JP2014118932A - Rotary compressor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce pressure loss caused by clogging and ensure a sufficient an oil supply amount by increasing the surface area of an oil filter immersed in oil.SOLUTION: A suction nozzle (60) is provided in a lower end portion of a driving shaft (23) and oil absorbed from an oil reservoir 17 circulates in an oil supply path (27). Surroundings of the suction nozzle (60) are covered with an oil filter (63), and the oil filter (63) captures foreign matters contained in the oil in the oil reservoir (17). The suction nozzle (60) and the oil filter (63) are provided in an internal space (61) of a skirt member (65). The skirt member (65) is formed into a cylindrical shape having a lower opening, and a lower end portion of the skirt member (65) is located below an oil level of the oil reservoir (17).

Description

  The present invention relates to a rotary compressor.

  2. Description of the Related Art Conventionally, a scroll compressor including a casing and a compression mechanism housed in the casing and having a fixed scroll and a movable scroll and having a compression chamber formed between the fixed scroll and the movable scroll is known (for example, Patent Document 1). In such a scroll compressor, lubricating oil is supplied to the sliding portion to prevent seizure.

  By the way, if foreign matter such as abrasion powder of the sliding portion is included in the lubricating oil, the foreign matter is supplied together with the lubricating oil to the sliding portion, and the sliding portion may be abnormally worn. Therefore, in the scroll compressor of Patent Document 1, an oil filter is provided so as to surround the oil pump that sucks up oil from the oil reservoir, and the foreign matter is collected by the oil filter so that the foreign matter does not enter the oil supply path. Yes.

JP-A-11-013654

  However, in the conventional scroll compressor, when the amount of oil collected in the oil reservoir is small, foreign matter is collected only by the oil filter near the tip of the oil pump, so the collection area of the oil filter is small, There is a problem that the oil filter is clogged only by collecting a small amount of foreign matter, and the pressure loss increases. And there was a possibility that oil could not be sucked up enough by resistance of an oil filter, and sufficient oil supply amount could not be secured.

  The present invention has been made in view of the above points, and its purpose is to increase the surface area of an oil filter immersed in oil, reduce pressure loss due to clogging, and ensure a sufficient amount of oil supply. There is to do.

  The present invention includes a casing (11) provided with an oil reservoir (17) at the bottom, a compression mechanism (30) disposed on an upper portion in the casing (11) and compressing a refrigerant, and the casing (11 The following solution was taken for a rotary compressor having a drive mechanism (20) having a drive shaft (23) that extends in the vertical direction to drive the compression mechanism (30). .

That is, the first invention is provided at the lower end of the drive shaft (23) so as to communicate with an oil supply passage (27) formed in the drive shaft (23), and the oil reservoir (17) A suction member (60) for sucking up and circulating in the oil supply passage (27);
An oil filter (63) that covers the periphery of the suction member (60) and collects foreign matter contained in the oil in the oil reservoir (17);
The suction member (60) and the oil filter (63) are provided in the inner space (61), and the lower end is formed from the oil surface of the oil reservoir (17). And a skirt member (65) disposed so as to be positioned below.

  In the first invention, the suction member (60) is provided at the lower end of the drive shaft (23), and the oil sucked up from the oil reservoir (17) is circulated through the oil supply passage (27). The periphery of the suction member (60) is covered with an oil filter (63), and foreign matter contained in the oil in the oil reservoir (17) is collected. The suction member (60) and the oil filter (63) are provided in the internal space (61) of the skirt member (65). The skirt member (65) is formed in a cylindrical shape having an opening at the bottom, and a lower end portion thereof is positioned below the oil surface of the oil reservoir (17).

  With such a configuration, it is possible to increase the surface area of the oil filter (63) immersed in oil, reduce pressure loss due to clogging, and secure a sufficient amount of oil supply. Specifically, when the compression mechanism (30) is driven, the outside of the skirt member (65) becomes higher in pressure than the internal space (61), and the internal space (61) reaches a position where the external refrigerant pressure and the internal refrigerant pressure are balanced. The oil level rises. Further, the refrigerant accumulated in the internal space (61) of the skirt member (65) is discharged, and the internal space (61) is decompressed. As a result, the oil level of the oil reservoir (17) rises in the internal space (61) of the skirt member (65), and not only the lower side of the oil filter (63) but also the outer peripheral side thereof is immersed in the oil. This means that the surface area immersed in the oil in the oil filter (63) is increased. Therefore, foreign matter contained in the oil is collected over a wide range of the oil filter (63), suppressing the uneven distribution of the foreign matter on the oil filter (63) and clogging the oil filter (63). be able to. Thereby, pressure loss can be reduced and sufficient oil supply amount can be ensured.

According to a second invention, in the first invention,
The lower end portion of the skirt member (65) is located below the lower end portion of the suction member (60).

  In the second invention, the lower end of the skirt member (65) is positioned below the lower end of the suction member (60). With such a configuration, even if a small amount of oil has accumulated in the oil reservoir (17), the lower end of the suction member (60) can be obtained by depressurizing the internal space (61) and raising the oil level. Can be immersed in the oil surface to ensure the amount of oil supply.

According to a third invention, in the first or second invention,
The suction port (60a) of the suction member (60) opens at a position closer to the upper part in the internal space (61) of the skirt member (65).

  In the third aspect of the invention, the suction port (60a) of the suction member (60) opens at a position closer to the upper part in the internal space (61) of the skirt member (65). With such a configuration, since the refrigerant accumulated in the internal space (61) of the skirt member (65) can be collected from the suction port (60a), the oil level is high in the internal space (61). You can keep holding.

  According to the present invention, by increasing the surface area of the oil filter (63) with a relatively simple configuration, pressure loss due to clogging can be reduced, and a sufficient amount of oil can be secured. Specifically, when the compression mechanism (30) is driven, the outside of the skirt member (65) becomes higher in pressure than the internal space (61), and the internal space (61) reaches a position where the external refrigerant pressure and the internal refrigerant pressure are balanced. The oil level rises. Further, the refrigerant accumulated in the internal space (61) of the skirt member (65) is discharged, and the internal space (61) is decompressed. As a result, the oil level of the oil reservoir (17) rises in the internal space (61) of the skirt member (65), and not only the lower side of the oil filter (63) but also the outer peripheral side thereof is immersed in the oil. This means that the surface area immersed in the oil in the oil filter (63) is increased. Therefore, foreign matter contained in the oil is collected over a wide range of the oil filter (63), suppressing the uneven distribution of the foreign matter on the oil filter (63) and clogging the oil filter (63). be able to. Thereby, pressure loss can be reduced and sufficient oil supply amount can be ensured.

It is side surface sectional drawing which shows the structure of the scroll compressor which concerns on Embodiment 1 of this invention. It is side surface sectional drawing in the compressor stop which shows the periphery of a skirt member partially expanded. FIG. 3 is a view corresponding to FIG. 2 showing a state in which the internal space of the skirt member is filled with oil. It is side surface sectional drawing which shows the structure of the scroll compressor which concerns on this Embodiment 2. FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. It should be noted that the following description of the preferred embodiment is merely illustrative in nature and is not intended to limit the present invention, its application, or its use.

Embodiment 1
FIG. 1 is a side sectional view showing a configuration of a scroll compressor according to Embodiment 1 of the present invention. The scroll compressor (10) is connected to a refrigerant circuit that performs a vapor compression refrigeration cycle of an air conditioner, for example. The scroll compressor (10) includes a casing (11), a rotary compression mechanism (30), and a drive mechanism (20) that rotationally drives the compression mechanism (30).

  The casing (11) is composed of a vertically long cylindrical hermetic container closed at both ends, and has a cylindrical body (12) and an upper end plate (13) fixed to the upper end side of the body (12). And a lower end plate (14) fixed to the lower end side of the body (12).

  The inside of the casing (11) is partitioned vertically by a housing (50) joined to the inner peripheral surface of the casing (11). The space above the housing (50) constitutes the upper space portion (15), and the space below the housing (50) constitutes the lower space portion (16). The configuration of the housing (50) will be described in detail later.

  An oil reservoir (17) for storing oil for lubricating the sliding portion of the scroll compressor (10) is provided at the bottom of the lower space (16) in the casing (11).

  A suction pipe (18) and a discharge pipe (19) are attached to the casing (11). The suction pipe (18) passes through the upper part of the upper end plate (13). One end of the suction pipe (18) is connected to a suction pipe joint (47) included in the rotary compression mechanism (30). The discharge pipe (19) penetrates the trunk part (12). The end of the discharge pipe (19) opens into the lower space (16) of the casing (11).

  The drive mechanism (20) includes a motor (21) and a drive shaft (23). The motor (21) is accommodated in the lower space (16) of the casing (11). The motor (21) includes a stator (21a) and a rotor (21b) formed in a cylindrical shape. The stator (21a) is fixed to the body (12) of the casing (11). A rotor (21b) is disposed in the hollow portion of the stator (21a). A drive shaft (23) is fixed in the hollow portion of the rotor (21b) so as to penetrate the rotor (21b), and the rotor (21b) and the drive shaft (23) rotate integrally. .

  The drive shaft (23) has a main shaft portion (24) extending in the vertical direction and an eccentric portion (25) provided on the upper side of the main shaft portion (24), and these are integrally formed. The eccentric portion (25) is formed with a diameter smaller than the maximum diameter of the main shaft portion (24), and the shaft center of the eccentric portion (25) is eccentric by a predetermined distance with respect to the shaft center of the main shaft portion (24). Yes. A lower end portion of the main shaft portion (24) of the drive shaft (23) is rotatably supported by a lower bearing portion (28) fixed near the lower end of the body portion (12) of the casing (11). The upper end portion of the main shaft portion (24) is rotatably supported by a bearing portion (53) included in the housing (50). An oil supply path (27) is formed inside the drive shaft (23).

  A suction nozzle (60) as a suction member for sucking up oil is provided at the lower end of the drive shaft (23). The suction nozzle (60) constitutes a positive displacement pump. The suction port (60a) of the suction nozzle (60) opens to the oil reservoir (17) of the casing (11). The discharge port of the suction nozzle (60) is connected to communicate with the oil supply passage (27) of the drive shaft (23). The oil sucked up from the oil reservoir (17) by the suction nozzle (60) flows through the oil supply passage (27) and is supplied to the sliding portion of the scroll compressor (10).

  The periphery of the suction nozzle (60) is covered with an oil filter (63). The oil filter (63) is for collecting foreign matter contained in the oil in the oil reservoir (17), and is disposed so as to wrap around the lower side and the outer peripheral surface side of the suction nozzle (60).

  A skirt member (65) is attached to the lower portion of the lower bearing portion (28). The skirt member (65) is formed in a cylindrical shape having an open bottom. A flange portion that expands in the radial direction is provided at the upper end portion of the skirt member (65), and this flange portion is fastened and fixed to the lower bearing portion (28) by a fastening bolt (66).

  A suction nozzle (60) and an oil filter (63) are disposed in the internal space (61) of the skirt member (65). The oil filter (63) is configured in a shape that tapers downward. The upper end edge of the oil filter (63) is attached in contact with the inner peripheral surface of the skirt member (65). The lower end of the skirt member (65) is located below the oil level of the oil reservoir (17).

  Here, when the compression mechanism (30) is driven, the outside of the skirt member (65) becomes higher than the internal space (61), and the oil in the internal space (61) reaches a position where the external refrigerant pressure and the internal refrigerant pressure are balanced. The face rises. Further, the refrigerant accumulated in the internal space (61) of the skirt member (65) is discharged, and the internal space (61) is decompressed. Thereby, the oil level of the oil sump part (17) rises in the internal space (61) of the skirt member (65). The oil in the oil reservoir (17) is sucked up from the suction port (60a) of the suction nozzle (60) by the positive displacement pump action.

  The lower end portion of the skirt member (65) is positioned below the lower end portion of the suction nozzle (60). As a result, even if a small amount of oil has accumulated in the oil reservoir (17), the internal space (61) is depressurized to raise the oil level, so that the lower end of the suction nozzle (60) is immersed in the oil surface. The amount of oil can be secured.

  The compression mechanism (30) is a so-called scroll type compression mechanism including a movable scroll (35), a fixed scroll (40), and a housing (50). The housing (50) and the fixed scroll (40) are fastened to each other with bolts, and the movable scroll (35) is rotatably accommodated between them.

  The movable scroll (35) has a substantially disc-shaped movable side end plate portion (36). A movable wrap (37) is erected on the upper surface (hereinafter referred to as the front surface) of the movable end plate portion (36). The movable side wrap (37) is a wall that spirally extends from the vicinity of the center of the movable side end plate portion (36) outward in the radial direction. Further, a boss part (38) projects from the lower surface (hereinafter referred to as the back surface) of the movable side end plate part (36).

  The fixed scroll (40) has a substantially disc-shaped fixed side end plate portion (41). A fixed side wrap (42) is erected on the lower surface (hereinafter referred to as the front surface) of the fixed side end plate portion (41). The fixed-side wrap (42) is formed so as to spiral from the vicinity of the center of the fixed-side end plate portion (41) outward in the radial direction and engage with the movable-side wrap (37) of the movable scroll (35). It is a wall. A compression chamber (31) is formed between the fixed side wrap (42) and the movable side wrap (37).

  The fixed scroll (40) has an outer edge portion (43) continuous radially outward from the outermost peripheral wall of the fixed side wrap (42). The lower end surface of the outer edge portion (43) is fixed to the upper end surface of the housing (50). The outer edge portion (43) is formed with an opening portion (44) that opens upward. And the suction port (34) which connects the inside of this opening part (44) and the outermost periphery end of a compression chamber (31) is formed in the outer edge part (43). The suction port (34) opens to the suction position of the compression chamber (31). The suction pipe joint (47) described above is connected to the opening (44) of the outer edge (43).

  Further, a discharge port (32) penetrating in the vertical direction is formed in the fixed side end plate portion (41) of the fixed scroll (40) and is positioned near the center of the fixed side wrap (42). The lower end of the discharge port (32) opens to the discharge position of the compression chamber (31). The upper end of the discharge port (32) opens into a discharge chamber (46) defined in the upper part of the fixed scroll (40). Although not shown, the discharge chamber (46) communicates with the lower space (16) of the casing (11).

  The housing (50) is formed in a substantially cylindrical shape. The outer peripheral surface of the housing (50) is formed so that the upper part has a larger diameter than the lower part. And the upper part of this outer peripheral surface is being fixed to the inner peripheral surface of a casing (11).

  The drive shaft (23) is inserted into the hollow portion of the housing (50). Further, the hollow portion is formed so that the upper portion has a larger diameter than the lower portion of the hollow portion. A bearing portion (53) is formed in the lower portion of the hollow portion. This bearing portion (53) rotatably supports the upper end portion of the main shaft portion (24) in the drive shaft (23). The upper part of the hollow part is partitioned by the seal member (55) to form the back pressure space (54). The back pressure space (54) faces the back of the movable scroll (35). A seal member (55) is fitted between the upper surface of the housing (50) and the rear surface of the movable scroll (35). Further, the boss portion (38) of the movable scroll (35) is located in the back pressure space (54). The boss portion (38) is engaged with the eccentric portion (25) of the drive shaft (23) protruding from the upper end of the bearing portion (53).

  Note that an end portion of the oil supply passage (27) of the drive shaft (23) is opened on the outer peripheral surface of the eccentric portion (25). Oil is supplied from the end of the oil supply passage (27) to the gap between the boss portion (38) and the eccentric portion (25). The oil supplied to this gap also flows into the back pressure space (54). Therefore, the back pressure space (54) has the same pressure as the lower space (16) of the casing (11). Then, the pressure in the back pressure space (54) acts on the back surface of the movable scroll (35) to press the movable scroll (35) against the fixed scroll (40).

-Driving action-
Next, the operation of the scroll compressor (10) described above will be described. When the motor (21) of the scroll compressor (10) is energized, the drive shaft (23) rotates with the rotor (21b), and the movable scroll (35) is eccentric about the axis of the drive shaft (23). Rotate. As the movable scroll (35) rotates eccentrically, the volume of the compression chamber (31) periodically increases and decreases.

  Specifically, when the drive shaft (23) rotates, the refrigerant is sucked into the compression chamber (31) from the suction port (34). As the drive shaft (23) rotates, the compression chamber (31) is closed. Furthermore, as the rotation of the drive shaft (23) proceeds, the volume of the compression chamber (31) starts to decrease, and the compression of the refrigerant in the compression chamber (31) is started.

  Thereafter, the volume of the compression chamber (31) is further reduced, and when the volume of the compression chamber (31) is reduced to a predetermined volume, the discharge port (32) is opened. Through the discharge port (32), the refrigerant compressed in the compression chamber (31) is discharged into the discharge chamber (46) of the fixed scroll (40). The refrigerant in the discharge chamber (46) is discharged from the discharge pipe (19) through the lower space (16) of the casing (11). As described above, the lower space portion (16) communicates with the back pressure space (54), and the movable scroll (35) moves to the fixed scroll (40) by the refrigerant pressure in the back pressure space (54). Pressed.

  Next, the refueling operation of the scroll compressor (10) will be described. When the compression mechanism (30) is stopped, as shown in FIG. 2, the oil level of the oil reservoir (17) maintains a constant height. When the compression mechanism (30) is driven, the outside of the skirt member (65) becomes higher in pressure than the internal space (61), and the oil level in the internal space (61) reaches a position where the external refrigerant pressure and the internal refrigerant pressure are balanced. Rises. The oil in the oil reservoir (17) is sucked up from the suction port (60a) of the suction nozzle (60) by the positive displacement pump action.

  As a result, as shown in FIG. 3, the oil level of the oil reservoir (17) rises in the internal space (61) of the skirt member (65), and not only the lower side of the oil filter (63) but also the outer peripheral surface thereof. The side is also immersed in oil. At this time, since the surface area immersed in the oil in the oil filter (63) is increased, the collection of foreign matters contained in the oil is performed over a wide range of the oil filter (63). Thereby, it is possible to suppress the occurrence of unevenness in the adhesion distribution of the foreign matter on the oil filter (63), and it is possible to suppress clogging of the oil filter (63). That is, it is possible to reduce the pressure loss of the oil passing through the oil filter (63) and ensure a sufficient oil supply amount.

  The oil sucked up from the suction nozzle (60) flows through the oil supply passage (27) of the drive shaft (23), and the sliding surfaces of the movable scroll (35) and the fixed scroll (40), the housing (50) To the bearing portion (53) and the lower bearing portion (28). The oil supplied to each sliding portion flows down and is collected again in the oil reservoir (17).

<< Embodiment 2 >>
FIG. 4 is a side sectional view showing the configuration of the scroll compressor according to the second embodiment. As shown in FIG. 4, a suction nozzle (60) as a suction member for sucking up oil is provided at the lower end of the drive shaft (23).

  The suction port (60a) of the suction nozzle (60) opens to the oil reservoir (17) of the casing (11). In addition, a suction port (60a) is opened toward the side also at a position near the top of the suction nozzle (60). The discharge port of the suction nozzle (60) is connected to communicate with the oil supply passage (27) of the drive shaft (23).

  Here, when the compression mechanism (30) is driven, the refrigerant accumulated in the internal space (61) of the skirt member (65) is discharged from the suction port (60a) of the suction nozzle (60) through the oil supply passage (27). As a result, the internal space (61) is depressurized. Furthermore, the high and low differential pressure is generated in the casing (11), so that the oil level of the oil reservoir (17) outside the skirt member (65) is pushed down. Thereby, the oil level of the oil sump part (17) rises in the internal space (61) of the skirt member (65).

  Further, since the high-pressure refrigerant discharged from the compression chamber (31) flows into the lower space (16), the oil in the oil reservoir (17) is sucked into the suction nozzle ( It is sucked up from the suction port (60a) of 60).

<< Other Embodiments >>
About the said embodiment, it is good also as following structures.

  In the present embodiment, the suction nozzle (60) has a suction port (60a) that opens toward the oil reservoir (17), and a suction port that opens at a position closer to the top in the internal space (61) of the skirt member (65). The configuration in which the mouth (60a) is formed has been described, but the suction port (60a) of the suction nozzle (60) only needs to open at a position near the upper portion of the internal space (61).

  Further, in this embodiment, the skirt member (65) is formed of a cylindrical member extending downward, but the lower end portion of the skirt member (65) has a shape that extends obliquely outwardly downward. Also good. The oil filter (63) may be in contact with the lower end plate (14).

  In the present embodiment, the internal space (61) is discharged by discharging the refrigerant in the internal space (61) of the skirt member (65) through the oil supply passage (27) as the compression mechanism (30) is driven. Although the oil level is raised by reducing the pressure, the present invention is not limited to this form. For example, a two-pump type compressor provided with a pump mechanism different from the suction nozzle (60), and circulating the refrigerant in the internal space (61) of the skirt member (65) to the oil supply passage (27) Instead, it may be configured to forcibly eject the skirt member (65) to the outside.

  In the present embodiment, the scroll compressor (10) in which the movable scroll (35) and the fixed scroll (40) are engaged is described as the rotary compressor. However, the rotary compression in which the piston rotates eccentrically in the cylinder. Even a machine can be similarly applied.

  As described above, the present invention provides a highly practical effect that the pressure loss due to clogging is reduced by increasing the surface area of the oil filter immersed in oil, and a sufficient amount of oil can be secured. It is extremely useful and has high industrial applicability.

10 Scroll compressor (rotary compressor)
11 Casing
17 Oil reservoir
20 Drive mechanism
23 Drive shaft
27 Refueling path
30 Compression mechanism
60 Suction nozzle (suction member)
60a inlet
61 Internal space
63 Oil filter
65 Skirt members

Claims (3)

A casing (11) provided with an oil reservoir (17) at the bottom, a compression mechanism (30) disposed at the top of the casing (11) for compressing refrigerant, and the casing (11) up and down A rotary compressor including a drive mechanism (20) having a drive shaft (23) extending in a direction to drive the compression mechanism (30),
Provided at the lower end portion of the drive shaft (23) so as to communicate with the oil supply passage (27) formed in the drive shaft (23), and sucks up oil from the oil reservoir (17) to provide the oil supply passage (27 A suction member (60) to be distributed to
An oil filter (63) that covers the periphery of the suction member (60) and collects foreign matter contained in the oil in the oil reservoir (17);
The suction member (60) and the oil filter (63) are provided in the inner space (61), and the lower end is formed from the oil surface of the oil reservoir (17). And a skirt member (65) disposed so as to be positioned below the rotary compressor. In claim 1,
The rotary compressor according to claim 1, wherein a lower end portion of the skirt member (65) is positioned below a lower end portion of the suction member (60). In claim 1 or 2,
The rotary compressor according to claim 1, wherein the suction port (60a) of the suction member (60) opens at a position closer to the upper part in the internal space (61) of the skirt member (65).

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