KR100266618B1 - Drive motor cooling structure of turbo compressor - Google Patents

Abstract

The present invention relates to a drive motor cooling structure of a turbocompressor, and the present invention provides cooling to be branched toward each fixed disc in a drive shaft from a first impeller of a turbocompressor to a position where a plurality of fixed discs constituting a stator are installed. Since the flow path is formed, the refrigerant coil can be directly supplied to the winding coil coupled to the fixed disk to cool the winding coil efficiently, thereby improving the performance of the driving motor, and also securing the stability of the device to increase the overall efficiency. Will be.

Description

Drive motor cooling structure of turbo compressor

The present invention relates to a cooling structure of a drive motor of a turbo compressor, and more particularly, to supply sufficient refrigerant gas directly to a winding coil coupled to a fixed disk constituting a stator of a drive motor mounted in a motor compartment of a turbo compressor. It is to be cooled by.

In general, a compressor is a device for compressing a gas such as air or refrigerant gas, and the compressor is a power generating unit for generating large power and a compression mechanism unit for sucking and compressing gas by a driving force transmitted from the power generating unit. The compressor is divided into a hermetic compressor provided together with a power generating section and a compression mechanism section in a sealed container having a predetermined internal volume, and a separate compressor having the power generating section and the compression mechanism section separated.

The hermetic compressor includes a rotary compressor (also called a rotary compressor), a reciprocating compressor, and a scroll compressor due to the structure of compressing the gas. Expression

In the volumetric compressor, the rotary compressor is configured to pressurize the gas as the eccentric shaft rotates inside the cylinder in which the cylindrical space is formed, thereby reducing the volume of the internal space. The reciprocating compressor has a piston in the cylinder. It is a structure that pressurizes the gas as the volume of the inner space is reduced while reciprocating, and the scroll compressor reduces the inner space volume while the upper and lower scrolls having the involute curved wrap are engaged with each other to rotate. Therefore, the gas is pressurized.

The rotary compressor and the reciprocating compressor generate periodic vibration and noise in the process of periodically pressurizing the gas and have low efficiency, while the manufacturing cost is low, and the scroll compressor has vibration and noise in the process of continuously pressurizing the gas. High efficiency, high number of parts used, high manufacturing cost, high volume refrigerant volume, relatively large volume, and relatively heavy weight for home appliances such as refrigerators and air conditioners. When applied, not only the size of the applied home appliances is large, but also the weight is heavy, making it difficult to handle.

On the other hand, as a device for compressing a gas by rotating a vane, a turbo compressor having a high compression efficiency for compressing gas has been proposed. Is a longitudinal sectional view showing a conventional turbo compressor, and as shown in the figure, a turbo compressor has a first compression chamber 3 having an inlet port 2 and a second compression chamber 5 having a discharge port 4 on both sides. The gas passage 9 is formed to form a motor chamber (7) in the center and communicate with the first compression chamber (3) and the second compression chamber (5) and communicate with the motor chamber (7). And a drive motor 6a attached to the motor chamber 7 to generate a driving force.

In addition, one end is inserted into the first compression chamber (3), the other end is inserted into the second compression chamber (5) and coupled to the drive motor (6a) drive shaft for transmitting the driving force of the drive motor (6a) 8a and a second compression through the gas flow path 9 by first compressing the gas flowing into the suction port 2 coupled to one end of the drive shaft 8a so as to be rotatable in the first compression chamber 3. The first impeller 10 which flows into the chamber 5 and the other end of the drive shaft 8a to be rotatable in the second compression chamber 5 are first compressed to flow into the second compression chamber 5. And a second impeller 11 for secondaryly compressing the gas to be discharged to the discharge port 4.

A thrust bearing 21 for supporting the drive shaft 8a in the axial direction is coupled to both sides of the drive shaft 8a, and a radial bearing for supporting the drive shaft 8a in the radial direction at the center of the drive shaft 8a. 17 are respectively engaged to be located at both sides of the drive motor 6a.

Reference numeral 15 denotes an accumulator.

Referring to the operation of the conventional turbo compressor as described above is as follows.

First, when a current is applied to the drive motor 6a, the drive motor 6a operates and the driving force of the drive motor 6a is transmitted to the drive shaft 8a so that the drive shaft 8a rotates, and at the same time, the drive shaft ( The first impeller 10 and the second impeller 11 coupled to both ends of the drive shaft 8a are rotated by the rotation of 8a.

At the same time, the refrigerant gas, which has passed through the accumulator 15 by the rotational force of the first impeller 10 and the second impeller 11, flows into the first compression chamber 3 through the suction port 2 and is first compressed. The first compressed refrigerant gas is introduced into the second compression chamber 5 through the gas flow path 9, and the first compressed refrigerant gas introduced into the second compression chamber 5 is the second compression chamber. The secondary compression in (5) is carried out and discharged through the discharge port 4, and the secondary compressed and discharged refrigerant gas flows into a condenser (not shown) constituting a refrigeration / air conditioning cycle.

At this time, most of the primary compressed refrigerant gas is introduced into the second compression chamber 5 through the gas flow path 9, while the primary compressed partial refrigerant gas is used to cool the driving motor 6a. The inlet hole 16 of the upper side of the motor chamber 7, the hole 18 of the radial bearing 17, the hole 22 of the rotating disk 19a constituting the drive motor 6a, and the fixed disk ( 12) while passing through the through hole 18 of the radial bearing 17 is introduced into the second compression chamber 5 through the gas passage 9 through the outflow hole 20 on the other side of the upper side of the motor chamber 7. Accordingly, the drive motor 6a is cooled.

Meanwhile, as illustrated in FIGS. 2 and 3, the drive motor 6a generating the driving force in the turbo compressor has a fixed disk having a predetermined thickness and a plurality of winding coils 13 wound in an annular shape. The fixed disk 12 is a stator composed of a plurality of fixedly coupled to the interior of the motor chamber 7 at predetermined intervals, and a rotating disk 19a having a predetermined thickness and coupled to the plurality of magnets 23 therein. It comprises a rotor which is alternately inserted between the (12) and formed integrally with the drive shaft (8a).

The fixed disk 12 constituting the stator, as shown in Figure 4, is formed in a circular shape having a predetermined thickness, the through-hole 24 is formed to be inserted into the drive shaft (8a) in the center, A plurality of winding coils 13 in which a coil is wound in a circular shape are coupled to each other, and the winding coil 13 is formed by winding a coil in a plurality of times in a circle, and the fixed disk 12 is made of plastic, but a glue ) Made of material.

Rotating disk 19a constituting the rotor, as shown in Figure 5, is formed in a circular shape having a predetermined thickness, a plurality of magnets 23 having a predetermined shape therein is radially inserted and coupled And the whole magnet 23 is formed in a fan shape, the rotating disk 19a is formed integrally with the drive shaft 8a, it is made of aluminum material.

When the drive motor 6a as described above applies a current to the winding coil 13, a flux is formed inside the winding coil 13, and the flux and the magnet 23 of the winding coil 13 are formed. The rotating disk 19a rotates under the rotational force by the interaction force of the magnetic force, thereby rotating the drive shaft 8a, and at the same time, the first and second impellers 10 and 11 coupled to both ends of the drive shaft 8a rotate. At the same time, the refrigerant gas is sucked from the first and second compression chambers 3 and 5 to be compressed first and second.

The drive motor 6a has a rotor composed of the rotating disk 19a and a stator composed of the fixed disk 12 arranged in the axial direction to enable high-speed rotation, and the fixed disk 12 and the rotating disk 19a The output can be generated in proportion to the number.

However, such a conventional turbo compressor is formed by forming a plurality of through holes 22 on the outer periphery of the center of the rotating disk 19a constituting the rotor of the drive motor 6a to form a stator of the drive motor 6a. Refrigerant gas for cooling the winding coil 13 is supplied to the winding coil 13 coupled to the disk 12 through the through hole 22 during the operation of the compressor, taking into account the rigidity of the rotating disk 19a. Since the through-hole 22 cannot be largely formed, a sufficient amount of refrigerant gas for cooling does not flow into the smooth state through the through-hole 22, and the rotating disk 19a rotates at high speed during operation. It is difficult to supply the refrigerant gas at a stable flow rate to the through holes 22 formed in the vicinity thereof, and thus it is impossible to perform an efficient cooling function, and the structure of the rotating disk 19a prevents the flow of the refrigerant gas through the through holes 22. There were many problems such as becoming.

Accordingly, the present invention is to solve the above-mentioned problems, by supplying a sufficient amount of refrigerant gas directly to the winding coil coupled to the fixed disk constituting the stator of the drive motor mounted in the motor compartment of the turbo compressor can be efficiently cooled The purpose of the present invention is not only to improve the performance of the drive motor, but also to provide a drive motor cooling structure of a turbo compressor that can increase the overall efficiency by securing the stability of the device.

1 is a longitudinal sectional view showing a conventional turbo compressor.

2 is an enlarged view of the driving motor of FIG.

3 is a perspective view of the driving motor of FIG.

4 is a front view of the fixing disk of FIG.

5 is a front view of the rotating disk of FIG.

6 is a longitudinal sectional view of a turbo compressor according to the present invention;

Explanation of symbols on the main parts of the drawings

8; Drive shaft 10; First impeller

12; Fixed disk 13; Winding coil

14; Cooling flow path

In order to achieve the above object, the present invention is a stator having a predetermined thickness and a fixed disk having a plurality of winding coils wound in an annular shape are fixedly coupled to the inside of the motor chamber at predetermined intervals, In a drive motor of a turbo compressor comprising a rotor having a thickness of and a rotating disk having a plurality of magnets coupled therein are inserted alternately between the fixed disk and integrally formed with a drive shaft, wherein the inside of the drive shaft It is achieved by providing a drive motor cooling structure of a turbocompressor, characterized in that a cooling passage for supplying a refrigerant gas to the winding coils coupled to the respective fixed disks is branched toward each fixed disk. do.

Here, the cooling passage is characterized in that the branch formed in the drive shaft from the first impeller to the position where the plurality of fixed disks constituting the stator is installed.

In addition, the cooling passage is characterized in that the branch formed in the drive shaft from the second impeller to the position where a plurality of fixed disks constituting the stator is installed.

Therefore, according to the present invention, a cooling flow path is formed so as to branch toward each fixed disk in the drive shaft from the first impeller of the turbocompressor to a position where a plurality of fixed disks constituting the stator are installed, thereby being coupled to the fixed disk. By supplying the refrigerant gas directly to the winding coil, which effectively cools the winding coil, the performance of the driving motor can be improved.

Hereinafter, preferred embodiments of the present invention for achieving the above object will be described in detail with reference to the accompanying drawings.

6 is a longitudinal sectional view showing a turbo compressor according to the present invention, in which the same parts as in the prior art are denoted by the same reference numerals to describe the present invention.

According to the present invention, a first compression chamber 3 having a suction port 2 and a second compression chamber 5 having a discharge port 4 are formed on both sides of a sealed container 1 of a turbo compressor, respectively. Both ends of the first and second compression chambers 3 and 5 are inserted into the center of the motor chamber 7 in which the drive motor 6 is mounted in (1) and coupled to the drive motor 6 to receive the driving force. A rotating drive shaft 8 is installed, and a second compression is performed through a gas flow path 9 formed at an upper portion of the airtight container 1 by first compressing a gas flowing into the inlet 1 at one end of the drive shaft 8. The first impeller 10 flowing into the chamber 5 is rotatably coupled in the first compression chamber 3, and the other end of the drive shaft 8 is first compressed to flow into the second compression chamber 5. The second impeller 11 which secondaryly compresses the gas and discharges it to the discharge port 4 is rotatably installed in the second compression chamber 5.

In addition, a winding coil 13 coupled to each of the fixed disks 12 in the drive shaft 8 from the first impeller 10 to a position where a plurality of fixed disks 12 constituting the stator are installed. A cooling passage 14 for supplying a refrigerant gas to the cooling coil 13 to cool the winding coil 13 is configured to be branched toward each of the fixed disks 12.

In the present invention configured as described above, as shown in FIG. 6, when a current is applied to the drive motor 6 during the operation of the turbo compressor, the drive motor 6 is operated and the driving force of the drive motor 6 is increased. The first impeller 10 and the second impeller 11 coupled to both ends of the drive shaft 8 by the rotation of the drive shaft 8 while being transmitted to the drive shaft 8 to rotate the drive shaft 8, respectively. Done.

At the same time, the refrigerant gas, which has passed through the accumulator 15 by the rotational force of the first impeller 10 and the second impeller 11, flows into the first compression chamber 3 through the suction port 2 and is first compressed. The first compressed refrigerant gas is introduced into the second compression chamber 5 through the gas flow path 9, and the first compressed refrigerant gas introduced into the second compression chamber 5 is the second compression chamber. The secondary compression in (5) is carried out and discharged through the discharge port 4, and the secondary compressed and discharged refrigerant gas flows into the condenser constituting the refrigerating / air conditioning cycle.

At this time, most of the primary compressed refrigerant gas is introduced into the second compression chamber 5 through the gas flow path 9, while the primary compressed partial refrigerant gas is used to cool the driving motor 6. The inlet hole 16 on one side of the upper side of the motor chamber 7, the hole 18 of the radial bearing 17, the rotating disk 19 constituting the drive motor 6, the fixed disk 12, and the radial body. The driving motor 6 is introduced into the second compression chamber 5 through the gas passage 9 through the outflow hole 20 on the other side of the upper side of the motor chamber 7 while passing through the through hole 18 of the bearing 17. ) Can be cooled.

Particularly, in the present invention, the cooling channel is branched toward each of the fixed disks 12 in the drive shaft 8 from the first impeller 10 to the position where the plurality of fixed disks 12 constituting the stator are installed. Since the 14 is formed, the refrigerant gas passing through the accumulator 15 by the rotational force of the first impeller 10 and the second impeller 11 is introduced into the first compression chamber 3 through the suction port 2. By passing through the cooling passage 14 of the drive shaft 8, the refrigerant coil can be directly supplied to the winding coil 13, which is an important cooling part coupled to each of the fixed disks 12, so that the winding coil 13 It can be cooled efficiently.

Meanwhile, the second compressed refrigerant is formed by branching the cooling passage 14 into the drive shaft 8 from the second impeller 11 to a position where the plurality of fixed disks 12 constituting the stator are installed. By using the gas it is possible to cool the winding coil 13 at a higher flow rate.

As described above, according to the present invention, the cooling disk is formed so that the cooling channel is branched in the drive shaft from the first impeller of the turbo compressor to a position where a plurality of fixed disks constituting the stator are installed. By supplying refrigerant gas directly to the winding coil coupled to the coil, it can effectively cool the winding coil, improving the performance of the drive motor, and improving the overall efficiency by securing the stability of the device, thereby greatly improving the efficiency and reliability of the compressor. Is a very useful invention.

Although the preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the above-described embodiments, and the present invention may be commonly used in the technical field to which the present invention pertains without departing from the gist of the present invention as claimed in the following claims. Anyone with knowledge will be able to make various changes.

Claims (3)

A stator having a predetermined thickness and a fixed disk in which a plurality of winding coils wound in an annular shape are fixedly coupled to the inside of the motor compartment at predetermined intervals, and having a predetermined thickness and a plurality of magnets therein. In the drive motor of the turbocompressor comprising a rotor which is coupled so that the rotating disk is coupled between the fixed disk and is integrally formed with the drive shaft, the winding is coupled to each of the fixed disk in the drive shaft And a cooling passage for supplying a refrigerant gas to the coil to cool the winding coil is branched toward each of the fixed disks. 2. The drive motor cooling structure of a turbocompressor according to claim 1, wherein the cooling passage is branched inside the drive shaft from the first impeller to a position where a plurality of fixed disks constituting the stator are installed. 2. The drive motor cooling structure of a turbocompressor according to claim 1, wherein the cooling passage is branched inside the drive shaft from the second impeller to a position where a plurality of fixed disks constituting the stator are installed.