CN2845192Y - The lead acid accumulator instrument for repairing - Google Patents

Abstract

The utility model discloses a kind of lead acid accumulator instrument for repairing, be formed by connecting by pulse signal generator circuit, pulse signal intensifier circuit, three cycle pulse frequency change control circuits, three cycle pulse change in duty cycle control circuits, three cycle pulse changes in amplitude control circuits, work indication and control circuit.This lead acid accumulator instrument for repairing, adopt the pulse current charge repair mode that pulse frequency changes, pulse duty factor changes, pulse amplitude changes that old and useless battery is repaired, because this pulse signal contains very abundant harmonic signal, can produce resonance with the lead sulfate crystal of inside battery different volumes, can decompose different volumes, difform lead sulfate crystal very effectively, make it can participate in electrochemical reaction, improve the charge storage ability of battery, reduce the internal resistance of cell, reparation speed is fast, and is effective.

Description

The lead acid accumulator instrument for repairing

Technical field

The utility model belongs to the reparation of storage battery, relates in particular to a kind of lead acid accumulator instrument for repairing.

Background technology

Lead acid accumulator is widely used in every profession and trade after invention.Recent popularizing along with electric bicycle, electro-tricycle, its quantity required increases especially with surprising rapidity, but because aspects such as battery itself and improper use all have a large amount of batteries seriously to scrap because of vulcanizing every year, not only waste resource, and serious environment pollution.The battery instrument for repairing of some producers of existing market mainly adopts the pulse current of fixed pulse frequency, fixed duty cycle that lead acid accumulator is repaired, though can repair the battery sulfuration to a certain extent, but because fixed-frequency, duty ratio are constant, harmonic components is few, so repairing effect is poor, speed is slow.

Summary of the invention

The purpose of this utility model provides a kind of lead acid accumulator instrument for repairing that pulse frequency changes, pulse duty factor changes, the pulse current charge repair mode of pulse amplitude variation is repaired old and useless battery that adopts.

For achieving the above object, the utility model adopts following technical scheme: a kind of lead acid accumulator instrument for repairing, by the pulse signal generator circuit, the pulse signal intensifier circuit, three cycle pulse frequency change control circuits, three cycle pulse change in duty cycle control circuits, three cycle pulse changes in amplitude control circuits, work indication and control circuit are formed by connecting, three cycle pulse frequency change control circuits link to each other with the pulse signal generator circuit, three cycle pulse change in duty cycle control circuits also link to each other with the pulse signal generator circuit, the pulse signal generator circuit links to each other with the pulse signal intensifier circuit, three cycle pulse changes in amplitude control circuits link to each other with the pulse signal intensifier circuit, and the pulse signal intensifier circuit links to each other with work indication and control circuit.

Described three cycle pulse frequency change control circuits are by three d type flip flop IC11, IC12, IC13, three triode VT11, VT12, VT13, three capacitor C 11 that capacity is different, C12, C13, three relay K 11, K12, K13, two NAND gate FA1, FB1, a time-base circuit ID1, variable resistor RF1, resistance R 11～R15, capacitor C 14, C15 is formed by connecting, the Q pin of d type flip flop IC11 links to each other with the base stage of triode VT11 by resistance R 11, the collector electrode of triode VT11 links to each other with relay K 11, one end of capacitor C 11 links to each other with the normally opened contact of relay K 11, the Q pin of d type flip flop IC12 links to each other with the base stage of triode VT12 by resistance R 12, the collector electrode of triode VT12 links to each other with relay K 12, one end of capacitor C 12 links to each other with the normally opened contact of relay K 12, the Q pin of d type flip flop IC13 links to each other with the base stage of triode VT13 by resistance R 13, the collector electrode of triode VT13 links to each other with relay K 13, one end of capacitor C 13 links to each other with the normally opened contact of relay K 13, relay K 11, relay K 12, the common port of relay K 13 links to each other, the D pin of d type flip flop IC11 links to each other with the Q pin of d type flip flop IC12, the D pin of d type flip flop IC12 links to each other with the Q pin of d type flip flop IC13, the Q pin of d type flip flop IC12 and the Q pin of d type flip flop IC13 connect two inputs of NAND gate FB1 respectively, two inputs of NAND gate FA1 connect the output of NAND gate FB1 simultaneously, the D pin of the output termination d type flip flop IC11 of NAND gate FA1, three d type flip flop IC11, IC12, IC13 meets working power VCC by resistance R 14, three triode VT11, VT12, the emitter of VT13 is ground connection all, 6 pin of time-base circuit ID1 and the 2 pin back that joins be connected in series the variable resistor RF1 CP pin of while and d type flip flop IC11 again, the CP pin of IC12, the CP pin of IC13 links to each other, 5 pin serial connection capacitor C, the 15 back ground connection of time-base circuit ID1,2 pin serial connection capacitor C, the 14 back ground connection of time-base circuit ID1.

Described work indication and control circuit are by two operational amplifier IC01, IC02, three variable resistor RF01, RF02, RF03, resistance R 01～R06, capacitor C 01, diode VD0, two light-emitting diode VD01, VD02, triode VT0, relay K 0 is formed by connecting, positive input terminal with operational amplifier IC01 behind the negative pole series resistance R06 of diode VD0 joins, also join after variable resistor RF02 and capacitor C 01 are in parallel with the positive input terminal of operational amplifier IC01, the negative input end of operational amplifier IC01 meets working power VCC after by variable resistor RF01, resistance R 05 1 end ground connection, the negative input end of the other end and operational amplifier IC01 joins, the negative input end of the output of operational amplifier IC01 and operational amplifier IC02 joins, the positive input terminal of operational amplifier IC02 meets working power VCC after by resistance R 03, variable resistor RF03 one end ground connection, the positive input terminal of the other end and operational amplifier IC02 joins, the output connecting resistance R02 of operational amplifier IC02, the other end of resistance R 02 is by ground connection behind the light-emitting diode VD02, one end of resistance R 01 and the output of operational amplifier IC01 join, the other end is by ground connection behind the light-emitting diode VD01, the base stage of triode VT0 is joined by the output of resistance R 04 with operational amplifier IC01, the grounded emitter of VT0, the collector electrode of VT0 and relay K 0 are joined, and the positive pole of the normally opened contact of relay K 0 and diode VD0 joins.

Described three cycle pulse change in duty cycle control circuits are formed by connecting by three d type flip flop IC21, IC22, IC23, three triode VT21, VT22, VT23, three relay K 21, K22, K23, two NAND gate FA2, FB2, time-base circuit ID2, variable resistor RF2, resistance R 21～R24, capacitor C 24, C25.

Described three cycle pulse changes in amplitude control circuits are formed by connecting by three d type flip flop IC41, IC42, IC43, three triode VT41, VT42, VT43, three different resistance R 01, R02, R03, three relay K 41, K42, K43, two NAND gate FA4, FB4, time-base circuit ID4, variable resistor RF4, resistance R 41～R45, capacitor C 44, C45 of resistance.

Described pulse signal generator circuit is by two NAND gate HF1, HF2, two diode VD301, VD302, resistance R 301, four variable resistor R31～R34 are formed by connecting, two inputs of the output of NAND gate HF1 and NAND gate HF2 join, variable resistor R33, R32, it is in parallel with the series circuit of being made up of variable resistor R34 and diode VD301 again after R31 and diode VD302 connect successively, two diode VD301, the negative pole of VD302 joins, one end of resistance R 301 and two diode VD301, the negative pole of VD302 joins, and two inputs of the other end and NAND gate HF1 join.

Described pulse signal intensifier circuit is formed by connecting by field effect transistor VT, diode VD, triode VT0, resistance R 1～R4, the base stage of triode VT0 and resistance R 1 are joined, the emitter of triode VT0 is by resistance R 3 ground connection, the collector electrode of triode VT0 meets working power VCC by resistance R 2, the input of field effect transistor VT joins by the emitter of resistance R 4 with triode VT0, and the positive pole of the output of field effect transistor VT and diode VD joins.

Adopt the lead acid accumulator instrument for repairing of technique scheme, adopt the pulse current charge repair mode that pulse frequency changes, pulse duty factor changes, pulse amplitude changes that old and useless battery is repaired, because this pulse signal contains very abundant harmonic signal, can produce resonance with the lead sulfate crystal of inside battery different volumes, can decompose different volumes, difform lead sulfate crystal very effectively, make it can participate in electrochemical reaction, improve the charge storage ability of battery, reduce the internal resistance of cell, reparation speed is fast, and is effective.

Description of drawings

Fig. 1 is an operation principle block diagram of the present utility model.

Fig. 2 is a circuit theory schematic diagram of the present utility model.

Embodiment

As shown in Figure 1, the utility model lead acid accumulator instrument for repairing, by the pulse signal generator circuit, the pulse signal intensifier circuit, three cycle pulse frequency change control circuits, three cycle pulse change in duty cycle control circuits, three cycle pulse changes in amplitude control circuits, work indication and control circuit are formed by connecting, three cycle pulse frequency change control circuits link to each other with the pulse signal generator circuit, three cycle pulse change in duty cycle control circuits also link to each other with the pulse signal generator circuit, the pulse signal generator circuit links to each other with the pulse signal intensifier circuit, three cycle pulse changes in amplitude control circuits link to each other with the pulse signal intensifier circuit, and the pulse signal intensifier circuit links to each other with work indication and control circuit.

As shown in Figure 2, three cycle pulse frequency change control circuits are by three d type flip flop IC11, IC12, IC13, three triode VT11, VT12, VT13, three capacitor C 11 that capacity is different, C12, C13, three relay K 11, K12, K13, two NAND gate FA1, FB1, a time-base circuit ID1, variable resistor RF1, resistance R 11～R15, capacitor C 14, C15 is formed by connecting, the positive output end Q pin of d type flip flop IC11 links to each other with the base stage of triode VT11 by resistance R 11, the collector electrode of triode VT11 links to each other with relay K 11, one end of capacitor C 11 links to each other with the normally opened contact of relay K 11, the Q pin of d type flip flop IC12 links to each other with the base stage of triode VT12 by resistance R 12, the collector electrode of triode VT12 links to each other with relay K 12, one end of capacitor C 12 links to each other with the normally opened contact of relay K 12, the Q pin of d type flip flop IC13 links to each other with the base stage of triode VT13 by resistance R 13, the collector electrode of triode VT13 links to each other with relay K 13, one end of capacitor C 13 links to each other with the normally opened contact of relay K 13, relay K 11, relay K 12, the common port of relay K 13 links to each other, the trigger end D pin of d type flip flop IC11 links to each other with the Q pin of d type flip flop IC12, the D pin of d type flip flop IC12 links to each other with the Q pin of d type flip flop IC13, the negative output terminal Q pin of d type flip flop IC12 and the Q pin of d type flip flop IC13 connect two inputs of NAND gate FB1 respectively, two inputs of NAND gate FA1 connect the output of NAND gate FB1 simultaneously, the D pin of the output termination d type flip flop IC11 of NAND gate FA1, three d type flip flop IC11, IC12, IC13 meets working power VCC by resistance R 14, three triode VT11, VT12, the emitter of VT13 is ground connection all, 6 pin of time-base circuit ID1 and the 2 pin back that joins be connected in series the variable resistor RF1 clock end CP pin of while and d type flip flop IC11 again, the CP pin of IC12, the CP pin of IC13 links to each other, 5 pin serial connection capacitor C, the 15 back ground connection of time-base circuit ID1,2 pin serial connection capacitor C, the 14 back ground connection of time-base circuit ID1.

Work indication and control circuit are by two operational amplifier IC01, IC02, three variable resistor RF01, RF02, RF03, resistance R 01～R06, capacitor C 01, diode VD0, two light-emitting diode VD01, VD02, triode VT0, relay K 0 is formed by connecting, positive input terminal with operational amplifier IC01 behind the negative pole series resistance R06 of diode VD0 joins, also join after variable resistor RF02 and capacitor C 01 are in parallel with the positive input terminal of operational amplifier IC01, the negative input end of operational amplifier IC01 meets working power VCC after by variable resistor RF01, resistance R 05 1 end ground connection, the negative input end of the other end and operational amplifier IC01 joins, the negative input end of the output of operational amplifier IC01 and operational amplifier IC02 joins, the positive input terminal of operational amplifier IC02 meets working power VCC after by resistance R 03, variable resistor RF03 one end ground connection, the positive input terminal of the other end and operational amplifier IC02 joins, the output connecting resistance R02 of operational amplifier IC02, the other end of resistance R 02 is by ground connection behind the light-emitting diode VD02, one end of resistance R 01 and the output of operational amplifier IC01 join, the other end is by ground connection behind the light-emitting diode VD01, the base stage of triode VT0 is joined by the output of resistance R 04 with operational amplifier IC01, the grounded emitter of VT0, the collector electrode of VT0 and relay K 0 are joined, and the positive pole of the normally opened contact of relay K 0 and diode VD0 joins.

Three cycle pulse change in duty cycle control circuits are formed by connecting by three d type flip flop IC21, IC22, IC23, three triode VT21, VT22, VT23, three relay K 21, K22, K23, two NAND gate FA2, FB2, time-base circuit ID2, variable resistor RF2, resistance R 21～R24, capacitor C 24, C25.As can be seen from Figure 2, the element composition of this circuit and connected mode and aforesaid three cycle pulse frequency change control circuits are basic identical, and difference does not just connect electric capacity at the normally opened contact of three relay K 21, K22, K23.

Three cycle pulse changes in amplitude control circuits are formed by connecting by three d type flip flop IC41, IC42, IC43, three triode VT41, VT42, VT43, three different resistance R 01, R02, R03, three relay K 41, K42, K43, two NAND gate FA4, FB4, time-base circuit ID4, variable resistor RF4, resistance R 41～R45, capacitor C 44, C45 of resistance.As can be seen from Figure 2, the element composition of this circuit and connected mode and aforesaid three cycle pulse frequency change control circuits are basic identical, and difference just connects resistance R 01, R02, R03 respectively at the normally opened contact of three relay K 41, K42, K43.

The pulse signal generator circuit is by two NAND gate HF1, HF2, two diode VD301, VD302, resistance R 301, four variable resistor R31～R34 are formed by connecting, two inputs of the output of NAND gate HF1 and NAND gate HF2 join, variable resistor R33, R32, it is in parallel with the series circuit of being made up of variable resistor R34 and diode VD301 again after R31 and diode VD302 connect successively, two diode VD301, the negative pole of VD302 joins, one end of resistance R 301 and two diode VD301, the negative pole of VD302 joins, and two inputs of the other end and NAND gate HF1 join.

The pulse signal intensifier circuit is formed by connecting by field effect transistor VT, diode VD, triode VT0, resistance R 1～R4, the base stage of triode VT0 and resistance R 1 are joined, the emitter of triode VT0 is by resistance R 3 ground connection, the collector electrode of triode VT0 meets working power VCC by resistance R 2, the grid of field effect transistor VT joins by the emitter of resistance R 4 with triode VT0, and the positive pole of the output of field effect transistor VT and diode VD joins.

As shown in Figure 2, three capacitor C 11, C12, C13 in the three cycle pulse frequency change control circuits are attempted by the output of NAND gate HF2 in the pulse signal generator circuit, and the common port of three relay K 11, K12, K13 is attempted by the negative pole of diode VD302; The common port of three relay K 21, K22, K23 is attempted by the output of NAND gate HF1 in the pulse signal generator circuit in the three cycle pulse change in duty cycle control circuits, the normally opened contact of relay K 21 is connected between variable resistor R31 and the R32, the normally opened contact of relay K 22 is connected between variable resistor R32 and the R33, and the normally opened contact of relay K 23 is connected between variable resistor R33 and the R34; The common port of three relay K 41, K42, K43 joins with Switching Power Supply VDD simultaneously in the three cycle pulse changes in amplitude control circuits, and resistance R 41, R42, R43 are attempted by the input of field effect transistor VT in the pulse signal intensifier circuit; One end of the resistance R 1 in the pulse signal intensifier circuit and the base stage of triode VT0 are joined, the output of NAND gate HF2 joins in the other end and the pulse signal amplifier circuit, and the negative pole of diode VD joins with the common port of work indication and control circuit repeat circuit K0.The positive pole of diode VD0 joins the minus earth of lead acid accumulator to be repaired in the positive pole of lead acid accumulator to be repaired and work indication and the control circuit.

In three cycle pulse frequency change control circuits, control the time that each road is connected by the multivibrator that time-base circuit ID1, capacitor C 14, C15, variable resistor RF1 form, can change the length of turn-on time by regulating variable resistor RF1, promptly control the operating time of every kind of pulse frequency.The control of three relay K 11, K12, K13 subject clock signal in circuit has only one to be in attracting state, connects C11, C12, C13, produces the pulse of different frequency to pulse signal generator.When actual fabrication, IC11, IC12, IC13 can adopt any three d type flip flops among the CD40175, and FA1, FB1 can adopt any two NAND gate among the CD4011, and ID1 can adopt 555 type integrated packages.

The operation principle of the operation principle of three cycle pulse change in duty cycle control circuits and three cycle pulse frequency change control circuits is basic identical, what just regulate when engage relay K21, K22, K23 respectively is the duty ratio of pulse signal, equally, regulating the variable resistor RF2 that is connected on the time-base circuit ID2 can make the pulse signal duration that is operated in each duty ratio change.Equally, when actual fabrication, IC21, IC22, IC23 can adopt any three d type flip flops among the CD40175, and FA2, FB2 can adopt any two NAND gate among the CD4011, and ID2 can adopt 555 type integrated packages.

In the pulse signal generator circuit, VD301, VD302 can adopt two 4148 triodes, and HF1, HF2 can adopt any two NAND gate among the CD4011.Its signal frequency is subjected to that capacitor C 11, C12, C13 control in the three cycle pulse frequency change control circuits, connect the pulse signal that K11, K12, K13 can obtain different frequency in order at different time, connect the pulse signal that K21, K22, K23 can obtain different duty in order at different time.The different frequency that pulse signal generator produces, the pulse signal of different duty amplify the grid of delivering to field effect transistor VT by the triode VT0 in the pulse signal intensifier circuit, produce different voltage signals at grid.

The operation principle of three cycle pulse amplitude control circuits is also basic identical with the operation principle of three cycle pulse frequency change control circuits, at different time engage relay K switch 41, K42, K43 in order, respective sequence is connected power resistor R41, R42, R43, then the scalable pulse amplitude is regulated the operating time that RF4 can control every kind of pulse amplitude.Equally, when actual fabrication, IC41, IC42, IC43 can adopt any three d type flip flops among the CD40175, and FA4, FB4 can adopt any two NAND gate among the CD4011, and ID4 can adopt 555 type integrated packages.

In work indication and control circuit, relay K 0 is the single-pole double throw relay, by regulating two variable resistor RF01, RF02, can set the numerical value of comparative level, the opportunity of control operational amplifier IC01 output high level.

In working indication and control circuit, connect the lead acid accumulator E that will repair, and after connecting Switching Power Supply VDD, whole instrument for repairing is just started working, and will add the pulse electrical signal of frequency change, change in duty cycle, changes in amplitude at storage battery E two ends.When just beginning to repair, the accumulator positive pole tension is lower, at this moment the IC01 output low level, light-emitting diode VD01 is in low level and does not work, and IC02 output high level, light-emitting diode VD02 work, glow green, expression is repaired, and along with reparation is carried out, cell voltage constantly raises, when voltage reaches predetermined value, IC01 exports high level, VD01 work, jaundice light, and the IC02 output low level, VD02 does not work, and green glow goes out, and the expression repair process is finished, triode VT0 conducting, relay K 0 disconnects, and instrument for repairing stops can to take off the battery detecting repairing effect to battery reparation power supply.

Claims (7)

1, a kind of lead acid accumulator instrument for repairing, it is characterized in that by the pulse signal generator circuit, the pulse signal intensifier circuit, three cycle pulse frequency change control circuits, three cycle pulse change in duty cycle control circuits, three cycle pulse changes in amplitude control circuits, work indication and control circuit are formed by connecting, three cycle pulse frequency change control circuits link to each other with the pulse signal generator circuit, three cycle pulse change in duty cycle control circuits also link to each other with the pulse signal generator circuit, the pulse signal generator circuit links to each other with the pulse signal intensifier circuit, three cycle pulse changes in amplitude control circuits link to each other with the pulse signal intensifier circuit, and the pulse signal intensifier circuit links to each other with work indication and control circuit.

2, lead acid accumulator instrument for repairing as claimed in claim 1, it is characterized in that described three cycle pulse frequency change control circuits are by three d type flip flop IC11, IC12, IC13, three triode VT11, VT12, VT13, three capacitor C 11 that capacity is different, C12, C13, three relay K 11, K12, K13, two NAND gate FA1, FB1, a time-base circuit ID1, variable resistor RF1, resistance R 11～R15, capacitor C 14, C15 is formed by connecting, the Q pin of d type flip flop IC11 links to each other with the base stage of triode VT11 by resistance R 11, the collector electrode of triode VT11 links to each other with relay K 11, one end of capacitor C 11 links to each other with the normally opened contact of relay K 11, the Q pin of d type flip flop IC12 links to each other with the base stage of triode VT12 by resistance R 12, the collector electrode of triode VT12 links to each other with relay K 12, one end of capacitor C 12 links to each other with the normally opened contact of relay K 12, the Q pin of d type flip flop IC13 links to each other with the base stage of triode VT13 by resistance R 13, the collector electrode of triode VT13 links to each other with relay K 13, one end of capacitor C 13 links to each other with the normally opened contact of relay K 13, relay K 11, relay K 12, the common port of relay K 13 links to each other, the D pin of d type flip flop IC11 links to each other with the Q pin of d type flip flop IC12, the D pin of d type flip flop IC12 links to each other with the Q pin of d type flip flop IC13, the Q pin of d type flip flop IC12 and the Q pin of d type flip flop IC13 connect two inputs of NAND gate FB1 respectively, two inputs of NAND gate FA1 connect the output of NAND gate FB1 simultaneously, the D pin of the output termination d type flip flop IC11 of NAND gate FA1, three d type flip flop IC11, IC12, IC13 meets working power VCC by resistance R 14, three triode VT11, VT12, the emitter of VT13 is ground connection all, 6 pin of time-base circuit ID1 and the 2 pin back that joins be connected in series the variable resistor RF1 CP pin of while and d type flip flop IC11 again, the CP pin of IC12, the CP pin of IC13 links to each other, 5 pin serial connection capacitor C, the 15 back ground connection of time-base circuit ID1,2 pin serial connection capacitor C, the 14 back ground connection of time-base circuit ID1.

3, lead acid accumulator instrument for repairing as claimed in claim 1, it is characterized in that described work indication and control circuit are by two operational amplifier IC01, IC02, three variable resistor RF01, RF02, RF03, resistance R 01～R06, capacitor C 01, diode VD0, two light-emitting diode VD01, VD02, triode VT0, relay K 0 is formed by connecting, positive input terminal with operational amplifier IC01 behind the negative pole series resistance R06 of diode VD0 joins, also join after variable resistor RF02 and capacitor C 01 are in parallel with the positive input terminal of operational amplifier IC01, the negative input end of operational amplifier IC01 meets working power VCC after by variable resistor RF01, resistance R 05 1 end ground connection, the negative input end of the other end and operational amplifier IC01 joins, the negative input end of the output of operational amplifier IC01 and operational amplifier IC02 joins, the positive input terminal of operational amplifier IC02 meets working power VCC after by resistance R 03, variable resistor RF03 one end ground connection, the positive input terminal of the other end and operational amplifier IC02 joins, the output connecting resistance R02 of operational amplifier IC02, the other end of resistance R 02 is by ground connection behind the light-emitting diode VD02, one end of resistance R 01 and the output of operational amplifier IC01 join, the other end is by ground connection behind the light-emitting diode VD01, the base stage of triode VT0 is joined by the output of resistance R 04 with operational amplifier IC01, the grounded emitter of VT0, the collector electrode of VT0 and relay K 0 are joined, and the positive pole of the normally opened contact of relay K 0 and diode VD0 joins.

4, lead acid accumulator instrument for repairing as claimed in claim 1 is characterized in that described three cycle pulse change in duty cycle control circuits are formed by connecting by three d type flip flop IC21, IC22, IC23, three triode VT21, VT22, VT23, three relay K 21, K22, K23, two NAND gate FA2, FB2, time-base circuit ID2, variable resistor RF2, resistance R 21～R24, capacitor C 24, C25.

5, lead acid accumulator instrument for repairing as claimed in claim 1 is characterized in that described three cycle pulse changes in amplitude control circuits are formed by connecting by three d type flip flop IC41, IC42, IC43, three triode VT41, VT42, VT43, three different resistance R 01, R02, R03, three relay K 41, K42, K43, two NAND gate FA4, FB4, time-base circuit ID4, variable resistor RF4, resistance R 41～R45, capacitor C 44, C45 of resistance.

6, lead acid accumulator instrument for repairing as claimed in claim 1, it is characterized in that described pulse signal generator circuit is by two NAND gate HF1, HF2, two diode VD301, VD302, resistance R 301, four variable resistor R31～R34 are formed by connecting, two inputs of the output of NAND gate HF1 and NAND gate HF2 join, variable resistor R33, R32, it is in parallel with the series circuit of being made up of variable resistor R34 and diode VD301 again after R31 and diode VD302 connect successively, two diode VD301, the negative pole of VD302 joins, one end of resistance R 301 and two diode VD301, the negative pole of VD302 joins, and two inputs of the other end and NAND gate HF1 join.

7, lead acid accumulator instrument for repairing as claimed in claim 1, it is characterized in that described pulse signal intensifier circuit is formed by connecting by field effect transistor VT, diode VD, triode VT0, resistance R 1～R4, the base stage of triode VT0 and resistance R 1 are joined, the emitter of triode VT0 is by resistance R 3 ground connection, the collector electrode of triode VT0 meets working power VCC by resistance R 2, the input of field effect transistor VT joins by the emitter of resistance R 4 with triode VT0, and the positive pole of the output of field effect transistor VT and diode VD joins.

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