KR910005691Y1 - Charging confirmation circuits of battery - Google Patents

Abstract

No content.

Description

Battery charge status check circuit

1 is a circuit diagram of the present invention.

2 is an input / output waveform diagram of a timer.

Truth table of third-degree code converter.

* Explanation of symbols for main parts of the drawings

A ₁ , A ₂ , A ₃ ... AND gate I _{1 to} I ₅ : inverter

FF ₁ -FF ₄ : Flip-flop D ₁ -D ₇ : Diode

LD ₁ -LD ₈ : light emitting diodes R ₁ , R ₂ , R ₃ ...

Q _{1 to} Q ₁₀ : transistor B ⁺ : power supply

RY ₁ , RY ₂ : relay 1: charging circuit

2: oscillator 3: timer

4: analog to digital converter 5: battery

6: latch 7: code converter

8: display unit

The present invention relates to a battery charge status check circuit that displays by lighting the level of the voltage charged in the battery with a light emitting diode so as to visually check the state of charge of the battery.

In the past, there was no circuit to indicate the state of charge when charging the battery, so it was impossible to check how much the state of charge was, so it was overcharged or undercharged. There was.

In view of the above, the present invention is a battery charge state check circuit that displays the state of charge of a battery as a light emitting diode. It displays the charging status according to the number of light-emitting diodes. When charging is completed, the relay is cut off to finish the charging operation.

This will be described in detail with reference to the accompanying drawings.

1 is a circuit diagram of the present invention, a relay (RY ₁ ) (RY ₂ ) between the charging circuit (1) and the battery (5) and the output of the oscillator (2) passes through the tie (3) At the same time as the strobe 6, it is applied to the transistor Q ₂ through the resistor R ₂ to control the relay RY ₂ .

The analog signal applied from the relay RY ₂ is converted into a digital signal by the analog digital converter 4 and the inverters I ₁ -I ₅ , the end gates A ₁ -A ₈ , and the flip-flop FF ₁ − After applying to the latch 6 composed of FF ₄ ), the output of the latch 6 passes through a sign converter 7 composed of an end gate A ₉ -A ₁₆ and a diode D ₁ -D ₇ . ^The light emitting diodes LD ₂ -LD ₅ are turned on in the display unit 8 including the resistors R ₃ -R ₁₈ , ⁺ transistors Q ₃ -Q ₁₀ , and the light emitting diodes LD ₁ -LD ₈ applied thereto. Configure the number to control. In addition, the AND gate A ₁₇ is connected to the output side of the latch 6 to configure the relay RY ₁ through the resistor R ₁ and the transistor Q ₁ .

The present invention configured as described above allows the output of the charging circuit 1 to be charged to the battery 5 through the relays RY ₁ and RY ₂ when the battery 5 is charged in the circuit diagram of FIG. 1. when driving the oscillator (2) to determine the state there is an output side, the third degree output 21 of the second degree output (a) is displayed is input to the timer 3, a timer 3 are displayed this time t ₁ is The charging confirmation time and t ₂ indicates the charging time. At this time, a high pulse during the charging confirmation time (t ₁ ) is applied to the latch 6 to strobe, and at the same time, a transistor (R ₂ ) is applied through the resistor (R ₂ ). Q ₂ ) becomes conductive.

Accordingly, the relay RY _{2 to} which the power supply B ⁺ is applied operates the battery 5 to stop charging and the charged voltage is applied to the analog digital converter 4 to convert the analog signal into a digital signal. 6 is applied to the AND gate A ₁₇ and the sign converter 7 through the inverters I ₁ -I ₅ , the AND gates A ₁ -A ₈ , and the flip-flop FF ₁ .

Therefore, the code converter 7 controls the number of lights of the light emitting diodes LD _1- LD ₈ of the display unit 8 by the truth table as shown in FIG.

That is, the number of light emitting diodes LD ₁ to LD ₈ of the light emitting diodes LD ₁ to LD ₈ varies according to the charging voltage level of the battery. At this time, the strobe of the latch 6 receives a second high pulse. Until the first high pulse comes to pass the signal latched to the signal converter (7).

When the battery 5 is fully charged, the output of the latch 6 becomes "1, 0, 0, 0", so that the light emitting diodes LD ₁ -LD ₈ of the display unit 8 are passed through the sign converter 7. At the same time, the lighting circuit ₁ is applied to the AND gate A ₁₇ and conducts the transistor Q ₁ through the resistor R ₁ to operate the relay RY ₁ to which the power supply B ⁺ is applied. The battery 5 is opened so that charging operation is no longer performed.

As described above, the present invention constitutes a relay (RY ₁ ) (RY ₂ ) between the charging circuit 1 and the battery 5 so that the battery 5 at the time of the output pulse passing through the tie 3 from the oscillator 2 ) Charge state of the battery 5 by lighting the light emitting diodes LD _1- LD ₈ on the display unit 8 via the analog digital converter 4, the latch 6, and the code converter 7. When the charging is completed, the relay RY ₁ operates by conducting the transistor Q ₁ through the AND gate A ₁₇ to stop the battery 5 and the charging circuit 1 to stop the charging operation. The user can easily know the voltage level charged in the battery (5) by the number of lighting of the light emitting diodes (LD ₁ -LD ₈ ), and when the charging is completed, the battery (5) and the charging circuit (1) are cut off and used. It is easy to confirm how much the charging voltage of (5) is so that the overcharge and overdischarge of the battery (5) It can be prevented.

Claims (1)

In the battery charging circuit in which the battery 5 is connected to the charging circuit 1, a relay RY ₁ (RY ₂ ) is formed between the charging circuit 1 and the battery 5, and the timer 3 in the oscillator 2 is used. Output through the transistor (6) and at the same time to control the relay (RY ₂ ) through the transistor (Q ₂ ) and to the relay (RY ₂ ) analog digital converter (4) and latch (6) and The sign converter 7 is connected to control the display unit 8 including the resistors R ₃ -R ₁₈ , the transistors Q ₃ -Q ₁₀ , and the light emitting diodes LD ₁ -LD ₈ , and then the latches 6 Battery charging status checking circuit configured to control the relay (RY ₁ ) with the transistor (Q ₁ ) by connecting the AND gate (A ₁₇ ) to the ().