KR101821578B1 - Electrical magnet lifter for wide steel plate - Google Patents

Abstract

The present invention relates to an electromagnet lifter for a wide-width steel plate, in which a plurality of electromagnet lifters are formed in a specific structure in accordance with the use of the electromagnet assembly for attracting and lifting a wide-width steel plate, The present invention provides an electromagnet lifter for a wide-width steel plate, which is capable of lifting a steel plate by lifting the steel plate by extending the length of the electromagnet lifter according to the increase of the electromagnet lifter,
To this end, according to an embodiment of the present invention, there is provided an electromagnet lifter for a wide-width steel plate, wherein a plurality of unit electromagnets are connected to each other to form a simultaneous-type magnet assembly, Each unit electromagnet is constituted such that a winding is wound on the outer circumferential surface of a vertical cylindrical iron core, a first frame magnetic pole of a rectangular plate shape is arranged on the front and rear surfaces thereof, and an upper yoke of a rectangular plate shape is arranged on the upper side thereof; The first frame magnetic pole and the upper magnetic pole provided in each unit electromagnet are spaced apart from the first frame magnetic pole and the upper yoke of the adjacent unit electromagnets by a predetermined distance to form a space between the unit electromagnets, And a plurality of unit electromagnets are integrally connected together via a second frame stimulus having a panel shape of a predetermined length.

Description

ELECTRICAL MAGNET LIFTER FOR WIDE STEEL PLATE

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electromagnet lifter for a wide-width steel plate, and more particularly, to an electromagnet lifter for a wide electromagnet assembly which is installed in a crane so that each electromagnet lifter has a specific structure, And an economical effect such as elimination of energy waste due to setting of an excessive attraction force is expected.

      Generally, an electromagnet lifter is a facility essential for the operation of a steel mill, and it plays a role of moving a steel plate and heavy steel produced in a crane.

      At this time, the attracting force of the electromagnet provided in the electromagnet lifter is basically determined according to the load of the object to be lifted, but in the case of the lifter for the steel plate, the condition according to the width and the length must be added in addition to the load.

      Particularly, as the width and length of the steel sheet increase to about 5.5 meters [m] and 23 meters [m], respectively, as the steelmaking technology develops, the electromagnet lifter for lifting the steel plate has a structure of connecting the plurality of unit electromagnet assemblies Type electromagnet assemblies so that the width of the steel plates can be increased and a plurality of simultaneous electromagnet assemblies can be arranged at regular intervals to prepare for an increase in the length of the steel plates.

      Since the multiple electromagnet assemblies are structured to mechanically connect a plurality of unit electromagnets, the attracting force and the self weight of the unit electromagnets increase as the number of electromagnets increases. Also, when a plurality of electromagnet assemblies are arranged, The total lifting force of the combined electromagnet assembly is several times higher than the lifting power of the crane, which is much higher than the safety standard defined by the relevant laws and regulations, and the energy consumption is economically burdensome .

      In the case of the ship-to-ship, many steel plates are lifted each time. At this time, the attracting force of the electromagnets is very strong between the laminated steel plates. Therefore, the electromagnet lifter needs to be divided into a production process for lifting one sheet at a time according to the purpose of use, and a shipping operation for lifting a plurality of sheets.

      On the other hand, the electromagnet is magnetized when a current is applied to the ferromagnetic iron core by winding the solenoid coil. When a current is applied to the coil wound on the iron core, a magnetomotive force is generated. .

      At this time, the magnitude of the magnetomotive force depends on the current and the number of turns of the winding.

           The magnetomotive force H = NI (AT)

      The amount of magnetic force penetrating the iron core is called magnetic flux density.

           Magnetic flux density B = μH

                         μ: magnetic permeability (magnetic property value of the material)

      The magnitude of the force

F = SB ² (S: iron core cross-sectional area).

      The magnetic flux density is defined as the number of magnetic flux lines passing through the inside of the iron core. The magnetic flux density is defined as a magnetic saturation state in which the magnetomotive force is not increased even if the magnetomotive force is increased according to the characteristics of the iron core. The magnetic flux density does not increase and energy is wasted.

      At this time, the magnetic flux density due to the magnetic force lines flowing inside the iron core is not uniformly distributed throughout the cross-sectional area of the iron core, and the density at the center portion is close to "0", and the skin effect is increased as the iron core surface is increased.

       Also, in a state in which the N pole and the S pole constituted by the parallel plates face each other with the space therebetween, the magnetic flux density in the intermediate inner space is high and the outer peripheral surface is relatively low in density.

      In addition, the winding formed by winding the wire so as to surround the center iron core generates heat due to the resistance when the current is passed for a long time, and the self temperature rises due to the heat generated at this time, The current is decreased and the magnetomotive force is reduced, and thus the attraction force is weakened.

      Accordingly, the magnetic circuit must be designed in consideration of the above-described problems.

      1 shows a schematic structure of a unit electromagnet assembly for lifting a steel sheet currently used in a steel mill and a shipyard, in which a winding 2 is wound around a vertically cylindrical iron core 1 located at the center, The lower end face of the vertical cylindrical iron core 1 and the lower end face of the outer frame pole 4a and 4b form the N pole and the S pole of the magnet respectively, A magnetic circuit is formed while being in contact with the steel plate 5.

      The magnetic force lines generated from the magnetomotive force are generated by the iron core 1, the upper yoke 3, the outer frame magnetic poles 4a and 4b, and the attracted steel plate 5 ) - As the magnetic circuit that flows to the iron core 2 is constituted, it is possible to lift the steel plate.

      At this time, the sectional areas of the iron core 1, the upper yoke 3, and the outer frame magnetic poles 4a and 4b through which the magnetic lines of force flow should be the same.

      Meanwhile, when an electromagnet lift is applied to a steel plate requiring a larger force for lifting a steel plate or a wide steel plate, a plurality of unit electromagnet assemblies may be connected and used depending on their sizes as shown in FIGS. 2A and 2B At this time, one side of the outer frame magnetic pole 4a is adjacent to the outer frame magnetic pole 4a of the added magnet assembly, and the outer frame magnetic pole 4b of the remaining side extends in the longitudinal direction to form a continuous type assembly do.

      Here, when two or more unit electromagnet assemblies are connected and used, the upper electromagnets 3 are composed of one steel plate. In the vicinity of the boundary where the two unit electromagnet assemblies are in contact with each other, The direction of the passing magnetism is opposite to each other and partially canceled, so that the attracting force of the simultaneous electromagnet assemblies is less than the arithmetic sum of the attracting forces of the unit electromagnet assemblies as shown in [Table 1].

Unit electromagnet number Three 4 5 Adsorption force (kg) 36,330 44,130 45,860 Adhesive force per unit (kg) 12,110 11,032.5 9,172

      In addition, the combined electromagnet assemblies composed of six unit electromagnets had a capacity of 24 tons. However, the unit electromagnet assemblies constituting the unit electromagnet assemblies had a capacity of 6 tons. Thus, measures for attenuating the attraction force between neighboring unit electromagnets are required The following figure shows the results of computer simulation by examining various solutions.

* Simulation results of domestic patent application No. 10-2010-0052149

      As described above, in order to solve the above-mentioned problems, the applicant of the present invention has proposed, through Korean Patent Application No. 10-2011-0132686 (Application No. 10-2010-0052149) To prevent the problem of offsetting the magnetism.

      That is, although the attraction force of the electromagnet is determined according to the weight of the steel to be lifted, the width and length of the steel sheet are much larger than the size of the unit electromagnet (400 mm x 400 mm), so that a plurality of unit electromagnets are connected, A plurality of longitudinal electromagnet assemblies are arranged in correspondence with the width of the steel sheet to lift the steel sheet that has grown in the longitudinal direction.

      Actually, steel plates produced in steel mills have a length exceeding 20 meters [m], so that about 6 to 7 parallel assemblies as described above are installed at intervals of about 2 to 3 meters [m] depending on the length of the steel plates To lift a steel plate having a width of 5 meters [m] and a length of 23 [m] or more (see FIG. 4).

      Since the multiple electromagnet assemblies mechanically connect a plurality of unit electromagnets, the attracting force and the self weight of the electromagnets increase as the number of electromagnets increases, and the actual lifting force of the crane is reduced by the self-load of the electromagnets.

      The sum of the attraction force of the almanac type electromagnet assemblies installed on the crane in the actual site is more than several times the safety value of the lifting force of the crane, which causes a problem that it is a waste of energy and cost.

      [Table 2] below shows the state of attraction force of the algebraic electromagnet assemblies installed in the actual crane.

Crane lifting rating Safety factor (3.0) Electromagnetism absorption force (ton) Remarks 30 tons 90 tons 168 tons For process
40 tons 120 tons 280 tons 40 tons 120 tons 480 tons Shipment

      Since the loss of the attracting force between the laminated steel plates becomes very large at this time, the attracting force of the electromagnet for shipment is determined by the lifting rating of the crane, Is required.

      Therefore, the electromagnet lifter for the production process requires a structure in which the attraction force is widely distributed in accordance with the width and length of the steel plate, while the lifting force of the crane is matched to the lifting rating of the crane. , A strong attraction force is required irrespective of the lifting rating of the crane.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide an electromagnet lifter having a specific structure in an electromagnet assembly for lifting a wide-width steel plate by being installed on a crane, Which is capable of lifting a stable steel sheet through a large-width steel plate.

      According to an aspect of the present invention, there is provided an electromagnet lifter for a wide-width steel plate, the electromagnet lifter for a wide-width steel plate comprising a plurality of unit electromagnets connected to each other, Each unit electromagnet is constituted such that a winding is wound on the outer circumferential surface of a vertical cylindrical iron core, a first frame magnetic pole of a rectangular plate shape is arranged on the front and rear surfaces thereof, and an upper yoke of a rectangular plate shape is arranged on the upper side thereof; The first frame magnetic pole and the upper magnetic pole provided on each unit electromagnet are spaced apart from the first frame magnetic pole and the upper yoke of the adjacent unit electromagnets by a predetermined distance to form a space between the unit electromagnets, And a plurality of unit electromagnets are integrally connected to each other through a second frame stimulus having a panel shape having a predetermined length.

      Preferably, an auxiliary magnetic pole in the form of a rod is provided along the longitudinal direction at the lower end of the inner wall of the second frame magnetic pole and the lower end of the outer circumferential face of each cylindrical iron core. At the lower end of the outer wall of the second frame magnetic pole, And a plurality of protection members are formed at regular intervals.

      Preferably, a lower portion of the second frame magnetic pole corresponding to the space portion formed at a predetermined distance from the first frame magnetic pole and the upper magnetic pole of each unit electromagnet is removed by a predetermined height.

      Preferably, the upper corner of the upper electromagnets of each unit electromagnet is formed so as to be inclined at an angle of 45 DEG from the lower side to the upper side, thereby preventing magnetic loss due to an edge effect do.

      Since the center of the iron core has no magnetic flux due to the skin effect, the center of the vertical cylindrical iron core is formed in a tubular shape along the longitudinal direction so that the magnetic force acts simultaneously on the center and outer edges of the iron core bottom surface .

      It is preferable that the vertical cylindrical iron core is divided into a plurality of sections so as to have a sector shape centering on the central part so that the distribution of the magnetic flux density is uniformly formed in an end face of the iron core contacting the electrolyte.

      Meanwhile, according to another embodiment of the present invention, there is provided an electromagnet lifter for a wide-width steel plate, in which a plurality of unit electromagnets are connected to each other to form a simultaneous-type magnet assembly, Each unit electromagnet is constituted by winding a winding around an outer peripheral surface of a rectangular parallelepiped core disposed horizontally; A plurality of unit electromagnets are integrally formed by a pair of frame magnetic poles having a certain length of a panel shape forming both side surfaces of the monolithic magnet assembly in a state where the unit electromagnets are spaced apart from each other by a space and mutually forming a space portion; .

      Preferably, the bar-shaped auxiliary magnetic pole is provided along the longitudinal direction at the lower end of the inner wall facing the N pole and the S pole of the pair of frame magnetic poles.

      More preferably, a plurality of steel plate surface protecting members each having a triangular shape are formed at a predetermined interval at the lower end of the outer wall of the pair of frame members.

      Since the center of the iron core has no magnetic flux due to the skin effect, the center of the rectangular iron core is formed in a tubular shape so that the magnetic force acts on both the center and the outer edge of both ends of the iron core. desirable.

      It is preferable that the rectangular parallelepiped iron core is divided into a plurality of squares of two or more, and the distribution of the magnetic flux density is uniformly formed at both ends of the rim.

      Preferably, the abutment surfaces of the plurality of unit electromagnets connected to each other are knurled.

According to the present invention as described above, in an electromagnet lifter that moves a wide-width steel plate installed in a crane at a steel plant, the electromagnet lifter is divided into a production line for lifting several sheets at the same time and a production line for lifting one sheet at a time And the electromagnet attracting force is appropriately set and operated according to the purpose, thereby reducing the load of the electromagnet assembly, reducing the energy used, and increasing the actual lifting force of the crane.

In addition, since the individual electromagnet assemblies for absorbing and lifting the wide steel plate are formed in a specific structure so as to have a space (space) between the unit electromagnet assemblies, the attracting force of the electromagnets can be greatly increased. So that it is possible to reliably lift the steel sheet.

1 is a view showing a schematic structure of a conventional unit magnet assembly for lifting a steel sheet,
FIGS. 2A and 2B are a plan sectional view and a front sectional view showing a schematic structure of a conventional simultaneous electromagnet assembly,
3 is a view showing a state of operation of a magnetomotive force of a conventional simultaneous electromagnet assembly,
4 is a view showing a state in which a plurality of simultaneous electromagnet assemblies are installed in a crane,
5 is a perspective view showing a structure of an electromagnet lifter (vertical winding type) for a wide-width steel plate according to the present invention,
6A to 6C are a side view, a front sectional view and a flat sectional view showing the construction of an electromagnet lifter (vertical winding type) for a wide-width steel sheet according to the present invention,
6D is a side view showing a modification of the electromagnet lifter (vertical winding type) for a wide-width steel plate according to the present invention,
Fig. 7 is a perspective view showing the configuration of an electromagnet lifter (horizontal winding type) for a wide-width steel sheet according to the present invention,
8 is a perspective view showing the appearance of a winding applied to an electromagnet lifter (horizontal winding type) for a wide-width steel sheet according to the present invention,
9A and 9B are a front sectional view and a plan view showing the structure of an electromagnet lifter (horizontal winding type) for a wide-width steel sheet according to the present invention,
10A and 10B are views showing various embodiments of an iron core applied to an electromagnet lifter (vertical winding type) for a wide-width steel sheet according to the present invention,
11A and 11B are views showing various embodiments of iron cores applied to an electromagnet lifter (horizontal winding type) for a wide-width steel sheet according to the present invention.

Hereinafter, the present invention configured as described above will be described in detail with reference to the accompanying drawings.

Fig. 5 is a perspective view showing the construction of an electromagnet lifter (vertical winding type) for a wide-width steel plate according to the present invention, and Figs. 6A to 6C are views showing a state in which a plurality of electromagnet assemblies Fig. 7 is a perspective view showing the construction of an electromagnet lifter (horizontal winding type) for a wide-width steel sheet according to the present invention, Fig. 8 is a perspective view showing the structure of an electromagnet lifter for a wide- 9A and 9B are a front sectional view and a plan view showing a structure of an electromagnet lifter (horizontal winding type) for a wide-width steel sheet according to the present invention. Fig. 9A is a perspective view showing the appearance of a winding applied to an electromagnet lifter for a wide-

First, the electromagnet lift for a wide-width steel plate according to the present invention is a coal-type electromagnet assembly that performs a role of moving a wide-width steel plate installed in a crane in a steelworks or the like. In the electromagnet assembly for each width, .

That is, the electromagnet lifter is a facility essential for the operation of a steelworks. As shown in FIG. 4, the electromagnet lifter performs a role of moving a steel plate and heavy steel produced in a state of being installed in the crane 200.

At this time, the size and the attraction force of the simultaneous electromagnet assembly 100 for moving the wide steel plate must be set differently according to the size and quantity of the steel sheet to be lifted, and the shape and the structure thereof must be designed differently.

Here, the electromagnet lifter for a wide-width steel sheet according to an embodiment of the present invention is configured to provide an attracting force necessary for lifting a plurality of steel plates for shipment of a wide-width steel sheet.

That is, at the time of shipment of the steel sheet, even though a plurality of steel plates are in close contact with each other, the attraction force is greatly decreased, so strong attraction force is required regardless of the lifting limit of the crane 200, The electromagnet assembly 100 having a vertical iron core structure is preferably applied to the electromagnet assembly 100. In this case, the electromagnet assemblies 100 are arranged such that the unit electromagnets are spaced apart from each other by a predetermined distance .

Accordingly, each unit electromagnet constituting the simultaneous electromagnet assembly 100 having the vertical iron core structure is constituted such that a winding 14 is wound on the outer circumferential surface of the cylindrical iron core 10, And an upper yoke 16 in the form of a rectangular plate is disposed on the upper side thereof.

The first frame magnetic pole 12a and the upper yoke 16 of the unit electromagnets are spaced apart from the first frame magnetic pole 12a and the upper yoke 16 of the adjacent unit electromagnets by a predetermined distance, And each of the unit electromagnets includes a plurality of unit electromagnets (not shown) via a second frame magnetic pole 12b having a panel shape of a predetermined length forming both sides of the same, It consists of an integral body.

As the auxiliary magnetic pole 18 in the form of a rod is formed along the longitudinal direction at the lower end of the inner wall of the second frame magnetic pole 12b and the lower end of the outer circumferential face of each cylindrical iron core 10, the attracting force is increased Lt; / RTI >

Since a plurality of steel plate surface protecting members 20 having a right-angled triangle shape are formed at the lower end of the outer wall of the second frame magnetic pole 12b at a predetermined interval, the contact area of the steel plate with the steel plate is enlarged, Can be minimized.

The upper electromagnets 16 of each unit electromagnet forming the coal type magnet assembly 100 are formed such that the upper corners of the upper electromagnets are removed from the lower side so as to be inclined at an angle of 45 DEG from the lower side, The magnetic force loss due to the edge effect can be prevented.

According to a modification of the electromagnet lifter (vertical winding) for a wide-width steel plate according to the present invention shown in FIG. 6 (d), a space portion formed at a predetermined interval between the first frame- It is possible to suppress the interference between the attracting forces acting between adjacent unit electromagnets by removing the lower portion of the second frame magnetic pole by a predetermined height.

10A, since there is no magnetic flux at the central portion of the iron core due to the skin effect, the center of the vertical cylindrical iron core 10 is formed in a tubular shape along the longitudinal direction, And may have a structure that acts simultaneously at the center and outer edges of the substrate.

As shown in FIG. 10B, the vertical cylindrical iron core 10 is divided into a plurality of sections so as to have a sector shape centering on the central portion, so that the distribution of the magnetic flux density is uniformly formed in the cross section of the iron core contacting the attracting object Structure.

The electromagnet lifter for a wide-width steel sheet according to another embodiment of the present invention is configured to provide an attraction force necessary for lifting a single steel sheet for a steel sheet production process in a steelworks.

      The electromagnet lifter used for the manufacturing process of the steelworks is preferably determined by the lifting limit of the crane when lifting a steel sheet, and the size thereof is preferably a horizontal iron core structure which is easy to adjust according to the width of the steel sheet.

      Table 4 shows an example (4 pole) of the installation method of the process magnet proportional to the lifting rating of the crane.

crane
Rated lifting Unit magnet
Adsorption power Number of magnet units
(Per pot) Per pot
Adsorption power Adsorption power 6 Pot 30 tons 3.75 tons 4 15 tons 90 tons (3.0) 40 tons 5 tons 20 tons 120 tons

      Here, in the electromagnet lifter for a wide-width steel plate composed of the simultaneous-type magnet assembly 100, each unit electromagnet has a winding 34 wound around the outer circumferential surface of a rectangular parallelepiped iron core 30 having a substantially rectangular parallelepiped shape, And a pair of frame magnetic poles 32 having a panel shape of a predetermined length forming both sides of the simultaneous magnet assembly 100 in a state in which they are spaced apart from each other by a space (L: air gap) So that they are integrally formed.

In addition, since the auxiliary magnetic poles 38 in the form of bars are provided along the longitudinal direction at the inner wall lower end of the pair of frame magnetic poles 32, the attracting force can be increased while the cross sectional area of contact with the steel plate is increased.

A plurality of steel plate surface protecting members 40 having a plurality of right angled triangles or strips are formed at regular intervals on the lower outer wall of the pair of frame magnetic poles 32. Through this, The damage of the surface of the steel sheet can be reduced.

Reference numeral 36 denotes a casing for protecting the windings wound on the outer circumferential surface of the rectangular parallelepiped core 30 and reference numeral 42 denotes a bolt for fastening the rectangular parallelepiped core 30 and the frame pole 32 to each other.

11A, since the magnetic flux does not exist in the central portion of the iron core due to the skin effect, the center of the rectangular parallelepiped iron core 30 is formed in a tubular shape so that the magnetic force is applied to the center of both ends of the iron core And to have a structure that acts simultaneously on the outer edge.

11 (b), the rectangular parallelepiped iron core 30 is divided into a plurality of quadrangles each formed of two or more pieces to form a structure in which magnetic flux density distributions are uniformly formed at both end surfaces of the rim magnetic pole .

Meanwhile, in the electromagnet lifter for the vertical winding type and the horizontal winding type wide width steel sheet according to the present invention, the contact surface of the yoke type magnet assembly in which the plurality of unit electromagnets are connected to each other is contacted with knurling Do.

Next, the operation of the present invention as described above will be described in detail as follows.

      The electromagnet lifter for a wide-width steel plate according to the present invention is a coal-type electromagnet assembly 100 that performs a role of moving a wide-width steel plate installed in a crane 200 at a steelworks, Or a three-layered electromagnet assembly having a horizontal iron core structure can be applied.

      Here, each of the unit electromagnets constituting the simultaneous electromagnet assembly 100 is configured such that the unit electromagnets are spaced apart from each other by a predetermined space (L: air gap) The problem that the attracting force of the simultaneous electromagnet assembly 100 is lowered is canceled as the directions of the magnetomotive force passing through the inside of the upper yoke 16 in the vicinity of the mutually adjacent pair of unit electromagnets come into mutual opposition .

      On the other hand, each unit electromagnet constituting the simultaneous electromagnet assembly 100 generates heat in the internal windings 14 and 34 according to repeated use. As the temperature of the electric wire rises, the resistance of the electric wire increases The current flowing therethrough is reduced, and the magnetomotive force and the attraction force are reduced.

      Therefore, the flow of magnetic flux in the central iron core, the upper yoke, and the frame stimulus is kept supersaturated to a certain level, and in the gap between the N pole and the S pole of the pole face contacting with the steel sheet, The lower end of the inner wall of the second frame magnetic pole 12b and the lower end of the outer circumferential face of each cylindrical iron core 10 in the embodiment of the present invention are provided with the ends of the magnetic poles 32 on the inner wall of the frame magnetic pole 32 It is possible to improve the attracting force by increasing the cross-sectional area of contact with the steel plate by additionally providing the auxiliary magnetic poles 18 and 38 partially extending in cross section.

      Since a plurality of steel plate surface protecting members 20, 40 having a right-angled triangle shape are formed at regular intervals at the outer wall lower end of the second frame magnetic pole 12b or the frame magnetic pole 32, The surface damage of the steel sheet can be prevented.

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, on the contrary, is intended to cover various modifications and equivalent arrangements included within the scope of the appended claims.

10: cylindrical iron core, 12a: first border stimulus,
12b: second border stimulus, 14: winding,
16: upper yoke, 18: auxiliary magnetic pole,
20: steel plate surface protecting member,
30: rectangular parallelepiped core, 32: outer frame stimulus,
34: winding, 36: casing,
38: auxiliary magnetic pole, 40: steel plate surface protecting member,
42: fastening bolt,
100: simultaneous electromagnet assembly, 200: crane,
L: Pore.

Claims (6)

1. An electromagnet lifter for a wide-width steel plate in which a plurality of unit electromagnets are connected to each other and constituted by a combination magnet assembly;
Each unit electromagnet is constituted by winding a winding around an outer circumferential surface of a rectangular parallelepiped core disposed horizontally and a plurality of unit electromagnets are spaced apart from each other by a predetermined distance to form a space, A pair of frame stimuli having a panel shape;
An auxiliary magnetic pole in the form of a rod is provided along the longitudinal direction at the lower end of the inner wall facing the N pole and the S pole of the pair of frame magnetic poles so that the attracting force is increased while the cross sectional area of contact with the steel plate is increased;
A plurality of steel plate surface protecting members each having a right angle triangle or a band shape are formed at a predetermined interval on the outer wall lower end of the pair of rim stripes to enlarge the contact area with the steel plate during the adsorption of the steel plate, Wherein the width of the elongated strip is reduced. delete delete The method according to claim 1,
The center of the iron core has no magnetic flux due to the skin effect, so that the center of the rectangular iron core is formed in a tubular shape so that the magnetic force acts on both the center and the outer edge of both ends of the iron core. Electromotive lifter for wide steel plate. The method according to claim 1,
Wherein the rectangular parallelepiped iron core is divided into a plurality of square portions each formed of two or more pieces so that the distribution of the magnetic flux density is uniformly formed at both end surfaces of the frame magnetic pole. The method according to claim 1,
Wherein the contact surfaces of the plurality of unit electromagnets connected to each other are knurled. ≪ RTI ID = 0.0 > 18. < / RTI >

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