KR100480128B1 - Apparatus for reducing friction loss of hermetic compressor - Google Patents

Abstract

The friction loss reduction device of the hermetic compressor is a cylinder assembly having an inner space such that the inlet and the discharge port communicate with each other, and inserted into the inner space of the cylinder assembly to move the fluid in the inner space in the compression direction while performing a relative rotational movement. One side surface is coupled to the cylinder assembly so as to be in close contact with the corrugated curved surface of the partition plate and to perform a relative linear movement along the corrugated curved surface of the partition plate in the axial direction. In the hermetic compressor comprising a vane for compressing by blocking the movement of the fluid, a buffer chamber recessed to have a predetermined space on the back surface of the partition plate in sliding contact with the cylinder assembly in the axial direction, the buffer chamber and The outside of the cylinder assembly is in communication with each other to pass a portion of the discharge gas to the buffer chamber By the configuration is provided with a communication hole for guiding the contact surface pressure between the thrust face and the cylinder assembly of the partition plate is reduced to one so that the friction loss due to friction can be reduced.

Description

Friction loss reduction device of hermetic compressor {APPARATUS FOR REDUCING FRICTION LOSS OF HERMETIC COMPRESSOR}

The present invention relates to an apparatus for reducing friction loss of a hermetic compressor. More specifically, the present invention relates to a pressure difference between an upper side and a lower side of the partition plate when driving the hermetic compressor having a partition plate having a curved surface formed only in one side of the upper side or the lower side. The present invention relates to a friction loss reducing device of a hermetic compressor which can reduce the friction loss caused by the compressor.

In general, a compressor is a machine for compressing a fluid. The configuration of such a compressor includes a hermetically sealed container having a predetermined internal space, an electric machine part mounted in the hermetically sealed container to generate a driving force, and a gas driven by the driving force of the electric machine part. Compressor section for compressing.

One of these compressors is a vane compressor, in which a vane is brought into close contact with a rotating body to rotate a partition plate while partitioning an inner space of a cylinder into a suction zone and a compression zone, thereby sucking fluid while continuously changing the suction zone and the compression zone. Compression discharge

1 is a longitudinal sectional view showing an example of a conventional vane-type hermetic compressor.

As shown in the drawing, a conventional vane hermetic compressor includes an electric mechanism part including a stator (Ms) and a rotor (Mr) installed so as to generate power in the upper portion of the casing (1), and a rotor under the electric mechanism part. It is composed of a compressor mechanism that is connected to (Mr) and is installed to suck and discharge the fluid.

1 and 2, the compression mechanism has an internal space for suction and compressing the refrigerant gas, and is fastened to the upper and lower surfaces of the cylinder 2 and the cylinder 2 fixed to the lower half of the casing 1, respectively. Combining the upper bearing 3A and the lower bearing 3B, which together form the cylinder assembly, with the rotor Mr of the power mechanism portion, and through the respective bearing plates 3A, 3B, compress the power of the power mechanism portion. A partition plate 5 which is formed in a sinusoidal wave shape for moving the refrigerant shaft sucked into the internal space of the cylinder 2 by being integrally molded or integrally formed with the rotary shaft 4 to be transmitted to the mechanism part; A vane 6 for axially contacting the curved surface of the plate 5 to partition the internal space V of the cylinder 2 into a suction zone and a compression zone, and a spring assembly 7 for elastically supporting the vane 6. ) Is included.

The cylinder 2 has a circular shape in which the partition plate 5 is rotatably coupled to form an inner space V for suction compression of the refrigerant gas, and on one side the inner space V on the outer circumferential surface of the cylinder 2. The suction port 2a is formed to penetrate the inner circumferential surface thereof to guide the suction gas into the inner space.

As shown in FIG. 2, the partition plate 5 is formed in a disc shape in a planar projection with respect to the rotation axis 4, and a convex surface portion r1 having a convex surface and a concave curved surface having a concave surface in one side projection. And a connecting curved portion r3 connecting the portion r2, the convex curved portion r1 and the concave curved portion r2. That is, one side of the partition plate 5 is composed of a sinusoidal wave shaped surface as a whole, and the convex curved portion r1 and the concave curved portion r2 are formed with a phase difference of 180 degrees, while the other side is formed in a plane.

In addition, when the partition plate 5 is radially cut at an arbitrary position about the rotation axis 4, the cutting line between the rotation axis 4 and the partition plate 4 always forms a right angle so that the convex surface portion r1 is formed. And the tip constituting the inflection point of the concave curved portion r2 is formed to form a closed space while sliding in contact with the inner surface of the upper or lower bearings 3A and 3B.

In the figure, 2b, which is not described, is a discharge port, 8 is a discharge muffler, and SP is a suction pipe.

The conventional compressor as described above operates as follows.

That is, when the rotor (Mr) is rotated by applying power to the electric mechanism, the rotating shaft (4) coupled to the rotor (Mr) transmits the rotational force to the partition plate (5) and any of the partition plate (5) together with the partition plate (5). Direction and the vane 6 in contact with the corrugated curved surface of the partition plate 5 reciprocates in the vertical direction along the height of the partition plate 5, the volume of the internal space (V) is variable, with the inside The new fluid was sucked into the space V and compressed, and then the compressed fluid was discharged through the discharge port 2b as soon as the top dead center of the partition plate 5 reached the discharge start point.

However, in the hermetic compressor having the conventional structure as described above, since only one of the upper and lower sides of the partition plate 5 is formed as a curved surface, as shown in FIG. The thickness difference is generated between the concave curved portion r2, and as a result, the vibration is increased by the eccentric mass generated toward the relatively thick convex curved portion r1 when the partition plate 5 rotates, and also shown in FIG. As the compression force F of the fluid sucked and compressed as described above acts only in one direction, the friction loss due to the friction between the upper bearing 3A and the partition plate thrust surface 5a is increased.

The object of the present invention devised in view of the above point is an eccentricity generated during operation by improving the structure of the compressor in which the fluid is sucked, compressed and discharged by the rotation of a partition plate having a curved surface formed on only one of the upper and lower sides. It is to provide a friction loss reduction device of a hermetic compressor to reduce the vibration and friction caused by the mass.

Friction loss reduction device of the hermetic compressor for achieving the object of the present invention as described above is a cylinder assembly having an inner space so that the inlet and the discharge port communicate with each other, the inner space of the cylinder assembly is inserted into the inner space while the relative rotational movement In order to move the fluid in the compression direction, the one side is formed in the corrugated curved surface, and the cylinder assembly to be in close contact with the corrugated curved surface of the partition plate in the axial direction along the corrugated curved surface of the partition plate. In a hermetic compressor having a vane coupled to and blocking a movement of a fluid moving by the partition plate, the closed compressor is provided to have a predetermined space on the rear surface of the partition plate in axial sliding contact with the cylinder assembly. Fidelity is formed, and the buffer chamber and the outside of the cylinder assembly communicate with each other. It is a partial section of the discharge gas with a communication hole is provided for guiding the thread buffer.

Hereinafter, the friction loss reduction apparatus of the hermetic compressor, which is an embodiment of the present invention, will be described in detail with reference to the accompanying drawings.

Figure 4 is a longitudinal sectional view showing the structure of the compression mechanism of the hermetic compressor equipped with a friction loss reducing device is an embodiment of the present invention, Figure 5 is a cross-sectional view showing a partial cross-sectional view of the partition plate shown in Figure 4, Figure 6 Is a perspective view of the partition plate shown in FIG. 4.

As shown, the compression mechanism of the hermetic compressor equipped with a friction loss reducing device according to an embodiment of the present invention is a cylinder assembly having a closed inner space (V) to suction and compress the fluid, and a rotating shaft for transmitting the rotational force of the electric mechanism ( 4) a partition plate 10 which is integrally or post-assembled to be integrally coupled to the inner space V of the cylinder assembly, and is inserted into and coupled to the cylinder assembly so as to press-contact the upper and lower sides of the partition plate 10 to the refrigerant. A vane 6 for compressing the gas.

The cylinder assembly forms an inner space (V) at the center and is coupled to the cylinder (2) having a suction port (2a) and the upper and lower sides of the cylinder (2) so as to communicate with one side of the inner space (V). The upper bearing 3A and the lower bearing 3B which form a V) and have a discharge port (not shown) so as to communicate with the above-mentioned inner space V, and support the rotating shaft 4 are formed.

The partition plate 10 has a circular shape substantially the same as the inner circumferential surface diameter of the cylinder 2 in planar projection, and one side of the partition plate forms a closed space in the inner space V of the cylinder 2 during side projection. While the inner surface of the bearing 3B is formed as a sinusoidal wave shaped curved surface 11 to be in line contact or partial surface contact, the other side is recessed to have a predetermined space and together with the cylinder 2 and the upper bearing 3A. A buffer chamber (C) is formed, and the buffer surface (12) is an axial negative pressure surface of the buffer chamber (C), and the buffer surface (12) of the partition plate (10) and the cylinder (2) and the upper bearing. A communication hole 13 penetrates through the upper bearing 3A so that the buffer chamber C formed by 3A communicates with the outside of the cylinder assembly.

The curved surface 11 has a convex surface portion r1 having a convex surface and a concave curved surface portion r2 having a concave surface, and a connecting curved portion connecting the convex surface portion r1 and the concave curved surface portion r2 ( r3).

As shown in FIGS. 5 and 6, the buffer surface 12 has a partition plate having the same volume as the compression chamber formed by the corrugated curved surface 11 and the cylinder assembly of the partition plate 10. 10) is formed so as not to be eccentric about the rotation axis 4 but to form a center of gravity. That is, the buffer surface 12 has the same shape symmetrical with the corrugated curved surface 11 formed on one side of the partition plate 10. However, the shock absorbing surface 12 does not need precision machining like the corrugated curved surface 11.

The operation process and the effects of the friction loss reduction device of the hermetic compressor configured as described above are as follows.

When the rotor (Mr) is rotated by applying power to the power mechanism, the partition plate (10) rotates in either direction while the rotating shaft (4) rotates together with the rotor (Mr) of the power mechanism portion, and with this compartment The vanes 6 in contact with the corrugated curved surface 11 of the plate 10 are moved back and forth in the axial direction along the corrugated curved surface 11 of the partition plate 10 to the internal space V of the cylinder 2. A series of processes of continuously sucking and compressing a refrigerant gas as a fluid and then discharging the refrigerant gas through the discharge port 2b is repeated.

In this case, the partition plate 10 is a curved surface 11 formed of a convex curved portion r1, a concave curved portion r2 and a connecting curved portion r3 on only one side (lower surface in the drawing) of the upper and lower sides of the partition plate (11) Is formed, the vane 6 is in close contact with the corrugated curved surface 11 to continuously suck, compress and discharge the refrigerant gas as a fluid, and a part of the compressed and discharged refrigerant gas is formed in the upper bearing 3A. The contact surface pressure between the upper bearing 3A and the partition plate thrust surface 5a is reduced by applying pressure to the buffer surface 12 of the partition plate 10 through the buffer chamber C through 13. . In addition, the buffer surface 12 is formed to be symmetrical with the corrugated curved surface 11, so that vibration caused by the eccentric mass during rotation is reduced.

Similarly, another embodiment of the present invention is recessed so as to have a predetermined space in the upper bearing (3A) of the cylinder assembly (3A) in axial sliding contact with the back surface of the corrugated curved surface (11) forming surface of the partition plate (10). The same effect can be obtained even when the buffer chamber is formed, and the buffer chamber and the outside of the cylinder assembly communicate with each other, and a communication hole for guiding a part of the discharge gas into the buffer chamber is provided.

Thus, the friction loss reduction device of the hermetic compressor according to the present invention forms a buffer surface 12 symmetrical with the corrugated curved surface 11 on the other side of the partition plate 10 formed with a corrugated curved surface 11 on one side. A portion of the refrigerant gas discharged into the buffer chamber C partitioned by the buffer surface 12 and the cylinder assembly through the communication hole 13 is introduced to the upper bearing 3A and the partition plate thrust surface 5a. By reducing the contact surface pressure of the liver, friction loss due to friction is reduced.

As described above, the apparatus for reducing frictional loss of the hermetic compressor according to the present invention is symmetrical with the corrugated curved surface on the other side of the partition plate in which the corrugated curved surface is formed so as to partition and rotate the inner space of the cylinder assembly and suck, compress and discharge the refrigerant. By forming a buffer surface to form a portion, the contact surface pressure between the upper bearing and the partition plate thrust surface is reduced by introducing a portion of the refrigerant gas which is the fluid discharged into the buffer chamber partitioned by the buffer surface and the cylinder assembly through the communication hole, There is an effect that the friction loss due to friction is reduced.

In addition, the buffer surface is formed to be symmetrical with the corrugated curved surface to reduce the vibration caused by the eccentric mass during rotation has the effect of improving the reliability of the compressor.

1 is a longitudinal sectional view showing a compression mechanism of a hermetic compressor having a conventional structure;

2 and 3 are a cross-sectional view and a perspective view partially showing the partition plate shown in FIG.

Figure 4 is a longitudinal cross-sectional view showing the structure of the compression mechanism of the hermetic compressor equipped with a friction loss reducing device of an embodiment of the present invention,

5 is a cross-sectional view partially showing the partition plate shown in FIG. 4;

FIG. 6 is a perspective view of the partition plate shown in FIG. 4. FIG.

** Description of the symbols for the main parts of the drawings **

10: partition plate 11: waveform surface

12: buffer surface 13: communication hole

C: buffer room

Claims (5)

A cylinder assembly having an inner space so that the inlet port and the outlet port communicate with each other, and a partition plate having one side formed with a corrugated curved surface to move the fluid in the inner space in the compression direction while being inserted into the inner space of the cylinder assembly and moving in relative rotation; A vane coupled to the cylinder assembly to be in close contact with the corrugated curved surface of the partition plate and to perform relative linear movement in the axial direction along the corrugated curved surface of the partition plate to block and compress the movement of the fluid moved by the partition plate. In the sealed compressor provided, A buffer chamber recessed to have a predetermined space is formed in the cylinder assembly in axial sliding contact on the rear surface of the partition plate, and the buffer chamber and the outside of the cylinder assembly communicate with each other to guide a part of the discharge gas into the buffer chamber. Friction loss reduction device of the hermetic compressor, characterized in that the communication hole is provided. A cylinder assembly having an inner space so that the inlet port and the outlet port communicate with each other, and a partition plate having one side formed with a corrugated curved surface to move the fluid in the inner space in the compression direction while being inserted into the inner space of the cylinder assembly and moving in relative rotation; A vane coupled to the cylinder assembly to be in close contact with the corrugated curved surface of the partition plate and to perform relative linear movement in the axial direction along the corrugated curved surface of the partition plate to block and compress the movement of the fluid moved by the partition plate. In the sealed compressor provided, A buffer chamber recessed to have a predetermined space is formed on the rear surface of the partition plate in sliding contact with the cylinder assembly in the axial direction, and the buffer chamber and the outside of the cylinder assembly communicate with each other to guide a part of the discharge gas into the buffer chamber. Friction loss reduction device of the hermetic compressor, characterized in that the communication hole is provided. The apparatus of claim 1 or 2, wherein the buffer chamber has the same volume as the compression chamber formed by the corrugated curved surface and the cylinder assembly of the partition plate. The apparatus of claim 2, wherein the axial negative pressure surface of the buffer chamber has the same shape to be symmetrical with a corrugated curved surface formed on one side of the partition plate. The apparatus of claim 1 or 2, wherein the communication hole penetrates the cylinder assembly in parallel with the axial direction.