KR20010088503A - Battery charge apparatus for saving electricity - Google Patents

Abstract

PURPOSE: The power saving type battery charging equipment is provided, in which minimizes to consume power with operation of charging equipment on charging and interrupting power source which is input to rectifying part on standby for charging. CONSTITUTION: The power saving type battery charging equipment comprises a rectifier part(110) to output after rectifying input power source, a charging part(120) to charge multiple batteries through power source to be input from the rectifier part(110), a DC-DC converter(130) to output after generating constant voltage of constant level by receiving power source of a battery(B) or the charging part(120), an A/D converter(140) to output after transferring what detects charging power source of the battery(B) to digital signal, a CPU(150) to be operated by constant voltage input from the DC-DC converter(130), and a switching part(160) to input power source to the rectifier part(110) and interrupt power source after switching by switching signal to be output from the CPU(150). The CPU(150) outputs switching signal if digital signal is within specified range in comparison of digital signal to be output from the A/D converter(140) with stored data.

Description

Power-saving battery chargers {BATTERY CHARGE APPARATUS FOR SAVING ELECTRICITY}

The present invention relates to a battery charging device, and more particularly, when the charging device does not charge the actual battery by detecting the battery charging power and cutting off and supplying power applied to the rectifying unit of the charging device according to the size of the charging power. The present invention relates to a power saving battery charging device for preventing standby power consumption.

In general, the battery charging device receives power from a commercial power source (110 / 220V), rectifies the DC power through the rectifying unit, and charges the battery using the DC power rectified in the charging unit. Meanwhile, the charging unit turns on / off the charging according to the size of the charging power of the battery, and turns off the charging when the charging power of the battery is above a predetermined level.

However, such a conventional battery charger has a problem in that unnecessary current is consumed because current is always applied even when the battery is being charged.

Therefore, an object of the present invention for solving the above problems is to reduce the waste of power by minimizing the power consumption by driving the charging device only when charging, and cut off the power applied to the rectifier when the charging standby.

1 is a block circuit diagram schematically showing the configuration of a power saving battery charging device according to the present invention;

Figure 2 is a circuit diagram showing the configuration of the switching means of the power saving battery charging device according to the present invention

3 is a circuit diagram illustrating a configuration of a selection switching unit of a power saving battery charging device according to the present invention;

<Explanation of symbols for main parts of the drawings>

110: rectifying part 120: charging part

130: DC-DC converter 140: A / D converter

150: CPU 160: switching means

170: emergency switching means 180: selective switching unit

Features of the present invention for achieving the above object,

In the battery charging device including a rectifying unit for receiving commercial power and rectified and output, and a charging unit for charging a plurality of batteries through the power applied from the rectifying unit,

A DC-DC converter which receives the power of the battery or the power of the charging unit and generates and outputs a constant voltage of a predetermined level;

An A / D converter which detects the charging power of the battery and converts it into a digital signal and outputs the digital signal;

A CPU which is driven with a constant voltage applied from the DC-DC converter and outputs a switching signal when the digital signal output from the A / D converter is included in a predetermined range compared to previously stored data;

And switching means for switching the switching signal output from the CPU to apply and cut off commercial power to the rectifier.

Here, between the commercial power supply and the rectifier,

When the battery is shorted or discharged, an emergency switching means for switching according to an external operation to apply commercial power to the rectifier to apply the output power of the charging unit to the DC-DC converter is further provided.

Here also between the charging section and the DC-DC converter,

The control unit may further include a selection switching unit including a plurality of switches that are switched under the control of the CPU to supply charging power of the charging unit to a specific battery according to the priority of the plurality of batteries.

Here again, between each battery and the DC-DC converter,

Diodes are respectively connected in the forward direction to prevent the reverse current from being applied while the plurality of batteries are connected to the charging terminals.

Here again the CPU,

When the digital signal output from the A / D converter is equal to the full charge level of the battery, the switching means is turned off to block commercial power from being applied to the rectifier.

Here, the predetermined range is

The maximum charge voltage at the minimum charge voltage of the battery.

Hereinafter, a configuration of a power saving battery charging device according to the present invention will be described in detail with reference to FIGS. 1 to 3.

1 is a block circuit diagram schematically showing the configuration of a power saving type battery charging apparatus according to the present invention, Figure 2 is a circuit diagram showing a configuration according to an embodiment of a switching means of the power saving type battery charging apparatus according to the present invention, 3 is a circuit diagram illustrating a configuration according to an embodiment of a selection switching unit of a power saving type battery charging apparatus according to the present invention.

1 to 3, the power saving battery charging apparatus 100 according to the present invention includes a rectifier 110, a charger 120, a DC-DC converter 130, and an A / D converter 140. And the CPU 150, the switching means 160, the emergency switching means 170, and the selective switching unit 180.

First, the rectifier 110 receives the commercial power 110 / 220V and rectifies and outputs the charge. The charger 120 charges the plurality of batteries B through the power applied from the rectifier 110.

The DC-DC converter 130 receives the power of the battery B or the power of the charging unit 120 to generate and output a constant voltage of a predetermined level.

The A / D converter 140 detects the charging power of the battery B, converts it into a digital signal, and outputs the digital signal.

The CPU 150 is driven with a constant voltage applied from the DC-DC converter 130, and when the digital signal output from the A / D converter 140 is included in a predetermined range compared to the pre-stored data, the CPU 150 switches the switching signal. Output Herein, if the digital signal output from the A / D converter 140 is equal to the full charge level of the battery B, the CPU 150 turns off the switching means 160 so that the commercial power is applied to the rectifier 110. Block it. Here, the predetermined range is the maximum charging voltage at the minimum charging voltage of the battery (B).

In addition, the switching means 160 is switched by a switching signal output from the CPU 150 to apply and cut off commercial power to the rectifier 110. Here, the switching means 160 is composed of a photo triac 161 and a triac 162 as shown in FIG. 2. The photo triac 161 is turned on / off according to a switching signal output from the CPU 150, and used to circuitally separate the commercial power supply 110 / 220V and the rectifier 110, and the triac 162. Is linked to the on / off of the photo triac 161 to apply power to the rectifier 110, and is used to protect the switching element even under high voltage environment. Meanwhile, photo triac 161 and triac 162 are used here, but other switching elements, that is, transistors, diodes, relays, and the like, may be used.

When the battery B is shorted or discharged, the emergency switching unit 170 is switched according to external operation to apply the commercial power 110 / 220V to the rectifier 110 so that the output power of the charging unit 120 is DC-. It is connected in parallel to the input terminal and the output terminal to the switching means 160 to be applied to the DC converter 130, respectively. Here, the emergency switching means 170 is a dip switch or the like is used, it is preferably formed on the outside of the charging device body (not shown).

In addition, the selection switching unit 180 is switched under the control of the CPU 150 to supply the charging power of the charging unit 120 to the specific battery B1 or B2 according to the priority of the plurality of batteries B in FIG. 3. As shown, each switch SW1 and SW2 are connected between the charging unit 120 of each battery B and the DC-DC converter 130. On the other hand, the direction of the current is determined in a state where the plurality of batteries B are connected to the charging terminal (not shown), and that the charging current of one battery B1 is blocked from being applied to the other battery B2, that is, 3, diodes D1 and D2 having an anode connected to the + terminal of the batteries B1 and B2 and a cathode connected to the input terminal of the DC-DC converter 130 as shown in FIG. Each is provided.

Hereinafter, an operation of the power saving battery charging device according to the present invention will be described in detail with reference to FIGS. 1 to 3.

First, when the battery B is inserted into the charging terminal, the A / D converter 140 converts the voltage output from the battery B into a digital signal and outputs the digital signal to the CPU 150. The DC-DC converter 130 is operated by a power source output from the battery B to output a constant level constant voltage (a driving voltage of the CPU) to the CPU 150.

Then, the CPU 150 is driven by the power supplied from the DC-DC converter 130 to compare the digital signal input from the A / D converter 140 with previously stored data. Thus, if the voltage of the battery B is within a predetermined range as a result of the comparison, that is, when charging is required, the switching means 160 is turned on by outputting a high signal to the switching means 160. When the switching means 160 is turned on, commercial power (110 / 220V) is applied to the rectifying unit 110 and the charging unit 120, and the charging power is output from the charging unit 120. At this time, when the plurality of batteries B1 and B2 are present in the charging terminal, the CPU 150 controls the specific switch SW1 of the selection switching unit 180 according to the priority to charge the specific battery B1 with priority. Let's do it. In this case, since the specific switch SW1 of the selective switching unit 180 maintains the first on state, and the other switch SW2 maintains the first off state, the CPU 150 separates the specific switch SW1. Do not output the control signal.

When charging power is output from the charging unit 120, it is applied to the battery B through the selection switching unit 180 to charge the battery B.

In this state, the CPU 150 continuously checks the digital signal output from the A / D converter 140. At this time, if the battery B is fully charged and a digital signal exceeding a predetermined range is output from the A / D converter 140, the CPU 150 turns off the selective switching unit to turn off the operation of the DC-DC converter 130. . Then, the CPU 150 is turned off when the DC-DC converter 130 is turned off, the switching signal output from the CPU 150 becomes a low signal, and the switching means 160 is turned off, so that power to the entire circuit is completely turned off. In the entire circuit including the rectifying unit 110 and the charging unit 120 because the power is applied to the entire circuit including the rectifying unit 110 and the charging unit 120 is cut off at the same time because the charge of the battery (B) is stopped. No power is consumed

Meanwhile, since the A / D converter 140 and the DC-DC converter 130 are operated continuously by the power output from the battery B, the CPU 150 repeats the above process when the battery B is discharged again. The battery B is charged.

In addition, when the battery B is detached from the charging terminal and there is no current flow in the charging terminal of the battery B, the CPU 150 detects this and turns off the momentarily when the selection switching unit 180 is on, thereby turning off the DC-DC converter. The operation of 130 is turned off. Then, the CPU 150 is turned off in response to the DC-DC converter 130 being turned off, the switching signal output from the CPU 150 is turned low, and the switching means 160 is turned off, so that power to the entire circuit is completely shut off. There is no power consumption. Meanwhile, the selection switching unit 180 returns to the original on state.

In addition, when the battery B is short-circuit or natural discharge due to the complete discharge and the charging power falls below a certain level, when the user operates the emergency switching means 170 momentarily, the commercial power (110 / 220V) is the rectifier 110 And the charging unit 120, the charging power of the charging unit 120 is applied to the DC-DC converter 130.

When charging power is applied to the DC-DC converter 130, the DC-DC converter 130 is driven to output a constant voltage. Since the CPU 150 operates when the constant voltage is output from the DC-DC converter 130, the battery B is charged in the same manner as described above, and when the charging is completed, the power supply of the entire circuit is cut off.

Therefore, after full charge, the power supply is completely shut off and the battery is charged by checking the remaining charge of the battery using the charging power of the battery. It can eliminate the power consumption during the many charge standby.

As described above, according to the power-saving charging device according to the present invention, the charging device is driven only during charging and cuts off the power applied to the rectifying unit during charging standby, thereby minimizing power consumption of the charging apparatus during charging standby, thereby minimizing waste of power. Can be reduced.

In addition, the preferred embodiment of the present invention is disclosed for the purpose of illustration, those skilled in the art will be able to various modifications, changes, additions, etc. within the spirit and scope of the present invention, such modifications and changes should be considered to belong to the following claims. something to do.

Claims (6)

In the battery charging device including a rectifying unit for receiving commercial power and rectified and output, and a charging unit for charging a plurality of batteries through the power applied from the rectifying unit, A DC-DC converter which receives the power of the battery or the power of the charging unit and generates and outputs a constant voltage of a predetermined level; An A / D converter which detects the charging power of the battery and converts it into a digital signal and outputs the digital signal; A CPU which is driven with a constant voltage applied from the DC-DC converter and outputs a switching signal when the digital signal output from the A / D converter is included in a predetermined range compared to previously stored data; And switching means for switching by a switching signal output from the CPU to apply and cut off commercial power to the rectifier. The method of claim 1, Between the commercial power supply and the rectifier, When the battery is short-circuited or discharged completely, an emergency switching means for switching according to an external operation to apply commercial power to the rectifier to apply the output power of the charging unit to the DC-DC converter, characterized in that it is further provided Power saving battery charger. The method of claim 1, Between the charging unit and the DC-DC converter, A power saving battery charging device, characterized in that the switching further comprises a plurality of switches to switch under the control of the CPU to supply the charging power of the charging unit to a specific battery in accordance with the priority of the plurality of batteries. The method of claim 1, Between each battery and the DC-DC converter, And a diode is connected in the forward direction to prevent the reverse current from being applied while the plurality of batteries are connected to the charging terminal. The method of claim 1, The CPU, And when the digital signal output from the A / D converter is equal to the full charge level of the battery, the switching means is turned off to block application of commercial power to the rectifier. The method of claim 1, The predetermined range is And a maximum charging voltage at the minimum charging voltage of the battery.