RU2692697C1 - Accumulator self-discharge compensation device - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention can be used in devices for charging accumulator batteries stored, in order to compensate for their self-discharge. Technical result is achieved due to that in device for compensation of self-discharge of accumulator batteries there additionally introduced is second photocell, key transistor, control transistor, stabilitron, relay and resistor; wherein relay winding and collector circuit of key transistor are connected in series and connected between positive and negative buses of device, and key transistor base is connected between mid point of series-connected resistor and control transistor, stabilitron is connected between the base of the control transistor and the photocell connected to the negative bus, and relay contacts are connected to outputs of photocells.

EFFECT: technical result is aimed at expansion of range of illumination of device and its applicability.

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Description

The invention relates to electrical engineering and can be applied in devices for recharging storage batteries stored, in order to compensate for their self-discharge.

A device for compensating self-discharge of batteries (Patent RF №2555323 C1 H02J 7/18 dated 07/10/2015 Bull. No. 19) containing a photocell as a current source, protection against battery inverse connection diode, series-connected choke and diode connected between the positive output of the photocell and the anode of the protection diode, a cumulative element connected between the anode of the protection diode and the minus bus, a switching transistor connected between the midpoint of the connection of the choke and the diode and the minus bus, to the base of which By connecting the outputs of the master oscillator and the threshold device, whose input is connected parallel to the storage element.

The disadvantage of this device is a narrow range of illumination of the device, which reduces its applicability.

It is also known a device for compensation of self-discharge of rechargeable batteries (Patent RF №2604204 C1 H02J 7/18 dated 12/10/2016 Bull. No. 34), which differs from the above by the presence of a protection circuit against short circuits and having a similar disadvantage.

The technical result is aimed at expanding the range of illumination of the device and its applicability.

The technical result is achieved in that the device for compensating the self-discharge of batteries, containing a photocell as a current source, a protection diode from inverse switching on the storage battery, a series-connected choke and a diode connected between the positive output of the photocell and the anode of the protection diode, is a cumulative element connected between the anode of the protection diode and the minus bus, a switching transistor connected between the midpoint of the junction of the choke and the diode and the minus bus, to the base of which yucheny oscillator outputs and threshold device having an input connected across the storage element is further administered a second photocell, a key transistor, control transistor, zener diode, relay, resistor; the relay coil and the collector circuit of the key transistor are connected in series and connected between the positive and negative buses of the device, and the base of the key transistor is connected between the midpoint of the series-connected resistor and the control transistor, the Zener diode is connected between the base of the control transistor and the photocell connected to the negative bus, and the contacts relays are connected to photocell pins.

Distinctive features is that the device circuit to compensate for self-discharge of batteries, containing a photocell as a current source, an inverse battery protection diode, a series-connected choke and a diode, a storage cell, a switching transistor, a master oscillator and a threshold device are additionally introduced a second photocell, key transistor, control transistor, Zener diode, relay and resistor.

The introduction of these elements expands the range of illumination of the device and its applicability, since the second photocell, depending on the illumination, is switched on in parallel or in series with the first photocell. In the latter case, in low light, the total emf of the photocells increases.

The drawing shows a diagram of the device to compensate for self-discharge of batteries.

The device contains photo cells 1 as a current source, a diode 2 protection against inverse switching on the battery. Between the positive output of the photocell 1 and the anode of the protection diode 2 are connected in series the choke 3 and diode 4, and between the anode of the diode 2 and the minus bus 5 of the device is included a storage element 6. Between the midpoint of the connection of the choke 3 and diode 4 and the minus bus 5 there is a switching transistor 7, to the base of which are connected the outputs of the master oscillator 8 and the threshold device 9, consisting of a resistor 10, a potentiometer 11, a Zener diode 12, a diode 13, a resistor 14, a transistor 15. Moreover, at the input of the threshold device 9 is turned on A voltage divider from resistor 10 and potentiometer 11 connected in parallel to storage element 6 is connected. Between the midpoint of the connection of resistor 10 and potentiometer 11 and minus bus 5 are connected in series the Zener diode 12, diode 13 and resistor 14 connected in parallel with the base-emitter junction of transistor 15. The output of the threshold device 9 through the collector of the transistor 15 is connected to the base of the switching transistor 7. The resistor 16 sets the offset on the basis of the switching transistor 7. Between the positive and negative bus and the devices are connected in series with the relay coil 19 and the collector circuit of the key transistor 20, and the base of the key transistor 20 is connected between the midpoint of the serially connected control transistor 21 and the resistor 23, the Zener diode 22 is connected between the base of the control transistor 21 and the photocell 1 connected to the negative bus, and the contacts of the relay 19 are connected to the terminals of the photo cells 1.

The battery 17 is connected to the device between the positive terminal 18 and the minus bus 5.

The device works as follows. The photo cells 1 produce a voltage, and with sufficient illumination under the action of the emf of the photocell 1 connected to the negative bus, the zener diode 22 punches and the control transistor 21 opens, and the key transistor 20 closes and the current does not flow through the winding of the relay 19. The contacts of the relay 19 remain in the initial state and the photo cells 1 are turned on in parallel. In low light EMF of the photocell 1 connected to the negative bus, the Zener diode 22 decreases and the control transistor 21 closes, and the key transistor 20 opens and a current flows through the winding of the relay 19. The contacts of the relay 19 are switched and the photo cells 1 are switched on in series, increasing the emf at the output of the device. The EMF of the photo cells 1 when the switching transistor 7 is open causes a current through the inductor 3. The switching transistor 7 periodically opens and closes under the action of the control pulses of the master oscillator 8. At the time when the switching transistor 7 closes, the EMF is induced at the terminal of the photo cells 1 Under the action of the EMF of the inductor 3, the storage element 6 is charged through diode 4. Diode 4 eliminates the discharge of storage element 6 through photocell 1. As a storage element It uses large capacitors or ionistors. The charge voltage of the storage element is set using the potentiometer 11 of the threshold device 9. As soon as the voltage on the storage element 6 reaches the desired value, the Zener diode 12 breaks through, the transistor 15 opens, and the switching transistor 7 closes and the charge of the storage element 6 stops. Diode 2 protects the circuit of the device from the inverse inclusion of the battery. The diode 13 has a temperature coefficient for increasing the voltage on the storage cell 6 with decreasing temperature in order to better charge the battery.

On a charge to compensate for self-discharge, serviceable batteries in a charged state are installed. Using a potentiometer 11 sets the voltage level on the cumulative element 6, equal to the EMF of a charged battery. The corresponding voltage level is determined by the zero readings of a milliammeter, which is then switched on in series with the battery to the output of the device.

Then, in the process of self-discharge of the battery, the EMF value decreases, and it starts charging from storage element 6, the voltage across it also decreases, which causes the zener diode 12 and transistor 15 to close. The master oscillator 8 starts working and the switching transistor 7 switches 3 is induced EMF, which leads to the charge of the storage element 6 to the set level.

Thus, the introduction of additional elements into the device to compensate for self-discharge of batteries, namely, the second photocell, a key transistor, a control transistor, a Zener diode, a relay and a resistor make it possible to provide the required recharge voltage at different illumination, since in low light the photo cells are connected in series, increasing the emf at the output of the device, which expands the range of illumination of the device and the applicability of the device.

Claims (1)

A device to compensate for self-discharge of batteries, containing a photocell as a current source, an inverse battery protection diode, a series-connected choke and a diode connected between the positive terminal of the photocell and the anode of the protection diode, a storage element connected between the anode of the protection diode and the negative bus, a switching transistor connected between the midpoint of the junction of the choke and the diode and the minus bus, to the base of which are connected the outputs of the master oscillator and the thresholds th device whose input is connected parallel to the storage element, characterized in that it entered the second photocell, a key transistor, control transistor, zener diode, relay, resistor; the relay coil and the collector circuit of the key transistor are connected in series and connected between the positive and negative buses of the device, and the base of the key transistor is connected between the midpoint of the series-connected resistor and the control transistor, the Zener diode is connected between the base of the control transistor and the photocell connected to the negative bus, and the contacts relays are connected to photocell pins.

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