KR100715232B1 - Static electricity preventing sheet - Google Patents

Abstract

The present invention relates to an antistatic sheet capable of reducing the generation of static electricity.

The antistatic sheet according to the present invention is formed of a resin material, but is formed to have a length to improve the conductivity and includes a metal fiber having a diameter of 50μm or less, the antistatic sheet of the antistatic sheet is improved while Color has the effect of being able to configure a variety of.

Description

Antistatic Sheets {STATIC ELECTRICITY PREVENTING SHEET}

1 is a cross-sectional view schematically showing a cross section of the antistatic sheet according to the present invention.

2 is a view showing an example of use of the antistatic sheet according to the present invention.

3 is an enlarged view of a metal fiber applied to the antistatic sheet according to the present invention.

Explanation of symbols on the main parts of the drawings

10: antistatic sheet 11: conductive layer

12: upper layer sheet 13: lower layer sheet

14: Ground Pin 15: Ground Wire

The present invention relates to an antistatic sheet capable of reducing static electricity, and more particularly, to an antistatic sheet that can be easily formed in various colors.

In general, the antistatic sheet is a material applied to a workbench or floor of a factory that makes static-sensitive electronic products such as semiconductors, and is formed of a material having excellent conductivity, and when a ground wire is connected to it, the charge is transferred to the antistatic sheet. It can be easily balanced by flowing through the connected ground wire to prevent the charging phenomenon and the generation of static electricity in advance.

Therefore, when considering only conductivity, it is preferable to form such an antistatic sheet with a metal plate, but since the metal plate is a material that is easily deformed, it is difficult to recover the original shape once the shape is changed. Difficult to apply to the site having a very low versatility.

Therefore, in recent years, a conductive layer is formed between the upper layer sheet and the lower layer sheet formed of a flexible resin material through a metal powder to secure an appropriate level of flexibility while having an antistatic ability.

Such an antistatic sheet has excellent antistatic performance as the RTT resistance value representing the resistance value between any two points on the sheet surface and the RTG resistance value representing the resistance value between any one point on the sheet surface and ground are closer to 10 ⁶ Ω, respectively. Performance.

However, in the case of the antistatic sheet having the upper sheet and the lower sheet formed of a flexible resin material, it is difficult to lower the RTT resistance value and the RTG resistance value of the upper sheet and the lower sheet to 10 ⁷ Ω or less due to the characteristics of the resin material. It acts as a factor to reduce the antistatic performance.

Therefore, in order to lower the RTT resistance value and the RTG resistance value to 10 ⁷ Ω or less, the upper sheet and the lower sheet may be mixed with carbon to form the upper sheet and the lower sheet, but the carbon may have a black color. When the carbon is mixed in the upper sheet and the lower sheet, the color of the antistatic sheet becomes black so that the antistatic sheet cannot meet various user's color requirements.

The present invention is to solve such a problem, it is an object of the present invention to provide an antistatic sheet that can be easily formed in various colors while improving the antistatic performance.

The antistatic sheet according to the present invention for achieving the above object is formed of a resin material, including a conductive layer formed of a conductive material so that current can easily flow, the conductive layer is formed to have a length and 50μm long It is characterized by being formed of a metal fiber having the following diameter.

In addition, the metal fiber is characterized in that it has a length between 100μm to 300μm.

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In addition, an upper layer sheet including the metal fiber is disposed on the upper side of the conductive layer to cover and protect the upper side of the conductive layer.

In addition, the lower side of the conductive layer is disposed on the lower side of the conductive layer is formed of foamed PVC so as to exert an elastic force, characterized in that the lower layer sheet including the metal fiber is disposed.

The method may further include a ground pin installed to penetrate the conductive layer, the upper layer sheet, and the lower layer sheet, and a ground line connecting the ground pin and an external ground.

Hereinafter, one preferred embodiment of the present invention will be described in detail with reference to the drawings.

1 schematically shows a configuration of an antistatic sheet according to the present invention.

The antistatic sheet 10 according to the present invention includes a conductive layer 11 formed of a conductive material, an upper layer sheet 12 covering and protecting the upper side of the conductive layer 11 to prevent generation of static electricity, and the conductive layer. And a lower layer sheet 13 covering and protecting the lower side of the bottom portion 11, and the conductive layer 11 and the upper layer of the antistatic sheet 10 in order to allow the antistatic sheet 10 to be grounded with an external ground. A ground pin 14 installed through both the sheet 12 and the lower sheet 13 and a ground wire 15 connecting the ground pin 14 and an external ground are provided.

When the upper layer sheet 12 and the lower layer sheet 13 of the antistatic sheet 10 are each formed of a flexible resin material and stored in a rolled manner as shown in FIG. It can be loosened and attached to a workbench or floor. In addition, the lower layer sheet 13 is formed of foamed PVC having a predetermined elastic force, so that the impact can be absorbed through the antistatic sheet 10 to improve the working environment to reduce the fatigue of the operator. .

In addition, the conductive layer 11 of the antistatic sheet 10 has a metal material having a silver or light gray color in order to minimize the influence on the color of the antistatic sheet 10 while having excellent conductivity. By using the antistatic sheet 10 can be easily configured in a variety of colors.

At this time, since the flexibility of the conductive layer 11 in the form of a metal plate has the disadvantage that the flexibility, the antistatic sheet 10 according to the present invention is excellent in conductivity and through the metal fiber exhibiting excellent properties in flexibility The conductive layer 11 is formed.

Metal fibers are used by being divided into metal wire having a diameter of 50 μm or more and metal fiber having a diameter of 50 μm or less and having a short length. Of these, in order to form the conductive layer 11 with metal wires to prevent the charging effect, the metal wires must be woven to have a string and a blade to form a mesh shape. As such, the metal wires form a mesh shape. The work is very difficult, and when the conductive layer 11 is formed by arranging the metal wires in a mesh form, the rigidity of the conductive layer 11 is increased due to the shape, so that the flexibility of the antistatic sheet 10 is increased. Since there is a problem of deterioration, the metal wire is difficult to be applied to the antistatic sheet 10 as in the present invention.

In addition, a powder metal powder may be used as a material forming the conductive layer 11, but in the case of the metal powder, the conductive layer 11 is disposed at a higher density than the metal powder in order to allow the electric charge to flow smoothly. Since (11) is to be formed, a relatively large amount of metal powder must be used. In addition, metal ions inevitably remain in the conductive layer 11 during the melting and solidification of the metal powder. The antistatic sheet forms a conductive layer through the metal powder because metal ions should not be detected due to the regulation of the product. It's hard to do.

Therefore, the antistatic sheet 10 according to the present invention uses a metal fiber having a predetermined length as a material forming the conductive layer 11. Although the metal fibers are arranged at a relatively low density compared to the metal powder, as shown in FIG. 3, the particles of the metal fibers cross each other and allow electric charge to flow to neighboring metal fiber particles, so that the conductivity is almost similar to that formed by the metal plate. The amount of metal used to form the conductive layer 11 can be greatly reduced, and the length of the metal used for forming the conductive layer 11 is very short, and thus the flexibility of the antistatic sheet 10 is hardly affected.

In the present embodiment, the metal fiber is formed to have a length of about 100 μm to about 300 μm, which means that when the length of the metal fiber is 100 μm or less, the metal fiber shows a property close to the metal powder, and thus the metal fiber has a length of 100 μm or less. In order for the conductive layer 11 to have a conductivity similar to that of the conductive layer 11 made of a metal fiber having a length of 100 μm or more, about 10 times of material must be consumed, resulting in waste of material and having a length of 300 μm or more. In this case, since the metal fiber has a property close to the metal wire, the metal fiber should be disposed in a mesh form in order to form the conductive layer 11 because it is very difficult to arrange the metal fiber in a mesh form.

In the present embodiment, the conductive layer 11 applied to the antistatic sheet 10 is made of a metal fiber made of stainless steel having excellent corrosion resistance. Thus, the conductive layer 11 is formed by manufacturing a metal fiber from stainless steel. In this case, the conductive layer 11 has a resistance value of 10 ³ Ω, and when the conductive layer 11 is formed alone, the conductive layer 11 has better antistatic performance than carbon having a resistance value of 10 ⁵ Ω. Performance.

In addition, in the antistatic sheet 10 according to the present invention, the metal fibers are mixed with the resin material forming the upper layer sheet 12 and the lower layer sheet 13 to promote conductivity of the upper layer sheet 12 and the lower layer sheet 13. It is supposed to be possible. Since the metal fiber is silver or light gray as mentioned above, the metal fiber has very little influence on the color of the upper sheet 12 and the lower sheet 13, so that the metal fiber can be replaced by the upper sheet 12 and the lower sheet ( 13, the upper layer sheet 12 and the lower layer sheet 13 are significantly reduced in resistance, thereby increasing conductivity while forming the upper layer sheet 12 and the lower layer sheet 13 in various colors.

As described in detail above, in the antistatic sheet according to the present invention, since the metal fiber of silver or light gray material is included to improve the conductivity of the antistatic sheet, the antistatic sheet of the antistatic sheet is further improved while the antistatic sheet is improved. There is an effect that can be easily configured in a variety of colors.

Claims (6)

It is formed of a resin material, including a conductive layer formed of a conductive material so that the current easily flows, the conductive layer is formed long to have a length and antistatic, characterized in that formed of a metal fiber having a diameter of 50μm or less Sheet. The method of claim 1, The metal fiber is antistatic sheet, characterized in that having a length between 100μm to 300μm. delete The method of claim 1, An antistatic sheet, wherein an upper layer sheet including the metal fiber is disposed on the upper side of the conductive layer to cover and protect the upper side of the conductive layer. The method of claim 4, wherein The antistatic sheet, wherein the lower side of the conductive layer is disposed on the lower side of the conductive layer and is formed of foamed PVC so as to exert an elastic force and a lower layer sheet including the metal fiber is disposed. The method of claim 5, An antistatic sheet further comprising a grounding pin installed to penetrate the conductive layer, the upper layer sheet, and the lower layer sheet, and a ground wire connecting the grounding pin and an external ground.

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