KR20090011246U - Rotary type compressor - Google Patents

Abstract

The present invention relates to a rotary compressor including a compression block in which a refrigerant is compressed and a cylinder block provided with a suction port through which a refrigerant is sucked into the compression chamber, wherein the width of the inlet end of the cylinder block is smaller than the diameter of the suction port. Since the guide groove is provided so that the suction port is formed on the inner surface of the suction guide groove, the roller can pass through the inlet end of the suction guide groove in a short time, thereby ensuring a longer refrigerant compression and suction time to ensure a refrigerant Compression performance is improved.

Description

Rotary compressors {ROTARY TYPE COMPRESSOR}

The present invention relates to a rotary compressor, and more particularly, to a rotary compressor having a cylinder block provided with a suction port so that the refrigerant is sucked into the compression chamber in which the refrigerant is compressed.

In general, the rotary compressor is a device used for the compression of the refrigerant is applied to the refrigeration cycle circuit.

Conventional rotary compressors include a driving device for generating a rotational force in a sealed container forming an external appearance, and a compression device for compressing a refrigerant by receiving a rotational force from the driving device.

The driving device includes a stator fixedly installed, a rotor rotating in interaction with the stator, and a rotating shaft having one end mounted on the rotor to transmit the rotational force generated by the driving device to the compression device, and the compression device includes a compression chamber. A cylinder block, an upper flange and a lower flange covering the upper and lower sides of the compression chamber, a roller which rotates eccentrically in the compression chamber by receiving rotational force from the driving device, and advances into the compression chamber so that the tip is supported by the roller. A vane is installed to be movable and partitions the inside of the compression chamber into a suction unit and a compression unit.

The cylinder block is provided with a vane installation groove in which the vane is moved forward and backward, and a suction port through which the refrigerant to be compressed in the compression chamber is sucked into the compression chamber, and a discharge port through which the compressed refrigerant is discharged from the compression chamber is provided in the upper flange. have.

However, in such a conventional rotary compressor, in order to allow the refrigerant to smoothly flow into the compression chamber, it is preferable to form a suction port having a sufficient diameter in the cylinder block, but the coolant while the roller passes through the area where the suction port is formed. Since the compression and suction of the refrigerant begins to occur after the roller passes through the suction port without compression and suction of the refrigerant, the suction of the refrigerant can be smoothly performed when the diameter of the suction port is increased. This shortens the problem that the refrigerant compression performance of the rotary compressor is lowered accordingly.

The present invention is to solve the problems of the prior art described above is an object of the present invention to provide a rotary compressor that can increase the refrigerant compression performance by securing a longer refrigerant compression and suction time.

The present invention for achieving the above object is a rotary compressor including a cylinder block provided with a compression chamber in which a refrigerant is compressed and a suction port for sucking the refrigerant into the compression chamber, the inner surface of the compression chamber of the cylinder block of the inlet end A suction guide groove having a width smaller than the diameter of the suction port is provided, and the suction port is formed on an inner surface of the suction guide groove.

In addition, the inlet side end of the suction guide groove is formed to have a rectangular shape extending in the vertical direction of the cylinder block so that the area of the inlet end of the suction guide groove is greater than the cross-sectional area of the suction port. .

In addition, the inlet side end of the suction guide groove is formed to have a rectangular shape extending in the vertical direction of the cylinder block so that the area of the inlet end of the suction guide groove is greater than the cross-sectional area of the suction port. .

In addition, the inlet of the suction guide groove connected to the compression chamber is formed to have a smaller width than the diameter of the suction port, the inner surface of the suction guide groove formed with the suction port is formed to have a width or more than the diameter of the suction port. It is done.

In addition, the suction guide groove is characterized in that the inlet end portion is formed in a trapezoidal shape that forms a short side and its inner surface forms a long side.

In addition, the cylinder block is provided with a vane installation groove in which a vane for partitioning the compression chamber is provided, and one side surface of the suction guide groove adjacent to the vane installation groove is parallel to the radial direction of the compression chamber. The other side surface of the suction guide groove is formed to be inclined with respect to the radial direction of the compression chamber.

As described above, the rotary compressor according to the present invention has a suction guide groove having a smaller width than the diameter of the suction port on the inner surface of the compression chamber of the cylinder block, so that the suction port is formed on the inner surface of the suction guide groove, so that the roller is the suction guide groove. It is possible to pass through the inlet end of the faster time, thereby ensuring a longer refrigerant compression and suction time has the effect of improving the refrigerant compression performance.

Hereinafter, one preferred embodiment of the present invention will be described in detail with reference to the drawings.

The rotary compressor according to the present invention is a device that is applied to the refrigeration cycle circuit used to compress the refrigerant, as shown in Figure 1, the drive device for generating a rotational force in the interior of the sealed container 10 to form an appearance (20) And a compression device 30 that compresses the refrigerant by receiving power from the driving device 20, and one side of the sealed container 10 is not evaporated by an evaporator (not shown) that is a component of the refrigeration cycle circuit. The accumulator 40 is installed to allow the refrigerant delivered in the liquid state to be introduced into the compression device 30 after being vaporized.

The upper side of the hermetic container 10 is connected to the discharge pipe 11 for discharging the refrigerant compressed therein, one end of the hermetic container 10 is connected to the accumulator 40, the refrigerant is compressed device The other end of the suction pipe 12 to be sucked into the 30 is connected.

The driving device 20 has a cylindrical stator 21 fixed to an inner surface of the hermetic container 10 and a rotor rotating in interaction with the stator 21 rotatably installed in the stator 21. 22 and one end is fixed to the rotor 22 and the other end is provided in the compression device 30 includes a rotating shaft 23 for transmitting the rotational force generated in the drive device 20 to the compression device (30).

The compression device 30 includes a cylinder block 31 provided with a compression chamber 31a for compression, an upper flange 32 and a lower flange 33 for closing the upper and lower portions of the compression chamber 31a, Arranged in the compression chamber 31a, the roller 34 receives the rotational force from the rotating shaft 23 to eccentrically rotate and compresses the refrigerant, and advances and retreats the compression chamber 31a so as to keep the tip supported by the roller 34. It is movable so that the compression chamber 31a includes the vane 35 which divides into the suction part which suction of a refrigerant | coolant, and the compression part which compresses a refrigerant | coolant. At this time, the eccentric part 23a is provided in the rotating shaft 23 so that the roller 34 may eccentrically rotate in the compression chamber 31a.

As shown in FIG. 2, the vane 35 is rotated in the cylinder block 31 by the vane installation groove 31b and the roller 34 of the vane installation groove 31b in which the vane 35 is installed to be moved forward and backward through the elastic member 36. It is provided on the rear side in the direction and is connected to the suction pipe 12 is provided with a suction port (31c) for sucking the refrigerant to be compressed in the compression chamber (31a), the upper flange 32, the roller 34 of the vane installation groove (31b) A discharge port 32a is provided at the front side in the rotational direction so that the refrigerant compressed in the compression chamber 31a can be discharged into the inner space of the sealed container 10.

In addition, the rotary compressor according to the present invention to the compression and suction of the refrigerant for a longer time to improve the refrigerant compression performance of the rotary compressor to the inner surface of the compression chamber (31a) of the cylinder block 31 to its inlet side A suction guide groove 31d having a width W of the end portion having a width relatively smaller than that of the suction port 31c is provided so that the suction port 31c is formed on the inner surface of the suction guide groove 31d.

The suction guide groove 31d is formed such that the width W of the inlet end connected to the compression chamber 31a is relatively smaller than the diameter D of the suction port 31c, and the suction guide groove 31c is formed. The width of the inner surface 31d is formed to be equal to or larger than the diameter D of the suction port 31c so that the suction port 31c can be formed.

At this time, the inlet end portion of the suction guide groove 31d is formed so that its area is equal to or greater than the cross-sectional area of the suction port 31c so that the amount of the refrigerant sucked through the suction port 31c can be maintained as it is. To this end, the inlet side end of the suction guide groove 31d is formed to have a substantially rectangular shape extending in the thickness direction of the cylinder block 31, that is, the vertical direction, as shown in FIG. 3, and the suction guide groove 31d. The area of the inlet side end portion of the inlet side is equal to or larger than the cross-sectional area of the suction port 31c, and thus the refrigerant suction into the compression chamber 31a through the suction guide groove 31d can be smoothly performed.

In this embodiment, the suction guide groove 31d is opened to the upper and lower sides of the cylinder block 31 so that the upper and lower sides are closed by the upper flange 32 and the lower flange 33, respectively, and the inlet end Is formed to have a width gradually increasing toward the inner surface, the inlet side end of the suction guide groove (31d) is formed in a trapezoidal shape that forms a short side and the inner surface of the suction guide groove (31d) makes a long side.

As described above, the rotary compressor which forms the suction guide groove 31d in the compression chamber 31a and allows the refrigerant delivered through the suction port 31c to be sucked into the compression chamber 31a through the suction guide groove 31d is roller. Since the compression of the refrigerant and the suction of the refrigerant proceed after the 34 passes through the inlet end of the suction guide groove 31d, the suction port 31c is formed directly on the inner surface of the compression chamber 31a so that the roller 34 Since the roller 34 passes through the inlet side end of the suction guide groove 31d within a relatively quick time compared to the time passing through the suction port 31c, the compression and suction of the refrigerant are started in a faster time and are longer. Compression and suction of the refrigerant may take place over time, thereby increasing the refrigerant compression performance of the rotary compressor.

1 is a longitudinal sectional view of a rotary compressor according to the present invention.

2 is a cross-sectional view of a rotary compressor according to the present invention.

3 is a perspective view of a cylinder block applied to a rotary compressor according to the present invention.

Explanation of symbols on the main parts of the drawings

10: sealed container 20: drive device

21: stator 22: rotor

23: rotating shaft 30: compression device

31: Cylinder block 31a: Compression chamber

31b: vane mounting groove 31c: suction port

31d: suction guide groove 32: upper flange

32a: discharge port 33: lower flange

34: roller 35: vane

36: elastic member

Claims (6)

In the rotary compressor comprising a cylinder block provided with a compression chamber in which a refrigerant is compressed and a suction port for allowing the refrigerant to be sucked into the compression chamber, And a suction guide groove having a smaller width at the inlet end of the cylinder block than the diameter of the suction port is formed on the inner surface of the suction guide groove. The method of claim 1, The inlet end of the suction guide groove is formed to have a rectangular shape extending in the vertical direction of the cylinder block so that the area of the inlet end of the suction guide groove is greater than the cross-sectional area of the suction port. . The method of claim 2, It is further provided with an upper flange and a lower flange installed on the upper and lower sides of the cylinder block covering the upper and lower sides of the compression chamber, The suction guide groove is open to the upper and lower sides of the cylinder block and the upper and lower sides of the rotary compressor characterized in that closed by the upper flange and the lower flange. The method of claim 1, The inlet of the suction guide groove connected to the compression chamber is formed to have a smaller width than the diameter of the suction port, and the inner surface of the suction guide groove in which the suction port is formed is formed to have a width greater than or equal to the diameter of the suction port. Rotary compressors. The method of claim 4, wherein The suction guide groove is a rotary compressor, characterized in that formed in a trapezoidal shape in which the inlet end portion forms a short side and an inner surface thereof forms a long side. The method of claim 5, wherein The cylinder block is provided with a vane installation groove in which vanes for partitioning the compression chamber are installed. One side surface of the suction guide groove adjacent to the vane installation groove is formed parallel to the radial direction of the compression chamber, and the other side surface of the suction guide groove is inclined with respect to the radial direction of the compression chamber. Rotary compressor.

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