JP3161797B2 - Fluid compressor - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fluid compressor for compressing a refrigerant in a refrigeration cycle, for example.

[0002]

2. Description of the Related Art For example, a fluid compressor (hereinafter referred to as a compressor) as shown in FIG. 3 has been proposed by the present applicant (for example, Japanese Patent Application Laid-Open No. 64-36990).

That is, in this type of compressor 1,
A compression mechanism 3 is provided inside a sealed case (hereinafter referred to as a case) 2. The compression mechanism 3 includes a cylindrical cylinder 4 having both ends opened in the axial direction, and a cylinder 4. 4 and a rotor piston 5 as a rotating body eccentrically arranged inside.

A main bearing 6 and a sub bearing 7 are inserted into both ends of the cylinder 4 in the axial direction, and the cylinder 4 is hermetically closed by the main bearing 6 and the sub bearing 7. Further, a main shaft 8 and a sub shaft 9 formed at both axial ends of the rotor piston 5 are inserted into the main bearing 6 and the sub bearing 7, respectively.

On the outer periphery of the rotor piston 5, there is formed a spiral groove 10 whose pitch is gradually reduced from one axial end to the other axial end of the rotor piston 5, A spiral blade 11 is fitted in the groove 10. The blade 11 freely moves in and out of the groove 10 in the radial direction of the rotor piston 5, and its outer peripheral surface is in contact with the inner peripheral surface of the cylinder 4.

A plurality of working chambers 12 formed by a blade 11 are formed inside the cylinder 4. The volume of the working chambers 12 is from the suction side to the discharge side of the cylinder 4, that is, in this case. Changes gradually from the right side to the left side in the figure.

The driving motor 13 is provided inside the case 2.
The drive motor 13 has a stator 14 fixed to the inner peripheral surface of the case 2 and a concentrically arranged inside the stator 14 and is fitted around the cylinder 4. And a rotor 15. The drive motor 13 rotates the cylinder 4 and the rotor piston 5 relatively and synchronously. Then, the compression mechanism 3 introduces a refrigerant gas as a working fluid into the working chambers 12. The refrigerant gas is compressed while being gradually transferred from the suction side to the discharge side of the cylinder 4.

The compressor 1 of this type is generally provided with a mechanism for transmitting the rotational force of the cylinder 4 to the rotor piston 5 while restricting the rotation of the rotor piston 5. As a mechanism for transmitting torque, for example, an Oldham mechanism 16 as shown in FIG. 4 has been proposed by the present applicant (Japanese Patent Application No. 2-96305).

That is, the Oldham mechanism 16 includes a piston Oldham portion 17 formed at the base end of the main shaft 8 (or the countershaft 9) of the rotor piston 5, a C-shaped Oldham ring 18, and a C-shaped Oldham ring. An Oldham ring receiver 19 is formed.

The piston Oldham portion 17 is formed in a cubic shape, and the vertical and horizontal dimensions of the piston Oldham portion 17 are both equal and smaller than the diameter of the main shaft 8. The Oldham ring 18 has a diameter substantially equal to the diameter of the piston body 5 a, and the Oldham ring receiver 19 has a diameter substantially equal to the inner diameter of the cylinder 4.

The Oldham ring 18 and the Oldham ring receiver 19 are both fitted around the piston Oldham portion 17. An Oldham ring receiver 19 is sandwiched between the Oldham ring 18 and the piston body 5a. The Oldham ring receiver 19 is fixed to the cylinder 4, and the Oldham ring 18 engages with the ridges 20, 20 of the Oldham ring receiver 19. The Oldham ring 18 slides in one direction along the ridges 20, 20 and allows the rotor piston 5 to be displaced in one direction. The direction of displacement of the Oldham ring 18 with respect to the Oldham ring receiver 19 is orthogonal to the direction of displacement of the piston 5 with respect to the Oldham ring 18.

In the fluid compressor having the Oldham mechanism 16 of the type in which the shape of the Oldham ring 18 and the Oldham ring receiver 19 is set in a C-shape, both members 18 and 19 are connected to the rotor piston 5. The outer diameter of the main shaft 8 can be set irrespective of the size of the rectangular holes 21 and 22 of the two members 18 and 19 since the outer diameter can be fitted to the piston Oldham portion 17 from the radial direction. Therefore, in order to balance the thrust force acting on the rotor piston 5, there is an advantage that the cross-sectional area of the main shaft 10 can be increased.

[0013]

By the way, in the fluid compressor provided with the Oldham mechanism 16 as described above,
Since the Oldham ring 18 and the Oldham ring receiver 19 were formed in a C-shape, and the two members 18 and 19 were partially cut in the circumferential direction, the rigidity of both members 18 and 19 was weak. SUMMARY OF THE INVENTION It is an object of the present invention to provide a fluid compressor in which the Oldham ring and the Oldham ring receiver have high rigidity and are easy to assemble.

[0014]

In order to achieve the above object, according to the present invention, a rotating body having a spiral groove on an outer peripheral portion is eccentrically arranged in a cylinder, and a spiral blade is provided in the groove. A plurality of working chambers with a gradually changing volume along the axial direction of the cylinder are formed inside the cylinder, and an Oldham mechanism is provided inside the cylinder. In a fluid compressor that compresses while transferring a working fluid by relatively rotating through a shaft, a shaft is formed at an axial end portion of a rotating body, and an Oldham mechanism is disposed between a body and a shaft of the rotating body. A rotating Oldham portion having a pair of parallel sliding contact surfaces provided on the shaft, an annular Oldham ring inserted into the shaft portion and engaging with the rotating body Oldham portion to regulate displacement of the rotating body; As well as Oldham A ring-shaped Oldham ring receiver that engages with the ring and allows the Oldham ring to be displaced in a predetermined direction, and a relief portion smaller in diameter than the shaft portion is provided between the shaft portion and the rotating body Oldham portion. That is. By doing so, the present invention increases the rigidity of the Oldham ring and the Oldham ring receiver, and also makes it possible to easily assemble the fluid compressor.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A main part of an embodiment of the present invention will be described below with reference to FIGS. Note that the same reference numerals are given to the same components as those described in the section of the related art, and the description thereof will be omitted.

FIG. 1 shows an essential part of an embodiment of the present invention, in which reference numeral 31 denotes a rotor piston as a rotating body,
Reference numeral 32 indicates an Oldham mechanism. A cylindrical sub shaft 33 is formed concentrically at one axial end of the rotor piston 31, and the sub shaft 33 is formed to have a smaller diameter than the piston body 31a.

The rotor piston 31 is provided with a piston Oldham portion 34 and a relief portion 35. Of these, the piston Oldham portion 34 is a piston body 31a.
The sliding contact surfaces 36, 3
6 and extends over the entire radial length of the piston body 31a.

The relief portion 35 is formed in a cylindrical shape, and is located concentrically between the piston Oldham portion 34 and the counter shaft 33. Further, the relief portion 35 is formed to have a smaller diameter than the countershaft 33.

The Oldham mechanism 32 is provided with an Oldham ring 37 and an Oldham ring receiver 38 which are both annular. The outside diameter of the Oldham ring 37 is the piston body 3
The outer diameter of the Oldham ring receiver 38 is set substantially equal to the inner diameter of the cylinder 4. Furthermore, the inside diameter of the Oldham ring 37 and Oldham ring receiving 38 are both set to a value approximately equal D _0.

On both sides of the Oldham ring 37, first and second engagement grooves 39 and 40 are provided.
9 and 40 extend in directions orthogonal to each other. The width of the first engagement grooves 39, 39 is set in accordance with the width of the piston Oldham portion. The countershaft 33 of the rotor piston 31 is inserted into the Oldham ring 37,
Reaches the piston Oldham part 34. The Oldham ring 37 receives the piston Oldham portion 34 in the first engagement grooves 39, 39 and engages with the rotor piston 31.

The Oldham ring receiver 38 has, on one side thereof, ridges 41, 41 extending in one direction. The countershaft 33 of the rotor piston 31 is inserted into the Oldham ring receiver 38, and the Oldham ring receiver 38 reaches the escape portion 35.
Further, the Oldham ring receiver 38 inserts the ridges 41, 41 into the second engagement grooves 40, 40 of the Oldham ring 37,
It engages with the Oldham ring 37. The Oldham ring receiver 38 is fixed to the cylinder 4.

The rotor piston 31 has the piston Oldham portion 34 in the first engagement groove of the Oldham ring 37, 39, 39.
Is displaced in one direction while sliding along. Also,
The Oldham ring 37 is a ridge 4 of the Oldham ring receiver 38.
It slides in one direction along 1,41. And b
The direction of displacement of the tap piston 31 with respect to the Oldham ring 37 and the direction of displacement of the Oldham ring 37 with respect to the Oldham ring receiver 38 are orthogonal to each other. As a result, the rotor piston 31 rotates integrally with the cylinder 4 while the positional relationship with the cylinder 4 is restricted.

The inner diameter D ₀ of the Oldham ring 37 and the Oldham ring receiver 38 is set to be substantially equal to and slightly larger than the outer diameter D ₁ of the sub shaft 33 of the rotor piston 31. The difference between the two diameters D ₀ and D ₁ is as small as possible.
In addition, it is set such that the sub shaft 33 easily passes through the Oldham ring receiver 37 and the Oldham ring 38 during assembly.

Further, the Oldham ring 37, the Oldham ring receiver 38, and the rotor piston 31 are relatively displaced as the fluid compressor is driven. The relative displacement of each member is the eccentricity e of the cylinder 4 and the rotor piston 31.
Is determined according to The Oldham ring 37, the Oldham ring receiver 38, and the rotor piston 31 are respectively formed on the inner peripheral surfaces 37 a, 3 </ b> A of the Oldham ring 37 and the Oldham ring receiver 38.
8a and the outer peripheral surface 35a of the escape portion 35 are relatively displaced by using a clearance. Therefore, it is a necessary condition that the diameter D ₂ of the escape portion 35 satisfies the relationship of D ₁ > (D ₂ + 2e). In other words, the diameter D ₀ of the Oldham ring 37 and Oldham ring receiving 38, the diameter D ₁ of the countershaft 33, and the relationship between the diameter D ₂ of the relief portion 35 is as follows. D ₀ D ₁ > (D ₂ + 2e) (1) or D ₀ > D ₁ > (D ₂ + 2e) (2)

That is, the Oldham mechanism 3 as described above
In the fluid compressor provided with
Since the and the Oldham ring receiver 38 are both formed in an annular shape, the rigidity of both members 37 and 38 is high.

Further, since the inner diameter D ₀ of the Oldham ring 37 and Oldham ring receiving 38 is substantially same configuration and the outer diameter D ₁ of the auxiliary shaft 33, the length of the ridges 41, 41 (of the Oldham ring receiving 38 (Length in the radial direction) can be increased. And the sliding area in the Oldham mechanism part 32 becomes large, and the surface pressure in the sliding part becomes small.

Further, since the shapes of the Oldham ring 37 and the Oldham ring receiver 38 can be set to be annular irrespective of the diameter of the counter shaft 33, the manufacturability of the Oldham ring 37 and the Oldham ring receiver 38 is improved, and furthermore, The assembly of the fluid compressor becomes easy.

In this embodiment, the Oldham mechanism 32 is disposed on the side of the sub shaft 33. However, for example, the invention is also applicable to a fluid compressor of the type in which the Oldham mechanism 32 is disposed on the side of the main shaft 8. It is possible.

The present invention also relates to a fluid compression type in which the ridges 41, 41 are provided on the Oldham ring 37 and the engagement grooves 40, 40 for receiving the ridges 41, 41 are provided on the Oldham ring receiver 38. It is also applicable to machines. Further, the present invention is also applicable to a type-type fluid compressor having, for example, two sets of spiral grooves 10 and blades 11.

[0030]

As described above, according to the present invention, a rotating body having a spiral groove on the outer periphery is eccentrically arranged in a cylinder,
A spiral blade is fitted into the groove so that it can enter and exit freely, a plurality of working chambers are formed in the cylinder whose volume is gradually changed along the axial direction of the cylinder, and an Oldham mechanism is provided in the cylinder. And a rotating body are relatively rotated via an Oldham mechanism, and the fluid is compressed while transferring the working fluid.In the fluid compressor, a shaft is formed at an axial end of the rotating body, and the Oldham mechanism rotates. A rotating body Oldham portion having a pair of sliding surfaces provided between a body of the body and a shaft portion, and a circle inserted into the shaft portion and engaging with the rotating body Oldham portion to regulate displacement of the rotating body. An Oldham ring, and an annular Oldham ring receiver which is inserted into the shaft portion and engages with the Oldham ring to allow the Oldham ring to be displaced in a predetermined direction. With substantially the same set with the shaft portion, in which the small diameter of the relief portion than the shaft portion between the rotating member Oldham portion and the shaft portion is provided. Therefore, the present invention
The rigidity of the Oldham ring and the Oldham ring receiver is increased, and the fluid compressor can be easily assembled.

[Brief description of the drawings]

FIG. 1 is an exploded perspective view showing a main part of an embodiment of the present invention.

FIG. 2 is an explanatory diagram showing a dimensional relationship of an Oldham ring, a countershaft, and a relief portion.

FIG. 3 is a sectional view showing a general fluid compressor.

FIG. 4 is an exploded perspective view showing an Oldham mechanism provided with a C-shaped Oldham ring and an Oldham ring receiver.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Fluid compressor, 4 ... Cylinder, 10 ... Groove, 11 ... Blade, 12 ... Working chamber, 16 ... Oldham mechanism part, 31 ... Rotor piston (rotary body), 32 ... Oldham mechanism part, 33
... Sub shaft (shaft), 34. Piston Oldham (rotor Oldham), 35. Relief, 36, 36.
... Oldham ring, 38 ... Oldham ring.

Claims (1)

(57) [Claims] 1. A rotating body having a spiral groove on an outer peripheral portion is eccentrically arranged in a cylinder, and a spiral blade is inserted into the groove so as to be able to freely enter and exit, and is inserted into the cylinder along an axial direction of the cylinder. Forming a plurality of working chambers having gradually changed volumes, having an Oldham mechanism in the cylinder, and relatively rotating the cylinder and the rotating body via the Oldham mechanism to provide a working fluid. In the fluid compressor that compresses while transferring, a shaft portion is formed at an axial end of the rotating body, and the Oldham mechanism is provided between the body of the rotating body and the shaft, and a pair of parallel members is provided. A rotating Oldham part having a smooth sliding contact surface, an annular Oldham ring inserted into the shaft portion and engaging with the rotating body Oldham portion to regulate displacement of the rotating body; As well as the above A ring-shaped Oldham ring receiver which engages with the dam ring to allow the Oldham ring to be displaced in a predetermined direction, and has a smaller diameter than the shaft portion between the shaft portion and the rotating body Oldham portion. A fluid compressor comprising a relief portion.