KR101609327B1 - Bowl system having a function of stirring - Google Patents

Abstract

The present invention discloses a container system having a stirring function capable of easily stirring an aqueous solution in a cup or a container by using a repulsive force between magnetic bodies.
A container system according to the present invention is a container system for stirring water in a cup or a container, comprising: a main cup having an arbitrary shape for receiving drinking water; Stirring means floated by the buoyant force in the drinking water loaded on the main cup and fixedly installed with a magnetic force member at a lower portion thereof; And a pedestal having a plate structure for seating the main cup, and a magnetic force rotating device for rotating the magnetic force member based on a magnetic force opposing the magnetic force member.
Therefore, according to the present invention, the cup or the aqueous solution in the container is stirred using the repulsive force between the magnetic bodies, thereby simplifying the structure of the system and reducing the manufacturing cost. Further, it is possible to expand the functionality of the stirrer by controlling the temperature of the aqueous solution to be increased or decreased during the stirring process by adding a Peltier element.

Description

[0001] BOWL SYSTEM HAVING A FUNCTION OF STIRRING [0002]

The present invention relates to a stirring system, and more particularly, to a stirring system which includes stirring means having a magnetic body inside a cup or a container, and rotating the stirring means using an external magnetic field to perform stirring function capable of smoothly stirring an aqueous solution in a cup or a container Lt; / RTI >

Generally, mixing work to dissolve a solute in a solvent to make a solution or mixing two different liquid materials uniformly to form a mixed solution is very frequently performed in daily life or in a chemical experiment. In everyday life, it is necessary to stir the coffee drink or tea mix by dissolving the drink mix into water to dissolve the coffee mix or tea mix in water to make the coffee or tea.

For this stirring operation, the user performs a stirring operation in such a manner as to use a teaspoon or, if the use of a teaspoon is not feasible, to reduce the water by using the wrapping paper of the drink mix so as to cause a flow of water inside the cup. However, in recent years, an automated stirring apparatus has been disclosed for convenience of use, and will be described with reference to FIG. 1 of the accompanying patent document.

As shown in the figure, the contents are stored in a container housing 10, a thermoelectric power generating module 20 installed in the container housing 10 to generate electric power from heat generated from an external heat source, and disposed inside the container housing 10 And a stirring module (30) for generating a rotating force by the electric power of the thermoelectric power generation module (20) to stir the contents.

The container housing 10 is a portion in which the contents are contained, preferably a bowl shape having an opened upper surface. The thermoelectric power generation module 20 includes a thermoelectric element 22 that applies a Seebeck effect as a part for converting heat energy into electric energy. When one side of the thermoelectric generator 22 is set to a low temperature and the other is set to a high temperature, a heat current is generated from the high temperature side to the low temperature side via the thermoelectric element 22. That is, the thermal energy flowing into the high-temperature side generates an electromotive force during the process of being discharged to the low-temperature side through the thermoelectric generator 22. When a plurality of such thermoelectric generators are connected, larger power can be obtained.

The thermoelectric generator module 20 includes a thermoelectric housing 24 that fixes the thermoelectric generator 22 to the lower side of the container housing 10 and the thermoelectric generator 22 supplies power to the stirring module 30 And a connecting electrode 22a. The thermoelectric housing 24 is integrally formed with the mounting portion 25 and the mounting portion 25 to which the thermoelectric generator 22 is inserted so that the mounting portion 25 is fixed to the lower side of the container housing 10, A connecting portion 26 for guiding the electrode 22a to the stirring module 30 and an insertion portion 27 formed in the connecting portion 26 and inserted into the container housing 10 through the container.

The high-temperature portion of the thermoelectric generator 22 is continuously heated at a high temperature by a heat source, and the low-temperature portion is continuously and low-temperature-cooled by the contents to generate electric power from the thermoelectric generator 22. At this time, preferably, a mounting groove 10a for the thermoelectric generator 22 and the connecting electrode 22a may be formed concavely on the lower side of the container housing 10, and the thermoelectric generator 22, (22a) is inserted into the installation groove (10a) to minimize the portion protruding outside the container housing (10).

The insertion portion 27 is formed in a cylindrical shape and has an electrode hole 27a for insertion of the connection electrode 22a on the outer circumferential surface thereof and a thread 27b for coupling with the stirring module 30 on the inner circumferential surface thereof. The stirring module 30 includes an inner housing 32 coupled to the insertion portion 27 and fixed to the inner side of the container housing 10, a motor 32 installed in the inner housing 32 to receive power from the connection electrode 22a, A top cover 36 for fixing the motor 34 to the inner housing 32, an outer housing 40 connected to the motor shaft 35 of the motor 34 and rotated by the rotational force of the motor 34, And a stirring paddle 50 integrally formed with the outer housing 40 and stirring the liquid inside the container housing 10.

When the heat generated from an external heat source is applied to the container housing, electric power is generated from the thermoelectric generator to rotate the stirring paddles inside the container housing, so that the contents can be stirred without supplying a separate power source have. However, since the stirring is performed using an external heat source, when the heat source is not uniform or the heat source is insufficient, there arises a problem that it becomes difficult to implement the stirring function. In addition, the use of the thermoelectric power generation module increases the unit price of the system, thereby lowering the practicality.

Korean Patent Publication No. 10-2011-0065382, published on Jun. 15, 2011, entitled "

SUMMARY OF THE INVENTION The present invention has been made in order to solve such a problem, and an object of the present invention is to provide a stirring function capable of reducing the manufacturing cost by simplifying the structure of the system by allowing the cup or the aqueous solution in the container to be stirred using the repulsive force between the magnetic bodies And a container system.

Another object of the present invention is to provide a container system having a stirring function capable of expanding the functionality of the stirrer by controlling the temperature of the aqueous solution to be increased or decreased during the stirring process by adding a Peltier element.

According to an aspect of the present invention, there is provided a container system for agitating water in a cup or a container, comprising: a main cup having an arbitrary shape for receiving drinking water; Stirring means floated by the buoyant force in the drinking water loaded on the main cup and fixedly installed with a magnetic force member at a lower portion thereof; And a pedestal having a plate structure for seating the main cup and having a magnetic force rotating device for rotating the magnetic force member based on a magnetic force opposing the magnetic force member.

According to a preferred embodiment of the present invention, the stirring means includes a plurality of blades at an outer peripheral portion thereof; The blade is a slant-like projecting structure and is formed to have a thickness within a range of 10 mm to 20 mm.

In addition, a pedestal according to a preferred embodiment of the present invention includes a housing having a flat structure for seating the main cup; A rotating plate provided with a fixed magnet facing the magnetic force member; A motor for rotating the rotating plate; Power transmission means for transmitting and decelerating power between the motor and the rotary plate; And a power supply for supplying a static capacity power to the motor.

According to a preferred embodiment of the present invention, the magnetic force member mounted on the lower portion of the stirring means is a permanent magnet, and the permanent magnet is uniformly disposed at least two or more; The pedestal including a housing of a flat structure for seating the main cup; A PCB having a circuit pattern for system control; An electromagnet which is inserted on the PC and generates a magnetic force by an electrical signal, the electromagnets being disposed at the same angle as the permanent magnet, and having at least N times (N = 2 or more integers); A microcomputer for activating an electromagnet at a position opposed to the permanent magnet and transferring the activation to an electromagnet adjacent to the electromagnet to control the permanent magnet to rotate according to the electromagnet activation; A switching module for supplying a rated voltage current to each of the electromagnets according to a control signal of the microcomputer; And a power unit configured to convert a commercial power source (AC) into a rated DC power source using the system power source or a battery.

According to a preferred embodiment of the present invention, there is further provided a variable resistor (VR) connected to the input port of the microcomputer for varying the activation speed of the electromagnet to vary the rotational speed of the stirring means .

The container system having the stirring function proposed in the present invention has an effect that the structure of the system can be simplified and the manufacturing cost can be reduced by allowing the cup or the aqueous solution in the container to be stirred using the repulsive force between the magnetic bodies. Further, it is possible to expand the functionality of the stirrer by controlling the temperature of the aqueous solution to be increased or decreased during the stirring process by adding a Peltier element.

1 is a view for explaining a conventional self-stirring container.
2 is a view for explaining a container system according to the present invention.
FIG. 3 is a view for explaining the structure of the pedestal of FIG. 2 as a first embodiment of the present invention.
4 is a view for explaining the structure of the pedestal of FIG. 2 as a second embodiment of the present invention.
5 is a circuit diagram of Fig.
6 is a perspective view showing another embodiment of the stirring means of the present invention.

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

First, the present invention is based on a magnetic force (permanent magnet) attached to an agitating means and a driving magnetic force which is rotated in proximity to the agitating means by rotating agitating means located in a cup (main cup) or a container using magnetic force. Preferably, the means for agitation has a cup shape, which means that the means for agitation is to adjust the size of the buoyancy from the drinking water loaded in the main cup or vessel.

That is, when the stirring means has the shape of a cup, the stirring means allows the drinking water to float in an arbitrary position inside the main cup in which the drinking water is housed. For example, beer is contained as a first drinking water in the main cup, and soju is received as a second drinking water in the agitating means, so that the mixing liquor of beer and soju can be amusing.

Of course, when the container system according to the present invention is used in a home, it may be used as a device for dissolving the composition of the mixed coffee, or for dissolving any aqueous solution with chemical equipment.

On the other hand, the fixed magnet and the driving magnetic force proposed in the present invention can be set to have mutual repulsive force or to induce reciprocal attraction. This can induce attraction between the permanent magnet mounted on the agitating means and the driving magnetic force to partially cancel the buoyancy of the agitating means when the agitating means is lifted above the predetermined height by buoyancy in the main cup. On the other hand, when the stirring means is small in buoyancy and sinks to the bottom of the main cup, a repulsive force is applied between the permanent magnet and the driving magnetic force, thereby inducing the stirring means to float to the desired position of the main cup.

In the present invention, the driving magnetic force refers to an electromagnet for generating a magnetic force including a magnet, and thus a motor for driving the driving magnetic force may be used or a circuit for driving the electromagnet may be applied. Such a driving magnetic force may be provided at a lower portion of the main cup to present the main cup and the driving magnetic force generating device in an integrated structure. If necessary, a separate pedestal may be provided to generate a driving magnetic force inside the pedestal. .

2 is a perspective view illustrating a container system having an agitating function according to an embodiment of the present invention. It will be appreciated that the embodiment of the present invention can be presented as a separate structure composed of a main cup and a pedestal, or an integral structure in which a driving magnetic force generating device configured in the pedestal is installed inside the main cup as described above.

As shown in the figure, a main cup (or a container) 201 having an arbitrary shape for receiving drinking water is provided. The main cup 201 is lifted by buoyant force in the drinking water loaded on the main cup 201, And a pedestal 221 having a plate structure for seating the main cup 201 and having a magnetic force rotating device for rotating the magnetic force member based on a magnetic force opposing the magnetic force member do.

The magnetic force member may be a neodymium magnet, a ferrite magnet, a rubber magnet, an Alico magnet, a samarium cobalt magnet, or the like as a permanent magnet, and neodymium magnets are preferably used in the embodiment of the present invention. Since the Neodymium magnet has strong magnetic force as compared with its size, it is easy to install and has an advantage of minimizing the appearance change of the stirring means 211.

The magnetic force of the magnetic force rotating device may be a magnetic force of the same polarity as the magnetic force member (permanent magnet) or a magnetic force of a different polarity. As described above, when the buoyancy of the stirring means 211 is large, The distance between the stirring means 211 and the pedestal 221 can be narrowed. On the other hand, when the buoyancy of the agitation means 211 is small, the distance between the agitation means 211 and the pedestal 221 can be increased by inducing the repulsive force with the permanent magnet.

Of course, the buoyancy or sinking degree of the stirring means 211 depends on the capacity of the drinking water to be loaded by the stirring means 211, so that the magnetic force polarity of the magnetic force rotating device can be set according to the characteristics of the product and the use thereof .

The stirring means 211 is for stirring the drinking water in the main cup 201 and it is a matter of course that a plurality of blades 215 may be provided on the outer peripheral portion of the stirring means 211. The blade 215 is preferably a slant-like projection having a thickness of, for example, 10 mm to 20 mm, which minimizes the frictional force with the drinking water during rotation of the stirring means 211 and induces the receiving stones of the drinking water.

On the other hand, at least one permanent magnet provided by the stirring means 211 is provided, and preferably three permanent magnets are provided, so that the magnetic force can be prevented from being deviated from the magnetic field of the magnetic force rotating device together with the stability of rotation.

In addition, the magnetic force rotating device may be applied to any other permanent magnet so as to face the permanent magnet, and an electromagnet may be used as another embodiment of the present invention. Further, the magnetic force rotating device has a mechanism for rotating the electromagnet or the permanent magnet at a constant speed, and may be simply rotated using a motor or a similar structure or principle.

The stirring means 211 may be configured to stir the drinking water loaded in the main cup 201 or to mold the upper end of the stirring means 211 so that another drinking water is loaded by the stirring means 211 . This makes it possible to mix and mix the drinking water loaded in the main cup 201 and the drinking water loaded in the stirring means 211 to expand the use of the container system according to the present invention.

3 is a block diagram showing a pedestal 221 according to the first embodiment of the present invention.

As shown in the figure, the pedestal 221 includes a housing 309 having a flat structure for seating the main cup 201, and the housing 309 is provided therein with a fixed magnet A motor 301 for rotating the rotating plate 303 and a power transmitting means 307 for decelerating and transmitting the power between the motor 301 and the rotating plate 303, And a power supply 311 for supplying static power to the motor 301.

The power transmission means 307 is for transmitting the rotation speed of the motor 301 to the rotation plate 303, and may be a belt or a gear type. The power supply 311 may include a converter circuit that can convert a commercial power supply AC into a DC power supply, or may be replaced with a battery.

The rotating speed of the rotating plate 303 is based on the rotating speed of the motor 301, but sets an appropriate speed based on the deceleration rate of the power transmitting means 307. [ A controller for controlling the rotational speed of the motor 301 may be mounted as needed to vary the rotational speed of the rotating plate 303. [ This will control the rotational speed of the stirring means 211 from the user depending on the intended use of the container system according to the present invention.

The fixed magnet 305 is opposed to the magnetic force member 213 mounted on the lower portion of the stirring means 211 and is provided so as to correspond to the mounting position (angle) and the number of the magnetic force member 213 It is preferable to set the position (angle) and the number. This is to transmit the rotational force of the rotating plate 303 to the stirring means 211 as much as possible.

4 shows a pedestal 221 according to the present invention as a second embodiment.

In this embodiment, the above-described fixed magnet 305 is not used but the electromagnet is used to control the stirring means 211 to rotate. To this end, it is assumed that the permanent magnets mounted on the lower portion of the stirring means 211 are uniformly arranged at least two or more.

(PCB) 411 having a circuit pattern for controlling the system, and a magnetic circuit which is inserted on the PCB 411 and generates a magnetic force by an electrical signal. The magnetic force is generated at the same angle as the magnetic force member 213 And an electromagnet 413 having a number of at least N (N = 2 or more integers) and an electromagnet 413 at a position facing the magnetic member 213 are activated, and the activation is transferred to the electromagnet adjacent thereto A microcomputer 417 for controlling the magnetic force member 213 to rotate in accordance with the activation of the electromagnet and a switching module 415 for supplying the rated voltage current to the electromagnets according to the control signal of the microcomputer 417.

The power source unit 419, which has not been described, converts the commercial power source AC into the rated DC power source with the system power source. It is natural that the battery can be used to supply the system power as needed.

The microcomputer 417 sequentially controls power supply to the plurality of fixed electromagnets 413, and the rotation speed of the stirring means 211 can be controlled by controlling the time interval in sequential control. That is, according to the program of the microcomputer 417, the user controls the rotation speed of the stirring means 211.

Each of the electromagnets 413 is wound with a coil 431 for dissipating the magnetic force corresponding to the magnetic force member 213. The number of turns of the coil is determined by the magnetic force. By implementing the structure in which the coils 431 are mutually connected in parallel, the simplicity of the circuit and the convenience of control can be ensured.

5 is a circuit diagram according to the second embodiment shown in FIG. As shown in the figure, the electromagnets 413 are installed in the number corresponding to N times of the magnetic force members (permanent magnets) 213 attached to the lower portion of the agitating means 211, and hold the respective coils 431. The coils 431 of the electromagnets 413 are alternately connected in parallel. As shown in the figure, the A coil is connected in parallel with the C coil and the E coil, and the B coil is connected in parallel with the D coil and the F coil .

The switching circuit corresponding to the switching module 415 controls the power supplied to each coil 431, and a Darlington circuit composed of a transistor which is a non-contact switching element can be applied.

The switching circuit operates based on a control signal of the microcomputer 417, and the microcomputer 417 performs switching control according to a preset program. The switching control is performed by supplying power to an AEC coil constituted by an arbitrary coil group, for example, an A coil, a C coil and an E coil, and then switching the power supply to a BDF coil constituted by a D coil and an F coil, Thereby rotating the direction of the magnetic force opposing the magnetic force member 213.

Accordingly, the magnetic force member 213 rotates in accordance with the magnetic force of the electromagnet 413, which rotates the stirring means 211. By repeatedly repeating the above process, the stirring means 211 located in the drinking water continuously rotates by the magnetic force of the electromagnet 413. The microcomputer 417 can vary the rotation speed of the stirring means 211 by varying the magnetic force transfer rate.

That is, a variable resistor (VR) for variable speed is added to the input port of the microcomputer 417, and the switching operation speed of the switching circuit is controlled by the variable resistor (VR) And the rotation speed of the motor.

By adding a plurality of light emitting elements to the outer circumferential portions of the housings 309 and 401 and performing the blinking of the light emitting elements according to the rotation speed of the rotation plate 303 or the magnetic force supply speed of the electromagnet 413, 0.0 > 211 < / RTI >

Meanwhile, the pedestal 221 shown in the present invention may include a temperature control device for controlling the temperature of the drinking water loaded on the main cup 201. Preferably, the temperature control device is a Peltier element 441 that can be electrically controlled. The Peltier element 441 is positioned at the bottom center of the pedestal 221 and heat sinks are provided on both sides of the Peltier element 441. Therefore, the heating temperature or the cooling temperature of the Peltier element 441 is transmitted to the drinking water accommodated in the main cup 201 via the heat sink, the pedestal 221 and the main cup 201.

Here, the microcomputer 417 is connected to the temperature setting unit 507 as an input port, and the display unit 505 for temperature display is connected to the output port. The temperature setting unit 507 may be a push switch, and the display unit 505 may display an image using an LCD or an FND.

The microcomputer 417 controls the current supplied to the Peltier element 441 according to the detection result of the temperature sensor 443 provided at a position close to the Peltier element 441 and the polarity of the current supplied to the Peltier element 441 in controlling the temperature of the Peltier element. do. Of course, since the temperature sensor 443 does not directly detect the temperature of the drinking water loaded in the main cup 201, it is preferable to display it by converting it into an appropriate temperature value on the basis of experiments.

As described above, according to the present invention, by rotating the rotating plate with the fixed magnet or by inducing a change in the magnetic force using a plurality of electromagnets, the rotation of the stirring means is controlled and the temperature of the drinking water is controlled, The dissolution of the organic solvent can be accelerated.

On the other hand, the stirring means provided in the present invention has a structure for receiving drinking water, but it is possible to provide a structure capable of loading food inside a subject such as a tea bag. 6, the stirring means 500 includes a cylindrical body 505 accommodated in the main cup, and a plurality of the cylindrical bodies 505 are embedded in the upper portion of the net body to form a magnetic force member 505).

Here, the agitation means 500 preferably maintains buoyancy by drinking water contained in the main cup, and the material of the net body 503 may be a polymer material capable of maintaining buoyancy. As shown in the drawing, the annular buoyant body 501 may be provided at the upper end of the net 503, and a plurality of magnetic force members 505 may be embedded along the outer circumferential surface of the annular buoyant body 501 to be.

An electromagnet (not shown) is provided on the upper portion of the main cup so as to face the magnetic force member 505, and a control device (not shown) for controlling the magnetic force of the electromagnet to rotate the stirring means 500 ). Preferably, the control device is driven by a battery. Accordingly, a battery is accommodated in one end of the main cup, and a case detachable structure for replacing a battery, a switch for controlling power supply, a display circuit And the like.

At least three magnetic force members 505 must be provided. As the number of the magnetic force members 505 increases, the rotational force of the stirring means 500 is strong and stable operation can be maintained. It is preferable that the electromagnets installed in the main cup also keep the same number so as to face the magnetic force member 505, but the number of the electromagnets may be limited to three for convenience of manufacturing the system.

Accordingly, the control device sequentially activates each electromagnet, whereby the stirring means 500 for holding the buoyancy is rotated based on the attraction force and the repulsion control between the magnetic member 505 and the electromagnet. This makes it easy to disturb the food by weighting the intersection of the food with the drinking water stored in the main cup and the inside of the stirrer 500 inside the tea bag.

The electromagnet activation control of the control device is based on the set speed, which can be set in the manufacturing process on an experimental basis. Needless to say, the rotation speed of the agitating means can be controlled by the user, and a switching means for speed control is connected to the control device, and a program for operating the switching means should be mounted.

201: main cup 211, 500: stirring means
213, 505: magnetic force member 215: blade
221: pedestal 301: motor
303: spindle 305: stationary magnet
307: Power transmission means 309, 401: Housing
311: Power supply unit 411: PCB (PCB)
413: electromagnet 415: switching module
417: Microcomputer 419: Power source
501: annular buoyancy body 503:

Claims (13)

A container system for stirring water in a cup or container,
A main cup having an arbitrary shape for receiving water;
Stirring means accommodated in the main cup and having a magnetic force member fixedly installed at a lower portion thereof; And
And a pedestal having a plate structure for seating the main cup and having a magnetic force rotating device for rotating the magnetic force member based on a magnetic force opposing the magnetic force member;
Wherein the pedestal includes a flat-plate-like housing for seating the main cup; A rotating plate provided with a fixed magnet facing the magnetic force member; A motor for rotating the rotating plate; Power transmission means for transmitting and decelerating power between the motor and the rotary plate; And a power supply for supplying a static capacity power to the motor. The method according to claim 1,
Wherein the agitating means is floated by buoyancy inside the drinking water loaded in the main cup. The method according to claim 1,
Wherein the stirring means includes a plurality of blades at an outer peripheral portion thereof;
Wherein said blades are oblique protruding structures and are formed to a thickness within 10 mm to 20 mm. delete The method according to claim 1,
Wherein the power transmission means is for transmitting the rotation speed of the motor to the rotating plate at a reduced speed, wherein a belt or gear system is applied. The method according to claim 1,
Wherein the power source device is a converter circuit capable of converting a commercial power source (AC) into a direct current power source, or a battery. The method according to claim 1,
The magnetic force member mounted on the lower portion of the stirring means is a permanent magnet, and the permanent magnet is uniformly disposed at least two or more;
The pedestal including a housing of a flat structure for seating the main cup;
A PCB having a circuit pattern for system control;
An electromagnet which is inserted on the PC and generates a magnetic force by an electrical signal, the electromagnets being disposed at the same angle as the permanent magnet, and having at least N times (N = 2 or more integers);
A microcomputer for activating an electromagnet at a position opposed to the permanent magnet and transferring the activation to an electromagnet adjacent to the electromagnet to control the permanent magnet to rotate according to the electromagnet activation;
A switching module for supplying a rated voltage current to each of the electromagnets according to a control signal of the microcomputer; And
Wherein the power supply unit comprises a power supply unit configured to convert a commercial power supply (AC) into a rated DC power supply or a battery as the system supply power. 8. The method of claim 7,
Further comprising a variable resistor (VR) connected to the input port of the microcomputer for varying an activation speed of the electromagnet to vary a rotation speed of the stirring means. 9. The method of claim 8,
Further comprising a light emitting element capable of displaying the rotational speed of the stirring means. 8. The method of claim 7,
Further comprising: a Peltier element capable of being electrically controlled; a temperature sensor for measuring a temperature change of the drinking water; a temperature setting unit for setting a temperature; and a display unit for displaying the temperature change;
Wherein the microcomputer controls the current supply and the polarity to the Peltier element so as to correspond to the detection result of the temperature sensor corresponding to the setting information inputted from the temperature setting unit. A container system for stirring water in a cup or container,
At least three or more uniformly distributed along the outer circumferential surface of the annular buoyant body for containing food to be attracted and extending downwardly of the buoyant body, the annular buoyant body including an annular buoyant body for holding buoyancy by the water; A stirring means provided with a magnetic member having the same magnetic polarity as that of the magnetic member; And
A main cup accommodating the stirring means after the drinking water is loaded and having an electromagnet arranged to face the magnetic force member and a control device for controlling the magnetic force of the electromagnet to rotate the stirring means;
Wherein the electromagnets are arranged at the same angle as the magnetic force member and have at least N times (N = 2 or more integers)
The control device activates an electromagnet at a position opposite to the magnetic force member and then transfers activation to an electromagnet adjacent to the electromagnet to control the magnetic member to rotate in accordance with activation of the electromagnet;
A switching module for supplying a rated voltage current to each of the electromagnets according to a control signal of the microcomputer; And
And a power supply unit configured to convert a commercial power supply (AC) into a rated direct current power supply or a battery, using the system supply power. The method according to claim 1 or 11,
Wherein the magnetic force member is one of a neodymium magnet, a ferrite magnet, a rubber magnet, an Alico magnet, and a samarium cobalt magnet as permanent magnets. The method according to claim 1 or 11,
Wherein the magnetic force member is a neodymium magnet.

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