RU2155426C1 - Automatic charging device - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: device used for charging electrical energy storage units such as storage batteries and storage capacitors is characterized in that charging process is conducted in pulse mode with floating component of charging current; automation is attained by using charging voltage ranging between rated value and voltage permissible for discharged electrical energy storage unit with currents of transformer secondary half-windings being unequal; pulse charging, its indication, ON/OFF operation of device are effected by contactless switch that has thyristor whose anode (gate electrode) is shorted out by light-emitting diode and by cathode connected to gate electrode. Contactless switch and uncontrolled full-wave rectifier are cooled down by means of semiconductor devices mounted on transformer case and spaced apart at maximal distance. EFFECT: reduced initial current and size of device. 1 dwg

Description

 The present invention relates to electrical engineering, in particular to the maintenance of secondary elements, and can be used to charge electric energy storage devices / NEE /, related by the dependence: the amount of charge accumulated on the element is inversely proportional to its internal resistance, such as batteries and capacitors.

 A device for the pulse charge of the batteries at constant voltage, based on the work of the sound tester-probe, with a constant closing-opening of the contacts which is a constant pulse charge and auditory control over its course [1].

 However, the device uses a circuit containing an audio tester-probe, which has mechanical contacts that wear out during operation and can burn and stick together at a significant current, which ultimately reduces the reliability of the device. In addition, the operation of the device creates radio interference.

 The closest in technical essence and the achieved result is a device for charging batteries with a pulsating current [2]. For this, static electric power converters / SPEE / are used, the rectification schemes of which are made on thyristors. In addition, the following are used in the general circuit: a pulse forming unit, an auxiliary thyristor unit, and a high-frequency generator. Devices containing a large number of elements are structurally complex and, as a result, unreliable.

 SPEE, like most ACUs, unlike the present invention, are made according to the general principle and contain a sensing element that senses the voltage of the constant voltage source (usually this is a voltage divider), a comparison element in which the voltage of the constant voltage source is compared with a reference value / usually this stabilization voltage of the Zener diode /, and a regulatory body that changes the charging characteristics if the voltage of the DC voltage source differs from the reference value. But since the electromotive force / EMF / of a discharged battery having a high-density electrolyte will be greater than the EMF of a charged battery with a weaker solution, therefore, it is impossible to be guided by the measurement of the EMF without an connected load on the degree of charge of a battery with an unknown initial density of the solution.

 In contrast, the present invention provides, in the role of the reference value, not voltage, but current.

In addition, the objective of the invention is:
- improving the reliability of the AZU by simplifying the design;
- increase the service life of NOE by increasing the efficiency of their charge;
- automation of the charge mode with a minimum of circuit elements;
- the introduction of the main pulsed charge mode, contributing to a better flow of electrochemical processes in the NEE;
- the introduction of an additional pulsed charge mode for a deeper restoration of the active mass of the plates;
- a partial decrease in current in the initial period of the charge and a decrease in the effect of voltage fluctuations in the network on the charging current, a decrease in the dimensions of the ACS, effective cooling of semiconductor devices and an indication of the charge process due to the combined use of elements.

The task:
- improving the reliability of the AZU, due to the simplification of the design, is solved by a circuit solution containing a small number of elements;
- increase the service life of NOE, by increasing the efficiency of their charge, is solved by a charge in a pulsed mode with a floating component of the charging current, depending on the state of the NEE, fluctuations in the mains voltage and characteristics of the supply transformer of the AZU;
- automation of the charge mode with a minimum of circuit elements is solved by reducing the charging voltage to a value less than the nominal voltage of the charged NEE, but greater than the voltage of an admissible discharged NEE so that the value of the mains voltage serves as a limiter of the maximum charging voltage of the NEE;
- the introduction of the main pulsed charge mode, contributing to a better flow of electrochemical processes in the NEE, is solved by the fact that the values of the charging current of the secondary half-windings of the supply transformer are not equal to each other;
- the introduction of an additional pulse charge mode for a deeper restoration of the active mass of the plates is solved by means of a contactless key / BK /, included in the gap of any wire leading to the NEE terminals from the rectifier, subject to the appropriate polarity, and consisting of a thyristor and an LED that serves as an indicator of the charging process included in the circuit anode-control electrode of the thyristor;
- a partial decrease in current in the initial period of the charge and a decrease in the effect of voltage fluctuations in the network on the charging current is solved by using the transformer casing as the limiting resistance;
- reducing the dimensions of the ACU, effective cooling of semiconductor devices is solved by fixing the diodes of a half-wave uncontrolled rectifier and thyristor BK on the casing of the supply transformer at a maximum distance from each other;
- indication of the charge process is solved using the BC as a device that provides an indication of the connected load.

 The general availability of the element base, the technical nature and the achieved result ensure the claimed technical solution meets the criterion of "industrial applicability".

 Comparison of the claimed technical solution with the prototype made it possible to establish compliance with its criterion of "novelty."

 In the study of other well-known technical solutions in the art, the features that distinguish the claimed invention from the prototype were not identified and do not explicitly follow from the prior art, and therefore they provide the claimed technical solution with the criterion of "inventive step".

 The drawing shows a circuit diagram of the AZU.

 The AZU contains output terminals 1 and 2 for connecting the battery 3, the supply transformer 4, the secondary winding of which is connected to the midpoint with a half-wave uncontrolled rectifier from diodes 5 and 6, the anodes of which are connected to the output terminal of negative polarity through the secondary winding of the transformer and its midpoint; and the cathodes connected together with the anode of the BK through the casing of the supply transformer 4, through the cathode of the BK - to the terminal of positive polarity of the battery.

 The BC consists of a thyristor 7, in the anode circuit the control electrode of which is connected by LED 8 by the cathode to the control electrode.

 AZU works as follows.

At the beginning of the charging process, the voltage on the battery 3 is small, the thyristor 7 is opened by current through the LED 8. The following conditions are met:
I _у = U _pit / R≥I _у.ot ,
where R = R ₁ + R ₂ ,
I _y is the current of the control electrode,
U _pit is the voltage of the anode supply,
R ₁ is the resistance of the LED,
R ₂ is the resistance of the battery,
I _u.ot - unlocking control current.

After opening the device, the voltage at the anode decreases, all the voltage of the power source is practically applied to the battery, and a small current equal to
I _y = U _OS / R ₂ ,
where U _OS - the voltage drop across the thyristor, due to the current in the open state.

The glow of the LED 8 indicates the flow through it of the current of the control electrode I _{at the} thyristor. The flickering of LED 8 indicates the thyristor is turned on and off when half-waves of the supply voltage pass, and the larger the difference in the current values of the secondary half-windings of the supply transformer 4 with the two-half-wave uncontrolled rectifier connected to them, the more flicker is. This difference in current values creates the main pulsed charge mode and contributes to a better flow of electrochemical processes in the battery 3.

где t - время заряда.The battery 3 is charged in the same way as a capacitor, the charging current I _{pr of the} capacitor C through a resistor R from a constant voltage source U _pit decreases exponentially during charging

where t is the charge time.

By the end of the charge, the charging current I _pr through the thyristor 7 decreases and becomes lower than the level of the holding current I _beats , while the resistance of the LED increases to a value at which the condition
I _at <I _at
and thyristor 7 turns off.

 The differential resistance of LED 8 can be from 40 Ohms at a current of 1 MA to 4-6 Ohms at a current of 10 MA, with each resistance value corresponding to its own brightness of the LED.

After a certain discharge of the battery 3, the voltage on it decreases, the ratio
I _ol <I _beats ,
I _at <I _at
disturbed to the side
I _ol > I _beats ,
I _y > I _y.ot
and the thyristor turns on again.

 The process repeats with a blinking LED.

 The battery is cycled by a pulse current, different in magnitude in each pulse and depending on the state of the battery and surges in the mains voltage supplied to the supply transformer. This is the period of the additional pulsed charge mode, intended for a deeper restoration of the active mass of the battery plates.

 To reduce the current value in the initial period of the charge and reduce the influence of voltage fluctuations in the network on the charging current, a limiting resistance of small value 9 is introduced into the electric circuit. This resistance is played by a transformer casing 4, on which diodes of an uncontrolled rectifier and thyristor are mounted as far as possible from each other BC. The transformer casing also acts as a radiator of semiconductor devices.

 In a specific case, the implementation of the AZU contained a supply transformer 4 of the TN-61-220 / 50-K brand, the four secondary windings of which, connected in series, produced a voltage of 22.6 V AC, with two series-connected windings giving 9.2 A, two others connected in series, 7 A. A two-half-wave uncontrolled rectifier on diodes 5 and 6 of type D 214 was connected to the common secondary winding of the supply transformer 4. Thyristor 7 is a triac ТС 112-16-6 and diodes 5 and 6 were mounted on the casing of transformer 4 on maximum beats alenia from each other. In the circuit anode-control electrode of the thyristor 7 was included LED 8 brand AL 307 BM, and its cathode to the control electrode. The batteries were charged, both acid and alkaline, of different brands, capacities and the degree of charge with a nominal voltage of 12 V. For all batteries, the charge was the same. When turning on the AZU, there is a sharp decrease in the charging current to 1 / 7-1 / 15 of the nominal battery capacity. Then, some stabilization of the charging current to a further decrease to a value of 0.5 - 0.7 A, at which the BC switches to a pulsating mode, then the current decreases to a charge value of 0 - 0.15 A. During the charge, when gas is released, its intensity decreases, and during BC operation, gas evolution practically disappears completely.

 As tests have shown, for a quick charge of batteries it is better to use night time, when the mains voltage rises to 240 - 250 V, and then decreases during the day to the nominal value at which the battery, when the battery is charged, turns off.

 Mains voltage acts as a limiter of the maximum charging voltage.

 RAM can be small in size and at least parts with a 100% battery charge. The use of a pulse mode with a floating component of the charging current makes it possible to more fully use the active mass of the plates and increase their service life.

 Thus, with a minimum of circuit elements, the task of servicing secondary elements, in particular the charge of electric energy storage devices, related by the dependence of the amount of charge accumulated on the element, is inversely proportional to its internal resistance, such as batteries and capacitors, is solved.

Bibliographic data
1. RF patent N 2012978, cl. H 02 J 7/00, 1994

 2. Atamanenko S. A., Shvalev E.B. Diagnostics and ways to extend the life of lead-acid batteries. - L .: The Knowledge Island of the RSFSR, Leningrad Region, LD NTP, 1990. - 16 p., Ill.

Claims (1)

 An automatic charger for charging electric energy storage devices (NEE), on which the amount of accumulated charge is inversely proportional to the internal resistance, containing output terminals for connecting the NEE, a supply transformer, the secondary winding of which is connected to a half-wave uncontrolled rectifier, characterized in that the charging voltage is less than the nominal voltage of the charged NEE, but greater than the voltage of the permissible discharged NEE, the magnitude of the charging current of the secondary semi-windings of the supply transformer are not equal to each other, a non-contact switch is introduced, consisting of a thyristor and an LED, connected to the anode-control electrode of the thyristor by a cathode to the control electrode, and the anode of the diodes of a half-wave uncontrolled rectifier through the secondary winding of the supply transformer and its midpoint are connected to the output terminal for connecting the NOE of negative polarity, and their cathodes connected to the anode of the contactless key through the casing of the power transformer, through the cathode of the contactless key yucheny to the output terminal for connection of IEE positive polarity, as limiting resistance and the heat sink of semiconductor devices using a transformer casing.