JPS63107430A - Battery charger - Google Patents

Abstract

(57) [Abstract] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed description of the invention] (a) Industrial application field The present invention operates an inverter circuit with a t-current voltage of an AC power supply, charges a storage battery with a half-wave current obtained by rectifying the output, and charges the storage battery with the impark. The present invention relates to a battery charging device that controls the oscillation duty of a circuit to stabilize the output, that is, to maintain a constant current.

<Explanation> Conventional technology The charging circuit disclosed in Japanese Patent Publication No. 5B-22930 attempts to stabilize the output by feeding back the secondary side output of the oscillating transformer configuring the inverter circuit to the primary side. . This technology connects the primary winding of an oscillation transformer to the output of a rectifier circuit connected to an AC power supply via the collector-emitter of a transistor, and directs a portion of the oscillation output of this oscillation transformer to the base of the transistor. A charging circuit comprising an adapter having an inverter circuit provided with a feedback winding to be fed back, and a device main body connected to the adapter and receiving power from the rectified output of the inverter circuit,
A transformer is inserted and connected in series to the secondary winding of the oscillation transformer of the impark circuit, and the secondary winding of this transformer is used as the feedback winding for the above-mentioned positive feedback. However, in this example, the base of the inverter transistor is directly affected by the feedback winding, so even though the problem of increasing the primary 'It current or stopping heat generation due to no-load driving when the output is open can be overcome, the This could not be said to be desirable from the viewpoint of stabilizing the output.

(c) Problems to be Solved by the Invention The problems to be solved by the present invention are the problems of the inverter transistors in the above-mentioned conventional charging circuit.

The aim is to improve the flow supply path and suppress output fluctuations while charging the storage battery.

(d) Means for solving the problem Connect the primary winding of an oscillation transformer to the output of the rectifier circuit connected to the AC TL source via the collector and emitter of the transistor, and output the oscillation output of this oscillation transformer. A part of the oscillation transformer is provided with a feedback winding that is fed back to the base of the control transistor that controls the Sumi current, and the feedback winding is connected in series with the secondary winding of the oscillation transformer. insert.

Kuho) Action AC Tf! , the output opening of the current is detected as a fluctuation in the current flowing through the secondary winding of the oscillation transformer, and the return in series with the secondary winding; Keep the duty constant.

Example) The battery charging device of the present invention will be described in detail below with reference to an example shown in the drawings.

(la) and (lb) are input terminals to which commercial AC its is connected, and the input terminals (la) and (lb) are respectively connected to a rectifier circuit (Dl), and both input terminals (la) and (lb) are connected to the rectifier circuit. A capacitor (C1) and a choke coil (Ll) are connected in parallel or in series between the circuits (Dl).

(2) is the oscillation transformer (T) that constitutes the inverter circuit
The second winding of (Ql) is an inverter transistor whose collector side is connected to the second winding, and both of are connected to the series circuit (3 ). (4) is a smoothing capacitor, and the series circuit (3) is connected to both ends of the front two rectifier circuits (Dl).
The current flowing through the series circuit (3) is smoothed and full-wave rectified.

(R1) (R2) are the inverter transistors (Ql
) is a resistor inserted between the base resistor (R5) of the rectifier circuit (01) and the positive end of the rectifier circuit (01), and the resistor (R1) (R
2> controls the oscillation of the inverter transistor (Ql) and determines the output current of the inverter circuit.

(R4) (03) is a resistor and a capacitor inserted between both ends of the secondary winding 11 (2'), and is used to remove noise generated in the secondary winding.

(C2) is a control transistor whose collector-emitter circuit is connected in parallel to a capacitor (C2) which is connected in series with the resistor (R1), and a resistor (R3) is connected between its base and emitter. It is intervening.

(5) is a tertiary winding provided on the input side of the oscillation transformer (T), its middle tap (6) is connected to the negative electrode of the rectifier circuit (Dl), and one end is connected to a capacitor (C4). The inverter transistor (Ql
) is connected to the base resistor (R5). The other end of the tertiary winding (5) is connected to a diode (C4) and a variable resistor (V
It can be connected to the negative electrode of the rectifier circuit (Dl) via the rectifier (RI). (C5) is a capacitor connected in parallel to the variable resistor (VRI). and the control transistor (
C2) has its base connected to the variable resistor (VRl) via a diode (C2) and a Zener diode (Dz).

Next, (7) is a secondary winding of the oscillation transformer, and a storage battery (8) can be connected between the output ends of the secondary winding (7). Between the secondary winding (7) and the battery (8) is a rectifier diode (C6), a capacitor (C7) connected to this, a choke coil (L2), and a current control circuit (9). A series circuit is inserted,
A capacitor (C8) is connected to the choke fill (L2>), which detects the end of charging of the storage battery (8) and operates the current control circuit (9) to cut off or reduce the current supplied to the storage battery (8). A detection circuit (10) is connected in parallel with the storage battery.

(11) is the secondary winding (7) connected in parallel to the storage battery (8).
) is a constant voltage circuit that is connected to both ends of the diode to create a constant operating voltage (VCC) for the detection circuit (10).
- (C7), the series circuit of the choke coil (L3) and the three-terminal regulator (12), and the connection point (13) of each element.
) (14) A capacitor (C
9) (CIO) (C11>).

(Cτ) is the secondary winding (76) of the oscillation transformer (T)
The secondary output of the current transformer (0) is connected in series to the secondary winding (7) and serves as a feedback winding to detect the current flowing through the secondary winding (7).
It is converted into a direct current through the circuit (D5), and this current is passed through the diode (D3) to the control transistor (Q).
It can be supplied to the base of l). Moreover, the rectifier circuit (05)
A capacitor (C6), a resistor (R6), and a second variable resistor (R2) are connected in parallel with each other.

In the charging device having the above configuration, the oscillation transformer (T
), and when the inverter transistor (Ql) becomes non-conductive, this #
The infused energy is transferred to the rectifier diode (D6) on the secondary side (
The basic operation is to release pressure to the storage battery (8) via D7). For this reason, when performing rapid charging, the power current control circuit (9) may be cut off when charging is completed, or the connection of the storage battery (8) may be suddenly canceled during charging, causing the oscillation transformer (T) to shut off.
As soon as the output side of the oscillating transformer (T) becomes open,
The balance between the input side and the output side of the oscilloscope is disrupted, and the oscillation state becomes unstable when no load is applied. As a result, the 1-voltage VCE between the collector and emitter of the inverter transistor (Ql) rises to near the limit value of its specifications, creating a risk of breakdown of the breakdown voltage.

However, in the above circuit, a current transformer (CT) is provided on the output side of the oscillation transformer (T), and the oscillation transformer (T)
By feeding back the secondary output current to the inverter transistor (Ql), the duty of the oscillation frequency of the oscillation transformer (T) is controlled, and the current output to the secondary side is again stabilized. The output current of this oscillation transformer (T) can be determined by the resistances (R1) and (R2) on the primary side, but if the input from commercial AC is increased by releasing the load on the secondary side, the secondary side output tP: A variable resistor <vRl) is used to control the voltage so that it does not rise abnormally.

That is, the control transistor (Ql) that controls the oscillation state of the inverter transistor (Ql) repeats on and off operations within the setting range of the variable resistor (VRI).

A current transformer (CT) provided on the secondary side of the oscillation transformer (T) detects an output current on the output side, and this current is converted into voltage and amplified. When a current of a predetermined level or higher flows, a signal is applied to the base of the control transistor (Ql) via the diode (03). Application of this signal causes the control transistor (Ql) to become conductive, so that the inverter transistor (Ql) tends to turn off.

Since the control transistor (Ql) repeats on and off states depending on the load fluctuation on the output side of the oscillation transformer (T), the oscillation of the inverter transistor (Ql) is also controlled, so that the output current exceeds the set value. is always clipped, and a constant output current is always supplied to the storage battery (8) regardless of the size of the load connected to the output side of the oscillation transformer (T) (for example, whether the storage battery (8) is attached or removed). This allows the output current of the oscillation transformer (T) to be constantly supplied even if the AC input fluctuates during charging.
Constant TFI charging is realized for the battery (8).

(g) Effects of the Invention As explained above, the present invention connects the primary winding of an oscillation transformer to the output of a rectifier circuit connected to an alternating current source via the collector and emitter of a transistor, and and a feedback winding that feeds back a part of the oscillation output to the base of a control transistor that controls the base current of the oscillation transformer, and the feedback S''11 is inserted in series with the secondary winding of the oscillation transformer. This makes it possible to prevent voltage breakdown of the inverter transistor due to abnormal oscillation that occurs when the load on the output side of the oscillation transformer in a switching regulator type charging circuit is opened, and also to reduce the output current by feeding back the output current of the oscillation transformer to the input side. The current is stabilized, allowing constant current charging.Furthermore, according to safety standards, the feedback winding facilitates insulation between the primary and secondary of the oscillation transformer.

[Brief explanation of the drawing]

The drawing is a circuit diagram of an embodiment of the battery charging device of the present invention. (01)... Rectifier circuit, (Ql)... Inverter transistor, (T)... Oscillation transformer, (Ql)...
・Controller)′ resistor, (CT)...Feedback winding, (7
)...Secondary winding of the oscillation transformer.

Claims (1)

[Claims] (1) Connect the primary winding of the oscillation transformer to the output of the rectifier circuit connected to the AC power supply via the collector and emitter of the transistor, and use part of the oscillation output of this oscillation transformer to control the base current of the oscillation transformer. and a feedback winding that returns to the base of a control transistor, the feedback winding being inserted in series with the secondary winding of the oscillation transformer.