JPH0291488A - Scroll-type fluid machine and oldham's ring thereof - Google Patents

Abstract

PURPOSE:To reduce sliding contact error between the respective spiral units and to ensure assembling efficiency by forming an Oldham's ring by a ring main body, and the first and second keys and interposing the Oldham's ring between movable and fixed scrolls. CONSTITUTION:An Oldham's ring 7 formed by projecting the first and second keys on the same plane side of a ring main body 71 is interposed between a movable scroll 3 and a fixed scroll 2. The first keys 72, 72 are directly engaged with the first key ways 33, 33 disposed on the movable scroll 3, and the second keys 73, 73 are directly engaged with the second key ways 23, 23. By this arrangement, an error due to addition of the respective parts can be lessened as compared with the conventional arrangement, so that a sliding contact error between spiral units 22, 32 of the fixed and movable scrolls 2, 3 can be reduced and the assembling efficiency can be ensured.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a scroll-type fluid machine mainly used as a compressor of a refrigeration system and an Oldham ring used in the machine.

(Prior art) Conventionally, this type of scroll-type fluid machine has been developed, for example, in Japanese Patent Application Laid-Open No.
As described in Japanese Patent No. 1-283785 and shown in FIG. 10, there is a fixed scroll (
B) and a movable scroll (C), which also has a spiral body (d) protruding from an end plate (C), are combined in a vertically opposed manner to form a frame J.
RcD), and a motor (E) is disposed on the inner lower side of the casing (A), and a drive shaft (F) coupled to the motor (E) is interlocked with the movable scroll (C). On the other hand, an Oldham ring (G) that prevents rotation of the movable scroll (C) is interposed between the movable scroll (C) and the frame (D), and the motor (E)
The movable scroll (C) is caused to revolve around the fixed scroll (B) by the rotation of the drive shaft (F) accompanying the rotation of the drive shaft (F),
The suction fluid is compressed between the spiral bodies (b) and (d) of each scroll (B) and (C).

Further, as shown in FIG. 11, the Oldham ring (G) includes a ring body (H) having a center hole (e), and a pair of opposing A first key (I, I) is provided protrudingly, and a second key (J, J) that is orthogonal to the first key (L I) is provided protrusively from the bottom side. ) (J, J) are engaged with the second and second key grooves formed in the movable scroll (C) and the frame (D), respectively, thereby preventing the movable scroll (C) from rotating. ing.

(Problem to be Solved by the Invention) By the way, the Oldham ring (G) in the above-mentioned scroll type fluid machine prevents the rotation of the movable scroll (C) and connects the movable scroll (C) to the fixed scroll (B). Since it is necessary to rotate and drive the spiral bodies (b) and (d) while making good sliding contact with each other, the perpendicularity of the first and second keys (I) and (J), etc. are adjusted between the movable and fixed scrolls. (B) It is necessary to provide high accuracy for (C).

However, in the above, the first key (1) and the second key (J) are provided on both the upper and lower end surfaces of the ring body (H) in different steps, and the first key (I) is attached to the movable scroll (C ), the second key (J) is engaged directly with the second keyway of the frame (D) that supports the fixed scroll (B), and the second key (J) is engaged with the second keyway of the frame (D) that supports the fixed scroll (B). Since the frame 11t (D) and the fixed scroll (B) are indirectly engaged with each other, the assembly error between the frame 11t (D) and the fixed scroll (B) is added, making it difficult to maintain the perpendicularity with high precision. Each spiral body (b) (d)
In some cases, sliding contact errors may appear between the spiral bodies (
A problem arises in that the parts b) and (d) interfere with each other, making assembly difficult.

Moreover, the Oldham ring CG used in the scroll type fluid machine has first and second keys (I, I) (J, J) protruding in different steps on both upper and lower end surfaces of the ring body (H), respectively. Because of the number of keys (I, I), it is difficult to manufacture and process the Oldham ring (G).
) (J.

When machining the sliding contact surface with each of the key grooves of J), it required multiple steps to cut at least the upper and lower two surfaces of the ring body (H), resulting in poor machinability. Moreover, first and second keys (1, I) (J
, J), it was necessary to take the material while ensuring the wall thickness, and the material yield was also poor.

The present invention was made in view of the above-mentioned problems, and its object is to provide a scroll-type fluid machine that can reduce sliding contact errors between the spiral bodies of fixed and movable scrolls and ensure ease of assembly. Another object of the present invention is to provide an Oldham ring that can improve workability.

(Means for Solving the Problem) In order to achieve the above object, the present invention provides a mirror plate (21).
Fixed and movable scrolls (2) and (3) having spiral bodies (22) and (32) respectively protruding from (31) are provided in an opposing manner,
A scroll type fluid machine in which rotation of the movable scroll (3) is prevented and the movable scroll (3) is driven to revolve relative to the fixed scroll (2),
The movable scroll (3) is provided with a ring body (71) having a center hole (71a) that allows the orbiting movement of the movable scroll (3).
A first key (72, 72) that engages with a first keyway (33, 33) provided in the first key (72, 72) is provided protrudingly.
a second key (73, 7) that is orthogonal to
3) is provided protrudingly on the same plane as the forming side plane of the first key (72, 72), so that the ring body (71) and the first and second keys (72, 72) (73, 73) The present invention is characterized in that an Oldham ring (7) is constructed, and the Oldham ring (7) is interposed between the movable scroll (3) and the fixed scroll (2).

The center hole (71a) of the Oldham ring (7) is formed to be larger than the outer diameter of the movable scroll (3), and the first keyway (33, 33) is formed to be larger than the outer diameter of the movable scroll (3). They are formed in the arms (34, 34) extending radially outward of the end plate (31).

Further, an Oldham ring (7) for preventing rotation of the movable scroll (3) and driving the movable scroll (3) to revolve around the fixed scroll (2) has a center hole (
The ring body (71) has a ring body (71a) with a first key (72, 72) protruding from one plane of the ring body (71), and a first key (72, 72) orthogonal to the first key (72, 72). The second key (73, 73) is configured to protrude from the same plane as the plane on which the first key (72, 72) is formed.

(Function) In the above scroll type fluid machine, the ring body (
The first and second keys (72) are located on the same plane side of the keys (71), respectively.
, 72) (73, 73) is interposed, and the first key (72, 72) is connected to the first key groove (33, 72) provided in the movable scroll (3). 33
), and since the second keys (73, 73) are directly engaged with the second key grooves (23, 23) provided in the fixed scroll (2), each part Errors due to the addition of the above are reduced, and it is possible to reduce sliding contact errors between the spiral bodies (22) and (32) of the fixed and movable scrolls (2) and (3), and to ensure ease of assembly.

Further, the center hole (71a) of the Oldham ring (7) is formed to be larger than the outer diameter of the movable scroll (3), and the first key W (33° 33) is connected to the movable scroll (3). ) is formed on the arm portions (34, 34) extending radially outward of the end plate (31), thereby reducing the load acting on the first key (72, 72).

Furthermore, in constructing the Oldham ring (7), first keys (72, 72) and second keys (73, 7) are placed on the same plane of the ring body (71) having a center hole (71a).
3), the Oldham ring (7) is formed.
), each of the keys (72, 72) (73, 73
) When cutting the sliding contact surface for each keyway (33, 33) (23, 23), it can be easily processed with a few steps using only one plane, improving workability and reducing the material When removing, each key (72, 72) (73, 73) should be placed only on one plane side within the ring body (71).
It is sufficient to ensure the wall thickness, and the amount of materials used can be reduced.

(Example) Examples will be described with reference to the drawings.

1st rI! The scroll-type fluid machine shown in J includes a fixed scroll (2) consisting of an end plate (21) with a spiral body (22) protruding from an end plate (21) on the inner upper side of a closed casing (1), and an end plate (31). A movable scroll (3) having a spiral body (32) protruding from the casing (1) is supported by a frame (4) in a vertically opposed manner, and a stator (3) is provided on the inner lower side of the casing (1). A motor (5) consisting of a rotor (51) and a rotor (52) is provided, and the upper side of a drive shaft (6) connected to the rotor (52) of the motor (5) is connected to the movable scroll (3). It is linked and linked.

However, in the scroll type fluid machine as described above,
The Oldham ring (7) which prevents the rotation of the movable scroll (3) and drives the movable scroll (3) to revolve relative to the fixed scroll (2) is configured as follows. 7) to the movable scroll (3
) and the fixed scroll (2).

That is, as shown in FIGS. 2 and 3, the Oldham ring (7) has the movable scroll (3) in the center.
) is provided with a ring body (71) having a center hole (71a) of a size that allows the revolving movement of the ring body (71).
The first keyway (
a pair of first keys (72, 72) engaged with the first keys (72, 72);
) are integrally provided upwardly protruding, and a second key 1a of the fixed scroll (2) is provided on the same side of the ring body (71) as the first key (72, 72) protrudes.
A second key (73, 73) that is engaged with the second key (23, 23) is provided to protrude upward perpendicularly to the first key (72, 72).

As described above, by forming the first keys (72, 72) and the second keys (73, 73) on the same plane of the ring body (7), when manufacturing the Oldham ring (7), When cutting the sliding surface of each of the keys (72, 72) (73, 73) with respect to each of the keys 11! (33, 33) (23, 23), it is possible to easily cut the side surfaces of the keys (72, 72) (73, 73) that come in sliding contact with the keys 11! (33, 33) (23, 23). It can be processed.

Furthermore, when taking materials, it is only necessary to ensure the protruding height of each of the keys (72, 72) (73, 73) on only one plane of the ring body (71), and less material can be used.

The center hole (71a) of the Oldham ring (7) is formed to be larger than the outer diameter of the end plate (31) of the movable scroll (3), and the center hole (71a) of the movable scroll (3) has a diameter larger than that of the end plate (31). The system is designed to allow rotational drive.

Further, as shown in FIGS. 4 and 5, arm portions (34, 34) protruding radially outward are provided at opposing outer peripheral portions of the end plate (31) of the movable scroll (3).
) are integrally provided, and the first key grooves (33, 33) each having a generally U-shape with an open tip are formed in each of the arm portions (34, 34). , 33), the Oldham ring (7) engages the first key (72, 72) with the movable scroll (33).
), the load acting on the first key (72, 72) can be reduced.

Furthermore, the fixed scroll (2) has a structure shown in FIGS. 6 and 7.
As shown in the figure, a pair of second key grooves (23, 23) are formed oppositely on the outer periphery of the lower surface side facing the frame (4).

and first and second keys (72, 72) (73, 73) formed on the same plane side of the Oldham ring (7).
, the movable scroll (3) and the fixed scroll (2)
The first key groove (33, 33) and the second key groove (2
3 and 23) respectively.

By doing so, conventionally, the second key (73,
73) was engaged with the bridge (4) side, which caused an adverse effect due to an assembly error between the bridge +R (4) and the fixed scroll (2), but the second key (73, 73) was directly engaged with the bridge (4). Since it is engaged with the second keyway (23, 23) of the fixed scroll (2), errors due to the addition of each part can be eliminated, and the sliding contact error between the spiral bodies (22) and (32) can be eliminated. This makes it possible to reduce the amount of damage and ensure ease of assembly.

Further, as shown in detail in FIGS. 8 and 8, the bridge (4) is fitted with a drive bin (61) of the drive shaft (6) and a drive bin (61) in the upper center part. A receiving hole (41) for receiving the fitting portion (35) of the movable scroll (3) is provided, and a recess (4) capable of receiving the Oldham ring (7) is provided on the outer peripheral side of the upper surface of the bridge (4).
2), and this recess (42) and the receiving hole (41)
The end plate (
31) is formed.

(Effects of the Invention) As explained above, the scroll type fluid machine according to the present invention includes a ring body (71) having a center hole (71a) that allows the orbiting movement of the movable scroll (3),
A first key (72, 72) that is engaged with a first keyway (33, 33) provided in the movable scroll (3) is provided protrudingly on the -blade side plane of the ring body (71), A second key (73, 73) that is orthogonal to the first key (72, 72) and engaged with a second key groove (23, 23) provided on the fixed scroll (2) side is attached to the second key (73, 73). 1 key (72,
These ring bodies (71) and the first and second keys (72, 72) (72) are provided protrudingly on the same plane as the formation side plane of the
3, 73) constitutes an Oldham ring (7), and since the Oldham ring (7) is interposed between each of the scrolls (3) and (2), each scroll of each of these scrolls (2) and (3) This makes it possible to reduce the sliding contact error between the bodies (22) and (32), and to ensure ease of assembly.

Further, the center hole (71a) of the Oldham ring (7) is formed to be larger than the outer diameter of the movable scroll (3), and the first keyway (33° 33) is formed to be larger than the outer diameter of the movable scroll (3). ), when forming the arms (34, 34) extending radially outward of the end plate (31), the first
The load acting on the key (72°72) can be reduced.

Furthermore, in constructing the Oldham ring (7), the first and second keys (72, 72) (73) are provided on the same plane side of the ring body (71) having the center hole (71a).
, 73), the Oldham ring (73) is formed to protrude.
), it has become possible to improve the processability of the material, and it has also become possible to economize on materials when taking materials.

[Brief explanation of the drawing]

FIG. 1 is a vertical sectional view showing the main parts of the scroll-type fluid machine according to the present invention, FIG. 2 is a plan view of the Oldham ring, and FIG.
The figure is a side view of the Oldham ring, Figure 4 is a plan view of the movable scroll, Figure 5 is a sectional view taken along line x-X in Figure 4, Figure 6 is a bottom view of the fixed scroll, and Figure 7 is the 8 is a plan view of the frame, and 9 is a sectional view taken along line Y-Y.
The line cross-sectional views, FIGS. 10 and 11, are drawings showing a conventional example. (2)... Fixed scroll (21)... End plate (22)... Fist spiral body (23)... Φ second keyway (3)... Movable scroll (31 )...φ・End plate (32)・Fist・Roll spiral body (33)・・・・1st keyway (34)・・O・Arm part (7)・・・Oldham ring (71)・− ... Ring body (71a) ... Center hole (72) ... 1st key (73) - Fist - 2nd key Fig. 2 Fig. 8 Fig. 4 X = ] Fig. 5 Fig. 8 Figure 9 Figure 6 Figure 7 Figure 1αA Figure 'i11

Claims (1)

[Claims] 1) Fixed and movable scrolls (2) and (3) in which spiral bodies (22) and (32) are respectively protruded from end plates (21 and 31).
In a scroll type fluid machine, the movable scroll (3) is provided with opposing rotations, and the movable scroll (3) is driven to revolve relative to the fixed scroll (2) by preventing rotation of the movable scroll (3). The ring body (71
), a first key (72, 72) protruding from one plane of the ring body (71) that engages with a first key groove (33, 33) provided in the movable scroll (3), A second key (73, 73) which is orthogonal to the first key (72, 72) and engages with a second keyway (23, 23) provided in the fixed scroll (2) is attached to the first key (72, 72). ,72)
The ring main body (71) and the first and second keys (72, 72) (73, 7
3) constitutes an Oldham ring (7), and the Oldham ring (7) is interposed between the movable scroll (3) and the fixed scroll (2). . 2) The center hole (71a) is larger than the outer diameter of the movable scroll (3), and the first keyway (33, 33) extends radially outward of the end plate (31) of the movable scroll (3). 2. The scroll-type fluid machine according to claim 1, wherein the scroll-type fluid machine is formed on the arm portions (34, 34) provided therein. 3) An Oldham ring for a scroll-type fluid machine that prevents the rotation of the movable scroll (3) and drives the movable scroll (3) to revolve relative to the fixed scroll (2), and has a center hole (71a). A ring body (71) is provided, and a first key (72, 7) is provided on one plane of the ring body (71).
2) protrudes, and a second key (73, 73) orthogonal to the first key (72, 72) is connected to the first key (72, 7).
2) An Oldham ring for a scroll type fluid machine, which is characterized in that it protrudes in the same plane as the forming side plane.