KR20040006668A - Structure of compressor - Google Patents

Abstract

PURPOSE: A structure of a compressor is provided to securely fix the compressor by improving mounting positions of a compression mechanism part and an electromotive mechanism part mounted in a hermetic container of the compressor. CONSTITUTION: A structure includes a hermetic container having one side coupled to a base plate to be fixed thereto, and forming an inner storage space; an electromotive mechanism part(M) mounted to a base plate coupling part, a lower side of the inner storage space formed in the hermetic container, to generate rotary force; and a compression mechanism part mounted to an upper side of the inner storage space formed in the hermetic space opposite to the base plate coupling part, and receiving driving of the electromotive mechanism part to introduce, compress and discharge gas. The compression mechanism part includes a rotary shaft interlocked with the electromotive mechanism part to rotate, and having a wavy partition placed on one side thereof; and a cylinder assembly(D) including a cylinder(230) mounted to the upper side of the hermetic container opposite to the base plate coupling part, and an upper bearing(240) and a lower bearing(250) inserted to an upper side and a lower side of the cylinder so that the inner space is partitioned by the partition.

Description

Compressor Structure {STRUCTURE OF COMPRESSOR}

The present invention relates to a structure of a compressor, and more particularly, to a structure of a compressor that achieves a stable internal structure by improving a mounting position of an electric mechanism part and a compression mechanism part mounted in an inner receiving space of a sealed container.

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.

Such compressors are generally classified into various types such as a rotary compressor, a rotary compressor, a scroll compressor, and the like according to a shape of a compression mechanism for compressing gas.

1 to 3 illustrate one of the compressors as an example, and as shown, the compression mechanism of the compressor having a conventional structure includes an internal space V and an internal space V thereof. A suction passage f1 and a discharge passage f2 communicating with each other, the center of which is located in the inner space V of the cylinder assembly D fixedly coupled to the hermetically sealed container 10 mounted on the base plate 1. A rotating shaft 20 is inserted to penetrate the rotating shaft 20, and the rotating shaft 20 is coupled to an electric mechanism part M generating a driving force required for rotation.

The cylinder assembly (D) is provided with a cylindrical through hole therein, the outer circumferential surface is welded to the sealed container 10 and fixed to the cylinder 30 and the upper and lower surfaces of the cylinder 30 are respectively coupled to the In addition to forming the inner space (V) with the cylinder 30 and includes an upper bearing 40 and a lower bearing 50 for supporting the rotating shaft 20, the cylinder 30 is the cylinder ( A suction flow path f1 radially penetrated toward the outer circumferential surface is formed in the internal space V of 30.

The upper bearing 40 and the lower bearing 50 protrude to have plate portions 41 and 51 formed to have a predetermined thickness and area, and have a predetermined height and outer diameter on one surface of the plate portions 41 and 51. And the support portions 42 and 52 formed therein, and the shaft insertion holes 43 and 53 formed through the central portions of the plate portions 41 and 51 and the support portions 42 and 52, respectively. The plate portion 41 of the 40 covers one side of the cylinder 30 and is coupled to the shaft insertion hole 43 so that the rotation shaft 20 is interpolated, and the lower bearing 50 is The other side of the cylinder 30 is covered, and the rotation shaft 20 is coupled to the insertion hole 53 so as to be interpolated.

The rotating shaft 20 is formed to have a predetermined outer diameter and a predetermined length is inserted into the shaft insertion hole (43. 53) of the upper bearing 40 and the lower bearing 50, and the shaft portion 21 A partition plate 22 extending from one side thereof and partitioning the internal space V of the cylinder assembly D into the first space V1 and the second space V2 is provided.

The partition plate 22 of the rotating shaft 20 has a predetermined thickness, and is formed in a circular shape when viewed on a plane, and when viewed from the side, an upper convex curved portion r1 having a convex surface and a lower side having a concave surface. It consists of a concave curved surface part r2, and the connection curved surface part r3 which connects the convex curved surface part r1 and the concave curved surface part r2. That is, the partition plate 22 forms a sinusoidal waveform surface, and the convex curved portion r1 and the concave curved portion r2 are formed to have a phase difference of 180 degrees.

In addition, the first and second spaces V1a and V2a are respectively elastically supported to be in contact with both side surfaces of the partition plate 22 so that the partition plate 22 rotates. ) And the vanes 70 moving in parallel to the longitudinal direction of the rotation shaft 20 while switching to the compression zones V1b and V2b are respectively provided on the upper bearing 40 and the lower bearing 50 of the cylinder assembly D. FIG. Inserted through and combined.

The vanes 70 are supported by an elastic support means 100 that elastically supports the vanes 70 at the center of the other side surface 72, which is the rear surface of the side surface 71, which is in contact with the partition plate. 73 is formed to be coupled so that the cylinder assembly (D) is located in the same phase when viewed in a horizontal plane, that is, above and below the partition plate 22 and the vanes (70) are the upper bearing 40 of the cylinder assembly (D) ) And vane slots 44 and 54 formed in the lower bearing 50, respectively.

Then, the opening and closing for discharging the compressed gas in the compression zone (V1b, V2b) of the first space (V1) and the second space (V2) while opening and closing each discharge passage (f2) formed in the cylinder assembly (D), respectively. The means 80 are coupled, and the suction pipe 90 is coupled to the hermetic container 10 so as to communicate with the suction passage f1.

Reference numeral 110 is a silencer.

When the rotary shaft 20 is rotated by receiving the driving force of the power mechanism (M) operated by the power is applied, the partition plate 22 formed on one side of the rotary shaft 20 is the inside of the cylinder assembly (D). It is rotated in the space (V).

As shown in FIGS. 3 and 4, the vanes 70 of which the front end of the convex curved portion r1 of the partition plate 22 is positioned in the first space V1 and the second space V2 are respectively located. In the first position V1, the discharge of the compressed gas filled in the compression region V1b is completed and the suction of the suction region V1a is completed. In the second space V2, the gas is sucked into the suction region V2a and the gas is compressed in the compression region V2b.

Next, the partition plate 22 is rotated so that the front end of the concave curved portion r2 of the partition plate 22 is the first space V1 and the second space V2. When the vanes 70 are positioned at the positions a1 of the vanes 70, the gas is sucked into the suction region V1a in the first space V1 and the gas is compressed in the compression region V1b. In the second space V2, the discharge of the compressed gas filled in the compression region V2b is completed and the suction of the suction region V2a is completed.

As such, each time the partition plate 22 rotates in the inner space V of the cylinder assembly D, the gas is sucked, compressed, and discharged in the first space V1 and the second space V2, respectively. The operation is performed repeatedly.

However, a compressor having a conventional structure having a structure in which a cylinder assembly (D) is mounted on the base plate (1) engaging portion side, which is the lower side of the hermetic container (10), and an electric mechanism (M) is mounted on the upper side thereof. Since the heavy electric power unit (M) is mounted on the upper side of the hermetic container (10) mounted on the base plate (1), the center of gravity is located on the upper side there is a problem that the compressor is unstable.

An object of the present invention devised in view of the above problems is to provide a structure of a compressor for stably fixing the compressor by improving the mounting position of the compression mechanism and the electric mechanism mounted inside the sealed container of the compressor.

1 is a longitudinal sectional view showing a compression mechanism of a typical compressor;

2 is a plan view showing the compression mechanism of the compressor shown in FIG.

3 is a perspective view partially showing a compression mechanism of the compressor shown in FIG. 1;

4 and 5 are a plan view showing a process of operating the compression mechanism of the compressor shown in FIG.

Figure 6 is a longitudinal sectional view showing the internal structure of a cylinder which is an embodiment of the present invention.

7 is a plan view showing the compression mechanism of the compressor shown in FIG.

8 is a perspective view partially showing a compression mechanism of the compressor shown in FIG. 6;

9 and 10 are a plan view showing a process of operating the compression mechanism of the compressor shown in FIG.

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

201: base plate 210: airtight container

M: Electric drive part D: Cylinder assembly

The structure of the compressor for achieving the object of the present invention as described above is fixed to the base plate is coupled to one side, the inner container to form an inner receiving space, the base plate which is the lower side of the inner receiving space formed in the sealed container It is mounted on the coupling part side to generate a rotational force and the other side of the base plate coupling part that is the upper side of the inner receiving space formed in the sealed container is received by the drive of the power mechanism to suck the gas, compress and discharge Compressor mechanism is provided.

In addition, the compressor mechanism is rotated in conjunction with the transmission mechanism, the rotating shaft is provided with a partition plate of the corrugated shape on one side, and the upper bearing and the lower bearing on both sides of the cylinder mounted on the other side of the base plate coupling portion that is the upper side of the sealed container And a cylinder assembly inserted into the compartment and partitioning the internal space by the partition plate.

Hereinafter, the structure of a compressor which is an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

6 is a longitudinal cross-sectional view showing the internal structure of a compressor which is an embodiment of the present invention, Figure 7 is a plan view showing the compression mechanism of the compressor shown in Figure 6, Figure 8 is a compression mechanism of the compressor shown in Figure 6 Is a perspective view showing a partial cross section.

As shown in the compressor according to the present invention, one side portion of the compressor is fixed to the base plate 201 and forms an inner receiving space, and a lower side of the inner receiving space formed in the closed container 210. Is mounted on the base plate coupling part side to generate a rotational force, and is mounted on the other side of the base plate coupling part which is an upper side of the inner receiving space formed in the airtight container 210 of the power mechanism part M. Compressor mechanisms for receiving, driving, compressing and discharging the gas received from the drive are provided.

The compressor mechanism is rotated in conjunction with the transmission mechanism (M) and the rotating shaft 210 is provided with a partition plate 222 of the wave shape on one side, and the base plate coupling portion on the other side of the upper side of the sealed container 210 Comprising a cylinder assembly (D) is inserted into the upper bearing 240 and the lower bearing 250 on both sides of the cylinder 230 to be mounted so that the internal space is partitioned by the partition plate 222.

The cylinder assembly (D) is provided with a cylindrical through-hole therein, the outer circumferential surface is welded to the sealed container 210 and fixed to the cylinder 230 and the upper and lower surfaces of the cylinder 230, respectively, In addition to forming the inner space (V) with the cylinder 230 and includes an upper bearing 240 and a lower bearing 250 for supporting the rotating shaft 220, the cylinder 230 is the cylinder ( A suction flow path f1 radially penetrated toward the outer circumferential surface of the inner space V of the 230 is formed.

The upper bearing 240 and the lower bearing 250 protrude to have plate portions 241 and 251 formed to have a predetermined thickness and area, and to have a predetermined height and outer diameter on one surface of the plate portions 241 and 251. And the support portions 242 and 252 formed therein, and the shaft insertion holes 243 and 253 formed through the central portions of the plate portions 241 and 251 and the support portions 242 and 252. The plate part 241 of the 240 covers the one side surface of the cylinder 230, and the rotation shaft 220 is coupled to the shaft insertion hole 243 so as to be interpolated, and the lower bearing 250 is The other side of the cylinder 230 is covered, and the rotation shaft 220 is coupled to the insertion hole 253 to be interpolated.

The rotating shaft 220 is formed to have a predetermined outer diameter and a predetermined length and is inserted into the shaft insertion holes 243 and 253 of the upper bearing 240 and the lower bearing 250, and the shaft portion 221. A partition plate 222 extending from one side thereof and partitioning the internal space V of the cylinder assembly D into the first space V1 and the second space V2 is provided.

The partition plate 222 of the rotation shaft 220 has a predetermined thickness, and is formed in a circular shape when viewed on a plane, and when viewed from the side, an upper convex curved portion r1 having a convex surface and a lower side having a concave surface. It consists of a concave curved surface part r2, and the connection curved surface part r3 which connects the convex curved surface part r1 and the concave curved surface part r2. That is, the partition plate 222 forms a sinusoidal waveform surface, and the convex curved portion r1 and the concave curved portion r2 are formed to have a phase difference of 180 degrees.

In addition, the first and second spaces V1 and V2 are respectively supported by elastically supported to be in contact with both sides of the partition plate 222 so that the partition plate 222 rotates. ) And the vanes 270 moving in parallel to the longitudinal direction of the rotation shaft 220 while switching to the compression zones V1b and V2b are respectively provided on the upper bearing 240 and the lower bearing 250 of the cylinder assembly D. FIG. Inserted through and combined.

The vanes 270 are supported by an elastic support means 300 that elastically supports the vanes 270 at a central portion of the other side 272, which is a rear surface of one side 271 that is in contact with the partition plate. 273 is formed to be coupled to the same phase when the cylinder assembly (D) is viewed in a horizontal plane, i.e., above and below the partition plate (222) and the vanes (270) are the upper bearing 240 of the cylinder assembly (D). ) And vane slots 244 and 254 formed in the lower bearing 250, respectively.

Then, the opening and closing for discharging the compressed gas in the compression zone (V1b, V2b) of the first space (V1) and the second space (V2) while opening and closing each discharge passage (f2) formed in the cylinder assembly (D), respectively. The means 280 is coupled, the suction tube 290 is coupled to the airtight passage (f1) to the airtight container 210 is coupled, compressed to the top of the airtight container 210, the other side of the base plate coupling portion A discharge tube 291 through which gas is discharged is formed.

Unexplained reference numeral 310 is a silencer.

Compressor constituting the structure of the compressor as an embodiment of the present invention configured as described above is applied to the electric mechanism unit (M) mounted on the base plate engaging side of the lower side of the receiving space inside the hermetic container 210 to rotate the torque It is generated, the rotational force is transmitted to the compression mechanism mounted on the upper side of the receiving space inside the sealed container 210 is operated in the process of sucking, compressing and discharging the gas, as described in more detail as follows.

When the rotary shaft 220 is rotated by receiving the driving force of the power mechanism (M) operated by the power is applied, the partition plate 222 formed on one side of the rotary shaft 220 is the inside of the cylinder assembly (D). It is rotated in the space (V).

As shown in FIGS. 8 and 9, the vanes 270 having the front end of the convex curved portion r1 of the partition plate 222 are respectively located in the first space V1 and the second space V2. In the first position V1, the discharge of the compressed gas filled in the compression region V1b is completed and the suction of the suction region V1a is completed. In the second space V2, the gas is sucked into the suction region V2a and the gas is compressed in the compression region V2b.

Next, the partition plate 222 is rotated, so that the front end of the concave curved portion r2 of the partition plate 222 is the first space (V1) and the second space (V2). When the gas is positioned at the positions a1 of the vanes 270, respectively, the gas is sucked into the suction region V1a and the gas is compressed in the compression region V1b. In the second space V2, the discharge of the compressed gas filled in the compression region V2b is completed and the suction of the suction region V2a is completed.

As the partition plate 222 rotates once in the cylinder assembly D internal space V, gas is sucked, compressed and discharged in the first space V1 and the second space V2, respectively. The operation is performed repeatedly.

As described above, the compressor according to the present invention has a structure in which the heavy electric power unit M is mounted on the lower side of the sealed container 210 and the cylinder assembly D, which is a compression mechanism, is mounted on the upper side thereof. The center of gravity is formed on the lower side in the direction in which the base plate 201 is coupled, so that the compressor is stably mounted.

In addition, the transmission mechanism (M) is mounted on the lower side, the discharge pipe 291 is formed on the uppermost side of the sealed container 210 to lubricate the inside of the sealed container through the discharge pipe 291 Outflow to the outside is reduced.

As described above, the structure of the compressor according to the present invention includes a structure in which a heavy electric machine part is mounted on the base plate coupling part, which is a lower side of the hermetically sealed container, and a cylinder assembly, which is a compression mechanism, is mounted on an upper side thereof. Compared with the conventional structure located above the upper side, the center of gravity is formed at the bottom, so that the compressor is stably mounted, thereby improving safety.

In addition, the transmission mechanism is mounted on the lower side, the discharge pipe for discharging the compressed gas to the outside is formed on the uppermost side of the sealed container so that the oil lubricating the inside of the sealed container flows out through the discharge pipe to the outside. There is an effect of reducing.

Claims (3)

One side of the base plate is coupled and fixed, and the airtight container to form an inner receiving space, An electric mechanism part mounted on the base plate coupling part, which is a lower side of the inner accommodating space formed in the airtight container, to generate rotational force; The compressor is characterized in that the compressor is provided on the other side of the base plate engaging portion formed on the inner side of the sealed container is provided with a compression mechanism for sucking, compressing and discharging the gas by receiving the drive of the power mechanism. rescue. According to claim 1, wherein the compression mechanism unit is rotated in conjunction with the transmission mechanism and the rotating shaft provided with a partition plate of the wave shape on one side, Characterized in that the cylinder assembly which is inserted through the upper bearing and the lower bearing on both sides of the cylinder which is mounted on the other side of the base plate coupling portion that is the upper side of the sealed container is partitioned by the partition plate is provided Structure of the compressor. The compressor structure according to claim 1 or 2, wherein a discharge pipe through which compressed gas is discharged is formed on the uppermost side of the sealed container, which is the other side of the base plate coupling portion.