SU1105979A1 - Device for charging storage battery by asymmetric current - Google Patents

Abstract

A BATTERY CHARGE DEVICE ASYMMETRIC CURRENT containing an AC source connected through a thyristor power unit with terminals for connecting, connecting the battery, rectifier with parametric output regulator, RC chain, asymmetry unit connected between the AC source and asymmetric output stabilizer, RC chain, asymmetry unit connected between the AC source and asymmetric output stabilizer, RC chain, asymmetry unit connected between the AC source and asymmetric output stabilizer, RC chain, asymmetry unit connected between the AC current source and the output stabilizer, RC circuit, asymmetry unit connected between the AC current source and the output stabilizer, RC circuit, asymmetry unit connected between the AC current source and the output stabilizer, RC chain, asymmetry unit connected between the AC source and the asymmetric output stabilizer, RC-chain, asymmetry unit connected between the AC current source and the output stabilizer, RC-chain, asymmetry unit connected between the AC current source and the output stabilizer an RC circuit input, a discharge node connected between the stabilizer outputs and an RC chain, a pulse shaping unit that is connected to the RC circuit by one input, and a thyristor output. molecular unit of tesla. Envisioned by the fact that, in order to automate the process of e-dag with the subsequent automatic transition to the content mode and to increase the specific energy indicators, the RC-chain is connected to the output of the parametric stabilizer and a threshold device is inserted that is embedded into the grid by the second input of the control pulse generation unit W and the terminal to connect the battery to the F battery. JV CO 4j with

Description

The invention relates to electrical engineering, in particular, to devices for charging and discharging power sources, and can be used, for example, in dp recovery of electroplating cells, their content and desulfation of batteries during charging. A device for charging an accumulator is known, which contains a power supply unit of a power unit made on a semiconductor device, for example, a semistor, a control unit including a phase-shifting circuit, a control driver, and a program control mechanism 1 1 However, the known device does not provide automatic control of the battery charge process battery and the subsequent automatic | transition to the content mode. Closest to the invention is a 4) bottom-discharge device containing an alternating current source (transformer), rectifier, parametric stabilizer, discharge unit, control pulse shaping unit, power thyristor unit (current regulator), RC - a chain based on the time of the specifying capacitor and resistor, the asymmetry unit in the form of a synchronizing diode and variable resistor 2, a plurality of winding elements make the design of this device cumbersome, which reduces the specific energy STUDIO device. It does not ensure proper automatic control of the battery charging process, as a result of which emergency operation is possible due to overcharging of the battery. The purpose of the invention is to automate the process of charging a battery with the subsequent automatic transition to the content mode and increasing the specific energy indicators of the battery charging device. The goal is achieved by the fact that in a device containing an alternating current source, connected via a thyristor power unit to the battery connection terminals dp, a rectifier with a parametric output stabilizer, RC circuit, asymmetry unit, connected to the source of changes 1 7S2 current and an RC circuit input, a discharge node connected between the stabilizer outputs and an RC chain, a control pulse shaping unit connected to the RC circuit output by one input, and an output thyristor unit, mentioned The chick of the RC-chain is connected to the output of the parametric stabilizer and a threshold device is inserted between the second input of the control pulse shaping unit and the terminal for connecting the battery. FIG. 1 shows a block diagram of the device; in fig. 2 - a printable electrical circuit of the device; in fig. 3 - timing diagrams for the operation of the device. The device contains an alternating current source 1, a rectifier 2, a stabilizer 3, a discharge unit 4, a control pulse shaping unit 5, a power thyristor unit 6, a threshold device 7, a PC chain 8, an asymmetry unit 9 connected via a battery key ( AB) 10. The AC source is connected via a power thyristor unit 6, made on the triac, with a battery. A source 3 connected to the stabilizer 3, connected to the output of the miter 2, RC-chain 8 is a series The connection of the variable resistor 11 and the charge (time of the driving capacitor and connected between the output of the stabilizer 3 and one input of the control pulse shaping unit 5. The asymmetry unit 9 is performed on the forward (synchronizing) diode 12 and the variable resistor 13 and is connected between the AC source 1 and the input of RC chain 8. Bit 4 is connected to transistor 14, guide diode 15, resistor 16 included in the base circuit of transistor 14, and resistor 16 bypasses the output of the parametric stabilizer 3 and is turned on Between the output of the stabilizer 3 and the output of the RC chain 8. A threshold device 7 is inserted into the battery charging device, consisting of connected in series and in accordance with the battery 10 of the guide diode J7 and the zener diode 18, and connected between the second input of the pulse shaping unit 5 and a battery. In the diagrams (Fig. 3), the following symbols are used: U: - voltage at the input of the device; U is the voltage across the capacitor plates; and - the value of the voltage triggered on the threshold device; U is the voltage across the battery terminals; current through the battery. The device works in the following way. At a negative voltage half-wave (plus at terminal 19, minus at terminal 20) from the AC source 1, the voltage is fed to the input of the device. At the output of rectifier 2, half-waves of rectified voltage appear, which are then limited by the stabilization level of stabilizer 3. The RC capacitor 8 strives to charge to the output voltage of stabilizer 3 through a variable resistor 11. When the RC-capacitor 8 reaches the value The voltage U S t triggers the pulse shaping unit 5 and the capacitance is discharged through the primary winding of the unit transformer. At the same time, a control voltage pulse is generated on the secondary winding of this transformer, and the triac of the unit opens. As a result, a discharge pulse flows through the battery, the moment of occurrence of which is determined by the time constant t Re, where R is the resistance of the variable resistor 11; With capacitor capacitance. At the end of the half-period of change in the input voltage at the output of the stabilizer 3, the voltage is lower than the voltage on the capacitor plates, which, through the emitter junction to the base of the transistor 14, the guide diode 15, the discharge node shunt resistor 16, tend to discharge. As a result, transistor 14 opens and discharges the capacitor. With a positive input voltage half-wave (plus at terminal 20, minus at terminal 19), the capacitor receives an additional accelerated charge through the guide diode 15 and the variable resistor 13, for this reason the delay in the appearance of the charge pulse relative to the beginning of the half period is less. The delay time is determined by a constant time of 2 11, where t- is the time constant with a positive voltage half-wave; R is the resistance of the parallel-connected resistors 11 and 13. As the battery is charged, the voltage across its terminals increases. As a consequence, the voltage on the capacitor plates later reaches the value Uu-j and, accordingly, the magnitude of the voltage pulses (the shaded part in Fig. 3) decreases. The device then recharges the battery with current pulses, the average value of which is equal to the battery self-discharge current, and thus keeps the battery in a charged state. Automation of the charging process with the subsequent automatic transition to the content mode is ensured by the time of the dependent intermittent connection entered into the device between the inter-control circuit and the battery being charged. Automating the mode of accelerated charging of a battery in the proposed device allows reducing gas cleaning when charging the battery; reduce the heating of the electrode when charging the battery; reduce energy consumption; extend battery life; eliminate power winding elements and improve specific energy indicators and ensure automatic transition to the maintenance mode.

Claims (1)

DEVICE FOR CHARGING A BATTERY WITH AN ASYMMETRIC CURRENT, containing an AC source connected via a thyristor power unit with terminals for connecting the battery, a rectifier with a parametric stabilizer at the output, an RC circuit, an asymmetry unit connected between the AC source and the input -chains, a discharge node connected between the outputs of the stabilizer and the RC -chain, a control pulse generation unit connected by one input to the output of the RC -chain, and the output with a thyristor block eye, about t - l. In that, in order to automate the charge process and then automatically switch to the mode of maintaining and increasing specific energy indices, the RC chain is connected to the output of the parametric stabilizer and a threshold device is inserted, connected between the second input of the control pulse generation unit and the terminal for connecting the battery. SU „„ 1105979 a FIG. 1 1105979 2