JP2001132669A - Cooling structure for scroll fluid machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cooling structure for a scroll fluid machine capable of excellently cooling turning scroll side heating. SOLUTION: This cooling structure has a cooling fin on an opposite side surface of a lap of a fixed scroll 4 and a turning scroll 5 and a driving member 6 being connected to a rotary shaft of a motor and driving the turning scroll by being integrally joined to the cooling fin side of the turning scroll, boss parts for an auxiliary crank are arranged in circumferential directional three places in the driving member 6, an installing hole with the turning scroll is arranged in one corner of the boss parts for the auxiliary crank, the cooling fin of the turning scroll is allowed to abut to a central part of a rotary shaft boss part corresponding part, the other part is put in a noncontact state, and the driving member 6 and the turning scroll 5 are integrally formed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention provides cooling fins on the surface of the fixed scroll and the orbiting scroll opposite to the wrap, and is connected to the rotating shaft of the motor to be integrated with the cooling fins of the orbiting scroll. And a driving member for driving the orbiting scroll in combination with the driving member, and a cooling structure in a scroll fluid machine for forcibly cooling by flowing a cooling gas in one direction.

[0002]

2. Description of the Related Art There are known various scroll fluid machines for forced cooling by flowing a cooling gas in one direction. JP-A-9-
Japanese Patent Publication No. 144673 (prior publication) is one of them. According to the prior art [FIG. 1], this technique includes a orbiting scroll 10 and a cover member 12 fixed to the orbiting scroll 10 with screws, the cover member having a large diameter having radial cooling fins on its outer periphery. And a boss portion 12B for a small diameter auxiliary crank having radial cooling fins on the outer periphery of the boss portion 12A, and the orbiting scroll and the cover member are integrally connected to each other with the boss portion 12A of the cover member. The orbiting scroll is configured to be driven by the drive shaft 2 connected to the motor, and the back surface of the boss portion is formed as a space 17,
It is separated from the radiation fin on the orbiting scroll side.

[0003]

According to the prior art described above, since the back surface of the boss is formed as the space 17, cooling air can be introduced into the space 17 and the boss 17 can be cooled. The transmission of compression heat from the orbiting scroll to the orbiting bearing provided on the boss 17A can be prevented, and the orbiting bearing can be kept at a low temperature.

However, after the compression ratio and the compression capacity of the scroll fluid machine are determined, when designing the cover member, the thickness of the cover member and the boss for driving the orbiting scroll so as to withstand the compression ratio and the compression capacity. If the shapes of the boss portion and the boss portion for the auxiliary crank are determined, and the cooling fins are provided on the outer periphery of these boss portions, the outer diameter of the cover member and thus the outer diameter of the orbiting scroll will be increased.

Further, the cover member transmits the rotational driving force to the orbiting scroll side, and the auxiliary crank portion restricts the rotation of the orbiting scroll, so that stress is generated. It is necessary to form the boss part firmly and to connect the cover member to the orbiting scroll and to integrate it firmly.

In addition, it is necessary to fix the required cooling space to the surface of the orbiting scroll on which the cooling fins are provided, with screws secured thereto. Means for screwing by contacting the support may be considered, but it is desirable that the support has a considerably large contact area. If a pillar having a large contact area is provided, extra weight increases.

Further, even if the orbiting scroll and the cover member are partially in contact with each other and other portions are floating, the number of floating portions should be reduced as much as possible. Are desirably distributed on average to reduce stress deflection.

Further, by cooling not only on the orbiting scroll side but also on the fixed scroll side, it is possible to perform better cooling. Therefore, it is desired that the cooling space on the fixed scroll side can be adjusted.

In view of the above circumstances, an object of the present invention is to provide a cooling structure in a scroll fluid machine that can satisfactorily cool heat generated on the orbiting scroll side. Another object of the present invention is to provide a cooling structure in a crawl fluid machine in which a orbiting scroll and a driving member for driving the orbiting scroll are firmly integrated. Another object of the present invention is to arrange a lid member capable of removing the cooling fin side of the fixed scroll, and easily adjust the cooling space volume by interposing a spacer between the lid member and the fixed scroll. An object of the present invention is to provide a cooling structure in a crawl fluid machine that can be configured.

[0010]

According to the present invention, a cooling fin is provided on the surface of the fixed scroll and the orbiting scroll opposite to the wrap, and is connected to the rotating shaft of the motor to be integrated with the cooling fin side of the orbiting scroll. And a driving member for driving the orbiting scroll in a combined manner, wherein a cooling gas flows in one direction to forcibly cool the scroll fluid machine, wherein the driving member has three auxiliary crank bosses in the circumferential direction. And a mounting hole for the orbiting scroll is provided at one corner of each of the auxiliary crank boss portions, and cooling gas flows through cooling fins having the same height as the back surface of the auxiliary crank boss portion. Along with providing the drive member back along the direction,
The height of the portion of the cooling fin provided on the back surface of the driving member corresponding to the boss portion for the rotating shaft corresponding to the boss portion for the rotating shaft connected to the rotating shaft of the motor, excluding the central portion of the portion corresponding to the boss portion for the rotating shaft, At least the back surface of the auxiliary crank boss portion and the central portion of the portion corresponding to the rotary shaft boss portion abut the cooling fin top on the orbiting scroll side to be integrated with the orbiting scroll. I do.

According to the present invention, the driving member attached to the orbiting scroll is provided with auxiliary crank bosses at three places in the circumferential direction, and mounting holes for the orbiting scroll are provided at one corner of each of the auxiliary crank bosses. Since at least the back surface of the auxiliary crank boss portion and the central portion of the portion corresponding to the rotary shaft boss portion abut on the cooling fin top on the orbiting scroll side, it can be integrated with the orbiting scroll. Are the three auxiliary crank boss portions and the central portion, and the fixed portion is the auxiliary crank boss portion that is substantially equidistant from the central portion, so that the two can be firmly integrated.

[0012] The present invention also provides a cooling fin having a top portion at the same height as the back surface of the auxiliary crank boss portion on the back surface of the driving member along the flowing direction of the cooling gas. The cooling fins provided are configured such that the height of the portion corresponding to the rotating shaft boss portion corresponding to the rotating shaft boss portion connected to the rotating shaft of the motor is low except for the center portion of the corresponding portion of the rotating shaft boss portion. Therefore, when the rear surface of the auxiliary crank boss portion and the central portion of the portion corresponding to the rotary shaft boss portion abut on the cooling fin top on the orbiting scroll side and are integrated with the orbiting scroll, the rotating shaft The lower cooling fin portion corresponding to the boss portion forms a cooling space.

It is also an effective means of the present invention that when the two are integrated, the back surface of the auxiliary crank boss portion comes into contact with a plurality of cooling fins for orbiting scroll.
In this case, the orbiting scroll can abut and hold the back surface of the auxiliary crank boss at a wide portion.

The orbiting scroll is provided with a plurality of cooling fins which are in contact with the cooling fins implanted at the same height as the rear surface, and the driving member is provided on the cooling fin which is in contact with the rear surface of the auxiliary crank boss. Is also an effective means of the present invention, and it is not necessary to separately provide a support and attach it to the support, and the weight of the entire orbiting scroll can be reduced.

If the top area of the cooling fin provided on the back surface of the driving member at the portion corresponding to the rotary shaft boss is N, the area of the central portion having a height in contact with the cooling fin of the orbiting scroll is N /. It is also an effective means of the present invention to set the rotation member to 6 or less, and since the orbiting scroll abuts and holds the center portion of the portion corresponding to the rotary shaft boss portion, the mounting of the drive member to the orbiting scroll becomes reliable, and the orbiting scroll The contact with the cooling fins from the side is less than 1/6 the area of the cooling space, the transmission path of the compression heat is small, and
The effect of the heat of compression on the drive member side is small in a short time, and the volume of cooling the heat of compression is larger, so that the cooling effect is sufficient, and the heat of compression transmitted from the center is the outer side of the drive member. The cooling is performed by the cooling fins provided at the bottom.

The drive member includes a rotary shaft boss portion having a concave portion which is open at one end on one surface of a substantially circular plate-shaped body and is surrounded by a circular wall surface; Outside the circular wall surface of the boss portion, the auxiliary crank boss portion having a concave portion which is open on the same side as the rotary shaft boss portion and is surrounded by the circular wall surface, and a mounting hole for the orbiting scroll. It is also an effective means of the present invention that the two bosses are provided close to each other with the circular wall surfaces of the two bosses separated from each other.

According to such a technical means, since the rotary shaft boss portion and the auxiliary crank boss portion are arranged close to each other, the scroll fluid machine can be made compact. In addition, since both bosses are arranged close to each other with the circular wall surfaces of both bosses separated from each other, the thickness between the circular wall surfaces of both bosses becomes integral and the wall thickness increases. By increasing the thickness of the portion, no countermeasures are taken against distortion, the weight does not increase, and a small scroll fluid machine can be configured.

It is also an effective means of the present invention that a plurality of mounting holes for the orbiting scroll are provided at symmetric positions with respect to a line connecting the center of the rotary shaft boss portion and the center of the driving member. According to this technical means, since at least two auxiliary bosses are mounted at symmetrical positions, the reliability of mounting is increased, the weight balance is good, and the operation is stable.

The fixed scroll has a fixed scroll cooling fin provided on a surface opposite to the fixed scroll wrap, and a cover member for covering the fixed scroll cooling fin except for a fluid suction hole and a compressed fluid discharge hole is provided. It is also an effective means of the present invention to removably arrange the fixed scroll, and by removing the lid member and attaching the lid member to the fixed scroll via a spacer, the cooling space on the fixed scroll side is increased, and the cooling efficiency is improved. It can be further improved.

[0020]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. However, the dimensions, materials, shapes, relative arrangements, and the like of the components described in this embodiment are not intended to limit the scope of the invention thereto, but are merely illustrative examples unless otherwise specified. Not just.

FIG. 1 is a cross-sectional view of a scroll fluid machine according to an embodiment of the present invention, FIG. 2 is a cross-sectional view of an orbiting scroll and a driving member, and FIG. is there.
In FIG. 1, a scroll fluid machine includes a fixed scroll 4 having a large number of cooling fins 4b on a back surface, a main body housing 10 in which an orbiting scroll is disposed, a support portion 12 for holding a rotation drive shaft 9 of a motor, and a motor housing 1.
And 3.

The rotary drive shaft 9 of the motor has a support 1 on the left side.
2 and the left side is a rotating shaft boss 6 described later.
1 and a joint 7 having an end 7a connected via a bearing.

On the other hand, inside the fixed scroll 4 end plate,
A sliding surface 4g, which is recessed and formed in a substantially circular cross-sectional rectangular shape, is provided. A discharge port 4d for discharging a compressed fluid is opened at the center of the sliding surface 4g, and is larger than the discharge port 4d. A discharge opening 4e having a diameter is opened toward the outside, and a discharge cylinder 23 is disposed in the discharge opening 4e.

A wrap 4a is spirally implanted on the sliding surface 4g from the vicinity of the discharge port 4d toward the outer periphery, and a concave groove is formed on the upper end ridge of the wrap from the center toward the outer periphery. A self-lubricating chip seal 22 made of a fluororesin or the like, which is in contact with the mating sliding surface and seals, is fitted in the groove.

The fixed scroll 4 is provided with a fluid suction port 4c communicating with the sliding surface 4g with an opening at the front. A plurality of cooling fins 4b are implanted on the front surface (fixed scroll back surface) where the suction port 4c is opened, and are perpendicular to the paper surface of FIG. 1, and from the outer peripheral surface of the cylindrical portion 4h where the discharge opening 4e is provided. Similarly, cooling fins are arranged in the direction perpendicular to the paper of FIG.

On the back side of the fixed scroll 4, a side cover (lid member) 20 having a discharge opening 20a at a position corresponding to the discharge opening 4e is formed, and a part of the cooling fin is formed to have a large diameter. It is detachably attached by the attaching portion 4k. By attaching the side cover 20 to the tip of the attachment portion 4k with a cylindrical spacer appropriately interposed therebetween, the cooling space on the fixed scroll side can be adjusted and the cooling efficiency can be improved.

On the inner surface 4m of the fixed scroll 4, a concave groove is formed so as to surround the outer peripheral portion of the wrap 4a. A self-lubricating dust seal 21 made of a fluorine resin or the like is fitted so that dust does not enter the side.

A revolving scroll 5 is disposed in the main body housing 10 and a fixed scroll 4 is provided on its sliding surface 5g.
A wrap 5a is formed to form a sealed space that comes into contact with the wrap 4a. A large number of cooling fins 5 are provided on the back side of the orbiting scroll 5 in the vertical direction on the paper of FIG.
b, 5c, 5d, 5e are provided.

As shown by the dashed line in FIG. 3, the cooling fins 5b, 5c, 5d and 5e are formed in a wave shape along the direction in which the cooling air flows as indicated by the arrow 24. 5d and 5e are provided with a receiving portion 51 having a diameter larger than the cooling fin width.
1 is provided with a screw hole (not shown).

A turning assist plate (drive member) 6 attached to the receiving portion 51 of the orbiting scroll 5 is screwed (not shown). The turning assist plate 6 is provided with a concave portion 6a, and the concave portion 6a is provided with an eccentric shaft portion 7 of the joint 7.
and a via a bearing. One end is supported by the main body housing 10 on the outer peripheral portion of the turning assist plate, and the other ends of three pairs of anti-rotation mechanisms (auxiliary crank portions) 14 are supported at three places in the circumferential direction by 120 °. The orbiting scroll 5 is arranged so as to revolve around the fixed scroll 4 with an eccentric rotation center via the rotation preventing mechanism 14.

Further, as shown in FIG.
In a state in which the rotary shaft boss portion 61 and the auxiliary crank boss portion 60 are provided outside the circular wall surface of the rotary shaft boss portion with the circular wall surfaces of both boss portions being separated from each other, Since the outer periphery 60Aa of the portion 60 and the outer periphery 6d of the rotary shaft boss 61 are arranged close to each other with the wall surfaces being separated, the scroll fluid machine can be made compact. In addition, since both bosses are arranged close to each other with the circular wall surfaces of both bosses separated from each other, the thickness between the circular wall surfaces of both bosses becomes integral and the wall thickness increases. By increasing the thickness of the portion, no countermeasures are taken against distortion, the weight does not increase, and a small scroll fluid machine can be configured.

FIG. 3 is a view taken in the direction of arrows AA in FIG. 2. Of the three auxiliary crank boss portions 60, four orbiting scroll cooling fins 5b and a receiving portion 51 are provided on the back surface of the boss portion 60A. The corresponding cooling fins 5c abut correspondingly, and three cooling fins 5b and 2
The cooling fins 5d and 5e of the book are configured to abut against each other. The bosses 60A, 60B, 60C
The cooling fins of the orbiting scroll abutting on the back surface may extend from top to bottom in FIG.

A one-dot chain line 6d indicating the outer peripheral wall of the boss 61 for the rotating shaft corresponding to the back surface of the boss 61 for the rotating shaft.
The part surrounded by is the two 6bh, 6 located at the center.
Except for bh, as shown by 6c in FIG. 2, the cooling space is formed without contacting the cooling fins of the orbiting scroll from the compression heat generating portion (shaded portion) of the wrap space of the orbiting scroll.

In the present embodiment, as described above, the driving member 6 attached to the orbiting scroll is provided with the auxiliary crank bosses 60 at three places in the circumferential direction, and the corners of the auxiliary crank bosses are provided at one corner of each of the auxiliary crank bosses. Since the mounting hole 60a for the orbiting scroll is provided, the cooling fin of the orbiting scroll contacts the back surface of the boss portion 60 for the auxiliary crank, and the cooling fin 6 at the center of the portion corresponding to the boss portion for the rotating shaft.
0bh and 60bh are in contact with the top of the cooling fin on the orbiting scroll side, and a screw is inserted into the mounting hole 60a and attached to the mounting portion of the cooling fin top of the orbiting scroll, whereby the orbiting scroll and the driving member 6 are integrated You can do it.

At this time, the contact portion is the three auxiliary crank boss portions and the central portion, and the fixed portion is the auxiliary crank boss portion substantially equidistant from the central portion. Since the back surface of the portion is in contact with the plurality of cooling fins for the orbiting scroll, the orbiting scroll can hold the back surface of the auxiliary crank boss portion in a wide portion, thereby firmly integrating the two. be able to.

As shown in FIG. 3, two mounting holes 60a for the driving member 6 to the orbiting scroll are provided at two symmetrical positions with respect to a line connecting the center of the rotary shaft boss portion and the center of the driving member. Since it is provided, the reliability of attachment is increased, the weight balance is good, and the operation is stable.

As described above, in this embodiment, since the mounting portion for the driving member is provided on the cooling fin which is in contact with the back surface of the boss portion for the auxiliary crank, it is not necessary to separately provide a support and attach it to the support. Therefore, the weight of the orbiting scroll as a whole is reduced.

Further, the fixed scroll has a fixed scroll cooling fin provided on a surface opposite to the fixed scroll wrap, and a cover member for covering the fixed scroll cooling fin except for a fluid suction hole and a compressed fluid discharge hole is provided. Since the cover is detachably disposed on the fixed scroll, by removing the cover member and attaching the cover member to the fixed scroll via a spacer, the cooling space on the fixed scroll side is increased, and the cooling efficiency can be further improved.

[0039]

As described above, according to the present invention, the drive member and the orbiting scroll can be firmly integrated, and the contact area of the cooling fin from the orbiting scroll side on the back surface of the rotary shaft boss portion. Since the number of cooling fins is reduced and the volume of the cooling space in which the cooling fins are provided is increased, it is possible to provide a cooling structure with improved cooling efficiency and improved compression efficiency.

[Brief description of the drawings]

FIG. 1 is a sectional view of a scroll fluid machine according to an embodiment of the present invention.

FIG. 2 is a sectional view of an orbiting scroll and a driving member.

FIG. 3 is a view as viewed in the direction of arrows AA in FIG. 2;

[Explanation of symbols]

 4 Fixed scroll 5 Orbiting scroll 6 Drive member (rotation auxiliary plate)

Claims (5)

[Claims] A cooling fin is provided on a surface of the fixed scroll and the orbiting scroll opposite to the wrap, and is connected to a rotating shaft of a motor to be integrally connected to a cooling fin side of the orbiting scroll. And a driving member for driving the cooling gas. The cooling structure in the scroll fluid machine for forcibly cooling the cooling gas by flowing the cooling gas in one direction. The driving member is provided with auxiliary crank bosses at three circumferential positions. A mounting hole for the orbiting scroll is provided at one corner of the auxiliary crank boss portion, and a cooling fin having a top portion at the same height as the rear surface of the auxiliary crank boss portion is moved along the direction in which the cooling gas flows. And the rotation of the cooling fins provided on the back surface of the driving member corresponding to the rotation shaft boss portion connected to the rotation shaft of the motor. The height of the portion corresponding to the boss portion is set low except for the center portion of the portion corresponding to the rotating shaft boss portion, and at least the back surface of the boss portion for the auxiliary crank and the center portion of the portion corresponding to the rotating shaft boss portion are the same. A cooling structure for a scroll fluid machine, wherein the cooling structure is integrated with the orbiting scroll by contacting the top of the cooling fin on the orbiting scroll side. 2. A plurality of cooling fins abutting on the back surface of the auxiliary crank boss portion when attached integrally with the orbiting scroll, and a plurality of cooling fins abutting on cooling fins planted at the same height as the back surface. The cooling fins are provided on the orbiting scroll, and the cooling fins abutting against the back surface of the auxiliary crank boss portion are provided with mounting portions for the drive member, and the cooling fins are provided on the back surface of the drive member corresponding to the rotary shaft boss portion. 2. The cooling structure for a scroll fluid machine according to claim 1, wherein the area of the center of the orbiting scroll having a height contacting the cooling fin is set to N / 6 or less, where N is the top area of the fin. . 3. The rotating shaft boss portion, wherein the driving member has a concave portion surrounded by a circular wall surface with one opening at a central portion of one surface of a substantially circular plate-shaped body; Outside the circular wall surface of the boss portion, the auxiliary crank boss portion having a concave portion which is open on the same side as the rotary shaft boss portion and is surrounded by the circular wall surface, and a mounting hole for the orbiting scroll. 2. The cooling structure for a scroll fluid machine according to claim 1, wherein the two bosses are arranged close to each other with the circular wall surfaces of the two bosses being separated from each other. 4. A mounting hole for the orbiting scroll,
The cooling structure for a scroll fluid machine according to claim 1, wherein a plurality of cooling structures are provided at left-right symmetric positions with respect to a line connecting the center of the rotation shaft boss portion and the center of the driving member. 5. A fixed scroll cooling fin is provided on a surface of the fixed scroll opposite to the fixed scroll wrap, and a cover member covering the fixed scroll cooling fin except for a fluid suction hole and a compressed fluid discharge hole is provided. The cooling structure for a scroll fluid machine according to claim 1, wherein the cooling structure is removably disposed on the fixed scroll.