KR20020035934A - Magnetic lift - Google Patents

Abstract

PURPOSE: A magnetic lift is provided to increase the adsorption strength and decrease tare of the lift and volume by installing another magnets inside the lift. CONSTITUTION: A magnetic lift includes a metal plate(5) equipped with a moving device, plural second fixed magnets(4,4a), plural iron cores of ferromagnetic material(3), plural first fixed magnets(2,2a), and plural rotary magnets(1,1a). The second fixed magnets are arranged on the lower surface of the metal plate at regular intervals and divided into the N pole and S pole up and down. The iron cores of ferromagnetic material are arranged on the lower surface of the second fixed magnets at the same intervals of the second fixed magnets. The first fixed magnets placed between each iron cores of ferromagnetic material and divided into the N pole and S pole have the same polarity of the polarity of the second fixed magnets. The rotary magnets placed at the separated space of each iron core of ferromagnetic material between the first fixed magnets and divided into the N pole and S pole have the same or opposite polarity with the first fixed magnets. Plural fixed magnets and installed between and between the iron cores of ferromagnetic material and the metal plates without isolating plates and therefore the adsorption strength is increased.

Description

Magnetic lift

The present invention relates to a magnetic lift, and more particularly, to a magnetic lift that can increase the efficiency of magnets installed inside the lift to further increase the attraction force with a metal object by improving the internal structure of the magnetic lift.

In general, the conventional magnetic lift is adapted to adsorb / detach a metal object by adjusting a rotating magnet installed inside the device with a handle installed on the outside of the device so that the magnetic flux direction of the stator magnet fixed to the lift coincides with the magnetic flux direction. I adopt a way to make it.

1A and 1B are adsorption principle and desorption principle diagrams according to the first example of the conventional magnetic lift, respectively, and a plurality of ferromagnetic iron cores 3 and a plurality of rotating magnets 1 and first stator magnets installed therebetween. (2), a metal plate (5) for fixing the plurality of ferromagnetic iron cores (3) and the eye bolt (7), the magnetic flux of the rotating magnet (1) and the first stator magnet (2) is the metal plate (5) It consists of a non-magnetic separator 10 for preventing from flowing.

Looking at the adsorption principle for the magnetic lift having the structure as described above, as shown in Figure 1a, first, the rotating magnet (1) and the first fixed to the one side of the respective ferromagnetic iron core with respect to the plurality of ferromagnetic iron core (3) The same polarity of the magnet 2 is disposed, and on the other side facing each side of the ferromagnetic iron core 3, another rotating magnet 1a and the first stator magnet 2a are arranged on the ferromagnetic iron core 3. The structures arranged so as to have the same polarity as that of the rotating magnet 1 and the first stator magnet 2 facing each other are sequentially arranged. In other words, each of the rotating magnets 1, 1a and the first stator magnets 2, 2a in contact with both sides of one ferromagnetic iron core is arranged to have the same polarity. The magnetic force lines from the N poles of the respective rotating magnets (1) (1a) and the first stator magnets (2) (2a) arranged as described above are moved with the ferromagnetic iron core (3) in contact with the N poles of the respective magnets. The magnetic flux flows through the metal object 9 and passes through the ferromagnetic iron core 3 in contact with the S poles of the respective rotating magnets 1, 1a and the first stator magnets 2, 2a. As a result, the metal object 9 is adsorbed to the ferromagnetic iron core 3.

Figure 1b shows the desorption principle of the metal object (9) adsorbed above by rotating the rotating magnet (1) (1a) 180 degrees by a handle (not shown) installed on the outside and the respective ferromagnetic iron core (3) and When the rotating magnets (1) (1a) and the first stator magnets (2) (2a) in contact with the same plane are arranged so that the polarity is reversed, the rotor magnets (1) (1a) and the first stator magnets ( 2) The magnetic flux from the N pole of (2a) flows to the S poles of the rotating magnets (1) (1a) and the first stator magnets (2) (2a) in contact with the same ferromagnetic iron cores (3). The flow of the magnetic flux penetrating the (9) is lost, and the metal object 9 is detached.

The rotating method of each rotating magnet (1) (1a) by the operation of the handle provided in the outside is a method that is already used in the conventional magnetic lift, and is not described in detail because it is irrelevant to the gist of the present invention.

As described above, in the prior art example of the magnetic lift, a part of the magnetic flux from the N poles of the rotating magnets 1, 1a and the first stator magnets 2, 2a is transferred to the separator 10. The ferromagnetic iron core 3 and the ferromagnetic iron core 3 are not completely blocked by the separator 10, and the separator 10 passes through the air space in contact with the side surface of the lift, or through the separator 10 due to the strong magnetic flux of each magnet. Through the separator 10 and the metal plate 5, a leakage magnetic flux that reaches the S pole of the rotating magnets 1, 1a and the first stator magnet 2, 2a is generated, and the separator 10 Some of the magnetic flux blocked by the will not be induced in the other direction will generate a magnetic flux saturation phenomenon is concentrated inside the ferromagnetic iron core (3). Such leakage magnetic flux and magnetic flux saturation are a cause of reducing the adsorption force between the ferromagnetic iron core 3 and the metal object 9.

The present invention has been made in order to improve the generation of leaking magnetic flux due to the structural inefficiency of the magnetic lift and the reduction of adsorption force caused by the magnetic flux saturation as a conventional problem, by improving the internal structure of the magnetic lift leakage magnetic flux In addition to reducing the saturation of the magnetic flux as well as to induce the leakage flux to contribute to the increase in the adsorption force between the object to be adsorbed and the magnetic lift.

1A and 1B are respectively an adsorption principle diagram and a desorption principle diagram of a magnetic lift according to the related art.

2A and 2B are adsorption principle and desorption principle diagram of the magnetic lift according to the present invention, respectively.

Figure 3 is a principle of adsorption according to the application of the present invention

Explanation of symbols on the main parts of the drawings

One ; Rotating magnet 2, 2a: first fixed magnet

3: ferromagnetic iron core 4, 4a: second stationary magnet

5: metal plate 7: eye bolt

9: metal object 10: separator

In order to achieve the above object, the present invention is an internal configuration of a magnetic lift for adsorbing or detaching a metal object by a magnetic force of a plurality of rotating magnets and a stationary magnet; A metal plate to which the eye bolt is attached; A rotating magnet rotatable by a handle installed outside; A first stator magnet in contact with the rotating magnet; A ferromagnetic iron core whose one end is in contact with the metal object and the rotating magnet and the first stator magnet are in contact with the side surface; Provided is a magnetic lift including a second pinned magnet in contact with the ferromagnetic iron core and a metal plate at the same time.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings, and the same or similar reference numerals are assigned to the same or similar components as the conventional configurations.

2A and 2B are adsorption and desorption principle diagrams of the magnetic lift according to the present invention, respectively, and a plurality of ferromagnetic iron cores 3 and a plurality of rotating magnets 1 and first stator magnets 2 installed therebetween. And a metal plate 5 for fixing the plurality of ferromagnetic iron cores 3 and the eye bolts 7, and a second pinned magnet 4 positioned between the ferromagnetic iron cores 3 and the metal plate 5. .

Looking at the adsorption principle for the magnetic lift of the structure described above, as shown in Figure 2a, first, the polarity of the rotating magnet (1) and the first stator magnet (2) in contact with one side of each of the plurality of ferromagnetic iron core (3) (S-pole or N-pole) are arranged in the same manner, and the other side of the ferromagnetic iron core (3) facing the other side, another rotating magnet (1a) and the first fixed magnet (2a) is the ferromagnetic iron core (3) ) Is a structure in which structures arranged so as to have the same polarity (S-pole or N-pole) of the rotating magnet 1 and the first stator magnet 2 facing each other are sequentially arranged. That is, the structure is arranged so that the polarities of the rotating magnets (1) (1a) and the first stator magnets (2) (2a) in contact with both sides of one ferromagnetic iron core. The first stator magnet (2) (2a) is provided between the ferromagnetic iron core (3) and the metal plate (5) in contact with the rotating magnets (1) (1a) and the first stator magnet (2) (2a) of the same polarity. And a second stationary magnet 4 arranged such that the same polarity as that of the rotating magnets 1 and 1a is in contact with the ferromagnetic iron core 3. The magnetic flux from the N poles of the respective rotating magnets (1) (1a), the first stator magnets (2) (2a) and the second stator magnets (4) is the first and second stator magnets (2) (2a). (4) and the ferromagnetic iron core (3) in contact with the rotating magnet (1) (1a) and the metal object (9) to be moved through the first and second stator magnets (2) (2a) (4) and the rotating magnet ( 1) Since the magnetic flux flowing through the ferromagnetic iron core 3 in contact with the S pole of (1a) enters the respective S poles is formed, the metal object 9 is adsorbed to the ferromagnetic iron core 3. In addition, the magnetic flux generated at the N pole of the second stator magnet 4 in contact with the metal plate 5 forms a magnetic flux flow entering the S pole of another second stator magnet 4a adjacent to each other through the metal plate. .

FIG. 2B illustrates a desorption principle of the metal object 9 adsorbed in FIG. 2A, and rotates the rotating magnet 1 and 1a by 180 degrees by a handle (not shown) installed outside. If the polarity of the rotating magnet (1) (1a) and the first stator magnet (2) (2a) in contact with the same plane is arranged differently, the rotor magnet (1) (1a) and the first, second stator magnet The magnetic flux from the N pole of (2) (2a) (4) is the rotating magnets (1) (1a) and the first and second stator magnets (2) (2a) ( Since it flows to the S pole of 4), the flow of the magnetic flux passing through the metal object 9 is lost, and the metal object 9 is detached.

3 is an adsorption principle diagram of a magnetic lift according to an application of the present invention, in which the arrangement of the second pinned magnet 4 located between a plurality of ferromagnetic iron cores 3 and a metal plate 5 is shown. It consists of intervals skipping one by one.

Looking at the adsorption principle for the application of the magnetic lift according to the present invention having the structure as described above, the magnetic flux from the N pole of each of the rotating magnet (1) (1a) and the first stator magnet (2) (2a) and the metal plate ( 5) The magnetic flux generated in the N pole of the second stator magnet 4 in contact with the metal plate 5 is in contact with the N pole of the rotor magnets 1, 1a and the first stator magnet 2, 2a. Ferromagnetic iron core (3) in contact with the S poles of the first and second stationary magnets (2) (2a) (4) and the rotating magnets (1) (1a) through a ferromagnetic iron core (3) and a metal object (9) to be moved. Since the magnetic flux flows through each of the S poles, the metal object 9 is attracted to the ferromagnetic iron core 3.

In addition, the desorption principle of the magnetic lift according to the application of the present invention described in Figure 3 is described in the same principle as in Figure 2b illustrating the desorption principle of the preferred embodiment of the present invention will not be described in detail.

Although the preferred embodiments according to the present invention have been described above, this is merely an example, and various changes and modifications may be made without departing from the spirit of the present invention, but all such modifications and changes fall within the scope of the present invention. You will find out.

As described above, in the embodiment of the present invention, by removing the separator configured in the existing magnetic lift and configuring a plurality of stationary magnets between the ferromagnetic iron cores and between the ferromagnetic iron cores and the metal plate, It is possible to eliminate the waste of magnetic flux caused by blockage of the magnetic separator and the reduction of adsorption force and the saturation of magnetic flux generated inside the ferromagnetic iron core. In addition, by forming a path through the metal plate, there is an effect that the existing separator is unnecessary and the manufacturing cost is reduced.

Claims (2)

A metal plate 5 provided with a moving means; A plurality of second pinned magnets (4) (4a) disposed in contact with a lower surface of the metal plate (5) at regular intervals, and divided into two poles (N and S); A plurality of ferromagnetic iron cores 3 having an upper surface contacting a lower surface of the second pinned magnets 4 and 4a and arranged at the same interval as the second pinned magnets 4 and 4a; Located in the spaced apart space of each ferromagnetic iron core (3), and divided into two poles N and S to the left and right, and the opposite surface with each ferromagnetic iron core (3) between them maintains the same polarity, but the polarity is A plurality of first stator magnets (2) (2a) having the same polarity as the second stator magnets (4) (4a) in contact with the upper surface of the ferromagnetic iron core (3); The ferromagnetic iron cores 3 between the metal plate 5 and the first stator magnets 2 and 2a are spaced apart from each other. The ferromagnetic iron cores 3 are divided into N and S poles to the left and right, and are rotatable. A plurality of rotor magnets (1) (1a), which may have the same polarity arrangement or the opposite polarity arrangement as the stator magnets (2) (2a) Magnetic lift including The method of claim 1, Magnetic lift, characterized in that the second stationary magnet (4) (4a) are arranged at intervals with respect to each of the ferromagnetic iron core (3)