JP2876922B2 - Rolling piston type 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 rolling piston type compressor, and more particularly to an improvement in a structure around a blade for dividing a compression chamber into a high pressure chamber and a low pressure chamber.

[0002]

2. Description of the Related Art In general, as one type of a compressor provided in a refrigerator or the like, for example, a rolling piston type compressor as disclosed in Japanese Patent Application Laid-Open No. 63-167095 is known. In this type of compressor, as shown in FIG. 8, a roller (b) is eccentrically disposed inside a cylinder (a).
A part of the outer peripheral surface of the roller (b) is in contact with the inner peripheral surface of the cylinder (a), and a compression chamber (c) is formed between the cylinder (a) and the roller (b). The cylinder (a) is formed with a blade groove (d) extending in the radial direction, and the blade groove (d) can be freely protruded and retracted from the inner peripheral surface of the cylinder (a). The blade (e) (see FIG. 9) is housed, and the tip of the blade (e) is brought into contact with the outer peripheral surface of the roller (b), so that the compression chamber (c) becomes a high-pressure chamber (c1). And low pressure chamber (c
2). Then, the volume of the compression chamber (c) is changed by rotating the roller (b) in the cylinder (a), and the high-pressure chamber (c1) is contracted to obtain a high-temperature and high-pressure discharge gas. Has become. At this time, the blade (e) reciprocates in the blade groove (d) with the rotation of the roller (b).

[0003]

By the way, lubricating oil for lubricating each sliding portion is stored inside this kind of compressor, and the oil level of the lubricating oil is Is set near the upper surface of the cylinder (a) in order to reliably perform Therefore, the inside of the blade groove (d) is filled with the lubricating oil (o). That is, the space formed between the back surface of the blade (e) and the blade groove (d) is filled with the lubricating oil (o).

[0004] When the compressor is operated in such a state, the blade (e) reciprocates in the blade groove (d) filled with the lubricating oil (o). When e) retreats, the lubricant oil (o) is pushed back on the back surface of the blade, that is, this blade groove (d)
The lubricating oil (o) must be drained from the inside and must be retracted, which causes a power loss (pumping loss), and also causes a contact between the blade tip and the roller outer peripheral surface. There is a problem that the power is increased more than necessary, which also increases the power loss. In particular, such a power loss increases significantly when the compressor is rotating at a high speed, and the compressor efficiency is greatly reduced. Furthermore, not only such power loss, but also the contact force between the blade tip and the outer peripheral surface of the roller is increased more than necessary as described above, so that lubricity between the two cannot be sufficiently secured. A so-called out-of-oil state may occur.

The present invention has been made in view of the above points, and has been made to reduce power loss due to lubricating oil present in the blade groove and to ensure lubricity between a blade tip and a roller outer peripheral surface. The purpose is to obtain a configuration that can be achieved.

[0006]

SUMMARY OF THE INVENTION In order to achieve the above object, the present invention reduces the power loss of reciprocating motion of a blade due to lubricating oil existing in a blade groove.

According to the first aspect of the present invention, there is provided a casing (2).
A driving means (3) and a compression means (4) connected to the driving means (3) are accommodated therein.
A roller (6) is housed in a cylinder (5), and heads (7),
A compression chamber (9) is formed between the inner peripheral surface of the cylinder (5) and the outer peripheral surface of the roller (6), and a compression chamber (9) is formed in the roller (6). Since the eccentric portion (3f) formed eccentrically in a predetermined direction from the axis of the drive shaft (3b) of the drive means (3) is inserted, the roller (6) is moved relative to the cylinder (5). The roller (6) is eccentric so that a part of the outer peripheral surface thereof comes into contact with the inner peripheral surface of the cylinder (5), and the cylinder (5) has a blade groove extending in the radial direction of the cylinder (5). (5
b) is formed, and the blade groove (5b) accommodates a blade (11) that can freely move into and out of the compression chamber (9), and the blade (11) is provided with the roller (6). A compression chamber (9) is partitioned into a low-pressure chamber (9a) and a high-pressure chamber (9b). The compression chamber (9) has a gas suction passage (5a) and Discharge path (7
b) is connected, and the roller (6) rotates in the cylinder (5) in accordance with the driving of the driving means (3), so that gas flows from the suction passage (5a) into the compression chamber (9). It is premised on a rolling piston type compressor configured to suck and compress the gas and then discharge it from the discharge path (7b).

A muffler (1) for forming muffler chambers (16a) and (17a) in each of the heads (7) and (8).
6) and (17), and the gas discharged from the discharge path (7b) to one muffler chamber (16a) is supplied to the blade groove (5b).
Introducing paths (7d), (8d) to the heads (7), (8) so as to flow sequentially to the back side space (13) formed by the blades (11) and the other muffler chamber (17a).
Is formed.

The invention according to a second aspect is based on the premise similar to that of the first aspect, and the upper head portion (7)
A muffler (16) for forming a muffler chamber (16a) into which gas discharged from the discharge passage (7b) is introduced, and a back side space (5) formed by the blade groove (5b) and the blade (11). 13) and muffler room (16a)
And a communication path (7d) that communicates with. A communication path (8d) is formed in the lower head section (8) to communicate the back space (13) with an oil chamber formed below the lower head section (8). Further, due to the difference between the muffler internal pressure of the muffler chamber (16a) acting on the rear space (13) via the communication path (7d) of the upper head part (7) and the casing internal pressure acting on the oil chamber, The oil level in the back space (13) is pushed down, and the communication path (8) of the lower head (8) is lowered.
The configuration is such that the lubricating oil is discharged from the back side space (13) to the oil chamber side via d).

[0010]

According to the present invention, the following effects can be obtained in the present invention.

According to the first aspect of the present invention, the driving means (3)
As a result, the roller (6) of the compression means (4) rotates in the cylinder (5), whereby the fluid flows into the compression chamber (9) and compresses the fluid. In such a compression operation, the high-pressure gas discharged from the discharge path (7b) is introduced into the introduction paths (7d), (7d) formed in the heads (7) and (8).
(8d) and the blade groove (5b) and the blade (1).
1), the lubricating oil (O) in the back space (13) is discharged, and the resistance when the blade (11) is retracted is eliminated.

According to the second aspect of the present invention, the rear space (1
Due to the difference between the muffler internal pressure acting on 3) and the casing internal pressure acting on the oil chamber, the oil level in the rear space (13) is pushed down. Thereby, the rear side space (13) passes through the communication path (8d) of the lower head portion (8).
From the oil chamber side. This also eliminates resistance when the blade (11) moves backward.

(First Introduction Example) First, before describing an embodiment of the present invention, an introduction example for describing an entire configuration of a rolling piston type compressor will be described.

As shown in FIG. 1, a rolling piston type compressor (1) according to the present embodiment is provided in an air conditioner, and includes a driving means (3) and a compression means in a casing (2). The compressor body (4) is housed and configured.

The drive means (3) comprises an electric motor (3a) and a crankshaft (3b) as a drive shaft.
The electric motor (3a) is provided above the internal space (2a) of the casing (2) and fixed to the inner peripheral surface of the casing (2).
c) and a rotor (3d) arranged at the center. The crankshaft (3b) has an upper end connected to the center of the rotor (3d) and a lower end extended downward to be connected to the compressor body (4). The bottom of the casing (2) is an oil chamber in which lubricating oil (O) is stored, and the lower end of the crankshaft (3b) is immersed in the lubricating oil (O). A centrifugal pump (3e) is provided at the lower end of the crankshaft (3b), and the crankshaft (3b)
An oil supply passage (not shown) extending in the vertical direction is formed in b), and when the compressor (1) is driven, the centrifugal pump (3e) pumps lubricating oil (O) into the oil supply passage. Is supplied to each sliding portion of the compressor (1).

On the other hand, the compressor body (4) has a fixed airfoil shape and is disposed below the electric motor (3a). As shown in FIGS. 1 and 2, the compressor body (4) has a roller (6) housed in a cylindrical cylinder (5) fixed to the inner wall of the casing (2). A front head (7) as a head portion is mounted on an upper end surface of the cylinder (5), and a rear head (8) also as a head portion is mounted on a lower end surface thereof. ), A compression chamber (9) is formed between the inner peripheral surface of the cylinder (5) and the outer peripheral surface of the roller (6). The front and rear heads (7) and (8) have the crankshaft (3).
The through holes (7a) and (8a) are formed to have a diameter substantially equal to the diameter of b) and extend in the vertical direction.
The crankshaft (3b) is rotatably supported by (8a) via a metal seal or the like. The cylinder (5) is provided with a suction port (5a) serving as a refrigerant suction passage that opens to the compression chamber (9). The suction port (5a) has a suction pipe (5) extending from an unillustrated accumulator. 10) are connected. On the other hand, at the center of the roller (6), a cam portion (3f) as an eccentric portion formed integrally with the crankshaft (3b) and eccentric in a predetermined direction with respect to the axis of the crankshaft (3b). ) Is inserted. Thus, the roller (6) is provided eccentrically with respect to the cylinder (5), and a part of the outer peripheral surface of the roller (6) is always in contact with the inner peripheral surface of the cylinder (5).

A blade groove (5b), which is one of the features of this embodiment, is formed in the cylinder (5) near the position where the suction port (5a) is provided. The blade groove (5b) extends in the radial direction of the cylinder (5) and is formed to penetrate both upper and lower end surfaces of the cylinder (5). In the blade groove (5b), an enlarged chamber (5c) having a slightly larger width is formed at an outer portion in the extension direction. That is, the enlarged chamber (5c) is formed so that the cross-sectional area is set to be larger than the area of the blade rear end surface.

The blade (11) is inserted into the blade groove (5b) so as to be able to protrude and retract from the inner peripheral surface of the cylinder (5). As shown in FIG. 3, the blade (11) of the present example has a tapered portion (11a) formed in a left-right symmetrical tapered shape so that the rear end portion is substantially mountain-shaped in plan view. ing. Thus, the drag coefficient (so-called Cd value) at the time of the retreat movement of the blade (11) is set to be small. Specifically, in the conventional blade (e) as shown in FIG. 9, the drag coefficient was 1.1, whereas in the configuration of this example, it was significantly reduced to 0.34. The enlarged chamber (5c) may be in the state where the blade (11) is at the bottom dead center position where the blade (11) is most advanced, or in the state where the blade (11) is in the state where the blade (11) is most retracted. It is formed at a position where the tapered portion (11a) faces. That is, the expansion chamber (5c) is formed at a position where the rear end of the blade (11) reciprocating in the blade groove (5b) always faces. Further, a spring (12) is compressed between the tapered portion (11a) of the blade (11) and the inner peripheral surface of the casing (2). That is, the back side space (1) is formed between the periphery of the tapered portion (11a) of the blade (11) and the enlarged chamber (5c) of the blade groove (5b).
3), and the space on the rear side (1) is formed.
By the biasing force of the spring (12) disposed in 3), the entire blade tip portion in the height direction is formed by the roller (6).
The compression chamber (9) is pressed against the outer peripheral surface of the low pressure chamber (9).
a) and a high-pressure chamber (9b).

Further, a discharge port (7b) as a discharge path is provided on the high pressure chamber (9b) side of the position where the blade (11) is disposed. This discharge port (7b)
Is formed by cutting out a part of the inner peripheral surface of the cylinder (5), and a reed valve (not shown) is provided at a discharge port thereof.

A discharge pipe (14) connected to a condenser (not shown) is connected to the upper surface of the casing (2), and the high-temperature and high-pressure refrigerant discharged from the compressor body (4) is connected to the discharge pipe. (14) is led to the condenser side. With such a configuration, when the compressor is driven, the crankshaft (3) driven by the electric motor (3a) is driven.
With the rotation of b), the roller (6) is turned into the cylinder (5).
And compresses the compression chambers (9a) and (9b).

Next, the operation of the rolling piston type compressor (1) will be described. First, when the electric motor (3a) is driven, this driving force is applied to the crankshaft (3a).
b) transmitted to the roller (6) of the compressor body (4) via the cam portion (3f), and the roller (6) rotates so as to contract the compression chamber (9) in the cylinder (5). . This allows the refrigerant gas to flow from the suction pipe (10) to the suction port (5a).
And flows into the low-pressure chamber (9a) of the compressor body (4).
Then, with the rotation of the roller (6), the low pressure chamber (9)
As a) becomes a high-pressure chamber (9b), the refrigerant gas is compressed.

With the rotation of the roller (6) in such a compression operation, the blade (11) reciprocates in the blade groove (5b) following the rotation of the roller (6). . As described above, the blade (11) has a tapered portion (11a) formed at its rear end to reduce its drag coefficient, and a part of the blade groove (5b) is formed in the enlarged chamber (5c). When the blade (11) moves backward, the resistance of the blade movement by the lubricating oil (O) is small, and a unit for pushing out the lubricating oil (O) in the enlarged chamber (5c). The pressing force per area can be small. Therefore, the blade (1
1) The pump power for discharging the lubricating oil (O) from the blade groove (5b) due to the retreat is greatly reduced, and the blade (11) which conventionally has a relatively large power loss
Power loss due to increased pumping loss and increased contact force between the blade tip and the outer peripheral surface of the roller, thereby greatly improving the compressor efficiency. Specifically, the pump power is proportional to the drag coefficient of the blade rear end portion, and is obtained by the following equation.

D = (Cd · ρ · v ² · A) / 2 (1) (D: pump power, Cd: drag coefficient, ρ: density of lubricating oil, v: blade retreat speed, A: blade Therefore, as described above, the drag coefficient is 1.1 to 0.3 as described above.
4, the pump power is reduced by about 31% only by the configuration in which the tapered portion (11a) is formed. Further, in this example, the blade groove (5b) is formed.
Since the expansion chamber (5c) is formed in the first embodiment, the power loss in the peripheral portion of the blade is greatly reduced to such a degree that the efficiency of the compressor is not adversely affected. Further, as another effect, the contact force between the blade tip and the outer peripheral surface of the roller is suppressed from increasing more than necessary, so that the lubricating property between the two can be sufficiently ensured. Thus, there is no fear of running out of oil.

Next, a second introduction example will be described. This example is an improvement of the blade (11) with respect to the above-described first introduction example, and the other configuration is the same as the above-described first introduction example. Therefore, only the configuration of the blade (11) is described. Stop it.

As shown in FIG. 4, the blade (1
1) is formed by an arc-shaped portion (11b) having a rear end portion formed in the same arc shape in plan view as the front end portion. Therefore, even with the blade (11) having such a configuration, the drag coefficient (Cd value) when the blade (11) retreats can be set small. When the shape of the rear end portion of the blade is the same as that of the front end portion as in this example, the direction of insertion of the blade (11) into the blade groove (5b) is reversed, that is, the rear end portion is the outer peripheral surface of the roller. May be disposed so as to be in contact with the blade groove (5) of the blade (11) during the manufacturing operation of the compressor (1).
There is no need to consider the direction of insertion into b), and the effect of simplifying the manufacturing operation can be obtained.

[0026]

【Example】

 First Embodiment Next, each embodiment according to the present invention will be described.

First, the first embodiment will be described. In the introduction example described above, the blade groove (5b) and the blade (1
Although the shape of 1) is improved, in this example, the power loss is reduced by discharging the lubricating oil (O) in the blade groove (5b). Hereinafter, the configuration of this example will be described with reference to the drawings. still,
Also in this example, the description of the same configuration as the above-described introduction example is omitted.

As shown in FIG. 5, the compressor (1) of the present embodiment
Has mufflers (16) and (17) on the upper surface side of the front head (7) and the lower surface side of the rear head (8), respectively. Further, the muffler (16) on the front head (7) side has an inner peripheral portion separated from the bearing portion (7c) of the front head (7), and the muffler internal space (16a) and the casing internal space (2a). And are communicated. Further, the discharge port (8b) is connected to the rear head (8).
The discharge port (8b) is provided with a reed valve (8e). In the front head (7) and the rear head (8), the portions corresponding to the back space (13) of the blade grooves communicate with each other as communication paths (7d) and (8d) as the introduction paths in the present invention, which penetrate vertically.
Are formed.

With such a configuration, when the compressor (1) is driven, as shown by the arrow in FIG. 5, the discharge gas protruding from the discharge port (8b) discharges the gas inside the lower muffler. The space (17a) is introduced into the rear space (13) through the communication path (8d) formed in the rear head (8), and then is introduced through the communication path (7d) formed in the front head (7). Upper muffler internal space (16a)
Is discharged into the casing internal space (2a). As described above, the discharge gas is supplied to the space (1) on the back side of the blade (11).
3), the back side space (13) is not filled with the lubricating oil (O), so that the resistance when the blade (11) retreats is reduced. The power loss is greatly reduced. The discharge gas is supplied to the lower muffler internal space (1
7a) and the upper muffler internal space (16a), the discharge noise is reduced, and the quietness of the compressor can be improved.

Second Embodiment Next, a second embodiment will be described. Also in this example, the lubricating oil (O) in the space (13) on the back side of the blade (11) is discharged.

As shown in FIG. 6, the front head (7)
Mufflers (16) and (17) are provided on the upper surface side of the rear head (8) and the lower surface side of the rear head (8), respectively.
The inner peripheral portions of (6) and (17) are fixed to the outer peripheral surfaces of the bearing portions (7c) and (8c) of the front head (7) and the rear head (8). Further, the discharge port (7b) is formed in the front head (7), and a reed valve (7e) is provided in the discharge port (7b). Further, communication passages (7d), (8) penetrating in the vertical direction as described above are provided in portions of the front head (7) and the rear head (8) corresponding to the back space (13) of the blade grooves.
d) is formed. Further, the rear head (8), the cylinder (5) and the front head (7) are located at a position (left side in FIG. 6) opposite to the position where the blade (11) is disposed with respect to the axis of the crankshaft (3b). A communication passage (18) penetrating the three members is formed, and a discharge pipe (19) passing through the upper muffler (16) is connected to an upper end of the communication passage (18). .

With such a structure, when the compressor (1) is driven, the discharge gas protruding from the discharge port (7b) is discharged from the discharge port (7b) as shown by an arrow in FIG. (16a) is introduced into the rear space (13) through a communication path (7d) formed in the front head (7), and then is lowered through a communication path (8a) formed in the rear head (8). Side muffler internal space (17a)
And a communication passage (18) passing through the rear head (8), the cylinder (5) and the front head (7).
Through the discharge pipe (19) to the casing internal space (2a).
Is discharged. Thus, even in this type, since the discharge gas flows through the back space (13) of the blade (11), the back space (13) is filled with the lubricating oil (O). As a result, there is no resistance when the blade (11) is retracted, and power loss is greatly reduced. Further, also in the case of this example, the silence of the compressor can be improved by the operation of each muffler internal space (16a, 17a).

Third Embodiment Next, a third embodiment will be described. Also in this example, the lubricating oil (O) in the space (13) on the back side of the blade (11) is discharged.

As shown in FIG. 7, the front head (7)
The muffler (16) is provided only on the upper surface side of the muffler, and the inner peripheral portion of the muffler (16) is separated from the bearing portion (7c) of the front head (7). In addition, the discharge port (7
b) is formed in the front head (7), and a reed valve (7e) is provided at the discharge port (7b). Further, communication passages (7d) and (8d) are formed in the front head (7) and the rear head (8) in portions corresponding to the back side space (13) of the blade grooves in the same manner as described above. I have. The lower end of the communication passage (8d) formed in the rear head (8) is formed to have a small diameter.

With such a configuration, when the compressor (1) is driven, the discharge gas protruding from the discharge port (7b) is discharged from the discharge port (7b) as shown by an arrow in FIG. (16a) to casing internal space (2a)
Is discharged. At this time, the upper muffler internal space (16a) is slightly higher than the pressure of the casing internal space (2a) due to the overcompression of gas in the compression chamber (9). Each communication path (7d), (8
d) and the back side space (13). on the other hand,
The oil level of the lubricating oil (O) stored in the oil chamber in the casing (2) is slightly lower than the high pressure introduced into the communication paths (7d), (8d) and the back space (13). The pressure of the low casing internal space (2a) is acting on the casing. Therefore, the oil level of the lubricating oil (O) is restricted by the lower surface portion of the rear head (8) due to the pressure difference, so that the lubricating oil (O) does not flow into the back space (13) of the blade (11). Therefore, even in this type, the back side space (13) is not filled with the lubricating oil (O), and as a result, there is no resistance when the blade (11) is retracted, and power loss is large. To be reduced.

Although each of the above embodiments has been described with reference to a compressor provided in an air conditioner, the present invention is not limited to this, but can be applied to various fluid compressors.

[0037]

As described above, according to the present invention, the following effects are exhibited. According to the invention described in claim 1, the gas discharged from the discharge path to one of the muffler chambers is
The back side space formed by the blade grooves and the blades, the introduction path is formed in each head portion so as to flow sequentially to the other muffler chamber, so that the lubricating oil in the back side space is caused by the gas flowing through the back side space. Since the resistance when the blade is ejected and the blade retreats is eliminated, the power loss can be greatly reduced, and the efficiency of the compressor can be greatly improved. Further, since the gas discharged from the discharge passage passes through the one muffler chamber and the other muffler chamber, the sound of discharging the gas can be significantly reduced, and the quietness of the compressor can be improved.

According to the second aspect of the invention, the internal pressure of the muffler in the muffler chamber acting on the back space via the communication path of the upper head portion and the internal pressure of the casing acting on the oil level of the lubricating oil in the oil chamber. Due to the difference, the oil level in the back side space is pushed down, and the lubricating oil is discharged from the back side space to the oil chamber side through the communication path of the lower head part, so the difference between the muffler internal pressure and the casing internal pressure The lubricating oil in the rear space can be discharged by effectively utilizing the pressure.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view of a rolling piston type compressor in a first introduction example.

FIG. 2 is a cross-sectional view at a position corresponding to line II-II in FIG.

FIG. 3 is a perspective view showing a blade.

FIG. 4 is a diagram corresponding to FIG. 3 in a second introduction example.

FIG. 5 is a longitudinal sectional view of the vicinity of a compressor main body in the first embodiment.

FIG. 6 is a diagram corresponding to FIG. 5 in a second embodiment.

FIG. 7 is a diagram corresponding to FIG. 5 in a third embodiment.

FIG. 8 is a diagram corresponding to FIG. 2 in a conventional example.

FIG. 9 is a perspective view showing a conventional blade.

[Explanation of symbols]

 (1) Rolling piston type compressor (2) Casing (3) Driving means (3b) Crank shaft (driving shaft) (3f) Cam part (eccentric part) (4) Compressor body (compression means) (5) Cylinder ( 5a) Suction port (suction path) (5b) Blade groove (5c) Enlarged chamber (6) Roller (7) Front head (head) (8) Rear head (head) (7b), (8b) Discharge port (discharge) (7d), (8d) Communication path (introduction path) (9) Compression chamber (11) Blade (11a) Tapered surface (13) Back space (O) Lubricating oil

──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Kazuhiro Furusho 1304 Kanaokacho, Sakai-shi, Osaka Daikin Industries, Ltd.Sakai Factory Kanaoka Factory (72) Inventor Kazumasa Ochiai 1304, Kanaokacho, Sakai-shi, Osaka Daikinko (56) References JP-A-60-128988 (JP, A) JP-A-63-167095 (JP, A) JP-A-4-358789 (JP, A) −130788 (JP, U) Fully open sho 59-28695 (JP, U) Really open sho 58-70484 (JP, U) (58) Fields investigated (Int. Cl. ⁶ , DB name) F04C 18/356

Claims (2)

(57) [Claims] 1. A drive means (3) in a casing (2).
And a compression means (4) connected to the driving means (3). The compression means (4) includes a roller (6) housed in a cylinder (5) and the cylinder (5).
The heads (7) and (8) are disposed on both end surfaces of the cylinder (5), and a compression chamber (9) is formed between the inner peripheral surface of the cylinder (5) and the outer peripheral surface of the roller (6). An eccentric portion (3f) formed eccentrically in a predetermined direction from the axis of the drive shaft (3b) of the drive means (3) is inserted into the roller (6). 6)
Is eccentric with respect to the cylinder (5) so that a part of the outer peripheral surface of the roller (6) comes into contact with the inner peripheral surface of the cylinder (5). ), A blade groove (5b) extending in the radial direction is formed, and the blade groove (5b) accommodates and arranges a blade (11) which can be moved into and out of the compression chamber (9). (11) is in contact with the outer peripheral surface of the roller (6) to partition the compression chamber (9) into a low-pressure chamber (9a) and a high-pressure chamber (9b). Is connected to a gas suction path (5a) and a discharge path (7b), and the roller (6) rotates in the cylinder (5) with the driving of the driving means (3).
A rolling piston compressor configured to suck a gas from the suction path (5a) into the compression chamber (9), compress the gas, and discharge the compressed gas from the discharge path (7b); Sections (7) and (8) have muffler chambers (16
a), mufflers (16), (17) forming (17a)
Is provided, and one muffler chamber (16) is provided from the discharge path (7b).
The heads (7), () are arranged so that the gas discharged to a) flows sequentially to the back side space (13) formed by the blade groove (5b) and the blade (11) and the other muffler chamber (17a). 8) A rolling piston type compressor characterized in that introduction passages (7d) and (8d) are formed in 8). 2. A driving means (3) in a casing (2).
And a compression means (4) connected to the driving means (3). The compression means (4) includes a roller (6) housed in a cylinder (5) and the cylinder (5).
Head portions (7) and (8) are provided on both upper and lower end surfaces of the cylinder, and a compression chamber (9) is formed between the inner peripheral surface of the cylinder (5) and the outer peripheral surface of the roller (6). An eccentric part (3f) formed eccentrically in a predetermined direction from the axis of the drive shaft (3b) of the driving means (3) is inserted into the roller (6), (6)
Is eccentric with respect to the cylinder (5) so that a part of the outer peripheral surface of the roller (6) comes into contact with the inner peripheral surface of the cylinder (5). ), A blade groove (5b) extending in the radial direction is formed, and the blade groove (5b) accommodates and arranges a blade (11) which can be moved into and out of the compression chamber (9). (11) is in contact with the outer peripheral surface of the roller (6) to partition the compression chamber (9) into a low-pressure chamber (9a) and a high-pressure chamber (9b). Is connected to a gas suction path (5a) and a discharge path (7b), and the roller (6) rotates in the cylinder (5) with the driving of the driving means (3).
In a rolling piston type compressor configured to suck gas from the suction passage (5a) into the compression chamber (9), compress the gas, and discharge the compressed gas from the discharge passage (7b), The section (7) is provided with a muffler (16) forming a muffler chamber (16a) into which gas discharged from the discharge path (7b) is introduced, and a blade groove (5).
A communication path (7d) for communicating the back side space (13) formed by the b) and the blade (11) with the muffler chamber (16a) is formed, and the lower head part (8) is formed in the lower head part (8). A communication path (8d) is formed for communicating the back side space (13) with an oil chamber formed below the lower head section (8), and a communication path for the upper head section (7). The difference between the muffler internal pressure of the muffler chamber (16a) acting on the back space (13) via (7d) and the casing internal pressure acting on the oil chamber is given by
The oil level in the rear side space (13) is pushed down, and passes through the communication path (8d) of the lower head part (8), so that the rear side space (1) is formed.
A rolling piston type compressor characterized in that the lubricating oil is discharged from 3) to the oil chamber side.