KR100990506B1 - Magnetic filter device - Google Patents

Abstract

Magnetic filter device according to an exemplary embodiment of the present invention, for filtering the fine metal powder contained in the powder raw material as an electromagnetic force, i) a frame, and ii) an electromagnetic force located around the frame to generate an electromagnetic force inside the frame A generating unit, and iii) a filter unit positioned inside the frame and attaching metal powder in the powder raw material through the electromagnetic force generated by the electromagnetic force generating unit, wherein the filter unit includes a plurality of mesh plates stacked on each other. The mesh plates have a plurality of filter holes interconnected along the height direction, and a plurality of unit filters continuously forming the filter holes along the length direction are connected inclined downward in the width direction.

Powder raw material, metal powder, filtering, matrix, mesh plate, unit filter

Description

Magnetic filter device {MAGNETIC FILTER DEVICE}

An exemplary embodiment of the present invention relates to a magnetic filter device for filtering metal powder contained in a powder raw material as an electromagnetic force, and more particularly, to a magnetic filter device having an improved matrix in a mesh form.

In general, a magnetic filter is conventionally used to remove raw iron from powdered raw materials such as fluid raw materials or powder raw materials, such as silica sand, mica crushed stone, porcelain stone powder, refractory materials, and secondary battery raw materials. Has been used.

The magnetic filter is a method using a magnet, in particular, for filtering the metal powder of the iron component contained in the powder raw material, it can be broadly classified into a permanent magnet method and an electromagnet method.

The magnetic filter of the electromagnet type is provided with an electromagnetic force generator for generating an electromagnetic force, and a filter body for applying the electromagnetic force generated by the electromagnetic force generator to attach and filter the metal powder of the iron component contained in the powder raw material.

Here, the filter body is referred to in the art as a matrix (matrix), it is composed of a plurality of plate members are stacked, the plate member is made of a mesh form that can pass the powder raw material.

In the prior art, the plate member has a plurality of unit holes through which the powder raw material can pass, and the unit holes have a rhombus shape by partition walls connected on a lattice.

Therefore, in the prior art, when the electromagnetic force is generated from the electromagnetic force generator and the electromagnetic force is supplied to the laminated plate members, the powder raw material is passed through the unit holes of the plate members. By being attached to the plate member it is possible to filter the metal powder of the iron component from the powder raw material.

By the way, in the prior art, in the plate member of the filter main body, a rhombus-shaped unit hole is formed through the partition wall connected to the lattice, and the contact portion of the powder raw material passing through the unit hole is limited to four partition walls, The raw material passes through the unit hole with the metal powder as it is, and has a problem that the filtering efficiency for the metal powder is relatively lowered.

That is, in the prior art, since the contact area of the powder raw material to the plate member is set as four partition walls, the filtering of the metal powder is not performed smoothly, and as a result, the metal powder of the iron component contained in the powder raw material is completely filtered. This results in a decrease in the reliability of products made from powdered raw materials.

Exemplary embodiments of the present invention have been created to improve the problems as described above, the magnetic filter device to maximize the contact area to the powder raw material to effectively filter the metal powder of the iron component contained in the powder raw material To provide.

Magnetic filter device according to an exemplary embodiment of the present invention as described above, for filtering the fine metal powder contained in the powder raw material as an electromagnetic force, i) a frame, ii) located around the frame and inside the frame Electromagnetic force generating unit for generating an electromagnetic force and ⅲ) is located inside the frame and comprises a filter unit for attaching the metal powder in the powder raw material through the electromagnetic force generated in the electromagnetic force generating unit, the filter unit is a plurality of mesh laminated Including the plates, the mesh plate has a plurality of filter holes are interconnected along the height direction, the plurality of unit filters that are continuously forming the filter holes along the longitudinal direction are connected inclined downward in the width direction.

In the magnetic filter device, each filter hole may be formed in a honeycomb form.

In the magnetic filter device, each filter hole may be formed by a pair of first portions parallel to the longitudinal direction of each unit filter and a pair of second portions respectively connected symmetrically to both ends of the first portion. have.

In the magnetic filter device, the unit filters may be integrally connected to the first portion adjacent to each other.

In the magnetic filter device, the filter unit may form a passage through which the powder raw material can pass while the mesh plates are stacked on each other and the respective filter holes are interconnected along the height direction.

In the magnetic filter device, each mesh plate may be formed such that a plurality of unit filters are integrally connected by pressing.

The magnetic filter device may further include a vibration source configured to be connected to the filter unit to provide a vibration force to the filter unit.

In the magnetic filter device, the filter unit includes a case accommodating a plurality of plate members, and the case may be configured to be connected to a hopper unit for supplying powder raw material to the filter unit.

According to the exemplary embodiment of the present invention as described above, it is possible to improve the mesh structure of the mesh plate to relatively maximize the contact area of the powder raw material passing through the filter holes unlike the prior art.

Therefore, in this embodiment, the filtering efficiency of the metal powder contained in the powder raw material can be increased, and as a result, the quality and reliability of the product made as the powder raw material can be further improved.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

1 is a block diagram schematically illustrating a magnetic filter device according to an exemplary embodiment of the present invention.

Referring to the drawings, the magnetic filter device 100 according to an exemplary embodiment of the present invention before packing the powder raw material (1) of filtering objects, such as silica sand, mica abrasive stone, porcelain stone powder, refractory, secondary battery raw material, etc. It is for removing the fine metal powder of the iron component contained in the powder raw material 1 as an electromagnetic force.

In the present embodiment, the above-described powder raw material 1 is used as the filtering object, but the present invention is not limited thereto, and the filtering object may be a raw material in a fluid state.

The apparatus 100 is divided into various components described below, which may be installed in one pedestal 10, or may be combined with each of the divided pedestals 10. FIG. .

The pedestal 10 is configured to support the apparatus 100 with respect to the ground, and is equipped with a sensor, a power plant, an electronic control system, and the like for driving the apparatus 100.

The components of the apparatus 100 described below are all installed on the pedestal 10, and various brackets, blocks, bars, plates, covers, and collars are used to mount the respective components to the pedestal 10. As the accessory elements, in the present embodiment, these accessory elements are referred to collectively as pedestal 10, except in exceptional cases.

The magnetic filter device 100 according to the exemplary embodiment of the present invention basically includes a frame 20, an electromagnetic force generating unit 40, and a filter unit 70. same.

The frame 20 is installed on the upper surface of the pedestal 10. The frame 20 may have a columnar shape in which an upper passage is opened and an inner passage connecting the upper portion and the lower portion is formed, and may be a cylinder.

In this embodiment, the electromagnetic force generating unit 40 is for generating an electromagnetic force by using an electromagnetic coil. The electromagnetic force generating unit 40 is located around the frame 20 and includes a plurality of coils 43 (commonly known as "solenoid coils" in the art) wound around the frame 20.

Since the electromagnetic force generating unit 40 is made of an electromagnet of a known technique for generating a magnetic field of a predetermined Gauss by applying power to the coil 43, its detailed description will be omitted herein.

In the present embodiment, the filter unit 70 receives the electromagnetic force generated from the electromagnetic force generating unit 40 while passing the powder raw material 1 separately supplied to filter the metal powder in the powder raw material 1.

In the art, such a filter unit 70 is also commonly referred to as a "matrix".

In the present embodiment, unlike the prior art, the filter unit 70 has a structure capable of effectively filtering the fine metal powder contained in the powder raw material 1 by maximizing the contact area with respect to the powder raw material 1.

The filter unit 70 is configured in the inner passage of the frame 20, and preferably includes a fixed plate 71 and a plurality of mesh plates 80 stacked on the fixed plate 71.

The upper end of the filter unit 70 is provided with a hopper unit 60 for supplying the powder raw material 1 to the filter unit 70. The lower portion of the hopper unit 60 may be inserted into the internal space of the frame 20 to supply the powder raw material 1 to the internal space of the frame 20 without flowing around.

In addition, when the lower portion of the hopper unit 60 is inserted into the internal space of the frame 20, the lower portion of the hopper unit 60 presses the upper portion of the mesh plates 80, the mesh plates 80 are frame ( It is possible to prevent the departure to the outside of 20).

The mesh plates 80 receive the electromagnetic force provided from the electromagnetic force generating unit 40 to attach and filter the metal powder contained in the powder raw material 1 as the electromagnetic force.

In the process of generating electromagnetic force from the electromagnetic force generating unit 40, the powder raw material 1 from which the metal powder is removed through the plurality of mesh plates 80 is discharged through the open lower portion of the frame 20.

In addition, with the electromagnetic force applied to the mesh plates 80 removed, metal powder falling from the mesh plates 80 is also discharged through the open lower portion of the frame 20.

In this embodiment, each mesh plate 80 passes through the powder raw material 1 supplied to the internal space of the frame 20 through the hopper unit 60 and at the same time, the electromagnetic force generated from the electromagnetic force generating unit 40. The metal powder in the powder raw material 1 is attached, and the remaining pure powder raw material 1 is formed as a mesh that can pass through as it is.

Specifically, each mesh plate 80 forms a plurality of filter holes 82 formed in a honeycomb form, as shown in FIGS.

The mesh plate 80 includes a plurality of unit filters 81 in which the filter holes 82 are continuously formed along the length direction, and the unit filters 81 are inclined downward in the width direction (diagonal lines). Direction) is made as a structure connected to each other.

Accordingly, as the mesh plates 80 are stacked in the inner space of the frame 20 as mentioned, the powder raw material 1 is formed while the filter holes 82 are interconnected (communicated) in the height direction as shown in FIG. 5. Will form a passage (83) through which.

In the present embodiment, since the plurality of unit filters 81 are inclined downward in a width direction of the mesh plate 80 (a diagonal direction), the mesh plates 80 are stacked on each other. The filter holes 82 are formed to be inclined along the diagonal direction with respect to the height direction of the mesh plates 80 while being interconnected in the stacking direction.

In this case, the filter hole 82 of each mesh plate 80 is mutually symmetrical with a pair of 1st part 85a parallel to the longitudinal direction of each unit filter 81, and the both ends of the 1st part 85a. It can be partitioned by the second part 85b to which it is connected.

Here, each mesh plate 80 is formed by a plurality of unit filters 81 are integrally connected as a press process, the first portion 85a of the unit filters 81 adjacent to each other integrally connected to the mesh Take form.

On the other hand, the magnetic filter device 100 according to the present embodiment further includes a vibration source 90 for providing a vibration force to the frame 20. In this case, the frame 20 includes horizontal plates 21 and 22 at upper and lower portions thereof, respectively, so that the frame 20 can be vibrated in the vertical direction through the vibration force provided from the vibration source 90, and the horizontal plates 21 and 22. The silver may be fixed to the electromagnetic force generating unit 40 through the elastic member (23).

The vibration source 90 is a metal attached to the mesh plates 80 by providing a vibration force to the filter unit 70 in a state in which the electromagnetic force provided to the mesh plates 80 from the electromagnetic force generating unit 40 is removed. The powder may be dropped and discharged to the outside of the frame 20. In addition, the vibration source 90 provides a vibration force to the filter unit 70 in a state in which electromagnetic force is provided from the electromagnetic force generating unit 40 to the mesh plates 80, so that the powder raw material 1 may be mesh plates ( 80) to pass more smoothly.

The vibration source 90 includes a deflection member in which the center of gravity is deflected, and a drive motor for rotating the deflection member, and the drive motor is constituted as a vibrating means of a known technique for causing vibration by rotating the deflection member.

In addition, the magnetic filter device 100 according to the present embodiment further includes a cooling unit 50 for cooling the electromagnetic force generating unit 40. The cooling unit 50 includes a cooling tube 51 for absorbing heat generated by the electromagnetic force generating unit 40 through the flow of the refrigerant, a refrigerant pump 52 for moving the refrigerant in the cooling tube 51, and electromagnetic force generation. And a heat exchanger 53 for discharging the heat absorbed by the unit 40 to the outside of the magnetic filter device 100.

Since the cooling unit 50 is a known technique for controlling the temperature of the electromagnetic force generating unit 40 by heat transfer through the refrigerant, its detailed description will be omitted.

Therefore, according to the magnetic filter device 100 according to an exemplary embodiment of the present invention configured as described above, when the current is first applied to the coil 43 of the electromagnetic force generating unit 40, the internal space of the frame 20 Magnetic field (electromagnetic force) is generated in the.

Here, the electromagnetic force generated from the electromagnetic force generating unit 40 is provided to the mesh plates 80 of the filter unit 70.

In this state, the powder raw material 1 is injected into the internal space of the frame 20 through the hopper unit 60.

Then, the powder raw material 1 passes through the passage 83 of the mutually laminated mesh plates 80, and the metal powder contained in the powder raw material 1 adheres to the mesh plates 80 by electromagnetic force. The remaining pure powder raw material 1 passes through the passage 83 as it is.

At this time, the pure powder raw material 1 is discharged to the outside through the open lower portion of the frame 20 is collected in a separate collecting container (not shown).

After such a process, when the current applied to the coil 43 of the electromagnetic force generating unit 40 is blocked, the electromagnetic force provided to the mesh plates 80 of the filter unit 70 is removed.

At the same time, when the vibration source 90 is driven, the vibration force is provided to the filter unit 70 by the vibration source 90, so that the metal powder attached to the mesh plates 80 falls by its own weight. And, it is discharged to the outside through the open bottom of the frame 20 is collected in a separate collecting container (not shown).

Accordingly, in the magnetic filter device 100 according to the exemplary embodiment of the present invention, a plurality of unit filters 81 in which the filter holes 82 of the filter unit 70 are continuously formed along the length direction are disposed in the width direction. As the mesh plate 80 is connected to be inclined downward, the passage 93 of the filter holes 82 inclined in the diagonal direction along the stacking height is formed while the mesh plates 80 are stacked. The contact area of the powder raw material 1 passing through the passage 83 can be maximized.

Therefore, in the present embodiment, the contact area of the powder raw material 1 with respect to the mesh plates 80 may be maximized to more effectively filter the fine metal powder contained in the powder raw material 1.

As an alternative, the exemplary embodiment of the present invention has been described as a structure in which the filter holes 82 of the mesh plates 80 are connected to each other in a diagonal direction along the height direction, but are not necessarily limited thereto. As described above, the filter holes 82 may have a structure in which mesh plates 80 are alternately stacked.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. Naturally, it belongs to the scope of the invention.

Since these drawings are for reference in describing exemplary embodiments of the present invention, the technical idea of the present invention should not be construed as being limited to the accompanying drawings.

1 is a block diagram schematically illustrating a magnetic filter device according to an exemplary embodiment of the present invention.

2 is a perspective view illustrating a mesh plate of a filter unit applied to a magnetic filter device according to an exemplary embodiment of the present invention.

3 is a plan view of FIG. 2.

4 is a cross-sectional view taken along the line A-A of FIG.

5 and 6 are cross-sectional view showing a laminated state of the mesh plate of the filter unit applied to the magnetic filter device according to an exemplary embodiment of the present invention.

≪ Description of reference numerals &

1: powder raw material 10: pedestal

20: frame 21, 22: horizontal plate

23: elastic member 40: electromagnetic force generating unit

43: coil 50: cooling unit

51: cooling tube 52: refrigerant pump

53: heat exchanger 60: hopper unit

70: filter unit 71: fixed plate

80: mesh plate 81: unit filter

82: filter hole 83: passage

85a: first part 85b: second part

90: vibration source 100: magnetic filter device

Claims (8)

In the magnetic filter device for filtering the fine metal powder contained in the powder raw material as an electromagnetic force, frame, An electromagnetic force generating unit positioned around the frame and generating an electromagnetic force inside the frame; Located inside the frame and comprises a filter unit for attaching the metal powder in the powder raw material through the electromagnetic force generated in the electromagnetic force generating unit, The filter unit includes a plurality of mesh plates stacked on each other, wherein the mesh plates have a plurality of filter holes interconnected along a height direction, and a plurality of units continuously forming the filter holes along a length direction. Magnetic filter device characterized in that the filter is connected inclined downward in the width direction. According to claim 1, The magnetic filter device, characterized in that each filter hole is formed in a honeycomb form. The method of claim 2, Each filter hole, And a pair of first portions parallel to the longitudinal direction of each unit filter, and a pair of second portions respectively connected symmetrically to both ends of the first portion. The method of claim 3, And the unit filters are integrally connected to the first portion adjacent to each other. According to claim 1, The filter unit, And the mesh plates are stacked on each other, and the filter holes are interconnected along a height direction to form a passage through which the powder raw material can pass. The method of claim 2, The mesh plate is a magnetic filter device characterized in that the plurality of unit filters are formed integrally connected by pressing. According to claim 1, The magnetic filter device is configured to be connected to the filter unit further comprises a vibration source for providing a vibration force to the filter unit. According to claim 1, The filter unit includes a case for receiving the plurality of plate members, The case is a magnetic filter device, characterized in that the hopper unit for supplying the powder raw material to the filter unit is configured to be connected.

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