KR101282436B1 - Circulating apparatus to use gas bearing - Google Patents

Abstract

PURPOSE: A gas bearing circulator is provided to make at least some of a gas flowing into via a circulation housing unit pass through an internal space of a driving unit, thereby preventing a demagnetization phenomenon of a magnet arranged in the driving unit. CONSTITUTION: A gas bearing circulator comprises a circulation housing unit (110), a bearing unit (120), and a driving unit (140). The circulation housing unit includes: an inlet where a gas flows into; an outlet where the gas is discharged; and an internal space. The bearing unit includes: a first bearing which is mounted on an inlet region of the internal space of the circulation housing unit; and a second bearing which is mounted on an outlet region thereof. The driving unit includes: a stator which is mounted between the first and second bearings and which includes a coil; and a rotator which is mounted to be relatively rotated around the stator inside the stator and which one end is arranged in the first bearing and the other end is arranged in the second bearing. An impeller is mounted on the other end of the driving unit.

Description

Circulating apparatus to use gas bearing

A gas bearing circulator is disclosed. More specifically, a gas bearing circulator is disclosed that allows at least a portion of the gas introduced through the inlet of the circulation housing to pass through the inner space of the drive to prevent demagnetization and coil damage of the magnets provided in the drive. .

In general, the gas bearing circulator is a device for discharging the introduced gas at a high pressure and is used in a reactor or the like. Such a gas bearing circulator has a high efficiency and a simple structure, and also has the advantage of implementing ultra-fast rotation of the impeller.

In detail, the conventional gas bearing circulator may allow the impeller to rotate at a high speed by driving the drive unit having the rotor and the driving unit, and accordingly, the gas introduced through the inlet is formed at high pressure and then discharged through the outlet. can do.

However, in the conventional gas bearing circulator, heat is generated due to the high speed rotation and the electric output of the impeller, and this heat heats the rotor, the stator, and the coils provided in the stator, thereby preventing the magnetism of the magnet or coil damage. There is a fear that the function of the gas bearing circulator may be lost. Thus, although a cooling fan is installed in the circulator to cool the heat, this also has a limitation in that the coil or rotor is not sufficiently cooled because the heat reduction effect is not great.

Therefore, there is a need for the development of a gas bearing circulator with a new structure that can reliably reduce the heat generated by the high speed rotation and electrical output of the impeller.

An object according to an embodiment of the present invention, by allowing at least a portion of the gas introduced through the inlet of the circulation housing to pass through the inner space of the drive unit to prevent the phenomenon of demagnetization of the magnet provided in the drive unit can be prevented from occurring It is to provide a gas bearing circulator that can prevent the damage to occur.

In addition, another object according to an embodiment of the present invention is to provide a gas bearing circulator capable of cooling the gas by the cooling unit when the gas moves through the inner space of the circulation housing to reduce the heat generated in the drive unit or the bearing, etc. It is.

According to an embodiment of the present invention, a gas bearing circulator includes a circulation housing having an inlet through which gas is introduced and an outlet through which compressed gas is discharged and an inner space is formed; A bearing part having a first bearing mounted in the inlet area and a second bearing mounted in the outlet area in an inner space of the circulation housing; A stator having a coil mounted between the first bearing and the second bearing, the stator having a coil, and being rotatably mounted relative to the stator from the inside of the stator, one end of which is disposed on the first bearing, and the other end of which comprises the first 2 is disposed in the bearing, the other end of the drive unit having a rotor to which the impeller is mounted; includes; the first cover is a bearing cover is coupled to the inlet of the circulation housing, the central region of the bearing cover A through hole may be formed to allow some of the gas introduced through the inlet to pass along the axial direction of the driving unit.

With this configuration, at least a portion of the gas introduced through the inlet of the circulation housing can pass through the inner space of the drive unit, thereby preventing the occurrence of demagnetization of the magnet provided in the drive unit while preventing damage to the coil. You can stop that.

According to an embodiment of the present invention, by allowing at least a portion of the gas introduced through the inlet of the circulation housing to pass through the inner space of the drive unit, it is possible to prevent the phenomenon of demagnetization of the magnet provided in the drive unit, while damaging the coil. This can be prevented from occurring.

In addition, according to the embodiment of the present invention, the gas can be cooled by the cooling unit when the gas moves through the inner space of the circulation housing to reduce the heat generated in the drive unit or the bearing.

1 is a view showing the internal configuration of a gas bearing circulator according to an embodiment of the present invention.
FIG. 2 is an enlarged view illustrating part II of FIG. 1.

Hereinafter, configurations and applications according to embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following description is one of several aspects of the patentable invention and the following description forms part of the detailed description of the invention.

In the following description, well-known functions or constructions are not described in detail for the sake of clarity and conciseness.

FIG. 1 is a diagram illustrating an internal configuration of a gas bearing circulator according to an embodiment of the present invention, and FIG. 2 is an enlarged view illustrating part II of FIG. 1.

As shown in FIG. 1, the gas bearing circulator 100 according to an exemplary embodiment of the present invention has an inlet 111 of a gas at one side thereof and an outlet 115 of a compressed gas at the other side thereof. A bearing portion 120 having a circular housing 110 formed therein, bearings 121 and 125 provided in the inlet 111 region and the outlet 115 region inside the circulation housing 110, and a bearing ( 121 and 125 are formed between the drive unit 140 for rotating the impeller 150 mounted in the outlet 115 region, and the side of the drive unit 140 in the circulation housing 110, the drive unit 140 It may include a cooling unit 160 for providing a cooled gas toward.

Here, a bearing cover 130 covering the bearing 121 is mounted on the bearing 121 provided in the region of the inlet 111 of the circulation housing 110, and a through-hole is formed in the center portion of the bearing cover 130. 130h) is formed and the gas introduced through the inlet 111 of the circulation housing 110 may move along the inner surface (arrow A direction) forming the inner space of the circulation housing 110, but through the through hole (130h) It may be provided directly to the inner region of the driver 140, thereby reducing the heat generated as a result of the driving of the driver 140.

Referring to each configuration, first, the circulation housing 110 of the present embodiment, as shown in Figure 1, forms a space for compressing the gas by the high-speed rotation of the impeller 150, for which the gas is introduced Inlet 111 and outlet 115 are formed.

In more detail, the circulation housing 110 includes an inlet forming body 110a in which an inlet is formed, an outlet forming body 110b in which an outlet 115 is formed, and a space forming body 110c forming an inner space. After the body (110a, 110b, 110c) are manufactured separately can be combined with each other by screw coupling.

Due to this coupling and separation structure, it is possible to smoothly assemble the configuration such as the driving unit 140, the cooling unit 160, etc. inside the circulation housing 110, and also can be easily disassembled.

On the other hand, the bearing portion 120 of the present embodiment, as shown in Figure 1, the first bearing 121 is disposed in the region of the inlet 111 in the inner space of the circulation housing 110, and the outlet 115 region The second bearing 125 is disposed.

The first bearing 121 and the second bearing 125 of the bearing part 120 not only support the rotor 145 of the driving unit 140 to be described later, but also smoothly rotate the shaft of the rotor 145. To lose. The first bearing 121 and the second bearing 125 are fixedly coupled to the circulation housing 110, and the rotor 145 of the driving unit 140 with respect to the first bearing 121 and the second bearing 125. Can rotate relative.

Here, the bearing cover 130 facing the inlet 111 of the circulation housing 110 is coupled to the first bearing 121. The bearing cover 130 may have a disk shape corresponding to the cylindrical shape of the internal space.

Therefore, the gas introduced through the inlet 111 of the circulation housing 110 moves along the outer surface of the bearing cover 130, and then the outer surface of the bearing unit 120 and the driving unit 140 to be described later and the circulation housing 110. It can move in the direction of the impeller 150 along the flow path formed between inner surfaces (arrow A direction).

In addition, the first bearing cover 130 has a through hole 130h formed in the central region, and passes a portion of the gas introduced into the driving unit 140 (axial direction) through the through hole 130h. The heat generated inside 140 may be cooled, which will be described later in detail.

On the other hand, the driving unit 140 of the present embodiment is disposed between the first bearing 121 and the second bearing 125, and has a principle of driving according to the application of power. As shown in FIG. 1, the stator 141 having the coil 142 and the stator 141 are disposed to be relatively rotatable with respect to the stator 141 inside the stator 141 and have a permanent magnet (not shown). It has a rotor 145 having.

By applying a current to the coil 142 of the stator 141 by this configuration, the electromagnetic interaction with the permanent magnet provided in the rotor 145 is generated, so that the rotor 145 can rotate, and thus The impeller 150 mounted at one end of the electron 145 may also rotate at a high speed according to the degree of power application. Therefore, the gas introduced into the circulation housing 110 may be discharged after being compressed at a high pressure in the impeller 150.

However, in the gas bearing circulator 100, since the impeller 150 is rotated at a high speed, and because of the electric output, the operating temperature may be increased, and thus the bearing unit 120 and the driving unit in the circulation housing 110 may be increased. 140 may be damaged. That is, demagnetization of the magnet and damage to the coil 120 may occur, and accordingly, the function of the gas bearing circulator 100 may be lost.

Therefore, in the present embodiment, the cooling unit for cooling the heat generated in the outer portion of the bearing unit 120 and the driving unit 140 by cooling a part of the gas moving along the outer surfaces of the bearing unit 120 and the driving unit 140 ( The inner portion of the driving unit 140 is provided by forming a through hole 130h through which the gas can be introduced into the driving unit 140 in the bearing cover 130 covering the first bearing 121 as described above. It can also cool the heat generated.

First, as shown in FIG. 1, the cooling unit 160 of the present embodiment is coupled to an inner wall of the circulation housing 110 so as to be adjacent to an outer surface of the stator 141 of the driving unit 140. Some of the gas flowing through the inlet 111 and moving along the outer surface of the bearing portion 120 and the driving unit 140 (arrow A direction) by cooling the fan gas by moving the cooled gas driving unit 140 ), The heat generated in the outer portion (eg, the stator 141) and the outer portion of the bearing portion 120 can be cooled.

On the other hand, the through-hole 130h formed in the bearing cover 130 to cool the inner portion of the drive unit 140 passes through some of the low-temperature gas flowing through the inlet 111 of the circulation housing 110 (arrow B direction) to cool the heat that may be generated in the inner part of the bearing part 120 and the inner part of the driving part 140.

Referring to FIG. 2, the gas flowing through the through hole 130h passes through the inner surface of the first bearing 121 and the outer surface of the rotor 145, and then between the rotor 145 and the stator 141. It can pass through the region and then pass between the inner surface of the second bearing 125 and the outer surface of the rotor 145, so that the inner part of the bearing portion 120 and the rotor 145 of the drive 140. ) And the coil 142 of the stator 141 can be prevented from heating.

Therefore, it is possible to prevent the potato phenomenon of the permanent magnet provided in the rotor 145 to be generated, and to prevent the coil or the like from being damaged.

As such, according to one embodiment of the present invention, the configuration mounted inside the circulation housing 110 through the cooling unit 160 (outer portions of the bearing unit 120 and the driving unit 140) may be prevented from being heated. In addition, a permanent magnet provided in the driving unit 140 by allowing some of the gas introduced into the circulation housing 110 to pass through the inner side of the bearing unit 120 and the driving unit 140 through the through hole 130h. The potato phenomenon and the coil 120 may be prevented from being damaged, and thus, the function of the gas bearing circulator 100 of the present embodiment may be prevented from being lost.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

100: gas bearing circulator 110: circulation housing
111: entrance 115: exit
120: bearing portion 121: first bearing
125: second bearing 130: bearing cover
130h: through hole 140: drive part
141: stator 142: coil
145: rotor 150: impeller
160: cooling unit

Claims (5)

A circulation housing having an inlet through which gas is introduced and an outlet through which compressed gas is discharged and an inner space is formed;
A bearing part having a first bearing mounted in the inlet area and a second bearing mounted in the outlet area in an inner space of the circulation housing; And
A stator having a coil mounted between the first bearing and the second bearing and rotatably mounted relative to the stator from the inside of the stator, one end of which is disposed in the first bearing and the other end of the second bearing; A driving part disposed on a bearing and having a rotor on which the impeller is mounted;
Including;
A bearing cover is coupled to the first bearing to face an inlet of the circulation housing, and a through hole is formed at a central region of the bearing cover to allow some of the gas introduced through the inlet to pass along the axial direction of the driving unit. Gas bearing circulator.
The method of claim 1,
And a cooling unit mounted to the side of the driving unit inside the circulation housing to cool the gas introduced through the inlet to provide the cooled gas in the direction of the driving unit.
The method of claim 1,
The through hole, the space between the first bearing and the rotor, the space between the rotor and the stator, and the space between the rotor and the second bearing communicate with each other and flow through the inlet. A gas bearing circulator in which some of the gas is movable to the impeller.
The method of claim 2,
Partial gas of the gas introduced through the inlet is moved along the outer surface of the first bearing, and then compressed by the impeller through the outer surface of the cooling unit, the second bearing.
The method of claim 1,
The circulation housing,
An inlet forming body in which the inlet is formed;
A space forming body in which the internal space is formed; And
An outlet forming body in which the outlet is formed,
And a gas bearing circuit in which the inlet forming body, the space forming body and the outlet forming body are detachably coupled.

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