CN201674261U - Intelligent battery charger - Google Patents

Abstract

The utility model discloses an intelligent battery charger, which comprises a rectifier filtering and starting circuit, a control circuit, a transformer, an output rectifier filtering circuit, a feedback circuit and a timing circuit, wherein the timing circuit comprises a four-operation amplifier IC3 and a singlechip IC4; maximum charging time and maximum threshold value charging time are stored in the singlechip IC4; the four-operation amplifier IC3 controls the singlechip IC4 to start two timing functions of the maximum charging time and the maximum threshold value charging time, and when the set time is up, if the battery is not transferred into a float charge stage, the singlechip IC4 is controlled to enforcedly a execute the transfer from constant voltage charging to float charging. The utility model adopts the timing circuit to realize the double-timing function, provides a simplest, most effective and most economic method for solving the problem that damage is caused by charging the battery for a long time by gate threshold voltage, effectively avoids overlong time for battery charging, and prolongs the service life of the charger.

Description

A kind of intelligent electric electrolytic battery charger

Technical field

The utility model relates to a kind of charger, particularly a kind of intelligent electric electrolytic battery charger of electric vehicle.

Background technology

Along with developing rapidly of electric motor car industry, the use of battery is very extensive.Though battery has low cost of manufacture, big, the cheap advantage of capacity, because its intrinsic characteristic, if improper use, the life-span will shorten greatly.The factor that influences battery life is a lot, adopts correct charging modes, can effectively prolong the useful life of battery.And the critical piece of electric motor car is a battery, and what cost was the highest also is battery, the still battery that loss at present is the fastest.Therefore, manufacturer has designed various battery chargers.There is following problem with regard to present electric car charger:

One, battery being carried out threshold voltage charges for a long time.This can cause the damage of battery.At present, the battery of electric motor car is lead-acid battery mostly.The expert points out: the general charging interval was controlled at about 8 hours is advisable, the long electric energy of not only having wasted of charging interval, and can make the serious dehydration of storage battery, quicken the sulfidation of pole plate, thereby shorten the useful life of battery greatly, this is the short-lived main cause of battery.

Two, when the charger that uses is opposite with battery polar, can cause the damage of charger.For different producers, the polarity of battery is different often, and the battery of different manufacturers need be equipped with the charger of appointment now, and not only versatility is not enough for this, has caused a large amount of wastes, nor has been user-friendly to.

The utility model content

The purpose of this utility model provides a kind of intelligent electric electrolytic battery charger, and it can thoroughly solve the damage of battery being carried out the battery that the long-time charging of big electric current causes with simple method, prolongs the useful life of battery.

The technical scheme that realizes the utility model purpose is a kind of intelligent electric electrolytic battery charger, comprises rectifying and wave-filtering and starts loop, control loop, transformer, output rectification filtering circuit and feedback loop; Civil power enters through rectifying and wave-filtering and starts the loop and transfers high voltage direct current to, transfers the high-frequency action of low-voltage pulse to through control loop and transformer again, then through exporting the direct current of rectification filtering circuit output LOW voltage; Feedback loop is used to export voltage stabilizing; Also comprise timing loop; Timing loop comprises four-operational amplifier IC3 and single-chip microcomputer IC4; Single-chip microcomputer IC4 internal memory contains the longest constant-current constant-voltage charging time and the longest threshold values charging interval; Four-operational amplifier IC3 control single chip computer IC4 starts the longest constant-current constant-voltage charging time and two kinds of clocking capabilitys of the longest threshold values charging interval, when each timing then battery do not change the floating charge stage over to, then control single chip computer IC4 executes the conversion of constant voltage charge to the floating charge stage.

The model of the four-operational amplifier IC3 of described timing loop is LM2902; The model of single-chip microcomputer IC4 is 108.

The pin 1 of described timing loop single-chip microcomputer IC4 is a power end, and pin 2 is regularly a start end, and pin 5 enters the floating charge stage, pin 8 ground connection by the pin 9 control batteries of four-operational amplifier IC3; Pin 11 ground connection of four-operational amplifier IC3, pin 4 be power supply just, pin 1 provides regularly starting resistor for the pin 2 of single-chip microcomputer IC4.

The longest constant-current constant-voltage charging time of described single-chip microcomputer IC4 stored is 11 hours, and the longest threshold values charging interval is 3 hours.

The intelligent electric electrolytic battery charger also comprises the anti-reverse loop that is connected between output rectification filtering circuit and the positive and negative output of charger; Described anti-reverse loop comprises photoelectrical coupler U1 and metal-oxide-semiconductor V2, photoelectrical coupler U1 according to the polarity of battery and charger whether correspondence whether determine conducting metal-oxide-semiconductor V2.

The anode of the light-emitting diode of the photoelectrical coupler U1 in described anti-reverse loop connects the charger positive output end through resistance, and negative electrode connects the charger negative output terminal; The collector electrode of the phototriode of photoelectrical coupler U1 connects the secondary of described transformer by resistance, and emitter is through resistance R 48 ground connection; The G utmost point of the metal-oxide-semiconductor V2 in described anti-reverse loop connects the emitter of the phototriode of photoelectrical coupler U1, and the D utmost point connects charger negative output terminal, S utmost point ground connection.

The model of the photoelectrical coupler U1 in described anti-reverse loop is 817, and the model of metal-oxide-semiconductor V2 is IRF540.

The model of the main control chip IC1 of described control loop is UC3842, is used to drive the metal-oxide-semiconductor V1 that model is 8N60; Described feedback loop comprises that model is that the precision voltage regulator IC2 of TL431 and model are 817 photoelectrical coupler U2, utilizes precision voltage regulator IC2 to constitute the error voltage amplifier, and U2 adjusts output by photoelectrical coupler.

Described output rectification filtering circuit also comprise by model be diode D16, the D17 of IN5404 constitute prevent the battery current reflux circuit.

The intelligent electric electrolytic battery charger also comprises the indicating module of being made up of light-emitting diode; Described indicating module comprises power supply indicator LED1 and charging indicator light LED2.

After the utility model has adopted technique scheme, have following good effect: (1) the utility model adopts timing loop to realize the plesichronous function, be to solve battery to cause simple, the most effective, the most most economical method of damaging this difficult problem with the charging of lock threshold voltage for a long time, under the control of this timing loop, battery can be automatically converted to the floating charge state charging, convenient safety again.Effectively avoided the charger charging interval long, prolonged the useful life of charger, saved the electricity charge simultaneously, through calculating 5 degree that can economize on electricity January, 1 year 60 degree that can economize on electricity is amounted to 30 yuan of RMB.

(2) the utility model adopts anti-reverse loop effectively to solve charger when opposite with battery polar, causes the problem of the damage of charger, is applicable to various chargers, and is convenient for users to use.

(3) intelligent electric electrolytic battery charger of the present utility model also has short-circuit protection, prevents that battery current from refluxing and the indicator light additional function, has further improved the stability of charger, uses convenient.

Description of drawings

Content of the present utility model is easier to be expressly understood in order to make, and according to specific embodiment also in conjunction with the accompanying drawings, the utility model is described in further detail, wherein below

Fig. 1 is circuit theory diagrams of the present utility model.

Label is in the accompanying drawing:

Rectifying and wave-filtering and start loop 1, control loop 2, transformer 3, output rectification filtering circuit 4, feedback loop 5, comprise timing loop 6, anti-reverse loop 7, indicating module 8.

Embodiment

See Fig. 1; the intelligent electric electrolytic battery charger of present embodiment is to be that core control part cooperates four-operational amplifier IC3 with main control chip IC1; a 220VAC that is input as of design; be output as the intelligent electric electrolytic battery charger of 48V, realize to the counnter attack charging protection function of charger and to the control of three stage charging processes of the constant current-constant voltage-floating charge of battery.The circuit of intelligent electric electrolytic battery charger comprises rectifying and wave-filtering and starts loop 1, control loop 2, transformer 3, output rectification filtering circuit 4, feedback loop 5, timing loop 6, anti-reverse loop 7 and indicating module 8.Civil power enters through rectifying and wave-filtering and starts loop 1 and transfers high voltage direct current to, transfers the high-frequency action of low-voltage pulse to through control loop 2 and transformer 3 again, then through exporting the direct current of rectification filtering circuit (4) output LOW voltage.

Specifically, the main control chip IC1 in rectifying and wave-filtering and startup 1 pair of commercial power rectification filtering in loop and the start-up control loop 2.Alternating current carries out low-pass filtering by C22, TL1, C21, and wherein C22, C21 form anti-series mode interference circuit, are used to suppress normal noise, and electromagnetic interference is had very strong decay bypass effect.Filtered alternating voltage becomes the pulsating dc voltage of 310V after D1～D4 bridge rectifier and electrochemical capacitor C2 filtering, this voltage charges to C4 after R51, R54 step-down, when the voltage of C4 reaches the starting resistor threshold value of the main control chip IC1 in the control loop 2, main control chip IC1 starts working and driving pulse is provided, by the metal-oxide-semiconductor V1 work that rises in the pin 6 output start-up control loops 2.Along with the startup of main control chip IC1, the work of R51, R54 is also just basic to be finished, and remaining task is given the feedback winding, produces voltage by the feedback winding and gives main control chip IC1 power supply.Because input voltage has surpassed the operating voltage of main control chip IC1,,, avoid main control chip IC1 to be damaged with the input voltage of ZD1 voltage-stabiliser tube qualification main control chip IC1 for fear of accident.

The model of the main control chip IC1 of control loop 2 is UC3842, is used to drive the metal-oxide-semiconductor V1 that model is 8N60.The Resistor-Capacitor Unit of the pin 1 external feedback loop 5 of main control chip IC1 is used for the frequency characteristic of compensating error amplifier; Pin 2 is feedback voltage inputs, and sampling voltage is added to the inverting input of error amplifier, and the reference voltage with in-phase input end compares again, produces error voltage; Pin 3 is current detecting inputs, cooperates with resistance, constitutes current foldback circuit; Pin 4 external saw-toothed oscillator external definition resistance R 6 and timing capacitor C7, the decision frequency of oscillation; Pin 5 ground connection; Pin 6 output square-wave pulse driven MOS pipe V1 work; Pin 7 is a positive source; The reference voltage V REF of pin 8 is 0.5V.The resistance of adjusting R1 can be adjusted the maximum current of charger.Because the instability of input voltage, perhaps other external factor causes circuit short circuit, overvoltage to occur, under-voltage etc. be unfavorable for that the phenomenon of circuit working takes place sometimes, and therefore, circuit must have the certain protection function.When for a certain reason, output short circuit and produce overcurrent, the D electrode current of metal-oxide-semiconductor V1 will rise significantly, and the voltage at R1 two ends rises, and the voltage on the pin 3 of main control chip IC1 also rises.When the voltage of pin 3 reached 1V above normal value 0.3V, the PWM comparator output high level of main control chip IC1 resetted the PWM latch, closes output.At this moment, pin 6 no-outputs of main control chip IC1, metal-oxide-semiconductor V1 ends, thereby has protected circuit.If supply power voltage generation overvoltage, as more than 265V, main control chip IC1 can't regulate duty ratio, and the elementary winding voltage of transformer 3 improves greatly, and pin 7 supply power voltages of main control chip IC1 also sharply rise, and the voltage of its pin 2 also rises, and closes output.If the voltage of electrical network is lower than 85V, pin 1 voltage of main control chip IC1 also descends, and when dropping to 1V (normal value is 3.4V) when following, PWM comparator output high level resets the PWM latch, closes output.

Transformer 3 is a high-frequency pulse transformer, and its effect of T1 has three: the firstth, will press high-voltage pulse to be action of low-voltage pulse; The secondth, play the effect of isolated high-voltage, with protection against electric shock; The 3rd is to provide working power for the main control chip IC1 in the control loop 2.

In the output rectification filtering circuit 4, D15 is the high-frequency rectification pipe, forms the RC buffer circuit with R50 and C16, to reduce the peak voltage of diode D15.C17, C23 are low-voltage filter electric capacity.D16, D17 formation prevents the battery current reflux circuit, plays preventing that battery current from pouring in down a chimney the effect to charger.R32 be current sampling resistor (0.1 ohm, 3w).

Feedback loop 5 comprises that model is that the precision voltage regulator IC2 of TL431 and model are 817 photoelectrical coupler U2, utilizes precision voltage regulator IC2 to constitute the error voltage amplifier, and U2 adjusts output by photoelectrical coupler.Utilize the adjustable accurate pressurizer of TL431 to constitute the error voltage amplifier, by photoelectrical coupler U2 output is adjusted accurately again.R13, R15, R16, R64, R57 are the external controlling resistances of precision voltage regulator IC2, and the height and the precision voltage regulator IC2 of their decision output voltages form the external error amplifier in the lump.When output voltage raises, sampling voltage on the R7 also increases, setting voltage is greater than the reference voltage 2.5V of precision voltage regulator IC2, the output voltage of the error amplifier in the precision voltage regulator IC2 is raise, cause the output voltage that drives phototriode in the sheet to reduce, output voltage V o is descended, and last Vo tends towards stability; Otherwise, output voltage descends and causes that voltage is set to descend, when output voltage is lower than when voltage is set, the output voltage of error amplifier descends, the output voltage of the driving phototriode in the sheet raises, and finally makes the compensation input current of pin 1 of main control chip IC1 change thereupon, impels in the sheet PWM comparator is regulated, change duty ratio, reach the purpose of voltage stabilizing.

Timing loop 6 comprises four-operational amplifier IC3 and single-chip microcomputer IC4; Single-chip microcomputer IC4 internal memory contains 11 hours the longest constant-current constant-voltage charging time and 3 hours the longest threshold values charging intervals; Four-operational amplifier IC3 control single chip computer IC4 starts the longest constant-current constant-voltage charging time and two kinds of clocking capabilitys of the longest threshold values charging interval, when each timing then battery do not change the floating charge stage over to, then control single chip computer IC4 executes the conversion of constant voltage charge to the floating charge stage.The model of four-operational amplifier IC3 is LM2902; The model of single-chip microcomputer IC4 is 108.The pin 1 of single-chip microcomputer IC4 is a power end, and pin 2 is regularly a start end, and pin 5 enters the floating charge stage, pin 8 ground connection by the pin 9 control batteries of four-operational amplifier IC3; Pin 11 ground connection of four-operational amplifier IC3, pin 4 be power supply just, pin 1 provides regularly starting resistor for the pin 2 of single-chip microcomputer IC4.Charger carries out constant current-constant voltage-three charging stages of floating charge to battery, and when charger started the constant current charge of phase I, single-chip microcomputer IC4 started the clocking capability of 11 hours the longest constant-current constant-voltage charging time automatically.When cell voltage rose to the 57.6V left and right sides, charger entered the constant voltage charge stage, and output voltage maintains about 57.6V, and charger enters constant voltage charge stage after-current and reduces gradually.When charger when the constant-voltage phase electric current drops to the 1.4A left and right sides, 1 pin of four-operational amplifier IC3 output high level triggers 2 pin of single-chip microcomputer IC4, makes it begin the timing stage in 3 hour threshold values charging interval the longest.In 3 hours stage in the longest threshold values charging interval, if charger has been finished the conversion of constant voltage charge to floating charge, illustrating charges finishes, if arrived 3 hour time, but still do not finish the conversion of constant voltage charge to floating charge, then the output of 5 pin of single-chip microcomputer IC4 will be executed this conversion, promptly execute the conversion of constant voltage charge to floating charge.When not finishing the conversion of constant voltage charge automatically to floating charge, or still be when forcing conversion to fail to carry out after 3 hours owing to accident, after 11 hours the longest constant-current constant-voltage charging time arrived, single-chip microcomputer IC4 executes the conversion of constant voltage charge to floating charge once more, has prevented long large current charge of battery so that damage with regard to dual timing like this.Change R59 ^*, R24 resistance can adjust the turning point electric current that charger changes floating charge.

Anti-reverse loop 7 is connected between output rectification filtering circuit 4 and the positive and negative output of charger.Comprise photoelectrical coupler U1 and metal-oxide-semiconductor V2, the model of photoelectrical coupler U1 is 817, and the model of metal-oxide-semiconductor V2 is IRF540.Photoelectrical coupler U1 according to the polarity of battery and charger whether correspondence whether determine conducting metal-oxide-semiconductor V2.The anode of the light-emitting diode of photoelectrical coupler U1 connects the charger positive output end through resistance R 31, and negative electrode connects the charger negative output terminal; The collector electrode of the phototriode of photoelectrical coupler U1 connects the secondary of transformer 3 by resistance R 34, and emitter is through resistance R 48 ground connection; The G utmost point of the metal-oxide-semiconductor V2 in anti-reverse loop 7 connects the emitter of the phototriode of photoelectrical coupler U1, and the D utmost point connects charger negative output terminal, S utmost point ground connection.When not connecting battery, charger do not have output voltage.If battery and charger voltage are corresponding, start working in the anti-reverse loop 7 of this moment, be charger positive output end DC+, R31, U1, charger negative output terminal DC-forms the loop, after photoelectrical coupler U1 starts working, the light-emitting diode conducting of photoelectrical coupler U1 and luminous, phototriode is subjected to producing electric current after the illumination, C, the conducting of the E utmost point, this moment transformer 3 the secondary D7 that passes through, R34, U1 gives driving voltage of metal-oxide-semiconductor V2, R48 forms the output voltage of the emitter of the phototriode among the U1, form simultaneously the G pole tension of metal-oxide-semiconductor V2 again, make the D of metal-oxide-semiconductor V2, the conducting of the S utmost point, be output and power ground short circuit, entire circuit forms the loop, and charger is started working.If battery and charger polarity are anti-, the positive pole that is battery connects power cathode, when the negative pole of battery connects power supply anodal, the Light-Emitting Diode of photoelectrical coupler U1 is in anti-state partially, phototriode ends, be that photoelectrical coupler U1 does not work, the D of metal-oxide-semiconductor V2, the S utmost point can conductings under this state, and circuit is in the no-output state.So the cell voltage electric current can instead not be added on the loop of charger under this kind situation, unlikely charger is damaged.

Indicating module 8 comprises power supply indicator LED1 and charging indicator light LED2.Charged state indicator light LED2 comprises green light and red light, and green light is represented to be in the charging stage.

During the energising beginning, the voltage about 300V is arranged on the C2.This voltage one tunnel is loaded into metal-oxide-semiconductor V1 through transformer T1.The second the tunnel through R51, R54, C4, reaches the 7th pin of main control chip IC1, forces main control chip IC1 to start.The 6 pin output square-wave pulse of main control chip IC1, driven MOS pipe V1 work, electric current arrives ground through R1.Transformer T1 secondary coil produces induced voltage simultaneously, and the voltage of T1 output winding obtains stable voltage through D15, C17, C23 rectifying and wave-filtering.This voltage one tunnel charges the battery through D16, D17.The second the tunnel provides working power through D7, R68, R49 for IC3 and IC4 and peripheral circuit thereof.Another road is through D8, and R35 arrives feedback loop 5, and voltage is reduced.D9 provides reference voltage for IC3, reaches the 12nd pin of IC3 through R21, R17 dividing potential drop.When charging normal, there is the 0.18V left and right sides voltage R21 upper end, and this voltage is added to IC3 the 12nd pin, and 13 pin of IC3 sampled voltage during for charging is when 13 pin are sent low-voltage from 14 pin during greater than 12 pin voltages.This moment, the 10 pin voltages of IC3 were higher than 9 pin, and red light is lighted thereby 8 pin are exported high level LED2, while 7 pin output low levels, and the LED2 green light is lighted charger and is entered the constant current charge stage.When cell voltage rose to the 57.6V left and right sides, charger entered the constant voltage charge stage, and output voltage maintains about 57.6V, and charger enters the constant voltage charge stage, and electric current reduces gradually.When charging current was reduced to 400mA-500mA, the 9 pin voltages of IC3 were higher than 10 pin, 8 pin output LOW voltages, and the LED2 red light goes out, while 7 pin output HIGH voltages, the LED2 green light is bright, and charger enters the floating charge stage.When charger began constant current charge, 2 pin of the 1 pin output low level signal triggering single-chip microcomputer IC4 of IC3 began the timing of 11 hours the longest constant-current constant-voltage charging time.The 5.1V reference voltage that D9 provides provides voltage about 0.12V for 3 pin of IC3 after R28, R30 dividing potential drop, when the charger charging current reaches the 1.4A left and right sides of constant-voltage phase, 2 pin of IC3 just sample the voltage about 0.12V, the 2 pin voltages of IC3 are lower than this voltage, 3 pin and 2 pin compare then, 3 pin voltages are higher than 2 pin voltages, the 1 pin output high level of IC3, and this high level is through resistance R 20, R20 ^*, the timing starting resistor of 5V is provided for 2 pin of single-chip microcomputer IC4 after the R38 dividing potential drop, the timing function in 3 hours the longest threshold values charging intervals of this moment begins to start.3 hours timing stages, if charger has been finished the conversion of constant voltage charge to floating charge, illustrating charges finishes, if also do not finish the conversion of constant voltage charge to floating charge 3 hours timing stages, single-chip microcomputer IC4 will make the 5 pin output high level of this chip after expiring in 3 hours, this high level makes amplifier 8 pin output low levels through 9 pin of R29, D10 arrival amplifier IC3 after 9 pin and 10 pin compare, this moment, the red light of charging indicator light LED2 went out.8 pin, 6 pin of IC3 lead to, therefore 6 pin also are low levels, 6 pin and 5 pin compare, 5 pin benchmark 5.1V, obtaining 7 pin is high level, this moment, the green light of charging indicator light LED2 was bright, D11 ends, charger enters the charging of floating charge stage, and promptly the timing function in 3 hours the longest threshold values charging intervals plays effect, and the timing function of 11 hours the longest constant-current constant-voltage charging time of this moment ceases to be in force automatically.When constant voltage charge to the conversion of floating charge or 3 hours timing functions because fortuitous event does not play effect, after charging reaches 11 hours, single-chip microcomputer IC4 will start 5 pin amplifier IC3 will be controlled, principle and 3 hours the longest threshold values charging intervals timing are consistent to the principle of carrying out when forcing conversion, slice is executed the conversion of constant voltage charge to floating charge once more after 11 hours, has prevented long large current charge of battery so that damage with regard to dual timing like this.

Should be appreciated that specific embodiment described above only is used to explain the utility model, and be not used in qualification the utility model.Conspicuous variation of being extended out by spirit of the present utility model or change still are among the protection range of the present utility model.

Claims (10)

1. an intelligent electric electrolytic battery charger comprises rectifying and wave-filtering and starts loop (1), control loop (2), transformer (3), output rectification filtering circuit (4) and feedback loop (5); Civil power enters through rectifying and wave-filtering and starts loop (1) and transfers high voltage direct current to, transfers the high-frequency action of low-voltage pulse to through control loop (2) and transformer (3) again, then through exporting the direct current of rectification filtering circuit (4) output LOW voltage; Feedback loop (5) is used to export voltage stabilizing; It is characterized in that: also comprise timing loop (6); Timing loop (6) comprises four-operational amplifier (IC3) and single-chip microcomputer (IC4); Single-chip microcomputer (IC4) internal memory contains the longest constant-current constant-voltage charging time and the longest threshold values charging interval; Four-operational amplifier (IC3) control single chip computer (IC4) starts the longest constant-current constant-voltage charging time and two kinds of clocking capabilitys of the longest threshold values charging interval, when each timing then battery do not change the floating charge stage over to, then control single chip computer (IC4) is executed the conversion of constant voltage charge to the floating charge stage.

2. a kind of intelligent electric electrolytic battery charger according to claim 1 is characterized in that: the model of the four-operational amplifier (IC3) of described timing loop (6) is LM2902; The model of single-chip microcomputer (IC4) is 108.

3. a kind of intelligent electric electrolytic battery charger according to claim 2, it is characterized in that: the pin 1 of the single-chip microcomputer (IC4) of described timing loop (6) is power end, pin 2 is regularly a start end, pin 5 enters the floating charge stage, pin 8 ground connection by the pin 9 control batteries of four-operational amplifier (IC3); Pin 11 ground connection of four-operational amplifier (IC3), pin 4 be power supply just, pin 1 provides regularly starting resistor for the pin 2 of single-chip microcomputer (IC4).

4. a kind of intelligent electric electrolytic battery charger according to claim 3 is characterized in that: the longest constant-current constant-voltage charging time of single-chip microcomputer (IC4) stored of described timing loop (6) is 11 hours, and the longest threshold values charging interval is 3 hours.

5. according to the described a kind of intelligent electric electrolytic battery charger of one of claim 1 to 4, it is characterized in that: also comprise the anti-reverse loop (7) that is connected between output rectification filtering circuit (4) and the positive and negative output of charger; Described anti-reverse loop (7) comprises photoelectrical coupler (U1) and metal-oxide-semiconductor (V2), photoelectrical coupler (U1) according to the polarity of battery and charger whether correspondence whether determine conducting metal-oxide-semiconductor (V2).

6. a kind of intelligent electric electrolytic battery charger according to claim 5, it is characterized in that: the anode of the light-emitting diode of the photoelectrical coupler (U1) in described anti-reverse loop (7) connects the charger positive output end through resistance (R31), and negative electrode connects the charger negative output terminal; The collector electrode of the phototriode of photoelectrical coupler (U1) connects the secondary of described transformer (3) by resistance (R34), and emitter is through resistance (R48) ground connection; The G utmost point of the metal-oxide-semiconductor (V2) in described anti-reverse loop (7) connects the emitter of the phototriode of photoelectrical coupler (U1), and the D utmost point connects charger negative output terminal, S utmost point ground connection.

7. a kind of intelligent electric electrolytic battery charger according to claim 6 is characterized in that: the model of the photoelectrical coupler (U1) in described anti-reverse loop (7) is 817, and the model of metal-oxide-semiconductor (V2) is IRF540.

8. a kind of intelligent electric electrolytic battery charger according to claim 7 is characterized in that: the model of the main control chip (IC1) of described control loop (2) is UC3842, is used to drive the metal-oxide-semiconductor that model is 8N60 (V1); Described feedback loop (5) comprises that model is that the precision voltage regulator (IC2) of TL431 and model are 817 photoelectrical coupler (U2), utilizes precision voltage regulator (IC2) to constitute the error voltage amplifier, and (U2) adjusts output by photoelectrical coupler.

9. a kind of intelligent electric electrolytic battery charger according to claim 8 is characterized in that: described output rectification filtering circuit (4) also comprise by model be the diode (D16, D17) of IN5404 constitute prevent the battery current reflux circuit.

10. a kind of intelligent electric electrolytic battery charger according to claim 9 is characterized in that: also comprise the indicating module of being made up of light-emitting diode (8); Described indicating module (8) comprises power supply indicator (LED1) and charging indicator light (LED2).

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