CS219246B1 - Connection for charging and pulse boost charging of accumulator batteries - Google Patents

Abstract

Connection for charging and pulse charging battery pack has a battery charger batteries connected to the terminals mains supply and grounded negative output terminal, at least one battery a battery with a grounded negative output and a source of pulses, connected to the power supply terminals. Its essence is that it is positive battery charger output terminal the battery is connected to the charger input pulses whose output is connected to positive output terminal of at least one rechargeable batteries.

Description

The invention provides a circuitry for charging and pulse charging accumulator batteries having a battery charger connected to the mains terminals and a grounded negative output terminal, at least one accumulator battery with a grounded negative output terminal, and a charging pulse source connected to the mains terminals.

Currently, battery chargers are known which charge the battery with pulsed currents. However, these chargers are quite complex and the pulse current requirement limits their function when pulsed. The output voltage of these chargers is always greater in one rectifier pulse than in the other rectifier pulses, resulting in a pulse current charging. This effect is achieved, for example, by unbalancing the rectifier or by connecting the rectifier phases to transformer taps or via resistors. Such chargers are circumferentially more complex than Π simple chargers that charge and recharge without pulsation current, and in addition, the requirement of pulsating current during charging limits their charging function when pulsating current is not appropriate. The series configuration of the charger with no pulsation current and charging pulse source has not been known yet.

These drawbacks are eliminated by the circuit according to the invention, characterized in that the positive output terminal of the battery charger is connected to the input of the charging pulse source, the output of which is connected to the positive output terminal of at least one accumulator battery. In this case, the mains terminals of the charging pulse source via a capacitor can be connected to the primary winding of the charging pulse source transformer, the secondary winding of which is connected in parallel with a diode whose cathode is connected to the positive output terminal of at least one accumulator battery. rechargeable batteries.

Advantages of the connection according to the invention are that in the circuit separation of the source of charging pulses from the battery charger, a simple circuit solution of the whole connection can achieve perfect function during charging and charging of the accumulator battery, eventually powering another appliance, eg telephone exchange.

The circuit according to the invention is explained in more detail below by way of example with reference to the drawing, in which Fig. 1 shows a circuit diagram according to the invention and Fig. 2 shows a detailed diagram of a charging pulse source.

The circuitry according to the invention has two main elements, ie a battery charger 3 and a charging pulse source 1. The accumulator battery charger 3 is connected to the mains terminals 4 and can be connected (not shown) directly to an appliance, such as a telephone exchange. The negative output terminal 8 of the battery charger 3 is grounded, and the positive output terminal fi is connected to the input of the charging pulse source 1. The charging pulse source 1 is connected to the mains terminals 2, its output terminal is connected to the positive input terminal 7 of the accumulator battery 5, the negative output terminal 9 of which is grounded.

The charging pulse source 1 can be connected so that the mains terminals 2 are connected via a capacitor 13 to the primary winding 10 of the transformer 11, to whose secondary winding 12 a diode 14 is connected in parallel, the cathode of which is connected to the positive input terminal 7 of the battery 5 and the anode is connected to the positive output terminal 6 of the battery charger 3.

The transformer 11 with the capacitor 13 in series with the primary winding 10 operates as an AC transformer, one half wave of the secondary winding 12 of the transformer 11 closes via a diode 14, the other half wave closes via the battery chargers 3 and a rechargeable battery 5 it is therefore recharged with a pulse current during continuous charging. When the accumulator battery 5 is charged or the current is drawn off, the core of the transformer 11 is magnetically supersaturated and the charging pulse source 1 is not applied. The secondary winding 12 must be dimensioned for the maximum current of the accumulator battery S, preferably it can be designed as a single thread of the connecting conductor or strip through the magnetic circuit of the transformer 11. The diode 14 can only be dimensioned for current corresponding to one half-wave charging pulses. It closes and can be connected with the opposite polarity, thus achieving negative pulses of current when charging the battery.

Claims (2)

1. A battery charging and pulse connection having a battery charger connected to the mains terminals and a grounded negative output terminal, at least one battery with a grounded negative output terminal, and a charging pulse source connected to the mains terminals, indicated by: in that the positive output terminal (6) of the battery charger (3) is connected to the input of the charging pulse source (1j), the output of which is connected to the positive input terminal (7) of the at least one accumulator battery (5). OF THE INVENTION Connection according to claim 1, characterized in that the mains supply terminals (2) of the charging pulse source (1j) are connected via a capacitor (13) to the primary winding (10) of the transformer (11) of the charging pulse source (1). (12), a diode (14) is connected in parallel, the cathode of which is connected to the positive input terminal (7) of at least one battery (5) and the anode is connected to the positive output terminal (6) of the battery charger (3J).