameter portion (12a) can be smoothly flowed from the reduced diameter portion (12c) to the small diameter portion (12b).

− Modification 1 of Embodiment 1
Hereinafter, the same parts as those in the first embodiment are designated by the same reference numerals, and only the differences will be described.

As shown in FIG. 4, the suction pipe (12) has a large diameter portion (12a), a small diameter portion (12b), and a reduced diameter portion (12c). The small diameter portion (12b) is provided on the downstream side of the large diameter portion (12a) and has a smaller outer diameter than the large diameter portion (12a). The outer diameter of the small diameter portion (12b) is formed to be smaller than the inner diameter of the suction port (64). The reduced diameter portion (12c) is provided between the large diameter portion (12a) and the small diameter portion (12b), and the outer diameter is gradually reduced.

The downstream end of the suction pipe (12) overlaps the upstream side of the suction port (64) when viewed from the axial direction. The downstream end of the suction tube (12) is coplanar with the opening surface (60a) of the suction port (64) in the fixed scroll (60).

As a result, there is a ring between the outer peripheral portion of the downstream end of the suction pipe (12) (the outer peripheral portion of the small diameter portion (12b)) and the inner peripheral portion of the upstream end of the suction port (64) when viewed from the axial direction. There is a gap that opens in a shape. The refrigerant containing the oil droplets (25) flowing through the upper space (23) is sucked into the suction port (64) through the gap between the suction pipe (12) and the suction port (64).

-Effect of variant 1-
In the scroll compressor (10) of the present modification 1, the downstream end of the suction pipe (12) is arranged on the same plane as the opening surface (60a) of the suction port (64) in the fixed scroll (60).

In the first modification, the downstream end of the suction pipe (12) is arranged on the same plane as the opening surface (60a) of the suction port (64) in the fixed scroll (60).

As a result, the oil flowing through the upper space (23) easily flows into the suction port (64) through the gap between the downstream end of the suction pipe (12) and the opening surface (60a). That is, as compared with the case where the lower end portion of the suction pipe (12) is inserted into the suction port (64), the suction effect due to the dynamic pressure can be exhibited and the efficiency can be improved.

− Modification of Embodiment 1 2-
As shown in FIG. 5, the suction pipe (12) has a large diameter portion (12a), a small diameter portion (12b), and a reduced diameter portion (12c). The small diameter portion (12b) is provided on the downstream side of the large diameter portion (12a) and has a smaller outer diameter than the large diameter portion (12a). The outer diameter of the small diameter portion (12b) is formed to be smaller than the inner diameter of the suction port (64). The reduced diameter portion (12c) is provided between the large diameter portion (12a) and the small diameter portion (12b), and the outer diameter is gradually reduced.

The downstream end of the suction pipe (12) overlaps the upstream side of the suction port (64) when viewed from the axial direction. The downstream end of the suction pipe (12) is located axially outwardly from the opening surface (60a) of the suction port (64) in the fixed scroll (60).

As a result, there is a ring between the outer peripheral portion of the downstream end of the suction pipe (12) (the outer peripheral portion of the small diameter portion (12b)) and the inner peripheral portion of the upstream end of the suction port (64) when viewed from the axial direction. There is a gap that opens in a shape. Further, a predetermined gap is provided between the downstream end of the suction pipe (12) and the opening surface (60a). The refrigerant containing the oil droplets (25) flowing through the upper space (23) is sucked into the suction port (64) through the gap between the suction pipe (12) and the suction port (64).

-Effect of variant 2-
In the scroll compressor (10) of the present modification 2, the downstream end of the suction pipe (12) is located at a position axially outward from the opening surface (60a) of the suction port (64) in the fixed scroll (60). Have been placed.

In the second modification, the downstream end of the suction pipe (12) is arranged at a position axially outward from the opening surface (60a) of the suction port (64) in the fixed scroll (60).

As a result, the oil flowing through the upper space (23) easily flows into the suction port (64) through the gap between the downstream end of the suction pipe (12) and the opening surface (60a). That is, as compared with the case where the lower end portion of the suction pipe (12) is inserted into the suction port (64), the suction effect due to the dynamic pressure can be exhibited and the efficiency can be improved.

<< Embodiment 2 >>
The second embodiment will be described.

As shown in FIG. 6, the suction pipe (12) has a large diameter portion (12a), a small diameter portion (12b), and a reduced diameter portion (12c). The small diameter portion (12b) is provided on the downstream side of the large diameter portion (12a) and has a smaller outer diameter than the large diameter portion (12a). The outer diameter of the small diameter portion (12b) is formed to be smaller than the inner diameter of the suction port (64). The reduced diameter portion (12c) is provided between the large diameter portion (12a) and the small diameter portion (12b), and the outer diameter is gradually reduced.

The downstream end of the suction pipe (12) overlaps the upstream side of the suction port (64) when viewed from the axial direction. The downstream end of the suction tube (12) penetrates inward of the opening surface (60a) of the suction port (64) in the fixed scroll (60).

Further, a tapered portion (64a) is provided on the peripheral portion on the upstream side of the suction port (64) in the fixed scroll (60). The taper portion (64a) gradually widens toward the upstream side of the suction port (64).

-Effect of Embodiment 2-
In the scroll compressor (10) of the second embodiment, a tapered portion (64a) is provided on the peripheral portion on the upstream side of the suction port (64) in the fixed scroll (60).

In the second embodiment, the opening width on the upstream side of the suction port (64) is widened by providing the tapered portion (64a). This facilitates the flow of oil along the tapered portion (64a) and allows the oil to efficiently flow into the suction port (64).

<< Other Embodiments >>
The embodiment may have the following configuration.

In the second embodiment, in the configuration in which the tapered portion (64a) is provided on the peripheral edge of the suction port (64), the downstream end of the suction pipe (12) is inserted into the suction port (64). It is not limited to this form.

For example, in a configuration in which a tapered portion (64a) is provided on the peripheral edge of the suction port (64), the downstream end of the suction pipe (12) is the opening surface (60a) of the suction port (64) as in the first modification. May be arranged on the same plane as. Further, as in the second modification, the downstream end of the suction pipe (12) may be arranged at a position axially outward from the opening surface (60a) of the suction port (64).

Although the embodiments and modifications have been described above, it will be understood that various modifications of the forms and details are possible without departing from the purpose and scope of the claims. Further, the above embodiments and modifications may be appropriately combined or replaced as long as the functions of the subject of the present disclosure are not impaired.

As described above, the present disclosure is useful for scroll compressors.

10 scroll compressor
12 Inhalation tube
12a Large diameter part
12b small diameter part
12c reduced diameter part
20 casing
23 Upper space (internal space)
60 Fixed scroll
60a Aperture surface
64 Inhalation port
64a taper part
70 Movable scroll

The present disclosure relates to a scroll compressor.

Patent Document 1 describes a first operation in which only the fixed side oil groove and the movable side oil groove of the fixed side oil groove, the movable side oil groove, and the compression chamber (fluid chamber) communicate with each other, and the movable side oil after the first operation. A scroll type compressor is disclosed in which the groove is configured to perform a second operation in which both the fixed side oil groove and the compression chamber communicate with each other at the same time.

Japanese Unexamined Patent Publication No. 2016-160816

In the invention of Patent Document 1, since the movable oil groove is communicated with the space radially outside the movable scroll in the compression chamber, it is difficult for oil to be supplied to the space inside the movable scroll in the compression chamber. It has become.

An object of the present disclosure is to enable oil to be supplied to the inner and outer spaces in the radial direction of the movable scroll in the compression chamber.

A first aspect of the present disclosure is between a casing (20) to which a suction tube (12) is connected, a fixed scroll (60) housed in the casing (20), and the fixed scroll (60). It is intended for scroll compressors equipped with a movable scroll (70) that forms a compression chamber (S). An internal space (23) through which an oil-containing refrigerant flows is provided inside the casing (20), and the fixed scroll (60) includes the internal space (23) and the compression chamber (S). The suction pipe (12) is provided in the internal space (23) on the large diameter portion (12a) and on the downstream side of the large diameter portion (12a). A small diameter portion (12b) having an outer diameter smaller than that of the large diameter portion (12a) is provided between the large diameter portion (12a) and the small diameter portion (12b), and the outer diameter is gradually reduced. It has a diameter portion (12c), and the downstream end of the small diameter portion (12b) is arranged at a position overlapping the upstream end of the suction port (64) when viewed from the axial direction, and is outside the small diameter portion (12b). The diameter is smaller than the diameter at the upstream end of the suction port (64).

In the first aspect, the suction tube (12) has a large diameter portion (12a), a small diameter portion (12b), and a reduced diameter portion (12c). The reduced diameter portion (12c) is provided between the large diameter portion (12a) and the small diameter portion (12b), and the outer diameter is gradually reduced. Further, the outer diameter of the small diameter portion (12b) is smaller than the inner diameter of the upstream end of the suction port (64), and the oil flowing through the internal space (23) is with the small diameter portion (12b) of the suction pipe (12). It flows into the suction port (64) through a gap with the suction port (64).

As a result, oil can be supplied to the inner and outer spaces in the radial direction of the movable scroll (70) in the compression chamber (S).

In the second aspect of the present disclosure, in the first aspect, a tapered portion (64a) is provided on the peripheral portion on the upstream side of the suction port (64) in the fixed scroll (60).

In the second aspect, by providing the tapered portion (64a), the opening width on the upstream side of the suction port (64) is widened. This facilitates the flow of oil along the tapered portion (64a) and allows the oil to efficiently flow into the suction port (64).

In a third aspect of the present disclosure, in the first or second aspect, the downstream end of the suction pipe (12) is the same as the opening surface (60a) of the suction port (64) in the fixed scroll (60). It is arranged on a plane or at a position distant from the opening surface (60a) in the axial direction.

In the third aspect, the downstream end of the suction pipe (12) is flush with the opening surface (60a) of the suction port (64) in the fixed scroll (60) or axially outside the opening surface (60a). It is placed at a distant position.

As a result, the oil flowing through the internal space (23) easily flows into the suction port (64) through the gap between the downstream end of the suction pipe (12) and the opening surface (60a).

FIG. 1 is a vertical cross-sectional view showing the configuration of the scroll compressor according to the first embodiment. FIG. 2 is a diagram showing a positional relationship between the suction pipe and the suction port. FIG. 3 is a cross-sectional view showing the configuration of a fixed scroll and a movable scroll. FIG. 4 is a view corresponding to FIG. 2 showing the configuration of the scroll compressor according to the first modification of the first embodiment. FIG. 5 is a view corresponding to FIG. 2 showing the configuration of the scroll compressor according to the second modification of the first embodiment. FIG. 6 is a view corresponding to FIG. 2 showing the configuration of the scroll compressor according to the second embodiment.

<< Embodiment 1 >>
The first embodiment will be described.

As shown in FIG. 1, the scroll compressor (10) includes a casing (20), an electric motor (30) and a compression mechanism (40) housed in the casing (20). The casing (20) is formed in a vertically long cylindrical shape and is configured in a closed dome type.

The scroll compressor (10) is provided in the refrigerant circuit of the vapor compression refrigeration cycle. In the refrigerant circuit, the refrigerant compressed by the scroll compressor (10) is condensed by the condenser, depressurized by the depressurizing mechanism, evaporated by the evaporator, and sucked into the scroll compressor (10).

The electric motor (30) includes a stator (31) fixed to a casing (20) and a rotor (32) arranged inside the stator (31). The rotor (32) is fixed to the drive shaft (11).

An oil reservoir (21) for storing oil is formed at the bottom of the casing (20). A suction pipe (12) is connected to the upper part of the casing (20). A discharge pipe (13) is connected to the central portion of the casing (20).

A housing (50) is fixed to the casing (20). The housing (50) is located above the electric motor (30). A compression mechanism (40) is arranged above the housing (50). The inflow end of the discharge pipe (13) is located between the electric motor (30) and the housing (50).

The drive shaft (11) extends vertically along the central axis of the casing (20). The drive shaft (11) has a spindle portion (14) and an eccentric portion (15) connected to the upper end of the spindle portion (14).

The lower part of the spindle portion (14) is rotatably supported by the casing (20) and the lower bearing (22). The lower bearing (22) is fixed to the inner peripheral surface of the casing (20). The upper portion of the spindle portion (14) extends through the housing (50) and is rotatably supported by the upper bearing (51) of the housing (50).

The compression mechanism (40) includes a fixed scroll (60) and a movable scroll (70). The fixed scroll (60) is fixed to the top surface of the housing (50). The movable scroll (70) is located between the fixed scroll (60) and the housing (50).

The housing (50) is formed with an annular portion (52) and a recess (53). The annular portion (52) is provided on the outer peripheral portion of the housing (50). The recess (53) is formed in the upper center of the housing (50), and the center thereof is formed in a concave dish shape. An upper bearing (51) is provided below the recess (53).

The housing (50) is fixed to the inside of the casing (20) by press fitting. The inner peripheral surface of the casing (20) and the outer peripheral surface of the annular portion (52) of the housing (50) are in close contact with each other in an airtight manner over the entire circumference. The housing (50) divides the inside of the casing (20) into an upper space (23) (internal space) in which the compression mechanism (40) is accommodated and a lower space (24) in which the electric motor (30) is accommodated. ing.

The fixed scroll (60) has a fixed side end plate (61), a substantially tubular outer wall (63) standing on the outer edge of the lower surface of the fixed side end plate (61), and an outer wall (61) on the fixed side end plate (61). It is equipped with a spiral fixed side wrap (62) that stands inside 63).

The fixed-side end plate (61) is located on the outer peripheral side and is formed continuously with the fixed-side wrap (62). The tip surface of the fixed side wrap (62) and the tip surface of the outer peripheral wall (63) are formed substantially flush with each other. Further, the fixed scroll (60) is fixed to the housing (50).

The movable scroll (70) is formed on the movable side end plate (71), the spiral movable side wrap (72) formed on the upper surface of the movable side end plate (71), and the central portion of the lower surface of the movable side end plate (71). It is equipped with a boss part (73).

The boss portion (73) is connected to the drive shaft (11) by inserting the eccentric portion (15) of the drive shaft (11). An Oldham joint (46) is provided at the top of the housing (50). The Oldham fitting (46) prevents the movable scroll (70) from rotating.

In the compression mechanism (40), a compression chamber (S) into which the refrigerant flows is formed between the fixed scroll (60) and the movable scroll (70). The movable scroll (70) is arranged so that the movable side lap (72) meshes with the fixed side lap (62) of the fixed scroll (60). Here, the lower surface of the outer peripheral wall (63) of the fixed scroll (60) is the surface facing the movable scroll (70). Further, the upper surface of the movable end plate (71) of the movable scroll (70) serves as a surface facing the fixed scroll (60).

As shown in FIG. 2, an suction port (64) communicating with the compression chamber (S) is formed on the outer peripheral wall (63) of the fixed scroll (60). The suction port (64) extends vertically through. On the upstream side of the suction port (64), a suction pipe (12) extending in the vertical direction is arranged.

The suction tube (12) is connected to the top of the casing (20). At the downstream end of the suction pipe (12), a part of the outer peripheral portion is cut out over the entire circumference. As a result, the suction pipe (12) has a large diameter portion (12a), a small diameter portion (12b), and a reduced diameter portion (12c).

The small diameter portion (12b) is provided on the downstream side of the large diameter portion (12a) and has a smaller outer diameter than the large diameter portion (12a). The outer diameter of the small diameter portion (12b) is formed to be smaller than the inner diameter of the suction port (64). The reduced diameter portion (12c) is provided between the large diameter portion (12a) and the small diameter portion (12b), and the outer diameter is gradually reduced.

The downstream end of the suction pipe (12) overlaps the upstream side of the suction port (64) when viewed from the axial direction. In the example shown in FIG. 2, the suction pipe (12) is arranged so as to be coaxial with the suction port (64). The downstream end of the suction tube (12) penetrates inward of the opening surface (60a) of the suction port (64) in the fixed scroll (60).

As a result, there is a ring between the outer peripheral portion of the downstream end of the suction pipe (12) (the outer peripheral portion of the small diameter portion (12b)) and the inner peripheral portion of the upstream end of the suction port (64) when viewed from the axial direction. There is a gap that opens in a shape. The suction port (64) communicates with the upper space (23) and the compression chamber (S) through a ring-shaped opening.

A refrigerant containing oil droplets (25) is flowing in the upper space (23). The refrigerant containing the oil droplets (25) flowing through the upper space (23) is sucked into the suction port (64) through the ring-shaped opening. In the example shown in FIG. 2, the suction pipe (12) is arranged so as to be coaxial with the suction port (64), but the flow of the refrigerant passing through the opening toward the suction port (64) is allowed to flow. It may be arranged with a slight shift as long as it does not interfere.

As shown in FIG. 3, the compression chamber (S) is divided into an outer chamber (S1) radially outside the movable scroll (70) and an inner chamber (S2) radially inside the movable scroll (70). It is partitioned. Specifically, when the inner peripheral surface of the outer peripheral wall (63) of the fixed scroll (60) and the outer peripheral surface of the movable side wrap (72) of the movable scroll (70) are substantially in contact with each other, the outer peripheral surface is sandwiched between the contact portions. The room (S1) and the inner room (S2) are separated.

As shown in FIG. 1, a discharge port (65) is formed in the center of the fixed side end plate (61) of the fixed scroll (60). A high-pressure chamber (66) through which the discharge port (65) opens is formed on the upper surface of the fixed-side end plate (61) of the fixed scroll (60). The high pressure chamber (66) communicates with the lower space (24) via a passage (not shown) formed in the fixed side end plate (61) and the housing (50) of the fixed scroll (60). The high-pressure refrigerant compressed by the compression mechanism (40) flows out to the lower space (24).

Inside the drive shaft (11), a refueling hole (16) extending in the vertical direction from the lower end to the upper end of the drive shaft (11) is formed. The lower end of the drive shaft (11) is immersed in the oil reservoir (21). The oil supply hole (16) supplies the oil from the oil reservoir (21) to the lower bearing (22) and the upper bearing (51), and also supplies the oil to the gap between the boss portion (73) and the drive shaft (11). The oil filler hole (16) opens on the upper end surface of the drive shaft (11) to supply oil above the drive shaft (11).

The recess (53) of the housing (50) communicates with the fuel filler hole (16) of the drive shaft (11) via the inside of the boss portion (73) of the movable scroll (70). By supplying high-pressure oil to the recess (53), a high-pressure pressure corresponding to the discharge pressure of the compression mechanism (40) acts. The movable scroll (70) is pressed against the fixed scroll (60) by the high pressure of the recess (53).

An oil passage (55) is formed inside the housing (50) and the fixed scroll (60). The inflow end of the oil passage (55) communicates with the recess (53) of the housing (50). The outflow end of the oil passage (55) is open to the opposite surface of the fixed scroll (60). The oil passage (55) supplies the high-pressure oil in the recess (53) to the facing surface of the movable side end plate (71) of the movable scroll (70) and the outer peripheral wall (63) of the fixed scroll (60).

As shown in FIG. 3, a refueling groove (80) is formed on the facing surface of the outer peripheral wall (63) of the fixed scroll (60). The refueling groove (80) is formed on the outer peripheral wall (63) of the fixed scroll (60) facing the movable side end plate (71) of the movable scroll (70). The refueling groove (80) extends in a substantially arc shape along the inner peripheral surface of the outer peripheral wall (63) of the fixed scroll (60). An oil passage (55) communicates with the oil passage (80), and oil is supplied from the oil passage (55) to the oil passage (80).

A plurality of notches (68) are provided on the outer peripheral portion of the fixed scroll (60). The notch (68) communicates with the upper space (23). The oil supplied to the refueling groove (80) flows toward the upper space (23) through the notch (68).

-Driving operation-
The basic operation of the scroll compressor (10) will be described. As shown in FIG. 1, when the electric motor (30) is operated, the movable scroll (70) of the compression mechanism (40) is rotationally driven. Since the movable scroll (70) is prevented from rotating by the Oldham joint (46), only the eccentric rotation is performed around the axis of the drive shaft (11).

As shown in FIG. 3, when the eccentric rotation of the movable scroll (70) rotates, the compression chamber (S) is divided into an outer chamber (S1) and an inner chamber (S2). A plurality of inner chambers (S2) are formed between the fixed side lap (62) of the fixed scroll (60) and the movable side lap (72) of the movable scroll (70). When the movable scroll (70) rotates eccentrically, these inner chambers (S2) gradually approach the center (discharge port (65)), and the volume of these inner chambers (S2) becomes smaller. As a result, the refrigerant is compressed in the inner chamber (S2).

When the inner chamber (S2) having the smallest volume communicates with the discharge port (65), the high-pressure gas refrigerant in the inner chamber (S2) is discharged to the high-pressure chamber (66) through the discharge port (65). The high-pressure refrigerant gas in the high-pressure chamber (66) flows out to the lower space (24) via the passages formed in the fixed scroll (60) and the housing (50). The high-pressure gas refrigerant in the lower space (24) is discharged to the outside of the casing (20) via the discharge pipe (13).

-Refueling operation-
Next, the oil refueling operation in the scroll compressor (10) will be described in detail with reference to FIGS. 1 to 3.

When a high-pressure gas refrigerant flows out into the lower space (24) of the scroll compressor (10), the lower space (24) becomes a high-pressure atmosphere, and the oil in the oil reservoir (21) also becomes a high-pressure state. The high-pressure oil in the oil reservoir (21) flows upward through the oil supply hole (16) of the drive shaft (11), and from the opening at the upper end of the eccentric part (15) of the drive shaft (11), the movable scroll (70) It flows out to the inside of the boss part (73).

The oil supplied to the boss portion (73) is supplied to the gap between the eccentric portion (15) and the boss portion (73) of the drive shaft (11). As a result, the recess (53) of the housing (50) becomes a high-pressure atmosphere corresponding to the discharge pressure of the compression mechanism (40). The high pressure of the recess (53) presses the movable scroll (70) against the fixed scroll (60).

The high-pressure oil accumulated in the recess (53) flows through the oil passage (55) and flows out to the oil supply groove (80). As a result, high-pressure oil corresponding to the discharge pressure of the compression mechanism (40) is supplied to the oil supply groove (80). The oil in the refueling groove (80) is used to lubricate the opposite surfaces of the fixed scroll (60) and the movable scroll (70).

The oil supplied to the opposite surface of the fixed scroll (60) flows outward in the radial direction due to the relative rotation of the movable scroll (70) with respect to the fixed scroll (60), and the cutout (68) is formed. It is discharged to the upper space (23) through it.

The refrigerant containing the oil droplets (25) discharged into the upper space (23) collides with the outer peripheral portion of the suction pipe (12). At this time, oil adheres to the outer peripheral surface of the suction pipe (12). Here, the oil adhering to the large diameter portion (12a) of the suction pipe (12) flows along the inclined surface of the reduced diameter portion (12c) and then smoothly flows toward the small diameter portion (12b).

As described above, even in the suction pipe (12) having the large diameter portion (12a) and the small diameter portion (12b), the reduced diameter portion (12c) is between the large diameter portion (12a) and the small diameter portion (12b). ), The oil adhering to the outer peripheral surface of the suction pipe (12) can be smoothly flowed down.

The oil flowing down along the outer peripheral surface of the suction pipe (12) is supplied to the suction port (64) through the gap between the suction pipe (12) and the suction port (64). The oil sucked into the suction port (64) is distributed to the outer chamber (S1) radially outside the movable side wrap (72) of the movable scroll (70) and to the inner chamber (S2) radially inside. (See the arrow line in FIG. 3). Thereby, the oil sealability of the outer chamber (S1) and the inner chamber (S2) can be enhanced.

-Effect of Embodiment 1-
The scroll compressor (10) of the first embodiment has a casing (20) to which the suction pipe (12) is connected, a fixed scroll (60) housed in the casing (20), and a fixed scroll (60). It is equipped with a movable scroll (70) that forms a compression chamber (S) between them. An upper space (23) (internal space) through which an oil-containing refrigerant flows is provided inside the casing (20), and the fixed scroll (60) has an upper space (23) and a compression chamber (S). The suction pipe (12) is provided in the upper space (23) on the downstream side of the large diameter portion (12a) and the large diameter portion (12a) and has a large diameter. A small diameter portion (12b) whose outer diameter is smaller than that of the portion (12a) and a reduced diameter portion (12c) provided between the large diameter portion (12a) and the small diameter portion (12b) and whose outer diameter gradually decreases. The downstream end of the small diameter portion (12b) is arranged at a position overlapping the upstream end of the suction port (64) when viewed from the axial direction, and the outer diameter of the small diameter portion (12b) is that of the suction port (64). It is smaller than the diameter of the upstream end.

In the first embodiment, the suction pipe (12) has a large diameter portion (12a), a small diameter portion (12b), and a reduced diameter portion (12c). The reduced diameter portion (12c) is provided between the large diameter portion (12a) and the small diameter portion (12b), and the outer diameter is gradually reduced. Further, the outer diameter of the small diameter portion (12b) is smaller than the inner diameter of the upstream end of the suction port (64), and the oil flowing through the internal space (23) is with the small diameter portion (12b) of the suction pipe (12). It flows into the suction port (64) through a gap with the suction port (64).

As a result, oil can be supplied to the inner and outer spaces in the radial direction of the movable scroll (70) in the compression chamber (S).

Specifically, the oil supplied to the facing surface of the fixed scroll (60) flows outward in the radial direction due to the relative rotation of the movable scroll (70) with respect to the fixed scroll (60), and the notch portion. It is discharged to the upper space (23) through (68).

The refrigerant containing the oil droplets (25) discharged into the upper space (23) is supplied to the suction port (64) through the gap between the suction pipe (12) and the suction port (64). After that, the oil is distributed to the inner and outer spaces in the radial direction of the movable scroll (70) in the compression chamber (S). Thereby, the oil sealing property of the inner and outer spaces can be improved.

Further, by continuously connecting the large diameter portion (12a) and the small diameter portion (12b) with the reduced diameter portion (12c), the oil adhering to the outer peripheral surface of the suction pipe (12) can be removed from the small diameter portion (12b). ) To the suction port (64).

Specifically, when the suction pipe (12) is not provided with the reduced diameter portion (12c), the oil flowing along the outer peripheral surface of the large diameter portion (12a) flows between the large diameter portion (12a) and the small diameter portion. It will fall as it is at the step with (12b). In this case, the oil does not flow from the large diameter portion (12a) to the small diameter portion (12b), and the oil cannot flow from the small diameter portion (12b) to the suction port (64).

On the other hand, in the present embodiment, the oil flowing along the outer peripheral surface of the large diameter portion (12a) can be smoothly flowed from the reduced diameter portion (12c) to the small diameter portion (12b).

− Modification 1 of Embodiment 1
Hereinafter, the same parts as those in the first embodiment are designated by the same reference numerals, and only the differences will be described.

As shown in FIG. 4, the suction pipe (12) has a large diameter portion (12a), a small diameter portion (12b), and a reduced diameter portion (12c). The small diameter portion (12b) is provided on the downstream side of the large diameter portion (12a) and has a smaller outer diameter than the large diameter portion (12a). The outer diameter of the small diameter portion (12b) is formed to be smaller than the inner diameter of the suction port (64). The reduced diameter portion (12c) is provided between the large diameter portion (12a) and the small diameter portion (12b), and the outer diameter is gradually reduced.

The downstream end of the suction pipe (12) overlaps the upstream side of the suction port (64) when viewed from the axial direction. The downstream end of the suction tube (12) is coplanar with the opening surface (60a) of the suction port (64) in the fixed scroll (60).

As a result, there is a ring between the outer peripheral portion of the downstream end of the suction pipe (12) (the outer peripheral portion of the small diameter portion (12b)) and the inner peripheral portion of the upstream end of the suction port (64) when viewed from the axial direction. There is a gap that opens in a shape. The refrigerant containing the oil droplets (25) flowing through the upper space (23) is sucked into the suction port (64) through the gap between the suction pipe (12) and the suction port (64).

-Effect of variant 1-
In the scroll compressor (10) of the present modification 1, the downstream end of the suction pipe (12) is arranged on the same plane as the opening surface (60a) of the suction port (64) in the fixed scroll (60).

In the first modification, the downstream end of the suction pipe (12) is arranged on the same plane as the opening surface (60a) of the suction port (64) in the fixed scroll (60).

As a result, the oil flowing through the upper space (23) easily flows into the suction port (64) through the gap between the downstream end of the suction pipe (12) and the opening surface (60a). That is, as compared with the case where the lower end portion of the suction pipe (12) is inserted into the suction port (64), the suction effect due to the dynamic pressure can be exhibited and the efficiency can be improved.

− Modification of Embodiment 1 2-
As shown in FIG. 5, the suction pipe (12) has a large diameter portion (12a), a small diameter portion (12b), and a reduced diameter portion (12c). The small diameter portion (12b) is provided on the downstream side of the large diameter portion (12a) and has a smaller outer diameter than the large diameter portion (12a). The outer diameter of the small diameter portion (12b) is formed to be smaller than the inner diameter of the suction port (64). The reduced diameter portion (12c) is provided between the large diameter portion (12a) and the small diameter portion (12b), and the outer diameter is gradually reduced.

The downstream end of the suction pipe (12) overlaps the upstream side of the suction port (64) when viewed from the axial direction. The downstream end of the suction pipe (12) is located axially outwardly from the opening surface (60a) of the suction port (64) in the fixed scroll (60).

As a result, there is a ring between the outer peripheral portion of the downstream end of the suction pipe (12) (the outer peripheral portion of the small diameter portion (12b)) and the inner peripheral portion of the upstream end of the suction port (64) when viewed from the axial direction. There is a gap that opens in a shape. Further, a predetermined gap is provided between the downstream end of the suction pipe (12) and the opening surface (60a). The refrigerant containing the oil droplets (25) flowing through the upper space (23) is sucked into the suction port (64) through the gap between the suction pipe (12) and the suction port (64).

-Effect of variant 2-
In the scroll compressor (10) of the present modification 2, the downstream end of the suction pipe (12) is located at a position axially outward from the opening surface (60a) of the suction port (64) in the fixed scroll (60). Have been placed.

In the second modification, the downstream end of the suction pipe (12) is arranged at a position axially outward from the opening surface (60a) of the suction port (64) in the fixed scroll (60).

As a result, the oil flowing through the upper space (23) easily flows into the suction port (64) through the gap between the downstream end of the suction pipe (12) and the opening surface (60a). That is, as compared with the case where the lower end portion of the suction pipe (12) is inserted into the suction port (64), the suction effect due to the dynamic pressure can be exhibited and the efficiency can be improved.

<< Embodiment 2 >>
The second embodiment will be described.

As shown in FIG. 6, the suction pipe (12) has a large diameter portion (12a), a small diameter portion (12b), and a reduced diameter portion (12c). The small diameter portion (12b) is provided on the downstream side of the large diameter portion (12a) and has a smaller outer diameter than the large diameter portion (12a). The outer diameter of the small diameter portion (12b) is formed to be smaller than the inner diameter of the suction port (64). The reduced diameter portion (12c) is provided between the large diameter portion (12a) and the small diameter portion (12b), and the outer diameter is gradually reduced.

The downstream end of the suction pipe (12) overlaps the upstream side of the suction port (64) when viewed from the axial direction. The downstream end of the suction tube (12) penetrates inward of the opening surface (60a) of the suction port (64) in the fixed scroll (60).

Further, a tapered portion (64a) is provided on the peripheral portion on the upstream side of the suction port (64) in the fixed scroll (60). The taper portion (64a) gradually widens toward the upstream side of the suction port (64).

-Effect of Embodiment 2-
In the scroll compressor (10) of the second embodiment, a tapered portion (64a) is provided on the peripheral portion on the upstream side of the suction port (64) in the fixed scroll (60).

In the second embodiment, the opening width on the upstream side of the suction port (64) is widened by providing the tapered portion (64a). This facilitates the flow of oil along the tapered portion (64a) and allows the oil to efficiently flow into the suction port (64).

<< Other Embodiments >>
The embodiment may have the following configuration.

In the second embodiment, in the configuration in which the tapered portion (64a) is provided on the peripheral edge of the suction port (64), the downstream end of the suction pipe (12) is inserted into the suction port (64). It is not limited to this form.

For example, in a configuration in which a tapered portion (64a) is provided on the peripheral edge of the suction port (64), the downstream end of the suction pipe (12) is the opening surface (60a) of the suction port (64) as in the first modification. May be arranged on the same plane as. Further, as in the second modification, the downstream end of the suction pipe (12) may be arranged at a position axially outward from the opening surface (60a) of the suction port (64).

Although the embodiments and modifications have been described above, it will be understood that various modifications of the forms and details are possible without departing from the purpose and scope of the claims. Further, the above embodiments and modifications may be appropriately combined or replaced as long as the functions of the subject of the present disclosure are not impaired.

As described above, the present disclosure is useful for scroll compressors.

10 scroll compressor
12 Inhalation tube
12a Large diameter part
12b small diameter part
12c reduced diameter part
20 casing
23 Upper space (internal space)
60 Fixed scroll
60a Aperture surface
64 Inhalation port
64a taper part
70 Movable scroll

Claims (3)

Movable to form a compression chamber (S) between the casing (20) to which the suction pipe (12) is connected, the fixed scroll (60) housed in the casing (20), and the fixed scroll (60). A scroll compressor with a scroll (70)
Inside the casing (20), an internal space (23) through which a refrigerant containing oil flows is provided.
The fixed scroll (60) has a suction port (64) that communicates with the internal space (23) and the compression chamber (S).
The suction pipe (12) includes a large-diameter portion (12a), a small-diameter portion (12b) provided on the downstream side of the large-diameter portion (12a) and having an outer diameter smaller than that of the large-diameter portion (12a). It has a reduced diameter portion (12c) provided between the large diameter portion (12a) and the small diameter portion (12b) and the outer diameter gradually decreases.
The downstream end of the small diameter portion (12b) is arranged at a position overlapping the upstream end of the suction port (64) when viewed from the axial direction.
A scroll compressor in which the outer diameter of the small diameter portion (12b) is smaller than the diameter of the upstream end of the suction port (64). In claim 1,
A scroll compressor in which a tapered portion (64a) is provided on the upstream peripheral portion of the fixed scroll (60) on the upstream side of the suction port (64). In claim 1 or 2,
The downstream end of the suction pipe (12) is coplanar with the opening surface (60a) of the suction port (64) in the fixed scroll (60), or is axially outward from the opening surface (60a). Scroll compressor located in position.

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