KR20220138918A - Apparatus and method for recycling lead-acid battery - Google Patents

Abstract

The present invention relates to an apparatus for restoring performance of a waste lead-acid battery and a method for restoring performance of a waste lead-acid battery using the same. The apparatus for restoring performance of a waste lead-acid battery comprises: a power supplying unit which receives external AC power to convert the same to DC power, and outputs and supplies the converted DC power; a pulse generating unit which receives the DC power supplied from the power supplying unit to generate high-frequency forward-reverse pulse, and supplies restoration power having currents and voltages linked to the generated high frequency forward-reverse pulse to the lead-acid battery; a protective circuit unit which is a protective circuit connected between the pulse generating unit and the lead-acid battery, and blocks short-circuit currents and overcurrent transmitted from the pulse generating unit to the lead-acid battery; a voltage detection unit which is connected to the protective circuit unit and detects a cell voltage value of the lead-acid battery; and a restoration control unit which, based on the cell voltage value of the lead-acid battery detected through the voltage detection unit, divides the high frequency forward-reverse pulse and the restoration power provided through the power supplying unit and the pulse generating unit multiple times, supplies the same to the lead-acid battery under different setting values and causes reduction of sulphates which is sticked and formed on a polar plate of the lead-acid battery. Accordingly, the present invention prevents the decrease of the performance restoration efficiency and has recharging time efficiently consumed.

Description

Waste lead-acid battery performance restoration device and waste lead-acid battery performance restoration method using the same {APPARATUS AND METHOD FOR RECYCLING LEAD-ACID BATTERY}

The present invention relates to an apparatus for restoring performance of a waste lead-acid battery and a method for restoring the performance of a waste lead-acid battery using the same and performing charging.

A lead-acid battery is a secondary battery using lead and sulfuric acid, and an electrolyte for accumulating electricity through a chemical reaction is provided inside to contain sulfuric acid and water, and (+) and (-) ) It has a shape in which the metal plate forming the pole is contained, forming a constituent unit called a cell.

These lead-acid batteries show a phenomenon in which their capacity is reduced by repeating charging and discharging. This is because it causes a decrease in the active material of

More specifically, the lead-acid battery stores electrical energy by the oxidation/reduction reaction as shown in FIG. 4 , and lead sulfate (PbSO ₄ ) is generated in the process of discharge, which is reversible when charging. However, there is irreversible lead sulfate that is not dissociated during the charging reaction because it is adhered to the electrode plate due to various causes among the lead sulfate generated during discharge.

The irreversible lead sulfate, which is not decomposed in this way, causes a decrease in the capacity of the lead-acid battery, and as a result, leads to a decrease in the performance of the lead-acid battery, and becomes a waste lead-acid battery, making it impossible to use.

Therefore, in order to restore the performance of the spent lead-acid battery generated by repeated use and to enable the reuse of the lead-acid battery through regeneration, various techniques for reducing the irreversible lead sulfate adhering to the electrode plate have been proposed.

In this regard, in the prior art on the prior art prepared to provide a battery restoration device capable of stably and efficiently restoring the battery while reducing the possibility of battery explosion and generating micro-bubbles to remove the waste of the battery, Republic of Korea Patent Publication No. 10 There is a "battery restoration device that cross-generates high-frequency forward and reverse pulses" (hereinafter referred to as 'prior art') of -1521604.

However, in the case of technologies related to performance restoration of waste lead-acid batteries, including the prior art, in order to drop the lead sulfate adhered to the electrode plate, a strong voltage and pulse waveform were randomly applied from the beginning. There was a problem in that excessive energy was applied to the pole plate, leading to damage to the pole plate and consequently affecting the performance degradation of the pole plate.

In addition, in the case of technologies related to performance restoration of waste lead-acid batteries, including the prior art, in the process of causing irreversible reduction of lead sulfate by applying a strong voltage and pulse waveform from the beginning to drop lead sulfate adhering to the electrode plate. Since the chemical mechanism of the change in the specific gravity of sulfuric acid was not taken into account at all, the effective performance restoration function of the lead-acid battery could not be expressed, but rather lead to damage to the electrode plate or it took a lot of time to complete the performance restoration.

The present invention was created to solve the above problems, and an object of the present invention is to restore the performance of the waste spasmodic anterior teeth through the reduction of lead sulfate adhering to the electrode plate, thereby regenerating and recharging the electrode plate to prevent damage to the electrode plate. To provide a waste lead-acid battery performance restoration device and a waste lead-acid battery performance restoration method using the same, which can efficiently take time for restoration and recharging based on the same without reducing the efficiency of performance restoration.

In order to achieve the above object, the waste lead-acid battery performance restoration device of the present invention is electrically connected to the lead-acid battery and reduces the sulfate formed adhering to the electrode plate of the lead-acid battery through the application of power to cause the performance of the lead-acid battery to restore the performance of the waste lead-acid battery A restoration device comprising: a power supply unit for receiving AC power from the outside, converting it into DC power, and outputting the converted DC power; a pulse generator for receiving the DC power supplied from the power supply unit to generate a high-frequency forward/reverse pulse, and supplying power for restoration having a current and voltage linked to the generated high-frequency forward/reverse pulse to the lead-acid battery; As a protection circuit connected between the pulse generating unit and the lead-acid battery, a protection circuit unit for blocking the short-circuit current and the overload current transmitted to the lead-acid battery from the pulse generating unit; It is connected to the protection circuit unit, the protection circuit lead-acid battery voltage detection unit for detecting the cell voltage value of the lead-acid battery; And on the basis of the cell voltage value of the lead-acid battery detected through the voltage detection unit, the high-frequency forward and reverse pulses and the power for restoration provided through the power supply unit and the pulse generation unit are divided by multiple times and supplied to the lead-acid battery under mutually different set values. and a restoration control unit that causes the reduction of the sulfate formed adhering to the electrode plate of the lead-acid battery.

Here, the restoration control unit, by setting the cell voltage value of the lead-acid battery detected through the voltage detection unit to the first applied voltage state, the power supply for restoration provided through the power supply unit and the pulse generator to the first applied state In accordance with, in the process of applying for a predetermined period of time to the lead-acid battery, by detecting the cell voltage value of the lead-acid battery through the voltage detection unit, a restoration possibility determination part for determining whether restoration is possible; includes; the restoration possibility determination part is performed by performing the detection of the cell voltage value of the lead-acid battery through the voltage detection unit over multiple times according to a predetermined detection unit time within the determination time, only when the cell voltage value of the lead-acid battery is 1.62V or less as a result of the lead-acid battery It is determined that the restoration of the lead-acid battery is regenerated through the restoration control unit.

In addition, when it is determined that the restoration of the lead-acid battery is possible through the restoration possibility determination part, the restoration control unit has a high-frequency forward and reverse pulse through the power supply unit and the pulse generator according to the second application state of a preset micro voltage A first restoration control part for applying the provided power supply to the lead-acid battery until the cell voltage value of the lead-acid battery is detected through the voltage detection unit and the cell voltage value of the lead-acid battery corresponds to 1.80V; When the power for restoration provided in accordance with the second applied power state through the first restoration control part is applied to the lead-acid battery and the cell voltage value of the lead-acid battery reaches 1.80V, the high frequency frequency is passed through the power supply unit and the pulse generator As a result of detecting the cell voltage value of the lead-acid battery through the voltage detection unit, the power for restoration provided in accordance with the third applied state, which is a preset voltage to gradually increase with time for the restoration of the forward and reverse pulses and the lead-acid battery, the cell voltage of the lead-acid battery a second restoration control part applied to the lead-acid battery until the value corresponds to 2.20V; And when the restoration power provided in accordance with the third applied power state through the second restoration control part is applied to the lead-acid battery and the cell voltage value of the lead-acid battery reaches 2.20V, through the power supply unit and the pulse generator As a result of detecting the cell voltage value of the lead-acid battery through the voltage detector, the power for restoration provided in accordance with the fourth application state, which is a preset voltage for charging the lead-acid battery and the high-frequency forward and reverse pulse, the cell voltage value of the lead-acid battery is 2.40 It includes; a third restoration control part applied to the lead-acid battery until it corresponds to V, wherein the voltage of the power supply for restoration according to the third application state is compared to the micro voltage of the restoration power supply according to the second application state high, and is in a low state compared to the voltage of the power source for restoration according to the fourth application state.

And the waste lead-acid battery performance restoration device, the restoration power provided in accordance with the fourth applied power state through the third restoration control part is applied to the lead-acid battery after the cell voltage value of the lead-acid battery reaches 2.40V , through the power supply unit and the pulse generator, a high-frequency forward/reverse pulse and a charging power provided in accordance with the fourth applied state, which is a preset voltage for charging of the lead-acid battery, through the voltage detection unit to detect the cell voltage value of the lead-acid battery A charging control unit for performing charging by applying to the lead-acid battery until the cell voltage value of the lead-acid battery as a result corresponds to the charge termination voltage; further includes.

On the other hand, the waste lead-acid battery performance restoration method using the waste lead-acid battery performance restoration device of the present invention in order to achieve the above object, the cell voltage value of the lead-acid battery in which the restoration possibility determination part in the restoration control unit is detected through the voltage detection unit is set to the first applied voltage state, and in the process of applying the power for restoration provided through the power supply unit and the pulse generating unit to the lead-acid battery in accordance with the first applied state for a predetermined period of time, it is connected through the voltage detection unit. A step of determining whether restoration is possible by detecting the cell voltage value of the storage battery; When it is determined that the restoration of the lead-acid battery is possible through the restoration possibility determination part, the first restoration control unit in the restoration control unit has a high-frequency forward and reverse pulse through the power supply unit and the pulse generator, and a second application of a preset microvoltage B step of applying the power for restoration prepared according to the state to the lead-acid battery until the cell voltage value of the lead-acid battery is detected through the voltage detection unit and the cell voltage value of the lead-acid battery corresponds to 1.80V; When the second restoration control unit in the restoration control unit is applied to the lead-acid battery according to the second applied power state through the first restoration control unit, the power for restoration is applied to the lead-acid battery and the cell voltage value of the lead-acid battery reaches 1.80V , through the power supply unit and the pulse generator, the high-frequency forward/reverse pulse and the cell voltage of the lead-acid battery through the voltage detection unit, the power for restoration provided in accordance with the third application state, which is a preset voltage to gradually increase with time for restoration of the lead-acid battery C step of applying the lead-acid battery until the cell voltage value of the lead-acid battery corresponds to 2.20V as a result of detecting the value; And the third restoration control unit in the restoration control unit through the second restoration control unit, the power for restoration provided in accordance with the third applied power state is applied to the lead-acid battery so that the cell voltage value of the lead-acid battery reaches 2.20V. In the case, through the power supply unit and the pulse generating unit, the high-frequency forward/reverse pulse and the cell voltage value of the lead-acid battery are detected by the voltage detection unit for restoration power provided in accordance with the fourth application state, which is a preset voltage for charging the lead-acid battery. As a result, step D of applying to the lead-acid battery until the cell voltage value of the lead-acid battery corresponds to 2.40V; includes, wherein the voltage of the power source for restoration according to the third applied state is restored according to the second applied state It is higher than the micro voltage of the power supply for use, and is lower than the voltage of the power supply for restoration according to the fourth application state.

Here, in the step A, the recovery possibility determination part performs the detection of the cell voltage value of the lead-acid battery through the voltage detection unit over multiple times according to a predetermined detection unit time within the determination time, the result of the lead-acid battery Only when the cell voltage value is 1.62V or less, it is determined that the restoration of the lead-acid battery is possible, so that the regeneration of the lead-acid battery occurs through the restoration control unit.

And the waste lead-acid battery performance restoration method using the waste lead-acid battery performance restoration device, the restoration control unit is provided in accordance with the fourth applied power state through the third restoration control part, the restoration power is applied to the lead-acid battery, the lead-acid battery After the cell voltage value of the storage battery reaches 2.40V, the power supply for charging provided in accordance with the fourth application state, which is a predetermined voltage preset for charging of the high-frequency forward and reverse pulses and lead-acid batteries, through the power supply unit and the pulse generator is supplied to the E-step of performing charging by applying to the lead-acid battery until the result of detecting the cell voltage value of the lead-acid battery through the voltage detection unit corresponds to the cell voltage value of the lead-acid battery corresponds to the charge termination voltage; further includes.

According to the present invention, there are the following effects.

First, the performance restoration function can be properly provided without damaging the electrode plate and lowering the efficiency of performance restoration by restoring the performance of the spent spasmodic anterior teeth through the reduction of lead sulfate adhering to the electrode plate, regenerating it and recharging it so that it can be reused. have.

Second, in order to drop lead sulfate adhering to the electrode plate, different voltages and pulse waveforms are applied multiple times to cause irreversible reduction of lead sulfate, taking into account chemical factors that change the specific gravity of sulfuric acid in electrolytes to restore the performance of lead-acid batteries The function is expressed, and not only provides a more effective performance restoration function, but also minimizes damage to the electrode plate, thereby effectively extending the service life.

Third, time for restoration and recharging based thereon can be efficiently consumed.

Fourth, as the effective performance restoration function can be applied even for lead-acid batteries with a rating rate of less than 50%, the application range can be expanded and economic feasibility improvement based on this can also be expected.

1 is a block diagram showing the detailed structure and configuration of a waste lead-acid battery performance restoration device according to the present invention.
Figure 2 is a flow chart showing a waste lead-acid battery performance restoration method using the waste lead-acid battery performance restoration device according to the present invention.
3 is a curve graph showing the relationship between the lead-acid battery cell voltage value, which is the basis of the restoration algorithm performed through the restoration control unit of the waste lead-acid battery performance restoration device according to the present invention, and the specific gravity of sulfuric acid in the electrolyte.
4 is a diagram illustrating an oxidation/reduction reaction equation occurring between an electrode plate and an electrolyte in the process of performing charging and discharging through a conventional lead-acid battery.

A preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings, but the already known technical parts will be omitted or compressed for the sake of brevity of description.

1. Description of the waste lead-acid battery performance restoration device

Referring to Figure 1, the waste lead-acid battery performance restoration device 100 of the present invention is one side is electrically connected to the external power supply source (10), the other side is electrically connected to the lead-acid battery (20) to apply power The power supply 110, the pulse generator 120, the circuit breaker 130, the voltage detector 140 to reduce the sulfate (lead sulfate) formed adhering to the electrode plate of the lead-acid battery 20 through the lead-acid battery to restore the performance of the lead-acid battery. ), a restoration control unit 150 and a charging control unit 160 .

The power supply unit 110 is an SMPS (Switching Mode Power Supply) module that receives AC power from the external power supply source 10, converts it into DC power, and outputs the converted DC power, and a restoration control unit 150 to be described later. And it is controlled to a predetermined voltage according to the control command of the charging control unit 160 performs supply so that it can be used for restoration or charging.

Pulse generating unit 120 receives the DC power supplied from the power supply unit 110 to generate a high-frequency forward/reverse pulse, and restore power having a current and voltage linked to the generated high-frequency forward/reverse pulse to the lead-acid battery 20. supply to supply

Here, the DC power-based high-frequency forward/reverse pulse generated through the pulse generator 120 preferably has a frequency band of 15,000 to 40,000 Hz by the pulse width modulation (PWM) method, but is not limited thereto, and various within the high-frequency region. can be implemented

The circuit breaker 130 is a protection circuit connected between the pulse generating unit 120 and the lead-acid battery 20, and a short-circuit current in the process of power being transferred from the pulse generating unit 120 to the lead-acid battery for restoration or charging. and a configuration for blocking an overload current, and a configuration for detecting a voltage value of the voltage detection unit 140 through connection with the voltage detection unit 140 to be described below.

In connection with this, the voltage detection unit 140 is connected to the protection circuit unit, and by detecting the cell voltage value of the lead-acid battery, the restoration control unit 150 and the charging control unit 160 are information that is based on the performance of the performance restoration function and the charging function. make it available for use.

Restoration control unit 150 is based on the cell voltage value of the lead-acid battery 20 detected through the voltage detection unit 140 through the power supply unit 110 and the pulse generating unit 120 is provided through the high-frequency forward and reverse pulses and power for restoration is divided by multiple times and supplied to the lead-acid battery 20 under mutually different set values to cause the reduction of the sulfate (lead sulfate) formed adhering to the electrode plate of the lead-acid battery 20.

Here, the restoration control unit 150 has a different voltage, voltage, and high-frequency forward and reverse pulse application form for each cycle in performing control through the provision of the performance restoration function over three times so as to stably cause minimal damage to the electrode plate. .

To this end, the restoration control unit 150 includes a restoration possibility determination unit 151 , a first restoration control unit 152 , a second restoration control unit 153 , and a third restoration control unit 154 .

First, the restoration possibility determination unit 151 sets the cell voltage value of the lead-acid battery detected through the voltage detection unit 140 to the first applied voltage state, through the power supply unit 110 and the pulse generation unit 120 It is determined whether restoration is possible by detecting the cell voltage value of the lead-acid battery 20 through the voltage detection unit 140 in the process of applying the restoration power to the lead-acid battery for a predetermined time according to the first application state. .

Specifically, the restoration possibility determination unit 151 performs the detection of the cell voltage value of the lead-acid battery 20 through the voltage detection unit 140 over multiple times according to a predetermined detection unit time within the determination time, the result of the execution Only when the cell voltage value of the lead-acid battery 20 is 1.62V or less, it is determined that the restoration of the lead-acid battery is possible and the restoration control unit 150 in the first restoration control part 152, the second restoration control part 153 and the second 3 The regeneration of the lead-acid battery step-by-step through the restoration control part 154 to occur.

Here, the restoration possibility determination unit 151 performs the detection of the cell voltage value of the lead-acid battery 20 through the voltage detection unit 140 over 5 times at 2-minute intervals for 10 minutes, and in this process, the result of the As soon as it is confirmed that the cell voltage value of the storage battery 20 is 1.62V or less, the functional activation of the first restoration control part 152 to be described below is made.

Next, when it is determined that the restoration of the lead-acid battery 20 is possible through the first restoration control unit 152 , the restoration possibility determination unit 151 , the power supply unit 110 and the pulse generation unit 120 through the power supply unit 110 and the pulse generation unit 120 . As a result of detecting the cell voltage value of the lead-acid battery 20 through the voltage detection unit 1400 of the power supply for restoration that has a high-frequency forward and reverse pulse and is prepared according to the second application state of a preset micro voltage, the cell voltage value of the lead-acid battery is 1.80V. It is applied to the lead-acid battery 20 until it corresponds.

In addition, the second restoration control part 153 is the first restoration control part 152 through the first restoration control part 152, the power for restoration provided in accordance with the second applied power state is applied to the lead-acid battery 20, the cell voltage value of the lead-acid battery (20) When this 1.80V is reached, the power supply 110 and the pulse generator 120 through the high-frequency forward/reverse pulse and the restoration prepared according to the third applied state, which is a preset voltage to gradually increase with time for restoration of the lead-acid battery As a result of detecting the cell voltage value of the lead-acid battery 20 through the voltage detection unit 140, the power for the lead-acid battery is applied to the lead-acid battery 20 until the cell voltage value of the lead-acid battery corresponds to 2.20V.

Finally, the third restoration control part 154 is applied to the lead-acid battery 20, the power for restoration provided in accordance with the third applied power state through the second restoration control part 153, the cell voltage of the lead-acid battery 20 When the value reaches 2.20V, the power supply 110 and the pulse generator 120 through the high-frequency forward/reverse pulse and the recovery prepared according to the fourth applied state, which is a preset voltage for charging the lead-acid battery 20 Power is applied to the lead-acid battery until the cell voltage value of the lead-acid battery 20 corresponds to 2.40V as a result of detecting the cell voltage value of the lead-acid battery through the voltage detection unit

As such, in the process of performing the reduction of lead sulfate adhered to the electrode plate for performance restoration with different voltages divided over three stages, the voltage of the restoration power according to the third applied state is that of the restoration power according to the second applied state. It is higher than the micro voltage, and is lower than the voltage of the power source for restoration according to the fourth applied state.

The charging control unit 160 is applied to the lead-acid battery 20, the power for restoration provided in accordance with the fourth applied power state through the third restoration control part 154, the cell voltage value of the lead-acid battery 20 reaches 2.40V After that, through the power supply unit 110 and the pulse generator 120, the high-frequency forward/reverse pulse and the charging power provided in accordance with the fourth application state, which is a predetermined voltage preset for charging the lead-acid battery, is applied to the voltage detection unit 140. Through the detection of the cell voltage value of the lead-acid battery 20, the lead-acid battery 20 is applied to the lead-acid battery 20 until the cell voltage value of the lead-acid battery 20 corresponds to the charge termination voltage, so that charging is performed.

2. Description of the method of restoring the performance of the spent lead-acid battery

It will be described in detail below with reference to the flowchart of FIG. 2 for how the method of performing the performance restoration of the spent lead-acid battery using the performance restoration apparatus 100 of the waste lead-acid battery of the present invention is made.

(1) Restoration possibility determination step <S110, A step>

This step (S110) is a process of determining whether the lead-acid battery electrically connected to the waste lead-acid battery performance restoration device 100 is at a level that can be restored as a waste lead-acid battery, or whether the provision of the performance restoration function itself is impossible.

Specifically, in the restoration possibility determination step (S110), the restoration possibility determination unit 151 sets the cell voltage value of the lead-acid battery 20 detected through the voltage detection unit 140 to the first applied voltage state, The power for restoration provided through the supply unit 110 and the pulse generating unit 120 is applied to the lead-acid battery 20 in accordance with the first application state, and the determination is performed within 10 minutes over 5 rounds of 2 minutes.

Through this, in the restoration possibility determination step (S110), it is determined that restoration of the lead-acid battery is possible only when the cell voltage value of the lead-acid battery detected through the voltage detection unit 140 as a result of the determination is 1.62V or less, and the restoration control unit It goes to the first restoration control step (S120) below so that the regeneration of the lead-acid battery occurs.

Otherwise, it is determined that the lead-acid battery electrically connected to the waste lead-acid battery performance restoration device 100 is a complete waste lead-acid battery so that it can be disposed of without performing the performance restoration function.

(2) first restoration control step <S120, B step>

In this step (S120), the first restoration control unit 152 in the restoration control unit 150 applies a minute voltage and a high-frequency forward/reverse pulse to the recoverable waste lead-acid battery 20, which causes little damage to the electrode plate. The process of starting the reduction of sulfate (lead sulfate) little by little is in progress.

Here, the minute voltage means a voltage value of 0.1V to 0.5V, and it is preferable that the output of the high frequency applied therewith is set between 0.1W and 2W.

Specifically, in the first restoration control step (S120), when it is determined that the restoration of the lead-acid battery 20 is possible through the first restoration control unit 152, the restoration possibility determination unit 151, the power supply unit 110 And having a high-frequency forward/reverse pulse through the pulse generating unit 120, the power for restoration provided in accordance with the second application state of the preset micro-voltage is primarily applied to the lead-acid battery (20).

Here, the time during which the first restoration control unit 152 proceeds with the application of the power for primary restoration through the first restoration control step (S120) is the cell voltage value of the lead-acid battery 20 through the voltage detection unit 140 As a result of the detection, it is determined until the cell voltage value of the lead-acid battery 20 corresponds to 1.80V.

As such, the process of applying power for the primary restoration of the first restoration control part 152 through the first restoration control step (S120) is the relationship between the lead-acid battery 20 cell voltage value and the specific gravity of sulfuric acid in the electrolyte, as shown in FIG. As a part of the execution process in Phase 1 in the graph of the algorithm designed based on the curve graph showing the performance, a strong voltage and pulse waveform is applied to the lead-acid battery 20 recklessly from the beginning to greatly damage the electrode plate, and as a result, the performance restoration is Of course, it is a starting process to solve the problem that leads to the deterioration of its own power storage performance.

(3) second restoration control step <S130, C step>

This step (S130) is to apply a preset voltage and high-frequency forward/reverse pulse to the recoverable waste lead-acid battery 20 so that it is gradually increased secondarily through the second restoration control part 153 in the restoration control unit 150 to damage the electrode plate. The process of carrying out the reduction of sulfate (lead sulfate) in earnest is in progress without giving little.

Specifically, in the second restoration control step (S130), the second restoration control part 153 is the first restoration control part 152 through the first restoration control part 152, the restoration power provided in accordance with the second applied power state is applied to the lead-acid battery (20) When the cell voltage value of the lead-acid battery reaches 1.80V, it is a preset voltage to gradually increase with time for the restoration of the high-frequency forward and reverse pulses and the lead-acid battery through the power supply 110 and the pulse generator 120. The power for restoration provided in accordance with the third application state is applied to the lead-acid battery 20 secondary.

Here, the second restoration control unit 153 through the second restoration control step (S130), the time during which the application of the secondary restoration power proceeds is the result of detecting the cell voltage value of the lead-acid battery through the voltage detection unit 140 It is determined until the cell voltage value of the lead-acid battery corresponds to 2.20V.

In addition, the voltage of the power source for restoration according to the third application state is gradually increased at a certain rate over time, and the minimum and maximum values of the corresponding rise range are the micro voltage of the restoration power according to the second application state and the fourth It is set to a value located between the voltages of the power source for restoration according to the application state, and most preferably shows a gradual increase in voltage and frequency at a rate of increase of 12 to 18%.

As such, the process of applying the power for the secondary restoration of the second restoration control part 153 through the second restoration control step (S130) is the relationship between the lead-acid battery 20 cell voltage value and the specific gravity of sulfuric acid in the electrolyte, as shown in FIG. As part of the execution process in Phase 2 of the algorithm designed based on the curve graph showing the characteristics, the electrode plate is applied to the lead-acid battery 20 of a full-scale voltage and pulse waveform after applying the power for primary restoration based on the microvoltage. It corresponds to the process of removing and reducing the sulfate (lead sulfate) adhering to the

(4) third restoration control step <S140, D step>

This step (S140) is to apply a preset voltage and high-frequency forward/reverse pulse to the recoverable waste lead-acid battery 20 so as to gradually rise tertiarily through the third restoration control part 154 in the restoration control unit 150 to damage the electrode plate. The process of finishing the reduction of sulfate (lead sulfate) is carried out while giving little.

Specifically, in the third restoration control step (S140), the third restoration control part 154 is applied to the lead-acid battery 20 through the second restoration control part 153 to restore power provided in accordance with the third applied power state. When the cell voltage value of the lead-acid battery reaches 2.20V, the high-frequency forward/reverse pulse through the power supply unit 110 and the pulse generator 120, and a predetermined voltage preset for charging the lead-acid battery 20 4 The power for restoration provided in accordance with the application state is applied to the lead-acid battery 20 tertiarily.

Here, the time during which the third restoration control unit 154 proceeds with the application of the power for the tertiary restoration through the third restoration control step (S140) is the result of detecting the cell voltage value of the lead-acid battery through the voltage detection unit 140 It is determined until the cell voltage value of the lead-acid battery corresponds to 2.40V.

As such, the process of applying the power for the tertiary restoration of the third restoration control part 154 through the third restoration control step (S140) is the relationship between the lead-acid battery 20 cell voltage value and the specific gravity of sulfuric acid in the electrolyte, as shown in FIG. As part of the execution process in Phase 3 of the algorithm designed based on the curve graph showing the performance, the sulfate reduction for full-fledged performance restoration through the application of power for secondary restoration based on the previously rising voltage is performed and then fixed to the electrode plate. It is the process of achieving cell stabilization by finishing the process of reducing the used sulfate (lead sulfate).

(5) Cell cycle control step <S150, E' step>

This step (S150) is a cell cycle (Cell Cycle) related to the cell (Cell) in the lead-acid battery 20 before the charge control unit 160 performs a full-scale charge control after the performance restoration control over the third is made A verification process is performed to check whether it is within the normal range or not.

Specifically, it is a process of confirming the normal charging voltage and capacity by performing a series of cycles corresponding to charge-discharge through the charging control unit 160, and whether or not the cell is normalized and restored after the restoration process over the previous three Before performing, the level of normalization compared to the initial level is tested.

Through this, only when the result of the cell cycle verification performed by the charging control unit 160 before charging control is recorded within the normal range, the charging control step S160 to be described below is performed, otherwise the normal range Repeatedly maintain the Cell Cycle verification mode until it enters the

(6) Charging control step <S160, E step>

This step (S160) is based on the cell voltage value of the lead-acid battery 20 detected through the voltage detection unit 140, the high-frequency forward and reverse pulses and the charging power provided through the power supply unit 110 and the pulse generation unit 120 The charging control unit 160 is supplied to the lead-acid battery 20, the process of charging the lead-acid battery 20 proceeds.

Specifically, in the charging control step (S160), the restoration control unit 150 is applied to the lead-acid battery 20 by the restoration control unit 150 provided in accordance with the fourth applied power state through the third restoration control unit 154 to the lead-acid battery 20. After the cell voltage value of ) reaches 2.40V, through the charging control unit 160, the power supply unit 110 and the pulse generator 120 through the high-frequency forward/reverse pulse and a predetermined voltage preset for charging the lead-acid battery When the cell voltage value of the lead-acid battery 20 is detected as a result of detecting the cell voltage value of the lead-acid battery 20 through the voltage detection unit 140 for the charging power provided in accordance with the fourth application state, the cell voltage value of the lead-acid battery 20 corresponds to the preset charge termination voltage It is applied to the lead-acid battery 20 to perform charging.

The embodiments disclosed in the present invention are for explanation rather than limiting the technical spirit of the present invention, and the scope of the technical spirit of the present invention is not limited by these embodiments. The scope of protection should be construed by the claims below, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

100: waste lead-acid battery performance restoration device
110: power supply 120: pulse generator
130: protection circuit unit 140: voltage detection unit
150: restoration control unit
151: restoration possibility judgment part
152: first restoration control part
153: second restoration control part
154: third restoration control part
160: charging control unit
10: external power supply
20: lead acid battery

Claims (7)

In the waste lead-acid battery performance restoration device that is electrically connected to the lead-acid battery and causes the performance restoration of the lead-acid battery by reducing the sulfate formed adhering to the electrode plate of the lead-acid battery through the application of power,
a power supply unit for receiving AC power from the outside, converting it into DC power, and outputting the converted DC power;
a pulse generator for receiving the DC power supplied from the power supply unit to generate a high-frequency forward/reverse pulse, and supplying power for restoration having a current and voltage linked to the generated high-frequency forward/reverse pulse to the lead-acid battery;
As a protection circuit connected between the pulse generating unit and the lead-acid battery, a protection circuit unit for blocking the short-circuit current and the overload current transmitted to the lead-acid battery from the pulse generating unit;
a voltage detection unit connected to the protection circuit unit to detect a cell voltage value of the lead-acid battery;
Based on the cell voltage value of the lead-acid battery detected through the voltage detection unit, the high-frequency forward/reverse pulse and power for restoration provided through the power supply unit and the pulse generator are divided by multiple times and supplied to the lead-acid battery under mutually different set values. It characterized in that it comprises;
Waste lead-acid battery performance restoration device.
According to claim 1,
The restoration control unit,
By setting the cell voltage value of the lead-acid battery detected through the voltage detection unit to the first applied voltage state, the power for restoration provided through the power supply unit and the pulse generator is supplied to the lead-acid battery according to the first applied state. In the process of applying for a determination time, a restoration possibility determination part for determining whether restoration is possible by detecting the cell voltage value of the lead-acid battery through the voltage detection unit;
The restoration possibility determination part performs the detection of the cell voltage value of the lead-acid battery through the voltage detection unit over multiple times according to a predetermined detection unit time within the determination time, the result of which is that the cell voltage value of the lead-acid battery is 1.62V It is determined that restoration of the lead-acid battery is possible only in the following cases, characterized in that the regeneration of the lead-acid battery through the restoration control unit occurs
Waste lead-acid battery performance restoration device.
3. The method of claim 2,
The restoration control unit,
When it is determined that the restoration of the lead-acid battery is possible through the restoration possibility determination part, it has a high-frequency forward and reverse pulse through the power supply unit and the pulse generator, and provides a power for restoration provided in accordance with the second application state of a preset micro-voltage to the voltage A first restoration control part applied to the lead-acid battery until the result of detecting the cell voltage value of the lead-acid battery through the detection unit corresponds to the cell voltage value of the lead-acid battery is 1.80V;
When the power for restoration provided in accordance with the second applied power state through the first restoration control part is applied to the lead-acid battery and the cell voltage value of the lead-acid battery reaches 1.80V, the high frequency frequency is passed through the power supply unit and the pulse generator As a result of detecting the cell voltage value of the lead-acid battery through the voltage detection unit, the power for restoration provided in accordance with the third applied state, which is a preset voltage to gradually increase with time for the restoration of the forward and reverse pulses and the lead-acid battery, the cell voltage of the lead-acid battery a second restoration control part applied to the lead-acid battery until the value corresponds to 2.20V; and
When the power for restoration provided in accordance with the third applied power state is applied to the lead-acid battery through the second restoration control part and the cell voltage value of the lead-acid battery reaches 2.20V, the high-frequency wave through the power supply unit and the pulse generator As a result of detecting the cell voltage value of the lead-acid battery through the voltage detector, the power for restoration provided in accordance with the fourth application state, which is a predetermined voltage preset for charging the lead-acid battery and the forward-reverse pulse, the cell voltage value of the lead-acid battery is 2.40V It includes; a third restoration control part applied to the lead-acid battery until it corresponds to
The voltage of the power supply for restoration according to the third application state is higher than the micro voltage of the power supply for restoration according to the second application state, and is lower than the voltage of the power supply for restoration according to the fourth application state. doing
Waste lead-acid battery performance restoration device.
4. The method of claim 3,
The waste lead-acid battery performance restoration device,
After the restoration power provided in accordance with the fourth applied power state is applied to the lead-acid battery through the third restoration control part and the cell voltage value of the lead-acid battery reaches 2.40V, the high frequency frequency is passed through the power supply unit and the pulse generator As a result of detecting the cell voltage value of the lead-acid battery through the voltage detection unit, the charging power provided in accordance with the fourth applied state, which is a predetermined voltage preset for charging the lead-acid battery and the forward/reverse pulse, the cell voltage value of the lead-acid battery is charged A charging control unit for performing charging by applying to the lead-acid battery until it corresponds to the final voltage; characterized in that it further comprises
Waste lead-acid battery performance restoration device.
In a method of performing performance restoration of a waste lead-acid battery using a waste lead-acid battery performance restoration device that is electrically connected to the lead-acid battery and causes the performance restoration of the lead-acid battery by reducing the sulfate formed adhering to the electrode plate of the lead-acid battery through the application of power,
The waste lead-acid battery performance restoration device, after receiving AC power from the outside and converting it into DC power, a power supply unit for outputting the converted DC power; a pulse generator for receiving the DC power supplied from the power supply unit to generate a high-frequency forward/reverse pulse, and supplying power for restoration having a current and voltage linked to the generated high-frequency forward/reverse pulse to the lead-acid battery; As a protection circuit connected between the pulse generating unit and the lead-acid battery, a protection circuit unit for blocking the short-circuit current and the overload current transmitted to the lead-acid battery from the pulse generating unit; a voltage detection unit connected to the protection circuit unit to detect a cell voltage value of the lead-acid battery; Based on the cell voltage value of the lead-acid battery detected through the voltage detection unit, the high-frequency forward/reverse pulse and power for restoration provided through the power supply unit and the pulse generator are divided by multiple times and supplied to the lead-acid battery under mutually different set values. Containing; includes a;
By setting the cell voltage value of the lead-acid battery detected through the voltage detection unit in the restoration control unit whether restoration is possible to determine the first applied voltage state, the power supply for restoration provided through the power supply unit and the pulse generating unit is the first A step of determining whether restoration is possible by detecting the cell voltage value of the lead-acid battery through the voltage detection unit in the process of applying to the lead-acid battery for a predetermined time according to the application state;
When it is determined that the restoration of the lead-acid battery is possible through the restoration possibility determination part, the first restoration control unit in the restoration control unit has a high-frequency forward and reverse pulse through the power supply unit and the pulse generator, and a second application of a preset microvoltage B step of applying the power for restoration prepared according to the state to the lead-acid battery until the cell voltage value of the lead-acid battery is detected through the voltage detection unit and the cell voltage value of the lead-acid battery corresponds to 1.80V;
When the second restoration control unit in the restoration control unit is applied to the lead-acid battery according to the second applied power state through the first restoration control unit, the power for restoration is applied to the lead-acid battery and the cell voltage value of the lead-acid battery reaches 1.80V , through the power supply unit and the pulse generator, the high-frequency forward/reverse pulse and the cell voltage of the lead-acid battery through the voltage detection unit, the power for restoration provided in accordance with the third application state, which is a preset voltage to gradually increase with time for restoration of the lead-acid battery C step of applying the lead-acid battery until the cell voltage value of the lead-acid battery corresponds to 2.20V as a result of detecting the value; and
When the third restoration control unit in the restoration control unit is applied to the lead-acid battery according to the third applied power state through the second restoration control unit, the cell voltage value of the lead-acid battery reaches 2.20V , through the power supply unit and the pulse generator, a high-frequency forward/reverse pulse and a cell voltage value of the lead-acid battery through the voltage detection unit for restoration power provided in accordance with the fourth application state, which is a preset voltage for charging the lead-acid battery. Step D of applying the lead-acid battery to the resultant lead-acid battery until the cell voltage value of the lead-acid battery corresponds to 2.40V;
The voltage of the power supply for restoration according to the third application state is higher than the micro voltage of the power supply for restoration according to the second application state, and is lower than the voltage of the power supply for restoration according to the fourth application state. characterized by
A waste lead-acid battery performance restoration method using a waste lead-acid battery performance restoration device.
6. The method of claim 5,
The step A is to perform the detection of the cell voltage value of the lead-acid battery through the voltage detection unit over multiple times according to a predetermined detection unit time within the determination time whether the restoration determination part is possible, the result of performing the cell voltage of the lead-acid battery Only when the value is 1.62V or less, it is determined that the restoration of the lead-acid battery is possible, characterized in that the step of allowing the regeneration of the lead-acid battery to occur through the restoration control unit
A waste lead-acid battery performance restoration method using a waste lead-acid battery performance restoration device.
7. The method of claim 6,
The waste lead-acid battery performance restoration device,
A restoration control unit for charging the lead-acid battery by supplying a high-frequency forward and reverse pulse and charging power provided through the power supply unit and the pulse generator to the lead-acid battery based on the cell voltage value of the lead-acid battery detected through the voltage detection unit; includes,
The waste lead-acid battery performance restoration method using the waste lead-acid battery performance restoration device,
After the restoration control unit is applied to the lead-acid battery and the cell voltage value of the lead-acid battery reaches 2.40V, the power supply unit and the pulse As a result of detecting the cell voltage value of the lead-acid battery through the voltage detection unit, the charging power provided in accordance with the fourth applied state, which is a predetermined voltage preset for charging the lead-acid battery and the high-frequency forward/reverse pulse through the generator, is the result of detecting the cell of the lead-acid battery E step of performing charging by applying to the lead-acid battery until the voltage value corresponds to the charging termination voltage; characterized by further comprising
A waste lead-acid battery performance restoration method using a waste lead-acid battery performance restoration device.

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