JP2021080903A - Scroll compressor - Google Patents

Abstract

To provide a scroll compressor capable of suppressing overheating of gas in a compression chamber.SOLUTION: A scroll compressor 101 includes a fixed scroll 24 having a fixed-side end plate 24a, and a movable scroll 26 having a movable-side end plate 26a. The fixed-side end plate 24a has a first fixed-side groove 24a5 and a second fixed-side groove 24a6. The first fixed-side groove 24a5 communicates with a compression chamber 40. The second fixed-side groove 24a6 is formed on the side of the movable-side end plate 26a. The movable-side end plate 26a has a movable-side hole 26a2 and a movable-side groove 26a3. The movable-side hole 26a2 communicates with a back pressure space 72 formed on the back side of the movable-side end plate 26a with respect to the compression chamber 40. The movable-side groove 26a3 is formed on the side of the fixed-side end plate 24a. The back pressure space 72 communicates with the compression chamber 40 through the movable-side hole 26a2, the second fixed-side groove 24a6, the movable-side groove 26a3, and the first fixed-side groove 24a5 while the movable scroll 26 turns with respect to the fixed scroll 24.SELECTED DRAWING: Figure 6A

Description

Scroll compressor used for air conditioners, etc.

Patent Document 1 (Japanese Unexamined Patent Publication No. 2014-070598) discloses a scroll compressor provided with a passage for supplying lubricating oil from a high-pressure space in a casing to a compression chamber.

The high-temperature and high-pressure lubricating oil may overheat the gas in the compression chamber, reducing the efficiency of the compressor. An object of the present disclosure is to provide a scroll compressor capable of suppressing a decrease in the efficiency of the compressor.

The scroll compressor of the first aspect includes a fixed scroll having a fixed side end plate and a movable scroll having a movable side end plate. The fixed side end plate has a first fixed side groove and a second fixed side groove. The first fixed gutter communicates with a compression chamber formed between the fixed scroll and the movable scroll. The second fixed gutter is formed on the side of the movable end plate. The movable side end plate has a movable side hole and a movable side groove. The movable side hole communicates with the back pressure space formed on the back side of the movable side end plate with respect to the compression chamber. The movable gutter is formed on the side of the fixed end plate. The back pressure space communicates with the compression chamber through the movable gutter, the second fixed gutter, the movable gutter and the first fixed gutter while the movable scroll swivels with respect to the fixed scroll.

The scroll compressor of the first aspect can suppress overheating of the gas in the compression chamber by supplying lubricating oil from the back pressure space to the compression chamber.

The scroll compressor of the second aspect is the scroll compressor of the first aspect, and the first fixed gutter communicates with the movable gutter while the movable scroll turns with respect to the fixed scroll. The second fixed gutter communicates with the movable gutter and the movable gutter while the movable scroll turns with respect to the fixed scroll.

The scroll compressor of the second aspect can suppress overheating of the gas in the compression chamber by supplying lubricating oil from the back pressure space to the compression chamber.

The scroll compressor of the third aspect is the scroll compressor of the first aspect or the second aspect, and the movable scroll is the fixed scroll in the first fixed side groove, the second fixed side groove, the movable side hole and the movable side groove. It is provided at a position where the transition from the first state to the fourth state is repeated in order while turning. The first state is a state in which the first fixed gutter does not communicate with the movable gutter and the movable gutter, and the second fixed gutter communicates with the movable gutter and the movable gutter. The second state is a state in which the first fixed gutter does not communicate with the movable gutter and the movable gutter, and the second fixed gutter does not communicate with the movable gutter and the movable gutter. The third state is a state in which the first fixed gutter does not communicate with the movable gutter, the first fixed gutter communicates with the movable gutter, and the second fixed gutter does not communicate with the movable gutter and the movable gutter. .. The fourth state is the same as the second state.

The scroll compressor of the third aspect can suppress overheating of the gas in the compression chamber by supplying lubricating oil from the back pressure space to the compression chamber.

The scroll compressor of the fourth aspect is the scroll compressor of the first aspect or the second aspect, and the movable scroll is the fixed scroll in the first fixed side groove, the second fixed side groove, the movable side hole and the movable side groove. It is provided at a position where the transition from the first state to the seventh state is repeated in order while turning. The first state is a state in which the first fixed gutter does not communicate with the movable gutter and the movable gutter, and the second fixed gutter communicates with the movable gutter and the movable gutter. The second state is a state in which the first fixed gutter does not communicate with the movable gutter and the movable gutter, the second fixed gutter does not communicate with the movable gutter, and the second fixed gutter communicates with the movable gutter. is there. The third state is a state in which the first fixed gutter does not communicate with the movable gutter and the movable gutter, and the second fixed gutter does not communicate with the movable gutter and the movable gutter. The fourth state is a state in which the first fixed gutter does not communicate with the movable gutter, the first fixed gutter communicates with the movable gutter, and the second fixed gutter does not communicate with the movable gutter and the movable gutter. .. The fifth state is the same as the third state. The sixth state is a state in which the first fixed gutter communicates with the movable gutter, the first fixed gutter does not communicate with the movable gutter, and the second fixed gutter does not communicate with the movable gutter and the movable gutter. .. The seventh state is the same as the second state.

The scroll compressor of the fourth aspect can suppress overheating of the gas in the compression chamber by supplying lubricating oil from the back pressure space to the compression chamber.

The scroll compressor of the fifth viewpoint is a scroll compressor of any one of the first to fourth viewpoints, and the movable scroll is a fixed scroll in the movable side hole, the second fixed side groove, the movable side groove and the first fixed side groove. Lubricating oil is supplied from the back pressure space to the compression chamber by the differential pressure while turning.

The fifth aspect scroll compressor does not require a power source to supply lubricating oil to the compression chamber.

The scroll compressor of the sixth aspect is the scroll compressor of any one of the first to fifth aspects, and the fixed side end plate further has a third fixed side groove formed on the surface sliding with the movable side end plate. Have.

The scroll compressor of the sixth aspect can suppress the seizure of the sliding surface of the fixed scroll.

It is a vertical sectional view of the scroll compressor 101. It is a bottom view of the fixed scroll 24. It is a top view of the movable scroll 26. It is the top view of the fixed scroll 24 which showed the movable side lap 26b of the movable scroll 26, and the compression chamber 40. It is a perspective view of the Oldham joint 39. It is a figure which shows the communication state of the 1st state. It is a figure which shows the communication state of the 2nd state. It is a figure which shows the communication state of the 3rd state. It is a figure which shows the communication state of the 4th state. It is a figure which shows the communication state of the 5th state. It is a figure which shows the communication state of the 6th state. It is a figure which shows the communication state of the 7th state. It is a figure which shows the change of the communication state while the movable scroll 26 makes one turn with respect to a fixed scroll 24.

(1) Overall Configuration The scroll compressor 101 is used in a device provided with a vapor compression refrigeration cycle using a refrigerant. The equipment in which the scroll compressor 101 is used is, for example, an air conditioner and a refrigerating device. The scroll compressor 101 compresses the refrigerant circulating in the refrigerant circuits constituting the refrigeration cycle.

FIG. 1 is a vertical cross-sectional view of the scroll compressor 101. In FIG. 1, the arrow U points to the upper side in the vertical direction. The scroll compressor 101 mainly consists of a casing 10, a compression mechanism 15, a housing 23, an old dam joint 39, a motor 16, a lower bearing 60, a crankshaft 17, a suction pipe 19, and a discharge pipe 20. It is composed.

(1-1) Casing 10
The casing 10 is composed of a cylindrical body casing portion 11, a bowl-shaped upper wall portion 12, and a bowl-shaped bottom wall portion 13. The upper wall portion 12 is airtightly welded to the upper end portion of the body casing portion 11. The bottom wall portion 13 is airtightly welded to the lower end portion of the body casing portion 11.

A compression mechanism 15, a housing 23, an old dam joint 39, a motor 16, a lower bearing 60, and a crankshaft 17 are mainly housed inside the casing 10. The suction pipe 19 and the discharge pipe 20 are airtightly welded to the casing 10.

At the bottom of the internal space of the casing 10, an oil sump portion 10a, which is a space for storing lubricating oil, is formed. The lubricating oil is a refrigerating machine oil used to maintain good lubricity of the compression mechanism 15 and the crankshaft 17 during the operation of the scroll compressor 101.

(1-2) Compression mechanism 15
The compression mechanism 15 sucks and compresses the low-temperature and low-pressure refrigerant gas, and discharges the high-temperature and high-pressure refrigerant gas (hereinafter, referred to as “compressed refrigerant”). The compression mechanism 15 is mainly composed of a fixed scroll 24 and a movable scroll 26. The fixed scroll 24 is fixed to the casing 10. The movable scroll 26 performs a turning motion that turns with respect to the fixed scroll 24. FIG. 2 is a bottom view of the fixed scroll 24 as viewed along the vertical direction. FIG. 3 is a top view of the movable scroll 26 as viewed along the vertical direction.

(1-2-1) Fixed scroll 24
The fixed scroll 24 has a fixed side end plate 24a and a fixed side wrap 24b. The fixed-side end plate 24a has a disk-shaped main body portion 24a1 and a peripheral edge portion 24a2 surrounding the fixed-side wrap 24b. The fixed side wrap 24b projects from the first lower surface 24a3 of the main body portion 24a1 of the fixed side end plate 24a. The fixed side wrap 24b has a spiral shape when viewed along the vertical direction. As shown in FIG. 2, a first fixed side groove 24a5, a second fixed side groove 24a6, and a third fixed side groove 24a7 are formed on the second lower surface 24a4 of the peripheral edge portion 24a2 of the fixed side end plate 24a.

A main suction hole 24c is formed in the fixed side end plate 24a. The main suction hole 24c is a space for connecting the suction pipe 19 and the compression chamber 40 described later. The main suction hole 24c is a space for introducing a low-temperature low-pressure refrigerant gas from the suction pipe 19 into the compression chamber 40.

As shown in FIG. 2, the first fixed side groove 24a5 and the second fixed side groove 24a6 are formed in the vicinity of the main suction hole 24c. Details of the first fixed gutter 24a5 and the second fixed gutter 24a6 will be described later.

As shown in FIG. 2, the third fixed gutter 24a7 has a C-shape. On the outside of the fixed-side wrap 24b, an oil communication passage 24f is formed inside the fixed-side end plate 24a. One end of the oil communication passage 24f opens to the second lower surface 24a4, and the other end of the oil communication passage 24f communicates with the third fixed gutter 24a7.

As shown in FIG. 1, an enlarged recess 42, which is a cylindrical recess, is formed on the upper surface of the fixed-side end plate 24a. The expansion recess 42 is covered with a cover member 44. A discharge hole 41 is formed on the bottom surface of the expansion recess 42. The discharge hole 41 communicates with the compression chamber 40.

A first compressed refrigerant flow path (not shown) is formed on the fixed side end plate 24a. The first compressed refrigerant flow path communicates with the expansion recess 42 and is open to the second lower surface 24a4 of the fixed side end plate 24a. The first compressed refrigerant flow path communicates with the second compressed refrigerant flow path described later through this opening.

Two first key grooves 24g are formed on the second lower surface 24a4 of the fixed side end plate 24a. The first key portion 39b of the Oldham joint 39, which will be described later, is fitted into each of the first key grooves 24g.

(1-2-2) Movable scroll 26
The movable scroll 26 has a movable side end plate 26a, a movable side lap 26b, and an upper end bearing 26c. The movable side wrap 26b projects from the first upper surface 26a1 of the disk-shaped movable side end plate 26a. The movable side lap 26b has a spiral shape when viewed along the vertical direction. The upper end bearing 26c projects from the central portion of the lower surface of the movable end plate 26a. The upper end bearing 26c has a cylindrical shape. The movable side end plate 26a has a movable side hole 26a2 and a movable side groove 26a3. The movable side hole 26a2 penetrates the movable side end plate 26a in the vertical direction. The movable gutter 26a3 is formed on the first upper surface 26a1 as shown in FIG. Details of the movable side hole 26a2 and the movable side groove 26a3 will be described later.

In the fixed scroll 24 and the movable scroll 26, the second lower surface 24a4 of the fixed side end plate 24a and the first upper surface 26a1 of the movable side end plate 26a are in contact with each other, and the fixed side wrap 24b and the movable side wrap 26b are engaged with each other. By being combined with, a compression chamber 40 is formed. The compression chamber 40 is a space surrounded by the fixed side end plate 24a, the fixed side wrap 24b, the movable side end plate 26a, and the movable side lap 26b. The volume of the compression chamber 40 changes periodically due to the turning motion of the movable scroll 26. During the turning of the movable scroll 26, the surfaces of the fixed side end plate 24a and the fixed side wrap 24b of the fixed scroll 24 slide with the surfaces of the movable side end plate 26a and the movable side wrap 26b of the movable scroll 26. Hereinafter, the surface of the fixed side end plate 24a that slides on the movable scroll 26 is referred to as a thrust sliding surface 24d. The thrust sliding surface 24d is a part of the second lower surface 24a4.

FIG. 4 is a top view of the fixed scroll 24 showing the movable side lap 26b, the movable side hole 26a2, the movable side groove 26a3, and the compression chamber 40. In FIG. 4, the hatched region represents the thrust sliding surface 24d. As shown in FIG. 4, the third fixed side groove 24a7 of the fixed scroll 24 is formed on the second lower surface 24a4 of the fixed side end plate 24a so as to fit within the thrust sliding surface 24d.

Two second key grooves 26d are formed on the second lower surface 24a4 of the movable end plate 26a. The second key portion 39c of the Oldham joint 39, which will be described later, is fitted into each of the second key grooves 26d.

(1-3) Housing 23
The housing 23 is arranged below the compression mechanism 15 and above the motor 16. The outer peripheral surface of the housing 23 is airtightly joined to the inner peripheral surface of the body casing portion 11. As a result, the internal space of the casing 10 is divided into a high pressure space 71 below the housing 23, a low pressure space 73 above the housing 23 and above the fixed scroll 24, and a back pressure space 72. As shown in FIG. 1, the back pressure space 72 is a space surrounded by the housing 23, the fixed scroll 24, and the movable scroll 26. The movable scroll 26 is pressed against the fixed scroll 24 by the pressure of the back pressure space 72. The oil sump portion 10a is located at the bottom of the high pressure space 71.

The housing 23 mounts the fixed scroll 24 and sandwiches the movable scroll 26 together with the fixed scroll 24. A second compressed refrigerant flow path (not shown) is formed on the outer peripheral portion of the housing 23. The second compressed refrigerant flow path is a hole that penetrates the outer peripheral portion of the housing 23 in the vertical direction. The second compressed refrigerant flow path communicates with the first compressed refrigerant flow path on the upper surface of the housing 23, and communicates with the high pressure space 71 on the lower surface of the housing 23. In other words, the discharge hole 41 of the compression mechanism 15 communicates with the high pressure space 71 via the expansion recess 42, the first compressed refrigerant flow path, and the second compressed refrigerant flow path.

A recess called a crank chamber 23a is formed on the upper surface of the housing 23. A housing through hole 31 is formed in the housing 23. The housing through hole 31 is a hole that vertically penetrates the housing 23 from the central portion of the bottom surface of the crank chamber 23a to the central portion of the lower surface of the housing 23. Hereinafter, a part of the housing 23 and a portion around the housing through hole 31 is referred to as an upper bearing 32. An annular groove 23g is formed on the outer peripheral portion of the bottom surface of the crank chamber 23a.

The housing 23 is formed with an oil discharge passage 23b that connects the crank chamber 23a and the high pressure space 71. In the crank chamber 23a, the opening of the oil discharge passage 23b is formed near the bottom surface of the crank chamber 23a.

The housing 23 is formed with a housing oil supply passage 23c for supplying lubricating oil to the compression mechanism 15. One end of the housing oil supply passage 23c is open to the annular groove 23g. The other end of the housing oil supply passage 23c opens to the outer peripheral portion of the upper surface of the housing 23 and communicates with the oil communication passage 24f of the fixed scroll 24. The lubricating oil of the crank chamber 23a flows into the third fixed gutter 24a7 via the annular groove 23g, the housing oil supply passage 23c and the oil communication passage 24f, and is supplied to the compression chamber 40 via the thrust sliding surface 24d. Inside the housing oil supply passage 23c, a throttle mechanism (not shown) for reducing the pressure of the lubricating oil flowing through the housing oil supply passage 23c is inserted.

(1-4) Oldham fitting 39
The oldham joint 39 is a member for suppressing the rotation of the rotating movable scroll 26. The oldham joint 39 is arranged between the movable scroll 26 and the housing 23 in the back pressure space 72. FIG. 5 is a perspective view of the Oldham joint 39.

The oldham joint 39 has an annular body portion 39a, a pair of first key portions 39b, and a pair of second key portions 39c. The first key portion 39b and the second key portion 39c are portions protruding from the upper surface of the annular main body portion 39a. The first key portion 39b is fitted in the first key groove 24g of the fixed scroll 24. The second key portion 39c is fitted in the second key groove 26d of the movable scroll 26. While the movable scroll 26 is turning, the first key portion 39b reciprocates in the first key groove 24g along a predetermined direction, and the second key portion 39c reciprocates in the second key groove 26d in a predetermined direction. Reciprocate along. As a result, the rotation of the rotating movable scroll 26 is suppressed.

(1-5) Motor 16
The motor 16 is arranged below the housing 23. The motor 16 mainly has a stator 51 and a rotor 52.

The stator 51 is mainly composed of a stator core 51a and a plurality of coils 51b. The stator core 51a is a cylindrical member fixed to the inner peripheral surface of the casing 10. The stator core 51a has a plurality of teeth (not shown). The coil 51b is formed by winding the winding around the teeth.

A plurality of core cuts are formed on the outer peripheral surface of the stator core 51a. The core cut is a groove formed in the vertical direction from the upper end surface to the lower end surface of the stator core 51a.

The rotor 52 is a cylindrical member arranged inside the stator core 51a. An air gap is formed between the inner peripheral surface of the stator core 51a and the outer peripheral surface of the rotor 52. The rotor 52 is connected to the crankshaft 17. The rotor 52 is connected to the compression mechanism 15 via the crankshaft 17. The rotor 52 rotates the crankshaft 17 around the rotation shaft 16a. The rotating shaft 16a passes through the central axis of the rotor 52.

The motor 16 rotates the movable scroll 26 via the rotation of the crankshaft 17 and functions as a power source for compressing the gas refrigerant in the compression chamber 40.

(1-6) Lower bearing 60
The lower bearing 60 is arranged below the motor 16. The outer peripheral surface of the lower bearing 60 is joined to the inner peripheral surface of the casing 10. The lower bearing 60 rotatably supports the crankshaft 17.

(1-7) Crankshaft 17
The crankshaft 17 is arranged so that its axial direction is along the vertical direction. The axial center of the upper end portion of the crankshaft 17 is eccentric with respect to the axial center of the portion excluding the upper end portion. The crankshaft 17 has a balance weight 18. The balance weight 18 is closely fixed to the crankshaft 17 at a height position below the housing 23 and above the motor 16.

The crankshaft 17 penetrates the rotation center of the rotor 52 in the vertical direction and is connected to the rotor 52. The upper end of the crankshaft 17 is fitted into the upper end bearing 26c of the movable scroll 26. As a result, since the crankshaft 17 is connected to the movable scroll 26, the rotation of the crankshaft 17 is transmitted to the movable scroll 26. The crankshaft 17 is rotatably supported by an upper bearing 32 and a lower bearing 60.

A main oil supply passage 61 is formed inside the crankshaft 17. The main oil supply passage 61 extends along the axial direction (vertical direction) of the crankshaft 17. The upper end of the main oil supply passage 61 communicates with the oil chamber 83, which is a space between the upper end surface of the crankshaft 17 and the lower surface of the movable end plate 26a. The lower end of the main oil supply passage 61 communicates with the oil sump portion 10a.

The crankshaft 17 has a first sub-fueling passage 61a, a second sub-fueling passage 61b, and a third sub-fueling passage 61c that branch from the main refueling passage 61. The first sub-fueling passage 61a, the second sub-fueling passage 61b, and the third sub-fueling passage 61c extend in the horizontal direction. The first auxiliary oil supply passage 61a is open to the sliding portion between the crankshaft 17 and the upper end bearing 26c of the movable scroll 26. The second auxiliary oil supply passage 61b is open to the sliding portion between the crankshaft 17 and the upper bearing 32 of the housing 23. The third auxiliary oil supply passage 61c is open to the sliding portion between the crankshaft 17 and the lower bearing 60.

(1-8) Inhalation tube 19
The suction pipe 19 is a pipe for introducing the refrigerant of the refrigerant circuit from the outside of the casing 10 to the compression mechanism 15. The suction pipe 19 penetrates the upper wall portion 12 of the casing 10. Inside the casing 10, the end of the suction pipe 19 is fitted into the main suction hole 24c of the fixed scroll 24.

(1-9) Discharge pipe 20
The discharge pipe 20 is a pipe for discharging the compressed refrigerant from the high-pressure space 71 to the outside of the casing 10. The discharge pipe 20 penetrates the body casing portion 11 of the casing 10.

(2) Operation of Scroll Compressor 101 First, the flow of the refrigerant inside the scroll compressor 101 will be described. Next, the flow of lubricating oil inside the scroll compressor 101 will be described.

(2-1) Flow of Refrigerant The low-temperature and low-pressure refrigerant before being compressed is supplied from the suction pipe 19 to the compression chamber 40 of the compression mechanism 15 via the main suction hole 24c. In the compression chamber 40, the refrigerant is compressed into a compressed refrigerant. The compressed refrigerant is discharged from the discharge hole 41 into the expansion recess 42, then supplied to the high-pressure space 71, and is discharged from the discharge pipe 20 to the outside of the scroll compressor 101.

(2-2) Flow of Lubricating Oil When the compression mechanism 15 compresses the refrigerant and the compressed refrigerant is supplied to the high pressure space 71, the pressure in the high pressure space 71 rises. The high-pressure space 71 communicates with the third fixed side groove 24a7 of the fixed scroll 24 via the main oil supply passage 61, the crank chamber 23a, the annular groove 23g, the housing oil supply passage 23c, the oil communication passage 24f, and the like, and communicates with the third fixed side groove 24a7. Communicates with the back pressure space 72 via the thrust sliding surface 24d. The back pressure space 72 is a space having a lower pressure than the high pressure space 71. Therefore, a differential pressure is generated between the high pressure space 71 and the back pressure space 72. Due to this differential pressure, the lubricating oil stored in the oil sump portion 10a of the high pressure space 71 rises up the main oil supply passage 61 and is sucked toward the back pressure space 72.

The lubricating oil that rises in the main oil supply passage 61 is supplied to each sliding portion. The sliding portion is a sliding portion between the crankshaft 17 and the lower bearing 60, a sliding portion between the crankshaft 17 and the upper bearing 32, and a sliding portion between the crankshaft 17 and the upper end bearing 26c. It is a moving part. A part of the lubricating oil that lubricates each sliding portion flows into the high-pressure space 71 and returns to the oil sump portion 10a, and the rest flows into the crank chamber 23a. A part of the lubricating oil that has flowed into the crank chamber 23a flows into the high-pressure space 71 via the oil discharge passage 23b and returns to the oil sump portion 10a. Most of the lubricating oil that has flowed into the crank chamber 23a passes through the annular groove 23g, the housing oil supply passage 23c, and the oil connecting passage 24f, and is supplied to the third fixed side groove 24a7. A part of the lubricating oil supplied to the third fixed gutter 24a7 flows into the back pressure space 72 and the compression chamber 40 while sealing the thrust sliding surface 24d. The lubricating oil that has flowed into the compression chamber 40 is mixed with the compressed refrigerant in the form of minute oil droplets, flows into the high-pressure space 71 together with the compressed refrigerant, and returns to the oil sump portion 10a.

A part of the lubricating oil that has flowed into the back pressure space 72 passes through the movable side hole 26a2, the second fixed side groove 24a6, the movable side groove 26a3, and the first fixed side groove 24a5 in this order, and flows into the compression chamber 40. Next, the flow of this lubricating oil will be described.

(3) Detailed configuration The first fixed gutter 24a5, the second fixed gutter 24a6, the movable gutter 26a2, and the movable gutter 26a3 have a back pressure space for lubricating oil due to a differential pressure while the movable gutter 26 turns with respect to the fixed gutter 24. It is a passage for supplying from 72 to the compression chamber 40. The first fixed side groove 24a5 and the second fixed side groove 24a6 are formed on the second lower surface 24a4 of the fixed side end plate 24a on the side of the movable side end plate 26a. The movable side groove 26a3 is formed on the first upper surface 26a1 of the movable side end plate 26a on the side of the fixed side end plate 24a.

The first fixed gutter 24a5 is a substantially J-shaped groove that communicates with the compression chamber 40. As shown in FIG. 2, the first fixed gutter 24a5 has a stretched portion 24a8 and a curved portion 24a9. The extending portion 24a8 extends from the inner edge of the peripheral edge portion 24a2 toward the outer edge. The curved portion 24a9 extends from the end portion of the extended portion 24a8 on the outer edge side of the peripheral edge portion 24a2 and is curved along the circumferential direction of the fixed side end plate 24a.

The second fixed gutter 24a6 is a groove formed in the vicinity of the first fixed gutter 24a5 and on the outer edge side of the peripheral edge portion 24a2 with respect to the first fixed gutter 24a5. The second fixed side groove 24a6 generally extends along the circumferential direction of the fixed side end plate 24a.

The movable side hole 26a2 is a hole that communicates with the back pressure space 72. The movable gutter 26a3 is a groove formed in the vicinity of the movable gutter 26a2. The movable side groove 26a3 generally extends along the circumferential direction of the movable side end plate 26a.

The back pressure space 72 communicates with the compression chamber 40 via the movable side hole 26a2, the second fixed side groove 24a6, the movable side groove 26a3, and the first fixed side groove 24a5 while the movable scroll 26 turns with respect to the fixed scroll 24. Specifically, in the process in which the movable scroll 26 turns once with respect to the fixed scroll 24, the first fixed gutter 24a5 communicates with at least the movable gutter 26a3, and the second fixed gutter 24a6 has at least the movable gutter 26a2 and It communicates with the movable gutter 26a3.

Next, referring to FIGS. 6A to 6G and FIG. 7, the movable gutter 26a2, the second fixed gutter 24a6, the movable gutter 26a3, and the first fixed while the movable scroll 26 turns once with respect to the fixed scroll 24. A change in the communication state of the gutters 24a5 (hereinafter, simply referred to as “communication state”) will be described. 6A to 6G are top views of the fixed scroll 24 showing the movable side lap 26b, the movable side hole 26a2, the movable side groove 26a3, and the compression chamber 40, as in FIG. FIG. 7 is a diagram showing a change in the communication state while the movable scroll 26 makes one turn with respect to the fixed scroll 24. In FIG. 7, as the movable scroll 26 turns, the communication state changes counterclockwise.

While the movable scroll 26 makes one turn with respect to the fixed scroll 24, the communication state changes in order from FIG. 6A to FIG. 6G and returns to FIG. 6A. Hereinafter, the communication states shown in FIGS. 6A to 6G are referred to as the first state to the seventh state, respectively.

7 shows the first period M1 to the fourth period M4 satisfying a predetermined communication state while the movable scroll 26 makes one turn with respect to the fixed scroll 24, and the first state shown in FIGS. 6A to 6G. The timing of the 7th state is shown. In the first period M1, the second fixed gutter 24a6 communicates with the movable gutter 26a2. In the second period M2, the second fixed gutter 24a6 communicates with the movable gutter 26a3. In the third period M3, the first fixed gutter 24a5 communicates with the movable gutter 26a3. In the fourth period M4, the first fixed gutter 24a5 communicates with the movable gutter 26a2. The first period M1 is included in the second period M2. While the movable scroll 26 is turning, the second period M2, the third period M3, and the fourth period M4 shift in this order, and these periods do not overlap each other.

The first fixed gutter 24a5, the second fixed gutter 24a6, the movable gutter 26a2, and the movable gutter 26a3 repeatedly shift from the first state to the seventh state in order while the movable scroll 26 turns once with respect to the fixed scroll 24. It is provided at such a position.

In the first to seventh states, the pressure of the back pressure space 72 communicating with the movable side hole 26a2 is always higher than the pressure of the compression chamber 40 communicating with the first fixed side groove 24a5. The compression chamber 40 communicating with the first fixed side groove 24a5 is the outermost compression chamber 40a formed on the outermost side in the radial direction of the fixed side end plate 24a.

In the first to seventh states, the pressure of the movable side hole 26a2 is always the same as the pressure of the back pressure space 72. In the process of repeatedly transitioning from the first state to the seventh state, the pressures of the first fixed gutter 24a5, the second fixed gutter 24a6, and the movable gutter 26a3 change.

In the following, the magnitude relation of the pressure of the first fixed side groove 24a5, the second fixed side groove 24a6, the movable side hole 26a2 and the movable side groove 26a3 in the first state to the seventh state corresponding to FIGS. Will be described using.
PF1: Pressure of the first fixed gutter 24a5 (pressure of the outermost compression chamber 40a)
-PF2: Pressure of the second fixed gutter 24a6-PO1: Pressure of the movable side hole 26a2 (pressure of the back pressure space 72)
-PO2: Pressure of movable gutter 26a3

(3-1) First state (communication state in FIG. 6A)
The first state is the state in the first period M1. In the first state, the first fixed gutter 24a5 does not communicate with the movable gutter 26a2 and the movable gutter 26a3, and the second fixed gutter 24a6 communicates with the movable gutter 26a2 and the movable gutter 26a3. In the first state, the first fixed gutter 24a5 communicates with the outermost compression chamber 40a.

The magnitude relationship of pressure in the first state is represented by PO2 = PF2 <PO1. In the first state, since PF2 <PO1, the lubricating oil in the back pressure space 72 passes through the movable side hole 26a2 and moves to the second fixed side groove 24a6 due to the differential pressure. As a result, PO2, PF2 and PO1 become equal to each other. In the first state, the lubricating oil in the second fixed gutter 24a6 moves to the movable gutter 26a3.

(3-2) Second state (communication state in FIG. 6B)
In the process of turning the movable scroll 26 to shift from the first state to the second state, the communication between the movable side hole 26a2 and the second fixed side groove 24a6 is completed. In the second state, the first fixed gutter 24a5 does not communicate with the outermost compression chamber 40a that communicated in the first state.

The second state is the state in the second period M2. In the second state, the first fixed gutter 24a5 does not communicate with the movable gutter 26a2 and the movable gutter 26a3, the second fixed gutter 24a6 does not communicate with the movable gutter 26a2, and the second fixed gutter 24a6. Communicates with the movable gutter 26a3.

The magnitude relationship of pressure in the second state is represented by PO2 = PF2 = PO1. In the second state, the lubricating oil in the second fixed gutter 24a6 moves to the movable gutter 26a3.

(3-3) Third state (communication state in FIG. 6C)
In the process of turning the movable scroll 26 to shift from the second state to the third state, the communication between the movable side groove 26a3 and the second fixed side groove 24a6 is completed, and a new outermost compression chamber 40a is formed. In the third state, the first fixed gutter 24a5 communicates with the newly formed outermost compression chamber 40a.

In the third state, the first fixed gutter 24a5 does not communicate with the movable gutter 26a2 and the movable gutter 26a3, and the second fixed gutter 24a6 does not communicate with the movable gutter 26a2 and the movable gutter 26a3.

The magnitude relationship of the pressure in the third state is represented by PF1 <PO2 = PF2 = PO1. In the third state, the lubricating oil in the second fixed gutter 24a6 moves to the movable gutter 26a3.

(3-4) Fourth state (communication state in FIG. 6D)
In the process of turning the movable scroll 26 to shift from the third state to the fourth state, communication between the movable side groove 26a3 and the first fixed side groove 24a5 starts. In the fourth state, the first fixed gutter 24a5 communicates with the outermost compression chamber 40a formed in the third state.

The fourth state is the state in the third period M3. In the fourth state, the first fixed gutter 24a5 does not communicate with the movable gutter 26a2, the first fixed gutter 24a5 communicates with the movable gutter 26a3, and the second fixed gutter 24a6 communicates with the movable gutter 26a2. And does not communicate with the movable gutter 26a3.

The magnitude relationship of the pressure in the fourth state is represented by PF1 <PO2 = PF2 = PO1. In the fourth state, since PF1 <PO2, the lubricating oil in the movable gutter 26a3 passes through the first fixed gutter 24a5 and moves to the outermost compression chamber 40a due to the differential pressure. As a result, PF1 becomes equal to PO2 and PO2 becomes lower than PF2.

(3-5) Fifth state (communication state in FIG. 6E)
In the process of turning the movable scroll 26 to shift from the fourth state to the fifth state, the communication between the movable side groove 26a3 and the first fixed side groove 24a5 is completed. In the fifth state, the first fixed gutter 24a5 communicates with the outermost compression chamber 40a formed in the third state.

The communication state of the fifth state is the same as that of the third state.

The magnitude relationship of the pressure in the fifth state is represented by PF1 = PO2 <PF2 = PO1.

(3-6) 6th state (communication state in FIG. 6F)
In the process of turning the movable scroll 26 to shift from the fifth state to the sixth state, communication between the movable side hole 26a2 and the first fixed side groove 24a5 starts. In the sixth state, the first fixed gutter 24a5 communicates with the outermost compression chamber 40a formed in the third state.

The sixth state is the state in the fourth period M4. In the sixth state, the first fixed gutter 24a5 communicates with the movable gutter 26a2, the first fixed gutter 24a5 does not communicate with the movable gutter 26a3, and the second fixed gutter 24a6 communicates with the movable gutter 26a2. And does not communicate with the movable gutter 26a3. In FIG. 6F, the movable gutter 26a2 is located near the center of the first fixed gutter 24a5 in the width direction.

In the fifth state, PF1 is smaller than PO1. PF1 increases in the process of transitioning from the fifth state to the sixth state. The magnitude relationship of the pressure in the sixth state shown in FIG. 6F is PF1 = PO1. In the process of transitioning from the sixth state to the seventh state, PF1 further increases and becomes larger than PO1.

(3-7) 7th state (communication state in FIG. 6G)
In the process of turning the movable scroll 26 to shift from the sixth state to the seventh state, the communication between the movable side hole 26a2 and the first fixed side groove 24a5 is completed, and the communication between the movable side groove 26a3 and the second fixed side groove 24a6 is completed. Start. In the seventh state, the first fixed gutter 24a5 communicates with the outermost compression chamber 40a formed in the third state.

The seventh state is the state in the second period M2. The communication state of the seventh state is the same as that of the second state.

The magnitude relationship of pressure in the seventh state is represented by PO2 <PF2 = PO1. In the seventh state, since PO2 <PF2, the lubricating oil in the second fixed gutter 24a6 moves to the movable gutter 26a3 due to the differential pressure. As a result, PO2 becomes equal to PF2 and PF2 becomes lower than PO1.

As shown in FIG. 7, between the sixth state and the seventh state, the same communication state as the third state and the fifth state may exist for a short time.

(3-8) First state (communication state in FIG. 6A)
In the process of turning the movable scroll 26 to shift from the seventh state to the first state, communication between the movable side hole 26a2 and the second fixed side groove 24a6 starts. In the first state, the first fixed gutter 24a5 communicates with the outermost compression chamber 40a formed in the third state.

(4) Features (4-1)
In the scroll compressor 101, as shown in FIGS. 6A to 6G, the back pressure space 72 has a movable gutter 26a2, a second fixed gutter 24a6, and a movable gutter 26a3 while the movable scroll 26 turns with respect to the fixed scroll 24. And communicate with the compression chamber 40 (outermost compression chamber 40a) via the first fixed gutter 24a5. As a result, the lubricating oil in the back pressure space 72 is supplied to the compression chamber 40 (outermost compression chamber 40a) by the differential pressure while the movable scroll 26 turns with respect to the fixed scroll 24.

The temperature of the lubricating oil in the back pressure space 72 is lower than the temperature of the lubricating oil in the high pressure space 71. Therefore, the scroll compressor 101 supplies the lubricating oil from the back pressure space 72 to the compression chamber 40, so that the gas in the compression chamber 40 is supplied as compared with the case where the lubricating oil is supplied from the high pressure space 71 to the compression chamber 40. Overheating can be suppressed. As a result, the decrease in volumetric efficiency and heat insulation efficiency of the scroll compressor 101 is suppressed.

(4-2)
In the scroll compressor 101, since the lubricating oil in the back pressure space 72 is supplied to the compression chamber 40 by the differential pressure, a power source for supplying the lubricating oil to the compression chamber 40 is not required.

(4-3)
In the scroll compressor 101, by changing the positions and dimensions of the first fixed gutter 24a5, the second fixed gutter 24a6, the movable gutter 26a2, and the movable gutter 26a3, the time and time for the back pressure space 72 and the compression chamber 40 to communicate with each other can be increased. The timing can be adjusted. Therefore, in the scroll compressor 101, the timing of supplying the lubricating oil to the compression chamber 40 and the amount of the lubricating oil supplied to the compression chamber 40 can be controlled relatively easily.

(4-4)
In the scroll compressor 101, the fixed scroll 24 has a third fixed gutter 24a7 to which lubricating oil is supplied. A part of the lubricating oil supplied to the third fixed gutter 24a7 flows into the back pressure space 72 and the compression chamber 40 while sealing the thrust sliding surface 24d. As a result, seizure of the sliding surface of the fixed scroll 24 is suppressed.

(5) Modification Example In the scroll compressor 101, as shown in FIGS. 6A to 6G, the movable scroll 26 is the fixed scroll 24 in the first fixed side groove 24a5, the second fixed side groove 24a6, the movable side hole 26a2 and the movable side groove 26a3. It is provided at a position where the transition from the first state to the seventh state is repeated in order while turning once.

However, in the scroll compressor 101, in the process in which the movable scroll 26 turns once with respect to the fixed scroll 24, the first fixed gutter 24a5 communicates with at least the movable gutter 26a3, and the second fixed gutter 24a6 is at least on the movable side. It suffices that the condition for communicating with the hole 26a2 and the movable gutter 26a3 is satisfied. As long as this condition is satisfied, changes in the shapes, dimensions, and communication states of the first fixed gutter 24a5, the second fixed gutter 24a6, the movable gutter 26a2, and the movable gutter 26a3 are not limited.

For example, the first fixed gutter 24a5, the second fixed gutter 24a6, the movable gutter 26a2, and the movable gutter 26a3 are first changed from the first state to the third state while the movable scroll 26 turns once with respect to the fixed scroll 24. It may be provided at a position where the cycle of shifting, then shifting to the fourth state, then shifting to the third state, and then shifting to the first state is repeated.
―Conclusion―
Although the embodiments of the present disclosure 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 present disclosure described in the claims. ..

24 Fixed scroll 24a Fixed gutter 24a5 1st fixed gutter 24a6 2nd fixed gutter 24a7 3rd fixed gutter 26 Movable gutter 26a Movable gutter 26a2 Movable gutter 26a3 Movable gutter 40 Compression chamber 72 Back pressure space 101 Scroll compressor

Japanese Unexamined Patent Publication No. 2014-070598

Claims (6)

A fixed scroll (24) having a fixed end plate (24a) and
A movable scroll (26) having a movable end plate (26a) and
With
The fixed side end plate is
A first fixed gutter (24a5) communicating with a compression chamber (40) formed between the fixed scroll and the movable scroll,
A second fixed gutter (24a6) formed on the side of the movable end plate,
Have,
The movable end plate is
A movable side hole (26a2) communicating with a back pressure space (72) formed on the back side of the movable side end plate with respect to the compression chamber,
A movable gutter (26a3) formed on the side of the fixed end plate,
Have,
The back pressure space communicates with the compression chamber through the movable gutter, the second fixed gutter, the movable gutter, and the first fixed gutter while the movable scroll swivels with respect to the fixed scroll.
Scroll compressor (101). The first fixed gutter communicates with the movable gutter while the movable scroll swivels with respect to the fixed scroll.
The second fixed gutter communicates with the movable gutter and the movable gutter while the movable scroll swivels with respect to the fixed scroll.
The scroll compressor according to claim 1. The first fixed gutter, the second fixed gutter, the movable gutter, and the movable gutter repeatedly shift from the first state to the fourth state in order while the movable scroll turns with respect to the fixed scroll. Provided in position,
The first state is a state in which the first fixed gutter does not communicate with the movable gutter and the movable gutter, and the second fixed gutter communicates with the movable gutter and the movable gutter.
The second state is a state in which the first fixed gutter does not communicate with the movable gutter and the movable gutter, and the second fixed gutter does not communicate with the movable gutter and the movable gutter.
In the third state, the first fixed gutter does not communicate with the movable gutter, the first fixed gutter communicates with the movable gutter, and the second fixed gutter communicates with the movable gutter and the movable gutter. It is in a state where it does not communicate with the movable gutter,
The fourth state is the same as the second state.
The scroll compressor according to claim 1 or 2. The first fixed gutter, the second fixed gutter, the movable gutter, and the movable gutter are repeatedly transitioned from the first state to the seventh state while the movable scroll turns with respect to the fixed scroll. Provided in position,
The first state is a state in which the first fixed gutter does not communicate with the movable gutter and the movable gutter, and the second fixed gutter communicates with the movable gutter and the movable gutter.
In the second state, the first fixed gutter does not communicate with the movable gutter and the movable gutter, the second fixed gutter does not communicate with the movable gutter, and the second fixed gutter does not communicate with the movable gutter. It is in a state of communicating with the movable gutter.
The third state is a state in which the first fixed gutter does not communicate with the movable gutter and the movable gutter, and the second fixed gutter does not communicate with the movable gutter and the movable gutter.
In the fourth state, the first fixed gutter does not communicate with the movable gutter, the first fixed gutter communicates with the movable gutter, and the second fixed gutter communicates with the movable gutter and the movable gutter. It is in a state where it does not communicate with the movable gutter,
The fifth state is the same as the third state,
In the sixth state, the first fixed gutter communicates with the movable gutter, the first fixed gutter does not communicate with the movable gutter, and the second fixed gutter communicates with the movable gutter and the movable gutter. It is in a state where it does not communicate with the movable gutter,
The seventh state is the same as the second state.
The scroll compressor according to claim 1 or 2. The movable side hole, the second fixed side groove, the movable side groove, and the first fixed side groove allow lubricating oil from the back pressure space to the compression chamber while the movable scroll swivels with respect to the fixed scroll. Supply to
The scroll compressor according to any one of claims 1 to 4. The fixed side end plate further has a third fixed side groove (24a7) formed on a surface sliding with the movable side end plate.
The scroll compressor according to any one of claims 1 to 5.

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