KR20110018013A - Battery charger - Google Patents

Abstract

PURPOSE: A battery charger is provided to increase the lifetime of a battery by preventing electrolytes from being attached to an inner electrode and solidified. CONSTITUTION: A battery charger detects the status of a battery(1) through a checking circuit(4). If the voltage for an initial charge is 90% of a battery rated voltage or more, the battery is charged with a charging circuit(8). If the voltage for an initial charge is 90 % of the battery rated voltage or less, a high frequency is applied to each cell electrode through an oscillation circuit(5).

Description

Battery restorer {Battery charger}

The present invention relates to a battery restoring device which prevents electrolyte from adhering to a battery internal electrode and solidifies.

In general, the battery uses a chemical action of the current, and the chemical energy can be used as electrical energy. When the battery is discharged, the battery can be restored again. When a battery is connected to a load on an external electrode terminal, an electrode plate in the battery and an electrolyte react with each other to generate a voltage.

Batteries use dilute sulfuric acid as the electrolyte, lead peroxide as the positive electrode, and pure lead as the negative electrode.

The battery is composed of thin plates connected in parallel, and the positive and negative plates face each other in order to increase the contact area of the electrolytic solution and the electrolytic plates in order to obtain the largest possible electrical energy in a small volume.

The two-electrode reaction of the positive and negative plates produces insoluble PbSO4, which is attached to both electrodes.When the battery is discharged, sulfuric acid is consumed to generate water, and the density of the water is lower than that of sulfuric acid, so the state of charge of the battery is the density of the electrolyte. Measure and confirm. When the battery is recharged, the electrode reaction is reversed.

However, if charge and discharge are repeated for a long period of time, the sulphate that is stuck to the electrode plate does not deviate during charging, but instead, the sulphation phenomenon occurs.

The sulphation phenomenon causes a problem of lowering the voltage, capacity and specific gravity of the battery since the passage of the electrical reaction of the electrode plate is blocked to perform the insulating function.

The present invention has been made to solve the above problems, to provide a battery restorer that can be used to regenerate the battery by restoring the intrinsic function of the electrode plate by removing the solidified sulfate attached to the battery electrode plate.

Another object of the present invention to provide a battery restorer that can improve the service life of the battery.

In order to achieve the above object, the battery restorer of the present invention, in the battery restorer that removes sulfur oxides attached to the electrode by performing one or more charge discharges, detects the state of the battery 1 through the battery state check circuit 4. After that, if the voltage after the initial charge is about 90% or more with respect to the rated voltage of the battery, the battery is charged through the charging circuit 8, and if less, the high frequency is applied to the battery electrode through the oscillator circuit 5. It is characterized by.

In addition, the battery charging and high frequency application is characterized in that it is configured to be repeated every predetermined time.

In addition, the battery charging and high frequency application is characterized in that configured to be made for each cell electrode of the battery.

The present invention can achieve the effect of extending the service life of the battery and long-term maintenance without degrading the performance of the battery.

In addition, it is possible to obtain an effect of reducing environmental pollution by recycling the discarded battery.

Hereinafter, the technical configuration and operation of the battery restorer of the present invention will be described in detail with reference to FIGS. 1 to 3.

1 is a three-dimensional view showing a state in which a general battery and the battery restorer of the present invention are connected,

2 is a block diagram showing the circuit configuration of the battery restorer of the present invention;

3 is a view for explaining the process of applying the high voltage of the present invention.

The high voltage is applied to the battery 1 through the voltage stabilization circuit 2 and the oscillation circuit 5 of the battery restorer 10. 3 shows an example in which the applied voltage or time pattern is compared with a preset reference voltage.

The voltage stabilization circuit 2 is provided with a control function in which the discharge current is the control amount and the generated voltage is the operation amount.

The control function is controlled by applying a discharge current equal to or greater than the threshold current at which the reduction phenomenon of the high resistance material occurs.

Since the optimum of the current pattern depends on the battery, the standard data obtained through the battery condition checking circuit 4 is applied.

Then, the determined current pattern is input to the central processing unit 3 as a control command.

As for the control for discontinuously flowing the discharge current above the threshold current, it is preferable to apply a high voltage having a longer time interval rather than the pulse current and pulse voltage of a normal (pulse charger).

Specifically, the current control is repeated through the oscillation circuit 5 at time intervals longer than 20 m seconds.

Alternatively, a commercial pulse is output through the oscillation circuit 5 and the discharge current of the threshold current or more is repeatedly flowed.

Moreover, you may output the generation command of the single pulse voltage which has the peak discharge current more than a threshold current.

For example, the partially impacted energy may be supplied to an electrode selected to partially destroy the high voltage material.

Determining the amount and timing of the high voltage application, the discharge operation, and the repetition number of charge discharges is determined by the central processing unit calculating data obtained through the battery state check circuit 4 and measuring the internal resistance of the battery.

A well-known measuring method is used about the measurement of battery internal resistance.

In addition, for the application of high frequency vibration, the vibration intensity and the vibration time can be determined based on the measured value of the internal resistance of the battery.

The voltage stabilization circuit is composed of an electrostatic accumulator charger and a capacitor, and is configured to supply a high voltage pulse to the battery by charging a charge from the electrostatic accumulator charger to the capacitor.

The power supply unit 6 is composed of components made of a silistor or a triac, a gate turn-off transistor, an electrostatic induction transistor, and an insulated gate bipolar transistor.

Preferred battery restorers of the invention are shown in FIG.

In FIG. 2, the battery 1 is charged through the charging circuit 8.

After charging is performed for a predetermined time, the central processing unit 3 determines the data input by the battery state checking circuit 4 and displays it on the display 9 whether the battery is rechargeable or in a state in which a regeneration process is required.

Specifically, for example, the voltage after the initial charge is approximately 90% of the voltage value (first measured voltage) is obtained with respect to the battery rated voltage, or the voltage of 90 or less (second measured voltage) with respect to the previous charge. Determine if a rise is obtained. When the first measurement voltage is reached, it is determined that the battery is a normal battery, the voltage stabilization circuit 2 is turned off, and the normal charging is performed through the charging circuit 8. When the second measurement voltage is determined that the sulfuric acid is attached to the electrode inside the battery or has already started, high frequency is applied to the external terminal of the battery through the voltage stabilization circuit 2 and the oscillation circuit 5.

The high frequency generated through the voltage stabilization circuit 2 and the oscillation circuit 5 may be applied in duplicate to the voltage applied from the charging circuit 8 to the battery.

High frequency vibration may be generated during or before voltage application.

The above description has been made using a structure in which an external terminal of the battery, that is, a negative electrode (−electrode) of the battery 1 and a positive electrode (+ electrode) of the battery is connected to the battery restorer 10.

In practice, however, since the degree of adhesion of the high-resistance material is different for each cell of the battery, a separate appropriate regeneration operation is required for each individual cell.

Charged for each positive electrode positive electrode of each cell terminal and the above-described process using the voltage value or the internal resistance estimation value to remove the sulfate film, which is a high resistance material attached to each cell electrode of the battery.

The internal resistance estimation for each cell may use a well-known battery internal resistance estimation method.

The battery restoring apparatus of the present invention is not limited to the above-described illustrated structure, and various modifications can be made within the scope of the claims and the objects of the present invention.

1 is a three-dimensional view showing a state in which a general battery and the battery restorer of the present invention are connected.

2 is a block diagram showing the circuit configuration of the battery restorer of the present invention.

3 is a view for explaining the process of applying the high voltage of the present invention.

<Explanation of symbols for the main parts of the drawings>

1-Battery 2-Voltage Stabilization Circuit

3-central processing unit 4-battery condition check circuit

5-Oscillator 6-Power Supply

8-Charging Circuit 9-Display

10-battery restorer

Claims (2)

In the battery restoring device which removes the sulfur oxide attached to the electrode by performing one or more charge discharges, after detecting the state of the battery 1 through the battery state checking circuit 4, the voltage after initial charge is the battery rated voltage. The battery restorer is configured to apply the high frequency to each cell electrode of the battery through the charging circuit 8 if less than about 90%, and the oscillation circuit 5 below. . The method of claim 1, The battery restorer of claim 1, wherein the battery charging and the high frequency application are repeated every predetermined time.

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