KR20210067650A - Separator with demagnetizer function - Google Patents

Abstract

According to the present invention, a separator with a demagnetization function comprises: a raw material supply member having an end connected to a supply pipe to supply a powder raw material; an electromagnetic force generating member disposed in the supply pipe to generate an electromagnetic force in the supply pipe; a filter member positioned at an end of the raw material supply member to attach fine metal powder contained in the powder raw material; a power supply unit for supplying power to the electromagnetic force generating member for magnetization; and a demagnetization control unit for controlling the power supply of the power supply unit to the electromagnetic force generating member with a polarity opposite to the polarity applied when an electromagnetic force is generated for demagnetizing the filter member. According to the present invention, after selecting the fine metal powder contained in the powder raw material by magnetic force, power is supplied in the opposite direction to the polarity during magnetization for demagnetization, so that a separate magnetizer is unnecessary.

Description

Separator with demagnetization function {SEPARATOR WITH DEMAGNETIZER FUNCTION}

The present invention relates to a separator having a demagnetization function, and more particularly, to a separator for demagnetizing a filter unit that removes fine metal powder contained in a powder raw material without a separate demagnetization.

In general, magnetic sorting machines are used to obtain high-purity raw materials by removing iron components contained in raw materials in a fluid state or raw materials in a powder state, such as silica sand, mica grinding stone, porcelain stone powder, refractory materials, secondary battery raw materials, etc. do.

In addition, a rotary drum type separator for magnetically separating iron from various chemical and food raw materials is used. In addition, in order to remove the iron component from the supplied raw material, a roller-type sorter using an electromagnet or a permanent magnet is sometimes mounted on the outlet side.

A technology related to such a selector has been proposed in Korean Utility Model Registration No. 0205029.

However, Patent Document 1 has a problem in that the magnetic material is difficult to remove because the magnetization state is maintained even when the current applied to the coil is cut off after the magnetic magnetic material particles are selected.

Korea Registered Utility Model No. 0205029 (2000.09.19)

The present invention has been devised in view of the above points, and an object of the present invention is to provide a separator having a demagnetization function that enables the residual magnetism of a filter member to be demagnetized by supplying power in the opposite direction of polarity when magnetizing but it has a purpose.

A separator having a demagnetizing function according to the present invention for achieving the above object includes: a raw material supply member having an end connected to a supply pipe to supply powder raw materials; an electromagnetic force generating member disposed in the supply pipe to generate an electromagnetic force in the supply pipe; a filter member positioned at an end of the raw material supply member to attach fine metal powder contained in the powder raw material; a power supply for supplying power to the electromagnetic force generating member for magnetization; and a demagnetization control unit configured to control supply of power to the electromagnetic force generating member by the power supply unit to the electromagnetic force generating member with a polarity opposite to the polarity applied when the electromagnetic force is generated for demagnetizing the filter member.

The demagnetization control unit may control to supply 40 to 60% of the power of the power supply unit at the time of magnetization to the electromagnetic force generating member during demagnetization.

The demagnetization control unit may supply power to the power supply unit for demagnetization when stabilization by stopping power supply to the electromagnetic force generating member.

According to the present invention, there is an effect that a separate magnetizer is unnecessary by selecting the fine metal powder contained in the powder raw material by magnetic force and then supplying power to the opposite of the polarity during magnetization for demagnetization.

1 is a schematic diagram showing a separator having a demagnetizing function according to the present invention.
2 is a schematic diagram of a configuration for realizing a demagnetizing function in a selector having a demagnetizing function according to the present invention.
3 is a front view showing a filter member in the separator having a demagnetizing function according to the present invention.
4 is a plan view and a front view illustrating a filter part of a filter member in a separator having a demagnetizing function according to the present invention.

The above objects, features and other advantages of the present invention will become more apparent by describing preferred embodiments of the present invention in detail with reference to the accompanying drawings. Hereinafter, a separator having a demagnetization function according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic diagram showing a separator having a demagnetization function according to the present invention, FIG. 2 is a schematic diagram of a configuration for implementing a demagnetization function in a separator having a demagnetization function according to the present invention, and FIG. 3 is It is a front view showing the filter member in the sorter having a demagnetization function according to the present invention, and FIG. 4 is a plan view and a front view showing the filter part of the filter member in the sorter having a demagnetization function according to the present invention.

1 to 4 , the separator 100 having a demagnetizing function according to the present invention includes a raw material supply member 110 , a supply pipe 120 , a filter member 130 , an electromagnetic force generating member 140 , and a power source. It includes the supply unit 150 and the vibration generating member 160, and includes a filtering target, for example, silica sand, mica grinding stone, porcelain stone powder, refractory material, iron component contained in the powder raw material before packaging the secondary battery raw material. It relates to an apparatus for removing fine metal powder of

Moreover, although the above-described powder raw material is exemplified as the filtering object, the filtering object is not necessarily limited thereto and the filtering object may be a raw material in a fluid state.

The raw material supply member 110 is configured to supply a powder raw material to the filter member 130 as shown in FIG. 1 , and is formed in a hopper shape.

At this time, the lower end of the raw material supply member 110 is inserted into the upper end of the supply pipe 120 , and an extension part 112 in the form of a diameter enlarged flange so as to be fastened to the upper support part 122 with the fastener B on the outer circumferential surface. is formed to protrude.

Here, the fastener (B) is an eye nut or the like applied thereto, and is spirally fastened to the end of the hinge bolt rotatably provided on the upper support part 122 . At this time, a corresponding groove is formed on the outer peripheral surface of the extension part 112 to allow the hinge bolt to pass therethrough.

As shown in FIG. 1, the supply pipe 120 has an upright cylindrical shape, the lower end of the raw material supply member 110 is inserted thereon, the upper support part 122 is provided on the outer peripheral surface, and the lower support part ( 124) is provided.

At this time, the upper support part 122 is provided with a hinge bolt rotatably so that the fastener B can be fastened through the extension part 112 of the raw material supply member 110 .

Although not shown in the drawings, a support jaw on which the lowermost filter part 134 of the filter member 130 is supported may be provided on the inner circumferential surface of the supply pipe 120 .

As shown in FIGS. 1, 3 and 4 , the filter member 130 is detachably located at the lower portion of the raw material supply member 110 to attach the fine metal powder contained in the powder raw material.

That is, the filter member 130 passes the powder raw material through the filtering holes 134b of the filter parts 134 in a state where the electromagnetic force is provided to the mutually stacked filter parts 134 by the electromagnetic force generating member 140 . When this is done, the metal powder contained in the powder raw material is attached to the filter unit 134 , thereby making it possible to filter the metal powder of the iron component from the powder raw material.

In this case, the filter member 130 includes a shaft portion 132 , a filter portion 134 , and a fastening portion 136 .

The shaft portion 132 is installed upright, and includes a locking protrusion 132a, an extension shaft 132b, a spiral 132c and a coupling protrusion 132d in detail.

The locking protrusion 132a is formed in an inverted cone shape, and the filter unit 134 is seated on the edge chin.

The extension shaft 132b extends upright from the center of the locking protrusion 132a, and a spiral 132c is formed on the upper outer circumferential surface.

The spiral 132c is formed on the upper portion of the extension shaft 132b or on the extension shaft 132b so that the uppermost filter portion 134 can be spirally fastened by the fastening portion 136 in a state in which a plurality of filter portions 134 are coupled to the extension shaft 132b. formed throughout.

The coupling protrusion 132d is formed on the spiral 132c so that the rotating part 133 can be coupled thereto. At this time, the rotating part 133 serves to rotate the shaft part 132 in which the filter part 134 is installed, and a groove part having a corresponding shape is formed to be coupled to the coupling protrusion 132d at the lower part.

On the other hand, although not shown in the drawings, the spiral may be rotatably provided above the extension shaft. That is, the spiral is formed on the outer circumferential surface of the cylindrical rotary sphere inserted into the outer circumferential surface of the extension shaft, and the coupling protrusion is integrally formed on the upper portion so as to freely rotate on the upper portion of the extension shaft.

In this case, when the rotating part is rotated in one direction in a state in which the fastening part is fastened to the spiral, the spirally fastened fastening part is lowered and locked while pressing the upper part of the filter part, and when the rotating part is rotated in the other direction, the fastening part fastened to the spiral is lowered. It descends to the upper part and is spaced apart from the upper part of the filter part.

In this way, when the helix and the extension shaft are separated, the fastening part must be rotated to fasten the fastening part, but if the helix is provided to rotate freely on the extension shaft, if only the helix is rotated while supporting the fastening part, the fastening part is raised and lowered according to the rotating spiral direction. while it is easy to work

A plurality of filter units 134 are seated on the lower portion of the shaft unit 132 and receive electromagnetic force generated from the electromagnetic force generating member 140 while passing the separately supplied powder material to filter the metal powder in the powder material. provided

At this time, the filter unit 134 is provided with an annular coupling portion 134a in the center so as to be coupled to the shaft portion 132, and the coupling portion 134a is positioned in the center to connect the vertical bar and the transverse bar in a cross shape. A plurality of lattice-shaped filtering holes 134b are formed.

Furthermore, the filtering holes 134b are interconnected (communicated) in the height direction to form a passage through which the powder raw material can pass.

Therefore, the filter unit 134 can effectively filter the fine metal powder contained in the powder raw material by maximizing the contact area with the powder raw material.

In addition, the filter unit 134 receives the electromagnetic force provided from the electromagnetic force generating member 140 and filters the metal powder contained in the powder raw material as electromagnetic force.

The fastening part 136 is formed in a nut shape, and while being spirally fastened to the helix 132c of the shaft part 132 , the uppermost filter part 134 among the filter parts 134 seated in the lower part of the shaft part 132 is fixed. make it

The electromagnetic force generating member 140 is disposed opposite to the supply pipe 120 as shown in FIG. 1 to generate electromagnetic force in the supply pipe. That is, the electromagnetic force generating member 140 is configured to generate electromagnetic force using an electromagnetic coil and includes a plurality of coils 142 (solenoid coils) wound around the supply pipe 120 .

Since the electromagnetic force generating member 140 is made as a known electromagnet that generates a predetermined Gaussian magnetic field by applying the power of the power supply unit 150 to the coil 142 , a detailed description thereof will be omitted.

Furthermore, the electromagnetic force generating member 140 is connected by a first elastic part 144 between the upper surface and the upper support part 122, and is connected by a second elastic part 146 between the lower surface and the lower support part 124, , is fixed to the upper and lower supports (122, 124) by the first and second elastic parts (144, 146).

The power supply unit 150 is connected to the coil 142 of the electromagnetic force generating member 140 as shown in FIG. 2 , and supplies power to the electromagnetic force generating member 140 for magnetization.

Moreover, the power supply unit 150 has a demagnetization control unit 152 that controls to supply the power of the power supply unit 150 to the electromagnetic force generating member 140 with a polarity opposite to the polarity applied when the electromagnetic force is generated for the demagnetization of the filter member 130 . includes

That is, when the demagnetization control unit 152 stops the power supply of the power supply unit 150 to the electromagnetic force generating member 140 and becomes stabilized, power is supplied to the electromagnetic force generating member 140 in the opposite polarity to the polarity applied when the electromagnetic force is generated for demagnetization. control to supply

Furthermore, a magnetic sensor (not shown in the drawing) may be provided in the middle of the filter member 130 , and in this case, the magnetic force applied to the filter member 130 is sensed to control the operation of the power supply unit 150 based on the detection signal. It is configurable including a control unit (not shown in the drawing) for controlling.

At this time, the demagnetization control unit 152 supplies the power of the power supply unit 150 to the electromagnetic force generating member 140 with 40 to 60% (preferably 50%) of the power when the filter member 130 is magnetized during demagnetization. will take control

The vibration generating member 160 generates vibration in the filter member 130 as shown in FIG. 1 , and the electromagnetic force provided from the electromagnetic force generating member 140 to the filter unit 134 is demagnetized by the demagnetization control unit 152 . In this state, by providing a vibration force to the filter member 130 , the metal powder attached to the filter unit 134 may be dropped and discharged to the outside of the supply pipe 120 .

In addition, the vibration generating member 160 provides a vibration force to the filter member 130 in a state in which electromagnetic force is provided from the electromagnetic force generating member 140 to the filter unit 134 , so that the powder raw material moves through the filter unit 134 . to allow it to pass smoothly.

The vibration generating member 160 is configured to include an eccentric part having an eccentric center of gravity and a driving motor rotating the eccentric part, and the driving motor rotates the eccentric part to cause vibration by rotating the eccentric part. .

As described above, in the separator 100 having a demagnetization function according to the present invention, the filter unit 134 is filtered while the coil 142 of the electromagnetic force generating member 140 is magnetized by the power supplied from the power supply unit 150 . The metal powder contained in the powder raw material passed through the holes 134b is attached to the filter unit 134, thereby filtering the metal powder of the iron component from the powder raw material.

After that, when the metal powder attached to the filtering holes 134b is removed from the filter unit 134 , the magnetization is maintained even when the power of the power supply unit 150 is stopped. As the polarity of the electric power supplied to the coil 142 of the electromagnetic force generating member 140 is reversed by this, the filter member 130 is demagnetized.

In this way, the demagnetization control unit 152 controls the demagnetization control unit 152 so that the power polarity of the power supply unit 150 supplied to the coil 142 to the electromagnetic force generating member 140 is reversed, so that demagnetization is easily possible.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, those of ordinary skill in the art to which the present invention pertains can realize that the present invention can be embodied in other specific forms without changing the technical spirit or essential features. you will be able to understand Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

100: a separator with a demagnetizing function
110: raw material supply member
112: extension
120: supply pipe
122, 124: upper and lower support parts
130: filter member
132: shaft
134: filter unit
136: fastening part
140: electromagnetic force generating member
142: coil
150: power supply
160: vibration generating member

Claims (3)

a raw material supply member having an end connected to a supply pipe to supply a powder raw material;
an electromagnetic force generating member disposed in the supply pipe to generate an electromagnetic force in the supply pipe;
a filter member positioned at an end of the raw material supply member to attach the fine metal powder contained in the powder raw material;
a power supply unit for supplying power to the electromagnetic force generating member for magnetization; and
and a demagnetization control unit for controlling the power supply of the power supply unit to the electromagnetic force generating member with a polarity opposite to the polarity applied when the electromagnetic force is generated for the demagnetization of the filter member.
According to claim 1,
and the demagnetization control unit controls to supply 40 to 60% of the power of the power supply unit during magnetization to the electromagnetic force generating member during demagnetization.
According to claim 1,
and the demagnetization control unit stops supplying power to the electromagnetic force generating member and supplies power to the power supply unit for demagnetization when stabilization is achieved.

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