KR20110113151A - Restoration apparatus of battery - Google Patents

Abstract

The present invention relates to a battery regeneration device for restoring spent battery to have a performance comparable to that of a new battery.
Battery regeneration device according to the invention SMPS for converting the input commercial AC power to DC power; A restoration power supply for converting the DC power input from the SPMS into a pulse wave power source and applying the same to the cell plate of the battery to decompose the sulfate adhered to the cell plate into sulfate ions; A discharge unit for discharging the charging power of the battery charged by the pulse wave power applied by the restoration power supply unit; A charging power supply unit converting the DC power input from the SMPS into a charging current of constant current and charging the battery by applying the same to the battery; A detector configured to detect a charging voltage of the battery; A switching unit for connecting or disconnecting a battery, the restoration power supply unit, and a battery and the charging power supply unit; And a microcomputer for controlling the restoration power supply unit, the discharge unit, the charging power supply unit, and the switching unit according to the detection signal of the detection unit and a predetermined program. do.

Description

Battery regeneration device

The present invention relates to a battery regeneration device for restoring spent battery to have a performance comparable to that of a new battery.

As a secondary battery, a battery performs a function by repeating a charge for converting electrical energy into chemical energy and a discharge for converting chemical energy into electrical energy.

These batteries gradually lose their performance over long periods of use and are discarded.

The reason for the battery's poor performance and discarding is that sulfation occurs in the cell plate of the battery, which increases the resistance inside the battery.

Here, the sulphation phenomenon refers to a phenomenon in which sulphate is fixed and adhered to the cell plate in a process of repeating charging and discharging.

The battery consists of an electrolyte solution in which distilled water and sulfate ions are mixed, and cell plates contained in the electrolyte solution.Sulfate ions are converted to sulfates in the discharging process and adhered to the cell plates. As it melts.

However, if the discharge and charge are repeated for a long time, the sulfate attached to the cell plate is fixed to the cell plate without being converted into sulfate ion, thereby degrading the performance of the battery.

When the performance of the battery is degraded, it is discarded and replaced with a new battery, which is inefficient because the replacement cost and disposal cost of the battery are considerable.

Therefore, a technology related to a regeneration device and a regeneration method for regenerating a waste battery having degraded performance has been disclosed.

Conventional technologies related to the recycling method and the regeneration device of the waste battery include Patent No. 0931510, "Regeneration device of a storage battery", Patent No. 0681529, "Regeneration and restoration method of a used battery".

The present invention dissolves the sulfate fixed in the cell plate through repeated chemical reactions to dissolve the sulfate into sulfate ions, the specific gravity of the sulfate ion of the battery electrolyte to a new level to restore the function of the battery to its original state, thereby improving the life of the battery An object of the present invention is to provide an extendable battery regeneration device.

Battery regeneration device according to the present invention for achieving the above object is

SMPS for converting input commercial AC power to DC power;

A restoration power supply for converting the DC power input from the SPMS into a pulse wave power source and applying the same to the cell plate of the battery to decompose the sulfate adhered to the cell plate into sulfate ions;

A discharge unit for discharging the charging power of the battery charged by the pulse wave power applied by the restoration power supply unit;

A charging power supply unit converting the DC power input from the SMPS into a charging current of constant current and charging the battery by applying the same to the battery;

A detector configured to detect a charging voltage of the battery;

A switching unit for connecting or disconnecting a battery, the restoration power supply unit, and a battery and the charging power supply unit;

And a microcomputer for controlling the restoration power supply unit, the discharge unit, the charging power supply unit, and the switching unit according to the detection signal of the detection unit and a predetermined program.

Charge the sulphate adhering to the cell plate of the battery after decomposing it above the standard value.

And a display connected to the microcomputer and displaying a regeneration process of the battery.

A buzzer connected to the microcomputer and outputting a warning sound when an abnormality occurs in a battery regeneration process;

A constant voltage unit supplying driving power to the microcomputer by converting the output power of the SPMS into a constant voltage;

A heat dissipation fan controlled by the microcomputer and dissipating heat generated during a regeneration process to the outside;

A shunt resistor for detecting a voltage and a current of a power applied to a battery and transmitting the detected voltage to the microcomputer;

And a power controller configured to control the voltage and current of the power applied by the restoration power supply unit and the charging power supply unit to the battery by the control of the microcomputer according to the voltage and current detected by the shunt resistor. .

The battery regeneration device according to the present invention having such a configuration is to decompose the sulphate into 99% sulfate ion by chemical reaction through repeated charge and discharge of the battery, in which the sulphate is fixed to the cell plate, thereby restoring to 95% or more performance of the new product. It is an invention that is very useful for industrial development as a device having the effect of saving energy and preventing pollution.

1 is a block diagram of a battery regeneration device according to the present invention.

Before describing the battery regeneration device according to the present invention with reference to the drawings in detail, the process of regenerating the battery in the present invention will be briefly described.

According to the present invention, before regeneration (restoration) of the battery, the screening power supply unit supplies the screening power of the constant current to the waste battery, and the controller measures the voltage of the battery to determine whether the battery is reproducible.

If the voltage of the battery suddenly bounces greatly or no voltage is detected when the selective power is supplied to the battery, the battery is disposed of as a non-renewable battery.

In the battery restoring step, the restoring current supply unit supplies a constant current pulse wave power source to the battery, decomposes the sulfate adhered to the cell plate, ionizes sulfuric acid, and mixes the electrolyte into the electrolyte.

The recovery current is a pulse wave (PP / high frequency) corresponding to several MHz at several Hz, and 10,000 or more pulse waves per second flow through the cell plate to give an electric shock to the cell plate to decompose the sulfate attached to the cell plate Convert to ions.

As a result, the movement of positive and negative ions in the electrolyte becomes active, resulting in a clean cell plate and a pure electrolyte, and the waste battery is restored to a battery having 95% or more performance of the new battery.

In the restoration step, the pulse wave power is not supplied only once, and after the pulse wave power is supplied for a predetermined time, the degree of decomposition of the sulfate is detected. When the decomposition is below the reference value, the pulse wave power is supplied again to decompose the sulfate.

At this time, before the pulse wave power is supplied again, the discharge unit discharges the power charged in the battery by the pulse wave power and supplies the pulse wave power again.

When the sulfate is decomposed cleanly, the voltage of the battery and the specific gravity of the electrolyte are close to that of the new battery.

In the battery charging step, the restoration is completed and the battery is charged by supplying a constant current charging power to the discharged battery.

The constant current of the charging power supply is larger than the pulse wave power supply which is the constant current of the restoration step.

Hereinafter, a battery regeneration device according to the present invention will be described in detail with reference to the accompanying drawings.

The battery regeneration device according to the present invention includes a microcomputer 10, an SMPS 20, a restoration power supply unit 30A, a charging power supply unit 30B, a constant voltage unit 40, a power control unit 50, a switching unit 60, The detector 70, the buzzer 80, the display 90, the shunt resistor 100, the heat dissipation fan 110, and a discharge unit (not shown) are formed.

The microcomputer 10 controls the operation of the components of the regeneration apparatus according to the present invention, monitors the state, and the concentration of sulfate ions in the electrolyte of the battery B is greater than or equal to the reference value through the restoration power supply unit 30A and the discharge unit. After the pulse wave power is applied and discharge of the charging power is continued until it is maintained, the charging power is supplied through the charging power supply unit 30B to charge the regenerated battery B, and the switching unit 60 is provided. Connect or cut off the battery B and the restoration power supply unit 30A or the charging power supply unit 30B, and display the playback process information on the display 90 to inform the user, and if an abnormality occurs through the buzzer 80 The battery reproducing apparatus according to the present invention is controlled as a whole by generating a warning sound to the user.

The SMPS 20 converts input commercial AC power into DC power.

The restoration power supply unit 30A converts the DC power input from the SPMS 20 into a pulse wave power source, and applies it to the cell plate of the battery B to decompose the sulfate salt adhered to the cell plate into sulfate ions.

The discharge unit discharges the charging power of the battery B charged by the pulse wave power applied from the restoration power supply 30A.

The charging power supply unit 30B converts the DC power input from the SMPS 20 into a charging current of constant current, and applies the same to the battery B to charge the battery.

The detector 70 detects a charging voltage of the battery B and transmits the detected voltage to the microcomputer 10.

The switching unit 6 connects or disconnects the battery B, the restoration power supply unit 30A, and the battery B and the charging power supply unit 30B.

The display 90 is connected to the microcomputer 10 and displays a playback process of the battery B to inform the user.

The buzzer 80 is connected to the microcomputer 10 and outputs a warning sound to warn the user when an abnormality occurs in the regeneration process of the battery B.

The constant voltage unit 40 converts the output power of the SPMS 20 into a constant voltage and supplies driving power to the microcomputer 10.

The heat dissipation fan 110 is controlled by the microcomputer 10 and discharges heat generated during the regeneration process to the outside.

The shunt resistor 100 detects the voltage and current of the power applied to the battery B and transmits the detected voltage and current to the microcomputer 10.

The power control unit 50 is controlled by the microcomputer 10 according to the voltage and current detected by the shunt resistor 100, the restoration power supply 30A and the charging power supply 30B is a battery (B) Control the voltage and current of the power supply.

In the above description of the present invention, a battery reproducing apparatus having a specific configuration has been described with reference to the accompanying drawings, but the present invention can be variously modified and changed by those skilled in the art, and such modifications and changes are within the protection scope of the present invention. Should be interpreted as belonging.

10: microcomputer 20: SMPS
30A: Restoration power supply 30B: Charging power supply
40: constant voltage 50: power supply control unit
60: switching unit 70: detection unit
80: buzzer 90: display
100: shunt resistor 110: heat dissipation fan

Claims (2)

SMPS for converting input commercial AC power to DC power;
A restoration power supply for converting the DC power input from the SPMS into a pulse wave power source and applying the same to the cell plate of the battery to decompose the sulfate adhered to the cell plate into sulfate ions;
A discharge unit for discharging the charging power of the battery charged by the pulse wave power applied by the restoration power supply unit;
A charging power supply unit converting the DC power input from the SMPS into a charging current of constant current and charging the battery by applying the same to the battery;
A detector configured to detect a charging voltage of the battery;
A switching unit for connecting or disconnecting a battery, the restoration power supply unit, and a battery and the charging power supply unit;
And a microcomputer for controlling the restoration power supply unit, the discharge unit, the charging power supply unit, and the switching unit according to the detection signal of the detection unit and a predetermined program.
Battery regenerator which charges after dissolving sulfate adhered to the cell plate of battery above the standard value. The method of claim 1,
A display connected to the microcomputer and displaying a regeneration process of a battery;
A buzzer connected to the microcomputer and outputting a warning sound when an abnormality occurs in a battery regeneration process;
A constant voltage unit supplying driving power to the microcomputer by converting the output power of the SPMS into a constant voltage;
A heat dissipation fan controlled by the microcomputer and dissipating heat generated during a regeneration process to the outside;
A shunt resistor for detecting a voltage and a current of a power applied to a battery and transmitting the detected voltage to the microcomputer;
And a power controller configured to control the voltage and current of the power applied by the restoration power supply unit and the charging power supply unit to the battery by the control of the microcomputer according to the voltage and current detected by the shunt resistor. Battery regenerator.

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