KR20200135030A - Free voltage multi charging device for battery - Google Patents

Abstract

The present invention relates to a free voltage multi charging device for a battery for charging batteries of various voltages and types by one charging device because a plurality of charging kits capable of charging batteries of different charging voltages and types may be coupled with one charger body. The free voltage multi charging device for a battery comprises: a charger body having a rectangular shape having a length in one direction, at least one charging socket being formed at one side of a longitudinal direction and provided therein with a display unit to display a charged state at an upper surface, and coupled with an external power supply to supply power; at least one charging kit including one end detachably coupled with the charging socket by magnetism and an upper surface formed therein with a mounting groove in which the battery is detachably mounted to charge a battery mounted in the mounting groove when the charging kit is coupled with the charging socket; and a controller provided at the charger body to determine a charged voltage and a charged condition of the battery mounted in the mounting groove when the charging kit is coupled with the charging socket and supply power necessary for charging from the charger body after the determination.

Description

Free voltage multi-charging device for battery {FREE VOLTAGE MULTI CHARGING DEVICE FOR BATTERY}

The disclosed content relates to a free-voltage multi-charger for a battery used for charging a battery used in various voltages and types of electronic products.

Unless otherwise indicated herein, the content described in this section is not prior art to the claims of this application, and inclusion in this section is not admitted to be prior art.

Recently, electronic products equipped with batteries such as digital cameras, smartphones, laptops, tablet PCs, vacuum cleaners, etc. are widely used, and rechargeable batteries are used as power supply devices so that they can operate smoothly even outdoors where power is not supplied in real time. Is being used. Lithium-ion (Li-ion) batteries, nickel hydride (Ni-MH) batteries, and the like are used for such rechargeable batteries.

Such a rechargeable battery has different charging voltages depending on the battery capacity, and if it is used outdoors for a long time in which real-time charging is not possible, the electronic product cannot be used anymore when the battery is discharged.

In this case, there was an inconvenience of having to prepare and use an extra battery, or to urgently charge the battery and reuse it by moving to a rechargeable place such as a nearby cafe, government office, vehicle, or convenience store. In addition, when traveling or on a business trip, you need to prepare a separate charger for charging the battery.There are no chargers that charge all different voltages and types of electronic products such as razors, smartphones, and tablet PCs, so all three chargers must be prepared. This is because the size and charging voltage of batteries are all different for each type of electronic product and brand, and the charging terminals of chargers are also different. In addition, there is a problem that additional battery purchase costs are incurred when preparing spare batteries.

1. Korean Patent Publication No. 10-2015-0094974 (2015.08.20) 2. Korean Patent Registration No. 10-1026223 (2011.03.24) 3. Korean Patent Registration No. 10-1290890 (2013.07.23)

It is intended to provide a free voltage multi-charging device for batteries that can charge various voltages and types of electronic product batteries with one charger.

The disclosed content as an embodiment is formed in the shape of a rectangular surface having a length in one direction, one or more charging sockets are formed on one side of the longitudinal direction, and a display for displaying the charging status is provided on the upper surface, and external power and power supply A charger main body connected to be supplied and one end of which is detachably coupled by magnetic force to the charging socket side, but a mounting groove in which a battery is detachably mounted is formed on the upper surface, and the mounting groove when coupled to the charging socket side One or more charging kits for charging the battery installed therein, and when the charging kit is provided in the charger body and coupled to the charging socket side, the charging voltage and charging condition of the battery installed in the mounting groove are determined A free voltage multi-charging device for a battery including a control unit for supplying power required for charging after determination from the charger main body is described.

According to the pre-voltage multi-charging device for batteries as described above, a plurality of charging kits in which different voltages and types of batteries can be mounted can be rechargeably combined in one charger body. It has an excellent effect that the battery can be charged.

1 is a perspective view of a free voltage multi-charging device for a battery according to an embodiment of the disclosed content.
2 is an exploded perspective view of a free voltage multi-charging device for a battery according to an embodiment of the disclosed content.
3 is another exploded perspective view of a free voltage multi-charging device for a battery according to an embodiment of the disclosed content.
4 is a use state diagram of a free voltage multi-charger for a battery according to an embodiment of the disclosed content.

Advantages and features of the disclosed content, and a method of achieving them will be apparent with reference to the embodiments described later in detail together with the accompanying drawings. However, the disclosed content is not limited to the embodiments disclosed below, but may be implemented in a variety of different forms, and only these embodiments are intended to complete the disclosure of the disclosed content, and provide common knowledge in the technical field to which the disclosed content belongs. It is provided to completely inform the scope of the disclosed content to the holder, and the disclosed content is only defined by the scope of the claims. The same reference numerals refer to the same elements throughout the specification.

In describing embodiments of the disclosed content, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the disclosed content, a detailed description thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in an embodiment of the disclosed content and may vary according to an operator's intention or custom. Therefore, the definition should be made based on the contents throughout this specification.

1 to 4 illustrate one embodiment according to the disclosed content. 1 is a perspective view, FIGS. 2 and 3 are exploded perspective views, and FIG. 4 is a use state diagram.

Hereinafter, a constituent member of the pre-voltage multi-charger 1 for a battery according to an embodiment of the present disclosure and a connection relationship thereof will be described in detail with reference to FIGS. 1 to 3.

First, referring to FIG. 1, a charger body 10 is provided. The charger body 10 serves to be coupled to the charging kit 20 to be described later and the battery 40 to be rechargeable. The charger body 10 is formed in a rectangular shape having a length in one direction, and one or more charging sockets 11 are formed on one side in the length direction.

In addition, a display 13 is provided on the upper surface of which the state of charge is displayed, and a power cable 14 connected to an external power source so as to supply power is provided on one side thereof. At this time, one end of the power cable 14 is coupled to the charger body 10 side, and the other end is formed in the shape of a USB terminal and can be coupled to a PC or laptop computer, or an adapter that can be coupled to a capacitor is coupled to the USB terminal, and this adapter is a 220V condenser. Can also be combined with The two batteries 40 can be simultaneously or individually charged through the power cable 14, but the charging voltage may be adjusted and supplied to an optimum charging voltage required for each battery.

The above-described charger body 10 is formed in a rectangular parallelepiped shape having a length in one direction, because the charging socket 11 is arranged along one side of the charger body 10, depending on how many charging sockets 11 are formed. Its length can be varied in various ways. And in the disclosed content, it is assumed that the charging socket 11 is formed along one side of the charger body 10 so that the shape is formed in a rectangular shape, but the charger body 10 is formed in a cube shape and not only one side. It goes without saying that the charging socket 11 may be formed on two or more sides.

The above-described power cable 14 is electrically connected to the control unit 30 to be described later, and the control unit 30 is also electrically connected to the display 13. The above-described display displays information related to charging, such as charging status and charging time, for each charging kit 20, and a separate alarm may be activated when fully charged.

In addition, the above-described charging sockets 11 are all formed of the same size, but the charging socket 11 includes a first charging terminal 12 electrically connected to the control unit 30, and the first charging terminal 12 ) Is connected to the second charging terminal 21 to be described later so that power required for charging the battery 40 is supplied.

All of the first charging terminals 12 are formed of the same standard so that the second charging terminal 21 to be described later can also be detachably inserted into the first charging terminal 12. It should be done. In addition, the first charging terminal 12 is formed to be recessed into the inside and the second charging terminal 21 is formed to protrude so as to be inserted into the first charging terminal 12, of course, the opposite may be formed.

In addition, a metal member 15 is provided in the above-described charging socket 11, which serves to be coupled to the charging kit 20 by magnetic force. The charging socket 11 is formed in the shape of a groove that is concave therein, and this is to allow one end of the charging kit 20 to be coupled in a state inserted therein.

In the disclosed content, one end of the charging kit 20 in the charging socket 11 is magnetically coupled or press-fit, and separately, the first charging terminal 12 and the second charging terminal 21 are detachably coupled. However, the charging socket 11 and the charging kit 20 are not coupled, and the first charging terminal 12 and the second charging terminal 21 may be detachably coupled by magnetic force or press-fitting alone.

Next, referring to FIGS. 2 and 3, a plurality of charging kits 20 are detachably coupled to the above-described charging socket 11 side by magnetic force. The charging kit 20 serves to charge the battery 40 by being coupled into the charging groove of the charger body 10 while one of the batteries 40 of various voltages and types is mounted in the mounting groove 22 Do it. To this end, the charging kit 20 has one end of which is detachably coupled to the charging socket 11 side by magnetic force, and a mounting groove 22 in which the battery 40 is detachably mounted is formed on the upper surface of the charging kit 20. In addition, at one end of the charging kit 20, a second charging terminal 21 electrically connected to the first charging terminal 12 is provided.

The mounting grooves 22 of the plurality of charging kits 20 described above are formed in different shapes so that batteries 40 of different voltages and types can be selectively mounted. For example, one charging kit 20 mounting groove 22 is formed in a shape in which the battery 40 for a digital camera can be mounted, and the other charging kit 20 mounting groove 22 is for a vacuum cleaner. It is formed in a shape in which the battery 40 can be mounted. Therefore, the user can easily charge the battery 40 of various voltages and types by preparing one charger body 10 and a plurality of charging kits 20 having mounting grooves 22 of different shapes required.

In addition, a third charging terminal 23 is provided in the above-described mounting groove 22 to be electrically connected to the battery 40 when the battery 40 is mounted. The third charging terminal 23 may have different positions and sizes depending on the battery 40 coupled to the inside of the mounting groove 22.

In addition, at one end of the above-described charging kit 20, a metal member 15 provided in the charging socket 11 and a magnetic body exerting an attractive force are provided, so that the charging kit 20 is detachable by magnetic force in the charging socket 11 Are combined. Therefore, the charging kit 20 can be stably coupled to the charging socket 11 by magnetic force, and at this time, charging can be performed while the first charging terminal 12 and the second charging terminal 21 are also stably connected. have.

In an embodiment of the disclosed content, it is assumed that the charging socket 11 and the charging kit 20 are coupled by magnetic force between the metal member 15 and the magnetic body, but one end of the charging kit 20 is press-fit into the charging socket 11. It may also be detachably coupled.

Meanwhile, the controller 30 is provided in the above-described charger body 10. The control unit 30 serves to immediately determine the charging voltage and charging condition of the battery 40 mounted in the mounting groove 22, and through this, the power required for charging is supplied from the charger main body 10.

That is, when the charging kit 20 in which the battery 40 is mounted is coupled into the charging groove of the charger body 10 or the charging kit 20 in which the battery 40 is mounted is coupled into the charging socket 11, the controller 30 ) Detects this and passes a minute current to analyze the charging voltage and type of the corresponding battery 40. When the analysis is completed, a charging voltage suitable for the result is supplied so that the battery 40 is charged.

In addition, the above-described control unit 30 may further include a function of predicting the life of the battery 40. That is, the battery 40 predicted that the controller 30 measures the AC impedance of the battery 40 by applying an AC signal having a single frequency to the battery 40 side and predicts the life of the battery 40 by using this The lifetime of may be displayed on the displayer 13 described above. Since the battery life prediction method using such an AC signal is a known technology, further detailed description will be omitted for the sake of simplification of the specification.

Hereinafter, a method of using the pre-voltage multi-charger 1 for a battery according to an exemplary embodiment of the present disclosure will be described in detail with reference to FIG. 4.

First, the power cable 14 of the charger main body 10 is connected to an external power source so that power can be supplied from an external power source. Then, by selecting a charging kit 20 suitable for the type of battery 40 required for charging, the battery 40 is coupled into the mounting groove 22 of the charging kit 20. At this time, the battery 40 is connected to be rechargeable to the third charging terminal 23 in the mounting groove 22.

Then, the charging kit 20 is coupled into the charging groove of the charger body 10, at which time the magnetic material provided at one end of the charging kit 20 and the metal member 15 provided in the charging groove are fixed by magnetic force. . At the same time, the second charging terminal 21 of the charging kit 20 and the first charging terminal 12 in the charging socket 11 are electrically connected.

When the combination is completed, the voltage and type of the battery 40 is analyzed by the controller 30, and when the analysis is completed, a charging voltage suitable for the result is supplied and the battery 40 starts to be charged. During charging, the charging status is displayed through the display 13, and when charging is finished, the charging completion is notified by an alarm.

According to the free voltage multi-charger 1 for a battery as described above, a plurality of charging kits 20 in which different voltages and types of batteries 40 can be mounted in one charger body 10 can be charged. Since it can be combined, various voltages and types of batteries 40 can be charged with one charging device.

The disclosed content is only an example, and a person skilled in the art can be modified in various ways by a person of ordinary skill without departing from the gist of the claims claimed in the claims, so the scope of protection of the disclosed content is limited to the specific implementation described above. It is not limited to examples.

1: Free voltage multi-charger for battery
10: charger body
11: charging socket
12: first charging terminal
13: displayer
14: power cable
15: metal member
20: charging kit
21: second charging terminal
22: mounting groove
23: 3rd charging terminal
30: control unit
40: battery

Claims (6)

A charger body formed in a rectangular shape having a length in one direction, one or more charging sockets formed on one side of the longitudinal direction, a displayer indicating a charging state on an upper surface thereof, and connected to an external power supply to enable power supply;
As long as one end thereof is detachably coupled to the charging socket side by magnetic force, a mounting groove is formed on the upper surface to allow the battery to be detachably mounted, and the battery mounted in the mounting groove is charged when the battery is attached to the charging socket side. More than one charging kit; And
A control unit provided in the charger body and configured to determine the charging voltage and charging condition of the battery mounted in the mounting groove when the charging kit is coupled to the charging socket side, and supply power required for charging after the determination from the charger body Free voltage multi-charging device for a battery containing;
The method according to claim 1,
A battery free, characterized in that a first charging terminal electrically connected to the control unit is provided in the charging socket, and a second charging terminal electrically connected to the first charging terminal is provided at one end of the charging kit. Voltage multi-charging device.
The method according to claim 2,
A metal member is provided in the charging socket, and a magnetic material that exerts attraction to the metal member is provided at one end of the charging kit, so that the charging kit is detachably coupled to the charging socket by magnetic force, and the charging kit is The pre-voltage multi-charge device for a battery, characterized in that when coupled to the charging socket, the first charging terminal and the second charging terminal are electrically connected to be rechargeable.
The method according to claim 2,
One end of the charging kit is detachably coupled to the charging socket by a press-fitting method, and when the charging kit is coupled to the charging socket, the first charging terminal and the second charging terminal are electrically connected to be charged. Free voltage multi-charging device for batteries.
The method according to claim 3 or 4,
The mounting grooves of the plurality of charging kits are formed in different shapes so that batteries of different voltages and types can be selectively mounted.
The method of claim 5,
A free voltage multi-charging device for a battery, characterized in that a third charging terminal is provided inside the mounting groove to be electrically connected to the battery when the battery is mounted.

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