KR20240047556A - Sticker for preventing EMI of portable communication device and manufacturing method thereof - Google Patents

Abstract

The present invention uses a fabric to form a copper and nickel plating layer that absorbs and blocks electromagnetic waves to which charcoal powder, which has the effect of deodorizing, antibacterial, emitting negative ions and far infrared rays, is adhered, and uses an acrylic adhesive that is easily attached to a portable communication device. It relates to an electromagnetic wave blocking sticker for a portable communication device that can conveniently and completely block electromagnetic waves from a portable communication device by providing a surface, as well as emitting negative ions and far infrared rays that are good for health, and a method of manufacturing the same.

Description

Electromagnetic wave blocking sticker for portable communication device and manufacturing method thereof {Sticker for preventing EMI of portable communication device and manufacturing method thereof}

The present invention relates to a sticker that is attached to a portable communication device to block electromagnetic waves and a method of manufacturing the same. More specifically, it relates to an acrylic adhesive surface that contains charcoal powder as a material for blocking electromagnetic waves and is easily attached to a portable communication device. It relates to an electromagnetic wave blocking sticker for a portable communication device that can conveniently and more completely block electromagnetic waves from a portable communication device and a method of manufacturing the same.

It is generally known that EMI harmful electromagnetic waves generated from portable communication devices such as mobile phones and smartphones affect the human brain, causing brain tumors and various diseases, and causing serious problems in surrounding electronic devices. Currently, almost all electronic products that generate electromagnetic waves are labeled with harmful electromagnetic waves, and especially in the case of portable communication devices such as mobile phones and smartphones, the number of cases of damage is increasing.

Meanwhile, the above-mentioned EMI is an abbreviation for Electro Magnetic Interference and refers to electromagnetic waves directly radiated or conducted from electric or electronic devices that interfere with the electromagnetic reception function of other devices.

In order to prevent EMI, there has been conventional technology to block electromagnetic waves by adding a double case blocking layer inside the body of a portable communication device. In addition, a material application technology for blocking EMI is disclosed in the application filed under application number 10-2007-72822. However, there are limitations in blocking electromagnetic waves generated overall from portable communication devices, and external methods for additional blocking also have significant limitations in terms of the economic burden borne by the purchaser and the manufacturing aspect of the producer.

In line with the trend of slimming and miniaturizing the size of portable communication devices, inserting an electromagnetic wave blocking plate between the boards of a portable communication device is also not effective in blocking because it can increase the volume.

In addition, even if existing models of portable communication devices have devices to block harmful electromagnetic waves, the degree of blocking is limited by the high precision of the circuit and the diversity of auxiliary functions. As the average time of terminals in contact with the human body increases, the degree of exposure to electromagnetic waves for a long period of time increases. As the number of devices increases, there are insufficient devices that can effectively increase the effectiveness of blocking electromagnetic waves compared to existing blocking devices, and there are problems such as being extremely harmful to the human body and causing interference due to electromagnetic waves in various electronic devices.

In addition, most of the electromagnetic wave blocking materials used in existing portable communication devices are copper and nickel, and there is a problem that the efficiency of electromagnetic wave blocking by these blocking materials is not very high.

Meanwhile, electromagnetic wave blocking members applied to existing portable communication devices focus only on blocking electromagnetic waves, and do not pay attention to actively emitting negative ions and far infrared rays that are good for health and providing deodorizing and antibacterial effects. .

Prior Document 1 (Application No. 10-2007-72822)

The present invention was invented to solve the above problems, and the fabric for forming a copper and nickel plating layer that absorbs and blocks electromagnetic waves is a fabric to which charcoal powder, which has the effect of deodorizing and antibacterial, emitting anions and far infrared rays, is fixed. , an electromagnetic wave blocking sticker for portable communication devices that can conveniently and completely block electromagnetic waves from portable communication devices by providing an acrylic adhesive surface that is easily attached to portable communication devices, as well as emitting negative ions and far infrared rays that are good for health. The purpose is to provide a manufacturing method.

In order to achieve the above object, an electromagnetic wave blocking sticker for a portable communication device according to an embodiment of the present invention includes a fabric body to which charcoal powder is adhered; a copper plating layer and a nickel plating layer sequentially formed on both sides of the fabric; An acrylic member adhered to each of the nickel plating layers and coated with an adhesive to which paper is detachably attached to a surface not adhered to the nickel plating layer; and a silk printed (or silk screen printed) paper member detachably attached to each acrylic member, wherein the silk printed paper member is separated from the acrylic member and the acrylic member is attached to the portable communication device. It is characterized by being made to do so.

Preferably, the fabric to which the charcoal powder is fixed is a polyester fabric composed of weft and warp yarns, and the copper plating layer and the nickel plating layer are formed by electrolytic plating.

In order to achieve the above object, a method of manufacturing an electromagnetic wave blocking sticker for a portable communication device according to another embodiment of the present invention includes forming copper plating layers on both sides of a fabric body to which charcoal powder is adhered; forming a nickel plating layer on each copper plating layer; A step of adhering an acrylic member to each of the nickel plating layers, wherein an adhesive to which paper is detachably attached is applied to the other side of the acrylic member; and detachably attaching a silk-printed paper member to each acrylic member, wherein the silk-printed paper member is separated from the acrylic member and the adhesive-coated surface of the acrylic member is attached to the portable communication device for use. It is characterized by being

According to the present invention, the fabric for forming a copper and nickel plating layer that absorbs and blocks electromagnetic waves is made of a fabric to which charcoal powder, which has the effect of deodorizing, antibacterial, emitting negative ions and far infrared rays, is fixed, and is easily attached to a portable communication device. Equipped with an acrylic adhesive surface, it can conveniently and completely block electromagnetic waves from portable communication devices at a low cost, and can also help improve health by emitting negative ions and far infrared rays that are good for health.

1 is a cross-sectional configuration diagram of an electromagnetic wave blocking sticker for a portable communication device according to the present invention.
Figure 2 is a flow chart of a method for manufacturing an electromagnetic wave blocking sticker for a portable communication device according to the present invention.
Figure 3 is an explanatory diagram of attaching an electromagnetic wave blocking sticker according to the present invention to a portable communication device.
Figure 4 is a side view of the electromagnetic wave blocking sticker according to the present invention attached to a portable communication device.
Figure 5 is a rear view of the electromagnetic wave blocking sticker according to the present invention attached to a portable communication device.

Hereinafter, a preferred embodiment of the electromagnetic wave blocking sticker for a portable communication device and its manufacturing method according to the present invention will be described in detail with reference to the attached drawings.

Referring to Figure 1, the electromagnetic wave blocking sticker 1 of the portable communication device of the present invention includes a fabric body 10 to which charcoal powder is adhered; A copper plating layer 20 and a nickel plating layer 30 sequentially formed on both sides of the fabric body 10 to which the charcoal powder is adhered; An acrylic member 40 that is adhered to each nickel plating layer 30 and is coated with an adhesive that allows paper to be detachably adhered to the surface not adhered to the nickel plating layer 30; and a silk printing paper member detachably adhered to each acrylic member 40.

After the silk printing paper member 50 is separated from the acrylic member 40 as shown in FIG. 3, the sticker 1 of the present invention is attached to the acrylic member 40 by the adhesive applied to the acrylic member 40 as shown in FIGS. 4 and 5. As shown, it is used by being attached to a portable communication device 100.

In this way, when the sticker 1 of the present invention is attached to the portable communication device 100 and used, in addition to blocking electromagnetic waves by the copper plating layer 20 and the nickel plating layer 30, the fabric constituting the sticker 1 ( 10) The effectiveness of the charcoal powder fixed on the charcoal powder not only blocks additional absorption of electromagnetic waves, but also provides various benefits to the human body.

That is, looking at the efficacy of charcoal by the charcoal powder fixed to the fabric body 10 included in the sticker 1 of the present invention, it is as follows.

First, it emits far-infrared rays and acts deep inside the human body, warming the body, promoting blood circulation and relieving fatigue.

Helps expel blessings and waste. Second, by emitting negative ions, the negative ions of the charcoal adsorb and neutralize the surrounding positive ions that have rapidly increased due to various types of pollution, thereby facilitating the human body's metabolism. Third, by controlling moisture, it absorbs moisture when the surroundings are humid and radiates it when it is dry, thereby maintaining health by repeating the absorption and release of moisture while the charcoal is in contact with the human body. Fourth, it protects the human body from harmful electromagnetic waves by absorbing electromagnetic waves harmful to the human body emitted from portable communication devices. Fifth, it provides anti-corruption and deodorizing effects by adsorbing various harmful microorganisms and odors.

It is preferable that the fabric 10 to which the charcoal powder constituting the sticker 1 of the present invention as described above is adhered is a polyester fabric composed of weft and warp yarns. The particle size of the charcoal powder fixed to the fabric 10 is set to 70 ㎛ or less, and when printing with a dye containing charcoal powder having this particle size to make the fabric 10 in which the charcoal powder is uniformly fixed, It is preferable that the proportion of the charcoal powder included in the dye is 5% or less. In addition, when making the fabric 10, when considering the amount of ingredients excluding general dyes, that is, charcoal powder, binder, and crosslinking agent as 100, these ingredients are 35% charcoal powder, 645% binder, and 05% crosslinking agent. It is desirable to configure it as:

The copper plating layer 20 and the nickel plating layer 30 of the sticker 1 according to the present invention are formed by electrolytic plating, and each plating layer is preferably plated with an ultra-thin thickness of 1/1000 to 5/1000 mm. The purpose of plating the copper plating layer 20 and the nickel plating layer 30 with an ultra-thin film is to prevent each plating layer from easily being separated from the fabric body 10 when the fabric body 10 is wrinkled and to reduce the weight.

Referring to Figure 2, the electromagnetic wave blocking sticker 1 of the portable communication device of the present invention is formed by sequentially plating copper and nickel through electrolysis on both sides of the fabric 10 to which charcoal powder is adhered. (S10) (S20) In this process, the thickness of each plating layer (20) (30) is 1/1000 to 5/1000 mm.

In the present invention, it is preferable to form the nickel plating layer 30 on the copper plating layer 20, but in some cases, it is also possible to form only the copper plating layer 20. This is because copper is oxidized when exposed to air, and a nickel plating layer is formed to prevent this. That is, in the present invention, since the acrylic member 40 is formed on the copper plating layer 20, there is not much concern about the copper plating layer being exposed to the air even without the nickel plating layer.

As described above, the charcoal powder adhered to the fabric 10 has a particle size of 70 ㎛ or less, preferably 20 to 40 ㎛ or less, and the dye content is 5% or less.

As described above, once the plating layers 20 and 30 have been formed on the fabric 10 to which the charcoal powder is adhered, the acrylic member 40 is attached to the nickel plating layer 30 as shown in FIG. 1. (S30) Here, the other side of the acrylic member 40, that is, the side not adhered to the nickel plating layer 30, is applied with an adhesive that allows paper to be detachably adhered. The reason for adhering the acrylic member 40 to the nickel plating layer 30 is that the fabric body 10 on which the plating layer 20 and 30 are formed is a fabric like regular cloth and therefore has no hardness and therefore cannot serve as a sticker. am. The acrylic member 40 can serve as a sticker, and the thinner the thickness, the better, but it is preferably 05 mm or less.

It will be apparent to those skilled in the art that in the present invention, if the nickel plating layer 30 is not formed, the acrylic member 40 will be adhered on the copper plating layer 20.

When the acrylic member 40 is adhered to the nickel plating layer 30 as described above, the silk printing paper member 50 is detachably attached to the adhesive side of the acrylic member 40 as shown in FIG. 1 (S40). Since advertising or promotional text is printed on the outer surface of the silk printing paper member 50, it is called a silk printing paper member.

Therefore, it will be obvious to those skilled in the art that if advertising phrases or promotional phrases are not silk-printed on the paper member 50, it will be a paper member other than the silk-printed paper member.

The reason why advertising phrases or promotional phrases are silk-printed on the paper member 50 as described above is because the sticker of the present invention may be sold as a general product, but in many cases, it is highly likely to be sold as a free gift.

If the silk printing paper member 50 is detachably adhered to the acrylic member 40 as described above, the sticker is cut to suit the attachment surface of the portable communication device to which the sticker is attached (S50). The cutting process (S50) is completed. Then, the sticker 1 of the form shown in FIG. 3 is completed.

As shown in Figure 3, when the sticker 1 of the present invention is completed, the detachably adhered paper member 50 is removed from the acrylic member 40 of the sticker 1, and then as shown in Figures 4 and 5. As shown, it is used by attaching it to the back of the portable communication device 100.

Accordingly, the sticker of the present invention is attached to a portable communication device to not only absorb and block electromagnetic waves, but also emit negative ions and far infrared rays to protect and improve the health of users of the portable communication device.

The embodiments of the electromagnetic wave blocking sticker for a portable communication device of the present invention and the manufacturing method thereof described above are merely illustrative, and those skilled in the art will be able to make various modifications and equivalent alternatives therefrom. It will be apparent that the embodiment is possible. Therefore, it will be understood that the present invention is not limited to the forms mentioned in the above detailed description. Therefore, the true scope of technical protection of the present invention should be determined by the technical spirit of the attached patent claims. In addition, the present invention should be understood to include all modifications, equivalents and substitutes within the spirit and scope of the present invention as defined by the appended claims.

1: Electromagnetic wave blocking sticker
10: Fabric body to which charcoal powder is adhered
20: Copper plating layer
30: Nickel plating layer
40: Acrylic member
50: Silk printed paper

Claims (3)

A fabric body to which charcoal powder is adhered;
A copper plating layer and a nickel plating layer sequentially formed on both sides of the fabric to which the charcoal powder is adhered;
An acrylic member adhered to each nickel plating layer and coated with an adhesive to which paper is detachably attached to a surface not adhered to the nickel plating layer; and
a silk printed paper member detachably adhered to each acrylic member;
The fabric to which the charcoal powder is attached is a polyester fabric composed of weft and warp yarns,
The copper plating layer and the nickel plating layer are formed by electrolytic plating,
An electromagnetic wave blocking sticker for a portable communication device, characterized in that the silk-printed paper member is separated from the acrylic member and the acrylic member is attached to a portable communication device for use.
In the method of manufacturing an electromagnetic wave blocking sticker for a portable communication device,
Forming a copper plating layer on both sides of the fabric to which charcoal powder is adhered;
forming a nickel plating layer on each copper plating layer;
A step of adhering an acrylic member to each nickel plating layer, wherein an adhesive that allows paper to be detachably adhered is applied to the other side of the acrylic member; and
Comprising the step of detachably adhering a silk-printed paper member to each acrylic member,
A method of manufacturing an electromagnetic wave blocking sticker for a portable communication device, characterized in that the silk-printed paper member is separated from the acrylic member and the adhesive-coated surface of the acrylic member is attached to the portable communication device.
According to paragraph 2,
A method of manufacturing an electromagnetic wave blocking sticker for a portable communication device, comprising the step of cutting the sticker onto the attachment surface of the portable communication device to which the sticker is to be attached, after the step of detachably adhering the silk-printed paper member.