JPH03145588A - Cooling device for full system rotational type scroll compressor - Google Patents

Abstract

PURPOSE:To cool both scrolls and each bearing respectively in a satisfactory way by arranging each cooling fan rotating simultaneously with both scrolls in each space chamber formed at the side opposite to respective laps of driving and driven scrolls. CONSTITUTION:A first space chamber 22 and a second space chamber 23 which are surrounded by first and second casings 3, 4 respectively are formed on the side opposite to respective laps 8, 15 of driving and driven scrolls 5, 12. First and second cooling fans 1, 2 are housed in the first and the second space chambers 22, 23 and also are fixed to respective rotary shaft 6, 13 of the driving and the driven scrolls 5, 12. As the driving and the driven scrolls 5, 12 are rotated by the driving of a motor 11, an air flow like a swirl flow is produced by the rotation of the first and the second cooling fans 1, 2. The driving and the driven scrolls 5, 12 and respective bearings 9, 10, 16, 17 are cooled in a satisfactory way, thereby.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a cooling device for a full-system rotary scroll compressor having a driving scroll and a driven scroll that rotate with each other to form a compression chamber.

[Prior Art] A conventional technique is to provide a cooling fan in the casing in order to cool the driving scroll and the driven scroll disposed in the casing, as well as the bearings and the like for pivotally supporting them to the casing. 6.
For example, in the device disclosed in Japanese Utility Model Application Publication No. 58-146895, a multi-blade fan is provided on the rotating shaft of an orbiting scroll rotated by a motor, and the fan is rotated in a fan chamber inside a casing to create an air flow inside the casing. This is then exhausted to the outside. This technology is also characterized by a structure in which a wrap and a heat dissipation fan are provided on both sides of the end plate of the fixed scroll, and the technology disclosed in Japanese Utility Model Publication No. 1-58790 has a structure in which a wrap and a heat dissipation fan are provided on both sides of the end plate of the fixed scroll. A heat dissipation fan is installed on the opposite side of the wrap, and the fixed scroll and orbiting scroll are cooled by cold air forcibly introduced by a fan, etc. Anything above 0 is a cooling method used in a general scroll compressor. However, in a full-system rotary scroll compressor, there is no disclosure of a system in which a cooling mechanism such as a cooling fan is disposed inside the casing to cool the driving scroll and the driven scroll, especially the driving scroll inside the casing. Also, there is no cooling device that actively cools the bearing that supports the rotating shaft of the driven scroll.

[Problem to be Solved by the Invention J] The present invention actively cools the driving scroll and the driven scroll housed in the casing, improves the efficiency of the compressor, and at the same time An object of the present invention is to provide a cooling device for a full-system rotary scroll compressor that cools a bearing fitted in a casing and improves its life.

[Means for Solving the Problems] In order to achieve the above objects, the present invention includes a drive scroll that is pivotally supported in a casing and rotated to open, and a wrap that meshes with the wrap of the drive scroll. An entire system that includes a driven scroll that is pivotally supported in a casing and rotates with the rotation of the driving scroll, and that compresses intake air to a predetermined pressure by a compression chamber formed between the wraps of the i & ij scrolls and discharges it. In the cooling device for a rotary scroll compressor, a cooling fan that rotates simultaneously with the driving scroll and the driven scroll is provided in a space surrounded by the inner wall of the casing on the opposite side of the wrap of the driving scroll and the driven scroll. This constitutes the cooling system for the system rotary scroll compressor.

[Operation] The cooling fan rotates within the casing as the driving scroll and the driven scroll rotate.

As a result, an air flow is generated inside the casing, and the air flow contacts the driving scroll and the driven scroll to cool them, and is also sent to the bearing side, where a cooling fan is housed to cool the bearing. By making the space inside the casing into a spiral chamber, a swirling air flow is generated, and the driving scroll and the driven scroll and their bearings are cooled more actively.

[Example] Hereinafter, one embodiment of the present invention will be described based on the drawings.

As shown in FIG. 1, the drive scroll 5 has a rotating shaft 6,
It consists of a mirror plate 7 and a wrap 8 that stands up from the mirror plate 7.
The rotary shaft 6 is pivotally supported by a bearing 9.10 fitted in the casing 3 of. Note that a motor 11 fixed to the first casing 3 is connected to the rotating shaft 6 and drives the motor to rotate.

On the other hand, the driven scroll 12 has a rotating shaft 13 and a ji plate 14.
and a wrap 15 that will be erected, and the rotating shaft 13 is
to support. Note that the first casing 3 and the second casing 4 are flange-connected to form an integral structure. The driven scroll 12 rotates with the rotation of the drive scroll 5, and an Oldham joint mechanism 18 (detailed structure omitted) is interposed between the two to smoothly rotate the driven scroll 12.

Air introduced from the suction port 19 formed in the casing 4 in FIG. 2 is introduced into the space between the wraps 8 and 15,
After being compressed to an appropriate pressure in the compression chamber 20, it is discharged to the outside through a discharge passage 21 formed through the rotation shaft 3.

A first space chamber 22 surrounded by the first casing 3 is formed on the side opposite to the wrap 8 of the driving scroll 5, and a first space chamber 22 surrounded by the second casing 4 is formed on the side opposite to the wrap 15 of the driven scroll 12. Second spatial chambers 23 are respectively formed. A first cooling fan 1 is housed in the carver's space chamber 22, and a second cooling fan 2 is housed in the second space chamber 23, respectively.

The first cooling fan 1 is fixed to the rotating shaft 6 of the driving scroll 5, and the second cooling fan 2 is fixed to the rotating shaft 13 of the driven scroll 12. Note that the first cooling fan 1 and the second cooling fan 2 are formed from something like a centrifugal fan.

Although FIG. 2 shows a cross section taken along the line ■--■ in FIG. 1, the details of the first cooling fan 1 will be omitted since they are arranged in substantially the same manner.

As shown in FIG. 2, the space chamber 2 in the second casing 4
3 is formed in a spiral shape, and an air inlet 24 and an air outlet 25 are provided to communicate with the space chamber 23 . The second cooling fan 2 is arranged at a position closer to the air intake port 24 side. The air introduced from the air intake port 24 is jetted outward from the center of the second cooling fan 2, travels through the spiral space chamber 23 in a whirlpool state, and is discharged from the air exhaust port 25.

With the above structure, by driving the motor 11,
The driving scroll 5 and the driven scroll 12 rotate,
Compressed air is discharged from the discharge passage 21, and the space chamber 2
2. Due to the rotation of the first cooling fan 1 and the second cooling fan rotating in the interior of the casing 2, a swirling air flow is generated in the first casing 3 and the second casing 4, and a
The movable scroll 5 and the driven scroll 12 are cooled, as well as the bearings 9, 10, 16, 17 located relatively close to the space chamber 22.23.

In this embodiment, the first cooling fan 1 and the second cooling fan 2 are formed independently, respectively, and are connected to the rotating shafts 6 and 1 of the driving scroll 5 and the driven scroll 12.
Although it is fixed at 3.

These may be integrally formed on the mirror plates 7 and 14 on the opposite side of the laps 8 and 15 of the driving scroll 5 and the driven scroll 12. This makes the overall structure compact and improves ease of assembly. You can. Further, the bearings 9, 10 and the bearings 16, 17 are fitted on the inner walls of the first casing 3 and the second casing 4, but ribs are provided on the inner walls of the first casing 3 and the second casing, and The bearing 6, etc. may be held on the inner peripheral side of the rib, and a gap may be provided between adjacent ribs to allow air to pass through the gap to actively cool the bearing 6, etc. Further, although the first and second cooling fans 1 and 2 are centrifugal fans, the present invention is not limited thereto.

[Effect of the invention] According to the present invention, the following remarkable effects are achieved.

(1) By putting a cooling fan inside the casing,
An air flow is generated within the casing, and the W scroll and the driven scroll are actively cooled, thereby preventing a rise in compressed air temperature and improving compression efficiency.

(2) Since the air flow generated by the rotation of the cooling fan comes into contact with the bearing fitted in the casing, it is actively cooled, preventing high temperature deterioration and improving durability.

(3) By forming the space chamber in the casing in which the cooling fan is housed in a spiral shape, a swirling air flow is generated, which more actively cools the driving scroll, driven scroll, and their bearings, etc. .

(4) Since the cooling fan is fixed to the rotating shafts of the driving scroll and the driven scroll, or is formed integrally with the scroll, it does not require a special rotation mechanism to drive its rotation, making it simple and inexpensive. It can be implemented.

(5) By making the driving scroll, the driven scroll, and the cooling fan from an integral structure, the internal structure of the compressor can be made compact and the ease of assembly can be improved. Furthermore, the integral structure improves heat conduction and efficiently dissipates compression heat. Furthermore, the integral structure allows the thickness of the mirror plate to be reduced, resulting in a lighter weight.

[Brief explanation of the drawing]

FIG. 1 is an axial sectional view of an embodiment of the present invention, and FIG. 2 is a sectional view taken along the line ■--■ in FIG. DESCRIPTION OF SYMBOLS 1... First cooling fan, 2... Second cooling fan, 3... First casing, 4... Second casing, 5... Drive scroll, 6°13... ·Axis of rotation,
7.14...End plate, 8,15...Wrap, 9,10
, 16.17...Bearing, 11...Motor, 12...
- Driven scroll, 18... Oldham joint mechanism, 19
... Suction port, 20... Compression chamber, 21... Discharge path,
22.23... Space chamber, 24... Air intake port, 25
...Air outlet.

Claims (1)

[Scope of Claims] 1) A drive scroll that is pivotally supported within a casing and driven to rotate, and a wrap that meshes with a wrap of the drive scroll that is pivotally supported within the casing and rotates as the drive scroll rotates. In a cooling device for an all-system rotary scroll compressor that has a rotating driven scroll and compresses intake air to a predetermined pressure and discharges it by a compression chamber formed between the wraps of both scrolls, the driving scroll and the driven scroll A cooling device for a full-system rotary scroll compressor, characterized in that a cooling fan that rotates simultaneously with the driving scroll and the driven scroll is provided in a space surrounded by the inner wall of the casing on the side opposite to the wrap of the scroll. 2) The cooling device for a full-system rotary scroll compressor according to claim 1, wherein the cooling fan is formed integrally with the driving scroll and the driven scroll. 3) The cooling device for a full-system rotary scroll compressor according to claim 1, wherein the space chamber of the casing surrounding the cooling fan is formed in a spiral shape.