KR20140129747A - Manufacturing method and it has been manufactured using receiver antenna for wireless charger wireless charger for receiver antenna - Google Patents

Abstract

A method of manufacturing a receiving antenna for a wireless charger used for wirelessly charging a portable terminal, the method comprising: preparing an electromagnetic wave shielding sheet for shielding electromagnetic waves; Embedding an NFC (Near Field Communication) antenna used for a short distance communication method on an upper outer peripheral surface of the electromagnetic wave shielding sheet; Embedding a receiving coil for receiving electric power on the electromagnetic shielding sheet to apply electric power to the portable terminal; And wrapping an upper portion of the NFC (Near Field Communication) antenna and the electromagnetic wave shielding sheet, on which the receiving coil is embedded, with a protective sheet.
According to another aspect of the present invention, there is provided a receiving antenna for a wireless charger used for wirelessly charging a portable terminal, comprising: an electromagnetic wave shielding sheet for shielding electromagnetic waves; An NFC (Near Field Communication) antenna embedded in an upper outer peripheral surface of the electromagnetic wave shielding sheet and used in a near field communication system; And a receiving coil embedded in the upper portion of the electromagnetic shielding sheet and receiving power to apply power to the portable terminal.
Accordingly, since the NFC antenna and the receiving coil are directly embedded on the electromagnetic shielding sheet using the ultrasonic welding method, the working time can be shortened and the cost can be reduced compared with the conventional method using the adhesive In the case of NFC antennas, it is necessary to perform etching process, so that pollutants are generated in the etching process and cleaning process. However, since the NFC antenna is embedded directly on the top of the electromagnetic wave shielding sheet using the ultrasonic welding method, the cost is reduced And the generation of pollutants can be prevented.

Description

[0001] The present invention relates to an antenna manufacturing method for a wireless charger, and a receiver antenna for a wireless charger,

The present invention relates to a method for manufacturing a receiving antenna for a wireless charger and a receiving antenna for a wireless charger manufactured using the same. More particularly, the present invention relates to a method for manufacturing a receiving antenna for a wireless charger capable of simultaneously performing wireless recognition and wireless charging, To a receiving antenna for a wireless charger.

BACKGROUND ART [0002] Referring to the background art described in Korean Patent Registration No. 10-1177302, a radio frequency identification (RFID) technology generally includes an antenna and a reader using radio waves, (Non-contact) communication system, which enables information to be recognized at a short distance as well as at a long distance by utilizing a radio frequency.

Recently, near-field communication (hereinafter, referred to as "NFC") technology, which is one of the RFID technologies, has been newly applied and emerged as a next generation technology with the spread of smart phones. It can support bidirectional communication, which can be written, and can be used for mobile payment, file sharing, ticket reservation, and the like.

Especially, this NFC is widely used for payment information, travel information transmission for goods information and visitors in supermarkets and general shops, transportation and access control locking devices, and the application area of smart phones is greatly expanded.

As described above, portable terminals such as a smart phone equipped with a wireless recognition antenna for RFID and NFC are increasingly capable of generating and guiding electromagnetic waves because of high density circuits and integrated electronic devices, Therefore, the electromagnetic wave is shielded and absorbed by the radio frequency identification antenna for RFID or NFC of the portable terminal, thereby suppressing the interference of the electromagnetic wave. Therefore, the electromagnetic wave for increasing the radio recognition performance It is a tendency to use an absorber attached thereto.

On the other hand, with the introduction of smart phones and the like, a wireless charging technology has been tried to be applied in order to further enhance the convenience of users using the portable terminal.

Such a wireless charging technology is a technique of charging a battery built in a mobile terminal by utilizing a radio wave without connecting a charger for a mobile terminal to an electrical outlet. When a radio energy transceiver is installed in a home, an office or a hotel, And the battery is charged into the portable terminal with electrical energy. Thus, it is possible to charge the battery of the portable terminal wirelessly anytime and anywhere.

To this end, a wireless recharging antenna having a coil for receiving radio waves for wireless recharging must be installed in the portable terminal, and an electromagnetic wave absorber is attached thereto in order to enhance the performance of wireless recharging.

At this time, the electromagnetic wave absorber coupled to the wireless rechargeable antenna and the electromagnetic wave absorber bonded to the wireless readable antenna differ in frequency characteristics due to wireless charging and radio recognition, so that there is a difference in the material composition as well as in the material composition Electromagnetic wave absorbers based on ferromagnetic materials or sintered bodies having a high permeability are usually applied.

However, a recent series of technical researches and attempts to use both the wireless recognition function such as RFID and NFC and the wireless battery charging function in a portable terminal such as a smart phone, And it has not reached the practical stage.

Previously, a wireless recognition antenna for NFC and a coil for receiving radio waves for radio reception were bonded to the top of the electromagnetic wave absorber using an adhesive. However, in the case of the wireless recognition antenna for NFC, the production lead time is long due to the etching method, And the coil for receiving radio wave for radio recharging must be subjected to a separate winding process, resulting in a problem of rising cost.

As shown in FIG. 1, a wireless charger for wirelessly charging a portable terminal, such as a smart phone, includes a wireless charging pad 10 having a pad structure for mounting a portable terminal 1 with a battery therein, On the wireless charging pad 10, a magnet 20 is built in to hold and position the portable terminal.

As described above, the magnet 20 is built on the wireless charging pad 10 provided for charging the battery of the portable terminal 1 wirelessly, In the case of the portable terminal 1 having the charging antenna, the magnetic force generated by the magnet of the wireless charging pad 10 adversely affects the electromagnetic wave absorber provided on the portable terminal 1 side, So that the wireless charging efficiency is greatly reduced or the wireless charging function is not provided at all.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a mobile terminal capable of combining two functions of wireless identification (NFC) and wireless charging in one portable terminal, And an object of the present invention is to provide a method of manufacturing a receiving antenna for a wireless charger and a receiver antenna for a wireless charger manufactured by using the same, which can reduce cost by eliminating an etching process of an NFC antenna, a winding process of a receiving coil, and an adhering process .

According to an aspect of the present invention, there is provided a method of manufacturing a receiving antenna for a wireless charger, the method comprising: preparing an electromagnetic wave shielding sheet for shielding electromagnetic waves; Embedding an NFC (Near Field Communication) antenna used for a short distance communication method on an upper outer peripheral surface of the electromagnetic wave shielding sheet; Embedding a receiving coil for receiving electric power on the electromagnetic shielding sheet to apply electric power to the portable terminal; And wrapping an upper portion of the NFC (Near Field Communication) antenna and the electromagnetic wave shielding sheet, on which the receiving coil is embedded, with a protective sheet.

In the method of manufacturing a receiving antenna for a wireless charger according to the present invention, ultrasonic welding may be used for embedding the NFC (Near Field Communication) antenna and the receiving coil, and the receiving coil may include a plurality of self- And the self-fusible enamel copper wire may be made of a copper wire as a conductor, an insulating layer surrounding the copper wire, and a magnetic fusion layer surrounding the outer circumferential surface of the insulating layer. have.

The step of embedding the NFC (Near Field Communication) antenna on the electromagnetic shielding sheet and the step of embedding the receiving coil may be performed at the same time, and the synthetic resin material to be laminated on the electromagnetic shielding sheet And a sheet of paper.

According to another aspect of the present invention, there is provided a receiving antenna for a wireless charger used for wirelessly charging a portable terminal, comprising: an electromagnetic wave shielding sheet for shielding electromagnetic waves; An NFC (Near Field Communication) antenna embedded in an upper outer peripheral surface of the electromagnetic wave shielding sheet and used in a near field communication system; And a receiving coil embedded in the upper portion of the electromagnetic shielding sheet and receiving power to apply power to the portable terminal.

A receiving antenna for a wireless charger according to the present invention is characterized in that a protective sheet for covering the electromagnetic wave shielding sheet is provided on an upper portion of the electromagnetic wave shielding sheet on which the NFC (Near Field Communication) antenna and the receiving coil are embedded .

An adhesive layer may be provided between the protective sheet and the electromagnetic shielding sheet, and a Litz wire formed by twisting a plurality of self-adhesive enamel copper wires may be used as the receiving coil. The self- The electromagnetic wave shielding sheet may further include a sheet of synthetic resin material which may be composed of a copper wire as a conductor, an insulating layer surrounding the copper wire, and a magnetic fusing layer surrounding the outer circumferential surface of the insulating layer, can do.

A method of manufacturing a receiving antenna for a wireless charger according to the present invention and a receiving antenna for a wireless charger manufactured using the method have the following effects.

First, since the NFC antenna and the receiving coil are directly embedded on the electromagnetic shielding sheet using the ultrasonic welding method, the working time can be shortened and the cost can be reduced as compared with the conventional method using the adhesive .

Secondly, in case of NFC antenna, pollution occurred in etching process and cleaning process due to etching process. However, by embedding NFC antenna directly on top of electromagnetic wave shielding sheet by using ultrasonic welding method, cost is reduced , It is possible to prevent the generation of pollutants.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is an illustration of a wireless charger having a conventional wireless charging pad.
2 is a block diagram illustrating a procedure for manufacturing a receiver antenna for a wireless charger according to an embodiment of the present invention.
3 is an exploded perspective view illustrating a receiver antenna for a wireless charger according to an embodiment of the present invention.
Fig. 4 is a sectional view of the coupling state of Fig. 3; Fig.
5 is a view showing a state where an NFC antenna is embedded in an upper part of the electromagnetic wave shielding sheet shown in FIG.
6 is a view showing a state in which a receiving coil is embedded in an upper part of the electromagnetic wave shielding sheet shown in FIG.
Fig. 7 is a view showing magnetic flux-adhering enamel copper lines constituting a Litz wire used as a receiving coil. Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms and words used in the specification and claims should not be construed to be limited to ordinary or dictionary meanings, and the inventor should appropriately define the concept of the term to describe its invention in the best way possible It should be construed in the meaning and concept consistent with the technical idea of the present invention.

FIG. 2 is a block diagram showing a procedure for manufacturing a receiving antenna for a wireless charger according to an embodiment of the present invention. FIG. 3 is an exploded perspective view illustrating a receiving antenna for a wireless charger according to an embodiment of the present invention. FIG. 5 is a view showing a state in which an NFC antenna is embedded in an upper portion of the electromagnetic wave shielding sheet shown in FIG. 3, FIG. 6 is a cross-sectional view of the electromagnetic wave shielding sheet shown in FIG. Fig. 7 is a view showing a magnetic flux-adhering enamel copper line constituting a Litz wire used as a receiving coil. Fig.

Referring to FIG. 2, a method for manufacturing a receiving antenna for a wireless charger according to an embodiment of the present invention is a method for manufacturing a receiving antenna 100 for a wireless charger used to wirelessly charge a wireless terminal, A step S300 of embedding the reception coil 130 and a step S300 of embedding the NFC antenna 120 in the step of preparing the protective sheet 140, (S400).

The step (S100) of preparing the electromagnetic wave shielding sheet 110 is a step of preparing an electromagnetic wave shielding sheet 110 that absorbs and shields electromagnetic waves generated in the portable terminal. The electromagnetic wave shielding sheet 110 is made of a magnetic material and has a sheet shape by extruding a raw material containing a magnetic powder and a binder. The electromagnetic wave shielding sheet 110 may include a ferrite sheet have.

The electromagnetic wave shielding sheet 110 absorbs magnetic flux due to the inclusion of a ferrite sheet and collects the magnetic flux in the electromagnetic shielding sheet 110 and transmits it again so that the NFC antenna 120 and the receiving coil 130, Thereby further improving the performance of the apparatus.

A synthetic resin sheet 112 may be laminated on the electromagnetic shielding sheet 110. The NFC antenna 120 and the reception coil 130 can be embedded easily by joining the sheet 112 on the electromagnetic shielding sheet 110. [ The sheet 112 is preferably made of a synthetic resin material such as polyimide, polycarbonate, PET, or the like.

When the electromagnetic shielding sheet 110 is prepared, a step S200 of embedding an NFC (Near Field Communication) antenna 120 on the electromagnetic shielding sheet 110 is performed.

The NFC antenna 120 is an antenna used for a short distance communication system. The NFC antenna 120 is capable of transmitting and receiving up to 10 cm. The NFC antenna 120 is connected to the upper part of the electromagnetic wave shielding sheet 110 It is preferable to embed along the outer periphery.

The ultrasonic welding method for embedding the NFC antenna 120 is preferably an ultrasonic welding method and the ultrasonic welding method for embedding the NFC antenna 120 on the electromagnetic wave shielding sheet 110 is described in detail below. (Step S300) of joining the reception coil 130 to the reception coil 130 will be described.

A step S300 of embedding the reception coil 130 on the electromagnetic wave shielding sheet 110 after the step S200 of embedding the NFC antenna 120 on the electromagnetic shielding sheet 110 is performed, .

The receiving coil 130 receives power and applies power to the portable terminal and the receiving coil 130 is embedded in the upper portion of the electromagnetic wave shielding sheet 110 inside the NFC antenna 120 . The receiving coil 130 is also embedded in the upper portion of the electromagnetic wave shielding sheet 110 using an ultrasonic welding method in the same manner as the NFC antenna 120.

The ultrasonic welding method converts electric energy of the power input into mechanical vibration energy through a vibrator and then presses the workpiece through a horn to generate a strong friction heat momentarily on the joint surface to melt and adhere the joint surface. Production is possible, and no adhesive is required.

A Litz wire formed by twisting a plurality of self-welding enamel copper wires 132 is used as the receiving coil 130. The strength of the receiving coil 130 is increased because the Rits wire is formed by twisting a plurality of the self-welding enamel copper wires 132. 7, the self-fusing enamel copper wire 132 is composed of a copper wire 133, an insulating layer 135, and a magnetic fusing layer 137.

The copper wire 133 is a conductor and the insulating layer 135 is intended to insulate the copper wire 133 which is a conductor from the outside and surrounds the copper wire 133 such that the copper wire 133 is not exposed to the outside, (137) is coated on the outside of the insulating layer (135) as a covering of an electric wire to surround the outer circumferential surface of the insulating layer.

The electromagnetic interference shielding layer 137 is melted by being embedded in the electromagnetic shielding sheet 110 by the ultrasonic fusion bonding method to increase the adhesive strength and the adhesive strength between the melted magnetic adhesion layer 137 and the electromagnetic shielding sheet 110 The surface is cooled and is stuck more strongly.

The self-adhesive layer 137 is preferably formed of one or more selected from the group consisting of polyamide, epoxy, butylal, and polyester.

Since the NFC antenna 120 and the receiving coil 130 are directly embedded on the electromagnetic shielding sheet 110 by using the ultrasonic welding method, the working time can be shortened compared with the conventional method of bonding using the adhesive agent , And the cost can be reduced.

The NFC antenna 120 may be directly etched on the upper portion of the electromagnetic wave shielding sheet 110 by using an ultrasonic welding method, It is possible to prevent the generation of pollutants.

The NFC antenna 120 and the receiving coil 130 are embedded on the electromagnetic shielding sheet 110 using an ultrasonic welding method so that the NFC antenna 120 and the receiving coil 130 are sequentially bonded But can be bonded at the same time, so that it is possible to shorten the working time.

After the NFC antenna 120 and the receiving coil 130 are embedded in the electromagnetic shielding sheet 110 at steps S200 and S300, the electromagnetic shielding sheet 110 is wrapped with the protective sheet 140 (S400).

The protective sheet 140 protects the electromagnetic shielding sheet 110, the NFC antenna 120 and the receiving coil 130 from external factors such as heat, moisture and moisture. The protective sheet 140 The electromagnetic wave shielding sheet 110, the NFC antenna 120, and the receiving coil 130 are protected from heat, moisture, and moisture by wrapping the electromagnetic shielding sheet 110.

The wireless receiving antenna 100 for wireless charger capable of wireless communication with a short distance communication can be manufactured through the above steps S100 to S400.

3 to 7, a receiver antenna 100 for a wireless charger according to an embodiment of the present invention is used for wirelessly charging a portable terminal and includes an electromagnetic wave shielding sheet 110, an NFC antenna 120 And a receiving coil 130, and may further include a protective sheet 140. [

The electromagnetic shielding sheet 110 absorbs electromagnetic waves generated by the portable terminal and shields the electromagnetic waves. The electromagnetic shielding sheet 110 is made of a magnetic material and extrudes a raw material containing the magnetic powder and the binder. Sheet shape.

The electromagnetic wave shielding sheet 110 preferably includes a ferrite sheet. The electromagnetic wave shielding sheet 100 absorbs magnetic flux due to the inclusion of a ferrite sheet and collects the magnetic flux in the electromagnetic shielding sheet 110 and transmits it again so that the NFC antenna 120 and the receiving coil 130, Thereby further improving the performance of the apparatus.

A synthetic resin sheet 112 may be laminated on the electromagnetic shielding sheet 110. The NFC antenna 120 and the reception coil 130 can be embedded easily by joining the sheet 112 on the electromagnetic shielding sheet 110. [ The sheet 112 is preferably made of a synthetic resin material such as polyimide, polycarbonate, PET, or the like.

An NFC antenna 120 is embedded on the electromagnetic shielding sheet 110. The NFC antenna 120 is an antenna used for a short distance communication system. The NFC antenna 120 is capable of transmitting and receiving up to 10 cm. The NFC antenna 120 is connected to the upper part of the electromagnetic wave shielding sheet 110 And is preferably embedded along the outer perimeter.

The NFC antenna 120 may be embedded on the electromagnetic shielding sheet 110 using an ultrasonic welding method. The ultrasonic welding method converts electric energy of the power input into mechanical vibration energy through a vibrator and then presses the workpiece through a horn to generate a strong friction heat momentarily on the joint surface to melt and adhere the joint surface. Production is possible, and no adhesive is required.

The reception coil 130 is embedded in the upper portion of the electromagnetic wave shielding sheet 110 in which the NFC antenna 120 is embedded. The receiving coil 130 receives power and applies power to the portable terminal. The receiving coil 130 is embedded in the upper portion of the electromagnetic wave shielding sheet 110 inside the NFC antenna 120 .

The receiving coil 130 is also embedded using an ultrasonic welding method. Since the NFC antenna 120 and the receiving coil 130 are directly embedded using an ultrasonic welding method, the receiving coil 130 is bonded to the receiving coil 130 using an adhesive. It is possible to shorten the working time and reduce the cost.

A Litz wire formed by twisting a plurality of self-welding enamel copper wires 132 is used as the receiving coil 130. The self-fusing enamel copper wire 132 is composed of a copper wire 133, an insulating layer 135, and a magnetic fusing layer 137.

The copper wire 133 is a conductor and the insulating layer 135 is intended to insulate the copper wire 133 which is a conductor from the outside and surrounds the copper wire 133 such that the copper wire 133 is not exposed to the outside, (137) is coated on the outside of the insulating layer (135) as a covering of an electric wire to surround the outer circumferential surface of the insulating layer.

The electromagnetic interference shielding layer 137 is melted by being embedded in the electromagnetic shielding sheet 110 by the ultrasonic fusion bonding method to increase the adhesive strength and the adhesive strength between the melted magnetic adhesion layer 137 and the electromagnetic shielding sheet 110 The surface is cooled and is stuck more strongly.

The self-adhesive layer 137 is preferably formed of one or more selected from the group consisting of polyamide, epoxy, butylal, and polyester.

The NFC antenna 120 and the reception coil 130 are sequentially bonded to the NFC antenna 120 and the reception coil 130 by embedding the NFC antenna 120 and the reception coil 130 on the electromagnetic shielding sheet 110 using an ultrasonic welding method So that it is possible to shorten the working time.

The protection sheet 140 protects the electromagnetic wave shielding sheet 110, the NFC antenna 120 and the reception coil 130 from external factors such as heat, moisture and moisture. The electromagnetic wave shielding sheet 110).

The electromagnetic wave shielding sheet 110, the NFC antenna 120, and the reception coil 130 are protected from heat, moisture, and moisture by the protective sheet 140 having the electromagnetic shielding sheet 110. [ do.

An adhesive layer 150 is preferably provided between the electromagnetic shielding sheet 110 and the protective sheet 140. The adhesive layer 150 may be formed by applying an adhesive or using a double-sided tape. Since the adhesive layer 150 is provided between the electromagnetic shielding sheet 110 and the protective sheet 140, the NFC antenna 120, the receiving coil 130, And the electromagnetic shielding sheet 110 can be further enhanced.

Therefore, since the NFC antenna 120 and the receiving coil 130 are directly embedded on the electromagnetic shielding sheet 110 by using the ultrasonic welding method, the working time can be shortened compared with the conventional method of bonding using the adhesive The NFC antenna 120 is etched using the ultrasonic welding method. However, since the NFC antenna 120 needs to be etched, pollutants are generated in the etching process and the cleaning process. However, By directly embedding in the upper part, the cost can be reduced and the generation of pollutants can be prevented.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: Receiver for wireless charger antenna 110: Electromagnetic wave shielding sheet
112: sheet 120: NFC antenna
130: Receiving coil 132: Self-fusing enamel copper wire
133: copper wire 135: insulating layer
137: magnetic fusion layer 140: protective sheet
150: adhesive layer

Claims (12)

A method for manufacturing a receiver antenna for a wireless charger used to charge a wireless terminal wirelessly,
Preparing an electromagnetic wave shielding sheet for shielding electromagnetic waves;
Embedding an NFC (Near Field Communication) antenna used for a short distance communication method on an upper outer peripheral surface of the electromagnetic wave shielding sheet;
Embedding a receiving coil for receiving electric power on the electromagnetic shielding sheet to apply electric power to the portable terminal; And
And wrapping an upper portion of the NFC (Near Field Communication) antenna and the electromagnetic wave shielding sheet, on which the receiving coil is embedded, with a protective sheet.
The method according to claim 1,
Wherein the NFC (Near Field Communication) antenna and the reception coil are embodied using ultrasonic welding.
The method according to claim 1,
Wherein the receiving coil is a Litz wire formed by twisting a plurality of self-adhesive enamel copper wires.
The method of claim 3,
The self-
A copper wire as a conductor,
An insulating layer surrounding the copper wire;
And a magnetic fusion layer surrounding the outer circumferential surface of the insulating layer.
The method according to claim 1,
Wherein embedding the NFC (Near Field Communication) antenna on an upper portion of the electromagnetic wave shielding sheet and embedding the reception coil are simultaneously performed.
The method according to claim 1,
Wherein the electromagnetic wave shielding sheet further comprises a synthetic resin sheet laminated on the electromagnetic shielding sheet.
1. A receiver antenna for a wireless charger used for wirelessly charging a portable terminal,
An electromagnetic wave shielding sheet for shielding electromagnetic waves;
An NFC (Near Field Communication) antenna embedded in an upper outer peripheral surface of the electromagnetic wave shielding sheet and used in a near field communication system; And
And a reception coil embedded in an upper portion of the electromagnetic wave shielding sheet and receiving power to apply power to the portable terminal.
The method of claim 7,
Further comprising a protective sheet provided on the electromagnetic shielding sheet on which the NFC (Near Field Communication) antenna and the receiving coil are embedded, the electromagnetic shielding sheet surrounding the electromagnetic shielding sheet.
The method of claim 8,
And an adhesive layer is provided between the protective sheet and the electromagnetic wave shielding sheet.
The method of claim 7,
Wherein the receiving coil is a Litz wire formed by twisting a plurality of self-adhesive enamel copper wires.
The method of claim 10,
The self-
A copper wire as a conductor,
An insulating layer surrounding the copper wire;
And a magnetic fusion layer surrounding the outer circumferential surface of the insulating layer.
The method of claim 7,
A receiver for a wireless charger, further comprising a sheet of synthetic resin material laminated on the electromagnetic shielding sheet,

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