JPH045489A - Scroll compressor - Google Patents

Abstract

PURPOSE:To simplify a structure to rotate two scrolls in the same direction for a drive unit by setting the circular track of an outer circumferential end of a guide groove provided diametrically to be outside the circular track of the center of a drive pin provided at the outer circumference. CONSTITUTION:A drive unit 31 for rotating a second scroll 15 in the same direction as a first scroll 14 is composed of a drive pin 32 provided at the outer circumference of the scroll 14 and a guide groove 33 engaged with the drive pin 32 and provided diametrically to the scroll 15. The circular track of the outer circumferential end of a guide groove 34 is set to be outside the circular track of the center of the drive pin 32. Both scrolls 14, 15 can thus be rotated in the same direction by the single drive unit 31 for compression. A stable operation of a scroll compressor is thus achieved in a simple structure.

Description

DETAILED DESCRIPTION OF THE INVENTION (A) Field of Industrial Application This invention relates to a scroll compressor that performs compression by rotating both scrolls in the same direction.

(Example) Prior Art A conventional scroll compressor is configured such that a fixed scroll is fixed to a closed container and an orbiting scroll is rotated around the center of the fixed scroll.

However, in the conventional type, the drive shaft of the orbiting scroll has a cantilevered structure, so vibrations become large in the type for high-speed rotation. In addition, in large-sized scrolls, the centrifugal force of the orbiting scroll becomes extremely large, increasing the load acting on the bearing provided at the back of the orbiting scroll, which may lead to a decrease in efficiency and reliability.

On the other hand, as a scroll compressor for high-speed rotation,
Japanese Patent No. 7-49721 discloses a type in which both scrolls rotate and one scroll rotates relative to the other scroll.

(8) Problems to be solved by the invention However, this type of device had the following problems. That is, since the orbiting scroll is oscillated relative to the drive shaft, there is a risk that the orbiting scroll may vibrate violently during high-speed rotation, which is not necessarily satisfactory as a scroll compressor for high-speed rotation. Moreover, this scroll compressor rotates both scrolls in the same direction using a coupling ring and a protrusion provided on the outer peripheral edge of the wrap that fits into the groove of this ring, and the compression space formed by the wraps of both scrolls. Since the structure is swung so as to be gradually contracted and compressed from the outside to the inside, there is a problem in that the structure becomes complicated.

This invention solves the above problem, and aims to provide a scroll compressor with a simplified structure in which both scrolls rotate in the same direction.

(2) Means for Solving the Problems This invention houses an electric element and a scroll compression element in a closed container, and the scroll compression element is constructed by forming a frame having a bearing in the center and a spiral wrap on an end plate. a first scroll provided therein and driven by an electric element; a second scroll having a center eccentric to the center of the first scroll and having a spiral wrap erected on an end plate that faces and engages with the first scroll; In a scroll compressor configured with a drive device that rotates the second scroll in the same direction as the first scroll, the drive device rotates the second scroll in the same direction as the first scroll.
It consists of a drive pin provided on the outer periphery of either one of the scrolls, and a guide groove provided in the radial direction into which this pin fits, and the circular orbit at the outer peripheral end of this guide groove is connected to the circular orbit at the center of the drive pin. It is placed outside of the .

(Main) Operation This invention is configured as described above, and the first scroll driven by the electric element and the second scroll that faces and meshes with the first scroll are configured by a drive pin and a guide groove. The first and second scrolls are mounted on the outer periphery of the end plate, and compression can be performed while rotating both scrolls in the same direction. be.

(f) Examples The present invention will be explained below based on the examples shown in FIGS. 1 to 3.

1 is a closed container, inside this container there is an electric element 2 on the lower side,
Scroll compression elements 3 are respectively housed on the upper side. The electric element 2 is composed of a stator 4 and a rotor 5 disposed inside the stator. An air gap 6 is formed between the stator 4 and the rotor 5. A passage 7 is formed by cutting out a portion of the outer periphery of the stator 4.

A main frame 8 is mounted in pressure contact with the inner wall of the closed container 1, and a main bearing 9 is provided in the center of this frame. Reference numeral 1o denotes an auxiliary frame which is also attached in pressure contact with the inner wall of the closed container 1, and this auxiliary frame is provided with an auxiliary bearing portion 11 at its center. The main frame 8 and the auxiliary frame 1o are fixed with bolts 13 so as to form a hollow chamber 12 inside.

The scroll compression element 3 is composed of a first scroll 14 driven by the electric element 2 and a second scroll 15 rotated in the same direction as the first scroll. The first scroll 14 rotates by having a cylindrical end plate 16, a spiral wrap 17 made of an involute curved line standing upright on one side of the end plate, and protruding from the center of the other side of the end plate 16. Main drive shaft 1 inserted and fixed into child 5
It consists of 8. and the first scroll 14
constitutes the drive side scroll.

The second scroll 15 includes a cylindrical end plate 19, an annular wall 20 that projects from the periphery of one side of the end plate and slides into contact with the end plate 16 of the first scroll 14, and a ring wall 20 that is surrounded by the annular wall and stands up on the end plate 19. It is composed of a spiral wrap 21 made of a curved line with an inbonito angle correction tooth profile, and a driven shaft 22 protruding from the center of the other surface of the end plate 19. The second scroll 15 constitutes a driven scroll.

Involute wrap 17 of first scroll 14
The coordinates of the wrap of the involute angle correction tooth profile of the second scroll 15 are determined as
]Y = −R(sinθ−(θ+β)cos(θ+β
)] β= tan-' (PsinθbaPcosθ+e
)) However, R: the radius of the base circle, P: the radius of the circular orbit of the drive pin, and is determined as follows.

The first scroll 14 has a main drive shaft 18 supported by a main bearing 9 of the main frame 8, the second scroll 15 has a driven shaft 22 supported by an auxiliary bearing 11 of an auxiliary frame 10, and both scrolls 14.15 The wraps 17, 21 are interlocked facing each other within the hollow chamber 12 to form a plurality of compression spaces 23 therein.

The main frame 8 and the auxiliary frame 10 partition the inside of the closed container 1 into a low pressure chamber 24 and a high pressure chamber 25.

The main drive shaft 18 is provided with a discharge hole 26 for discharging the refrigerant compressed within the compression space 23 into the high pressure chamber 25 . This discharge hole has high pressure chambers 25 at the upper and lower sides of the electric element 2, respectively.
Two discharge ports 27 and 28 are provided.

The driven shaft 22 is provided with a suction hole 29 that guides the refrigerant in the low pressure chamber 24 into the compression space 23 . Reference numeral 30 denotes a communication passage provided in the end plate 19, which communicates with the suction hole 29 and guides the refrigerant into the compression space 23 from the outside.

31 is a drive device, and this drive device drives the first scroll 1
A drive pin 32 protruding from the outer periphery of the end plate 16 of No. 4
and a guide groove 33 provided in the radial direction in the annular wall 20 of the second scroll 15 into which the drive pin is fitted. This guide groove is formed in a 0-shape by notching the outside.

The circular orbit at the outer peripheral end of the guide groove 33 is formed outside the circular orbit at the center of the drive pin 32.

34 is a small hole provided in the end plate 16 of the first scroll 14, and this small hole communicates the compression space 23 during compression with the hollow chamber 12. The hollow chamber 12 and the low pressure chamber 24 are sealed by a seal member 35 provided on the sliding surface of the auxiliary bearing 11 of the auxiliary frame 10 and the driven shaft 22. The hollow chamber 12 and the high pressure chamber 25 are sealed by a seal member 36 provided on the sliding surface of the main bearing 9 of the main frame 8 and the main drive shaft 18.

37 is a suction pipe, and this suction pipe communicates with the inside of the low pressure chamber 24. 38 is a discharge pipe, and this discharge pipe communicates with the inside of the high pressure chamber 25.

In the scroll compressor configured in this manner, when the electric element 2 is rotated, its rotational force is transmitted to the first scroll 14 via the main drive shaft 18. The rotational force transmitted to the first scroll is transmitted to the second scroll 15 via the drive device 31, causing the second scroll to rotate in the same direction as the first scroll 14. The second scroll 15 rotates at a position where the center of the driven shaft 22 is allowed to be eccentric by a length te with respect to the center of the main drive shaft 18 of the first scroll 14. Therefore, the first scroll 14 and the second scroll 15 gradually reduce the compression space 23 formed by these scrolls from the outside to the inside, and the refrigerant flowing into the low pressure chamber 24 from the suction pipe 37 is caused to flow from the suction hole 29 of the driven shaft 22 through the communication passage 30 of the end plate 19 into the outer compression space 23 and is compressed. This compressed refrigerant passes through the discharge hole 26 provided in the main drive shaft 18 of the first scroll 14 (7), is discharged from the discharge port 27.28 into the high pressure chamber 25, and is then sealed from the discharge pipe 38. It is discharged outside the container 1. In addition, the medium-pressure refrigerant in the middle of compression is discharged into the hollow chamber 12 from the small hole 34 and acts as back pressure on the first and second scrolls 14.15, and the wraps 17.21 of these scrolls are
The ends of the mirror plate 16゜1 while maintaining a certain clearance from each other.
It is designed to slide at 9.

The drive device 31 that rotates the second scroll 15 together with the first scroll 14 in the same direction is driven by forming a circular orbit at the outer peripheral end of the guide groove 33 outside the circular orbit at the center of the drive pin 32. The pin 32 is prevented from coming out of the guide groove 33, and the second scroll 15 is rotated in the same direction as the rotation direction of the first scroll 14 by the second drive pin 32, so that compression can be performed in the compression space 23. ing.

Further, the first scroll 14 and the second scroll 15 are eccentrically centered by a length e, and the wrap 17 of the first scroll 14 is formed into a spiral consisting of an involute curve.
By forming the wrap 21 of the second scroll 15 into a spiral formed by the curve of the involute angle correction tooth profile, the contact portion of the wrap 17.21 is Compression is performed in the compression space 23 while preventing separation or abnormal pressure contact.

Further, the hollow chamber 12 is sealed by sealing members 35 and 36 to form the low pressure chamber 24.
By sealing the high-pressure chambers 25 and 25, low-pressure refrigerant and high-pressure refrigerant are prevented from entering, and the pressure can be maintained at a constant medium pressure.
This allows the axial sealing force of 4.15 to be an appropriate pressure.

The refrigerant compressed in the compression space 23 passes through the discharge hole 26 and is discharged into the high pressure chamber 25 from the upper discharge port 27 and the lower discharge port 28 of the electric element 2, respectively. At the same time, the refrigerant discharged from one discharge port 28 flows into the discharge pipe 38 through the air gap 6' of the electric element 2 and the passage 7, and the electric element 2 is effectively This allows for cooling and effective use of the heat from this electric element.

In this invention, the first and second scrolls 14.15 are compressed by rotating the first and second scrolls 14.15 in the same direction as the rotational direction of the electric element 2 using the drive device 31. It is possible to prevent one of the scrolls from vibrating, and to perform compression in the compression space 23 while rotating the first and second scrolls in the same direction using the drive pin 32.

In the above description, one wrap is formed in a spiral shape consisting of an involute curve, and the other wrap is formed in a spiral shape consisting of a curve of an involute angle correction tooth profile. Even if each is formed into a semi-circular spiral shape, a single drive pin can
- It goes without saying that compression can be performed while rotating the second scroll in the same direction.

(G) Effects of the Invention As described above, according to the present invention, the drive device can be connected to the first and second
It consists of a drive pin provided on the outer periphery of either one of the scrolls, and a guide groove provided in the radial direction into which this pin fits, and the circular orbit at the outer peripheral end of this guide groove is connected to the circular orbit at the center of the drive pin. Since the first and second scrolls are rotated in the same direction by a single drive pin, compression can be performed in the compression space, and even during high-speed rotation, the first and second scrolls can be rotated in the same direction.
- It is possible to prevent the second scroll from vibrating and to enable stable operation of the scroll compressor with a simple structure.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal sectional view of a scroll compressor showing an embodiment of the present invention, FIG. 2 is a sectional view of the scroll compressor taken along line A-A in FIG. 1, and FIG. 1st
FIG. 3 is a plan view showing the rotation orbits between the center of the drive pin and the outer peripheral end of the guide groove of the scroll and the second scroll. 1...Airtight container, 2...Electric element, 3...
・Scroll compression element, 8... Main frame, 9.
...Main bearing, 10...Auxiliary frame, -frame, 11
...Auxiliary bearing, 14...First scroll, Second
Scroll, 16.19...End plate, 17.21
...Um, 318.・Drive device, 32・
... Drive pin, 33... Guide groove.

Claims (4)

[Claims] 1. An electric element and a scroll compression element are housed in an airtight container, and the scroll compression element is connected to a frame having a bearing in the center and a first scroll having a spiral wrap erected on an end plate and driven by the electric element. And this first
a second scroll having a spiral wrap erected on end plates that face and engage with each other with a center eccentric to the center of the scroll; and a drive device that rotates the second scroll in the same direction as the first scroll. In the scroll compressor, the drive device includes a drive pin provided on the outer periphery of either one of the end plates of the first or second scroll, and a guide groove provided in the radial direction in which the pin is fitted. A scroll compressor characterized in that the circular orbit at the outer peripheral end of the guide groove is outside the circular orbit at the center of the drive pin. 2. The scroll compressor according to claim 1, characterized in that a plurality of drive devices are provided. 3. The scroll compressor according to claim 1, wherein the wrap of one scroll is an involute spiral, and the wrap of the other scroll is an involute angle correction tooth spiral. 4. The scroll compressor according to claim 1, wherein the wrap of the scroll is a semi-circular spiral.