JPH0726616B2 - Scroll type fluid device - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dual rotary scroll type fluid device used for a compressor or the like, and more particularly to a driven scroll side oil supply mechanism.

(Prior Art) Generally, in this type of both-system rotary scroll compressor, as disclosed in JP-A-62-191685,
A spiral wrap is erected on the front of each end plate,
A drive scroll and a driven scroll, which are formed by connecting a drive shaft and a driven shaft to the back side, are arranged and housed side by side in a hermetically sealed casing by meshing the respective wraps, and the drive shaft and the driven shaft are respectively provided on the back side of the end plate. The scrolls are rotatably fitted to the frame to support each scroll on the frame, and both scrolls are arranged so that the drive shaft and the driven shaft have a predetermined interval.

Then, when the drive scroll is rotated, the driven scroll rotates in synchronization with the rotation, while a sealed chamber is formed between the end plates by the wraps, and the sealed chamber shrinks while moving in the central direction. The fluid is being compressed.

(Problems to be Solved by the Invention) In the scroll fluid device described above, since each scroll is supported by the frame on the back side of the end plate, the bearing between the drive shaft and the frame is driven by the oil sump at the bottom of the casing. Lubricating oil can be easily supplied through the shaft. However, since the bearing between the driven shaft and the frame has a scroll mechanism, which is a rotating mechanism, between the oil sump and the oil reservoir,
The oil is supplied from the oil supply pump to the oil sump of the driven side frame via the oil supply pipe, and oil is supplied to the driven side bearing from the oil sump.

However, this has a problem in that the fuel supply pipe has to be arranged and the structure becomes complicated. In particular, since the oil supply pipe is arranged from the bottom to the upper part of the casing, there is a problem that the size of the entire casing becomes large.

The present invention has been made in view of the above point, and by using a connecting pin that transmits the rotation of the driving scroll to the driven scroll, the driven side bearing is lubricated, so that the lubrication can be reliably performed with a simple structure. The purpose is to

(Means for Solving the Problems) In order to achieve the above-mentioned object, the means taken by the invention according to claim (1) is, as shown in FIG. 1, first, end plates (31), (41), respectively. Spiral wraps (32), (42) on the front of the
And a driven scroll (4) in which a drive shaft (33) and a driven shaft (43) are connected to each other on the back surface and a driven scroll (4) meshes the respective wraps (32), (42). The drive shaft (33) and the driven shaft (43) provided on the rear side of the end plates (31), (41) so that their axial centers are at a predetermined distance. The bearing (3) is attached to the frame (5) and the driven side frame (6) respectively.
4) and (44) are fitted together, and the both frames (5),
It is intended for a scroll type fluid device in which the space between (6) is formed in the low pressure chamber (2b) and the back side of the driven frame (6) is formed in the high pressure chamber (2a).

The driven scroll (4) is provided between the outer peripheral edges of the end plates (31) and (41) as the drive scroll (3) rotates.
So that they rotate in synchronism with both end plates (31), (4
A plurality of connecting pins (7), (7), ... engaged with 1) are erected, and at least one connecting pin (7) has a through passage (73) penetrating both ends. There is. Further, one end of the drive shaft (33) and the end plate (31) of the drive scroll (3) is an oil sump (23) formed at the bottom of the casing (2) and the other end of the connecting pin (7). An oil supply passage (8) communicating with the through passage (73) and guiding lubricating oil to the through passage (73) is formed. In addition, the driven scroll (4) is provided with a supply means (9), one end of which communicates with the through passage (73) of the connecting pin (7) to supply lubricating oil to the driven bearing (44). It has a structure.

Further, the means taken by the invention according to claim (2) is the same as the invention according to claim (1), in which one end of the oil supply means (9) communicates with the through passage (73) of the connecting pin (7), A lubricating oil passage (91) having the other end opened to the rear surface of the end plate (41), and a lubricating oil from the oil supply passage (91) formed between the driven-side frame (6) and the end plate (41). Supply space leading to 44) (92)
The means of the invention according to claim (3) has a centripetal pump (93) provided in the supply space (92).

Further, the means taken by the invention according to claim (4) is, as shown in FIG. 2, the high pressure chamber between the driven shaft (43) and the driven side frame (6) in the invention according to claim (1). (2
While the seal member (47) is provided at the end on the a) side,
The oil supply means (9) is an end plate (41) of the driven scroll (4).
And an oil supply passage (94) formed on the driven shaft (43), one end of which communicates with the through passage (73) of the connecting pin (7) and the other end of which opens to the outer peripheral surface of the driven shaft (44). There is.

(Operation) With the above configuration, in the invention according to claim (1), when the drive shaft (33) is rotated, the drive scroll (3) is rotated, the end plate (31) is rotated, and the end plate (31) and the follower plate are driven. Since the connecting pin (7) is provided between the scroll (4) and the end plate (41), the driven scroll (4) is synchronized with the drive scroll (3) by the rotation of the drive scroll (3). It will rotate.

The rotation of both scrolls (3) and (4) forms a closed chamber (13) between both wraps (32) and (42), and
The closed chamber (13) contracts while moving toward the center to compress the fluid, for example.

On the other hand, the lubricating oil from the oil sump (23) at the bottom of the casing (2) passes through the oil supply passage (8) of the drive scroll (3) and the follower scroll (73) through the through passage (73) of the connecting pin (7). 4) side is supplied. The lubricating oil is supplied from the connecting pin (7) by the oil supply means (9) to the driven side bearing (44).
Specifically, in the invention according to claim (2), the lubricating oil flows from the connecting pin (7) through the oil supply passage (91) to the supply space (92) on the rear side of the end plate (41), and is driven. Side bearing (4
While being guided to 4), in the invention according to claim (3), the lubricating oil is pressurized by the centripetal pump (93) in the supply space (92) and supplied to the bearing (44).

In the invention according to claim (4), the driven side bearing (44)
The seal member (47) creates a low pressure atmosphere in the portion, and the lubricating oil is supplied from the connecting pin (7) to the bearing (44) through the oil supply passage (94).

(Effect of the invention) Therefore, according to the inventions according to claims (1) and (2),
Connecting pin (7) connecting both scrolls (3), (4)
Since the lubricating oil is guided to the driven scroll (4) side through the lubricant, the lubricating oil can be guided to the driven scroll (4) side without disposing an oil supply pipe as in the conventional case. Therefore, the driven side bearing (44) can be lubricated.

Further, since the connecting pin (7) of both scrolls (3) and (4) is used, the number of parts can be reduced,
It is possible to reduce the size of the entire device.

Further, according to the invention of claim (3), since the centripetal pump (93) is provided, it is possible to reliably supply oil to the driven side bearing (44).

Further, according to the invention of claim (4), since the driven side bearing (44) is in a low pressure atmosphere, it is possible to easily supply oil to the bearing (44).

(Example) Hereinafter, the Example of this invention is described in detail based on drawing.

As shown in FIG. 1, (1) is a dual-system rotary scroll type fluid device, which is used for a compressor in a refrigeration system and compresses and discharges a refrigerant gas.

The scroll type fluid device (1) has a closed casing (2).
The scroll mechanism (11) is housed therein, and the drive motor (12) is housed therein.
The drive scroll (3) and the driven scroll (4) are supported by the frames (5) and (6), respectively. Both frames (5) and (6) are formed in a substantially disc shape, and are provided in parallel at a predetermined interval so as to be located on the back side of the scrolls (3) and (4), respectively. Both frames (5) and (6) are fixed to the casing (2) at their outer peripheral surfaces, and a shaft hole (5) that rotatably supports the scrolls (3) and (4) is provided at the center.
1) and (61) are bored in the vertical direction, and the shaft holes (5
1) and (61) are formed so that their axial centers have a predetermined interval in the radial direction.

In both scrolls (3) and (4), spiral-shaped (involute-shaped) wraps (32) and (42) are erected on the front faces of disk-shaped end plates (31) and (41). And the front surfaces of the end plates (31) and (41) face each other, and the end plates (31) and (41) are arranged side by side between the frames (5) and (6), and the wraps (32) and (42) are also arranged. Are meshed with each other. Further, the drive shaft (33) is provided on the rear surface (lower surface) of the end plate (31) of the drive scroll (3), and the driven shaft (43) is provided on the rear surface (upper surface) of the end plate (4) of the driven scroll (4). The shaft holes (51) of the frames (5) and (6),
It is rotatably fitted in (61) via radial bearings (34), (44). Further, a thrust bearing (3) is provided between each of the end plates (31), (41) and each of the frames (5), (6).
5) and (45) are provided to allow the scrolls (3),
(4) is supported by the frames (5) and (6). The drive shaft (33) extends to the bottom of the casing (2), and the rotor (12a) of the drive motor (12).
Is inserted into the stator (12) of the drive motor (12).
b) is fixed to the casing (2).

The drive shaft (33) and the driven shaft (43) are the drive shaft centers.
(O ₁ ) and the driven shaft (O ₂ ) are eccentrically provided at a predetermined interval in the radial direction, and the driven scroll is driven by the rotation of the drive scroll (3) through the connecting pin (7). (4) rotates synchronously, and one scroll (3) or (4) relatively rotates the other scroll (4) or (3).
It is configured to only revolve around. On the other hand, the respective wraps (32), (42) are in contact with the end plates (31), (41) whose front end faces face each other, and the inner peripheral side face and the outer peripheral side face are in contact with each other at a plurality of positions, and the space between these contacts is a sealed chamber. It is formed in (13) and is configured such that the closed chamber (13) contracts while moving toward the centers of both scrolls (3), (4).

In the casing (2), the driven-side frame (6) serves as the high-pressure chamber (2a) above the frame (6), the low-pressure chamber (2b) between the frames (5) and (6), and the drive-side frame. Due to (5), the lower part of the frame (5) has a high pressure chamber (2
It is divided into sections in c). A suction pipe (21) communicates with the low pressure chamber (2b) on the side surface of the casing (2), and a discharge pipe (2) communicates with the high pressure chamber (2a) at the upper part.
2) are connected to each other so that the low-pressure refrigerant gas introduced from the suction pipe (21) flows from the low-pressure chamber (2b) into the closed chamber (13). Further, the driven scroll (4) is provided with a discharge passageway (46) at the center thereof from the front surface of the end plate (41) to the end surface (upper surface) of the driven shaft (43), and the discharge chamber (13) extends from the closed chamber (13). The high-pressure refrigerant gas is configured to flow into the high-pressure chamber (2a), and the driven radial bearing (44) has a high-pressure atmosphere. Furthermore, the bottom of the casing (2) is an oil sump (23) for lubricating oil,
The lower end of the drive shaft (33) is immersed.

Next, the connection pin (7) and the oil supply mechanism, which characterize the present invention, will be described.

A plurality of (for example, four) connecting pins (7) are erected between the end plates (31) and (41) of the scrolls (3) and (4), respectively. ) Large diameter section (71)
And a small diameter portion (72) protruding from the upper end of the large diameter portion (71), the lower end of the large diameter portion (71) being fixed to the outer peripheral edge of the front surface (upper surface) of the drive side end plate (31). ing. The small-diameter portion (72) is inserted into the recess (4a) formed on the outer peripheral edge of the front surface (lower surface) of the driven side end plate (41) and engages with the end plate (41), and the recess (4a) is It is formed to have a larger diameter and higher than the small diameter portion (72) and is closed at the upper end surface of the large diameter portion (71). Further, of the plurality of connecting pins (7), (7), ..., the two connecting pins (7), (7) at the symmetrical positions have a smaller diameter portion (72) than the lower end surface of the large diameter portion (71). ) Has a through passage (73) penetrating the upper end surface thereof, and the upper end of the through passage (73) communicates with the recess (4a).

On the other hand, an oil supply passage (8) is provided in the drive scroll (3),
The driven scroll (4) is provided with a refueling means (9), respectively. The oil supply passage (8) has a longitudinal passage portion (81) formed in the drive shaft (33) and a lateral passage portion (8) formed in the end plate (31).
2) is formed into a substantially T shape, the lower end of the vertical passage portion (81) communicates with the oil sump (23), and the upper end of the vertical passage portion (81) communicates with the central portion of the lateral passage portion (82). Both ends of 82) communicate with the lower end of the through passage (73) of the connecting pin (7). And
One end of the branch passage (83) branched from the vertical passage portion (81) is opened to the bearing (34) portion on the outer peripheral surface of the drive shaft (33),
The high-pressure refrigerant pressure in the high-pressure chamber (2c) causes the lubricating oil to pass from the oil sump (23) through the vertical passage (81) to the drive-side radial bearing (3
4) and centrifugal force by the rotation of the drive scroll (3) is applied in the lateral passage portion (82) and is supplied to the recess (4a) through the through passage (73) of the connecting pin (7). And the recess (4a) serves as an oil sump.

The oil supply means (9) includes an oil supply passage (91) formed in the end plate (41) of the driven scroll (4) and the driven side end plate (4).
It is composed of a supply space (92) formed between 1) and the driven-side frame (6) and a centripetal pump (93).
Then, one end of the oil supply passage (91) communicates with the recess (4a), and the other end is opened on the rear surface (upper surface) of the driven side end plate (41) and inside the thrust bearing (45). The supply space (92) is formed from the inner side of the thrust bearing (45) to the driven side bearing (44), and has an oil sump circumferential groove (92a) formed in the driven side frame (6). The thrust bearing (45) also serves as a seal member. As shown in FIG. 2, the centripetal pump (93) is composed of a screw groove type pump having a spiral groove (93a), and is provided inside the orbiting groove (92a) in the driven frame (6). The lubricating oil in the supply space (92) is pumped to the driven-side bearing (44).

Next, the compression operation of the scroll fluid device (1) will be described.

First, when the drive motor (12) is driven to rotate the drive shaft (33), the drive scroll (3) causes the drive shaft (33) to have a center (O).
_Since the end plate (31) rotates around ₁ ) as a center, the connecting pin (7) also rotates. Since the small diameter portion (72) of the connecting pin (7) is engaged with the end plate (41) of the driven scroll (4), the driven scroll (4) is rotated by the rotation of the connecting pin (7). Moreover, the driven scroll (4)
Rotates in synchronization with the driving scroll (3), and in accordance with this synchronous rotation, the other scroll (4) or (3) only revolves relative to one scroll (3) or (4). . Along with this revolution, laps (32), (4
The contact point of 2) moves toward the center, and the sealed chamber (13) is formed between the wraps (32) and (42).
The closed chamber (13) is formed from the outer peripheral end of (42) and contracts while moving in a spiral toward the discharge passage (46) at the center.

On the other hand, the low pressure refrigerant gas flows from the suction pipe (21) into the closed chamber (13) through the low pressure chamber (2b) in the casing (2). Then, the low-pressure refrigerant gas is compressed into high-pressure refrigerant gas by contraction of the closed chamber (13), and the high-pressure refrigerant gas passes through the discharge passage (46) and flows into the high-pressure chamber (2a),
It is discharged from the discharge pipe (22).

Further, high-pressure refrigerant gas is introduced into the high-pressure chamber (2c) below the drive-side frame (5), and the lubricating oil in the oil sump (23) is pumped to the oil supply passage (8) of the drive scroll (3) to vertically Drive-side radial bearing (3
4) Supplied to. Further, the lubricating oil in the vertical passage portion (81) flows into the lateral passage portion (82), and centrifugal force is applied by the rotation of the drive scroll (3) in the lateral passage portion (82), so that the connecting pin (7) passes through the passage. It passes through (73) and flows into the recess (4a) of the driven scroll (4). Then, the lubricating oil in the recess (4a) flows into the supply space (92) through the oil supply passageway (91) of the driven scroll (4), and is centripetalized by the rotation of the driven scroll (4) in the supply space (92). The pump (93) exerts a pumping action, and the lubricating oil is pressurized and supplied to the driven side radial bearing (44).

Therefore, since the lubricating oil is guided to the driven scroll (4) side through the connecting pin (7) that connects both scrolls (3) and (4), there is no need to dispose an oil supply pipe as in the conventional case. Since the lubricating oil can be guided to the driven scroll (4) side, the driven side radial bearing (4
Oil can be supplied to 4), and the bearing (44) can be reliably lubricated.

Further, since the connecting pin (7) of both scrolls (3) and (4) is used, the number of parts can be reduced,
It is possible to reduce the size of the entire device.

Further, since the centripetal pump (93) is provided, it is possible to reliably supply oil to the driven side radial bearing (44).

FIG. 3 shows another embodiment, in which the driven side radial bearing (44) portion of the previous embodiment has a low pressure atmosphere instead of the high pressure atmosphere.

That is, a mechanical seal (47), which is a seal member, is provided between the driven shaft (45) and the frame (6) at the end on the high pressure chamber (2a) side, which is the mechanical seal. The end plate (41) side of the (47) is configured to have a low pressure atmosphere.

On the other hand, the oil supply means (9) of the driven scroll (4) is formed by an oil supply path (94), and one end of the oil supply path (94) is connected to the recess (4a) formed in the end plate (41). The end portion extends in the centripetal direction of the end plate (41), the inner end extends in the axial direction of the driven shaft (43), and the other end is formed so as to open to the outer peripheral surface of the driven shaft (43).

Therefore, since the opening of the driven shaft (43) in the oil supply passage (94) of the driven scroll (4) is in a low pressure atmosphere, the lubricating oil that has passed through the connecting pin (7) passes through the recess (4a) to the oil supply passage (94). 94) and is easily supplied to the driven side radial bearing (44).

4 and 5 show another embodiment of the connecting pin (7), in which the roller (74) is rotatably fitted to the small diameter portion (72) of the connecting pin (7). ) Is inserted into the recess (4a) of the end plate (41), and the roller (74) rolls on the inner surface of the recess (4a). Therefore, since the roller (74) rolls into contact with the inner surface of the recess (4a) to transmit power, the power transmission efficiency can be improved as compared with the case of sliding contact, and at the same time the lubricating oil is removed. It is reliably supplied between the roller (74) and the recess (4a) and the small diameter portion (72).

In each of the above-described embodiments, the through passage (73) is formed in the two connecting pins (7), but the through passage (73) may have only one connecting pin (7), and conversely, 3 It may be formed on more than one connecting pin (7).

Also, the rear side (downward) of the drive-side frame (5) may be a low-pressure chamber, in which case a lubrication pump is provided at the lower end of the drive shaft (33) to guide the lubricating oil to the lubrication passage (8). To do.

[Brief description of drawings]

The drawings show an embodiment of the present invention. FIG. 1 is a vertical sectional view of a scroll type fluid device, and FIG. 2 is a front view of a driven frame. FIG. 3 is a vertical sectional view of a scroll type fluid device showing another embodiment, FIG. 4 is an enlarged sectional view showing another embodiment of the connecting pin, and FIG. 5 is a plan view of the same. (1) …… Scroll type fluid device (2) …… Casing (2a), (2c) …… High pressure chamber (2b) …… Low pressure chamber (3) …… Drive scroll (4) …… Following scroll (5) , (6) …… Frame (7) …… Connecting pin (8) …… Lubrication passage (9) …… Lubrication means (31), (41) …… End plate (32), (42) …… Wrap (33 ) …… Drive shaft (43) …… Driven shaft (47) …… Mechanical seals (34), (44) …… Radial bearings (73) …… Through passages (91), (94) …… Oil supply passages (92) ) …… Supply space (93) …… Centering pump

Claims (4)

[Claims] 1. Spiral wraps (32), (42) are erected on the front surfaces of the end plates (31), (41), respectively, and the drive shaft (33) and the driven shaft (43) are connected on the rear surfaces thereof. The drive scroll (3) and the driven scroll (4) that are formed by each wrap (3
2) and (42) are meshed with each other and are arranged side by side in the casing (2). The drive shaft (33) and the driven shaft (43) have the end plates (31), (41) so that their axial centers are spaced by a predetermined distance. ) Drive side frame (5) and driven side frame (6) provided on the back side
To the low pressure chamber (2b) between the frames (5) and (6), and the rear side of the driven side frame (6) to the high pressure chamber (2a). In the scroll type fluid device formed in each of the above, the driven scroll (4) rotates synchronously with the rotation of the drive scroll (3) between the outer peripheral edges of the end plates (31) and (41). A plurality of connecting pins (7), (7), ..., whose both ends engage with the end plates (31), (41) are erected, and at least one connecting pin (7) has both ends at both ends. A through passage (73) is formed so as to penetrate the drive shaft (33) and the end plate (3) of the drive scroll (3).
1) One end communicates with an oil sump (23) formed at the bottom of the casing (2) and the other end communicates with the through passage (73) of the connecting pin (7) and circulates through the through passage (73). An oil supply passage (8) for guiding oil is formed, and one end of the driven scroll (4) communicates with the through passage (73) of the connecting pin (7) to transfer lubricating oil to the driven side bearing (44). A scroll type fluid device characterized in that it is provided with a supply means (9) for supplying to the. 2. The scroll type fluid device according to claim 1, wherein the oil supply means (9) has one end communicating with the through passage (73) of the connecting pin (7) and the other end having an end plate (41). The oil supply passage (91) opening to the back, the driven side frame (6) and the end plate (4
1) A scroll type fluid device, characterized in that it is configured with a supply space (92) which is formed between the lubricating oil from the oil supply passage (91) and guides the lubricating oil to the bearing (44). 3. The scroll type fluid device according to claim 2, wherein a centripetal pump (93) is provided in the supply space (92). 4. The scroll type fluid device according to claim 1, wherein a seal member (47) is provided at an end portion of the high pressure chamber (2a) side between the driven shaft (43) and the driven side frame (6). Meanwhile, the refueling means (9) is the end plate (41) of the driven scroll (41).
And an oil supply passage (94) formed on the driven shaft (43), one end of which communicates with the through passage (73) of the connecting pin (7) and the other end of which opens to the outer peripheral surface of the driven shaft (44). A scroll type fluid device characterized in that