JP2005327737A - Method for regenerating storage battery - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for regenerating a storage battery capable of promptly regenerating the deteriorated storage battery electrically by superimposing a base current and a pulse current as a charging current. <P>SOLUTION: In this method for regenerating the storage battery, the base current Ib and the square pulse current Ip with a pulse frequency of a kHz order are superimposed to form the charging current Ic with a quiescent period of T2≈0.5 to 1 minute, and the charging time T1≈5-10 minutes is repeated periodically. Therefore, the regenerating time of the storage battery is shortened. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a storage battery regeneration processing method for electrically regenerating and reusing a storage battery whose performance has deteriorated.

  A storage battery typified by a lead storage battery deteriorates in performance due to long-term use or neglect for a long period of time, making recharge impossible and impossible to reuse.

Deterioration of the storage battery is manifested as an external phenomenon such as an increase in internal resistance, a decrease in the specific gravity of the electrolyte, an inability to charge, and an inability to recover discharge capacity. On the other hand, the deterioration of the lead-acid battery is caused by the fact that large crystals of PbSO ₄ are deposited on the surface of the electrode of the storage battery, in particular, the negative electrode surface, and the electrochemical activity of the electrode is lost. Is known as sulfation.

In view of this, the applicant first applied a DC pulse current having an appropriate duty to a deteriorated storage battery (referred to as a pulse waveform current rising from 0 V to a predetermined peak value, hereinafter the same) and electrically regenerating the storage battery. (Patent Document 1). This method is based on the knowledge that Pb SO ₄ on the electrode surface is molecularly decomposed by applying a DC pulse current.
JP 2001-118611 A

  According to such a conventional technique, since only a direct current pulse current is supplied to the storage battery, there is a problem that the time required for the regeneration process is excessive and the regeneration efficiency is not good.

  Therefore, in view of the problems of the prior art, an object of the present invention is to recharge a deteriorated storage battery electrically more quickly by superimposing a base current and a pulse current to form a charging current. A reproduction processing method is provided.

  The configuration of the present invention for achieving such an object is that when a deteriorated storage battery is regenerated, a base current and a square-wave pulse current having a pulse frequency on the order of kHz are sandwiched by a rest period of about 0.5 to 1 minute. The gist of this is to periodically repeat a charging period of about 5 to 10 minutes to superimpose.

According to the configuration of the present invention, the charging current that superimposes the base current and the pulse current can significantly shorten the regeneration processing time of the storage battery as compared with the case where the DC pulse current is simply applied. For example, in a lead storage battery, PbSO ₄ on the electrode surface is refined and decomposed by a pulse current, and the storage battery can be charged by a base current. That is, according to the present invention, by periodically repeating the charging period in which the base current and the pulse current are superimposed to obtain the charging current, the electrochemical activity of the electrode is quickly recovered, and the deteriorated storage battery is promptly regenerated. Processing can shorten the reproduction processing time. The regeneration of the storage battery can be evaluated by an increase in CCA (cold cranking average) as well as an increase in terminal voltage, a decrease in internal resistance, and an increase in the specific gravity of the electrolyte. However, CCA is defined as the maximum discharge current that can be energized for 30 seconds at 0 ° F. (−17.8 ° C.) without the terminal voltage dropping below a specific cutoff voltage. It is set to 10.5V for a storage battery with a rated voltage of 12V.

  The pulse current should be set to a peak value of about 2 to 10 times the base current. For example, it is preferable to set the pulse frequency to about 1 to 5 kHz and the duty to about 25%. The optimum value is determined experimentally depending on the capacity. In other words, the pulse frequency of the pulse current is preferably determined experimentally in the order of kHz. Further, the charging period and the suspension period per time are preferably set to about 5 to 10 minutes and about 0.5 to 1 minute, respectively. The required number of repetitions of the charging period and the suspension period required for the regeneration process is 100. ~ 300 orders.

  For example, when batteries with extremely different degrees of deterioration are mixed, such as automobile storage batteries, the degree of deterioration is determined in advance, and the parameters of the regeneration process including the number of repetitions of the charging period are optimized according to the deterioration. Can be set. In the prior determination, for example, an internal resistance of 100 mΩ or less and an excess of 100 mΩ can be determined as a low-deterioration product and a high-deterioration product, respectively, based on the internal resistance after constant current charging of about 5A30 minutes. However, for example, a storage battery having a rated voltage of 12 V and having a terminal voltage of less than 10 V after constant current charging is discarded as non-recyclable.

  In addition, the time required for the regeneration process can be further shortened by providing a discharge period for each predetermined number of repetitions of the charge period. The discharge current is set to a constant current equal to or higher than the peak value of the charge current, and the discharge period is set to about 3 to 4 minutes, and the charge period is repeated on the order of 100 to 300 times. In this case, about 10 times are dispersed evenly and sandwiched. Furthermore, the regeneration process is terminated not after the discharge period but when the charge period elapses, so that the time required for the subsequent charge process can be shortened.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  The storage battery regeneration processing method is carried out by a regeneration processing apparatus that combines the microcomputer 11, the DC power source 12, and the switching elements SW1 and SW2 (FIG. 1).

  The output of the DC power source 12 is grounded via switching elements SW1 and SW2, and control signals S1 and S2 from the microcomputer 11 are individually input to the switching elements SW1 and SW2. Further, a storage battery B to be subjected to regeneration processing is connected to a connection point between the switching elements SW1 and SW2 via a current limiting resistor R, and a terminal voltage Vt of the storage battery B is fed back to the microcomputer 11. ing. The switching elements SW1 and SW2 can cut off the direct current according to the control signals S1 and S2, respectively. In addition to the illustrated transistors, any semiconductor switching elements such as FET, GTO, and bidirectional thyristor can be used. is there.

  The microcomputer 11 can arbitrarily charge and discharge the storage battery B via the resistor R by controlling the switching elements SW1 and SW2 via the control signals S1 and S2. Therefore, the microcomputer 11 can regenerate the storage battery B according to the program flowchart of FIG.

  In the program, first, the storage battery B is charged by the charging current Ic for the first charging period T1 (program steps (1) and (2) in FIG. 2, hereinafter, simply ((1) and (2)). Write down). However, the charging current Ic superimposes the base current Ib and the square-wave pulse current Ip (FIG. 3), and the base current Ib, the pulse current Ip, and the charging period T1 depend on the type and capacity of the storage battery B. Are preset in the microcomputer 11. Therefore, when the predetermined charging period T1 elapses (2), the program stops charging with the charging current Ic = 0 (3), and determines whether or not the number N of repetitions of the charging period T1 and the suspension period T2 has been achieved. Check (4). The suspension period T2 and the number of repetitions N are also set in the microcomputer 11 in advance.

  If the repetition number N is not achieved (4), the program waits for the elapse of the suspension period T2 (4) and repeats the same operation for the repetition number N ((4), (5), (1) to (4), FIG. 3), when the number of repetitions N is reached (4), the reproduction process is completed. For example, the microcomputer 11 reads and displays the terminal voltage Vt of the storage battery B after a predetermined time from the start of the suspension period T2, and ends the regeneration process when the charging period T1 elapses.

  An example of the regeneration processing data of the storage battery B for a motorcycle having a rated voltage of 6V is shown in FIG. However, the horizontal axis of FIG. 4 is the regeneration processing time t (minutes), and the vertical axis is the CCA (A) of the storage battery B, the internal resistance Ri (mΩ), the terminal voltage Vt (V), and the specific gravity ρ of the electrolyte. It is. Since the internal resistance Ri and the terminal voltage Vt are rapidly recovered within a short period at the beginning of the reproduction process, the time required for the entire reproduction process can be shortened. In addition, the storage battery B regenerated in this way can be effectively reused by performing a regular charging process.

Other embodiments

  Prior to the regeneration process, the degree of deterioration of the storage battery B can be determined in advance (FIG. 5).

  That is, the storage battery B is charged with a constant current for a predetermined time (program steps (1) and (2) in FIG. 5 and hereinafter referred to simply as ((1) and (2))), and the terminal voltage Vt is checked. (3). For example, a storage battery B having a rated voltage of 12 V and having a terminal voltage Vt <10 V is discarded as non-recyclable ((3), (4)), and a battery having a terminal voltage Vt ≧ 10 V is further checked for internal resistance Ri (5 ), For example, depending on whether or not the internal resistance Ri ≦ 100 mΩ, the product is classified into a low degradation product and a high degradation product ((6), (7)). Depending on the degree of deterioration of the storage battery B, the charging current Ic = Ib + Ip, the charging period T1, the number of repetitions N, and the like can be optimally changed. At this time, it is preferable to set at least the number of repetitions N of the charging period T1 according to deterioration.

  2 can be provided with a discharge period following the program step (5) according to the program flowchart of FIG.

  In FIG. 6, when the suspension period T2 after the charging period T1 elapses (program step (5) in FIG. 6, hereinafter simply described as (5)), the charging period T1 is a predetermined number of times n <N. If it is repeated (6), the storage battery B is forcibly discharged for a predetermined discharge period ((7) to (9)) and a suitable rest period of about 0.5 to 2 minutes is waited for. (10), the program returns to the program step (1) in FIG. That is, the discharge period is assumed to be sandwiched once every predetermined repetition number n of the charging period T1, and constant current discharge is performed for about 3 to 4 minutes. In this case as well, the regeneration process ends with the elapse of the charging period T1 (program step (4) in FIG. 2). However, the discharge period may be DC pulse current discharge instead of constant current discharge.

  An example of the effect of providing the discharge period is shown in FIG. However, the horizontal and vertical axes in FIG. 7 are the regeneration processing time t (hours) and CCA (A), respectively, and the curves (1) and (2) in FIG. It corresponds. By providing the discharge period, the recovery speed of CCA (A) can be improved several times.

  An example of setting parameters applied to the regeneration process of the storage battery B is shown in FIG. However, in FIG. 8, automobiles include those for small vehicles such as motorcycles, and industrial ones, for example, for power supplies such as forklifts and electric vehicles. The term “emergency” refers to a stationary type that is always floating-charged as an emergency power source. Further, the degree of deterioration indicates whether the product is a low deterioration product or a high deterioration product determined in accordance with the program of FIG. 5, and the number of discharges is almost uniformly distributed and sandwiched within the number N of repetitions of the charging period T1. The number of times the discharge period is sandwiched is shown.

  In addition, in this invention, the storage battery B shall include various secondary batteries, such as a Ni-Cd battery and an alkaline battery, besides a lead storage battery, and this invention is widely applicable to the regeneration process of these secondary batteries. is there.

Block diagram of playback processor Program flow chart (1) Operation explanation diagram Diagram showing experimental data (1) Program flow chart (2) Program flow chart (3) Diagram showing experimental data (2) Parameter setting chart

Explanation of symbols

B ... Storage battery T1 ... Charging period T2 ... Rest period Ib ... Base current Ip ... Pulse current Ic ... Charging current N ... Number of repetitions

Patent Applicant Takeshi Nishida
Attorney Tadaaki Matsuda, Attorney

Claims (1)

When regenerating a deteriorated storage battery, a charging current is obtained by superimposing a base current and a square-wave pulse current having a pulse frequency on the order of kHz with a pause period of about 0.5 to 1 minute. A storage battery regeneration processing method characterized by periodically repeating a charging period of about a degree.

Images