KR101317866B1 - Portable device - Google Patents

Abstract

PURPOSE: A portable device is provided to reliably charge a battery of a terminal unit by installing a charging unit on the rear side of the terminal unit. CONSTITUTION: A terminal unit (100) is driven with a battery. A charging unit (200) is formed on the rear side of the terminal unit and is separated from the battery. The charging unit converts light energy into electric energy and charges the battery with the electric energy.

Description

Mobile device {PORTABLE DEVICE}

The present invention relates to a portable device and to a portable device capable of easily and reliably charging a battery of a portable terminal unit.

Portable electronic devices are being released to have various functions and types with the development of complex technologies such as batteries, liquid crystals, and memory chips. Portable electronic devices include, for example, mobile phones, PDAs, game machines, PMPs, MP3 players, MIDs, e-book readers, and the like.

Portable electronic devices are basically equipped with a built-in battery to be supplied with power. The emphasis on portability is that the weight of the main body is reduced and the battery size is decreasing. Of course, the battery technology is more developed than in the past, but due to the reduced battery capacity, when the external use of portable electronic devices for a long time, the battery is often run out of situations.

In order to prevent such a problem, a secondary battery that can be coupled to a USB port or a power connection terminal has been released. However, the auxiliary battery has a disadvantage in that it does not have a good grip and use state because the auxiliary battery has a shape that protrudes to one side and is not good in shape.

Korean Patent Laid-Open Publication No. 2002-0063050 discloses a technique for charging a battery through wireless power transmission. However, since a power transmission unit corresponding to an adapter using commercial power is required, portability is low, .

Korean Laid-Open Patent Publication No. 2002-0063050

The present invention is to provide a portable device capable of easily and reliably charging a battery of a portable terminal unit.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not intended to limit the invention to the precise forms disclosed. Other objects, which will be apparent to those skilled in the art, It will be possible.

The portable device of the present invention may include a charging unit disposed separately from the battery on the rear of the battery powered portable terminal unit, converting light energy into electrical energy, and charging the battery with the electrical energy.

In addition, the portable device of the present invention includes a solar panel having a shape that is planarly joined to at least a portion of a rear surface of a battery powered portable terminal unit, wherein the solar panel includes a rear case of the terminal unit provided separately from the battery. It can be formed integrally.

In addition, the portable apparatus of the present invention may include a solar panel having a shape that is planarly joined to at least a portion of a rear surface of a battery powered portable terminal unit, and the solar panel may have an adhesive layer adhered to the rear surface of the terminal unit. .

In addition, the portable device of the present invention includes a solar panel having a shape that is planarly joined to at least a portion of a rear surface of a battery powered portable terminal unit and a protective cover formed to cover at least the rear surface of the terminal unit and detachable from the terminal unit. The solar panel may be disposed between at least one of the terminal unit and the protective cover, an inner surface of the protective cover, and an outer surface of the protective cover.

The portable device of the present invention converts light energy into electrical energy and installs a charging unit on the back of the terminal unit that charges the portable terminal unit with the converted electrical energy, thereby limiting the use of the portable terminal unit. Can be charged easily and reliably.

1 is a schematic diagram showing a portable device of the present invention.
2 is a schematic view showing a terminal portion of the portable device of the present invention.
3 is a schematic view showing a state in which a terminal unit is installed in the portable device of the present invention.
4 is a schematic view showing another terminal portion of the portable device of the present invention.
5 is a schematic diagram illustrating a portable device for expanding a solar panel in a sliding manner.
6 is a schematic diagram illustrating a portable device for expanding a solar panel in a foldable manner.
7 is a schematic view showing another portable device of the present invention.
8 is a schematic diagram showing another portable device of the present invention.
9 is a schematic view showing a state in which a solar panel is installed on a protective cover.
10 is a schematic view showing another state in which a solar panel is installed on a protective cover.
11 is a schematic diagram showing a state in which a solar panel is installed on a protective cover at another angle.
12 is a schematic diagram showing a connector connecting the portable device and the terminal unit of the present invention.
13 is a circuit diagram illustrating a power processor of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience. In addition, terms defined in consideration of the configuration and operation of the present invention may be changed according to the intention or custom of the user, the operator. Definitions of these terms should be based on the content of this specification.

1 is a schematic diagram showing a portable device of the present invention.

The portable device shown in FIG. 1 is provided at the rear of the terminal unit 100 and the portable terminal 100 driven by the battery 180 and is disposed separately from the battery 180 and converts light energy into electrical energy. And, it may include a charging unit 200 for charging the battery 180 with electrical energy.

The portable terminal unit 100 is a device used in a state of being carried by a user and includes a mobile phone, a PDA, a game machine, a PMP, an MP3 player, a MID, an e-book reader, a notebook computer, a tablet computer, and the like. Since the terminal unit 100 does not receive power by wire, the terminal unit 100 receives power from the battery 180 required for the expression of the unique function of each terminal unit 100.

The battery 180 stores power input from the outside or the inside, and supplies power to various members of the terminal unit 100 when necessary. The battery 180 charges the power and supplies the charged power so that the terminal unit 100 expresses a unique function.

The battery 180 is charged by receiving power from a portable device through a terminal formed in the terminal unit 100. The portable device may be provided separately from the terminal unit 100.

Although the capacity of the battery 180 is increasing, the user is complaining of the lack of the battery 180 due to the increase in the size of the display 120 installed in the terminal unit 100. Since the portable apparatus provided separately from the terminal unit 100 requires commercial power, the portable apparatus may not always be used even if the user possesses the portable apparatus.

The charging unit 200 of the present invention does not require a commercial power source by converting light energy into electrical energy. The charging unit 200 of the present invention may include a solar panel 210, an optical device, and the like for converting light energy into electrical energy. The location of the charging unit 200 in the terminal unit 100 is also important. The portable terminal unit 100 aims at a small size for the convenience of carrying. In addition, a display 120 of the largest size possible is often mounted to meet the needs of the user. Typical examples of this are smartphones and tablet PCs. The terminal unit 100 has a small installation space of the charging unit 200 on the front of the terminal unit 100 in which the display 120, the speaker 140, and the input unit 150 are installed.

Therefore, the charging unit 200 may be disposed on the rear surface of the terminal unit 100. For example, in the terminal unit 100 including the display 120, the surface on which the display 120 is installed is the front surface, and the opposite surface is the rear surface. An additional element such as a camera 160 may be disposed on the back of the terminal unit 100, but the charging unit 200 may be formed to avoid such an additional element.

In addition, the charging unit 200 may be disposed separately from the battery 180. When the battery 180 and the charging unit 200 are integrally formed, there are many difficulties in maintenance, and the arrangement and position of the charging unit 200 may also be limited. Thus, the charging unit 200 is advantageously formed separately from the battery 180.

What is important in the charging unit 200 is how to provide the electrical energy generated by the charging unit 200 to the battery 180. In addition, how to increase the amount of electrical energy output from the charging unit 200 is also an important problem.

A method of supplying electrical energy to the battery 180 in the charging unit 200 disposed on the back of the terminal unit 100 may vary.

For example, when the terminal unit 100 is formed of the first terminal 181 formed in the battery 180 and the second terminal 111 formed in the body of the terminal unit 100 and in contact with the first terminal 181. Assume

The charging unit 200 may include a terminal unit 250 as an interface for supplying the generated electrical energy to the outside. In this case, the terminal unit 250 may be connected to the battery 180 in various ways.

Fig. 2 is a schematic diagram showing a terminal portion of the portable device of the present invention, and Fig. 3 is a schematic diagram showing a state in which the terminal portion is installed in the portable device of the present invention.

In general, terminals 180 are formed in the battery 180 and the terminal unit 100 to electrically connect each other. At this time, the terminals are the first terminal 181 of the battery 180 and the second terminal 111 of the terminal unit 100.

In FIG. 2, a terminal portion 250 protruding in the rear case 190 of the terminal unit 100 toward the front case 110 of the terminal unit 100 is formed. In FIG. 2, the left terminal part 250 may be interposed between the first terminal 181 of the battery 180 and the second terminal 111 of the terminal unit 100. The charging unit is also included in the existing terminal unit 100 having the first terminal 181 and the second terminal 111 by configuring the terminal unit 250 to be interposed between the first terminal 181 and the second terminal 111. Electrical energy of 200 may be supplied.

In order to protect the first terminal 181 formed in the battery 180 from external impact, the first terminal 181 may be concave. The second terminal 111 formed in the terminal unit 100 to be in electrical contact with the first terminal 181 may be formed to be convex and elastic. The terminal unit 250 may be interposed between the first terminal 181 and the second terminal 111 by using characteristics of the second terminal 111 having elasticity. Even when the terminal part 250 is interposed between the first terminal 181 and the second terminal 111 by using the elasticity of the second terminal 111, the terminal part ( The contact between the 250 and the first terminal 181 may not be made reliably.

In order to prevent such a phenomenon, the terminal part 250 may include an insertion part 251 inserted between the first terminal 181 and the second terminal 111, and the insertion part 251 may include the first terminal 181 and the second terminal. An auxiliary part 253 protruding from the insertion part 251 toward the first terminal 181 in the state interposed between the 111 and 111 may be included. Since the auxiliary part 253 is formed to protrude, the contact with the first terminal 181 is made reliably. The auxiliary part 253 may be formed in various ways. For example, the protrusion may be a protrusion. Or it may be a plate extending from the insertion portion 251 as shown in FIG.

In the above, the terminal part 250 interposed between the first terminal 181 and the second terminal 111 has been described. The terminal unit 250 may be formed to be in contact with the third terminal 113 which is provided separately from the first terminal 181 and is provided separately from the second terminal 111. In FIG. 2, the terminal part 250 on the right side of the rear case 190 corresponds to this case.

The terminal unit 100 may include a battery 180 in which a first terminal 181 is formed, a second terminal 111 in contact with the first terminal 181, and a third terminal circuitly connected to the second terminal 111 ( 113, and a case covering at least the third terminal 113. In this case, the charging unit 200 may include a terminal unit 250 provided in the case and in contact with the third terminal 113. When the charging unit 200 is provided on the outer surface of the case, the terminal unit 250 may be formed through the case.

The third terminal 113 part is formed in the front case 110 or the body of the terminal unit 100 and may be provided by the manufacturer of the terminal unit 100. The third terminal 113 is entirely exposed to the outside unlike the first terminal 181 and the second terminal 111 in contact with each other. Therefore, since the third terminal 113 is easily damaged by external shock and static electricity, it is recommended to cover and protect the case. In FIG. 2, an example of protecting the third terminal 113 with the rear case 190 is disclosed.

Since the solar panel 210 and the like should be disposed at a position capable of receiving light, when the solar panel 210 is installed in the rear case 190, the solar panel 210 is installed on the outer surface of the rear case 190. Since the third terminal 113 is protected by the case, the third terminal 113 may not be exposed to the outside. Therefore, in order to provide electrical energy generated by the solar panel 210 to the third terminal 113, the charging unit 200 may include a terminal portion 250 penetrating the case and contacting the third terminal 113. have. In this case, the terminal unit 250 may be disposed at a position corresponding to the third terminal 113 in a state in which the rear case 190 is mounted on the terminal unit 100.

Meanwhile, the terminal unit 250 may be connected to the socket 130 formed in the terminal unit 100.

4 is a schematic view showing another terminal portion of the portable device of the present invention.

The terminal unit 100 may include a socket 130 exposed to the outside for charging the battery 180 and inputting / outputting various data. If the terminal unit 100 includes a socket 130 that is circuitally connected to the battery 180, the charging unit 200 includes a terminal unit 250 detachable from the socket 130 as shown in FIG. 4. can do. For other purposes of the socket 130 of the terminal unit 100, it is necessary to be connected to other devices other than the charging unit 200. Therefore, if necessary, the terminal 130 of the charging unit 200 needs to be separated from the socket 130 of the terminal unit 100 so as to be connected with another device. In addition, if necessary, the terminal unit 250 of the charging unit 200 should be mounted to the socket 130. Therefore, the terminal unit 250 of the charging unit 200 may be detachably attached to the socket 130. In this case, the terminal unit 250 may be connected to the charging unit through the wire 259.

In the above, the method of electrically connecting the charging unit 200 disposed on the back of the terminal unit 100 and the battery 180 of the terminal unit 100 has been described. Hereinafter, the expansion of the capacity of the charging unit 200 will be described.

Since the charging unit 200 converts light energy into electrical energy, reliable input of light energy is required. However, since the light energy input to the charging unit 200 is related to the location, weather, time, etc. of the user, it is difficult to always receive a sufficient amount to charge the battery 180.

Therefore, in order to obtain as much light energy as possible, the charging unit 200 needs to expand the amount of input light energy.

To this end, the charging unit 200 may include a solar panel 210 and a guide unit 191.

The solar panel 210 is an element that converts light energy into electrical energy and may be a so-called solar cell.

The guide unit 191 may guide one or more solar panels 210 to be received and slide in a side direction of the terminal unit 100.

FIG. 5 is a schematic diagram illustrating a portable device for expanding a solar panel in a sliding manner, and FIG. 6 is a schematic diagram illustrating a portable device for expanding a solar panel in a folding manner.

The charging unit 200 disclosed in FIG. 5 discloses a guide unit 191 in which n solar panels 210 are stored (n is a natural number of two or more). At this time, the solar panel 210 accommodated in the guide 191 is sequentially guided from the first solar panel 210 to the m-th solar panel 210 ((1≤m≤n and m is a natural number)) 191).

According to this configuration, m solar panels 210 are unfolded according to the sliding distance of the first solar panel 210. According to this, when the conversion capacity of the solar panel 210 is assumed to be 1, a maximum conversion capacity of n may be ensured. The charging unit 200 may have a solar panel 210 disposed on the rear surface of the terminal unit 100 separately from the n solar panels 210 as shown in FIG. 5. In this case, the maximum conversion capacity is n + 1. In summary, the amount of electrical energy output from the charging unit 200 may vary according to the number of solar panels 210 exposed to light energy.

In order to unfold m solar panels 210 by only manipulating the first solar panel 210, a hook portion 211 may be formed at an edge of each solar panel 210. For example, a locking part 211 protruding downward is formed on the left side of the first solar panel 210 in FIG. 5. In addition, a locking part 211 protruding upward from the right side of the second solar panel 210 is formed. When the first solar panel 210 is slid to the right, only the first solar panel 210 is slid, but the engaging portion 211 of the first solar panel 210 and the engaging portion 211 of the second solar panel 210 are closed. After contact, the first solar panel 210 and the second solar panel 210 slide together with the right side of the second solar panel 210 adjacent to the left side of the first solar panel 210. In this manner, sliding to the mth solar panel 210 may be performed.

The charging unit 200 disclosed in FIG. 6 also discloses a guide portion 191 in which n solar panels 210 are stored (n is a natural number of two or more). In this case, the n solar panels 210 may be stored in n layers along the rear direction of the terminal unit 100.

The solar panel 210 is separated from the guide portion 191 in a state in which n pieces (n is a natural number of two or more) are stacked on the guide portion 191, and the i-th solar panel 210 (2 ≦ i ≦ n) i is a natural number) may be unfolded based on the i-1 th solar panel 210. In summary, the n solar panels 210 may be unfolded in a folding manner.

In this case, one side of the i-th solar panel 210 and one side of the i-1th solar panel 210 may be connected by a hinge structure.

The charging unit 200 may be disposed on the rear surface of the terminal unit 100 in various ways.

The portable device may include a solar panel 210 having a shape that is planarly joined to at least a portion of the rear surface of the portable terminal unit 100 driven by the battery 180. In this case, the solar panel 210 may be integrally formed with the rear case 190 of the terminal unit 100 provided separately from the battery 180. Examples of this are disclosed in FIGS. 1 to 6.

According to the above configuration, since the terminal unit 250 of the charging unit 200 may be formed inside the rear case 190, the socket 130 of the terminal unit 100 may not be used.

In addition, the terminal part 250 which removes the rear case 190 of the terminal unit 100 and is interposed between the first terminal 181 of the battery 180 and the second terminal 111 of the terminal unit 100 is provided. The provided rear case 190 may be mounted. Accordingly, the charging unit 200 may be naturally installed in the terminal unit 100 by replacing the rear case 190 of the existing terminal unit 100.

In addition, the manufacturer of the terminal unit 100 may directly manufacture the rear case 190 having the charging unit 200 and ship the terminal unit 100 in a state in which the rear case 190 is coupled to the terminal unit 100. It may be. In this case, it is preferable to form the third terminal 113 to which the terminal unit 250 is connected to the terminal unit 100.

Between the solar panel 210 and the terminal unit 250 converts the electrical energy generated in the solar panel 210 to the terminal unit 100 or the battery 180 to suitably convert the solar panel 210 or the battery 180. It may include a power processor 230 to protect from shock.

13 is a circuit diagram illustrating a power processor of the present invention.

The power processor 230 detects a charging voltage of the battery 180, that is, a voltage of electrical energy output from the solar panel 210 and charged to the battery 180, and when the charging voltage is greater than or equal to an upper limit, the charging of the battery 180 is performed. By blocking the battery 180 is not overcharged.

The power processor 230 includes a voltage detector 610 and a switching circuit 620. The voltage detecting element 610 monitors the charging voltage of the battery 180 through the battery 180 connection terminals B + and B- and operates the switching circuit 620 when the charging voltage of the battery 180 is greater than or equal to an upper limit. Output a control signal. The switching circuit 620 cuts off the charging operation of the battery 180 according to the control signal output from the voltage detecting element 610.

The switching circuit 620 has a switching function by having a MOSFET installed between the battery 180 connection terminals B + and B- and the panel connection terminals V + and V-. That is, the voltage detecting element 610 and the switching between the battery 180 connection terminals B + and B- connected to the battery 180 and the panel connection terminals V + and V- connected to the solar panel 210. Circuit 620 is provided.

The backflow prevention diode 690 prevents the power of the battery 180 from flowing back to the solar panel 210. The backflow prevention diode 690 may be connected to the charging unit 200, specifically, the output terminal of the solar panel 210.

The voltage detecting element 610 monitors the charging voltage of the battery 180 through the battery 180 connection terminals B + and B-, and supplies power to each part when the charging voltage of the battery 180 is greater than or equal to an upper limit. Outputs a control signal. For example, a voltage detector IC or a reset IC is used as the voltage detection element 610.

The output control signal is selectively outputted with a high or low signal according to the type of switching element configured in the switching circuit 620. The switching circuit 620 stops the charging operation of the battery 180 according to the control signal output from the voltage detecting element 610. In the illustrated embodiment, the switching circuit 620 is connected between the battery 180 connection terminals B + and B-. N channel MOSFET is installed.

Therefore, when the control signal output from the voltage detection element 610 is High, the N channel MOSFET is turned on to charge the battery 180, and the control signal output from the voltage detection element 610 is When low, the N Channel MOSFET is turned off to stop charging of the battery 180.

That is, the voltage detecting element 610 turns off the N channel MOSFET of the switching circuit 620 by outputting a low signal when the voltage at both ends of the battery 180 is overcharged to be above the upper limit.

7 is a schematic view showing another portable device of the present invention.

The portable device illustrated in FIG. 7 includes a solar panel 210 that is planarly joined to at least a portion of the rear surface of the portable terminal unit 100 driven by the battery 180. The solar panel 210 may have an adhesive layer 213 adhered to the rear surface of the terminal unit 100. According to this configuration, the adhesive layer 213 is positioned between the panel layer 211 of the solar panel 210 and the rear surface of the terminal unit 100.

According to the adhesive layer 213, the solar panel 210 may be attached to the rear surfaces of all the terminal units 100. In this case, it is difficult for the terminal unit 250 of the solar panel 210 to penetrate the rear case 190 of the battery 180. Therefore, the terminal unit 250 supplying the electrical energy generated by the solar panel 210 to the battery 180 may be configured to be connected to the socket 130 of the terminal unit 100. The solar panel 210 may be made of a flexible material, and thus may be protected from external impact, and convenience of installation may be increased.

8 is a schematic view showing another portable device of the present invention, Figure 9 is a schematic view showing a state in which a solar panel is installed on the protective cover.

The portable device illustrated in FIG. 8 covers the solar panel 210 and at least the rear surface of the terminal unit 100 having a shape that is planarly joined to at least a portion of the rear surface of the portable terminal unit 100 driven by the battery 180. It may include a protective cover 290 is formed and detached to the terminal unit 100.

In this case, as illustrated in FIG. 9, the solar panel 210 may be disposed between at least one of the terminal unit 100 and the protective cover 290, the inside of the protective cover 290, and the outer surface of the protective cover 290.

By installing the solar panel 210 in the protective cover 290, the solar panel 210 can be easily installed in the terminal unit 100. In addition, when the solar panel 210 is disposed between the terminal unit 100 and the protective cover 290 or inside the protective cover 290, the solar panel 210 may be protected from external impact.

When the solar panel 210 is disposed inside the protective cover 290, a space for accommodating the solar panel 210 is required inside the protective cover 290, which may form the guide portion 291. have. That is, after the plurality of solar panels 210 are inserted into the guide portion 291, the capacities of the solar panels 210 may be expanded by the sliding method or the folding method as described above.

Even in the case of the protective cover 290, it is difficult to install the terminal portion 250 connected to the solar panel 210 through the case of the terminal unit 100. Therefore, it is preferable to connect the terminal unit 250 to the socket 130 formed in the terminal unit 100.

The solar panel 210 may be disposed in various ways according to the type of the protective cover 290.

10 is a schematic view showing another state in which a solar panel is installed on a protective cover, and FIG. 11 is a schematic view showing another state in which a solar panel is installed in a protective cover.

The protective cover 290 may include a rear cover covering the rear surface of the terminal unit 100 and a front cover covering the front surface of the terminal unit 100.

In this case, the solar panel 210 may be installed on the rear cover and the front cover.

10 and 11, solar panels 210 are installed on the front and rear surfaces of the front cover and the rear surfaces of the front cover.

By installing the solar panel 210 on the front cover and the rear cover, the capacity of the solar panel 210 can be easily expanded.

Meanwhile, electrical energy output from the solar panel 210 may be provided to various terminal units 100. In this case, since the sockets 130 of the respective terminal units 100 may be different from each other, the terminal unit 250 may be provided in plurality in correspondence with the sockets 130 of the respective terminal units 100.

12 is a schematic diagram showing a connector connecting the portable device and the terminal unit of the present invention.

The connector illustrated in FIG. 12 includes a power input unit 310 connected to the terminal unit 250 of the charging unit 200, a multi connection unit 350 for branching electrical energy input to the power input unit 310 into a plurality of paths, and The power output unit 330 may be provided at an end of each path branched from the connection unit 350 and connected to the socket 130 of the terminal unit 100.

The power input unit 310 is an element connected to the terminal unit 250 and may be formed as a socket 130 corresponding to the terminal unit 250. The power input unit 310 may be integrally formed with the terminal unit 250. In this case, the connector of FIG. 12 becomes the terminal unit 250 of the charging unit 200. When the power input unit 310 and the terminal unit 250 are integrally formed, the power input unit 310 and the terminal unit 250 may be replaced by wires for transporting electrical energy.

Electrical energy input to the power input unit 310 is transferred to the multi connection unit 350 through a single wire.

The multi-connector 350 branches the electrical energy input through a single wire into a plurality of paths. Each path at this time may be composed of a wire.

The power output unit 330 is provided at the end of each path branched from the multi connection unit 350. The power output unit 330 may include a terminal corresponding to the socket 130 of the terminal unit 100. A plurality of power output units 330 are connected to the multi connection unit 350, and each power output unit 330 may be different from each other. Of course, the same may be the case.

According to the above connector, the terminal unit 250 may be connected to the terminal unit 100 regardless of the type of the terminal unit 100. In addition, according to the connector, the plurality of terminal units 100 can be charged at the same time.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, the true scope of the present invention should be determined by the following claims.

Terminal unit 110 ... front case
111 ... 2nd terminal 113 ... 3rd terminal
120 Display 130 Socket
140 ... speaker 150 ... input
160 ... Camera 180 ... Battery
181 1st terminal 190 ... rear case
191, 291 ... guide part 200 ... charging unit
210 Solar panels 211 Panel layer
213 ... Adhesive layer 230 ... Power processing unit
250 Terminal 251 Insert
253 Auxiliary part 259 Wire
290 ... Protection cover 310 ... Power input
330 ... power output 350 ... multi-connection
610 ... voltage detection element 620 ... switching circuit
690 ... backflow protection diode

Claims (14)

A battery powered and portable terminal unit; And
A charging unit provided on a rear surface of the terminal unit, disposed separately from the battery, converting light energy into electrical energy, and charging the battery with the electrical energy;
The terminal unit includes a first terminal formed in the battery, a second terminal in contact with the first terminal,
The charging unit includes a terminal portion interposed between the first terminal and the second terminal for supplying electrical energy of the charging unit,
And the terminal portion includes an insertion portion inserted between the first terminal and the second terminal, and an auxiliary portion protruding in the direction from the insertion portion toward the first terminal and contacting the first terminal.
delete delete delete The method of claim 1,
The charging unit includes a solar panel for converting the light energy into the electrical energy, and a guide unit for guiding the solar panel is accommodated and sliding in the side direction of the terminal unit.
delete delete The method of claim 1,
And a power processor configured to block charging of the battery when the charging voltage of the electrical energy charged by the battery is equal to or greater than an upper limit.
delete delete The method of claim 1,
The terminal unit has a rear case,
And the charging unit is integrally formed with the rear case and includes a solar panel that generates the electrical energy.
The method of claim 1,
The charging unit includes a solar panel attached to the terminal unit by an adhesive layer.
delete The method of claim 1,
And a protective cover detachable from the terminal unit so as to cover a rear surface of the terminal unit.
The protective cover includes a rear cover covering a rear surface of the terminal unit and a front cover covering a front surface of the terminal unit.
The charging unit includes a solar panel installed on the rear cover and the front cover.

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