KR20090045998A - Magnet bearing - Google Patents

Abstract

The present invention discloses a magnetic bearing having the same polarity on the outer ring and the inner ring. The magnetic bearing according to the present invention includes an outer ring case, an inner ring case rotatably installed in the outer ring case, and a recess is formed in the center thereof, and a portion in which the recess is formed is formed to have the same polarity and the outer ring. An outer ring magnet member installed in a case, and one side is installed in the inner ring case so that the groove is embedded, the one side includes an inner ring magnet member having the same polarity as the groove. Therefore, by using the repulsive force of the magnet having the same polarity to prevent contact between the outer ring and the inner ring and injecting magnetic fluid between the magnets to minimize the friction between the magnets to improve durability and airtightness.

Magnet, bearing, repulsive force, attraction

Description

Magnetic Bearings

The present invention relates to a magnetic bearing having the same polarity on the outer ring and the inner ring, and more particularly, to inject magnetic fluid between the magnets while preventing contact between the outer ring and the inner ring using the repulsive force of the magnet having the same polarity. The present invention relates to a magnetic bearing capable of improving durability and airtightness by minimizing frictional force between magnets.

In general, a bearing is a mechanical element that plays a role of rotating the shaft while fixing the shaft of the rotating machine to a certain position and supporting the weight of the shaft and the load on the shaft. The bearing is in contact with the bearing. According to the contact state, it is classified into two types: sliding bearing and rolling bearing.

The sliding bearing is surrounded by all or part of the surface of the bearing journal portion, and there is usually lubricating oil between the bearing and the contact surface of the journal, which is in contact with the surface, so that the frictional resistance is higher than that of the rolling bearing when the shaft rotates. Although large, the ability to support loads generally has great advantages. On the other hand, rolling bearings have a configuration in which the ball or roller of the shaft is in contact with each other. When the shaft rotates, the ball or roller rotates as well, so the friction resistance is small. There are cases where it is caught vertically and axially, and bearings must be able to withstand these loads and ensure rotational movement.

As described above, the bearing has a lot of different structures depending on the load direction, and the radial bearing is used when the load is applied perpendicular to the shaft, and the thrust bearing is used when the load is applied in the axial direction. For example, in the case of ball bearings, there are needle bearings, which use lady's ball bearings, thrust ball bearings and thin long needle rollers.

By the way, the general bearing as described above is complicated in configuration, and the bearing is frequently worn and broken by frictional force. In order to solve this problem, Korean Utility Model Model No. 341078 discloses a magnetic bearing using a magnet.

In the magnetic bearing disclosed in Korean Utility Model Registration No. 341078, the inner and outer rings of the bearing are formed in a ring of a predetermined standard, and a magnet having magnetic force is attached thereto. The magnet has a multi-stepped stepped portion formed at a position corresponding to each other on the outer circumferential surface of the inner ring and the inner circumferential surface of the outer ring, and is formed to have the same polarity. That is, the inner ring and the outer ring have a predetermined interval by a magnet having the same polarity.

However, in the conventional magnetic bearing as described above, the surfaces of the magnets which are in contact with each other are formed in multiple stages, so that the force acts in the same direction as the repulsive force acting between the magnets and the axial load acting on the outer ring or inner ring. This problem is separable.

In addition, since the housing for supporting the magnet and the magnet installed inside the housing are in contact with each other, the housing and the magnet may be damaged, thereby degrading durability and causing a problem of foreign matter penetrating into the bearing. .

The present invention has been made to solve the above conventional problems, by using a repulsive force of a magnet having the same polarity to prevent contact between the outer ring and the inner ring and injecting a magnetic fluid between the magnets and frictional force between the magnets It is an object of the present invention to provide a magnetic bearing that can minimize durability and improve durability and airtightness.

In order to achieve the above object, the magnetic bearing according to the present invention includes an outer ring case, an inner ring case rotatably installed in the outer ring case, and a recess is formed in the center thereof, and the recess is formed in the same polarity. Is formed to have an outer ring magnet member is installed in the outer ring case, and one side is installed in the inner ring case so that the groove is embedded, the one side includes an inner ring magnetic member having the same polarity as the groove It features.

Here, the outer ring magnet member and the inner ring magnet member characterized in that it further comprises a sealing magnet member to prevent foreign matter from penetrating into the inside.

The outer ring magnet member may be coupled to the outer ring case so as to be spaced apart from the outer circumferential surface of the inner ring magnet member, and a portion corresponding to the outer circumferential surface of the inner ring magnet member may have the same polarity as that of the inner ring magnet member. A first magnet and an outer circumferential surface portion of the inner ring magnet member are attached to the outer ring case so as to protrude toward the inner circumferential surface side of the first magnet from both sides of the first magnet, and a portion corresponding to the inner ring magnetic member is attached to the inner ring. It characterized in that it comprises a ring-shaped second and third magnet having the same polarity as the magnet member.

In addition, the sealing magnet member is composed of a ring-shaped first magnet coupled to the outer ring case, and a ring-shaped second magnet attached to the inner ring case to be located inside the first magnet of the sealing magnet member. It is characterized in that each provided on both sides of the outer ring magnet member.

In addition, a corresponding portion of the first and second magnets is provided to have different polarities so that a magnetic fluid is injected between the first and second magnets.

According to the magnetic bearing according to the embodiment of the present invention, since the outer ring and the inner ring are prevented from contacting each other by using the repulsive force of the magnet having the same polarity, a magnetic fluid is provided between the magnets, so that frictional force between the magnets is minimized and durability is achieved. And the airtightness is improved.

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. Prior to this, the terms or words used in the present specification and claims are defined in the technical spirit of the present invention on the basis of the principle that the inventor can appropriately define the concept of the term in order to explain his invention in the best way. It must be interpreted to mean meanings and concepts.

Hereinafter, a magnetic bearing according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2, the magnetic bearing 100 is provided with an outer ring case 110 fixed to a structure (not shown), and is rotatably provided in the outer ring case 110, and a rotating body therein. The inner ring case 120 is inserted, and the outer ring magnet member 130 and the inner ring magnet member 140 are installed between the outer ring case 110 and the inner ring case 120. In addition, sealing magnet members 150 are provided at both sides of the magnet bearing 100 to prevent foreign substances from penetrating into the outer ring magnet member 130 and the inner ring magnet member 140.

The outer ring case 110 of the magnet bearing 100 is provided with a predetermined space therein, the outer ring magnet member 130 and the sealing magnet member 150 is attached to the space portion. The inner ring case 120 is also provided with a predetermined space therein, the inner ring magnet member 140 and the sealing magnet member 150 is attached to the space portion. At this time, the outer ring case 110 and the inner ring case 120 is divided so that the outer ring magnet member 130, the inner ring magnet member 140 and the sealing magnet member 150 can be easily coupled. In addition, the outer ring case 110 and the inner ring case 120 that are divided are firmly coupled by a long bolt B and a nut N fastened thereto. In this embodiment, the outer ring case 110 and the inner ring case 120 is shown to be coupled using the bolt (B) and the nut (N), but can also be coupled to each other by welding.

The outer ring magnetic member 130 attached to the outer ring case 110 is formed with a groove 130a so that the outer side of the inner ring magnetic member 140 is accommodated in the center portion, and a portion where the groove 130a is formed has the same polarity. It is configured to. Specifically, the outer ring magnet member 130 is a ring-shaped first magnet 131 is coupled to the outer ring case 110 so as to be spaced apart from the outer circumferential surface of the inner ring magnet member 140, the first magnet 131 Second and third magnets 133 and 135 in the form of rings are coupled to the outer ring case 110 so as to be located at both sides of the.

In this case, the outer diameter D1 of the second and third magnets 133 and 135 is smaller than the outer diameter D2 of the first magnet 131 and larger than the inner diameter D3 so as to be exposed to the inside of the first magnet 131. The inner diameter D4 of the second and third magnets 133 and 135 is smaller than the inner diameter D3 of the first magnet 131. Therefore, the groove 130a in which the inner ring magnet member 140 is accommodated in the outer ring magnet member 130 is formed.

The first, second, and third magnets 131, 133, and 135 have the same polarity as that of the inner ring magnetic member 140 in a portion corresponding to the inner ring magnetic member 140 so that the repulsive force acts on the inner ring magnetic member 140. Have For example, when the outer circumferential surface side of the inner ring magnetic member 140 has an N pole, the first magnet 131 of the outer ring magnetic member 130 corresponding thereto has an N pole, and the inner side of the outer ring magnetic member 130 is formed. The second and third magnets 133 and 135 have an N pole inside thereof. Due to this, a repulsion force is applied between the outer ring magnet member 130 and the inner ring magnet member 140 to form a gap (GAP) of a predetermined interval so that the inner ring case 120 and the outer ring case 110 of the magnet bearing 100 are formed. It will rotate without contact.

The sealing magnet member 150 provided to seal the inner ring magnet member 140 and the outer ring magnet member 130 has a ring-shaped first and second coupling to the outer ring case 110 and the inner ring case 120, respectively. Magnets 151 and 153 are provided on both sides of the outer ring magnet member 130. The first magnet 151 of the sealing magnet member 150 is coupled to the outer ring case 110, the second magnet 153 is located inside the outer ring case 110 is coupled to the inner ring case 120. In addition, the sealing magnet member 150 is provided with a magnetic fluid 155 between the first and second magnets 151 and 153 to completely seal between the first magnet 151 and the second magnet 153.

In this case, the sealing magnet member 150 prevents the magnetic fluid 155 from being separated between the first and second magnets 151 and 153 and at the same time the inner ring case 120 is separated from the outer ring case 110. Corresponding portions of the first and second magnets 151, 153 have different polarities so as to be prevented. That is, since corresponding portions of the first and second magnets 151 and 153 of the sealing magnet member 150 have different polarities, attraction force is generated between the first and second magnets 151 and 153. The inner ring case 120 and the outer ring case 110 is firmly coupled.

Meanwhile, the magnetic fluid 155 provided between the first and second magnets 151 and 153 of the sealing magnet member 150 may lower the frictional force between the first magnet 151 and the second magnet 153 to reduce the frictional force between the first magnet 151 and the second magnet 153. And wear of the second magnets 151 and 153.

Now, the operation and action of the magnetic bearing according to the present embodiment configured as described above will be described in detail.

The magnetic bearing 100 is fixed to the outer ring case 110 and the inner ring case 120 is fixed to the rotating body in the structure so that the rotating body can rotate smoothly in the structure. And when the inner ring case 120 rotates in the outer ring case 110, the outer ring of the outer ring magnet member 130 having the same polarity as the outer side of the inner ring magnet member 140 so that the outer ring of the inner ring magnet member 140 is generated Since it is accommodated in the recess 130a, the inner ring magnetic member 140 and the outer ring magnetic member 130 are rotated while being in contact with each other by the mutual repulsive force.

In addition, since the first and second magnets 151 and 153 of the sealing magnet member 150 have corresponding polarities, mutual attraction is applied to the inner ring magnetic member 140 and the outer ring magnetic member 130 due to the repulsive force. The inner ring case 120 is prevented from being separated from the outer ring case 110. That is, the magnet bearing 100 is rotated while the inner ring magnet member 140 and the outer ring magnet member 130 is non-contacted by the outer ring case 110 and the inner ring case 120 by the repulsive force, the sealing magnetic member 150 Due to the attraction of the first and second magnets 151 and 153, the inner ring magnet member 140 and the outer ring magnet member 130 maintain a constant interval and the outer ring case 110 and the inner ring case 120 Deviation from each other is prevented.

At this time, foreign matter is prevented from penetrating into the magnetic bearing 100 by the magnetic fluid 155 provided between the first and second magnets 151 and 153 of the sealing magnet member 150.

On the other hand, Figure 3 is a perspective view of the outer ring magnet member 130 according to another embodiment of the present invention, as shown in Figure 3, the outer ring magnetic member 160 has a groove (160a) is formed in a corresponding shape It can also be produced by attaching the ring-shaped magnets (161, 163). That is, the inner sides of the magnets 161 and 163 having the grooves 160a are formed in the same polarity as the inner ring magnet member 140 so that mutual repulsive force is generated, and the outside thereof may be fixed to the outer ring case 110.

What has been described above is only one embodiment for carrying out the present invention, and the present invention is not limited to the above-described embodiment, and the present invention is made without departing from the gist of the present invention as claimed in the following claims. Anyone with ordinary knowledge in this field will have the technical spirit of the present invention to the extent that various modifications can be made.

1 is a perspective view showing the configuration of a magnetic bearing according to an embodiment of the present invention.

2 is a cross-sectional view taken along the line A-A of Figure 1 showing the configuration of the magnetic bearing according to the embodiment of the present invention.

Figure 3 is a perspective view showing another embodiment of the outer ring magnet member of the present invention.

♠ Code description for the main part of the drawing ♠

100: magnetic bearing 110: outer ring case

120: inner ring case 130: outer ring magnet member

140: inner ring magnet member 150: sealing magnet member

Claims (5)

Outer ring case; An inner ring case rotatably installed in the outer ring case; Grooves are formed in the center portion, and the grooves are formed in the outer ring magnetic member is formed to have the same polarity is installed in the outer ring case; An inner ring magnet member having one side installed in the inner ring case to be embedded in the groove, and one side having the same polarity as the groove portion; Magnetic bearing comprising a. The method of claim 1, And a sealing magnet member to prevent foreign matter from penetrating into the outer ring magnet member and the inner ring magnet member. The method according to claim 1 or 2, The outer ring magnet member is coupled to the outer ring case so as to be spaced apart from the outer circumferential surface of the inner ring magnet member, and a portion corresponding to the outer circumferential surface of the inner ring magnet member has the same polarity as the inner ring magnet member. A magnet is attached to the outer ring case so as to protrude from both sides of the first magnet to the inner circumferential surface side of the first magnet so that a portion of the inner circumferential surface of the inner ring magnet member is inserted, and a portion corresponding to the inner ring magnet member is the inner ring magnet. And a ring-shaped second and third magnet having the same polarity as the member. The method of claim 3, wherein The sealing magnet member is composed of a ring-shaped first magnet coupled to the outer ring case, and a ring-shaped second magnet attached to the inner ring case so as to be located inside the first magnet of the sealing magnet member. And a magnetic fluid provided between the first magnet and the second magnet. The method of claim 4, wherein The first and second magnets, the magnetic bearing, characterized in that the corresponding portion has a different polarity to prevent the magnetic fluid from being separated.

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