KR200182620Y1 - Structure of electric magnet for magnetic separator - Google Patents

Abstract

The present invention relates to an electromagnet for a magnetic separator, and more particularly, in an electromagnet for a magnetic separator for separating iron pieces or iron powders by magnetic force from ores or grains in which iron pieces or iron powders are mixed. In order to easily dissipate the heat generated in the coil of the coil to form a double, and between the coil is separated between the dual relates to the structure of the electromagnet for magnetic separator for forming a heat dissipation passage for heat dissipation.

According to the present invention, since the heat generated in the coil of the electromagnet can be easily discharged and accumulated around the coil, it is possible to prevent the increase of the coil resistance due to the increase in the ambient temperature, thereby preventing the decrease in the amount of current flowing through the coil. By maintaining a constant magnetic force of the electromagnet has the effect of dramatically improving the performance of the electromagnet for the magnetic separator. In addition, it is possible to reduce the thickness of the coil and the distance between the lines, thus lowering the production cost of the electromagnet, it is effective to increase the life of the insulation around the coil.

Description

Electromagnet structure for magnetic separator {Structure of Electric Magnet For Magnetic Separator}

The present invention relates to an electromagnet for a magnetic separator, and more specifically, to separate iron pieces or iron powders by magnetic force from ores or grains (hereinafter referred to as 'iron mixtures') in which iron pieces or iron powders are mixed. In the electromagnet for magnetic separator, in order to easily discharge the heat generated from the coil of the electromagnet, the coil is separated and formed in duplicate, and the magnetic separator for the magnetic separator is formed with a heat dissipation passage for heat radiation It is about the structure.

Referring to the accompanying drawings, an electromagnet structure for a magnetic separator according to the prior art is as follows. 1 is a perspective view showing the appearance of the magnetic separator for the magnetic separator according to the prior art, Figure 2 is a cross-sectional view of the electromagnet for the magnetic separator according to the prior art shown in FIG.

As shown in FIG. 2, the conventional electromagnet for magnetizer has a core 24 having a core cooling hole 2, a bobbin 6 inserted into the core 24, and an integral part of the bobbin 6. Coil 5 wound around, Bobbin fixing cap 7 for fixing bobbin 6 wound around coil 5 to core 24, Core 24, Bobbin 6 and coil ( Yoke (3,4) formed to accommodate the 5) and the lug (1) is installed in the upper corner of the yoke and formed to connect the wire rope (not shown). The lug 1 is connected to the structure fixing device (not shown) for installing the magnetic separator with a wire rope.

The conventional electromagnet for magnetic separator having the configuration as described above inevitably increases the number of windings of the coil in order to obtain a sufficient magnetic force required for the suction and support of the magnetic material, so that the size of the electromagnet is usually large. The biggest problem in the conventional magnetic separator is the heat accumulated in the coil. As the number of turns of the coil increases, the thickness of the coil becomes thicker and the accumulated heat increases, which not only causes the coil insulator to age easily, but also increases the resistance of the coil to attenuate the magnetic flow of the electromagnet by interrupting current flow. There is a problem.

Conventionally, various methods have been tried to solve the thermal problem generated in the above-described coil. In order to increase the heat dissipation area, a method of increasing the length of the core and distributing the coil in a large area or using a coil having a large diameter to reduce the current density of the coil is adopted. The electromagnet manufactured as described above has a certain limit in releasing heat accumulated in the winding in the case of a large electromagnet requiring a large magnetic force, and the manufacturing cost increases, the volume is larger than necessary.

The present invention in consideration of the above problems is to provide a structure of an electromagnet for magnetic separator of the structure to easily discharge the Joule heat generated in the coil by maximizing the heat dissipation area of the electromagnet.

1 is a perspective view showing the appearance of a conventional electromagnet for magnetic separator.

FIG. 2 is a front sectional view of the electromagnet for the conventional magnetic separator shown in FIG.

Figure 3 is a perspective view showing the appearance of an electromagnet for a magnetic separator according to the present invention.

4 is an exploded perspective view of an electromagnet for a magnetic separator according to the present invention.

5 is a plan view of an electromagnet for a magnetic separator according to the present invention.

FIG. 6 is a sectional view taken along the line A-A shown in FIG.

* Description of the symbols for the main parts of the drawings *

1: Lug 2: Core cooling hole 3: York top plate

4: York side plate 5: Coil 6: Bobbin

7: bobbin fixing cap 8: magnetic flux compensation yoke 9: magnetic flux compensation yoke

10: Magnetic flux compensation yoke support plate 12: Terminal box 13: Cable ball

14: 1st bobbin 15: 2nd bobbin 16: 1st coil

17: 2nd coil 18: Coil isolation container 19a: Top cover heat opening

19b: heat dissipation passage 19c: second bobbin fixing cap heat dissipation opening 20: first bobbin fixing cap

21: Second bobbin fixing cap 22: First bobbin protective plate 23: Second bobbin protective plate

24: core 25: first coil inlet 26: second coil inlet

The present invention in consideration of the above object is in the electromagnet for magnetic separator comprising a yoke formed of the upper plate and the side plate and a core installed in the yoke,

A first bobbin inserted into and fixed to the core;

A first coil wound around the first bobbin,

Cylindrical coil isolation passage inserted into the outer side of the first bobbin and the first coil,

A second bobbin inserted and fixed to an outer side of the coil isolator, the inner circumferential surface of which is inserted and fixed while maintaining an appropriate distance from the coil isolator to form a heat dissipation passage capable of dissipating heat generated from the coil while air is in communication;

A second coil wound around the second bobbin,

A plurality of top plate heat dissipation openings formed along the flat cross-sectional path of the heat dissipation passage to the yoke top plate to be connected to the heat dissipation passage to allow air communication;

Magnetic flux compensation means is installed while maintaining a constant height across the top of the top plate heat release opening from the inside to the outside to compensate for the magnetic flux attenuated by the top plate heat opening;

Located at the lower end of the heat dissipation passage and fixedly support the lower end of the coil isolation cylinder and the bottom of the second bobbin to maintain a constant distance, the central portion includes a second bobbin fixing cap formed with a heat dissipation opening along the heat dissipation passage; Characterized in that the configuration.

When the electromagnet for magnetic separator has the configuration as described above, heat generated in the coil of the electromagnet is easily discharged through the heat dissipation passage formed between the two coils, and the heat dissipation opening formed continuously with the heat dissipation passage above and below the heat dissipation passage. It becomes possible.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Figure 3 is a perspective view showing the appearance of the electromagnet for magnetic separator according to the present invention, Figure 4 is an exploded perspective view of the electromagnet for magnetic separator according to the present invention, Figure 5 is a plan view of the electromagnet for magnetic separator according to the present invention, 6 is a cross-sectional view of the AA line shown in FIG. 5, respectively.

Electromagnet structure for the magnetic separator of the present invention is yoke top plate 3 and yoke side plate 4, core 24, core cooling hole (2) and wire rope lug (1) as shown in Figure 3 and 4 It has the same structure as the conventional electromagnet for magnetic separator.

However, as shown in FIG. 4, the magnetic separator for the magnetic separator according to the present invention is configured to double the first coil 16 and the second coil 17 by separating the coils, which are conventionally formed integrally, and between the coils. The heat dissipation passage 19b is formed so that the heat generated by the coil can be easily discharged.

In general, the coil of the electromagnet is wound around the bobbin and installed in the electromagnet core. According to the present invention, since the coil is separated into the first coil 16 and the second coil 17, the first bobbin according to each bobbin coil Two bobbins (14) and a second bobbin are required. The bobbin is generally made of stainless material and the inner surface is coated with an insulator.

The heat dissipation passage 19b is formed by the following method.

First, the core 24 is fixed to the yoke top plate 3, and then the first bobbin 14 in which the first coil 16 is wound is inserted into and fixed to the core 24. At the bottom of the first bobbin 14 is inserted and fixed to the first bobbin fixing cap 20 formed to accommodate them. Next, the cylindrical coil isolator 18 is inserted into and fixed to the outer circumferential surfaces of the first coil 16 and the first bobbin 14. Next, the second bobbin having a diameter of the inner circumferential surface larger than the diameter of the outer circumferential surface of the coil isolator 18 and which can maintain a constant distance from the outer circumferential surface of the coil isolator 18, and the second coil 17 is wound. 15) is installed outside the coil isolator (18). By doing so, a predetermined space is formed between the outer circumferential surface of the coil isolator 18 and the inner circumferential surface of the second bobbin 15. In the electromagnet for magnetic separator according to the present invention, the space is used as the heat dissipation passage 19b. The second bobbin fixing cap 20 is fixed to the lower end of the second bobbin 15 and the lower end of the coil isolator 18 to accommodate them. The second bobbin fixing cap 20 is positioned at the lower end of the heat dissipation passage 19b to support the coil isolation cylinder 18 and the second bobbin fixing cap 20, wherein the heat dissipation passage 19b is formed on the outside of the heat dissipation passage 19b. In order to be connected continuously, the heat dissipation opening 19c as shown in FIGS. 4 and 6 is formed at the center of the second bobbin fixing cap 20.

The heat dissipation opening 19a is also formed at the yoke top plate 3 so as to be connected to the heat dissipation passage 19b and the second bobbin fixing cap heat dissipation opening 19c so as to allow the air to communicate with the heat dissipation to the outside. The top plate heat dissipation opening 19 is required for air communication, but it causes discontinuity in the magnetic fields formed in the cores 24 and the yokes 3 and 4, resulting in attenuation of the magnetic flux density. In order to solve this problem, the magnetic flux separator electromagnet according to the present invention is provided with a magnetic flux compensating means for compensating for attenuated magnetic flux.

The magnetic flux compensation means may be implemented in various ways above the upper plate heat release opening 19a, but a preferred embodiment thereof is illustrated in FIGS. 4 to 6.

As shown in Figures 4 to 6, the magnetic flux compensation means according to a preferred embodiment

The magnetic flux compensation yoke 8 is installed at the center of the yoke upper plate 3 and has an overall disk-shaped structure and has a protrusion extending at the edge thereof to extend the upper plate heat dissipation opening 19a. The magnetic flux compensating yoke 8 and the yoke are installed to be positioned between the magnetic flux compensating yoke 8 and the yoke top plate 3 while being spaced apart from the yoke top plate 3 at regular intervals. A disk-shaped magnetic flux compensation yoke support plate 10 for forming a magnetic path between the upper plates 3 and the protrusion of the compensation yoke 8 provided outside the upper plate heat release opening 19a. It is characterized in that it is composed of a bar-shaped magnetic flux compensation yoke part 9 for forming a path between the protrusion of the compensation yoke 8 and the yoke top plate 3 while supporting the end.

As shown in Figs. 4 to 6, openings 2a and 2b are formed at the center of the magnetic flux compensation yoke 8 and the magnetic flux compensating yoke support plate 10 so as to constitute a part of the core cooling hole 2. .

The yoke top plate 3 shown in Figs. 3 to 6 is provided with a terminal box 12 having a cable hole 13 for connecting cables to the outside while including a control panel therein. As shown in the cross-sectional view of the terminal box, two coil outlets 25 and 26 are formed through the yoke upper plate 3 below, and these coils of the electromagnet of the magnetic separator according to the present invention are connected to the terminal box. And it is for drawing out to the outside, it is not unique to the present invention except that two coil outlets are formed on the structural features of the present invention for separating the coil in two.

According to the present invention, since the heat generated in the coil of the electromagnet can be easily discharged and accumulated around the coil, it is possible to prevent the increase of the coil resistance due to the increase in the ambient temperature, thereby preventing the decrease in the amount of current flowing through the coil. By maintaining a constant magnetic force of the electromagnet has the effect of dramatically improving the performance of the electromagnet for the magnetic separator. In addition, it is possible to reduce the thickness of the coil and the distance between the lines, thus lowering the production cost of the electromagnet, it is effective to increase the life of the insulation around the coil.

Claims (2)

Magnetic coil that separates iron or iron powder by magnetic force from the bobbin coiled with coil and core to accept the bobbin, and yolk to accommodate the bobbin and core, from ore or grain in which iron or iron powder is mixed In the electromagnet for the separator, the electromagnet is A first bobbin 14 inserted and fixed to the core; A first coil 16 wound around the first bobbin 14, A cylindrical coil isolator 18 inserted into an outer side of the first bobbin 14 and the first coil 16, Inserted and fixed to the outside of the coil isolator 18, the inner circumferential surface is inserted and fixed so as to form a heat dissipation passage (19b) that can dissipate heat generated from the coil while air is in communication with the coil isolator The second bobbin 15, A second coil 17 wound around the second bobbin 15, A plurality of top plate heat dissipation openings 19a formed along the flat cross-sectional path of the heat dissipation passage to the yoke top plate to be connected to the heat dissipation passage 19b to allow air communication; Magnetic flux compensation means is installed while maintaining a constant height across the top of the top plate heat release opening (19a) from the inside to the outside to compensate for the magnetic flux attenuated by the top plate heat release opening (19a), Located at the lower end of the heat dissipation passage (19b) and fixed to support the lower end of the coil isolation cylinder 18 and the lower end of the second bobbin 15 to maintain a constant distance, the center of the heat dissipation passage (19b) Electromagnet structure for magnetic separator, characterized in that it comprises a second bobbin fixing cap 21 is formed along the heat dissipation opening (19c). According to claim 1, wherein the magnetic flux compensation means is installed in the center of the yoke upper plate (3), and has a disk-shaped structure as a whole, the protruding portion extended so that the upper plate heat dissipation opening (19a) can be over the edge It is installed to be located between the magnetic flux compensation yoke (8) and the magnetic flux compensation yoke (8) and the yoke upper plate (3) spaced apart from the yoke upper plate (3) at regular intervals. While the magnetic flux compensation yoke plate (10) of the disk-shaped to form a magnetic path between the magnetic flux compensation yoke (8) and the yoke top plate (3), the outer side of the top plate heat dissipation opening (19a) A magnetic flux compensation yoke part of a rod shape, which is installed in the rod shape to support the end of the protrusion of the compensation yoke 8 and to form a magnetic path between the protrusion of the compensation yoke 8 and the yoke top plate 3. (9) characterized in that Power screening appointed electromagnet structure.