SU547914A1 - Device for charging the battery with asymmetric current - Google Patents

Description

(54) ASSEMBLY FOR BATTERY CHARGING ASYMMETRIC CURRENT

pe 1, i.e. The energy of the battery discharge pulse is summed with the energy of source 2, the capacitor 6 is charged to a voltage almost equal to twice the sum of the voltage of the source and the battery. The resonant charge provides the natural suppression of the thyristor 3. When the thyristor 4 is turned on, the capacitor 6 is resonantly discharged to the battery 1, giving away the energy stored by it, which is the sum of the energy of the battery's discharge pulse and the source energy. At the end of the discharge of capacitor 6, the thyristor 4 goes out.

When charging batteries from an AC source, the proposed method can be implemented according to the scheme shown in FIG. 2. Here, in contrast to the previously described, the charging device is additionally equipped with a valve 8 and a current-limiting resistance 9, for example, a choke, while the anode of the said valve 8 is connected to the negative terminal of the battery 1 directly, and the cathode to the positive terminal through the limiting resistance 9 and source 2. These differences reduce the typical power of an inductive-capacitive resonant circuit.

Indeed, in a half-period, when the voltage at the source terminal connected to the battery is negative, when opening the thyristor 3, the storage capacitor 6 is resonantly charged and the battery 1 is discharged (with the accumulation of the discharge pulse with the source energy). In the next half-period the source is energized through the open thyristor 4, the storage capacitor 6 is resonantly discharged to the battery 1, and the battery is simultaneously charged from the power supply 2 through the gate 8 and limiting resistance 9. This charging mode (simultaneously from the power supply and storage capacitor) allows you to reduce T1show power inductive capacitive resonance sonture.

A further improvement of the devices can be the circuits shown in Figs 3 and 4, where the battery is divided into two groups in order to more fully utilize the power and, therefore, the weight of the charging source.

The scheme shown on fig. 3 is similar to the diagram shown in FIG. 1. Differences only in crosslinks that allow the storage capacitor of one group to be charged and at the same time discharge the storage capacitor of the other. The circuit shown in FIG. 4. similar to that shown in FIG. 2 with the above differences. In these devices during the charging of one group of accumulators, the energy of the source is summed up in the capacitor of the second circuit together with the energy of the second group of batteries.

It is obvious that the use of only two thyristors in the circuit of FIG. 1 (or two thyristors and one diode in the circuit of Fig. 2) allows the device to be 2-3 times worse and its efficiency to increase, since the natural extinction of the thyristors does not require energy to lock them, as it did is in prototype. The charge of two groups of batteries using devices made according to the schemes of FIG. 3, 4, in addition, allows the production of the formation of an asymmetric current with an optimal duty cycle of charge pulses equal to two, to double the efficiency of using the power of the source of electrical energy.

Claims (1)

Invention Formula A device for charging a battery with an asymmetrical current, containing a DC source with two output terminals, a serial inductive-capacitive resonant circuit, thyristors and a control unit connected to the output terminals of the source that, for the sake of simplicity, the positive terminal of the battery is connected to the negative terminal of the source, both terminals of which are connected via two connected in series thyristors, and the negative terminal of the battery is connected to the connection point thyristors through the mentioned inductive-capacitive resonant circuit.  7 I 11 one w  2 M Fig.Z fcgl