KR101921078B1 - Apparatus for filtering silica - Google Patents

Abstract

In the apparatus for separating a silica sand particle size uniform according to the present invention, a mesh for filtering silica sand; A mounting support attached along the periphery of the mesh; A reinforcing support portion that is partially disposed within the periphery of the mesh; And a mounting portion provided on the mounting support portion and on which the vibration generating device for generating vibration is mounted. Thereby providing a more rigid structure to support the sandpaper to which the mesh is applied.

Description

{APPARATUS FOR FILTERING SILICA}

The present invention relates to a silica sand particle size uniformity separating apparatus.

Silicon used in the manufacture of liquid crystal displays (LCDs) shall meet the particle size specifications. For this purpose, a mesh was used to separate the silica sand of desired grain size by manual or mechanical vibration device.

However, there is a disadvantage in that it is difficult to maintain productivity and quality uniformity by separating the silica sand by hand. When the silica sand is separated by an automated method using a mechanical vibration device, the mesh may not be able to withstand the impact caused by the vibration when the vibration of high intensity is generated, and may be broken.

Further, even when an excessive amount of silica sand is put on the mesh, there is a problem that the silica sand can not be supported and can be damaged.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a sand-stratum grain uniformity separating apparatus which provides a reinforced structure to support the sanding yarn into which the mesh is introduced.

It is still another object of the present invention to provide a device for separating a silica sand particle size uniform that supports a mesh to withstand a shock caused by strong vibration.

According to the present invention, the above object is achieved by a sand-and-grain-size uniform separating apparatus comprising: a mesh for filtering sand; A mounting support attached along the periphery of the mesh; A reinforcing support portion that is partially disposed within the periphery of the mesh; And a mounting portion provided on the mounting support portion and on which the vibration generating device for generating vibration is mounted.

According to such an embodiment of the present invention, the mesh is provided with a reinforced structure to support the sand dune to be introduced. Further, the present invention provides a structure for supporting the mesh so as to withstand a shock caused by strong vibration.

And an input receiving unit provided on a top surface of the mesh at a position corresponding to the input area of the silica sand. Thus, by providing the reinforcing material at the position where the sandpaper is put, the mesh is prevented from being broken when a large amount of sandpaper is put in.

The mounting support portion, the reinforcing support portion, and the input receiving portion may be a polyethylene (PE) knitted fabric. Accordingly, the mesh is supported by using a poly-material superior in strength and stretchability to the mesh.

The mounting support, the reinforcing support, and the charging support may be attached to the mesh using a silicone adhesive. Accordingly, the stiffener and the mesh can be stretched together when the vibration is generated.

As described above, according to the present invention, it is possible to provide a silica sand uniformity separating apparatus that provides a reinforced structure for supporting silica sand fed with a mesh.

Further, according to the present invention, it is possible to provide a device for separating a silica sand particle size uniform that supports the mesh so as to withstand a shock caused by strong vibration.

1 is a top view of a device for separating silica sand uniformity according to an embodiment of the present invention.
2 is a cross-sectional view of a device for separating silica sand uniformity according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention.

1 is a top view of a device for separating silica sand uniformity according to an embodiment of the present invention. 1, the apparatus for separating silica sand particle size uniform 1 includes a mesh 10, a reinforcing support portion 11, a mounting support portion 12, a mounting portion 13, and a charge receiving portion 14 do. The silica sand particle size uniformity separator (1) is equipped with a vibration generating device for generating vibration through a mounting portion (13).

According to the above-described constitution, the silica sand uniformity separator (1) of the present invention supports the sand dune into which the mesh (10) is put and supports it so as to withstand the strong vibration by the vibration generator.

The mesh 10 filters the silica sand. The silica sand filtered through the mesh 10 is used for producing a liquid crystal display (LCD).

The mesh 10 is made of nylon, polypropylene, or the like. Particularly, nylon is suitable for being used as a material of the mesh 10 because it is light, strong against friction, and good in elasticity. In addition, nylon is superior in tensile strength to other fibers, and thus has a merit in that it is not broken off when it is made of the mesh 10. The material used for the mesh 10 is not limited to the embodiment of the present invention, and can be manufactured using various other materials having excellent elasticity and strength.

Silica sand mainly contains quartz grains and contains 90% or more of silicon dioxide (SiO2) and is used as a glass raw material. In order to use silica sand as a raw material for an LCD, it is required to satisfy specifications below a predetermined particle size. As an embodiment, the silica sand for LCD can be obtained by using the mesh 10 having a body size of 80 to 150 micrometers.

As described above, the mesh 10 filters the silica sand using a sieve of a size suitable for the size of the silica sand available for LCD production.

The mounting support 12 is attached along the periphery of the mesh 10. The mounting support 12 serves to protect and support the mesh 10 so that the mesh 10 is not broken when the mesh 10 is connected to the vibration generator.

The mounting support portion 12 is made of a polyethylene (PE) knitted fabric. The material used for the mounting support portion 12 is not limited to the embodiment of the present invention but may be provided with various materials having high strength.

The reinforcing support portion (11) is partially disposed within the periphery of the mesh (10). The reinforcement supporting portion 11 is disposed at a position where the resistance from the outside is highly received among the regions corresponding to the inside of the periphery of the mesh 10. [

For example, when a part of the structure of the vibration generator mounted on the apparatus 1 touches or comes close to a part of the area of the mesh 10, the mesh 10 may be damaged. In this case, it is possible to dispose the reinforcing supporting portion 11 at a position corresponding to the structure of the vibration generating device that can be contacted, thereby preventing the mesh 10 from being damaged.

In the illustrated embodiment, a plurality of reinforcing supports 11 are arranged in parallel with each other on the upper surface of the mesh 10 in a strip shape. At this time, the mesh 10 serves to separate the sandbags from the areas exposed between the reinforcing supports 11.

In the illustrated embodiment, the reinforcing supports 11 are arranged in the same width and spacing. The manner in which the reinforcing support portions 11 are disposed is not limited to the illustrated example, and may be arranged with different widths and intervals. Alternatively, as another example, they may be arranged in a lattice pattern or a concentric pattern.

According to the above-described structure, the reinforcement supporting part 11 plays the role of supporting the mesh 10 so as not to be slackened downward when silica sand is put on the mesh 10. In addition, when the mesh 10 is subjected to resistance by a vibration generating device or the like, the reinforcing supporting portion 11 serves to relieve such resistance and to support the mesh 10.

The reinforcement supporting portion 11 is provided as a knitted fabric made of polyethylene (PE) like the mounting support portion 12. [ Polyethylene (PE) is a material having high heat resistance and durability, and is suitable for use as a material for supporting the mesh 10. The material used for the reinforcement supporting portion 11 is not limited to the embodiment of the present invention, but may be made of another material having high strength suitable for supporting the mesh 10. [

The mounting portion 13 is provided in the mounting support portion 12, and a vibration generating device for generating vibration is mounted. The mounting portion 13 is a connecting means for connecting the present apparatus 10 directly to the vibration generating device and is provided with, for example, a fastening hole, a bolt, and a nut.

1, the mounting portion 13 is provided on a mounting support 12 attached along the periphery of the mesh 10, and a part of the structure of the vibration generating device can be caught or fixed In the form of a plurality of fastening holes. At this time, the fastening holes are made of a high-strength metal material or the like so as not to be broken or deformed when connected to the vibration generating device. The shape of the mounting portion 13 is not limited to the embodiment of the present invention, but may be provided in various types of fastening that can mount the vibration generating device to the present device 1. [

Further, the plurality of fastening holes are arranged at regular intervals along the direction in which the mounting support portions 12 are formed. The interval at which the fastening holes are disposed can be determined differently depending on the area of the mesh 10 and the strength of vibration of the connected vibration generating device.

The input receiving portion 14 is provided on the upper surface of the mesh 10 at a position corresponding to the input area of the silica sand. In this apparatus (1), silica sand is put on the upper side of the mesh (10) and silica sand below a predetermined particle size is discharged through the sieve of the mesh (10). At this time, an inlet for inputting silica sand is provided on the upper side of the mesh 10, and if a large amount of silica sand is input through the inlet, the mesh 10 can not handle a large amount of silica sand and is likely to be damaged.

In order to solve such a problem, an input receiving portion 14 is provided on the upper surface of the mesh 10 at a position corresponding to the input area of the silica sand so that the input silica sand is supported.

The input receiving unit 14 may be provided in a form corresponding to the input area of the sandpaper. Although it is employed in the illustrated embodiment in a rectangular shape, it may have various shapes such as a circular shape and a triangular shape as necessary. As another example, the charge receiving portion 14 may be provided so as to have a larger area than the input area of the sandpaper. That is, even when the sand dunes falling on the upper surface of the mesh 10 are scattered over a wider area than the input area, the sand dune can be supported.

Like the reinforcing support portion 11 and the mounting support portion 12, a polyethylene (PE) based knitted fabric is preferable as the material of the input receiving portion 14. [ However, a natural or synthetic rubber material or a composite material having excellent weather resistance can also be used. In some cases, a metal sheet or an engineering plastic material may be used singly or in combination.

The reinforcing supporting portion 11, the mounting supporting portion 12 and the charging receiving portion 14 are attached to the mesh 10 using a silicone adhesive.

Silicone is an organic compound containing silicon and has properties of excellent heat resistance, oxidation resistance, water resistance and electric insulation. In particular, when processing a fiber product, silicon penetrates into the fiber and then is strongly bonded to the fiber when heated, thereby exhibiting a permanent waterproof effect.

Therefore, by using the silicone adhesive, the mesh 10 and the reinforcing support portion 11 used as a reinforcing member, the mounting support portion 12, and the input receiving portion 14 are maintained for a long time.

Further, in the case of using silicone having a hardness of 10 or less, for example, the silicone adhesive can be stretched together with the mesh 10 so that the reinforcing material does not interfere with the fact that the mesh 10 is stretched in the vertical direction due to vibration have.

2 is a cross-sectional view of a device for separating silica sand uniformity according to an embodiment of the present invention. 2, the silica sand uniformity separation apparatus 1 according to the present invention has a structure in which a mounting support portion 12, a reinforcing support portion 11, and a charge receiving portion 14 are attached to the upper surface of a mesh 10 .

The mesh 10 has a sieve size of 80 to 150 micrometer size, and filters the silica sand that is fed from above. The silica sand filtered through the mesh 10 is used for an LCD. The mesh 10 is made of a material such as nylon or polypropylene.

The mounting support 12 is attached to the upper surface of the mesh 10 along the periphery of the mesh 10. When attaching the mounting support 12 to the mesh 10, a silicone adhesive is used. The mounting support portion 12 is made of a polyethylene (PE) material. The material used for the mounting support portion 12 is not limited to the embodiment of the present invention but may be provided with various materials having high strength.

The mounting support 12 serves to protect and support the mesh 10 so that the mesh 10 is not broken when the mesh 10 is connected to the vibration generator.

In the illustrated embodiment, the reinforcement supporting portions 11 are arranged in parallel with each other on the upper surface of the mesh 10 in a plurality of strips. Further, in the illustrated embodiment, the reinforcing supports 11 are arranged at the same width and spacing. The manner in which the reinforcing support portions 11 are disposed is not limited to the illustrated example, and may be arranged with different widths and intervals.

The reinforcing supporting portion 11 is made of a polyethylene (PE) material and attached to the mesh 10 using a silicone adhesive.

The input receiving portion 14 is provided on the upper surface of the mesh 10 at a position corresponding to the input area of the silica sand. The charge receiving portion 14 is made of a polyethylene (PE) -based material and is attached to the mesh 10 using a silicone adhesive.

In the illustrated embodiment, the charging receiving portion 14 is attached between the reinforcing supporting portions 11, and is provided with a greater thickness than the reinforcing supporting portion 11. [ The thickness of the charge receiving portion 14 is not limited to the example shown in the sectional view and may be the same as the thickness of the reinforcing supporting portion 11 or may be set to twice or more the thickness of the reinforcing supporting portion 11 to support the mesh 10 .

As described above, according to the present invention, it is possible to provide a reinforced structure for supporting the sandwiched sand fed with the mesh. Further, the mesh 10 is supported so as to withstand a shock caused by a strong vibration.

1: Silica particle size uniform separator
10: Mesh
11: reinforcing support
12: mounting support
13:
14:

Claims (4)

In the silica-particle size uniform separator,
A mesh for filtering sand;
A mounting support attached along the periphery of the mesh;
A reinforcing support portion that is partially disposed within the periphery of the mesh;
And a mounting portion provided on the mounting support portion and mounted with a vibration generating device for generating vibration,
The reinforcing support portion is disposed on the upper surface of the mesh in a strip shape and parallel to each other,
Further comprising a charging receiver provided at a position corresponding to a charging area of the sandpaper falling on the upper surface of the mesh,
Wherein the input receiving portion is attached to the upper surface of the mesh and has a greater thickness than the reinforcing supporting portion. delete The method according to claim 1,
Wherein the mounting support portion, the reinforcing support portion, and the charge receiving portion are knitted fabrics of polyethylene (PE). The method according to claim 1,
Wherein the mounting support portion, the reinforcing support portion, and the charge receiving portion are attached to the mesh using a silicone adhesive.

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