KR20020007115A - A method for charging lithium ion secondary battery by solar battery, and apparatus for charging as solar battery of secondary battery - Google Patents

Abstract

PURPOSE: A method for charging a lithium-ion secondary battery using a solar cell and a solar-cell-type charger for a lithium secondary battery are provided to charge a lithium-ion secondary battery by a small output current of a solar cell. CONSTITUTION: A condensing unit(12) is charged with a DC current output from a solar cell(10). A potential difference between the condensing unit(12) and a lithium-ion secondary battery(14) is checked. When the potential difference is higher than a predetermined voltage value(Vref), specifically, when the condensing unit(12) is charged by the solar cell(10) and only the voltage value(Vref) except a voltage of the lithium-ion secondary battery(14) is increased, the condensing unit(12) and the lithium-ion secondary battery(14) are electrically connected. As for the voltage value(Vref), it should be considered the condensing unit(12), the lithium-ion secondary battery(14), and an internal resistance of a current path flowing while a charging is performed with respect to the lithium-ion secondary battery(14). The voltage value(Vref) should be set to be a value capable of charging the lithium-ion secondary battery(14) in the pertinent path.

Description

A method for charging a lithium ion secondary battery using a solar cell and a solar cell type charging device for an lithium ion secondary battery

The present invention relates to a method for charging a lithium ion secondary battery using a solar cell and a solar cell type charging device for a lithium ion secondary battery.

Currently, lithium secondary batteries are widely used in various portable terminals including personal computers and mobile phones because of the fact that rechargeable secondary batteries do not contain harmful substances such as carbonium and should be suitable for long-term continuous use and light weight. have. In order to charge a lithium ion secondary battery, it is common to charge with a commercial power supply (AC100V) with a large output energy, an automobile battery, or the like. This is because a large current of several hundred mA is required to charge the lithium ion secondary battery.

On the other hand, among the computers, a notebook computer or a portable terminal is usually used with a user. For this reason, it wants to charge the lithium ion secondary battery built in such a device even in a place where commercial power is not available, and it wants a means which can charge other than a commercial power supply (AC100V) or the battery of an automobile.

Therefore, the idea is that a solar cell that can be carried as compact and lightweight and can be easily converted into solar energy that can be used anywhere can be used as a charging means for a lithium ion secondary battery.

However, the output of each solar cell device is about 0.4 to 0.5 volts in voltage and about 25 mA per square centimeter in current, and it sends several hundred mA of current to a relatively high (3.6 volt) lithium ion secondary battery for charging. In order to secure a voltage by connecting a large number of cells in series and to connect a large number of cells in parallel, a solar cell becomes large and difficult to carry.

Therefore, the present invention has been made to solve the above problems, and an object thereof is to charge a lithium ion secondary battery even with a small output current of a solar cell, and to use a solar cell to charge a lithium ion secondary battery and a lithium ion. It is providing the solar cell type charging apparatus for secondary batteries.

BRIEF DESCRIPTION OF THE DRAWINGS It is a block diagram which shows the structure of one Embodiment of the solar cell type charging apparatus for lithium ion secondary batteries which concerns on this invention.

FIG. 2 is a circuit diagram showing a specific circuit example of FIG. 1.

Explanation of symbols on the main parts of the drawings

5 ..... Solar battery charger for lithium ion secondary battery

10 .... solar cell

12 .... Power storage means

14 .... Lithium Ion Secondary Battery

16 .... Charge control means

In order to achieve the above object, the present invention has the following configuration.

That is, in the method for charging a lithium ion secondary battery using the solar cell of the present invention, the potential difference between the power storage means and the lithium ion secondary battery is equal to or higher than a predetermined voltage value while charging the power storage means by a direct current output from the solar cell. In this case, the power storage means and the lithium ion secondary battery are electrically connected to each other to charge the lithium ion secondary battery by a direct current output from the power storage means.

In addition, the solar cell type charging apparatus for a lithium ion secondary battery of the present invention is disposed between a power storage means that is charged by a solar cell and a direct current output by the solar cell, and between the power storage means and a lithium ion secondary battery. When the potential difference between the power storage means and the lithium ion secondary battery becomes equal to or greater than a predetermined voltage value, the power storage means and the lithium ion secondary battery are electrically connected, and the lithium ion secondary battery is connected by a direct current output by the power storage means. Characterized in that it comprises a charging control means for charging.

According to the above structure, since the output current of the solar cell is accumulated by the storage means once, and the lithium ion secondary battery is charged from the power storage means, the one having a high current supply capability (for example, a small internal resistance) is selected. In this case, the lithium ion secondary battery can be sufficiently charged using the solar cell.

Embodiment of the Invention

EMBODIMENT OF THE INVENTION Hereinafter, the preferred embodiment of the method for charging a lithium ion secondary battery using a solar cell and the solar cell type charging apparatus for lithium ion secondary batteries is demonstrated in detail based on an accompanying drawing. It goes without saying that the present invention can be applied to secondary batteries other than lithium ion secondary batteries.

First, the outline | summary of the method of charging a lithium ion secondary battery is demonstrated using FIG.

The method checks the potential difference Vdef between the power storage means 12 and the lithium ion secondary battery 14 while charging the power storage means 12 with the direct current output by the solar cell 10.

In the case where the potential difference Vdef becomes higher than or equal to the predetermined voltage value Vref, the accumulating means 12 is charged by the solar cell 10 in more detail, and the voltage thereof is only the voltage value Vref than the voltage of the lithium ion secondary battery 14. When it becomes high, the electrical storage means 12 and the lithium ion secondary battery 14 etc. are electrically connected. The voltage value Vref takes into account the internal resistance of the current path flowing while charging the lithium ion secondary battery 14, such as the power storage means 12 or the lithium ion secondary battery 14, and the lithium ion secondary battery 14 in the corresponding path. ) Set the value that the current can flow as long as it can charge.

Thus, the lithium ion battery 14 is charged by the direct current output from the power storage means 12.

According to the present invention, since the output current of the solar cell 10 is once stored in the power storage means 12, and the lithium ion secondary battery 14 is charged in the power storage means 12, the current supply capability to the power storage means 12. By selecting this high one (for example, one having a low internal resistance and having a large capacity), the lithium ion secondary battery 14 can be sufficiently charged in the lithium ion secondary battery 14 by the power storage means 12. As much current as possible can flow.

The larger the capacity, the longer the current can be sent. Therefore, as a result, the lithium ion secondary battery 14 can be charged from the solar cell 10.

Next, one Embodiment of the solar cell type charging apparatus 5 for lithium ion secondary batteries which implements the said method is demonstrated using FIG. 1 and FIG.

First, the configuration will be described.

The electrical storage means 12 is implemented as an example using the capacitor C1.

The capacitor is inexpensive, and in particular, by using an electrolytic capacitor, it is possible to realize a small and large capacity power storage means 12. In fact, about 220 mW is enough to function as the power storage means of the present application. In addition, since the capacitor has a relatively small internal resistance, the capacitor prevents the charging current to the lithium ion secondary battery 14 from being limited to a low value.

The charging control means 16 includes switch means 16a retrofitted in series between the power storage means 12 and the lithium ion secondary battery 14, and the power storage means 12 and the lithium ion secondary battery 14. When the voltage difference Vdef between the < RTI ID = 0.0 >) < / RTI > and the predetermined voltage value Vref is equal to or higher than the predetermined value, the switch means 16a is turned ON, and the power storage means 12 and the lithium ion secondary battery 14 are electrically connected to each other. It can be configured with the means 16b.

Still, the p-type field effect transistor FET (hereinafter simply referred to as FET) 2 in FIG. 2 corresponds to the switch means 16a, and other circuit elements of the charge control means 16 are connected to the control means 16b. Is possible.

An example of a specific circuit of the charging control means 16 will be described with reference to FIG.

It goes without saying that the same function can be realized in other circuit configurations in addition to the circuit examples described below.

Between the power storage means 12 and the lithium ion secondary battery 14, a resistor R2, a FET2 and a diode D2 are connected in series in that order. In detail, the source terminal of FET2 is connected with the resistor R2, and the diode terminal of FET2 is connected with the anode of D2.

A bias resistor R3 is connected in parallel between the source terminal and the gate terminal of the FET2.

The power storage means 12 is connected to an emitter terminal of the transistor Tr1 (pnp type), and a resistor R1 for bias is connected between the collector terminal of the transformer Tr1 and ground. The capacitor C2 is connected in parallel with the resistor R1.

The gate terminal of the n-type FET1 is connected to the collector terminal of the transistor Tr1. The gate terminal of the n-type FET1 is connected to the collector terminal of this FET1. The drain terminal of this FET1 is connected to the gate terminal of FET2, and the source terminal is directly connected to ground.

The diode D1 is connected between the base terminal of the transistor TR1 and the drain terminal of the FET2 with the anode connected to the base terminal of the transistor Tr1.

Next, the operation of the solar cell type charging apparatus 5 for the lithium ion secondary battery will be described including the operation of the charge control means 16.

The solar cell 10 is directly connected with power storage means 12 in parallel. Therefore, the direct current generated when the solar cell 10 receives light is charged in the power storage means 12.

Then, the voltage of the power storage means 12 is further increased so that the potential difference Vdef with the lithium ion secondary battery 14 adds forward voltages Vd1 and Vd2 of the diodes D1 and D2 to the direction voltage Veb between the emitter base terminals of the transistor Tr1. When the voltage Vref is higher than or equal to, the current flows through the path of the emitter terminal → base thereof → D1 → D2 → lithium ion secondary battery 14 of transistor Tr1.

As a result, the transistor Tr1 is turned on, a current flows to the resistor R1 toward the ground, and a bias voltage is generated between the resistors R1, thereby applying a constant voltage to the gate terminal of the FET1.

As a result, the n-type FET1 is turned on, and a current flows through the path from the resistor R2 to the resistor R3 to the drain terminal of the FET1 to the source terminal of the FET1 to ground. Thus, a bias voltage is generated between the resistors R3 and the p-type FET2 is turned on by the bias voltage.

As a result, the power storage means 12 is directed toward the lithium ion secondary battery 14 to the lithium ion secondary battery 14 via the path of the resistor R2-> FET2 source terminal-> drain terminal-> diode D2-lithium ion secondary battery 14. Charge current flows.

The voltage Vref which adds the forward voltages Vd1 and Vd2 of the diodes D1 and D2 to the forward voltage Veb between the emitter base terminals of the transistor Tr1 is equal to that when the transistors Tr1 or diodes D1 and D2 are composed of silicon. Since the forward voltage is about 0.6-0.7 volts, it is about 2 volts in total.

Therefore, if the resistance R2 is set to about 10? As an example, the initial charging current can be set to about 200 mA, and sufficient current can be secured to charge the lithium ion secondary battery 14.

When a current starts to flow in the lithium ion secondary battery 14, the voltage of the electrical storage means 12 also falls with it, and the voltage difference Vdef of both becomes less than voltage Vref in a short time.

As a result, no current flows in the path of the emitter terminal → the base terminal → D1 → D2 → the lithium ion secondary battery 14 of the transistor Tr1, and the transistor Tr1 is turned off. As a result, FET1 is also turned off and FET2 is also turned off to stop the charging operation.

As a result, the flow of current from the power storage means 12 to the lithium ion secondary battery 14 is eliminated, and the power storage means 12 is rechargeable in the solar cell 10 again.

In the above operation, that is, the charging operation by the solar cell 10 to the power storage means 12 and the charging operation by the power storage means 12 to the lithium ion secondary battery 14, the voltage of the lithium ion secondary battery 14 is predetermined. Repeat until the voltage (approximately 3.6 volts-4 volts) is reached.

As a result of this, the lithium ion secondary battery 14 can be charged by the solar cell 10.

In the circuit example of the charging control means 16, there is no transistor and the reason for using the FET is that when the charging operation to the lithium ion secondary battery 14 is performed using a transistor instead of FET1 or FET2, the ON state is maintained. This is because a base current is required, and the base current flows to ground and becomes useless.

By using the FET, the current corresponding to the base current is reduced to about 2 mA and becomes a negligible value. Therefore, efficient charging becomes possible.

The diode D2 also has a function of preventing discharge from the lithium ion secondary battery 14 once charged to the charge control means 16 side.

The capacitor C2 prevents the gate voltage of the FET1 from decreasing instantaneously with the start of the charging operation from the power storage means 12 to the lithium ion secondary battery 14, and the FET1 once turned on for a certain amount of time. This is to maintain and preserve the bias voltage to maintain the state.

As an example, since the power storage means 12 or the charging control means 16 can be configured by the simple circuit configuration shown in Fig. 2, for example, a volume of lithium that can be sufficiently mounted in a mobile phone, for example. A solar cell charging device 5 for an ion secondary battery is feasible. Therefore, since the mobile phone is often used outside, when the solar cell 10 is exposed and mounted on the surface of the mobile phone, the built-in lithium ion secondary battery 14 can be charged using the solar cell 10. Talk time and standby time will also increase drastically, and the convenience of writing will be greatly improved.

When the method for charging a lithium ion secondary battery using the solar cell according to the present invention and the solar cell type charging device for a lithium ion secondary battery are used, the output current of the solar cell is once stored in the power storage means, and the lithium ion secondary battery Since the power storage means charges, selecting a high current supply capability (for example, a small internal resistance) to the power storage means has an effect that the lithium ion secondary battery can be sufficiently charged using a solar cell.

Claims (2)

While charging the power storage means by the direct current output by the solar cell, when the potential difference between the power storage means and the lithium ion secondary battery becomes more than a predetermined voltage value, the power storage means and the lithium ion secondary battery are electrically connected to each other. A method of charging a lithium ion secondary battery using a solar cell, characterized in that for charging the lithium ion secondary battery by a direct current output from the power storage means. Solar cells, Power storage means charged by a DC current output from the solar cell; Disposed between the power storage means and the lithium ion secondary battery, wherein the power storage means and the lithium ion secondary battery are electrically connected when the potential difference between the power storage means and the lithium ion secondary battery becomes equal to or greater than a predetermined voltage value; And a charge control means for charging the lithium ion secondary battery by a direct current output from a power storage means.