KR20120119165A - Battery remaining voltage discharging apparatus - Google Patents

Abstract

PURPOSE: A battery residual voltage discharge device is provided to efficiently reduce discharge time of a residual voltage without increasing the amount of female current. CONSTITUTION: A reverse connection preventing part(30) transfers power of a battery to a main circuit part(20) according to a connection state of the battery. If the battery is detached, a switch is turned on. A discharging resistor(R) is arranged between the switch and a ground. A residual voltage discharging part(40) discharges residual voltage through the switch. [Reference numerals] (10) Battery part; (20) Main circuit part

Description

Battery residual voltage discharge device {BATTERY REMAINING VOLTAGE DISCHARGING APPARATUS}

The present invention relates to a battery residual voltage discharge device for solving a problem that may occur due to the residual voltage remaining when the battery is removed, and more particularly, remaining when the battery is removed without causing an increase in the amount of dark current. The present invention relates to a battery residual voltage discharge device having a structure capable of effectively shortening the discharge time for discharging the residual voltage.

In general, there are two types of power sources for operating each electric device of the vehicle, a battery and a charging system.The engine is powered by the charging device when the engine is running and by the battery when the engine is stopped or started. Is supplied.

As such, the electronic device in a vehicle using a battery uses a large capacitance for the purpose of suppressing the positive power surge that may occur in the power stage due to motors or various actuators when the power stage is designed. The reverse connection prevention circuit using a diode is used to cut off the electricity supply.

In addition, the conventional electronic device in the vehicle as described above uses a residual voltage discharge circuit for discharging the residual voltage in order to solve the problem that may occur due to the internal residual voltage remaining when the battery is replaced or removed. .

Referring to FIG. 1, in particular, the conventional electronic device, the residual voltage discharge circuit cuts off current when the capacitor C1 and the battery 10 are connected in reverse to suppress a sudden increase in positive power. In order to provide a diode D1, the battery 10 has a discharge path through a separate discharge resistor R1 for discharging the remaining voltage remaining at the rear end c of the diode D1 when the battery 10 is removed.

Accordingly, in the conventional residual voltage discharge circuit, the positive electrode (+) of the battery 10 is connected to the positive power supply terminal (a) of the power cable, and the negative electrode (-) of the battery 10 is connected to the negative power supply terminal (b) of the power cable. When normally connected to the power of the battery 10 is provided to the main circuit unit 20 through the diode (D1). On the other hand, the residual voltage remaining at the rear end c of the diode D1 when the battery 10 is removed is discharged through the discharge path.

As described above, in the residual voltage discharge circuit using the discharge resistor R1, the discharge time can be shortened by adjusting the resistance value of the discharge resistor R1. However, when the discharge time is shortened by adjusting the resistance value of the discharge resistor R1. This can cause problems in satisfying the leakage current limit.

That is, in the conventional residual voltage discharge circuit, when the resistance value of the discharge resistor R1 is reduced to shorten the discharge time, the amount of dark current increases accordingly. There is this.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a reverse connection preventing unit for transmitting the power of the battery to the main circuit unit according to whether or not the normal connection state of the battery, and the reverse connection prevention The battery includes a switch interposed between the first branch point and the ground between the unit and the main circuit unit and turned on when the battery is removed, and a discharge resistor R interposed between the switch and the ground. A battery residual voltage discharge device including a residual voltage discharge unit for discharging the voltage remaining on the rear end of the reverse connection prevention unit through the switch and the discharge resistor (R) upon removal of It is to effectively shorten the discharge time for discharging the remaining voltage remaining when the battery is removed without increasing the problem.

Battery residual voltage discharge apparatus according to a first aspect of the present invention for achieving the above object is a reverse connection preventing unit for transmitting the power of the battery to the main circuit unit according to whether the state of normal connection of the battery; And a switch interposed between the first branch point between the reverse connection preventing part and the main circuit part and the ground to be turned on when the battery is removed, and a discharge resistance R interposed between the switch and the ground. And a residual voltage discharge part configured to discharge the voltage remaining behind the reverse connection prevention part through the switch and the discharge resistor R when the battery is removed.

Preferably, the residual voltage discharge unit is based on a resistor unit having a plurality of resistors (R) for distributing the power applied interposed between the front end of the reverse connection prevention unit and the ground, and based on the distributed power supply by the resistor unit. And a transistor as the switch to be switched and the discharge resistor (R).

Preferably, the resistor unit, when the battery is normally connected, the distribution power becomes a specific voltage level, the switch is turned off, and when the battery is removed, the distribution power becomes the ground level so that the switch is turned on. on).

Accordingly, according to the battery residual voltage discharge device of the present invention, the discharge current is not connected when the battery is normally connected, but the discharge path is connected / formed only when the battery is removed, so that the residual voltage is discharged, thereby increasing the amount of dark current. It is possible to effectively reduce the discharge time of the remaining voltage remaining when the battery is removed without problems.

1 is a view showing a conventional residual voltage discharge circuit.
2 is a view showing a battery residual voltage discharge device according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

2 is a view showing a battery residual voltage discharge device according to a preferred embodiment of the present invention.

As shown in FIG. 2, the battery residual voltage discharge device according to the present invention includes a reverse connection preventing unit configured to transfer power of the battery 10 to the main circuit unit 20 depending on whether the connection state of the battery 10 is normal. A switch interposed between the first branch point and the ground between the reverse connection preventing unit 30 and the main circuit unit 20 and the battery 10 when the battery 10 is removed, between the switch and the ground. Discharge resistance (R) interposed therebetween, when the battery 10 is removed through the switch and the discharge resistance (R) on the voltage remaining on the rear end of the reverse connection prevention unit 30 (on) The remaining voltage discharge part 40 which discharges is included.

The battery 10 is preferably a vehicle battery connected to / used by a vehicle. There are two types of powers for operating each electric device of the vehicle, a battery 10 and a charging device. The engine supplies power from the charging device when the engine is running, and the power from the battery 10 when the engine is stopped or started. Is supplied.

The power by the vehicle battery 10 is provided to each electric device of the main circuit unit 20 by a power cable connected between the battery 10 and the main circuit unit 20 on which the electric devices are mounted / included.

The reverse connection prevention unit 30 transmits the power of the battery 10 to the main circuit unit 20 according to whether the connection state of the battery 10 is normal.

That is, the reverse connection prevention unit 30 controls the transmission path of the battery 10 power depending on whether the connection state of the battery 10 is normal connection or reverse connection.

In more detail, the reverse connection prevention unit 30 includes an anode and a main connected to the positive connection terminal of the power cable to which the positive electrode (+) of the battery 10 is connected when the battery 10 is normally connected. It may include a diode (D2) having a cathode connected to the circuit portion 20.

Accordingly, as shown in FIG. 2, the diode D2 as the reverse connection preventing unit 30 is connected to the positive terminal of the power cable to which the positive electrode of the battery 10 is connected when the battery 10 is normally connected. An anode is connected to (a) and a cathode is connected to the main circuit unit 20.

Therefore, when the positive electrode (+) of the battery 10 is normally connected to the positive power connection terminal (a) of the power cable and the negative electrode (-) of the battery 10 is normally connected to the negative power connection terminal (b) of the power cable, The power of 10 will be transmitted / provided to the main circuit unit 20 through the diode D2 as the reverse connection prevention unit 30.

Of course, when the reverse connection of the battery 10, that is, the positive electrode (+) of the battery 10 is connected to the negative power connection terminal (b) of the power cable and connected in reverse, the power of the battery 10 is reverse connection prevention unit 30 It will not flow through the diode D2 as) and will not be delivered / provided to the main circuit unit 20.

As described above, the remaining voltage discharge part 40 includes a switch part interposed between the first branch point d between the reverse connection preventing part 30 and the main circuit part 20 and the ground, and a resistance as a discharge resistance ( R4), the battery 10 is discharged through the switch and the discharge resistor (R4) to be turned on (on) the voltage remaining in the rear end of the reverse connection prevention unit 30 when removing.

More specifically, the residual voltage discharge unit 40 may include a resistor unit including a plurality of resistors R for distributing power applied between the front end f and the ground of the reverse connection preventing unit 30. 42 and a transistor as a switch to be switched based on the distributed power supply by the resistor 42 and the discharge resistor R4.

Here, the transistor as a switch belonging to the residual voltage discharge unit 40 preferably includes a pnp-type Bipolar Junction Transistor (BJT) as shown in FIG. 2.

That is, the residual voltage discharge portion 40 includes a resistor portion 42 having a plurality of resistors R arranged in series between the front end f of the reverse connection prevention portion 30 and the ground, and a discharge resistance. And a base end connected to the second branch point e between the resistors R of the resistor unit 42 as a switch, and between the reverse connection preventing unit 30 and the main circuit unit 20. It may include a pnp-type BJT (T1) having an emitter terminal (Emitter) connected to the first branch point (d) and a collector terminal (Collector) connected to the discharge resistor (R4).

In other words, as shown in FIG. 2, the residual voltage discharge unit 40 distributes power applied in series between the front end f and the ground of the diode D2 as the reverse connection preventing unit 30. The resistor unit 42 includes a plurality of resistors R2 and R3.

Here, in the resistor unit 42, when the battery 10 is normally connected, the second branch point e becomes a specific voltage level, so that the switch T1 having a base connected to the second branch point e is turned off. When the battery 10 is removed, the second branch point e becomes the ground level so that the switch T1 is turned on.

To this end, the resistor unit 42 is configured such that when the battery 10 is normally connected, the second branch point e becomes above a specific voltage level so that the switch T1 is turned off, that is, the switch T1 is not forward biased. It is desirable to combine / design it with a resistance value of several hundred k ohms.

The remaining voltage discharge part 40 includes a base end connected to the second branch point e between the resistors R of the resistor part 42 and the reverse connection preventing part 30 and the main circuit part 20. Pnp-type BJT (T1), that is, switch T1, having an emitter terminal connected to the first branch point d between and a collector terminal connected to the discharge resistor R4; Resistor R4.

That is, the switch T1 of the residual voltage discharge part 40 has a base end connected to the second branch point e and an emitter end connected to the first branch point d between the diode D2 and the main circuit unit 20. The discharge resistor R4 is connected to the collector terminal.

Therefore, when the battery 10 is normally connected, the second branch point e becomes a specific voltage level, and the switch T1 connected to the base end of the second branch point e is turned off. The discharge path made of the dedicated resistor R4 is not connected / formed.

When the battery 10 is removed, the second branch point e becomes the ground level and the switch T1 is turned on, so that the discharge path consisting of the switch T1 and the discharge resistor R4 is connected / formed. do. Therefore, the remaining voltage remaining at the rear end c of the diode D2 when the battery 10 is removed is discharged through the discharge path including the switch T1 and the discharge resistor R4.

According to the battery residual voltage discharge device of the present invention as described above, when the battery 10 is normally connected, the switch T1 of the residual voltage discharge unit 40 is turned off so that a discharge path is not connected to the battery 10. Since the switch T1 is turned on only when it is removed, the discharge path is connected and the residual voltage is discharged. Thus, even when the resistance value of the discharge resistor R4 is adjusted to shorten the discharge time, except when the battery 10 is removed. In this case, since the discharge path is not connected, the problem of increasing the dark current amount due to the adjustment of the resistance value of the discharge resistor R4 will not occur.

As described above, in the battery residual voltage discharge device according to the present invention, the discharge path is not connected when the battery is normally connected, and the discharge path is connected / formed only when the battery is removed, thereby suggesting a structure in which the residual voltage is discharged. It is possible to effectively shorten the discharge time of the residual voltage remaining when the battery is removed without causing an increase in the amount of dark current.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

The discharge voltage is not connected when the battery is normally connected, and the discharge path is connected / formed only when the battery is removed, so that the remaining voltage discharges, suggesting a structure in which the residual current remains when the battery is removed without increasing the amount of dark current. The application of the battery residual voltage discharge device, which shortens the discharge time of the battery, can bring about great advances in terms of device stability, malfunction prevention, and power efficiency. can do.

10: Battery
20: main circuit
30: state detection unit
40:

Claims (3)

A reverse connection preventing unit for transferring the power of the battery to the main circuit unit according to whether the connection state of the battery is normal; And
A switch interposed between the first branch point and the ground between the reverse connection preventing part and the main circuit part and turned on when the battery is removed, and a discharge resistance R interposed between the switch and the ground. And a residual voltage discharge part configured to discharge the voltage remaining at the rear end of the reverse connection prevention part through the switch and the discharge resistance R when the battery is removed. Discharge device. The method of claim 1,
The remaining voltage discharge unit,
A resistor having a plurality of resistors R for distributing power applied between the front end of the reverse connection preventing portion and the ground; a transistor as the switch switched based on the distributed power by the resistor; Battery residual voltage discharge device comprising a dedicated resistor (R). The method of claim 2,
The resistance unit,
When the battery is normally connected, the distribution power becomes a specific voltage level so that the switch is turned off, and when the battery is removed, the distribution power becomes ground level so that the switch is turned on. Battery residual voltage discharge device.

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