TWI463765B - Magnetic coupling - Google Patents

Description

Magnetic coupling

The invention relates to a coupling technology, in particular to a magnetic force transmitting torque, transmitting a torque through a non-contact and non-mechanical coupling method, and more capable of adjusting a torque, driving a large wheel with a small wheel, driving a small wheel with two wheels or two wheels The principle of the same large mutual drive, the transmission speed is reduced or increased or the same, and the torque is increased or decreased or the same magnetic coupling.

There are quite a few types of rotating machinery, and the use is quite extensive, and the rotating machine needs to be continuously rotated through the driving structure. The conventional transmission structure usually uses a pulley or a direct contact connection with a coupling to mechanically connect the torque to achieve the purpose of driving rotation.

Since each belt has an acceptable mounting tension at the factory, in order to avoid premature damage to the belt, shaft or bearing. Therefore, in practical use, it must be adjusted to allow the installation tension to maintain the optimal use of the transmission components and belts for a long time. However, after long-term use, pulleys, belt-driven couplings, or generally mechanically coupled couplings are often broken for a certain period of time due to time, temperature, or centering problems. Especially for belt-driven couplings, it is often necessary to adjust the tightness of the belt within one month after use. The belt should be replaced within four months to six months, otherwise the belt will break due to the above factors. Therefore, it takes a lot of time, money and manpower to adjust the belt and change the belt regularly. Moreover, the bearing is also quickly damaged by the side tension of the belt for a long time, which is a hidden danger to the rotating machine, and no method or structure for solving this problem has been found so far.

Therefore, the present invention mainly provides a magnetic coupling, the most important being the magnetic force transmitting torque, the non-direct contact with the rotating machinery, the non-mechanical connection transmitting the torque, and the adjustment of the transmission torque, improving the overall reliability, non-contact mode It can avoid the vibration and eliminate the need to change the belt regularly, so there is no need for maintenance, the overall structure is simpler, and the performance is improved. This is the most important spirit of the present invention and the active disclosure.

The object of the present invention is to provide a magnetic coupling, which is mainly applied to a rotating machine, in particular, a non-direct contact, non-mechanical coupling, which reduces the transmission speed, increases or the same, and increases and reduces the torque. Or the same), to adjust the torque according to different needs, improve the overall reliability.

The object of the present invention is to provide a magnetic coupling, which has a simple overall structure and requires no maintenance, and can eliminate vibrations generated during rotation and eliminate periodic load blocking.

To achieve the above object, the present invention provides a magnetic coupling for use in a rotating machine for connecting a drive mechanism or a load mechanism, including a magnetic disk and a conductor disk. The magnetic disk has a circular shape and has a plurality of permanent magnets arranged in a ring shape. The hub of the disk is provided with a hub. The hub is used for connecting a driving mechanism or a load mechanism; the conductor disk is circular, and a hub is disposed at the center of the conductor disk ( The conductor disk is made of a non-magnetic metal material, and the magnetic disk is disposed on a periphery of a surface adjacent to the conductor disk, and has an air gap with the conductor disk, and the other surface of the conductor disk is covered with a magnetic metal.

In a preferred embodiment, the non-magnetic metal material is aluminum or copper. The magnetic metal is iron. The magnetic metal is circular, and the diameter of the magnetic metal is equal to the diameter of the conductor disk. The thickness of the magnetic metal is greater than the thickness of the conductor disk, although in other embodiments the thickness may also be less than or the same. The drive mechanism connects the disk or the conductor disk to rotate, so that the eddy current generated by the magnetic wire cutting conductor disk of the plurality of permanent magnets on the disk generates a magnetic field to transmit the required torque. Moreover, the closer the air gap of the magnetic disk and the conductor disk is, the denser the distribution of magnetic lines of force is, and the farther the air gap of the magnetic disk and the conductor disk is, the thinner the distribution of magnetic lines of force is, thereby adjusting the torque.

Compared with the prior art, the magnetic coupling of the present invention mainly transmits the torque required for rotating the machine in a non-contact and non-mechanical connection manner, which is different from the conventional pulley or coupling, and the conventional coupling is It is a direct contact of contact type. It not only needs to adjust the tightness at regular intervals, but also can not avoid the vibration. It will break after using for a period of time due to time, temperature or heart-to-heart problem. It is necessary to change the belt of the heart continuously, resulting in The increase in manpower and cost, therefore, the present invention can completely solve the above problems, and maintenance can save costs and improve reliability.

The embodiments of the present invention are described by way of specific examples, and those skilled in the art can readily appreciate the other advantages and advantages of the present invention.

The embodiments of the present invention are described below with reference to the drawings, and the following drawings are simplified schematic diagrams, and only the basic concept of the present invention is illustrated in a schematic manner, and only the structures related to the present invention are illustrated in the drawings. Rather than drawing according to the number, shape and size of the components in actual implementation, the types, quantities and proportions of the components in actual implementation are not limited to the illustrations, and can be changed according to the actual design requirements.

First, referring to FIG. 1, FIG. 2 and FIG. 3, it is a perspective structural view, a top view and a side view of a preferred embodiment of the magnetic coupling of the present invention. As shown, the magnetic coupling 1 of the present invention comprises: a magnetic disk 11 and a conductor disk 12.

The magnetic disk 11 is circular, has a plurality of permanent magnets 111 arranged in a ring shape, and a hub 110 is disposed at the center of the disk, and a hub 110 is used to connect the driving mechanism 2 or the load mechanism.

The conductor disk 12 is circular, the diameter of the conductor disk 12 is larger than the diameter of the magnetic disk 11, and the conductor disk 12 is made of a non-magnetic metal material, and the magnetic disk 11 is disposed on the periphery of a surface adjacent to the conductor disk 12 (in different embodiments It is disposed at a different position and has an air gap 10 between the conductor disk 12, and the other surface of the conductor disk 12 opposite to the magnetic disk 11 is covered with a magnetic metal 121. The magnetic metal 121 has a circular shape, and the diameter of the magnetic metal 121 is equal to the diameter of the conductor disk 12. The thickness of the magnetic metal 121 is greater than the thickness of the conductor disk 12 (in other embodiments, the thickness of the magnetic metal 121 may be less than the thickness of the conductor disk 12 or equal to the thickness of the conductor disk 12).

In the present embodiment, the non-magnetic metal material is copper, and the magnetic metal 121 is made of carbon steel. Of course, the material of the non-magnetic metal material is not limited to copper, and may be aluminum or other equivalent materials in other embodiments. The material of the magnetic metal 121 is not limited to carbon steel, and in other embodiments, it may be an equivalent material having magnetic properties. In actual use, the magnetic disk 11 is disposed at a position below the conductor disk 12 near the periphery (in different embodiments, it may be in the upper or horizontal direction, and not necessarily in the peripheral position), and is connected to the conductor disk 12 There is an air gap 10 (shown in FIG. 3 ), and the disk 11 is centered and provided with a driving mechanism 2 or a load mechanism. In the embodiment, the driving mechanism 2 is a motor mechanism, which is not limited thereto. The driving mechanism 2 is not limited thereto. In other embodiments, it may be an engine mechanism, a steam turbine or other equivalent mechanism, and the load mechanism is a fan, a pump, an air compressor, a conveyor belt, and the like. Thereby, the driving mechanism 2 drives the magnetic disk 11 to rotate, and the magnetic field lines generated by the plurality of permanent magnets 111 on the magnetic disk 11 cut the eddy current generated by the conductor disk 12 to generate a magnetic field to transmit the required torque to drive the conductor disk 12 to rotate.

Moreover, the distance between the magnetic disk 11 and the conductor disk 12 can be adjusted axially to adjust the amount of magnetic lines of force, and the distance between the magnetic disk 11 and the conductor disk 12 can be adjusted radially to adjust the amount of magnetic lines of force. Specifically, when adjusting in the axial direction, when the magnetic disk 11 is closer to the conductor disk 12, that is, the smaller the distance of the air gap 10 is, the generated magnetic field lines are denser; on the contrary, when the magnetic disk 11 and the conductor disk 12 are farther apart, That is to say, the larger the distance of the air gap 10, the more sparse the magnetic lines of force are generated. In the radial adjustment, in addition to the proximity of the disk 11 to the conductor disk 12, in principle, the closer the center of the disk 11 is to the center of the conductor disk 12, the denser the magnetic lines of force, and conversely, the center of the disk 11 and the conductor disk The farther the center of 12 is, the thinner the magnetic field lines are. Thereby, the user can adjust the axial or radial distance according to different situations or needs to generate magnetic lines of different density, thereby transmitting different torques. And the larger disk 11 is driven by the smaller disk 11, so that the transmission speed is reduced and the torque is increased.

In different embodiments, a hub may be disposed at the center of the conductor disk 12 for connecting the driving mechanism 2 or the load mechanism, so that the driving mechanism 2 drives the conductor disk 12 to drive the disk 11).

Moreover, in other embodiments, the smaller disk 11 can be driven by the larger disk 11 to achieve the purpose of increasing the transmission speed and reducing the torque. Or the same size of the disk 11 and the conductor disk 12 Driven to reach the same speed as the transmission, while the same purpose of torque. It can be adjusted according to different needs.

Please refer to FIG. 4 again, which is a reference diagram of the use state of a preferred embodiment of the magnetic coupling of the present invention. As shown in the figure, the magnetic coupling 1 of the present invention is applied to a rotating machine, in the present embodiment. In the example, the fan 3 is used as an embodiment. In use, the fan 3 is coupled to the center of the conductor disk 12, whereby when the drive mechanism 2 drives the disk 11 to rotate, the magnetic field wire is cut by the plurality of permanent magnets 111 on the disk 11. The generated eddy current generates a magnetic field, and the required torque is transmitted, and the conductor disk 12 is rotated to drive the fan 3 connected to the conductor disk 12 to rotate.

Thereby, the rotating machine is driven by non-contact and non-mechanical connection, and has the following advantages: energy saving, simple structure, simple centering, simple installation, no maintenance, adjustable rotating machine speed, use in harsh environments, Eliminates difficult vibrations and isolation vibrations, eliminates periodic load stalls, provides efficient torsional transmission, is suitable for pulsed loads, and has high reliability.

Compared with the prior art, the magnetic coupling of the present invention mainly transmits the torque required for rotating the machine in a non-contact and non-mechanical connection manner, which is different from the conventional pulley or coupling, and the conventional coupling is It is a direct contact of contact type. It is not only necessary to adjust the tightness at regular intervals, but also can not avoid the vibration, and it will break after using for a period of time due to time, temperature or heart-to-heart problem. It is necessary to constantly change the belt of the heart. After breaking for a period of time, it is necessary to continuously replace the belt of the heart, resulting in an increase in labor and cost. Therefore, the present invention can completely solve the above problems, and maintenance can save cost and improve reliability.

While the foregoing description of the preferred embodiments of the invention, the embodiments of the invention The spirit and scope of this creative principle. Modifications of many forms, structures, arrangements, ratios, materials, components and components can be made by those skilled in the art to which the invention pertains. Therefore, the embodiments disclosed herein are to be considered as illustrative and not restrictive. The scope of the present invention is defined by the scope of the appended claims, and the legal equivalents thereof are not limited to the foregoing description.

1. . . Magnetic coupling

10. . . Air gap

11. . . Disk

110. . . Hub

111. . . permanent magnet

12. . . Conductor disk

121. . . Magnetic metal

2. . . Drive mechanism

3. . . Fan

1 is a perspective structural view of a preferred embodiment of a magnetic coupling of the present invention;

2 is a top plan view of a preferred embodiment of the magnetic coupling of the present invention;

Figure 3 is a side view of a preferred embodiment of the magnetic coupling of the present invention;

Fig. 4 is a view showing the state of use of a preferred embodiment of the magnetic coupling of the present invention.

1. . . Magnetic coupling

10. . . Air gap

11. . . Disk

110. . . Hub

111. . . permanent magnet

12. . . Conductor disk

121. . . Magnetic metal

2. . . Drive mechanism

Claims (10)

A magnetic coupling is applied to a rotating machine for connecting a driving mechanism or a load mechanism, comprising: a magnetic disk having a circular shape and a plurality of permanent magnets arranged in a ring shape, wherein the disk is provided with a hub, the hub (hub) for connecting a driving mechanism or a load mechanism; and a conductor disk having a circular shape, the conductor disk being made of a non-magnetic metal material, and a hub is provided in the center of the conductor disk, and the hub is used for the hub To connect the driving mechanism or the loading mechanism, wherein the magnetic disk is disposed adjacent to a surface of the conductor disk and has an air gap between the conductive disk and the other surface of the conductive disk is covered with a magnetic metal. The magnetic coupling of claim 1, wherein the non-magnetic metal material is aluminum or copper or other conductor. The magnetic coupling of claim 1, wherein the magnetic metal is carbon steel or magnetic metal. The magnetic coupling of claim 1, wherein the magnetic metal has a circular shape, and the diameter of the magnetic metal is equal to, smaller than, or larger than a diameter of the conductor disk. The magnetic coupling of claim 1 wherein the diameter of the disk is less than, equal to, or greater than the diameter of the conductor disk. The magnetic coupling according to claim 1, wherein the driving mechanism is coupled to the magnetic disk or the conductive disk is rotated, so that the eddy current generated by the magnetic line cutting conductor disk of the plurality of permanent magnets on the magnetic disk generates a magnetic field to transmit the required torque. The magnetic coupling according to claim 1, wherein the closer the air gap of the magnetic disk and the conductor disk is, the denser the distribution of magnetic lines of force, and the farther the air gap of the magnetic disk and the conductor disk is, the thinner the distribution of magnetic lines of force is. The magnetic coupling according to claim 1, wherein the closer the center of the disk is to the center of the conductor disk, the denser the distribution of the magnetic lines of force, and the farther the center of the disk is from the center of the conductor disk, the magnetic field line The more sparse the distribution. The magnetic coupling according to claim 1, wherein the driving mechanism is a motor mechanism, an engine mechanism, a steam turbine, or the like. The magnetic coupling according to claim 1, wherein the load mechanism is a fan, a pump, an air compressor, a conveyor belt, or the like.