JP2012102708A - Scroll type compressor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress an increase in an amount of oil supply to a sliding surface even when a movable scroll has capsized.SOLUTION: A scroll type compressor includes a concave part 82 formed on the sliding surface of an outer edge 62 of a fixed scroll 60, and an oil supply passage 81 formed on an end plate 71 of the movable scroll 70 that opens into the concave part 82 for supplying lubricant to the concave part 82. An effluence end of the oil supply passage 81 that opens into the concave part 82 revolves in the concave part 82 accompanying the revolution of the movable scroll. A blocking part 91 is provided in which a part of the bottom wall of the concave part 82 projects. The blocking part 91 is configured so as to block a part of the effluence end of the oil supply passage 81 in an area of the revolution angle in which the capsizing moment that acts on the movable scroll 70 is a predetermined value or above, and open the entire effluence end of the oil supply passage 81 in the area other than the above area of the revolution angle.

Description

    The present invention relates to a scroll compressor, and particularly relates to a countermeasure against oil supply on sliding surfaces of a fixed scroll and a movable scroll.

    Conventionally, for example, Patent Document 1 discloses a scroll compressor that supplies lubricating oil to sliding surfaces of a fixed scroll and a movable scroll. In this scroll compressor, high-pressure lubricating oil in the casing is supplied to the sliding surface between the end plate of the fixed scroll and the end plate of the movable scroll through the oil supply passage of the drive shaft. Thereby, the sliding surface is lubricated.

Japanese Patent No. 3731433

    By the way, in the scroll type compressor as described above, the rollover moment is applied to the movable scroll due to the gas pressure (gas load in the thrust direction or radial direction) in the compression chamber formed by meshing the fixed scroll and the movable scroll. Works. This overturning moment fluctuates during one revolution of the movable scroll, and reaches a peak value at a predetermined revolution angle. When the rollover moment reaches a peak value or a value in the vicinity thereof, there is a high possibility that the movable scroll rolls over. When the movable scroll rolls over, the end plate of the fixed scroll and the end plate of the movable scroll are separated from each other, and the amount of lubricating oil supplied to these sliding surfaces increases. That is, when the end plates of the scrolls are separated from each other, the supply resistance of the lubricant is reduced at a stretch as compared to when the end plates are sliding, so that the amount of lubricant supplied is significantly increased. Thus, when the supply amount of the lubricating oil increases, the amount of the lubricating oil flowing into the compressor chamber increases, and as a result, the suction fluid in the compression chamber is heated by the high-pressure lubricant and suction superheat increases. Problems arise. Further, when the supply amount of the lubricating oil is increased, there is a problem that the supply amount of the lubricating oil to the other sliding portions is reduced correspondingly, resulting in insufficient lubrication.

    The present invention has been made in view of such a point, and the object of the present invention is to provide a scroll compressor in which lubricating oil is supplied to the sliding surfaces of the fixed scroll and the movable scroll. This is to suppress an increase in the amount of oil supplied to the sliding surface.

    In order to solve the above-mentioned problems, the present invention is configured so that the lubricating oil slides between the fixed scroll (60) and the movable scroll (70) at the timing when the rollover moment acting on the movable scroll (70) reaches a peak or near the peak. It is designed to be difficult to distribute to the surface.

    Specifically, in the first invention, the casing (20), the end plate (61) on which the wrap (63) is erected, and the outer edge portion (62) formed on the outer peripheral side of the wrap (63) are fixed. A scroll (60) and a wrap (72) meshing with the wrap (63) of the fixed scroll (60) are provided upright and have an end plate (71) in sliding contact with the outer edge (62) of the fixed scroll (60) A compression mechanism (40) housed in the casing (20), an outer edge portion (62) of the fixed scroll (60), and an end plate (71) of the movable scroll (70). An oil supply mechanism (80) that constantly supplies lubricating oil to the sliding surface of the movable scroll, and the movable scroll in which a rollover moment that acts on the movable scroll (70) during one revolution of the movable scroll (70) becomes a predetermined value or more. In the revolution angle region of (70), the lubricating oil of the oil supply mechanism (80) A scroll compressor and a control mechanism for increasing the feed resistors (90).

    In the first invention, the movable scroll (70) moves relative to the fixed scroll (60) while the outer edge (62) of the fixed scroll (60) and the end plate (71) of the movable scroll (70) slide. Revolve (turn). Thereby, the fluid is compressed in the compression chamber formed between both scrolls (60, 70). A rollover moment acts on the movable scroll (70) by the fluid pressure in the compression chamber. The fluid pressure in the compression chamber fluctuates with the revolving motion of the movable scroll (70), and the overturning moment fluctuates accordingly and peaks at a predetermined revolving angle.

    On the other hand, in the present invention, while the movable scroll (70) revolves, the oil supply mechanism (80) always supplies lubricating oil to the sliding surfaces of the fixed scroll (60) and the movable scroll (70). Thereby, a sliding surface is lubricated and a sliding loss is reduced. Here, when the revolution angle of the movable scroll (70) becomes a predetermined angle region and the rollover moment acting on the movable scroll (70) becomes a predetermined value or more, the possibility that the movable scroll (70) rolls over increases. When the movable scroll (70) rolls over, the outer edge (62) of the fixed scroll (60) that had been slid and the end plate (71) of the movable scroll (70) are separated from each other by the oil supply mechanism (80). Lubricant supply resistance is significantly reduced. If it does so, the supply amount of lubricating oil will increase. However, in the present invention, when the rollover moment becomes a predetermined revolution angle region where the predetermined value or more is reached, the supply resistance of the lubricating oil by the oil supply mechanism (80) is increased. Therefore, it becomes difficult to supply lubricating oil to the sliding surface. Thereby, it can avoid that the amount of oil supply to a sliding surface increases.

    In a second aspect based on the first aspect, the oil supply mechanism (80) slides between the outer edge (62) of the fixed scroll (60) and the end plate (71) of the movable scroll (70). A concave portion (82, 86) formed on the surface, and formed in the fixed scroll (60) or the movable scroll (70) and open into the concave portion (82, 86) to supply lubricating oil to the concave portion (82, 86). And an oil supply passage (81,85) for supplying the oil supply passage (81,85) to the recess-side opening end of the oil supply passage (81,85) during one revolution of the movable scroll (70). , 86). The adjustment mechanism (90) is formed on the outer edge (62) of the fixed scroll (60) or the end plate (71) of the movable scroll (70), and inside the recess (82, 86). Along with the revolution of the movable scroll (70), the oil supply passage (81, 85) revolves relatively with the recess-side opening end, and during the revolution, the oil supply passage (81 , 85), a closed portion (91, 92) that closes a part of the recess-side opening end of the oil supply passage (81, 85) in a revolution angle region other than the revolution angle region. ).

    In the second aspect of the invention, since the lubricating oil is supplied to the recesses (82, 86) formed on the sliding surface, a certain amount of lubricating oil is likely to intervene on the sliding surface. Thereby, the lubrication performance of the sliding surface is improved. On the other hand, the closed portion (91,92) is located in the recessed portion (82,86), and the closed portion (91,92) is relatively moved in the recessed portion (82,86) as the movable scroll (70) revolves. Revolves around. During the revolving operation, part of the opening end (opening end on the recess side) of the oil supply passage (81,85) that opens into the recess (82,86) when the revolving angle region where the overturning moment exceeds a predetermined value Is closed by the closing portions (91, 92), and the entire open end (the recessed portion-side open end) is opened outside the above-described revolution angle region. When a part of the open end of the oil supply passage (81,85) is blocked, the oil supply passage (81,85) is recessed into the recess (82,86) compared to when the entire open end is open. The flow resistance of lubricating oil to the oil increases. That is, the supply resistance of the lubricating oil to the sliding surface increases. Thereby, even if the movable scroll (70) rolls over, the lubricating oil is hardly supplied into the recesses (82, 86), and an increase in the amount of oil supply is avoided.

    In a third aspect based on the second aspect, the recess (82) is formed on the sliding surface of the outer edge (62) of the fixed scroll (60) or the end plate (71) of the movable scroll (70). On the other hand, the oil supply path (81) is formed in the fixed scroll (60) or the movable scroll (70) different from the formation side of the recess (82). The closing portion (91) is formed such that a part of the bottom wall of the recess (82) protrudes toward the opening side of the recess (82).

    In the third invention, for example, as shown in FIG. 2, the recess (82) is formed on the sliding surface of the outer edge portion (62) of the fixed scroll (60), and the blocking portion (91) is formed in the recess (82). ) Is formed. An oil supply path (81) is formed in the movable scroll (70) and opens into the recess (82). In this configuration, the opening end of the oil supply path (81) revolves in the recess (82) as the movable scroll (70) revolves. That is, the open end of the oil supply passage (81) revolves with respect to the closed portion (91) in a stationary state. And in the revolution angle area | region where a capsizing moment becomes more than predetermined value, a part of opening end of an oil supply path (81) is obstruct | occluded by the obstruction | occlusion part (91).

    In a fourth aspect based on the second aspect, the recess (86) is formed on the sliding surface of the outer edge (62) of the fixed scroll (60) or the end plate (71) of the movable scroll (70). On the other hand, the oil supply path (85) is formed in the fixed scroll (60) or the movable scroll (70) in which the concave portion (86) is formed, and is open to the bottom of the concave portion (86). . And the said closure part (92) is different from the formation side of the said recessed part (86) from the outer edge part (62) of the said fixed scroll (60), or the sliding surface of the end plate (71) of the said movable scroll (70). It protrudes and is formed so as to be located inside the recess (86).

    In the fourth aspect of the invention, for example, as shown in FIG. 10, the concave portion (86) and the oil supply passage (85) are formed in the movable scroll (70), and the closing portion (92) is the outer edge portion of the fixed scroll (60). It projects from the sliding surface of (62) and is located in the recess (86). In this configuration, even if the movable scroll (70) revolves, the positional relationship between the recess (86) and the open end of the oil supply passage (85) does not change. In this configuration, when the movable scroll (70) revolves, the recess (86) and the open end of the oil supply path (85) revolve with respect to the stationary closed portion (92). That is, the closed portion (92) revolves relatively with the open end of the oil supply passage (85) in the recess (86). In the revolution angle region where the rollover moment is equal to or greater than a predetermined value, a part of the opening end of the oil supply passage (85) is blocked by the blocking portion (92).

    According to a fifth invention, in any one of the second to fourth inventions, the oil supply mechanism (80) is formed on the sliding surface on which the recesses (82, 86) are formed, and the recesses (82, 86) and an oil groove (83, 87) extending in the circumferential direction.

    In the fifth invention, for example, as shown in FIG. 3, the oil groove (83, 87) that communicates with the recess (82, 86) and extends in the circumferential direction on the sliding surface where the recess (82, 86) is formed. Is formed. In this configuration, the lubricating oil supplied from the oil supply path (81, 85) into the recess (82, 86) flows into the oil groove (83, 87). Thereby, since lubricating oil is supplied to the widest possible range of the sliding surface, the lubricating performance of the sliding surface is further improved.

    According to the present invention, the movable scroll (70) is provided with the adjustment mechanism (90) that increases the supply resistance of the lubricating oil of the oil supply mechanism (80) in the revolution angle region where the rollover moment is a predetermined value or more. It is possible to avoid an increase in the amount of lubricating oil supplied to the sliding surfaces of the fixed scroll (60) and the movable scroll (70) when overturning. That is, the supply amount of the lubricating oil to the sliding surface can be made constant during one revolution of the movable scroll (70). As a result, an increase in suction overheating and insufficient lubrication in other sliding portions can be avoided.

    According to the second to fourth inventions, a part of the outflow end of the oil supply passage (81, 85) that opens to the recess (82, 86) in the revolution angle region θ1 to θ2 in which the overturning moment is a predetermined value or more. Was blocked by the obstruction (91,92). That is, the outflow end of the oil supply passage (81, 85) is restricted by the closed portion (91, 92) in a predetermined revolution angle region. Therefore, the lubricating oil supply resistance of the oil supply mechanism (80) can be reliably increased with a simple configuration. Therefore, it is possible to reliably avoid an increase in the amount of lubricating oil supplied when the movable scroll (70) is turned over.

    According to the fifth aspect of the present invention, the oil grooves (83, 87) that are connected to the recesses (82, 86) and extend in the circumferential direction are formed on the sliding surfaces of the fixed scroll (60) and the movable scroll (70). did. Thereby, lubricating oil can be supplied to the wide range of a sliding surface as much as possible, and the lubricating performance of a sliding surface can be improved more.

FIG. 1 is a longitudinal sectional view of a scroll compressor according to an embodiment. FIG. 2 is a longitudinal sectional view of a main part of the scroll compressor according to the first embodiment. FIG. 3 is a diagram illustrating a part of the movable scroll in the bottom view of the fixed scroll according to the first embodiment. FIG. 4 is a plan view illustrating configurations of an oil supply mechanism and an adjustment mechanism according to the first embodiment. FIG. 5 is a plan view illustrating the revolution operation of the oil supply path according to the first embodiment. FIG. 6 is a graph showing the opening area of the oil supply passage and the rollover moment with respect to the crank angle. FIG. 7 is a view for explaining the formation position of the oil supply path. FIG. 8 is a plan view illustrating configurations of an oil supply mechanism and an adjustment mechanism according to a modification of the first embodiment. FIG. 9 is a plan view illustrating the revolution operation of the oil supply path according to the modification of the first embodiment. FIG. 10 is a longitudinal sectional view of a main part of the scroll compressor according to the second embodiment. FIG. 11 is a plan view illustrating configurations of an oil supply mechanism and an adjustment mechanism according to the second embodiment. FIG. 12 is a plan view illustrating the revolution operation of the oil supply path according to the second embodiment.

    Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

Embodiment 1
A first embodiment of the present invention will be described. The scroll compressor (10) according to the present embodiment is connected to a refrigerant circuit of a refrigeration apparatus. That is, in the refrigeration apparatus, the refrigerant compressed by the scroll compressor (10) circulates in the refrigerant circuit, so that a vapor compression refrigeration cycle is performed.

    As shown in FIGS. 1 and 2, the scroll compressor (10) includes a casing (20), and 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 as a sealed dome.

    The electric motor (30) constitutes a drive mechanism that rotates the drive shaft (11) to drive the compression mechanism (40). The electric motor (30) includes a stator (31) fixed to the casing (20), and a rotor (32) disposed inside the stator (31). The rotor (32) is fixed to the drive shaft (11) through the drive shaft (11).

    The bottom of the casing (20) constitutes an oil reservoir (21) in which lubricating oil is stored. A suction pipe (12) is fixed through the upper portion of the casing (20), while a discharge pipe (13) is connected to the central portion.

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

    The drive shaft (11) is arranged vertically along the casing (20), and includes a main shaft portion (14) and an eccentric portion (15) connected to the upper end of the main shaft portion (14). The lower portion of the main shaft portion (14) is supported by the casing (20) via the lower bearing (22), and the upper portion of the main shaft portion (14) passes through the housing (50), and the upper bearing of the housing (50) Supported by (51).

    The compression mechanism (40) includes a fixed scroll (60) fixed to the upper surface of the housing (50), and a movable scroll (70) meshing with the fixed scroll (60). The movable scroll (70) is disposed between the fixed scroll (60) and the housing (50), and is installed in the housing (50).

    The housing (50) has an annular part (52) formed on the outer peripheral part, a large-diameter concave part (53) formed in the upper part of the central part, and is formed in a dish shape with a concave central part. The lower part of 53) constitutes the upper bearing (51). The housing (50) is press-fitted and fixed to the casing (20), and 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. Yes. The housing (50) partitions the inside of the casing (20) into an upper space (23) in which the compression mechanism (40) is accommodated and a lower space (24) in which the electric motor (30) is accommodated.

    The fixed scroll (60) constitutes a fixed member fixed to the housing (50). The fixed scroll (60) includes an end plate (61), an outer edge portion (62) continuously formed on the outer periphery of the end plate (61), and a front surface (61) on the inner side of the outer edge portion (62) ( And a wrap (63) standing on the lower surface in FIGS. The end plate (61) is formed in a substantially disc shape. The outer edge (62) is formed so as to protrude downward from the end plate (61). The wrap (63) is formed in a spiral shape (involute shape) (see FIG. 3). The front end surface of the outer edge portion (62) and the front end surface of the wrap (63) are substantially flush with each other.

    The movable scroll (70) constitutes a movable member that revolves (turns) with respect to the fixed scroll (60). The movable scroll (70) includes a mirror plate (71), a spiral (involute) wrap (72) formed on the front surface (upper surface in FIGS. 1 and 2) of the mirror plate (71), and a mirror plate (71). And a cylindrical boss portion (73) formed at the center of the back surface of the head. The eccentric part (15) of the drive shaft (11) is inserted into the boss part (73). Thereby, the movable scroll (70) is connected with the electric motor (30) via the drive shaft (11).

    The compression mechanism (40) is configured such that the wrap (72) of the movable scroll (70) meshes with the wrap (63) of the fixed scroll (60). In the compression mechanism (40), a compression chamber (41) is formed between the contact portions of both wraps (63, 72). That is, as shown in FIG. 3, in the fixed scroll (60), a wrap groove is formed between the outer edge portion (62) and the wrap (63) or between the adjacent wraps (63). In the movable scroll (70), a wrap groove is formed between adjacent wraps (72). In the compression mechanism (40), the compression chamber (41) is formed inside these wrap grooves.

    A suction port (12a) is formed on the outer edge (62) of the fixed scroll (60). A downstream end of the suction pipe (12) is connected to the suction port (12a). A discharge port (65) is formed at the center of the end plate (61) of the fixed scroll (60). A high-pressure chamber (66) in which the discharge port (65) is opened is formed on the back surface (upper surface in FIGS. 1 and 2) of the 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 end plate (61) of the fixed scroll (60) and the housing (50). Thereby, the lower space (24) has a high-pressure atmosphere corresponding to the pressure of the refrigerant discharged from the compression mechanism (40).

    An oil supply path (16) extending from the lower end to the upper end is formed in the drive shaft (11). An oil supply pump (17) is attached to the lower end of the drive shaft (11). The lower end of the drive shaft (11) and the oil supply pump (17) are immersed in the oil reservoir (21). The oil supply passage (16) supplies the lubricating oil in the oil reservoir (21) sucked up by the oil supply pump (17) to the sliding surfaces of the lower bearing (22) and the upper bearing (51). The oil supply passage (16) is opened at the upper end surface of the drive shaft (11), and lubricates the boss portion (73) to lubricate the sliding surface of the boss portion (73). The lubricating oil in the oil reservoir (21) is similarly at high pressure because the lower space (24) is in a high pressure atmosphere.

    Although not shown, the annular member (52) of the housing (50) is provided with a seal member on the upper surface of the inner periphery. The sealing member partitions the large-diameter concave portion (53) in an airtight manner, and the large-diameter concave portion (53) communicates with an oil supply passage (16) through which high-pressure lubricating oil flows. Thereby, the back pressure part (42) which becomes a high pressure atmosphere equivalent to the pressure of the discharge refrigerant | coolant of a compression mechanism (40) is formed in the inside of a large diameter recessed part (53). The back pressure part (42) constitutes a pressing mechanism that presses the movable scroll (70) against the fixed scroll (60) side by applying a high pressure to the back surface of the end plate (71) of the movable scroll (70). .

    Further, an intermediate pressure portion (43) that is an intermediate pressure space is defined on the outer peripheral side of the seal member. That is, the intermediate pressure part (43) is an atmosphere having an intermediate pressure between the suction pressure and the discharge pressure of the compression mechanism (40). The intermediate pressure part (43) includes a movable side pressure part (44) and a fixed side pressure part (45). The movable side pressure portion (44) is formed from the outer peripheral portion of the end plate (71), which is a part of the back surface of the end plate (71) of the movable scroll (70), to the side of the end plate (71). That is, the movable side pressure part (44) is formed outside the back pressure part (42), and presses the movable scroll (70) to the fixed scroll (60) side with an intermediate pressure. The fixed-side pressure part (45) is formed outside the fixed scroll (60) in the upper space (23), and between the outer edge part (63) of the end plate (61) of the fixed scroll (60) and the casing (20). Is communicated with the movable pressure part (44).

    The housing (50) is provided with a rotation preventing member (46) of the movable scroll (70). The rotation prevention member (46) is formed of, for example, an Oldham ring, is provided on the upper surface of the annular portion (52) of the housing (50), and slides between the end plate (71) of the movable scroll (70) and the housing (50). Fits freely.

<Configuration of oil supply mechanism and adjustment mechanism>
As shown in FIGS. 2 to 4, the compression mechanism (40) includes an oil supply mechanism (80) and an adjustment mechanism (90).

    While the movable scroll (70) revolves, the oil supply mechanism (80) is always on the sliding surface between the outer edge (62) of the fixed scroll (60) and the end plate (71) of the movable scroll (70). Lubricating oil is supplied. The adjustment mechanism (90) has a supply resistance of the lubricating oil of the oil supply mechanism (80) in a revolution angle region in which the overturning moment acting on the movable scroll (70) during one revolution of the movable scroll (70) is a predetermined value or more. Is to increase.

    The oil supply mechanism (80) has an oil supply path (81), a recess (82), and an oil groove (83). The oil supply path (81) is formed in the end plate (71) of the movable scroll (70). The oil supply path (81) has an inflow end opened to a space in the boss portion (73), and an outflow end opened to the front (upper surface in FIG. 2) of the end plate (71). That is, the outflow end of the oil supply path (81) opens to the sliding surface of the end plate (71) that slides with the outer edge (62) of the fixed scroll (60). In addition, the outflow end of the oil supply path (81) constitutes the recess-side opening end according to the present invention. The lubricating oil that has flowed into the boss portion (73) from the oil supply passage (16) of the drive shaft (11) flows into the oil supply passage (81). The recess (82) and the oil groove (83) are formed in the outer edge (62) of the fixed scroll (60). That is, the concave portion (82) and the oil groove (83) are formed on the sliding surface of the outer edge portion (62) that slides with the end plate (71) of the movable scroll (70). The recess (82) is formed in a flat disk shape having a circular shape in plan view. The oil groove (83) is formed in a substantially arc shape extending in the circumferential direction. The oil groove (83) is formed with the recess (82) in the middle and connected to the recess (82).

    The oil supply mechanism (80) is configured such that the outflow end of the oil supply path (81) opens into the recess (82). As the movable scroll (70) revolves as shown by the arrows in FIG. 5, the outflow end (opening end) of the oil supply passage (81) revolves around the recess (82) with S as the center of revolution. To do. That is, in the oil supply mechanism (80), during one revolution of the movable scroll (70), the outflow end of the oil supply path (81) does not protrude outside the recess (82), and the entire outflow end is the recess ( 82) located within. In this configuration, high-pressure lubricating oil is supplied into the recess (82) through the oil supply path (81) and then flows into the oil groove (83).

    The adjustment mechanism (90) has a cylindrical blocking portion (91) formed in the recess (82) of the fixed scroll (60). The closed portion (91) is a convex portion in which a part of the bottom wall of the concave portion (82) protrudes toward the opening side of the concave portion (82), and is formed without being in contact with the side wall of the concave portion (82). . That is, the closing part (91) is integrally formed with the recess (82). And the obstruction | occlusion part (91) has the center R shifted | deviated only predetermined amount from the center Q of the recessed part (82) (refer FIG. 4). That is, the closed part (91) and the recessed part (82) are eccentric. Further, the closed portion (91) is configured such that a part of the outflow end of the oil supply passage (81) is blocked by the closed portion (91) in a predetermined revolution angle region while the outflow end of the oil supply passage (81) makes one revolution. In the revolving angle region other than the revolving angle region, the entire outflow end of the oil supply path (81) is opened (81 in FIG. 5). (States of (a), 81 (b), 81 (c)). The predetermined revolution angle region is a revolution angle region in which the rollover moment acting on the movable scroll (70) is a predetermined value or more. The recess (82) is formed on the sliding surface of the outer edge (62) of the fixed scroll (60) with the outer edge (62) of the fixed scroll (60) when the movable scroll (70) rolls over due to the rollover moment. The movable scroll (70) is formed in a region where it is separated from the end plate (71).

-Driving action-
First, the basic operation of the scroll compressor (10) will be described.

    When the electric motor (30) is operated, the movable scroll (70) of the compression mechanism (40) is rotationally driven. Since the orbiting scroll (70) is prevented from rotating by the rotation preventing member (46), the orbiting scroll (70) does not rotate and only revolves (turns) around the axis of the drive shaft (11). I do. That is, the movable scroll (70) revolves (turns) with respect to the fixed scroll (60) while the outer edge (62) of the fixed scroll (60) and the end plate (71) of the movable scroll (70) slide. . Along with the revolution of the movable scroll (70), the volume of the compression chamber (41) decreases toward the center, and the compression chamber (41) compresses the gas refrigerant sucked from the suction pipe (12). The compressed gas refrigerant is discharged to the high-pressure chamber (66) through the discharge port (65) of the fixed scroll (60). The high-pressure gas refrigerant in the high-pressure chamber (66) flows into the lower space (24) through the passages of the fixed scroll (60) and the housing (50). Then, the refrigerant in the lower space (24) is discharged to the outside of the casing (20) through the discharge pipe (13).

    The lower space (24) of the casing (20) is maintained in a pressure state of the high-pressure gas refrigerant to be discharged, and the lubricating oil in the oil reservoir (21) is also maintained in a high pressure state. The high-pressure lubricating oil in the oil reservoir (21) flows through the oil supply passage (16) of the drive shaft (11) toward the upper end, and is movable from the upper end opening of the eccentric portion (15) of the drive shaft (11). ) Flows out into the boss part (73). The oil supplied to the boss part (73) lubricates the sliding surfaces of the boss part (73) and the eccentric part (15) of the drive shaft (11). Therefore, the inside of the boss part (73) and the back pressure part (42) are in a high pressure atmosphere corresponding to the discharge pressure. The high pressure pressure acts on the back surface of the movable scroll (70), so that the movable scroll (70) is pressed against the fixed scroll (60). This pressing force avoids the state in which the movable scroll (70) is separated from the fixed scroll (60) by the gas pressure in the compression chamber (41). As a result, the sealing performance of the compression chamber (41) is improved, and the compression efficiency can be improved.

<Operation of oil supply mechanism and adjustment mechanism>
The high-pressure lubricating oil that has flowed out of the oil supply passage (16) of the drive shaft (11) into the boss portion (73) of the movable scroll (70) passes through the oil supply passage (81) and is recessed in the fixed scroll (60) ( 82). The supply of the lubricating oil to the recess (82) is always performed while the movable scroll (70) revolves. Thereby, a sliding surface is lubricated and a sliding loss is reduced. In particular, since the lubricating oil is not supplied directly to the sliding surface but is supplied to the recess (82) having a constant volume, a certain amount of lubricating oil is likely to intervene on the sliding surface. Thereby, the lubrication performance of the sliding surface is improved. The high-pressure lubricating oil supplied into the recess (82) flows into the oil groove (83). Thereby, lubricating oil can be supplied with respect to a wide sliding surface, and the lubricating performance of a sliding surface improves more. A part of the lubricating oil in the recess (82) and the oil groove (83) flows into the inner compression chamber (41). The minute gap between each wrap (63, 72) and each end plate (61, 71) is sealed by the inflowing lubricating oil. Thereby, the sealing performance of the compression chamber (41) is improved. Further, since the movable scroll (70) is pressed against the fixed scroll (60) as described above, the sliding resistance between the fixed scroll (60) and the movable scroll (70) tends to increase, but the concave portion (82 ) The sliding resistance is reduced by the lubricating oil supplied inside.

    By the way, the gas pressure in the compression chamber (41) varies with the revolution movement of the movable scroll (70), and the rollover moment also varies accordingly. Specifically, the rollover moment fluctuates as shown in FIG. 6 while the movable scroll (70) makes one revolution. Then, the rollover moment becomes a predetermined value M or more in a predetermined revolution angle region θ1 to θ2. The predetermined value M is a value that increases the possibility that the movable scroll (70) will roll over. The rollover moment reaches a peak at the revolution angle θ3 in the revolution angle region θ1 to θ2. In FIG. 6, the revolution angle is referred to as a crank angle, and is a graph showing fluctuations in the revolution angle of 0 ° to 360 °.

    When the revolution angle of the movable scroll (70) becomes the revolution angle region θ1 to θ2 and the movable scroll (70) rolls over, the outer edge portion (62) of the fixed scroll (60) and the movable scroll (70) ) Are separated from each other, and the flow resistance of the lubricating oil from the oil supply passage (81) to the recess (82) is significantly reduced. As a result, the amount of lubricating oil supplied from the oil supply path (81) to the recess (82) increases. As a result, the suction refrigerant in the compression chamber (41) is heated by the high-pressure lubricant and the intake superheat increases, or the lubricant is applied to other sliding parts such as the upper bearing (51) and the lower bearing (22). The supply amount decreases, resulting in insufficient lubrication.

    However, in this embodiment, in the revolution angle regions other than the revolution angle regions θ1 to θ2 where the movable scroll (70) is less likely to roll over, as shown by 81 (a) to 81 (c) in FIG. As shown by 81 (d) and 81 (e) in FIG. 5, in the revolution angle region θ1 to θ2 where the entire outflow end of the supply path (81) is opened and the movable scroll (70) is likely to roll over. A part of the outflow end of the oil supply path (81) is blocked by the blocking portion (91). When a part of the outflow end of the oil supply path (81) is blocked, the lubricating oil flows from the oil supply path (81) to the recess (82) compared to when the entire outflow end is open. Resistance increases. That is, the supply resistance of the lubricating oil to the recess (82) increases. Thereby, even if the movable scroll (70) rolls over, it becomes difficult to supply the lubricating oil from the oil supply path (81) to the concave portion (82), and an increase in the amount of lubricating oil supplied to the concave portion (82) is avoided. . As a result, the amount of lubricating oil supplied to the recess (82) is constant over one revolution of the movable scroll (70). Therefore, it is possible to avoid an increase in suction overheating and insufficient lubrication in other sliding portions.

    Further, in the revolution angle regions θ1 to θ2, the blockage area (the blockage area) of the outflow end of the oil supply path (81) increases as the rollover moment increases. In other words, the opening area (open area) of the outflow end of the oil supply passage (81) decreases as the overturning moment increases. That is, in the revolution angle regions θ1 to θ2, at the revolution angles θ1 and θ2 at which the rollover moment is minimized, the closed area at the outflow end of the oil supply passage (81) is minimized (opening area is maximized), and the rollover moment is maximized (peak). ) So that the closed area at the outflow end of the oil supply passage (81) is maximized (corresponding to the state of 81 (e) in FIG. 5) so that the closed portion (91) Is configured. This is based on the following idea. As the overturning moment increases, the separation distance between the movable scroll (70) and the fixed scroll (60) increases. When this separation distance increases, the lubricating oil flows from the oil supply passage (81) to the recess (82). Resistance decreases. By increasing the closed area of the outflow end of the oil supply passage (81) in accordance with the decrease in the flow resistance, the supply resistance of the lubricating oil to the recess (82) is increased and the supply amount of the lubricating oil becomes constant. .

    Moreover, in this embodiment, the formation position of the oil groove (83) is devised. As shown in FIG. 5, in the oil groove (83) of the present embodiment, the connection position in the recess (82) is the oil supply path in the revolution angle region θ1 to θ2 (particularly, the revolution angle θ3 that maximizes the rollover moment). It is formed so as to be as far as possible from the outflow end of (81). That is, in this embodiment, in the recess (82), the oil groove (83) and the open portion of the oil supply path (81) in the revolution angle regions θ1 to θ2 are prevented from approaching each other. For example, as shown in FIG. 7, in the recess (2), an oil groove (3) is formed in the vicinity of the outflow end of the oil supply passage (1) partially closed by the closing portion (4). Then, the lubricating oil tends to flow from the oil supply path (1) to the recess (2). In other words, when the oil groove (3) is formed on the outer peripheral side of the open part of the oil supply channel (1), the pressure on the oil groove (3) is greater than when the outer peripheral side is surrounded by the side wall of the recess (2). The flow resistance of the lubricating oil from the oil supply path (1) to the recess (2) is reduced by the amount of opening. Then, even if a part of the outflow end of the oil supply passage (1) is blocked by the closed portion (4), the supply resistance of the lubricating oil from the oil supply passage (1) to the recess (2) cannot be increased so much. . In this respect, in the present embodiment, the oil groove (83) is formed at a position as far as possible from the oil supply path (81) partially blocked by the blocking portion (91), so that the oil supply path (81) Therefore, the supply resistance of the lubricating oil to the recess (82) can be reliably increased by the closing portion (91). Therefore, even if the movable scroll (70) rolls over, the supply amount of the lubricating oil can be surely made constant.

-Effect of Embodiment 1-
As described above, according to the present embodiment, the adjustment mechanism (90) that increases the supply resistance of the lubricating oil of the oil supply mechanism (80) in the revolution angle regions θ1 to θ2 where the rollover moment is equal to or greater than a predetermined value is provided. Therefore, it is possible to avoid an increase in the amount of lubricating oil supplied to the sliding surfaces of the fixed scroll (60) and the movable scroll (70) when the movable scroll (70) rolls over. That is, the supply amount of the lubricating oil to the sliding surface can be made constant during one revolution of the movable scroll (70). As a result, an increase in suction overheating and insufficient lubrication in other sliding portions can be avoided.

    Further, when the amount of lubricating oil supplied to the sliding surfaces of the fixed scroll (60) and the movable scroll (70) increases when the movable scroll (70) rolls over, the movable scroll (70) is generated by the fluid pressure of the lubricating oil. ) May be promoted. However, in the present embodiment, as described above, an increase in the amount of lubricating oil supplied to the sliding surface is avoided, so there is no possibility of promoting the rollover of the movable scroll (70).

    Specifically, in this embodiment, the supply resistance of the lubricating oil is increased by forming a blocking portion (91) for closing a part of the outflow end of the oil supply passage (81) that opens to the recess (82). I tried to make it. That is, in this embodiment, the outflow end of the oil supply passage (81) is narrowed to increase the flow resistance of the lubricating oil. Therefore, with a simple configuration, it is possible to reliably avoid an increase in the amount of lubricating oil supplied when the movable scroll (70) is overturned.

    In particular, the entire outflow end of the oil supply path (81) is configured to revolve in the recess (82), and the outflow end of the oil supply path (81) is formed by the closed portion (91) formed in the recess (82). Therefore, the lubricating oil from the oil supply passage (81) can be prevented from leaking to the outer peripheral side of the fixed scroll (60) and the movable scroll (70). For example, the entire outflow end of the oil supply path (81) does not revolve in the recess (82), but revolves so that a part of the outflow end protrudes outside the recess (82) in a predetermined revolution angle region. When the part of the outflow end is blocked by protruding, that is, when the part of the outflow end is blocked by the sliding surface outside the recess (82), the sliding from the oil supply path (81) There is a possibility that the lubricating oil that has flowed out to the moving surface leaks out to the outer peripheral side of the scroll (60, 70) through the sliding surface. If so, insufficient lubrication occurs. In this regard, in the present embodiment, since only a closed portion (91) formed in the recess (82) is used to block a part of the outflow end of the oil supply path (81), the lubricating oil is in the recess (82). It flows out and is held inside. Therefore, there is no possibility that the lubricating oil leaks to the outer peripheral side of the scroll (60, 70).

-Modification of Embodiment 1-
This modification is obtained by changing the positional relationship between the concave portion (82) and the blocking portion (91) in the first embodiment. Specifically, in the first embodiment, the blocking portion (91) is formed eccentrically with respect to the recess (82). However, in this modification, as shown in FIGS. 8 and 9, the blocking portion (82) is closed with respect to the recess (82). (91) was formed concentrically. That is, the center Q of the recessed part (82) and the center R of the closed part (91) coincide. Also in this modified example, while the outflow end of the oil supply passage (81) makes one revolution, a part of the outflow end of the oil supply passage (81) is blocked by the blocking portion (91) in the revolution angle region θ1 to θ2. In the revolving angle region other than the revolving angle regions θ1 to θ2, the entire outflow end of the oil supply passage (81) is opened (see FIG. 9). 81 (a), 81 (b), 81 (c)). Other configurations, operations, and effects are the same as those of the first embodiment.

<< Embodiment 2 >>
A second embodiment of the present invention will be described with reference to FIGS. The scroll compressor (10) according to the present embodiment is different from the above-described first embodiment in the configuration of the oil supply mechanism (80) and the adjustment mechanism (90).

    Specifically, the oil supply mechanism (80) of the present embodiment has an oil supply path (85), a recess (86), and an oil groove (87), as in the first embodiment. The oil supply path (85) is formed in the end plate (71) of the movable scroll (70). Unlike the first embodiment, the recess (86) and the oil groove (87) are formed on the end plate (71) of the movable scroll (70). That is, the recess (86) and the oil groove (87) are formed on the sliding surface of the end plate (71) that slides with the outer edge (62) of the fixed scroll (60). The recess (86) is formed in a flat disk shape having a circular shape in plan view. The oil groove (87) is formed in a substantially arc shape extending in the circumferential direction. In the oil groove (87), the recess (86) is formed in the middle and is connected to the recess (86). The oil supply path (85) has an inflow end opened to a space in the boss portion (73), and an outflow end opened to the bottom (lower side in FIG. 10) of the recess (86). The outflow end of the oil supply path (85) is formed at the center of the recess (86) and concentric with the center Q of the recess (86). High-pressure lubricating oil that has flowed into the boss portion (73) from the oil supply passage (16) of the drive shaft (11) flows into the oil supply passage (85). The high-pressure lubricating oil that has flowed into the oil supply path (85) is supplied into the recess (86) and then flows into the oil groove (87).

The adjustment mechanism (90) of the present embodiment has a closing part (92) formed on the outer edge part (62) of the fixed scroll (60). The closing part (92) is a convex part protruding from the sliding surface of the outer edge part (62), and is formed so as to be located inside the concave part (86) of the movable scroll (70). And
In the present embodiment, as indicated by an arrow in FIG. 12, as the movable scroll (70) revolves, the recess (86) and the outflow end (opening end) of the oil supply path (85) are integrated into S. Revolves as the center of revolution. Of course, during the revolution of the movable scroll (70), the outflow end of the oil supply passage (85) does not protrude outside the recess (86), and the entire outflow end is located in the recess (86). In FIG. 12, the recess (86) and the oil groove (87) are omitted. As in the first embodiment, a part of the outflow end of the oil supply path (85) is blocked by the blocking portion (92). Specifically, as shown in FIG. 12, during one revolution of the recess (86) and the outflow end of the oil supply path (85), the outflow end of the oil supply path (85) in a predetermined revolution angle region θ1 to θ2. Is blocked by the blocking portion (92) (states 85 (d) and 85 (e) in FIG. 12), and the oil supply path (85) is not rotated in the revolution angle regions other than the revolution angle regions θ1 to θ2. The entire outflow end is opened (states 85 (a), 85 (b), and 85 (c) in FIG. 12). Similarly to the first embodiment, the concave portion (86) is formed on the sliding surface of the end plate (71) of the movable scroll (70) when the movable scroll (70) is overturned by the overturning moment. The outer edge portion (62) and the end plate (71) of the movable scroll (70) are formed in a region where they are separated from each other.

    According to the present embodiment, as in the first embodiment, a part of the outflow end of the oil supply path (85) is blocked by the blocking portion (92) in the revolution angle regions θ1 to θ2 where the rollover moment is equal to or greater than a predetermined value. Thereby, the supply resistance of the lubricating oil of the oil supply mechanism (80) can be increased. Therefore, it is possible to avoid an increase in the amount of lubricating oil supplied to the sliding surfaces of the fixed scroll (60) and the movable scroll (70) when the movable scroll (70) rolls over. That is, the supply amount of the lubricating oil to the sliding surface can be made constant during one revolution of the movable scroll (70). As a result, an increase in suction overheating and insufficient lubrication in other sliding portions can be avoided. Other configurations, operations, and effects are the same as those of the first embodiment.

-Other embodiments-
About the said embodiment, it is good also as the following structures.

    For example, in the first embodiment, the oil supply path (81) is formed in the end plate (71) of the movable scroll (70), and the recess (82), the oil groove (83), and the closing portion (91) are fixed scrolls (60 However, in the present invention, these forming portions may be interchanged with each other. That is, the oil supply path (81) is formed in the outer edge portion (62) of the fixed scroll (60), and the recess (82), the oil groove (83), and the closing portion (91) are the end plate (71 of the movable scroll (70). ), The same effect can be obtained. In this case, a mechanism for supplying the lubricating oil in the oil reservoir (21) to the oil supply path (81) may be provided.

    In the second embodiment, the oil supply path (85), the recess (86), and the oil groove (87) are formed in the end plate (71) of the movable scroll (70), and the closing portion (92) is a fixed scroll (60). However, in the present invention, these forming portions may be interchanged with each other. That is, the oil supply path (85), the recess (86), and the oil groove (87) are formed on the outer edge (62) of the fixed scroll (60), and the closing portion (92) is the end plate (71 of the movable scroll (70). ), The same effect can be obtained.

    Moreover, in each said embodiment, you may make it abbreviate | omit an oil groove | channel (83,87), and the shape of a recessed part (82,86) and a closure part (91,92) is not restricted to what was mentioned above.

    The scroll compressor (10) is applied to a refrigeration apparatus having a refrigerant circuit, but may be applied to other apparatuses as long as it compresses a fluid.

    As described above, the present invention is useful for a scroll compressor having a mechanism for supplying lubricating oil to sliding surfaces of a fixed scroll and a movable scroll.

10 Scroll type compressor
20 casing
40 Compression mechanism
60 Fixed scroll
61 End plate
62 Outer edge
63 laps
70 Moveable scroll
71 End plate
72 wraps
80 Oil supply mechanism
81,85 Oil supply path
82,86 recess
83,87 Oil groove
90 Adjustment mechanism
91,92 Obstruction

Claims (5)

A casing (20);
A fixed scroll (60) having an end plate (61) on which a wrap (63) is erected and an outer edge (62) formed on the outer peripheral side of the wrap (63), and a wrap (63) of the fixed scroll (60) And a movable scroll (70) having an end plate (71) slidably contacting an outer edge (62) of the fixed scroll (60) and accommodated in the casing (20). A compression mechanism (40),
An oil supply mechanism (80) that constantly supplies lubricating oil to the sliding surfaces of the outer edge (62) of the fixed scroll (60) and the end plate (71) of the movable scroll (70);
Lubricating oil of the oil supply mechanism (80) in a revolution angle region of the movable scroll (70) in which a rollover moment acting on the movable scroll (70) becomes a predetermined value or more during one revolution of the movable scroll (70). A scroll type compressor comprising an adjustment mechanism (90) for increasing the supply resistance of the compressor. In claim 1,
The oil supply mechanism (80) includes a recess (82, 86) formed on a sliding surface between an outer edge portion (62) of the fixed scroll (60) and an end plate (71) of the movable scroll (70); An oil supply passage (81,85) formed in the fixed scroll (60) or the movable scroll (70) and opened to the recesses (82,86) to supply lubricating oil to the recesses (82,86); And the entire recess-side opening end of the oil supply passage (81, 85) is located inside the recess (82, 86) during one revolution of the movable scroll (70).
The adjustment mechanism (90) is formed on the outer edge (62) of the fixed scroll (60) or the end plate (71) of the movable scroll (70), and is movable inside the recess (82, 86). Along with the revolution of the scroll (70), the oil supply passage (81,85) relatively revolves between the recess-side opening end and the oil supply passage (81,85) in the revolution angle region during the revolution. ) In the revolving angle region other than the revolving angle region, the closing portion (91, 92) that opens the entire retreating side open end of the oil supply passage (81, 85) is closed. A scroll type compressor characterized by comprising. In claim 2,
The recess (82) is formed on the sliding surface of the outer edge (62) of the fixed scroll (60) or the end plate (71) of the movable scroll (70), while the oil supply path (81) Formed on the fixed scroll (60) or the movable scroll (70) different from the formation side of the recess (82),
The scroll type compressor is characterized in that the closing portion (91) is formed such that a part of the bottom wall of the recess (82) protrudes toward the opening side of the recess (82). In claim 2,
The recess (86) is formed on the sliding surface of the outer edge (62) of the fixed scroll (60) or the end plate (71) of the movable scroll (70), while the oil supply path (85) Formed in the fixed scroll (60) or the movable scroll (70) in which the concave portion (86) is formed and opened at the bottom of the concave portion (86);
The closing portion (92) protrudes from a sliding surface of an outer edge portion (62) of the fixed scroll (60) or the end plate (71) of the movable scroll (70), which is different from the formation side of the recess (86). A scroll compressor characterized by being formed so as to be located inside the recess (86). In any one of Claims 2 thru | or 4,
The oil supply mechanism (80) is formed on the sliding surface where the recess (82, 86) is formed, and has an oil groove (83, 87) connected to the recess (82, 86) and extending in the circumferential direction. A scroll type compressor characterized by comprising.

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