SU1179480A1 - Charging device for storage battery - Google Patents

Abstract

A BATTERY CHARGER, containing a lowering transformer, a full-wave counter, sequentially switches the regulating thyristor and a phase switch, which is used to simplify the stabilization of the charging current, additionally introduced a thyristor state sensor, made in the form of a transistor switch, and a voltage measuring circuit on an open thyristor, made in the form of a series-connected first resistor, diode and cond The cathode, the free terminals of which are connected respectively to the anode and cathode of the regulating thyristor, the cathode of the diode connected to the capacitor is connected via a second resistor to the input of the phase control circuit, and the anode of the diode and the first resistor are connected to the output of the thyristor state sensor.

Description

The invention relates to regulated power sources, preferably devices for charging batteries with a constant current.

The purpose of the invention is to simplify device II improving the accuracy of current stabilization,

FIG. 1 is a schematic diagram of the device in FIG. 2 - enhancing the operation of the device; TWA diagrams.

The device consists of a step-down transformer 1, to the secondary winding of which a two-half-rectifier rectifier is connected, formed by diodes 2J in series with which battery 3 and control 1 thyristor 4 are connected. Control of the thyristor 4 is performed from the pulse-phase control circuit 5. Parallel to the thyristor A, a sensor is connected STATUS1 6. The phase control circuit is synchronized by the voltage applied to the Zener diode 7 connected through the current limiting resistor 8 in parallel with the thyristor. The phase control circuit contains a single junction transistor 9 and a time master circuit formed by a trimming resistor 10 and a capacitor 11. One of the bases of the single junction transistor 9 is connected to the control electrode of the thyristor 4. The capacitor 11 is bridged by the transistor 12, the base of which is the input of the phase control circuit 5 and connected via a second resistor 13 to a voltage measuring circuit on an open thyristor, which is formed by a series circuit formed by a diode. 14, the first resistor 15 and the capacitor 16. The anode of the diode 14 is connected to the output of the thyristor state sensor 6, comprising a transistor switch 17, a resistor 18 and a diode 19.

The device works as follows.

When the battery 3 is connected by a potentiometer 10, the required value of the charging current is set by changing the turn-on phase of the thyristor 4. The voltage on the thyristor 4 after setting the required current value is shown in FIG. 2 in the form of a diagram 20 (conventionally, the voltage of a battery of batteries is sufficiently small). The voltage on the Zener diode 7 is shown in FIG. 2-21. When thyristor 4 is closed, transistor switch 17 of state sensor 6 is open.

As the key 17, a transistor with a low saturation voltage is used. When the thyristor 4 is unlocked in each half-period of the supply voltage, the transistor switch 17 is locked and the capacitor 16 is charged through the resistors 8 and 15, and the diode 14, by the voltage on the unlocked thyristor. The magnitude of this voltage is determined by the magnitude of the current flowing through the thyristor and the temperature of its structure (also a function of the current flowing through it). This voltage 22 (Fig. 2) charges the capacitor 16 during the thyristor conductivity time. As a result, the voltage 23 on the capacitor (Fig. 2) is proportional to the magnitude of the current flowing through the thyristor. This voltage through the second resistor 13 is applied to the base of the transistor 12, which determines the degree of shunting of the capacitor 11, and hence the phase angle of the control pulse 24 supplied to the thyristor 4 (Fig. 2). As the battery 3 is charged, the voltage at its terminals increases, which leads to a decrease in the magnitude of the charging current. A decrease in the current flowing through the thyristor causes a decrease in the voltage on the unlocked thyristor, and consequently, the voltage on the capacitor 16. At the same time, the transistor 12 starts to lock, its shunting effect to the capacitor 11 also decreases, which ultimately leads to a decrease in phase thyristor switching angle and

hence, stabilizing the magnitude

current. FIG. 2 shows the voltage 25 on the battery 3.

Thus, measuring the voltage on the thyristor regulator allows the change in the phase angle of the thyristor to be such that the average current remains unchanged.

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Claims (1)

A BATTERY CHARGER containing a step-down transformer, a half-wave rectifier, a thyristor in series with it, and a thyristor phase control circuit to increase the accuracy of stabilization of the charging current, a thyristor state sensor made in the form of a transistor switch, and an open voltage measuring circuit thyristor, made in the form of series-connected first resistor, diode and capacitor, the free terminals of which are connected respectively to a a cathode and a cathode of the control thyristor, the diode cathode connected to the capacitor connected through the second resistor to the input of the phase control circuit, and the diode anode and the first resistor connected to the output of the thyristor suction sensor. torus, characterized in that, in order to simplify the device and SU, 1179480 (Fig. 7 1 1179480 2