SU543090A1 - Device to power the load - Google Patents

Description

sections 7, 8, is connected to the load 9, the cathode is connected to the positive terminal of the battery and the anode of the Zener diode 10 to the negative. The device, providing the battery charge according to the Mitkevich circuit, provides continuous power to the load 9 with direct current and also prevents battery sections 7 and 8 from overcharging, if the breakdown voltage of the zener diode 10 is equal to the charging voltage of the battery 1.

The device works as follows.

Through both sections of battery 1, a battery discharge current is proportional to the voltage of the battery and inversely proportional to the load resistance 9. The battery is then discharged.

If source 2 is working, then, assuming that in one half period (let's call it odd, for example, the first), section 7 will charge through diode 5, then in the second (even), section 8 will charge through diode 6.

The discharge current of the battery, which is equal to the discharge current of the section, is pulsed in nature and alternates with the charge current pulses of these sections. The charging current flows when the potential of the anode of the conducting diode is positive with respect to the potential of the cathode, i.e. during that part of the half period when the instantaneous voltage of the source is higher than the voltage of the battery sections and the current of the source exceeds the discharge current of the battery.

The instantaneous value of the charging current is proportional to the voltage difference between the source (transformer) and the charging section of the battery and inversely proportional to the resistance of the charging circuit. The average value of the charge current is equal to the integral of its instantaneous value over the period. During the charging section, the source also energizes the load 9. In addition, when the voltage at the terminals of battery 1 exceeds the voltage of the breakdown of Zener diode 10, the source current flows through this Zener diode. This occurs (during the charging of section 7) when the sum of the voltages of section 8 and the secondary winding reaches the voltage of the zener diode breakdown. This, in turn, will cause an increase in the discharge current of section 8 in the odd half-period or the discharge current of section 7 in the even half-period of the voltage of source 2. The value of the current of the subpart of the sections through Zener diode 10 is also determined by the voltage across the diode, and is inversely proportional to the sum of the resistances of resistor 4 and diode 10. Therefore, the resistance of resistor 4 determines the magnitude of the current and the charge and discharge pulses.

Thus, if a load resistance 9 is connected to the battery, then the energy of the discharge pulses of the battery sections is used to benefit from the load. If the load resistance 9 is increased or even switched off completely, the energy of the discharge pulses of the battery sections will dissipate at the zener diode. Such a device, forming an asymmetric alternating current in sections of battery 1,

provides for the charge of batteries, as well as the regeneration of manganese-zinc and other elements often used as power sources for various radio receivers.

As the sections 7, 8 of the battery 1 are charged, the charge current of these sections decreases, and the current of their sub-section through the zener diode increases; at the end of the charge cycle, the charge and discharge currents are equalized, and the charge stops, that

Protects battery from overcharging.

The device can be used both in stationary conditions and when operating it on various moving objects. It can also provide multiple

regeneration (in stationary conditions) of cells discharged partially with autonomous power supply to the load (when there is no alternating current source in the device).

Claims (1)

1. Copyright certificate № 420022, cl. H 02J 7/34, 1974.