DE29608208U1 - battery charger - Google Patents

Description

14580

Cardinal-Tech co., Ltd., Taiwan, Rep. China

battery charger Description

The present invention relates to battery chargers, and more particularly relates to a charger having a high impedance power supply circuit for charging a rechargeable battery when the impedance of the rechargeable battery is high, and a reverse battery monitoring circuit for outputting a warning signal via a light emitting diode when the rechargeable battery is reversely connected and at the same time delaying activation of the charging current to prevent a short circuit.

A variety of battery chargers have been developed to charge storage batteries. However, normal battery chargers can only charge normal storage batteries. If the impedance of a storage battery is excessively high, it cannot be charged by a normal battery charger 5. Furthermore, if the storage battery is connected in reverse or reverse polarity and the battery charger's power supply circuit is not turned off, a short circuit may occur.

Summary of the invention

According to one aspect of the present invention, the battery charger comprises a battery impedance monitoring circuit, which comprises the following features:

a diode and a series circuit consisting of an amplifier and a capacitor connected in parallel to the

to be charged, a battery voltage monitoring circuit comprising a transformer, a variable resistor and a comparator connected in series to the output side of the transformer, a constant current control circuit comprising a voltage controlled oscillator and a transistor coupled to the transformer, a low impedance power supply circuit and an inductor controlled by the constant current control circuit to charge the rechargeable battery, a high impedance power supply circuit connected in parallel to the low impedance power supply circuit and the inductor and then connected in series to a voltage divider circuit comprising a variable resistor connected in parallel to the rechargeable battery.

According to another aspect of the present invention, the constant current control circuit is connected to a current monitoring circuit which includes a comparator and a variable resistor, and a constant current monitoring circuit which is connected in parallel to the rechargeable battery and includes a divider circuit and an initial state monitoring circuit which includes an integrated delay circuit and a comparator.

According to still another aspect of the present invention, the constant current control circuit is provided with a reverse battery connection detection circuit connected in parallel to the rechargeable battery and comprising a light emitting diode and a series circuit consisting of a variable resistor and a comparator connected in parallel to the light emitting diode.

Short description of the drawings

Fig. 1 is a block diagram of a battery charger according to the present invention;

Fig. 2 is a circuit diagram of a charging circuit for a rechargeable battery according to the present invention;

Fig. 3 is a circuit diagram of a monitoring circuit for a reverse polarity connection of the battery

according to the present invention;

Fig. 4 is a circuit diagram of a battery impedance monitoring circuit according to the present invention;

Fig. 5 is a circuit diagram of a battery voltage monitoring circuit according to the present invention;

Fig. 6 is a circuit diagram for a constant current monitoring circuit according to the present

0 invention, and

Fig. 7 is a circuit diagram of a constant current control circuit according to the present invention.

Detailed description of the preferred embodiment

Referring to Figure 1, a battery charger according to the present invention generally comprises a low impedance power supply circuit 1, a constant current control circuit 2, a constant current monitoring circuit 3, a battery reverse connection monitoring circuit 4, a battery voltage monitoring circuit 5, a battery impedance monitoring circuit 6, a high impedance power supply circuit 7, and a voltage divider circuit 8.

5 Referring to Figures 2 to 7 and again to Figure 1, the high impedance power supply circuit 7

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· I

(see Figure 2) is connected in parallel with the low impedance power supply circuit 1 and in series with the voltage divider circuit 8 connected in parallel with a rechargeable battery 10. The battery reverse connection monitoring circuit 4 is connected in parallel with two opposite sides of the rechargeable battery 10 (see Figure 3) and comprises a comparator 40, an LED (light emitting diode) 41 and a variable resistor 42. The variable resistor 42 is connected in series with the comparator 40 and then connected to the parallel circuit of the LED 41 and the constant current control circuit 2. The battery impedance monitoring circuit 6 comprising an amplifier 60, a diode 61, a resistor 62 and a capacitor 63 is connected in parallel with the rechargeable battery 10. The amplifier 60 and the capacitor 63 are connected in series and then connected in parallel to the diode 61 and the resistor 62 (see Figure 4). The battery voltage monitoring circuit 5 includes a variable resistor 50 and a comparator 51 connected in series to the battery impedance monitoring circuit 6 (see Figure 5). The constant current monitoring circuit 3 is connected in parallel to the rechargeable battery 10 and then connected to the battery voltage monitoring circuit 5 which includes a current monitoring circuit 32 consisting of a comparator 30 and a variable resistor 31 and an initial state monitoring circuit 37 consisting of a divider circuit 34, an integrated delay circuit 35 and a comparator 36 (see Figure 6). The constant current control circuit 2 0 is connected to the accumulator battery reverse connection monitoring circuit 4, the battery voltage monitoring circuit 5 and the constant current monitoring circuit 3 for monitoring reverse connection of the accumulator battery, which is controlled to provide a reference output pulse by an AC voltage reset monitoring circuit 9.

and which comprises a voltage controlled oscillator 20 and a transistor 21. The voltage controlled oscillator 20 and the transistor 21 are connected in series to the low impedance power supply circuit 1 (see Figure 7).

In use, the rechargeable battery 10 is connected to the battery charger through the terminals 11, with the battery reverse connection monitoring circuit 4 comparing the positive terminal +VB with the voltage V4.2 of the variable resistor 42. If +VB>V4.2, it means that the rechargeable battery 10 is correctly connected and the battery reverse connection monitoring circuit 4 provides a positive potential at the output of V4.1 to the constant current control circuit 2 at a normal start. In contrast, if +VB<V4.2, the LED 41 is turned on to give a warning signal and the constant current control circuit 2 is not started. When starting, the impedance V6.1 of the rechargeable battery 10 measured by the battery impedance monitoring circuit 6 is compared with the voltage V5.2 of the variable resistor 50 at the comparator 51. When V6.1<V5.2, a positive potential signal is sent to the constant current control circuit 2, causing it to start the low impedance power supply circuit 1 2, and thus the power supply is provided by the low impedance power supply circuit 1 to the rechargeable battery 10. The constant current monitoring circuit 3 uses the set voltage V3.3 of the variable resistor 31 as a reference voltage. When V3.3>-VB, the constant current monitoring circuit 3 provides a positive potential signal to the constant current control circuit 2, indicating the situation that the charging current does not reach the set current, and the constant current control circuit 2 continues to provide a charging current to the rechargeable battery 10. When V3.3<-VB, a low potential signal is sent through the constant current control circuit 2.

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constant current monitoring circuit 3 is provided for the constant current control circuit 2, causing it to stop the charging current for the rechargeable battery 10. This achieves the constant current control. The divided voltage V3.4 of the divider circuit 34 is compared with the output voltage V5.1 of the battery voltage monitoring circuit 5. Because V5.1 is controlled by the integrated delay circuit 35, the start time for V3.5 is set after that of V5.1 to avoid short-circuiting the terminals 11.

When V3.5 and the output voltage V3.6 of the comparator 30 are reached, an output voltage V3.1 is provided by the constant current monitoring circuit 3 to the constant current control circuit 2. When V4.1 and V5.1 are at a positive potential state (no reverse battery connection exists and the battery voltage is not saturated), the constant current control circuit 2 is turned on to trigger the voltage controlled oscillator 20 and the voltage V3.1 is integrated by the resistor 22 and the capacitor 23 to provide V2.1 which starts the voltage controlled oscillator 20. When V2.1 is input to the voltage controlled oscillator, the voltage controlled oscillator provides low frequency and long duration pulses through transistor 21 and transformer 24 to trigger low impedance power supply circuit 1, causing it to charge rechargeable battery 10 with a voltage pulse while at the same time inductor 12 buffers the charging current. If rechargeable battery 10 is abnormal and has a high impedance, low impedance power supply circuit 1 cannot be triggered by rechargeable battery 10. However, high impedance power supply circuit 7 provides an output which is divided by voltage divider circuit 8 into a high output voltage which allows rechargeable battery 10 to be charged by a high voltage at

low current (about a few mA of electrical current).

While only one embodiment of the present invention has been shown and described, it is to be understood that various modifications and changes may be made without departing from the spirit and purpose of the disclosed invention.

Claims (3)

PROTECTION CLAIMS 1. Battery charger with a battery impedance monitoring circuit (6) comprising the following features: a diode (61) and a series circuit consisting of an amplifier (60) and a capacitor (63) connected in parallel to the rechargeable battery to be charged, a battery voltage monitoring circuit (5) comprising a transformer, a variable resistor (50) and a comparator (51) connected in series to the output side of the transformer, a constant current control circuit (2) comprising a voltage-controlled oscillator (20) and a transistor (21) coupled to the transformer, a low impedance power supply circuit (1) and an inductor (12) controlled by the constant current control circuit (2) to charge the storage battery (10), wherein a high impedance power supply circuit (7) is connected in parallel with the low impedance power supply circuit (1) and the inductor (12) and then connected in series with a voltage divider circuit (8) comprising a variable resistor connected in parallel with the rechargeable battery (10). 2. The battery charger of claim 1, wherein the constant current control circuit (2) is connected to a current monitoring circuit (32) comprising a comparator (30) and a variable resistor (31), and a constant current monitoring circuit (3) connected in parallel to the rechargeable battery (10) and comprising a divider circuit (34) and an initial state monitoring circuit (37) comprising an integrated delay circuit (35) and a comparator (3 6). 3. The battery charger of claim 1, wherein the constant current control circuit (2) is provided with a reverse battery connection detection circuit (4) connected in parallel to the rechargeable battery (10) and comprising a light emitting diode (41) and a series circuit consisting of a variable resistor (42) and a comparator (40) connected in parallel to the light emitting diode (41).