KR101335695B1 - Magnetic levitation transporting system for display pannel - Google Patents

Abstract

The magnetic levitation display panel transport system according to an aspect of the present invention includes a permanent magnet module having a plurality of permanent magnet pieces having different magnetization directions, and a floating device including a motor for rotating the permanent magnet module, and the display panel. It includes a transfer device for forming an eddy current to generate a driving force.

Description

MAGNETIC LEVITATION TRANSPORTING SYSTEM FOR DISPLAY PANNEL}

The present invention relates to a magnetic levitation system, and more particularly, to a display panel transfer system using magnetic levitation.

The magnetic levitation system refers to a system that uses electric magnetic force to float to a certain height from a track to move a carriage or the like. The magnetic levitation system includes a bogie that floats and propels on a track, and a vehicle body mounted on the bogie to form a carriage or wagon.

The magnetic levitation system applies the attractive force or the repulsive force by the electromagnet between the bogie and the orbit to propel the bogie away from the orbit. As described above, the magnetic levitation system is driven in a non-contact state with the orbit, so that it is possible to carry out the high speed propulsion with less noise and vibration.

The floating method of the magnetic levitation system includes a suction method using the attractive force of the magnet and a repulsion type using the repulsive force of the magnet.

In addition, the floating method of the magnetic levitation system has a superconducting method and a phase conducting method according to the principle of the electromagnet. The superconducting method is applied at high speed because there is no electric resistance and strong magnetic force can be obtained, and the phase conduction method is applied for stopping distance of medium speed.

Reaction type includes permanent magnet repulsion using repulsive force acting between permanent magnets of the same pole, and inductive repulsion floating by magnetic field repulsive force caused by induced current of ground coil induced by movement of magnet attached to vehicle. Repulsion is easier to control than recognition, and suction has the advantage that it can be injured even at low speeds.

In particular, the inductive repulsion is not sensitive to changes in load and is suitable for ultra-high speeds. The magnet of the vehicle uses a superconducting magnet and requires a very low temperature for superconducting.

Both suction and repulsion are generating flotation by using an electromagnet, but in order to obtain a desired flotation force, the volume of the electromagnet must be large, and accordingly, power consumption is large.

As such, the conventional magnetic levitation system needs to mount an electromagnet to the vehicle, so that the weight of the vehicle increases, so that a larger flotation force is required, and power consumption is large.

On the other hand, the display panel is conveyed by a roller system or a belt system, there is a problem that the display panel is scratched by the friction of the display panel and the roller or belt.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a magnetic levitation display panel transport system capable of stably transporting the display panel.

The magnetic levitation display panel transport system according to an aspect of the present invention includes a permanent magnet module having a plurality of permanent magnet pieces having different magnetization directions, and a floating device including a motor for rotating the permanent magnet module, and the display panel. It includes a transfer device for forming an eddy current to generate a driving force.

The transfer apparatus may include a transfer magnet module including a plurality of permanent magnet pieces having an outer circumferential surface facing the display panel and having a different magnetization direction, and an electric motor for rotating the transfer magnet module. The device may consist of a linear motor.

The transfer apparatus may include a core including a groove formed between the protrusion and the protrusion and a coil inserted into the groove, wherein the permanent magnet module has an N-type permanent magnet piece having an N-type polarity and the N-type permanent magnet. It is disposed between the pieces and may include an S-type permanent magnet piece having an S-type polarity on the upper surface.

The permanent magnet module may be disposed so that an upper surface thereof faces the display panel and form a Halbach array, and the magnetization direction of the permanent magnet pieces disposed along the circumferential direction of the permanent magnet module may be permanent. It can be arranged to change in the thickness direction of the magnet module.

The permanent magnet module is positioned between a first magnetic pole magnet piece having a magnetization direction facing downward, a second magnetic pole magnet piece having a magnetization direction facing upward, and between the first magnetic pole magnet piece and the second magnetic pole magnet piece. And an induction magnet piece having a magnetization direction in a direction from the first magnetic pole magnet piece to the second magnetic pole magnet piece, wherein the induction magnet piece is formed in plural, and the magnetization direction of the induction magnet pieces is the first. It may be arranged to gradually change in the magnetization direction of the second magnetic pole magnet piece in the magnetization direction of the magnetic pole magnet piece.

The permanent magnet module includes a first permanent magnet part and a second permanent magnet part disposed outside the first permanent magnet part, and the first permanent magnet part is located in a lower side than the second permanent magnet part. It can be formed to have a larger magnetic force per area.

The first permanent magnet part may be formed to have a height greater than that of the second permanent magnet part. The first permanent magnet part and the second permanent magnet part may be formed of a plurality of stacked permanent magnets, and the first The permanent magnet part may be made of more permanent magnets than the second permanent magnet part.

The magnetic force per unit volume of the first permanent magnet part may be greater than the magnetic force per unit volume of the second permanent magnet, and the first permanent magnet part and the second permanent magnet part are arranged along the circumferential direction of the permanent magnet module. It may include a plurality of permanent magnet unit, the permanent magnet unit may be arranged to have a Halbach arrangement that the magnetization direction is changed along the circumferential direction of the permanent magnet module.

The permanent magnet module has a smaller magnetic force per unit area between the first permanent magnet part and the second permanent magnet part with a lower magnetic force than the first permanent magnet part, and faces downward than the second permanent magnet part. It may include a third permanent magnet portion having a larger magnetic force per unit area in the plane, the floating device and the transfer device may be fixed to the ground. In addition, the display panel may include a conductive layer formed between the insulating layer and the insulating layer.

The magnetic levitation display panel transfer system according to an embodiment of the present invention transfers the display panel in a non-contact manner, thereby stably transferring the display panel without scratching.

In addition, since no floating device or propulsion device is installed in the display panel, the display panel can be easily transferred using the floating device and the propulsion device installed on the ground.

1 is a cross-sectional view showing a magnetic levitation display panel transfer system according to a first embodiment of the present invention.
2 is a perspective view illustrating a floating device and a conveying device of the magnetic levitation display panel conveying system according to the first embodiment of the present invention.
3 is a perspective view showing a permanent magnet module according to a first embodiment of the present invention.
Figure 4 is a perspective view showing a permanent magnet module according to a second embodiment of the present invention.
5 is a perspective view showing a permanent magnet module according to the third embodiment.
6 is a plan view illustrating a magnetic levitation display panel transport system according to a fourth exemplary embodiment of the present invention.
7 is a plan view showing a permanent magnet module according to a fifth embodiment of the present invention.
FIG. 8 is a cross-sectional view taken along the line VII-VII in FIG. 7.
9 is a perspective view showing a case of a permanent magnet module according to a fifth embodiment of the present invention.
10 is a cross-sectional view illustrating a permanent magnet module of the magnetic levitation display panel transport system according to the sixth embodiment of the present invention.
11 is a cross-sectional view showing a permanent magnet module of the magnetic levitation display panel transfer system according to the seventh embodiment of the present invention.
12 is a plan view illustrating a permanent magnet module of the magnetic levitation display panel transport system according to the eighth embodiment of the present invention.
13 is a plan view of a magnetic levitation display panel transport system according to a ninth embodiment of the present invention.
FIG. 14 is a cross-sectional view taken along the line XIV-XIV of FIG. 13.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

1 is a cross-sectional view showing a magnetic levitation display panel transfer system according to a first embodiment of the present invention, Figure 2 shows a floating device and a transfer device of the magnetic levitation display panel transfer system according to a first embodiment of the present invention One perspective view.

Referring to FIGS. 1 and 2, the magnetic levitation display panel transport system 100 according to the present embodiment includes a floating device 140 and a transport device 130 positioned below the display panel 120. . The floating device 140 and the transfer device 130 are fixed to the ground and the display panel 120 is lifted from the floating device 140 and the transfer device 130 and transferred.

The display panel 120 may be formed of various types of display panels having metal electrodes, such as a liquid crystal display panel and an organic light emitting display panel. The display panel 120 includes two transparent substrates 121 and a conductor layer 123, and the conductor layer 123 is formed between the transparent substrates 121. The transparent substrate 121 may be generally made of glass, synthetic resin, or the like constituting the display panel 120, and the conductor layer 123 may be made of transparent metal electrodes such as ITO, ATO, AZO, copper, silver, platinum, or the like. Can be.

After the display panel 120 is manufactured, the display panel 120 may be transferred by a roller or the like, and scratches may occur on the display panel 120 by contact with the rollers. Preventing such scratches is a very important factor that can reduce the defective rate of the display panel.

A transfer plate 127 formed along the moving path of the display panel 120 is installed above the floating device 140 and the transfer device 130. The transfer plate 127 is a member for transmitting the magnetic force generated in the flotation device 140 and the transfer device 130 to the display panel 120 and is made of stainless steel, synthetic resin, or the like. However, the present invention is not limited thereto, and the transfer plate 127 is sufficient as long as it can pass a magnetic force, and there is no limitation on the composition material.

The floating device 140 includes a plurality of permanent magnet modules 145 facing the display panel 120 and an electric motor 141 for rotating the permanent magnet modules 145.

The permanent magnet modules 145 are arranged in a plurality of rows and columns and are arranged along a moving path of the display panel, and the upper surface of the permanent magnet module 145 is disposed toward the display panel 120. The electric motor 141 is connected through the permanent magnet module 145 and the drive shaft 147, and the permanent magnet module 145 has a plurality of permanent magnet pieces having different magnetization directions. The driving shaft 147 may be vertically installed with respect to the display panel 120, and in particular, may be vertically installed with respect to the display panel 120.

As shown in FIG. 3, the permanent magnet module 145 is inserted into the case 144, and includes an N-type permanent magnet piece 142 and an S-type permanent magnet piece 143. The permanent magnet module 145 is formed in a substantially circular ring shape, the S-type permanent magnet piece 143 is inserted between the N-type permanent magnet piece 142 and substantially between the N-type permanent magnet piece 142 Type permanent magnet pieces 143 are alternately arranged.

Accordingly, when the permanent magnet module 145 rotates, an electric field is induced by Faraday's law, and a current is generated in the display panel 120 due to the induced electric field. That is, an electromotive force is formed to interfere with the change of the magnetic field of the magnet in the direction in which the permanent magnet module 145 moves, and this electromotive force generates an eddy current in the conductor layer 123 of the display panel 120. The intensity of the eddy current is proportional to the conductivity of the conductor layer 123, the moving speed of the permanent magnet module 145, and the magnitude of the magnetic flux density in the normal direction. When an eddy current occurs, a magnetic force called Lorentz's force is generated, and the vertical component of the magnetic force acts as a floating force.

In addition to the floating force caused by the Lorentz force, the resistance is also generated, the drag force (drag-force) refers to the force acting in the direction opposite to the rotation direction of the permanent magnet module 145. Resistance is large at low speeds, but decreases with increasing speed, and flotation increases with increasing speed. In this embodiment, the resistive force is generated in the rotation direction of the permanent drive shaft 147 instead of the direction in which the display panel 120 moves, and the permanent drive shaft 147 rotates at high speed by the electric motor 141, thereby minimizing the resistive force. .

On the other hand, the transfer device 130 includes a motor 136 for rotating the transfer magnet module 135 and the transfer magnet module 135. The transfer magnet module 135 is formed in a cylindrical shape and is formed in the width direction of the transfer plate 127. The transfer magnet module 135 includes permanent magnet pieces having different magnetization directions and is laid down so that the outer circumferential surface thereof faces the display panel 120. The transfer magnet module 135 is connected to the electric motor 136 via the drive shaft 137 to be rotated by the electric motor 136. In this case, the driving shaft 137 is disposed in parallel with the display panel 120.

The transfer magnet module 135 includes an N-type permanent magnet piece 131 and an S-type permanent magnet piece 132, and the N-type permanent magnet piece 131 and the S-type permanent magnet piece 135 are transfer magnet modules 135. ) Is arranged along the circumferential direction. In addition, the S-type permanent magnet piece 132 is installed between the N-type permanent magnet piece 131 is made of a structure in which the N-type permanent magnet piece 131 and the S-type permanent magnet piece 132 are alternately installed. In the present description, the N-type permanent magnet piece means that the surface facing the display panel has an N-type polarity, and the S-type permanent magnet piece means that the surface facing the display panel has an S-type polarity. In this case, the surface facing the display panel means the upper surface.

When the transfer magnet module 135 rotates, magnetic fluxes that move in time and space generate eddy currents in the conductor layer 123 of the display panel 120. The interaction between the eddy currents and the air magnetic flux is represented by Lorentz's force equation. When the transfer device 130 is applied as in the present embodiment, propulsion force may be generated by the action of the flat panel display panel 120.

As such, the magnetic levitation display panel transport system 100 according to the present exemplary embodiment includes a flotation device 140 and a transfer device 130 that exert a magnetic force on the display panel 120. As a result, scratches may be prevented from occurring on the display panel 120.

4 is a perspective view illustrating a permanent magnet module of the magnetic levitation display panel transport system according to the second embodiment of the present invention.

Referring to FIG. 4, the magnetic levitation display panel transport system according to the present embodiment has the same structure as the magnetic levitation display panel transport system according to the first embodiment except for the structure of the permanent magnet module 151. Since it is made, duplicate description of the same structure is omitted.

The permanent magnet module 151 according to the present embodiment is formed in a circular ring shape and includes a plurality of permanent magnet pieces 151a, 151b, 151c, 151d, and 151e. The permanent magnet pieces 151a, 151b, 151c, 151d, and 151e are arranged along the circumferential direction, and the magnetization direction of the permanent magnet pieces 151a, 151b, 151c, 151d, and 151e becomes the permanent magnet module as the circumferential direction progresses. 151 is arranged to change in the thickness direction. The magnetization direction is changed in the thickness direction in the present description means that the magnetization directions of the permanent magnet pieces 151a, 151b, 151c, 151d, and 151e constituting the permanent magnet module 151 are different.

The permanent magnet module 151 includes guide magnet pieces 151c, 151d, and 151e disposed between the magnetic pole magnet pieces 151a and 151b and the magnetic pole magnet pieces 151a and 151b. The magnetic pole magnet pieces 151a and 151b and the guide magnet pieces 151c, 151d and 151e are arranged along the circumferential direction of the permanent magnet module 151.

The first magnetic pole magnet piece 151a has a magnetization direction toward the lower side (the direction toward the surface), and the second magnetic pole magnet piece 151b has a magnetization direction toward the upper side (the direction toward the display panel). In the present description, the upper side and the lower side are based on the direction of gravity.

Accordingly, the first magnetic pole magnet piece 151a emits magnetic force lines downward, and the second magnetic pole magnet piece 151b emits magnetic force lines upward. The guide magnet pieces 151c, 151d, and 151e serve to guide the lines of magnetic force, and are arranged such that the magnetization direction gradually changes from the first magnetic pole magnet piece 151a to the second magnetic pole magnet piece 151b. The guide magnet pieces 151c, 151d, and 151e move the line of magnetic force emitted from the first magnetic pole magnet piece 151a to the second magnetic pole magnet piece 151b, so that the magnetic force lines extending downward are not concentrated and spread. The magnetic field lines going upward are concentrated. The permanent magnet module 151 may be formed by dividing the permanent magnet having a constant magnetization direction into several pieces and then combining them.

Even if the permanent magnet module 151 according to the present embodiment is made of an annular shape, the magnetization direction is not changed in the circumferential direction, but the magnetization direction is changed in the vertical direction, so that the permanent magnet module 151 has the strength of the magnetic field formed at the bottom. The magnetic field formed at the top can be concentrated while minimizing. Therefore, the magnetic field of the permanent magnet module 151 is concentrated in the upward direction can obtain a larger flotation force than the existing permanent magnet.

When the permanent magnet module 151 rotates, an electric field is induced by Faraday's law, and a current is generated in the display panel 120 due to the induced electric field. That is, an electromotive force is formed to interfere with the change of the magnetic field of the magnet in the direction in which the permanent magnet module 151 moves, and this electromotive force generates an eddy current in the display panel 120. The intensity of the eddy current is proportional to the conductivity of the display panel 120, the moving speed of the permanent magnet module 151, and the magnitude of the magnetic flux density in the normal direction.

If the permanent magnet module 151 has a Halbach array as in this embodiment, the magnetic flux density in the normal direction increases by 1.4 times or more, thereby generating a larger eddy current. When an eddy current occurs, a magnetic force called Lorentz's force is generated, and the vertical component of the magnetic force acts as a floating force.

As described above, according to the present exemplary embodiment, a large flotation force may be generated by using the permanent magnet module 151 having the Halbach arrangement, and thus, power consumption for injuries may be significantly reduced as compared to a conventional magnetic levitation system. .

In the present embodiment, the permanent magnet module 151 is illustrated as being composed of a Halbach array of eight elements, but the present invention is not limited thereto.

5 is a perspective view illustrating a permanent magnet module 152 of the magnetic levitation display panel transport system according to the third embodiment.

Referring to FIG. 5, the magnetic levitation display panel transport system according to the present embodiment has the same structure as the magnetic levitation display panel transport system according to the first embodiment except for the structure of the permanent magnet module 152. Since it is made, duplicate description of the same structure is omitted.

The permanent magnet module 152 according to the present embodiment includes a guide magnet piece 152c disposed between the magnetic pole magnet pieces 152a and 152b and the magnetic pole magnet pieces 152a and 152b. The magnetic pole magnet pieces 152a and 152b and the guide magnet piece 152c are arranged to extend in the circumferential direction of the permanent magnet module 152. Accordingly, the permanent magnet module 152 has a substantially circular ring shape.

The first magnetic pole magnet piece 152b emits magnetic force lines downward, and the second magnetic pole magnet piece 152a emits magnetic force lines upwards. The guide magnet pieces 152c serve to guide the lines of magnetic force, and the magnetization direction is a direction from the first magnetic pole magnet piece 152b to the second magnetic pole magnet piece 152a. Accordingly, the guide magnet pieces 152c move the line of magnetic force emitted from the first magnetic pole magnet piece 152b to the second magnetic pole magnet piece 152a. Therefore, the lines of magnetic force going downward are not concentrated and spread, but the lines of magnetic force going upward are concentrated. The permanent magnet module 152 may be formed by dividing the permanent magnet having a constant magnetization direction into several pieces, and then combining them.

The permanent magnet module 152 according to the present embodiment may compact the magnetic field formed at the top while minimizing the strength of the magnetic field formed at the bottom. Therefore, the magnetic field of the permanent magnet module 152 may be concentrated in the upward direction to obtain a larger flotation force than the existing permanent magnet.

6 is a plan view illustrating a magnetic levitation display panel transport system according to a fourth exemplary embodiment of the present invention.

Referring to FIG. 6, the magnetic levitation display panel conveying system 110 according to the present embodiment is conveyed with the floating device 114, the conveying device 113, and the floating device 140 positioned below the display panel. The transfer plate 117 is formed along the movement path of the display panel on the top of the device 130.

The floating device 114 includes a plurality of permanent magnet modules facing the display panel and a motor for rotating the permanent magnet module. Since the floating apparatus according to the present embodiment has the same structure as the floating apparatus according to the first embodiment described above, duplicate description of the same structure is omitted.

The transfer apparatus 113 includes a motor 113b for rotating the transfer magnet module 113a and the transfer magnet module 113b. The transfer magnet module 135 is formed in a cylindrical shape. The transfer magnet module 135 includes permanent magnet pieces having different magnetization directions and is laid down so that the outer circumferential surface thereof faces the display panel 120. The transfer magnet module 135 is installed between the floating device, and is disposed at the center in the width direction of the transfer plate 117.

The transfer magnet module 113a is connected to the motor 113b via the drive shaft 113c and rotated by the motor 113b. In this case, the driving shaft 113c is disposed in parallel with the display panel.

The transfer magnet module 113a includes N-type permanent magnet pieces and S-type permanent magnet pieces, and S-type permanent magnet pieces are installed between the N-type permanent magnet pieces so that the N-type permanent magnet pieces and the S-type permanent magnet pieces alternately. It consists of an installed structure.

When the transfer magnet module 113a rotates, magnetic fluxes that move in time and space generate eddy currents in the display panel 120. The interaction between the eddy currents and the air magnetic flux is represented by Lorentz's force equation. When the transfer device 130 is applied as in the present embodiment, propulsion force may be generated by the action of the flat panel display panel 120.

When the display panel is magnetically injured and transported as in the present exemplary embodiment, even if a small size transfer magnet module is installed in the center, sufficient display force can be generated to easily transport the display panel.

7 is a plan view illustrating a permanent magnet module of a magnetic levitation display panel transport system according to a fifth exemplary embodiment of the present invention, and FIG. 8 is a cross-sectional view taken along the line VII-VII of FIG. 7.

Referring to FIGS. 7 and 8, the magnetic levitation display panel transport system according to the present embodiment is identical to the magnetic levitation display panel transport system according to the first embodiment except for the structure of the permanent magnet module 160. Since the structure is made of a duplicate description of the same structure is omitted.

The permanent magnet module 160 includes a case 161 and a plurality of permanent magnets inserted into the case 161.

The permanent magnet part includes a second permanent magnet part 163 disposed outside the first permanent magnet part 162 and the first permanent magnet part 162, and a second permanent magnet part 163 and the first permanent magnet. And a third permanent magnet portion 165 disposed between the portions 162. Accordingly, the first permanent magnet 162 is disposed adjacent to the drive shaft 147, and the second permanent magnet part is disposed at the longest distance from the drive shaft 163.

As shown in FIG. 9, the case 161 has a substantially cylindrical shape, and the first groove 161a and the second permanent magnet portion 163 into which the first permanent magnet portion 162 is inserted are inserted into the case 161. ) Is formed a second groove 161b and a third groove 161c into which the third permanent magnet 165 is inserted. The first groove 161a is formed at the center of the case 161, the second groove 161b is formed outside the first groove 161a, and the third groove 161c is the first groove 161a. And the second groove 161b. The depth of the first groove 161a is the largest, the depth of the second groove 161b is the smallest, and the depth of the third groove 161c is the depth of the first groove 161a and the second groove 161b. Is the median of depth. Accordingly, as shown in FIG. 10, although the heights of the permanent magnet parts are different from each other, the distance between the permanent magnet parts and the display panel 120 is substantially the same.

The first permanent magnet 162, the second permanent magnet 163, and the third permanent magnet 165 include a plurality of permanent magnet units arranged along the circumferential direction of the permanent magnet module 160. The permanent magnet unit has a different magnetization direction from neighboring permanent magnet units along the circumferential direction of the permanent magnet module 160, and the circumferential direction of the permanent magnet module 160 is determined based on a surface facing the display panel 120. Accordingly, the north pole and the south pole are alternately arranged.

The first permanent magnet part 162 disposed at the innermost part is composed of six permanent magnet units stacked, and the second permanent magnet part 163 at the outermost part is composed of two permanent magnet units stacked, The third permanent magnet unit 165 disposed in the middle is composed of four permanent magnet units stacked.

Meanwhile, a screw groove 161e is formed in the case 161, and the permanent magnet parts are fixed to the case 161 through the screw 166. The screw 166 is inserted into and fixed to the screw groove 161e through the permanent magnets. In the center of the case 161, a hole 161d into which the drive shaft 147 is inserted is formed.

Here, the stacked permanent magnets constituting the permanent magnet parts have the same thickness and the same magnetic force. Accordingly, the height of the first permanent magnet 162 is the largest, the height of the second permanent magnet 163 is the smallest, and the height of the third permanent magnet 165 is greater than the height of the first permanent magnet 162. It is small and larger than the height of the second permanent magnet 163.

Accordingly, the magnetic force per unit area in the surface facing the display panel 120 is the largest first permanent magnet 162, the second permanent magnet 163 is the smallest, the third permanent magnet 165 is It has an intermediate value between the first permanent magnet 162 and the second permanent magnet 163.

If the magnetic force of the inner portion of the permanent magnet module 160 is larger as in this embodiment, a larger flotation force is generated at the center of the drive shaft 147 and a smaller flotation force is generated toward the outside, thereby reducing fluctuations. In the permanent magnet module 160, if the magnetic force on the outside is large or the magnetic force on the center and the outside is the same as the conventional one, the center of the floating force may move, causing fluctuations. This is because the floating force generated by the rotation of the permanent magnet is generated by magnetic induction as described above, so that the center of the permanent magnet module 160 may not coincide with the center of the floating force. However, if the magnetic force of the central portion is larger as in this embodiment, the flotation force is concentrated in the center of the permanent magnet module 160, so that the center of the flotation force and the center of the permanent magnet module 160 are almost coincident and can stably float. Can significantly reduce fluctuations.

In the present embodiment, three permanent magnets are installed to centralize magnetic force density, but the present invention is not limited thereto, and two permanent magnets may be installed to centralize magnetic force density.

10 is a cross-sectional view illustrating a permanent magnet module of the magnetic levitation display panel transport system according to the sixth embodiment of the present invention.

Referring to FIG. 10, the magnetic levitation display panel transport system according to the present embodiment has the same structure as the magnetic levitation display panel transport system according to the first embodiment except for the structure of the permanent magnet module 170. Since it is made, duplicate description of the same structure is omitted.

The permanent magnet module 170 according to the present embodiment includes a case 171 and a plurality of permanent magnets inserted into the case 171.

The permanent magnet module 170 may include a second permanent magnet part 173 disposed outside the first permanent magnet part 172 and the first permanent magnet part 172, and a second permanent magnet part 173. The third permanent magnet part 175 is disposed between the first permanent magnet part 172. Accordingly, the first permanent magnet 172 is disposed adjacent to the center of the permanent magnet module 170, the second permanent magnet 173 is disposed at the outermost.

On the other hand, the case 171 is formed in a substantially cylindrical shape, the case 171 is a second groove in which the first groove 171a and the second permanent magnet portion 173 into which the first permanent magnet portion 172 is inserted are inserted. The groove 171b and the third groove 171c into which the third permanent magnet 175 is inserted are formed. The first groove 171a is formed at the center of the case 171, the second groove 171b is formed outside the first groove 171a, and the third groove 171c is the first groove 171a. And the second groove 171b. The depth of the first groove 171a is the largest, the depth of the second groove 171b is the smallest, and the depth of the third groove 171c is the depth of the first groove 171a and the second groove 171b. Is the median of depth. Accordingly, although the heights of the permanent magnet parts are different from each other, as shown in FIG. 11, the distance between the permanent magnet parts and the display panel is substantially the same. On the other hand, the center of the case 171 is formed with a hole 171d into which the drive shaft is inserted.

The first permanent magnet part 172, the second permanent magnet part 173, and the third permanent magnet part 175 include a plurality of permanent magnet units arranged along the circumferential direction of the permanent magnet module. The north pole and the south pole are alternately arranged along the circumferential direction of the permanent magnet module with respect to the surface facing the display panel. Each permanent magnet unit is fixed to the case 171 via a screw 176.

Each permanent magnet unit consists of one permanent magnet formed integrally. Here, the height of the first permanent magnet part 172 is the largest, the height of the second permanent magnet part 173 is the smallest, and the height of the third permanent magnet part 175 is greater than the height of the first permanent magnet part 172. It is small and larger than the height of the second permanent magnet portion 173. Accordingly, the magnetic force per unit area in the surface facing the display panel is the largest in the first permanent magnet portion 172, the second permanent magnet portion 173 is the smallest, the third permanent magnet portion 175 is the first permanent The magnet part 172 has a middle value between the second permanent magnet part 173.

If the magnetic force of the inner portion of the permanent magnet module 170 is larger as in this embodiment, a larger flotation force is generated at the center of the drive shaft and a smaller flotation force is generated toward the outside, thereby reducing fluctuations.

11 is a cross-sectional view showing a permanent magnet module of the magnetic levitation display panel transfer system according to the seventh embodiment of the present invention.

Referring to FIG. 11, the magnetic levitation display panel transport system according to the present embodiment has the same structure as the magnetic levitation display panel transport system according to the first embodiment except for the structure of the permanent magnet module 180. Since it is made, duplicate description of the same structure is omitted.

The permanent magnet module 180 according to the present embodiment includes a case 181 and a plurality of permanent magnets inserted into the case 181.

The permanent magnet module 180 may include a second permanent magnet part 183 disposed outside the first permanent magnet part 182 and the first permanent magnet part 182, and a second permanent magnet part 183. The third permanent magnet 185 is disposed between the first permanent magnet 182. Accordingly, the first permanent magnet 182 is disposed adjacent to the center of the permanent magnet module 180, the second permanent magnet portion 183 is disposed at the outermost.

On the other hand, the case 181 is formed in a substantially cylindrical shape, the case 181 is formed with a groove 181a into which the permanent magnets are inserted. In the center of the case 181, a hole 181b into which the drive shaft is inserted is formed.

The first permanent magnet part 182, the second permanent magnet part 183, and the third permanent magnet part 185 include a plurality of permanent magnet units arranged along the circumferential direction of the permanent magnet module 180 and are permanent. In the magnet unit, the north pole and the south pole are alternately arranged along the circumferential direction of the permanent magnet module with respect to the surface facing the display panel. The permanent magnet units are fixed to the case 181 via the screw 186.

Each permanent magnet unit is composed of one permanent magnet formed integrally and has the same height. The first permanent magnet 182, the second permanent magnet 183, and the third permanent magnet 185 have magnetic strengths of different strengths. More specifically, the magnetic force per unit volume of the first permanent magnet unit 182 is the largest, the magnetic force per unit volume of the second permanent magnet unit 183 is the smallest, and the magnetic force per unit volume of the third permanent magnet unit 185 is the first. Less than the magnetic force per unit volume of the permanent magnet portion 182, greater than the magnetic force per unit volume of the second permanent magnet portion 183.

Accordingly, the magnetic force per unit area in the surface facing the display panel is the largest in the first permanent magnet portion 182, the second permanent magnet portion 183 is the smallest, the third permanent magnet portion 185 is the first permanent The magnet part 182 has a middle value between the second permanent magnet part 183.

If the magnetic force of the inner portion of the permanent magnet module 180 is larger as in this embodiment, a larger flotation force is generated at the center of the drive shaft and a smaller flotation force is generated toward the outside, thereby reducing fluctuations.

12 is a plan view illustrating a permanent magnet module of the magnetic levitation display panel transport system according to the eighth embodiment of the present invention.

Referring to FIG. 12, the magnetic levitation display panel transport system according to the present embodiment has the same structure as the magnetic levitation display panel transport system according to the first embodiment except for the structure of the permanent magnet module 190. Since it is made, duplicate description of the same structure is omitted.

The permanent magnet module 190 according to the present embodiment includes a case 191 and a plurality of permanent magnets inserted into the case 191.

The permanent magnet module 190 may include a second permanent magnet part 193 disposed outside the first permanent magnet part 192 and the first permanent magnet part 192, and a second permanent magnet part 193. The third permanent magnet part 195 is disposed between the first permanent magnet part 192. Accordingly, the first permanent magnet part 192 is disposed adjacent to the center of the permanent magnet module 190, and the second permanent magnet part 193 is disposed at the outermost side.

On the other hand, the case 191 is made of a substantially cylindrical shape, the case 191 is made of the same structure as the case of the permanent magnet module according to the first embodiment described above.

The first permanent magnet part 192, the second permanent magnet part 193, and the third permanent magnet part 195 include a plurality of permanent magnet units arranged along the circumferential direction of the permanent magnet module 190 and are permanent. The magnet units are arranged in a Halbach arrangement along the circumferential direction of the permanent magnet module 190 with respect to the surface facing the display panel. The magnetization direction of the permanent magnet units is arranged to change in the height direction of the permanent magnet module as it progresses along the circumferential direction of the permanent magnet module, so that one permanent magnet part forms one Halbach arrangement.

The first permanent magnet part 192 has a first permanent magnet unit 192a having a magnetization direction in a direction toward the display panel (upward), and a direction opposite to the first permanent magnet unit 192a (toward the ground). Direction between the second permanent magnet unit 192b and the first permanent magnet unit 192a and the second permanent magnet unit 192b, and the first permanent magnet unit 192b has a magnetization direction. And an induction permanent magnet unit 192c having a magnetization direction in the direction toward the permanent magnet unit 192a.

The induction permanent magnet unit 192c serves to guide the line of magnetic force, and the magnetization direction is a direction from the second permanent magnet unit 192b toward the first permanent magnet unit 192a. Accordingly, the inductive permanent magnet unit 192c may increase the density of the lines of magnetic force directed toward the display panel, thereby generating more floating force with a smaller magnet.

In addition, the second permanent magnet unit 193 includes a first permanent magnet unit 193a having a magnetization direction in a direction toward the display panel, and a second permanent magnet having a magnetization direction opposite to the first permanent magnet unit 193a. It is located between the magnet unit 193b and the first permanent magnet unit 193a and the second permanent magnet unit 193b and in a direction from the second permanent magnet unit 193b to the first permanent magnet unit 193a. And an induction permanent magnet unit 193c having a magnetization direction.

In addition, the third permanent magnet unit 195 may include a first permanent magnet unit 195a having a magnetization direction toward the display panel and a second permanent magnet having a magnetization direction opposite to the first permanent magnet unit 195a. It is located between the magnet unit 195b and the first permanent magnet unit 195a and the second permanent magnet unit 195b and in a direction from the second permanent magnet unit 195b to the first permanent magnet unit 195a. And an induction permanent magnet unit 195c having a magnetization direction.

If the permanent magnet module 190 has a Halbach array as shown in the present embodiment, since the normal magnetic flux density increases by 1.4 times or more, a larger eddy current may be generated. When a large eddy current occurs, a larger magnetic force is generated, thereby increasing the floating force which is a vertical component of the magnetic force.

The permanent magnet module 190 according to the present embodiment may maximize the strength of the magnetic force formed at the bottom while minimizing the strength of the magnetic force formed at the top. Therefore, the magnetic field of the permanent magnet module 190 is concentrated in the downward direction can obtain a greater flotation force than the existing permanent magnet.

On the other hand, the first permanent magnet portion 192 disposed in the innermost is composed of six permanent magnets stacked, the second permanent magnet portion 193 disposed in the outermost is composed of two permanent magnets stacked, The third permanent magnet unit 195 disposed in the middle is composed of four permanent magnets stacked.

Here, the stacked permanent magnets constituting the permanent magnet parts have the same thickness and the same magnetic force. Therefore, the height of the first permanent magnet portion 192 is the largest, the height of the second permanent magnet portion 193 is the smallest, the height of the third permanent magnet portion 195 is smaller than the height of the first permanent magnet portion, the second It is larger than the height of the permanent magnet.

Accordingly, the magnetic force per unit area of the surface facing the display panel is the largest in the first permanent magnet 192, the smallest in the second permanent magnet 193, and the third permanent magnet 195 is the first permanent. The magnet part 192 has a middle value between the second permanent magnet part 193.

If the magnetic force of the inner portion of the permanent magnet module 190 is larger as in this embodiment, a larger flotation force is generated at the center of the drive shaft and a smaller flotation force is generated toward the outside, thereby reducing fluctuations.

FIG. 13 is a plan view of a magnetic levitation display panel transport system according to a ninth embodiment of the present invention, and FIG. 14 is a cross-sectional view taken along the line IV-XIV of FIG. 13.

Referring to FIGS. 13 and 14, the magnetic levitation display panel transport system 200 according to the present exemplary embodiment includes a floating device 240 and a transport device 230 positioned below the display panel 220.

The display panel 220 may be formed of various types of display panels having metal electrodes, such as a liquid crystal display panel and an organic light emitting display panel. The display panel 220 includes two transparent substrates 221 and a conductor layer 223, and the conductor layer 223 is formed between the transparent substrates 221. The display panel 220 floats and moves, and has the same structure as the display panel according to the first embodiment.

A transfer plate 227 formed along the moving path of the display panel 120 is installed on the floating device 240 and the transfer device 230. The transfer plate 227 is a member for transmitting the magnetic force generated in the flotation device 240 and the transfer device 230 to the display panel 120 is made of stainless steel, synthetic resin and the like.

The floating device 240 includes a plurality of permanent magnet modules 245 facing the display panel 120 and an electric motor 241 for rotating the permanent magnet modules 245.

The permanent magnet modules 245 are arranged in a plurality of rows and columns so that the permanent magnet modules 245 are arranged along the moving path of the display panel 120, and the upper surfaces of the permanent magnet modules 245 face the display panel 120. The electric motor 241 is connected through the permanent magnet module 245 and the drive shaft 247, the permanent magnet module 245 has a plurality of permanent magnet pieces having different magnetization directions. The driving shaft 247 is installed upright with respect to the display panel 120, and is preferably installed upright with respect to the display panel 120. Since the permanent magnet module 245 according to the present exemplary embodiment has the same structure as the permanent magnet module according to the first embodiment, duplicate description of the same structure will be omitted.

The transfer device 230 is formed of a linear induction motor, which is disposed along the path along which the display panel 120 moves. The transfer device 230 includes a core 231 and a coil 232 wound and installed on the core 231. The core 231 is provided with a projection 231a, and a coil 232 is provided in the groove between the projections 231a. Three coils 232 are installed and three coils 232 are alternately inserted into grooves to form a meandering shape. Since the transfer device 230 is installed to face the display panel 120, when the display panel 120 moves, magnetic fluxes that move in time and space generate eddy currents in the display panel 120. The interaction between the eddy currents and the air magnetic flux is represented by Lorentz's force equation. When the linear induction motor is applied as in the present embodiment, the driving force can be generated by non-contact action with the flat panel display panel. Accordingly, the display panel can be stably transported without generating scratches.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but many variations and modifications may be made without departing from the spirit and scope of the invention. And it goes without saying that they belong to the scope of the present invention.

100, 110, 200: Maglev display panel transfer system
114, 152, 145, 150, 160, 170, 180, 190, 245: permanent magnet module
152a, 151: 2nd magnetic pole magnet piece 152b, 151a: 1st magnetic pole magnet piece
152c, 151c, 151d, and 151e: guide magnets 120 and 220: display panel
136, 141, 241: electric motors 117, 127, 227: transmission plate
113, 130, 230: Feeder 131, 142: N-type permanent magnet piece
132, 143: S-type permanent magnet piece 135: Transfer magnet module
137, 147, 247: drive shaft 114, 140, 240: floating device
144, 161, 171, 181, 191: cases 161a, 171a: first groove
161b, 171c: second groove 161c, 171b: third groove
161d, 171d: hole 161e: screw groove
165, 172, 182, 192: first permanent magnet
162, 175, 185, 193: second permanent magnet
163, 173, 183, 195: Third Permanent Magnet
166, 176, 186: screw
193a, 195a, 192a: first permanent magnet unit
193b, 195b, 192b: second permanent magnet unit
193c, 195c, 192c: Inductive Permanent Magnet Unit
231: core 231a: protrusion
232: coil

Claims (19)

In the magnetic levitation display panel transfer system for transferring the display panel,
A floating device including a permanent magnet module having a plurality of permanent magnet pieces having different magnetization directions and an electric motor for rotating the permanent magnet module; And
A transfer device generating an eddy current by forming an eddy current in the display panel;
Including;
The permanent magnet module includes a first permanent magnet part and a second permanent magnet part disposed outside the first permanent magnet part, and the first permanent magnet part is located in a lower side than the second permanent magnet part. Maglev display panel transport system with greater magnetic force per area. The method according to claim 1,
The transfer apparatus is disposed so that an outer circumferential surface thereof faces the display panel, and the magnetic levitation display panel includes a transfer magnet module including a plurality of permanent magnet pieces having different magnetization directions, and a motor for rotating the transfer magnet module. system. The method according to claim 1,
The conveying apparatus is a magnetic levitation display panel transport system consisting of a linear motor. The method of claim 3,
And the transfer device includes a core including a protrusion formed between the protrusion and the protrusion and a coil inserted into the groove. The method according to claim 1,
The permanent magnet module is a magnetic levitation display panel transfer system comprising an N-type permanent magnet piece having an N-type polarity on the top surface and an S-type permanent magnet piece having an S-type polarity on the upper surface. delete delete delete delete delete The method according to claim 1,
And the first permanent magnet portion has a height greater than that of the second permanent magnet portion. The method according to claim 1,
The first permanent magnet portion and the second permanent magnet portion is composed of a plurality of permanent magnets arranged in a stack,
And the first permanent magnet part comprising more permanent magnets than the second permanent magnet part. The method according to claim 1,
And a magnetic force per unit volume of the first permanent magnet portion is greater than a magnetic force per unit volume of the second permanent magnet. The method according to claim 1,
And the first permanent magnet part and the second permanent magnet part comprising a plurality of permanent magnet units arranged along the circumferential direction of the permanent magnet module. 15. The method of claim 14,
And the permanent magnet unit is arranged to have a Halbach arrangement in which the magnetization direction is changed along the circumferential direction of the permanent magnet module. The method according to claim 1,
The permanent magnet module has a smaller magnetic force per unit area between the first permanent magnet part and the second permanent magnet part in a downward direction than the first permanent magnet part,
And a third permanent magnet having a larger magnetic force per unit area in a surface facing downward than the second permanent magnet. The method according to claim 1,
And a transfer plate installed on an upper portion of the floating device and the transfer device and transmitting a magnetic force generated by the floating device and the transfer device to the display panel. The method according to claim 1,
The floating device and the conveying device is a magnetic levitation display panel transport system fixed to the ground. The method according to claim 1,
And the display panel includes a transparent substrate and a conductor layer formed between the transparent substrates.

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