KR102383011B1 - Magnetic damper system applied to dry gas seal - Google Patents

Abstract

The present invention relates to a magnetic damper system applied to a compressor, comprising: a shaft connected to a gear unit to receive driving force to rotate about a rotating shaft, and connected to a rotating body to transmit the driving force to the rotating body; It is spaced apart from the shaft in the radial direction of the shaft and is formed to surround the shaft, and includes two sealing blocks spaced apart from each other in a direction parallel to the rotation axis, and disposed adjacent to the rotation body and the rotation body. A process gas is introduced into a space between the sealing blocks, and a seal gas is introduced into a space between the shaft and the sealing block disposed far from the rotating body, and the process gas and the seal gas are the two sealing blocks. The two sealing blocks each include an electromagnet that applies a magnetic force to the shaft so that the dry gas seal is formed by being discharged into the interspace, and the shaft is positioned at a preset position.

Description

Magnetic damper system applied to dry gas seal

The present invention relates to a magnetic damper system, and more particularly, to a magnetic damper system provided in a compressor or expander.

A centrifugal compressor is a device that compresses a fluid by applying a centrifugal force to the fluid using an impeller that rotates. Referring to FIG. 1 , an overall configuration that can be applied to a centrifugal compressor or an expander can be confirmed.

A centrifugal compressor generally includes a driving unit that produces a driving force, a gear unit connected to the driving unit, a shaft connected to the gear unit to receive driving force and rotated, an impeller 102 connected to a rotating shaft to rotate, and an impeller ( scrolls surrounding 102 and other turbine casings 101 and the like.

Among them, the impeller 102 functions to increase the pressure of the fluid by transferring rotational kinetic energy to the fluid. The impeller 102 includes a hub and a plurality of blades that help the fluid move and transfer energy to the fluid, and the blades may be formed on the outer circumferential surface of the hub. At this time, the impeller 102 may rotate the blade by rotating the hub to suck the fluid and discharge it to the outside.

A sealing technology is applied to the rear surface of the impeller 102 to prevent the fluid compressed by the impeller 102 from leaking into the gearbox area, cooling the rotating shaft of the recently rotating impeller 102 and reducing the axial load. A dry gas seal (103, DGS, Dry Gas Seal) is used. Unlike the oil seal that uses lubricating oil, it is a technology that seals the rear surface of the impeller by introducing the seal gas into the flow path.

Recently, a method using supercritical carbon dioxide (sCO2) has been proposed for the DGS 103 . Referring to FIG. 2 , the structure of DGS using supercritical carbon dioxide can be confirmed. In this sCO2 DGS, the low-temperature seal gas 107 introduced from the seal side and the high-temperature process gas 106 introduced from the impeller side meet at the center and are discharged to the central flow path. Accordingly, two sealing blocks 104 are required to form an inlet flow path through which the seal gas 107 and the process gas 106 are introduced, and a central flow path through which the mixed gas 108 is discharged.

The high temperature process gas 106 may be a gas of about 705°C. Since the impeller 102 forms a flow path through which the high-temperature process gas 106 is introduced, and the shaft 31 is in contact with the impeller 102 , the shaft 31 follows the impeller 102 from the high-temperature process gas 106 . ) can transfer heat. However, there is no separate means for cooling the heat conducted from the impeller 102 to the shaft 31 due to the high-temperature process gas 106 in the conventional sCO2 DGS.

On the other hand, for stable operation of the compressor or expander, the rotation shaft of the compressor must be stably maintained. To maintain this, a thrust collar, a journal bearing, etc. are used on the shaft to support the shaft. However, even if thrust collar and journal beveling are used, the vibration caused by the rotation of the rotating shaft cannot be completely canceled.

Accordingly, the present invention intends to propose a magnetic damper system that includes a means for cooling the heat conducted to the shaft and can additionally suppress vibration caused by the rotation of the shaft.

Japanese Patent No. 3879414

SUMMARY OF THE INVENTION The problem to be solved by the present invention is to provide a magnetic damper system with a dry gas seal in a compressor or expander.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

A magnetic damper system according to an embodiment of the present invention for solving the above problems includes a shaft that receives a driving force and rotates about a rotating shaft; It is spaced apart from the shaft in the radial direction of the shaft and is formed to surround the shaft, and includes two sealing blocks spaced apart from each other in a direction parallel to the rotation axis, and disposed adjacent to the rotation body and the rotation body. A process gas is introduced into a space between the sealing blocks, and a seal gas is introduced into a space between the shaft and the sealing block disposed far from the rotating body, and the process gas and the seal gas are the two sealing blocks. The two sealing blocks may each include an electromagnet for applying a magnetic force to the shaft so that the dry gas seal is formed by being discharged into the interspace, and the shaft is positioned at a preset position.

Other specific details of the invention are included in the detailed description and drawings.

According to the embodiments of the present invention, there are at least the following effects.

Supercritical carbon dioxide DGS and magnetic attenuator can be implemented without wasting space.

A magnetic damper can be used to stabilize the rotation and vibration of the shaft.

The effect according to the present invention is not limited by the contents exemplified above, and more various effects are included in the present specification. Other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a perspective view showing an overall appearance of a conventional compressor.
2 is a side cross-sectional view showing the structure of DGS using conventional supercritical carbon dioxide.
3 is a side cross-sectional view showing the structure of DGS using supercritical carbon dioxide according to an embodiment of the present invention.
4 is a side cross-sectional view conceptually illustrating a situation in which a magnetic attenuator system according to an embodiment of the present invention is installed in a compressor.
5 is a side cross-sectional view showing a structure of a thrust electromagnet of a magnetic attenuator system according to an embodiment of the present invention.
6 is a perspective view showing a structure of a thrust electromagnet of a magnetic attenuator system according to an embodiment of the present invention along with a partial cross section.
7 is a perspective view illustrating a structure of a radial electromagnet of a magnetic attenuator system according to an embodiment of the present invention.
8 is a cross-sectional view showing the structure of a radial electromagnet of a magnetic attenuator system according to an embodiment of the present invention.

Advantages and features of the present invention and methods of achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only these embodiments allow the disclosure of the present invention to be complete, and common knowledge in the art to which the present invention pertains It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout.

Unless otherwise defined, all terms (including technical and scientific terms) used herein may be used with the meaning commonly understood by those of ordinary skill in the art to which the present invention belongs. In addition, terms defined in a commonly used dictionary are not to be interpreted ideally or excessively unless clearly defined in particular.

The terminology used herein is for the purpose of describing the embodiments and is not intended to limit the present invention. In this specification, the singular also includes the plural unless specifically stated otherwise in the phrase. As used herein, “comprises” and/or “comprising” does not exclude the presence or addition of one or more other components in addition to the stated components.

Further, the embodiments described herein will be described with reference to cross-sectional and/or schematic diagrams that are ideal illustrative views of the present invention. Accordingly, the shape of the illustrative drawing may be modified due to manufacturing technology and/or tolerance. In addition, in each of the drawings shown in the present invention, each component may be enlarged or reduced to some extent in consideration of convenience of description. Like reference numerals refer to like elements throughout, and "and/or" includes each and every combination of one or more of the recited items.

Spatially relative terms should be understood as terms including different directions of components during use or operation in addition to the directions shown in the drawings. Components may also be oriented in other orientations, and thus spatially relative terms may be interpreted according to orientation.

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

3 is a side cross-sectional view showing the structure of DGS using supercritical carbon dioxide according to an embodiment of the present invention. In the description with reference to FIG. 2 above, in the conventional sCOS DRS, a problem in which high-temperature heat is transferred to the shaft 31 along the impeller 102 by the high-temperature process gas 106 was examined. 3 shows a configuration for improving this.

The shaft 31 may include a real gas inlet hole 110 penetrating the shaft 31 , and the impeller 102 may include a real gas outlet hole 111 penetrating the impeller 102 . The low-temperature seal gas 107 introduced from the seal side may be branched into a space between the impeller 102 and the impeller fastening shaft 113 along the seal gas inlet hole 110 . The branched low-temperature real gas 107 may be discharged to the outside along the real gas outlet hole 111 .

The low-temperature real gas 112 branched along the real gas inlet hole 110 flows along the outer peripheral surface of the impeller 102 until it is discharged along the real gas outlet hole 111, and is It performs a function of cooling the heat transferred to the impeller (102). Accordingly, heat conducted from the impeller 102 to the shaft 31 by the high-temperature process gas 106 is cooled to prevent the temperature of the shaft 31 from becoming higher than necessary.

4 is a side cross-sectional view conceptually illustrating a situation in which a magnetic attenuator system according to an embodiment of the present invention is installed in a compressor.

Referring to FIG. 4 , a magnetic attenuator system according to an embodiment of the present invention includes a plurality of sealing blocks 10 and 20 , a thrust collar 32 , a plurality of axial displacement sensors 41 , and a plurality of radial displacement sensors 40 . ), it can be seen that

The gear unit 35 is a power transmission unit configured by interlocking various gears, and is connected to a driving unit generating a driving force to transmit a driving force to the shaft 31 by rotation of the gears. Since the direction in which the gear unit 35 is connected to the shaft 31 is parallel to the axis of rotation A, the thrust limit 33 is further formed so that the gear unit 35 and the shaft 31 move in the direction of the axis of rotation (A). You can limit the range you can move.

The shaft 31 is a component that is connected to the gear unit 35 and rotates by receiving a driving force. The shaft 31 rotates about the rotational shaft A, and is connected to the gear unit 35 at one end and at the same time connected to the rotating body 30 at the other end. Accordingly, the rotating body 30 rotates around the same rotating shaft A according to the rotation of the shaft 31 .

The rotating body 30 is a rotating component connected to the shaft 31, and may be an impeller or a wheel. Therefore, the compressor performs the main function of compressing the incoming fluid by transferring kinetic energy. In the specification of the present invention, it is assumed that the rotating body 30 is an impeller, and it is assumed that the impeller is used in a compressor for compressing a fluid. However, the magnetic damper system of the present invention can also be used in an expander using rotational force.

The sealing blocks 10 and 20 are components formed to surround the shaft 31, and are configured in plurality to constitute a flow path required for the supercritical carbon dioxide dry gas seal. Accordingly, two are located immediately behind the rotating body 30 . In one embodiment of the present invention, two sealing blocks 10 and 20 are positioned at the rear of the rotating body 30 located at both ends of the shaft 31, respectively, and a total of four are arranged to constitute a magnetic attenuator system.

The sealing blocks 10 and 20 surround the shaft 31 along the outer circumferential surface of the shaft 31 , but do not contact the shaft 31 . Accordingly, it is disposed to be spaced apart from the shaft 31 by a predetermined interval in the radial direction. The shaft 31 is a rotating component, but the sealing blocks 10 and 20 do not rotate, and friction does not occur due to contact.

The sealing blocks 10 and 20 are arranged two by one, and are arranged in a direction parallel to the axis of rotation (A). Also, the sealing blocks 10 and 20 are disposed so as not to contact each other. Accordingly, the two sealing blocks 10 and 20 are disposed to be spaced apart from each other by a predetermined interval in a direction parallel to the rotation axis A.

The sealing blocks 10 and 20 include an electromagnet in which a coil is wound. There are two types of electromagnets that the sealing blocks 10 and 20 can include, a thrust electromagnet 12 and a radial electromagnet 22, and in FIG. 4 representing an embodiment of the present invention, two sealing blocks located on the left side (10) shows the thrust electromagnet 12, and the two sealing blocks 20 located on the right side include the radial electromagnet 22, but the arrangement is not limited thereto. However, since the two thrust electromagnets 12 must form a pair, and the radial electromagnet 22 is also the same, the same type of electromagnet must be included between the two adjacent sealing blocks 10 and 20 .

The electromagnets included in the sealing blocks 10 and 20 receive electric power from the outside and apply magnetic force to the shaft acting part 34 or the thrust collar 32 to be described later so that the shaft 31 is placed in the correct position. The action and specific configuration of the electromagnet included in the sealing blocks 10 and 20 will be described later in the description of FIGS. 5 to 8 .

A dry gas seal included in the sealing block 10 located on the left of the sealing blocks shown in FIG. 4 will be described as an example. However, the same content applies to the sealing block 20 located on the right side, and the flow of gas is expressed only for the flow path located at the upper left, but the same gas flow exists for the flow paths located at the lower left, upper right and lower right.

A high-temperature process gas 71 is introduced into the space between the rotating body 30 and the sealing block 10 disposed adjacent to the rotating body 30 . In one embodiment of the present invention, supercritical carbon dioxide is used as the process gas 71 . Since the introduced fluid will proceed along the continuous flow path, the process gas 71 passes through the space 14 between the rotating body 30 and the sealing block 10, and the sealing block disposed adjacent to the rotating body 30 ( 10) and the shaft 31 enters the space 11.

Of the two sealing blocks 10 , a low-temperature seal gas 72 is introduced into the space 11 between the sealing block 10 and the shaft 31 disposed far from the rotating body 30 . In an embodiment of the present invention, low-temperature supercritical carbon dioxide is used as the real gas 72 .

The process gas 71 and the seal gas 72 travel through the space 11 between the sealing blocks 10 and 20 and the shaft 31 , respectively, and meet in the space 13 between the two sealing blocks 10 . Therefore, it is mixed and discharged into the space 13 between the two sealing blocks 10 . Due to this, two sealing blocks 10 and 20 and a dry gas seal using supercritical carbon dioxide are constituted. Other components, such as a labyrinth seal (109, labyrinth seal) for constituting the dry gas seal, follow the structure of a general dry gas seal.

The magnetic damper system according to an embodiment of the present invention has a sealing block 10 near the rotating body 30 with respect to the compressor in which the rotating body 30 is connected to both ends of the shaft 31 with the gear unit 35 as the center. , 20) can be installed so that it is located. However, the compressor may be configured in a form in which the rotating body 30 is connected only to one end of the shaft 31 , and in this case, the sealing blocks 10 and 20 are arranged only in one side, not in both directions, based on the gear unit 35 . can

The thrust collar 32 is a component formed on the outer circumferential surface of the shaft 31 , and is formed as a torus protruding from the outer circumferential surface of the shaft 31 in the radial direction of the shaft 31 . It rotates along with the rotation.

The thrust collar 32 protrudes from the space between two adjacent sealing blocks 10 . Accordingly, the thrust collar 32 separates two adjacent sealing blocks 10 . The sealing blocks 10 are arranged one by one before and after the thrust collar 32 in the direction parallel to the rotation axis A.

The thrust collar 32 must be located between the sealing blocks 10 when the type of electromagnet included in the adjacent sealing blocks 10 is the thrust electromagnet 12 , but the type of electromagnet included in the adjacent sealing blocks 20 is lady In the case of the Earl electromagnet 22, it does not matter if it is not disposed. This is because the thrust collar 32 is a component for controlling the axial movement of the shaft 31 by receiving a magnetic force parallel to the rotation axis A by the electromagnet. A process in which the magnetic force by the electromagnet acts on the thrust collar 32 will be described later with reference to FIGS. 5 and 6 .

The shaft working surface 34 is a thin metal plate formed along the outer circumferential surface of the shaft 31 , and may preferably be formed by laminating silicon steel plates. When the type of electromagnet included in the adjacent sealing blocks 20 is the radial electromagnet 22, the shaft acting part 34 should be formed on the outer circumferential surface of the shaft 31, but If the type is the thrust electromagnet 12, it is not formed. This is because the shaft acting part 34 is a component for controlling the radial movement of the shaft 31 by receiving the magnetic force in the radial direction of the shaft 31 by the electromagnet. A process in which the magnetic force by the electromagnet acts on the shaft acting part 34 will be described later with reference to FIGS. 7 and 8 .

The axial displacement sensor 41 detects a displacement of the shaft 31 in the direction of the rotation axis A. A method for the shaft displacement sensor 41 to detect the displacement in the direction of the rotation axis A includes a method by transmitting and receiving light, a method using an eddy current sensor, and the like, but the method is not limited thereto.

The shaft displacement sensor 41 may be located in front of the rotational body 30 in a direction parallel to the rotational shaft A in order to detect a displacement in the rotational axis A direction of the shaft 31, but the arrangement position is not limited thereto .

The displacement in the direction of the axis of rotation (A) of the shaft (31) sensed by the axial displacement sensor (41) is transmitted to the thrust electromagnet (12) among the electromagnets included in the sealing blocks (10, 20), and the axis of rotation (A) of the shaft (31) The directional displacement is controlled by the action of magnetic force. A control unit for controlling the amount of power to be supplied to the thrust electromagnet 12 by using the measured value of the axial displacement sensor 41 may pass through the middle. Therefore, when the shaft 31 is deviated from the correct position in the direction of the axis of rotation (A), the axis displacement sensor 41 detects it and transmits the measured value to the thrust electromagnet 12 to the shaft 31 in the direction of the axis of rotation (A) to suppress the vibration in the direction of the shaft's rotation axis (A) by applying magnetic force and return the shaft (31) to the correct position.

The radial displacement sensor 40 senses the radial displacement of the shaft 31 . Methods for the radial displacement sensor 40 to detect the radial displacement include a method by transmitting and receiving light, a method using a magnetic Hall sensor, and the like, but the method is not limited thereto.

The radial displacement sensor 40 may be disposed to face the shaft 31 in a direction orthogonal to the rotation axis A in order to detect the radial displacement of the shaft 31 , but the disposed position is not limited thereto.

The radial displacement of the shaft 31 sensed by the radial displacement sensor 40 is transmitted to the radial electromagnet 22 among the electromagnets included in the sealing blocks 10 and 20 to convert the radial displacement of the shaft 31 of the magnetic force. to be controlled by action. A control unit for controlling the amount of power to be supplied to the radial electromagnet 22 by using the measured value of the radial displacement sensor 40 may pass through the middle. Therefore, when the shaft 31 is out of the correct position in the radial direction, the radial displacement sensor 40 detects it and transmits the measured value to the radial electromagnet 22 to apply a magnetic force to the shaft 31 in the radial direction. Suppresses the radial vibration of the shaft and returns the shaft 31 to the correct position.

The bearing 50 is disposed to support the shaft 31 on which a magnetic force is applied by the magnetic damper system according to an embodiment of the present invention. Accordingly, it is formed to surround the shaft 31 to support the shaft 31 . In one embodiment of the present invention, it is expressed that two bearings 50 are disposed on both sides of the gear unit 35 , but the number and arrangement positions of the bearings 50 are not limited thereto. A journal bearing may be used as the bearing 50 , but the type of the bearing 50 is also not limited thereto.

Hereinafter, the structure and operation of the thrust electromagnet 12 of the magnetic attenuator system according to an embodiment of the present invention will be described with reference to FIGS. 5 and 6 .

5 is a side cross-sectional view showing the structure of the thrust electromagnet 12 of the magnetic attenuator system according to an embodiment of the present invention. 6 is a perspective view showing the structure of the thrust electromagnet 12 of the magnetic attenuator system according to an embodiment of the present invention together with a partial cross section.

5 and 6, the sealing block 10, 20 of the magnetic attenuator system according to an embodiment of the present invention may include a thrust electromagnet 12, between the two sealing blocks (10, 20) A thrust collar 32 may be disposed there.

A conductive coil is wound around the shaft 31 to configure the thrust electromagnet 12 . Since the sealing blocks 10 and 20 are disposed one by one before and after the thrust collar 32 in the direction of the axis of rotation (A) and the two are disposed adjacently, the shaft 31 is enclosed in the inside of each sealing block 10 and 20 . A coil wound in such a way is accommodated. A total of two thrust electromagnets 12 are disposed.

The coil constituting the thrust electromagnet 12 is formed as a torus surrounding the shaft 31 . Therefore, current flows along the circumferential direction of the coil, and accordingly, at the center of the circle formed by the coil, a magnetic force line 60 parallel to the axis of rotation (A) is formed, which is directed in a direction orthogonal to the circle, and out of the radial direction of the circle. In , the magnetic force line 60 is formed in a direction opposite to the direction of the magnetic force line 60 formed at the center of the circle.

The magnetic force lines 60 formed in the front and rear of the coil in a direction parallel to the rotation axis A are formed in the radial direction of the shaft 31, the magnetic force lines 60 formed in the front of the coil and the magnetic force lines formed in the rear of the coil ( 60) are opposite to each other. Accordingly, a closed loop of the magnetic force lines 60 surrounding the coil is formed.

The sealing blocks 10 and 20 may be formed of a metal through which magnetic flux may flow, and the thrust collar 32 may also be formed of a metal. Accordingly, the magnetic flux formed by the thrust electromagnet 12 may flow through the sealing block 10 and the thrust collar 32 . It is to increase the efficiency of the electromagnet by arranging a metal with high magnetic permeability without allowing magnetic flux to flow through the insulator or air gap.

In FIG. 5, the magnetic force line 60 is shown only around the cross-section of the thrust electromagnet 12 located below. However, although not shown around the cross section of the thrust electromagnet 12 located above, the lines of magnetic force 60 formed around the end surface of the thrust electromagnet 12 located below and the lines of magnetic force 60 are formed symmetrically about the axis of rotation A. . If the closed loop of the magnetic force line 60 formed around the cross section of the thrust electromagnet 12 located at the lower left side is formed to circulate in the clockwise direction, it circulates in the counterclockwise direction around the cross section of the thrust electromagnet 12 located at the upper left side. A closed loop of the magnetic force lines 60 is formed. The flow direction of the magnetic force lines 60 is exemplary, and the opposite direction is also possible.

In Fig. 5, the thrust electromagnet 12 located on the left and the thrust electromagnet 12 located on the right form a closed loop with lines of magnetic force 60 in opposite directions, so that attractive forces are applied to the thrust collar 32 located at the center, respectively. do. Accordingly, the thrust collar 32 is in a state of receiving attractive force by the respective thrust electromagnets 12 in both directions parallel to the rotation axis A, and is positioned where the balance is achieved.

If the shaft 31 is deviated to the right rather than the correct position in FIG. 5 , the axial displacement sensor 41 detects a displacement of the shaft 31 in the direction of the rotation axis A. The axial displacement sensor 41 transmits a control signal to the thrust electromagnet 12 . The thrust electromagnet 12 located on the left generates a magnetic force that pulls the thrust collar 32 more strongly. Accordingly, the thrust collar 32 is moved to the left by the changed magnetic force to place the shaft 31 coupled to the thrust collar 32 in the correct position.

In addition, when an impact or vibration occurs with respect to the shaft 31 in the direction of the axis of rotation (A), the thrust electromagnet 12 continuously applies a magnetic force even against this, so that the movement is damped and returned to the correct position.

Hereinafter, the structure and operation of the radial electromagnet 22 of the magnetic attenuator system according to an embodiment of the present invention will be described with reference to FIGS. 7 and 8 .

7 is a perspective view showing a partially opened structure of the radial electromagnet 22 of the magnetic attenuator system according to an embodiment of the present invention. 8 is a cross-sectional view showing the structure of the radial electromagnet 22 of the magnetic attenuator system according to an embodiment of the present invention.

7 and 8 , the sealing block 20 of the magnetic attenuator system according to an embodiment of the present invention may include a radial electromagnet 22 .

A plurality of protrusions 23 extending in a direction opposite to the direction of the shaft 31 are disposed in the sealing block 20 at regular intervals along the circumference of the sealing block 20 . In one embodiment of the present invention, the protrusion 23 from the inner circumferential surface of the sealing block 20 is made to protrude along the radial direction of the shaft 31 toward the shaft (31). A conductive coil is wound around the protrusion 23 to form a plurality of radial electromagnets 22 .

The coil constituting the radial electromagnet 22 is formed in an annular shape surrounding the protrusion 23 . Accordingly, current flows along the direction in which the coil is wound, and accordingly, at the center of the ring formed by the coil, the magnetic force line 61 is formed in the direction orthogonal to the ring, parallel to the direction of the protrusion 23 .

By flowing a current in opposite directions to the radial electromagnets 22 adjacent to each other, lines of magnetic force 61 in opposite directions are formed at the center of the rings formed by the coils of each radial electromagnet 22 . Accordingly, a closed loop of the magnetic force lines 61 is formed by the radial electromagnets 22 adjacent to each other.

The sealing block 20 may be formed of a metal through which magnetic flux can flow, and the protrusion 23 that is a part of the sealing block 20 may also be formed of metal. Accordingly, the magnetic flux formed by the radial electromagnet 22 may flow through the sealing block 20 . It is to increase the efficiency of the electromagnet by arranging a metal with high magnetic permeability without allowing magnetic flux to flow through the insulator or air gap.

Since a plurality of protrusions 23 are spaced apart from each other at regular intervals along the inner circumferential surface of the sealing block 20 , the radial electromagnets 22 are also formed in a corresponding number. Since the radial electromagnet 22 is disposed around the shaft 31, the radial electromagnets 22 located on opposite sides of the shaft 31 apply magnetic force to the shaft acting part 34 in opposite directions. do.

In FIG. 8 , the magnetic force lines 61 are shown only around the cross-section of the radial electromagnet 22 located in one region. However, the magnetic force lines 61 are formed around the cross-section of the radial electromagnet 22 located in the remaining area in the same manner as the illustrated magnetic force lines 61, although not shown.

The plurality of radial electromagnets 22 disposed to surround the shaft 31 act as attractive forces respectively to the shaft acting portion 34 formed on the outer circumferential surface of the shaft 31 located at the center. Since the plurality of radial electromagnets 22 act with a magnetic force in the radial direction with respect to the shaft 31 , it is possible to control the radial movement of the shaft 31 and suppress the radial vibration. The shaft 31 is positioned where the magnetic force applied by the plurality of radial electromagnets 22 is balanced.

If the shaft 31 is deviated to the lower left than the correct position in FIG. 8 , the radial displacement sensor 40 spaced apart from the shaft 31 detects the radial displacement of the shaft 31 . The radial displacement sensor 40 transmits a control signal to the radial electromagnet 22 . Magnetic force so that the radial electromagnet 22 located at the upper right generates a magnetic force that pulls the shaft acting part 34 more strongly, and to send the shaft 31 to the upper right for the rest of the radial electromagnet 22 as well. It transmits a control signal that generates Accordingly, the changed magnetic force acts on the shaft acting portion 34, and the shaft 31 moves to the upper right. The shaft 31 is thus placed in the correct position.

In addition, when a shock or vibration occurs in the radial direction with respect to the shaft 31, since the magnetic force is continuously applied to the plurality of radial electromagnets 22, the movement is damped and returned to the correct position.

Although both surfaces of the sealing block 20 in the direction of the rotation axis (A) are shown to be open in FIG. 7 , it may be configured to be closed by further including a separate side wall. In addition, in FIG. 7 , the sealing block 20 does not form a perfect circle, but opens some regions, and is shown as an incomplete circle, but this is only for the sake of understanding. The actual sealing block 20 forms a circle.

In this way, the radial electromagnet 22 connected to the radial displacement sensor 40 and the thrust electromagnet 12 connected to the axial displacement sensor 41 move in the radial direction and the rotation axis (A) direction of the rotating shaft 31 by the action. to act as an attenuator for the sudden movement of the shaft 31 by controlling the shaft 31 to be positioned in the correct position. At the same time, since the sealing blocks 10 and 20 including the electromagnet become a supercritical carbon dioxide dry gas seal, the seal can perform the role of the seal without wasting space.

Those of ordinary skill in the art to which the present invention pertains will understand that the present invention may be embodied in other specific forms without changing the technical spirit or essential features thereof. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the following claims rather than the above detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be interpreted as being included in the scope of the present invention. do.

Although the present invention has been described with reference to the above-mentioned preferred embodiments, various modifications and variations are possible without departing from the spirit and scope of the invention. Accordingly, it is intended that the appended claims cover such modifications and variations as long as they fall within the gist of the present invention.

10, 20, 104: sealing block 11: space between sealing block and shaft
12: thrust electromagnet 13: space between sealing blocks
14: space between sealing block and rotating body
21: sealing block inner circumferential surface 22: radial electromagnet
23: protrusion 24: space between sealing block and shaft
30: rotating body 31: shaft
32: thrust collar 33: thrust limit
34: shaft acting portion 35: gear unit
40: radial displacement sensor 41: axial displacement sensor
50, 105: bearing 60, 61: magnetic force line
71, 106: process gas 72, 107, 112: real gas
101: casing 102: impeller
103: dry gas seal 109: labyrinth seal
110: real gas inlet hole 111: real gas outlet hole
113: impeller fastening shaft A: rotating shaft

Claims (6)

a shaft that receives a driving force and rotates about a rotating shaft;
It is spaced apart from the shaft in the radial direction of the shaft, is provided at at least one end of both ends of the shaft, is formed to surround the shaft, and includes two sealing blocks that are spaced apart from each other in a direction parallel to the axis of rotation,
A dry gas seal is formed between the shaft, the two sealing blocks, and a rotating body positioned at an end of the shaft, and the dry gas seal is a high-temperature process gas introduced between the sealing blocks disposed adjacent to the rotating body. and a space in which low-temperature real gas is introduced and flows between the sealing block and the shaft disposed far from the rotating body, and a space in which the process gas and the seal gas are discharged between the two sealing blocks. and,
The magnetic attenuator system comprising an electromagnet in which the two sealing blocks apply a magnetic force to the shafts, respectively, so that the shafts are located at preset positions inside the two sealing blocks. The method of claim 1,
The shaft is
and a thrust collar protruding from an outer circumferential surface of the shaft in a radial direction of the shaft and disposed in a space between the two sealing blocks. 3. The method of claim 2,
The two electromagnets each include a coil wound around the shaft,
A magnetic attenuator system in which a current flows in a coil included in each of the two electromagnets. The method of claim 1,
The two sealing blocks include a plurality of protrusions extending in a radial direction of the shaft and disposed to surround the shaft,
The electromagnet includes a plurality of coils each wound on the plurality of protrusions. The method of claim 1,
Further comprising an impeller fastened to be fixed to the shaft,
The shaft includes a real gas inlet hole through which the real gas is branched and introduced, and the impeller includes a real gas outlet hole through which the branched real gas flows,
A magnetic damper system in which heat conducted to the shaft by the branched seal gas is cooled. The method of claim 1,
an axial displacement sensor for detecting a movement in the rotational axis direction of the shaft; and
Further comprising a radial displacement sensor for detecting the radial movement of the shaft,
The axial displacement sensor and the radial displacement sensor transmit the sensed rotational axis direction movement of the shaft and the sensed radial movement of the shaft to the electromagnet so that the electromagnet applies a magnetic force to the shaft.

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