JPS583539A - Charging circuit - Google Patents

Abstract

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

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a charging circuit for electrical equipment, such as a rechargeable electric shaver, which may be used in areas with different power supply voltages.

BACKGROUND ART Conventionally, in rechargeable electric appliances, there are those whose usable power supply voltage is set to -mm and those whose usable power supply voltage is switchable. In the former case, if the power supply voltage differs from the set value, it will become completely unusable, whereas in the latter case, even if it is possible to switch, it must be done manually, and if you forget to do so, the device will be damaged. There is a risk of damaging the.

The present invention has been made with these points in mind, and an object of the present invention is to provide a charging circuit that can automatically switch inputs and perform normal charging even if the commercial AC power source is different.

The present invention provides a plurality of intermediate taps in the primary winding of the transformer (5-tC) to select the number of windings, detects the voltage of the commercial AC power supply using the input switching circuit, and adjusts the primary winding in accordance with the detected voltage. The number of turns to be used can be selected so that the secondary voltage can be kept constant and compatible with various commercial AC power sources.

An embodiment of the present invention will be described based on the drawings. First, a commercial AC power supply (3) is connected between (Iha) of the negative winding (2) of the transformer (1), and this second best M (2) is (
An intermediate tap (4) labeled b) is provided.

An input switching circuit (5) is connected to each connection point (a, opening, c) of the secondary winding (2) of such a transformer (1). This input switching circuit (5) consists of a triac B (6) connected between the connection points (E port), a resistor Rs (7) and a triac B (8) connected between the connection points (E...). , a diac (9) connected between the connection midpoint of these resistors Rs (7) and triac B (8) and the gate of triac A (6), and the gate of triac B (8). A resistor R that gives a divided voltage to
2 (G) and a resistor RsQυ.

Therefore, the secondary winding (6) of the transformer (1) has connection points (2, E, H), and the connection points (2, H) pass through the rectifier circuit (to) to accommodate the secondary battery ◆ The connection point (E) is connected to the negative side of the secondary battery α◆.

In such a configuration, the power supply voltage in the commercial AC power supply (3) is now vl and v as shown in Figure 2 (al).
I assume that there are two types, 3 and 3. And voltage v3
is a voltage that provides more than the gate trigger voltage of triac B (8). That is, given by the tiger. Further, the voltage v4 is the breakover voltage of the diac (9).

Therefore, the case where the power supply voltage is vl will now be explained. In this case, it will never reach vl, so
Triac B (8) is always in a cut-off state. and,
This voltage v1 is applied to the (E...) terminal of the primary winding (2), and when v4 occurs, the diac (9) becomes conductive and the diac A (6) becomes conductive. As a result, voltage v1 is applied between the primary windings (2).

As a result, a secondary voltage v11 is generated in the secondary winding (6).

Next, a state in which the power supply voltage becomes vl will be explained. In this case, first, v
A state in which a voltage l is applied and it generates v4,
That is, after the time Tl has elapsed, the diac (9) becomes conductive and the triac (6) becomes conductive, thereby causing v
A voltage of 1 is applied across the primary winding (2). Here, the waveform shown in Fig. 2(k) is the primary winding (2).
It shows the voltage applied between (loha). Then, when time T11 further elapses, triac B (
8) becomes conductive, thereby sequentially cutting off diac (9) and triac A (6), and a voltage s V2 is applied between (Iha) of first-order #jl (2). Therefore, the voltage between (Low...) decreases as shown in Figure 2 (Jl), and this voltage approximates that when the power supply voltage is vl.Therefore, the voltage of the commercial AC power supply (3) is Even if the voltage v5 changes, the voltage v5 to the secondary battery remains almost constant, and this is automatically switched.

In the above embodiment, the number of the intermediate taps (4) of -suboptimal M(2) is one, but in the case of implementation, a plurality of intermediate taps may be provided, and the input switching circuit (5) may be Combinations of triacs (6) and diacs (9) are provided in multiple stages, the value of the resistor R+ (7) provided in each stage is varied, and a triac B (8) is connected to the final stage. As a result, the number of turns of the primary winding (2) to be used is set in accordance with the input voltage, just as a plurality of types of voltage v3 are set.

In the present invention, an input switching circuit is connected to each connection point of the primary winding provided with a plurality of intermediate taps as described above, and the number of turns to be used is switched according to the voltage of the commercial AC power supply. Even when connected to a commercial AC power supply with various voltages, the voltage will automatically switch, giving a constant charging voltage to the secondary battery, protecting the device, and eliminating the need for manual switching. This has the advantage that there is no need to worry about doing any work.

[Brief explanation of drawings]

The drawings show an embodiment of the present invention, and FIG. 1 is a circuit diagram, and FIG. 2 is a graph (al) showing changes in power supply voltage and accompanying voltage changes between the primary windings. , 3rd
The figure is an enlarged view of the section seen by arrow A in FIG. 2. 1...Transformer, 2...-secondary winding, 3...Commercial AC power supply, 4...Intermediate tap, 5...Manual switching circuit,
14...Secondary battery June 26, 1980 Inventor: Murakami, Urayama, Tokyo Electric Co., Ltd., Agent: Aiki Akira:,,;r,-,
--:+il

Claims (1)

[Claims] In a transformer in which a commercial AC power source is connected to the primary side of the transformer and a secondary battery is connected to the secondary side through a rectifier circuit, a plurality of intermediate taps are provided in the primary winding of the transformer,
A charging circuit characterized in that an input switching circuit is connected to each connection point of the secondary winding to detect the voltage of the commercial AC power source and switch the number of turns to be used in the secondary winding.