JPH0712065A - Variable displacement type scroll compressor - Google Patents

Abstract

PURPOSE:To make displacement of a compressor continuously variable, and realize displacement control according to a load change by forming a suction chamber, a delivery chamber and an intermediate pressure chamber of a housing and a fixed scroll, and constituting so as to carry out opening and closing control on a bypass passage to communicate the intermediate pressure chamber and the suction chamber with each other. CONSTITUTION:A suction chamber 18 is defined on one side surface side of an end plate 16a by a fixed scroll 16 and a rear housing 10a, and a delivery chamber 18b and an intermediate pressure chamber 18c are formed on the other side surface side of the end plate 16a, and a bypass hole 19b communicated with the intermediate pressure chamber 18c is formed in an intermediate part in the diameter direction of the end plate 16a. A bypass passage 19c is formed to communicate the intermediate pressure chamber 18c and a suction chamber 18a with each other, and a bottomed cylindrical rotary valve 40 rotatable around the axis Y is housed in a cylinder 19c, forming an upstream area of this bypass passage 19c. A turning angle of the rotary valve 40 is changed continuously by a stepping motor 44, and a reflux quantity of fluid to a suction chamber 18a, that is, displacement of a compressor is changed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a scroll type compressor.

[0002]

2. Description of the Related Art A conventional variable capacity scroll compressor will be described with reference to FIGS. In FIG. 6, 10 is a housing of the compressor. The housing 10 includes a rear housing 10a comprising a bottomed cylindrical body having a large diameter, and a front housing 10b fixed to the large-diameter cylindrical portion 10b ₁ and the small-diameter cylindrical portion 10b ₂ and the rear housing 10a has. The rear housing 10a and the front housing 10b are arranged concentrically. The shaft 11 arranged on the central axis X of the housing 10 passes through the small-diameter cylindrical portion 10b ₂ of the front housing, and the housing 1
It extends into 0. The shaft 11 includes a small diameter portion 11a surrounded by a small diameter cylindrical portion 10b ₂ of the front housing,
It has a large diameter portion 11b surrounded by a large diameter cylindrical portion 10b ₁ of the front housing. A crankpin 12 extending parallel to the axis X is eccentrically fixed to the end surface of the large diameter portion 11b from the axis. The shaft 11 has a large diameter portion 1.
1b is rotatably supported by a large-diameter cylindrical portion 10b ₁ of the front housing via a ball bearing 13, and the small-diameter portion 11a is rotatably supported by a small-diameter cylindrical portion 10b ₂ of the front housing via a ball bearing 14. .

Small diameter cylindrical portion 10b _{2 of the} front housing
An electromagnetic clutch 15 is provided so as to surround the. The electromagnetic clutch 15 includes a small-diameter cylindrical portion 10b of the front housing.
A pulley 15a that is rotatably fitted to the outer peripheral portion ₂ and is connected to an external drive source (not shown) through a V belt (not shown).
And the electromagnet 15 fixed to the front housing 10b.
b, and a clutch armature 15c serration-coupled to the end of the small diameter portion 11a of the shaft 11. The shaft 11 is rotationally driven by an external drive source (not shown) via the electromagnetic clutch 15.

A fixed scroll 16 is arranged in the rear housing 10a. The fixed scroll 16 includes a disc-shaped end plate 16a fitted to the rear housing 10a,
Swirl body 16b formed on one side surface of the end plate 16a
It has and. The fixed scroll 16 is fixed to the rear housing 10a by a bolt 17 penetrating the bottom portion 10a ₁ of the rear housing 10a. The fixed scroll 16 and the rear housing 10a form a suction chamber 18a on the one side surface of the end plate 16a.
a discharge chamber 18b and an intermediate pressure chamber 18c on the side of the other side surface of a.
And are formed. The discharge chamber 1 is provided at the center of the end plate 16a.
A discharge hole 19a communicating with 8b is formed, and a bypass hole 19b communicating with the intermediate pressure chamber 18c is formed in the radial middle portion of the end plate 16a. Check valves 19a ₁ and 19b ₁ are provided so as to cover the discharge hole 19a and the bypass hole 19b. A bypass passage 19c that connects the intermediate pressure chamber 18c and the suction chamber 18a is formed at the outer edge of the end plate 16a and the outer edge of the rear housing 10a. A valve 20 is slidably accommodated in a cylinder 19c ₁ forming an upstream region of the bypass passage 19c. Cylinder 1
The side wall of 9c ₁ has a communication hole 19c to the intermediate pressure chamber 18c.
₂ is formed. The spring 21 arranged in the downstream region of the bypass passage 19c contacts one end of the valve 20,
The valve 20 is urged toward the upstream end of the cylinder 19c ₁ . The upstream end of the cylinder 19c ₁ communicates with the discharge chamber 18b via the orifice 22 and communicates with the suction chamber 18a via the solenoid valve 23. Rear housing 1
A movable scroll 24 is disposed adjacent to the fixed scroll 16 in 0a. The movable scroll 24 includes a disk-shaped end plate 24a, a spiral body 24b formed on one side surface of the end plate 24a, and an annular boss 24c formed on the other side surface of the end plate 24a. . The spiral scroll 24b of the orbiting scroll 24 meshes with the spiral scroll 16b of the fixed scroll 16 with a 180 ° angular offset.

The thick disk-shaped bush 2 is attached to the boss 24c.
5 is rotatably fitted in the needle bearing 26. The bush 25 is formed with a through hole 27 extending parallel to the axis X. The through hole 27 is the shaft 1
The crank pin 12 fixed to the large-diameter portion 11b of No. 1 is slidably accommodated. Therefore, the movable scroll 24
Is rotatably supported by a crank pin 12. As a result, when the shaft 11 rotates, the movable scroll 24 supported by the crankpin 12 revolves around the axis X, that is, makes a circular orbital motion.

A ball coupling mechanism 30 for preventing rotation of the movable scroll is disposed between the front housing 10b and the movable scroll 24.

The scroll type compressor having the above structure operates as follows. The shaft 11 is rotationally driven via an electromagnetic clutch 15 by an external drive source (not shown). The rotation of the shaft 11 causes the movable scroll 24 rotatably supported by the crank pin 12 to make a circular orbital motion around the axis X. The rotation of the movable scroll 24 due to the circular orbital movement is prevented by the ball coupling mechanism 30. A space formed between the spiral scroll body 24b of the movable scroll and the spiral scroll body 16b of the fixed scroll which are engaged with each other by the circular orbital motion of the movable scroll 24,
That is, the pressurizing chamber moves toward the center of the spiral while reducing its volume. As a result, the fluid that has flowed into the suction chamber 18a from the external fluid circuit through the suction port 100 formed in the housing 10 is taken into the pressurizing chamber from the outer peripheral ends of both spirals, and is compressed and fixed in the pressurizing chamber. It flows out to the discharge chamber 18b through the discharge hole 19a formed in the scroll and the check valve 19a ₁ . The pressurized fluid flowing into the discharge chamber 18b passes through the discharge port 200 formed in the housing 10 and flows out to the external fluid circuit.

The capacity of the scroll compressor is selectively controlled between a maximum value and a minimum value in the following manner.
From the pressurizing chamber in the intermediate compression state, a part of the fluid being compressed flows into the intermediate pressure chamber 18c through the bypass hole 19b and the check valve 19b ₁ . As shown in FIG. 6, the solenoid valve 23
Is OFF, the passage that connects the upstream end of the cylinder 19c ₁ and the suction chamber 18a is closed, and the discharge pressure in the discharge chamber 18b is applied to the other end of the valve 20. The force exerted by the discharge pressure on the other end of the valve 20 overcomes the force exerted by the spring 21 and the suction pressure on the one end of the valve 20.
Is pressed against the downstream end of the cylinder 19c. As a result,
The communication hole 19c ₂ formed in the side wall of the cylinder 19c is closed by the side surface of the valve 20, and thus the bypass passage 19c is closed. Therefore, the intermediate pressure chamber 18c
The fluid being compressed therein cannot flow back to the suction chamber 18a. Therefore, the capacity of the scroll compressor is maximized.

As shown in FIG. 7, when the solenoid valve 23 is ON, the passage that connects the upstream end of the cylinder 19c ₁ and the suction chamber 18a is opened. As a result, the fluid pressure lower than the discharge pressure in the discharge chamber 18b is applied to the other end of the valve 20 via the orifice 22. The force exerted on the one end of the valve 20 by the spring 21 and the suction pressure overcomes the force exerted on the other end of the valve 20 by the fluid pressure lower than the discharge pressure, and presses the valve 20 against the upstream end of the cylinder 19c. As a result, the communication hole 19c _{2 and} thus the bypass passage 19c are opened. For this reason, the fluid in the middle of the intermediate pressure chamber 18c, which is in the process of being compressed, recirculates to the suction chamber 18a. That is, a part of the fluid being compressed is recirculated from the pressurizing chamber in the intermediate compression state to the suction chamber 18a. Therefore, the capacity of the scroll compressor is minimized.

[0010]

The variable capacity scroll compressor having the conventional structure has the following problems. The pressure applied to the valve 20 is switched to two stages of high pressure and low pressure by the solenoid valve 23, and the capacity of the compressor is only selectively controlled between the maximum value and the minimum value. The capacity cannot be controlled according to fluctuations. The spring 21 in the bypass passage 19c acts as a resistance,
The circulation of the fluid from the intermediate pressure chamber 18c to the suction chamber 18a is hindered. Therefore, the desired capacity change cannot be obtained. The present invention has been made in view of the above problems, and an object of the present invention is to provide a variable capacity scroll compressor capable of performing capacity control according to load fluctuation and reliably obtaining a desired capacity change. To do.

[0011]

In order to solve the above-mentioned problems, according to the present invention, a housing, a fixed scroll having a spiral body and disposed in the housing, and an angle with respect to the spiral body of the fixed scroll. A movable scroll disposed in the housing, the movable scroll having a spiral body forming a pressure chamber between the spiral scroll and the spiral scroll of the fixed scroll, and a drive means for revolving the movable scroll with respect to the fixed scroll. A suction chamber, a discharge chamber, and an intermediate pressure chamber are formed by the housing and the fixed scroll, and a bypass hole that connects the pressure chamber and the intermediate pressure chamber in the intermediate pressure state is formed in the fixed scroll, and is fixed to the housing. A bypass passage that connects the intermediate pressure chamber and the suction chamber is formed in the scroll, and a rotary valve that opens and closes the bypass passage is provided. Providing variable displacement scroll compressor, characterized in that it comprises a motor for rotating the over tally valve.

[0012]

In the present invention, the area of the bypass passage connecting the intermediate pressure chamber and the suction chamber is continuously changed by continuously changing the rotation angle of the rotary valve, and the suction pressure is increased from the intermediate pressure chamber. The amount of fluid returned to the chamber changes continuously. This causes the capacity of the compressor to change continuously. Therefore, according to the present invention, the capacity control according to the load fluctuation can be performed. In addition, except for the rotary valve, there is no obstacle in the bypass passage that hinders the flow of the fluid from the intermediate pressure chamber to the suction chamber, so that the desired capacity change can be obtained.

[0013]

EXAMPLES Examples of the present invention will be described with reference to FIGS. 1 to 5, the same members as those in FIGS. 6 and 7 are denoted by the same member numbers as those in FIGS.

As shown in FIG. 1, in the present embodiment,
Cylinder 19 forming the upstream region of bypass passage 19c
The c _1, slidably rotate about the axis Y of the cylinder 19c _1, bottomed cylindrical rotary valve 40 is housed. The movement of the rotary valve 40 along the axis Y is blocked by a fixing fitting 41 that snaps into a circumferential groove formed in the cylinder 19c ₁ . Fixing bracket 4
A support bearing 42 is arranged between the valve 1 and the bottom of the rotary valve 40. The sliding surface between the rotary valve 40 and the cylinder 19c ₁ is sealed by an O-ring 43. The open end of the cylinder of the rotary valve 40 is
It is directed toward the downstream region of the bypass passage 19c. A communication hole 40a is formed in the cylindrical side wall of the rotary valve 40. The rotary valve 40 is rotationally driven around the axis Y by a stepping motor 44. Except for the above, the structure of the scroll compressor according to this embodiment is the same as the structure of the conventional variable displacement scroll compressor shown in FIG.

In the variable displacement scroll compressor according to this embodiment, in the state shown in FIGS. 1 and 2, the side wall of the rotary valve 40 closes the communication hole 19c ₂ of the cylinder, and thus the bypass passage 19c. It This prevents the fluid from flowing back from the intermediate pressure chamber 18c to the suction chamber 18a. Therefore, the capacity of the compressor is maximized. In the state of FIG. 3, the communication hole 40a formed in the side wall of the rotary valve 40 and the communication hole 19c _{2 of the} cylinder partially overlap with each other. Thereby, the bypass passage 19c
Area becomes an intermediate value, and the intermediate pressure chamber 18c to the suction chamber 1
The amount of fluid recirculated to 8a also becomes an intermediate value. Therefore, the capacity of the compressor also becomes an intermediate value. In the state of FIGS. 4 and 5, the communication hole 40a formed in the side wall of the rotary valve 40 and the communication hole 19c of the cylinder are formed.
₂ and completely overlap. As a result, the bypass passage 19
The area of c becomes maximum, and the intermediate pressure chamber 18c to the suction chamber 1
The amount of reflux of the fluid to 8a is also maximum. Therefore, the capacity of the compressor is minimized.

As can be seen from the above description, in the variable displacement scroll compressor according to the present embodiment, the rotation angle of the rotary valve 40 is continuously changed by the operation of the stepping motor 44, and the intermediate pressure chamber 18c Suction chamber 18a
The area of the bypass passage 19c communicating with and continuously changes, and the recirculation amount of the fluid from the intermediate pressure chamber 18c to the suction chamber 18a continuously changes. That is, the capacity of the compressor changes continuously. Therefore, in the variable capacity scroll compressor according to the present embodiment, the capacity control can be performed according to the load fluctuation. Further, except for the rotary valve 40, the intermediate pressure chamber 18c to the suction chamber 18a are provided in the bypass passage 19c.
The desired volume change is obtained since there are no obstacles that impede the return of fluid to the. Although the embodiments of the present invention have been described above, the present invention is not limited to the above embodiments.
For example, in the above embodiment, the intermediate pressure chamber 18c, the bypass hole 19b, the bypass passage 19c, the communication hole 19c _2, rotary valve 40 has been set provided the stepping motor 44 and the like, and spiral element 24b of orbiting scroll interdigitated With the spiral scroll 16b of the fixed scroll,
Since the two pressure chambers are formed symmetrically with respect to the axis X,
Two sets of the above components may be provided. Thereby, a larger capacitance change can be obtained.

[0017]

As described above, in the present invention, the area of the bypass passage that connects the intermediate pressure chamber and the suction chamber continuously changes due to the continuous change of the rotation angle of the rotary valve. The amount of fluid recirculated from the intermediate pressure chamber to the suction chamber continuously changes. This causes the capacity of the compressor to change continuously. Therefore, according to the present invention, the capacity control according to the load fluctuation can be performed. Also, except for the rotary valve, there are no obstacles in the bypass passage that hinder the flow of fluid from the intermediate pressure chamber to the suction chamber.
The desired capacity change can be obtained.

[Brief description of drawings]

FIG. 1 is a side sectional view of a variable capacity scroll compressor according to an embodiment of the present invention at maximum capacity.

FIG. 2 is a view taken along the line II-II in FIG.

FIG. 3 is a view of the variable capacity scroll compressor of FIG. 1 when viewed from the direction of an arrow corresponding to FIG.

FIG. 4 is a partial side sectional view of the variable displacement scroll compressor shown in FIG. 1 at a minimum capacity.

5 is a view taken along the line VV of FIG.

FIG. 6 is a side sectional view of a conventional variable displacement scroll compressor at the time of maximum capacity.

FIG. 7 is a side cross-sectional view of a conventional variable displacement scroll compressor at a minimum capacity.

[Explanation of symbols]

10 Housing 10a Rear Housing 16 Fixed Scroll 18c Intermediate Pressure Chamber 19b Bypass Hole 19c Bypass Passage 19c ₁ Cylinder 19c ₂ Communication Hole 40 Rotary Valve 40a Communication Hole 44 Stepping Motor

Claims (1)

[Claims] 1. A pressurizing chamber is provided between a housing, a fixed scroll which has a spiral scroll and is disposed in the housing, and which meshes with the spiral scroll of the fixed scroll by shifting an angle to form a spiral scroll of the fixed scroll. A movable scroll having a spiral body to be formed and arranged in the housing,
A drive means for revolving the movable scroll with respect to the fixed scroll, and a suction chamber, a discharge chamber and an intermediate pressure chamber are formed by the housing and the fixed scroll, and the fixed scroll has an intermediate pressure state and an intermediate pressure chamber. A bypass hole communicating with the pressure chamber is formed, a bypass passage communicating between the intermediate pressure chamber and the suction chamber is formed between the housing and the fixed scroll, and a rotary valve for opening and closing the bypass passage and a rotary valve are rotationally driven. A variable displacement scroll compressor, comprising: a motor.