KR101205419B1 - Battery pack with NFC anttena involving assistant absorber - Google Patents

Abstract

PURPOSE: A battery pack equipped with near field communication which has an auxiliary absorber structure is provided to minimize performance degradation of an antenna due to electromagnetic wave generated from the battery cell. CONSTITUTION: A battery pack equipped with near field communication which has an auxiliary absorber structure comprises a battery cell(100), a roof antenna part(300), a first absorber(200) located between the battery cell and the roof antenna part, a cover(400) which surrounds the battery cell and the roof antenna part, and second absorbers(500) which are attached to the cover and is in contact with domains where the first absorber is placed. The front part of the roof antenna part is in close contact with the first absorber by inserting the second absorber into the grooves. The back part of the roof antenna part adheres closely with one part of the cover, and the edges are surrounded by the second absorber.

Description

A battery pack having an NFC antenna having an auxiliary absorber structure {Battery pack with NFC anttena involving assistant absorber}

The present invention relates to an antenna battery pack including an absorber for removing noise due to electromagnetic waves.

Absorber absorbs incident radio waves, converts them into heat, and does not generate reflected waves.Its use is to be installed around antenna-free anechoic chambers, parabolic antennas, etc. to improve directivity. In addition, many examples are used for ghost measures of television broadcasting and radar in terms of electronic environment.

Recently, with the advent of small and thin digital devices such as slim phones, the importance of electromagnetic wave countermeasures has increased, and the adoption of electromagnetic wave absorbers has been increasing, especially in mobile phone RFID.

Electromagnetic wave absorbers use magnetic materials to convert electrical energy into thermal energy to absorb and dissipate electromagnetic waves. Conductive material is applied to the inside and outside walls of the device to reduce the effects of noise by reflecting or flowing electromagnetic waves, which are used to remove noise that cannot be processed.

Recently, since the mobile terminal has become smaller and lighter, the antenna of the terminal is included in the battery. In this case, an electromagnetic wave generated from the battery during operation of the mobile terminal may cause a problem in the performance of the antenna, so that an absorber for blocking the electromagnetic wave affecting the antenna is used.

However, in the conventional battery pack, since the absorber is used only where the antenna is located, antenna performance may be degraded due to electromagnetic waves generated from the battery region which the absorber cannot block.

An object of the present invention is to minimize the performance degradation of the antenna due to electromagnetic waves generated from the battery cell during use of the battery by absorbing the absorber constituted in the battery pack including the antenna completely.

Other objects of the present invention will be readily understood through the following description of the embodiments.

The present invention provides a battery cell comprising: a battery cell; and a loop antenna part; a first absorber positioned between the battery cell and the loop antenna part; and a cover surrounding the battery cell and the loop antenna part; And a second absorber attached to the cover and in contact with an area other than the battery cell area in which the first absorber is located. Provided is a battery pack having a NFC (Near Field Communication) antenna, characterized in that it comprises a.

Here, the front portion of the loop antenna portion may be in close contact with the first absorber, the rear portion may be in close contact with a portion of the cover, and the edge portion may be surrounded by the second absorber.

Here, the first absorber and the second absorber may be characterized by absorbing electromagnetic waves generated from the battery cell using a conductive material.

Here, the loop antenna unit may be characterized by including a patch antenna.

The loop antenna unit may include a patch antenna, and the patch antenna may be a loop antenna including any one selected from copper, carbon black, magnesium, aluminum, silver paste, and a stamping method.

The patch antenna may be a loop antenna including any one selected from copper, carbon black, magnesium, aluminum, silver paste, and a stamping method.

Here, the second absorber may be characterized in that the cover is configured by printing or deposition method.

The present invention can simply minimize the influence of electromagnetic waves generated from the battery cells by including an absorber in the cover which is a packaging material surrounding the battery cells when configuring the battery pack.

In addition, by enclosing the antenna in an absorber double, there is an effect that can prevent the reduction of the performance of the antenna.

1 is a diagram illustrating a configuration of a battery pack excluding a cover according to an embodiment of the present invention.
FIG. 2 is a view showing a second absorbent body formed in a cover according to an embodiment of the present invention.
3 is a cross-sectional view illustrating a positional relationship between a first absorber positioned in a battery cell and a second absorber positioned in a cover according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram illustrating a configuration of a battery pack excluding a cover according to an embodiment of the present invention.

The first absorber 200 is positioned on one side of the battery cell 100, and the loop antenna part 300 is positioned on the first absorber 200.

Here, the first absorber 200 is composed of at least one of a resistor, a dielectric loss material, and a magnetic loss material, and absorbs / blocks electromagnetic waves generated directly from the battery cell 100. . Therefore, the first absorber 200 prevents the antenna performance of the loop antenna unit 300 from being degraded due to the electromagnetic waves generated from the battery cell 100.

The loop antenna unit 300 is provided with a patch antenna in which a loop pattern is formed. The loop pattern of the patch antenna may be composed of at least one selected from copper, carbon black, magnesium, aluminum, silver paste, and stamping.

Here, the patch antenna is an NFC antenna.

2 is a view showing a second absorbent body which is attached to a cover in one embodiment of the present invention.

The second absorbent 500 may be attached to the cover 400 of the battery pack of the present invention.

The second absorbent 500 is attached to the cover 400 in contact with an area (part) of the battery cell in which the first absorbent 200 is not located when the cover 400 surrounds the battery cell 100. Therefore, when the cover 400 to which the second absorber 500 is attached surrounds the battery cell 100, the battery cell 100 is completely surrounded by the first absorber 200 and the second absorber 500. This will be.

In a more preferred example of the present invention, the second absorbent member 500 may be configured only in a portion of the portion of the cover 400 that contacts the loop antenna portion 300 when the cover 400 surrounds the battery cell 100. have. That is, when the cover 400 surrounds the battery cell 100, the second absorber 500 may include the battery cell 100 in which the first absorber 200 is not positioned on the cover surface that contacts the loop antenna part 300. It may only be attached to the cover portion in contact with the area of the.

As shown in FIG. 2, the second absorber 500 is attached to the cover 400 in contact with the loop antenna part 300, except for the part 550 in which the loop antenna part 300 is in contact with the cover 400. Is only attached.

Here, the second absorbent 500 may be coated on the cover 400 in a printing manner. That is, the second absorbent body 500 may be formed of any one or more of a resistor, a dielectric loss material, and a magnetic loss material and may be printed on the cover.

The second absorber 500 absorbs and blocks electromagnetic waves propagated from an area where the battery cell 100 is not covered by the first absorber 200. Therefore, the second absorber 500 prevents the performance of the loop antenna unit 300 from degrading due to electromagnetic waves that are not blocked by the first absorber 200.

3 is a cross-sectional view illustrating a positional relationship between a first absorber positioned in a battery cell and a second absorber positioned in a cover according to an embodiment of the present invention.

As described above, the first absorber 200 is positioned on one side of the battery cell 100, and the loop antenna part 300 is positioned on the first absorber 200.

As described above, when the cover 400 including the second absorber 500 surrounds the battery cell 100, the loop antenna unit 300 may be formed as shown on the left in the arrow direction of FIG. 3. It is surrounded by the absorber 200 and the second absorbent 500.

The positional relationship between the loop antenna part 300 and the first absorbent body 200, the second absorbent body 500, and the cover 400 is as follows.

In this case, it is assumed that the loop antenna part 300 has a rectangular shape, and a direction in which the battery cell is located is called front and a direction in which the cover is located is called a rear. Then, the roof antenna part 300 is in close contact with the first absorbent body 200, the rear part is in close contact with a portion (550 of FIG. 2) of the cover 400, and the edge portion except the front part and the rear part is the second absorber 500. Surrounded by).

Here, the loop antenna part 300 may be configured in a circular shape other than a square shape and other shapes.

Therefore, the battery pack of the present invention can completely block the electromagnetic wave generated from the battery cell 100 by the first absorber 200 and the second absorber 500 while the battery is in use, thereby preventing performance degradation of the antenna.

As the material of the first absorber 200 and the second absorber 500 of the present invention, any one or more of a resistor, a dielectric loss material, and a magnetic loss material can be used.

Here, the resistor absorbs radio waves in accordance with the high-frequency current flowing through the resistance wire or the resistive film.

Here, the dielectric loss material includes carbon rubber, urethane for foaming carbon-containing foam, polystyrene for foaming graphite-containing foam, and the like.

The representative of the magnetic loss material here is ferrite. Ferrite plates backed by metal plates exhibit good absorption properties over a relatively wide frequency range.

Although the above has been described with reference to embodiments of the present invention, those skilled in the art may variously modify the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. And can be changed.

100: battery cell
200: first absorber
300 loop antenna
400: cover
500: second absorber

Claims (7)

Battery cells;
Loop antenna portion;
A first absorber positioned between the battery cell and the loop antenna portion;
A cover surrounding the battery cell and the loop antenna part; And
A second absorber attached to the cover and in contact with an area other than the battery cell area in which the first absorber is located; Including but not limited to:
The loop antenna portion is inserted into a groove formed by the second absorber, the front portion of the loop antenna portion is in close contact with the first absorber, the rear portion is in close contact with a portion of the cover, and the edge portion is surrounded by the second absorber. The loop antenna unit is a battery pack with a NFC (Near Field Communication) antenna, characterized in that completely surrounded by the first absorber, the second absorber and the cover.
delete The method of claim 1,
And the first absorber and the second absorber absorb electromagnetic waves generated from the battery cell using a conductive material.
The method of claim 1,
The loop antenna unit is a battery pack having an NFC antenna, characterized in that it comprises a patch antenna.
The method of claim 1,
The loop antenna unit includes a patch antenna and the patch antenna is a battery pack with an NFC antenna, characterized in that the loop antenna consisting of any one selected from copper, carbon black, magnesium, aluminum, silver paste (Silver Paste) and stamping method .
5. The method of claim 4,
The patch antenna is a battery pack with an NFC antenna, characterized in that the loop antenna consisting of any one selected from copper, carbon black, magnesium, aluminum, silver paste (Silver Paste) and stamping method.
The method of claim 1,
The second absorber is a battery pack with an NFC antenna, characterized in that the cover is configured by printing or deposition method.

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