CN2927451Y - High-frequency intelligent battery charger - Google Patents

Abstract

The utility model relates to an intelligent high frequency storage battery charger, comprising an SCM control circuit and a charging control circuit and a detection circuit for respective circuit connection of the single chip; wherein the single chip control circuit comprises a single chip and also an auxiliary power circuit and a key-press display circuit for respective circuit connection of the single chip; the charging control circuit comprises a pulse width modulation circuit, a driving circuit, a rectifier filter circuit, and an output control circuit, all for circuit connection, and a current sampling circuit; the detection circuit comprises a battery detection circuit, a reverse connecting detection circuit, a battery-voltage detection circuit and an automatic pole circuit. The utility model provides an intelligent high frequency storage battery charger which is connected with the storage battery and can automatically detect the with-or-without of the battery and then judge and regulate the electrode of the battery; the utility model adopts the intermittence voltage sample of the battery so as to ensure no overcharge or low-charge and is high in efficiency and energy saving, reliable and convenient in application and better in maneuverability.

Description

Intelligent high-frequency accumulator charger

Technical field

The utility model relates to a kind of battery charger, relates in particular to a kind of intelligent high-frequency accumulator charger.

Background technology

General battery charger mainly is made up of Industrial Frequency Transformer and fairly simple control circuit.The volume and weight of Industrial Frequency Transformer is bigger, and charging process is slower, and charging modes is single.This circuit has output once powering on, and control circuit detects comparison in real time to battery tension, changes the different charging stages over to according to the magnitude of voltage of setting then, has been full of and then enters floating charge when detecting battery.

When this kind charger is connected with storage battery, just can start charger after must connecting storage battery earlier, connect storage battery again behind the charger and can produce spark if start earlier, want the polarity of scrutiny storage battery whether to connect instead simultaneously, and be easy to generate towards being discontented with or overcharging phenomenon.This just makes the reliability of this kind charger and fail safe and operability greatly reduce.

The utility model content

The purpose of this utility model is to provide a kind of intelligent high-frequency accumulator charger.Adopt high frequency technique, and in conjunction with single-chip microcomputer.Can detect automatically when it is connected with storage battery and have or not battery, judge battery polar simultaneously, no matter battery is just to connect or the equal operate as normal of reversal connection but make, and the voltage rising characteristic during according to charge in batteries, adopt " batch (-type) " battery voltage sampling, can guarantee that battery can not overcharge or be not fully filled.The utility model is energy-efficient, and safety easy to use is workable.

In order to achieve the above object, the utility model provides a kind of intelligent high-frequency accumulator charger, comprises single chip machine controlling circuit, circuit connects the charging control circuit and the testing circuit of described single chip machine controlling circuit respectively;

Described single chip machine controlling circuit comprises single-chip microcomputer, also comprises auxiliary power circuit and button display circuit that circuit respectively connects described single-chip microcomputer;

The work of the whole intelligent high-frequency accumulator charger of described Single-chip Controlling;

Described auxiliary power circuit produces required accessory power supply by auxiliary transformer after the charger that the utility model provides is provided power supply;

Described button display circuit comprises plurality of keys and the some display lamps that circuit connects, and indicates the operating state of whole battery charger;

Described charging control circuit comprises pulse width modulation circuit, drive circuit, current rectifying and wave filtering circuit and output control circuit, also comprises current sampling circuit;

Described pulse width modulation circuit, its inlet circuit connects the output of described single-chip microcomputer; Described drive circuit, its inlet circuit connects the output of described pulse width modulation circuit; Described current rectifying and wave filtering circuit, its inlet circuit connects the output of described drive circuit; Described output control circuit, its inlet circuit connects the output of described current rectifying and wave filtering circuit and single-chip microcomputer, and its circuit of output terminal connects described pulse width modulation circuit and storage battery; Described current sampling circuit is obtained current value by the current sample transformer, its respectively circuit connect described pulse width modulation circuit and single-chip microcomputer;

Described pulse width modulation circuit comprises pulse width modulation chip and peripheral circuit; This peripheral circuit connects described pulse width modulation chip;

Further, described pulse width modulation circuit also comprises current-limiting protection circuit, and this current-limiting protection circuit connects described current sampling circuit and drive circuit;

Described drive circuit comprises some driving transformers, drive logic and some power switch pipes of circuit connection successively;

Further, described charging control circuit also comprises temperature sensing circuit and battery discharging circuit; Described temperature sensing circuit connects described single-chip microcomputer; Described battery discharging circuit circuit respectively connects described single-chip microcomputer and storage battery;

Described testing circuit comprises battery detection circuit, reversal connection testing circuit and battery voltage detection circuit, also comprises automatic polar circuit; The inlet circuit of described battery detection circuit connects described storage battery, and the circuit of output terminal of this battery detection circuit connects described single-chip microcomputer; The inlet circuit of described reversal connection testing circuit connects described storage battery, and the circuit of output terminal of this reversal connection testing circuit connects described single-chip microcomputer; The inlet circuit of described battery voltage detection circuit connects described storage battery, and the circuit of output terminal of this battery voltage detection circuit connects described single-chip microcomputer; The inlet circuit of described automatic polar circuit connects described single-chip microcomputer, and the circuit of output terminal of this automatic polar circuit connects described storage battery;

After a kind of intelligent high-frequency accumulator charger that the utility model provides was provided power supply, the power supply indicator on the button display circuit was bright, and auxiliary power circuit produces required accessory power supply by auxiliary transformer;

Whether battery detection circuit detects has storage battery to connect, if storage battery is arranged, this battery detection circuit can produce a high signal when detecting and pass to single-chip microcomputer, if no storage battery, this battery detection circuit can produce a low signal when detecting and pass to single-chip microcomputer; If no storage battery connects, single-chip microcomputer is then given low signal of output control circuit, button on the button display circuit is invalid at this moment, program is not moved, charger is output not, if connected storage battery, whether the reversal connection testing circuit will detect accumulator polarity and connect correct, and the result sent to single-chip microcomputer with the form of high level signal or low level signal, if accumulator polarity reversal connection, then the automatic polar circuit of Single-chip Controlling connects correctly accumulator polarity, after having only the correct connection of accumulator polarity, just can select the size of charging current by the button on the button display circuit, this moment, battery voltage detection circuit detected the accumulator voltage that inserts, and passed to single-chip microcomputer after this voltage changed, single-chip microcomputer is with this amount and the desire value of establishing U1, U2, U3 compares, judge and enter which kind of charging stage:, promptly charge with 1/4 continuous current if detected magnitude of voltage U, then enters the charging of recovery formula less than U1; If during U1＜U＜U2, enter constant-current phase; If during U2＜U＜U3, enter constant-voltage phase; If during U3＜U, charge with very little electric current, this moment, battery tension rose very slowly, entered floating towards the stage;

Single-chip microcomputer provides correct control voltage and pulse-width-modulated current control signal, give pulse width modulation circuit, pulse width modulation circuit is exported two group pulse drive signals through relatively, this pulse drive signal is given drive logic by driving transformer, thus the driving power switching tube; Simultaneously, after drive logic is driven the signal driving, flow through owing to have sizable electric current, carry out current-limiting protection so be provided with current-limiting protection circuit, this current-limiting protection circuit is to be controlled by the pulse width modulation of single-chip microcomputer to realize; Current rectifying and wave filtering circuit carries out rectifying and wave-filtering to current signal, obtains current signal preferably; Sampling by current sampling circuit, the current signal that obtains is through after amplifying computing, export to pulse width modulation circuit and single-chip microcomputer, the corresponding pulse duration waveform of single-chip microcomputer output, electric current is lower than rated current if the single-chip microcomputer detection obtains this moment, then single-chip microcomputer is correctly regulated the output of control voltage, and this current value is remained in the prescribed limit; When if single-chip microcomputer detects and to obtain that this moment, electric current was higher than rated current, single-chip microcomputer also can correctly be regulated the output of control voltage, change the pulse drive signal of pulse width modulation circuit, by controlling the ON time that duty ratio (described duty ratio is meant the ratio that high level is occupied in the unit period) is come power switch pipe in the controlling and driving logical circuit;

When the timer T1 in the Single Chip Microcomputer (SCM) program arrives the time of defined, the output of single-chip microcomputer output control signal stop pulse width modulation circuit, close all power switch pipes, make not output of entire circuit, single-chip microcomputer output control signal is connected storage battery and battery discharging circuit simultaneously, storage battery is carried out of short duration discharge, when discharge time that arrive to be provided with during T2, single-chip microcomputer output control signal disconnection storage battery is connected with the battery discharging circuit, battery voltage detection circuit detects the terminal voltage of storage battery simultaneously, and through passing to single-chip microcomputer after A/D (analog/digital) conversion, single-chip microcomputer compares voltage detecting value and preset value, judge the charging stage, continue charging;

The intelligent high-frequency charger that the utility model provides is in the process of charging normal, will stop charging at regular intervals, meeting be connected storage battery between charge period with the battery discharging circuit stopping, carry out of short duration discharge, battery voltage detection circuit detects the terminal voltage of storage battery simultaneously, and through passing to single-chip microcomputer after the A/D conversion, when finished discharge time, single-chip microcomputer compared last detected value and the preset value that sends of battery voltage detection circuit, judges the charging stage, continue charging, through after the same time, repeat above-mentioned action, after battery is full of, charger can be out of service automatically, and charging process finishes;

In charging process, if temperature sensing circuit detects temperature and meets or exceeds the protection temperature limit, then temperature sensing circuit provides a level signal to single-chip microcomputer, after single-chip microcomputer is received signal, send control signal and close pulse width modulation circuit, make pulse width modulation circuit not have pulse drive signal output, power switch pipe quits work, entire circuit is output not, stops charging; When " beginning/stop " button on the display circuit that pushes button once more; temperature sensing circuit will detect temperature once more; if temperature is lower than the protection temperature limit; battery voltage detection circuit is passed to single-chip microcomputer after detected accumulator voltage is changed through A/D; single-chip microcomputer compares voltage detecting value and preset value; judge the charging stage, continue charging.

A kind of intelligent high-frequency accumulator charger that the utility model provides adopts high frequency technique, in conjunction with single-chip microcomputer.Can detect automatically when it is connected with storage battery and have or not battery, judge simultaneously whether battery polar connects correct, if incorrect, then regulates, make the circuit can operate as normal, when not having battery or battery reversal connection, circuit is output not.Only just can provide correct output satisfying above two conditions and press start button.Voltage rising characteristic during according to charge in batteries, the utility model adopts " batch (-type) " battery voltage sampling, can guarantee that battery can not overcharge or be not fully filled.The utility model is energy-efficient, and safety easy to use is workable, is applicable to the storage battery of different capabilities.

Description of drawings

Fig. 1 is the circuit structure schematic diagram of a kind of intelligent high-frequency accumulator charger of providing of the utility model.

Embodiment

Following according to Fig. 1, specify a kind of better embodiment of the present utility model:

As shown in Figure 1, the utility model provides a kind of intelligent high-frequency accumulator charger, comprises single chip machine controlling circuit, circuit connects the charging control circuit and the testing circuit of described single chip machine controlling circuit respectively;

Described single chip machine controlling circuit comprises single-chip microcomputer 1011, also comprises auxiliary power circuit 1012 and button display circuit 1013 that circuit respectively connects described single-chip microcomputer 1011;

The work of the whole intelligent high-frequency accumulator charger of described single-chip microcomputer 1011 controls;

Described auxiliary power circuit 1012 produces required accessory power supply by auxiliary transformer after the charger that the utility model provides is provided power supply;

Described button display circuit 1013 comprises plurality of keys and the some display lamps that circuit connects, and indicates the operating state of whole battery charger;

Described charging control circuit comprises pulse width modulation circuit 1021, drive circuit 1022, current rectifying and wave filtering circuit 1023 and output control circuit 1024, also comprises current sampling circuit 1025;

Described pulse width modulation circuit 1021, its inlet circuit connects the output of described single-chip microcomputer 1011; Described drive circuit 1022, its inlet circuit connects the output of described pulse width modulation circuit 1021; Described current rectifying and wave filtering circuit 1023, its inlet circuit connects the output of described drive circuit 1022; Described output control circuit 1024, its inlet circuit connect the output of described current rectifying and wave filtering circuit 1023 and single-chip microcomputer 1011, and its circuit of output terminal connects described pulse width modulation circuit 1021 and storage battery 100; Described current sampling circuit 1025 circuit respectively connects described pulse width modulation circuit 1021 and single-chip microcomputer 1011;

Described pulse width modulation circuit 1021 comprises pulse width modulation chip and peripheral circuit; This peripheral circuit connects described pulse width modulation chip;

Further, described pulse width modulation circuit 1021 also comprises current-limiting protection circuit, and this current-limiting protection circuit connects described current sampling circuit 1025 and drive circuit 1022;

Described drive circuit 1022 comprises some driving transformers, drive logic and some power switch pipes of circuit connection successively;

Further, described charging control circuit also comprises temperature sensing circuit 1026 and battery discharging circuit 1027; Described temperature sensing circuit 1026 connects described single-chip microcomputer 1011; Described battery discharging circuit 1027 circuit respectively connects described single-chip microcomputer 1011 and storage battery 100;

Described testing circuit comprises battery detection circuit 1031, reversal connection testing circuit 1032 and battery voltage detection circuit 1033, also comprises automatic polar circuit 1034; The inlet circuit of described battery detection circuit 1031 connects described storage battery 100, and the circuit of output terminal of this battery detection circuit 1031 connects described single-chip microcomputer 1011; The inlet circuit of described reversal connection testing circuit 1032 connects described storage battery 100; The inlet circuit of described battery voltage detection circuit 1033 connects described storage battery 100, and the circuit of output terminal of this battery voltage detection circuit 1033 connects described single-chip microcomputer 1011; The inlet circuit of described automatic polar circuit 1034 connects described single-chip microcomputer 1011, and the circuit of output terminal of this automatic polar circuit 1034 connects described storage battery 100;

After a kind of intelligent high-frequency accumulator charger that the utility model provides was provided power supply, the power supply indicator on the button display circuit 1013 was bright, and auxiliary power circuit 1012 produces required accessory power supply by auxiliary transformer;

Whether battery detection circuit 1031 detects has storage battery 100 to connect, if storage battery 100 is arranged, this battery detection circuit 1031 can produce a high signal when detecting and pass to single-chip microcomputer 1011, if no storage battery 100, this battery detection circuit 1031 can produce a low signal when detecting and pass to single-chip microcomputer 1011; If no storage battery 100 connects, 1011 of single-chip microcomputers are given 1024 low signals of output control circuit, button on the button display circuit 1013 is invalid at this moment, program is not moved, charger is output not, if connected storage battery 100, whether reversal connection testing circuit 1032 will detect storage battery 100 polarity and connect correct, and the result sent to single-chip microcomputer 1011 with the form of high level signal or low level signal, if storage battery 100 error-polarity connections, then the automatic polar circuit 1034 of single-chip microcomputer 1011 controls connects correctly storage battery 100 polarity, after having only the correct connection of storage battery 100 polarity, just can select the size of charging current by the button on the button display circuit 1013, storage battery 100 terminal voltages of 1033 pairs of accesses of battery voltage detection circuit this moment detect, and pass to single-chip microcomputer 1011 after this voltage changed, single-chip microcomputer 1011 is with this amount and the desire value of establishing U1, U2, U3 compares, judge and enter which kind of charging stage: if detected magnitude of voltage U is less than U1, then enter the charging of recovery formula, promptly charge with 1/4 continuous current; If during UI＜U＜U2, enter constant-current phase; If during U2＜U＜U3, enter constant-voltage phase; If during U3＜U, charge with very little electric current, this moment, storage battery 100 voltages rose very slowly, entered floating towards the stage;

Single-chip microcomputer 1011 provides correct control voltage and pulse-width-modulated current control signal, give pulse width modulation circuit 1021, pulse width modulation circuit 1021 is through comparing, export two group pulse drive signals and give drive circuit 1022, this pulse drive signal is given drive logic by driving transformer, thus the driving power switching tube; Simultaneously, after drive logic is driven the signal driving, flow through owing to have sizable electric current, carry out current-limiting protection so be provided with current-limiting protection circuit, this current-limiting protection circuit is to be controlled by the pulse width modulation of single-chip microcomputer 1011 to realize; 1023 pairs of current signals of current rectifying and wave filtering circuit carry out rectifying and wave-filtering, obtain current signal preferably; Sampling by current sampling circuit 1025, the current signal that obtains is through after amplifying computing, export to pulse width modulation circuit 1021 and single-chip microcomputer 1011, the corresponding pulse duration waveform of single-chip microcomputer 1011 outputs, electric current is lower than rated current if single-chip microcomputer 1011 detections obtain this moment, the then single-chip microcomputer 1011 correct outputs of regulating control voltage remain in the prescribed limit this current value; When if single-chip microcomputer 1011 detects and obtains that this moment, electric current was higher than rated current, single-chip microcomputer 1011 also can correctly be regulated the output of control voltage, change the pulse drive signal of pulse width modulation circuit 1021, by controlling the ON time that duty ratio (described duty ratio is meant the ratio that high level is occupied in the unit period) is come power switch pipe in the controlling and driving logical circuit;

When the timer T1 in single-chip microcomputer 1011 programs arrives the time t1 of defined, the output of single-chip microcomputer 1011 output control signal stop pulse width modulation circuits 1021, close all power switch pipes, make not output of entire circuit, single-chip microcomputer 1011 output control signals are connected storage battery 100 and battery discharging circuit 1027 simultaneously, storage battery 100 is carried out of short duration discharge, when discharge time that arrive to be provided with during t2, single-chip microcomputer 1011 output control signals disconnection storage batterys 100 are connected with battery discharging circuit 1027, the terminal voltage of 1033 pairs of storage batterys 100 of battery voltage detection circuit detects simultaneously, and through passing to single-chip microcomputer 1011 after A/D (analog/digital) conversion, single-chip microcomputer 1011 compares voltage detecting value and preset value, judge the charging stage, continue charging;

The intelligent high-frequency charger that the utility model provides is in the process of charging normal, will stop charging at regular intervals, meeting be connected storage battery 100 between charge period with battery discharging circuit 1027 stopping, carry out of short duration discharge, the terminal voltage of 1033 pairs of storage batterys 100 of battery voltage detection circuit detects simultaneously, and through passing to single-chip microcomputer 1011 after the A/D conversion, when finish discharge time, single-chip microcomputer 1011 compares battery voltage detection circuit 1027 last detected value and the preset values that send, judge the charging stage, continue charging, through after the same time, repeat above-mentioned action, after battery is full of, charger can be out of service automatically, and charging process finishes;

In charging process, if temperature sensing circuit 1026 detects temperature and meets or exceeds the protection temperature limit, then temperature sensing circuit 1026 provides a level signal to single-chip microcomputer 1011, after single-chip microcomputer 1011 is received signal, send control signal and close pulse width modulation circuit 1021, make pulse width modulation circuit 1021 not have pulse drive signal output, power switch pipe quits work, entire circuit is output not, stops charging; When " beginning/stop " button on the display circuit 1013 that pushes button once more; temperature sensing circuit 1026 will detect temperature once more; if temperature is lower than the protection temperature limit; battery voltage detection circuit 1033 is passed to single-chip microcomputer 1011 after detected storage battery 100 terminal voltages are changed through A/D; single-chip microcomputer 1011 compares voltage detecting value and preset value; judge the charging stage, continue charging.

A kind of intelligent high-frequency accumulator charger that the utility model provides adopts high frequency technique, in conjunction with single-chip microcomputer.Can detect automatically when it is connected with storage battery and have or not battery, judge simultaneously whether battery polar connects correct, if incorrect, then regulates, make the circuit can operate as normal, when not having battery or battery reversal connection, circuit is output not.Only just can provide correct output satisfying above two conditions and press start button.Voltage rising characteristic during according to charge in batteries, the utility model adopts " batch (-type) " battery voltage sampling, can guarantee that battery can not overcharge or be not fully filled.The utility model is energy-efficient, and safety easy to use is workable, is applicable to the storage battery of different capabilities.

Claims (7)

1. an intelligent high-frequency accumulator charger is characterized in that, comprises single chip machine controlling circuit, circuit connects the charging control circuit and the testing circuit of described single chip machine controlling circuit respectively;

Described single chip machine controlling circuit comprises single-chip microcomputer (1011), also comprises auxiliary power circuit (1012) and button display circuit (1013) that circuit respectively connects described single-chip microcomputer (1011);

Described charging control circuit comprises pulse width modulation circuit (1021), drive circuit (1022), current rectifying and wave filtering circuit (1023) and output control circuit (1024), also comprises current sampling circuit (1025);

Described pulse width modulation circuit (1021), its inlet circuit connects the output of described single-chip microcomputer (1011);

Described drive circuit (1022), its inlet circuit connects the output of described pulse width modulation circuit (1021);

Described current rectifying and wave filtering circuit (1023), its inlet circuit connects the output of described drive circuit (1022);

Described output control circuit (1024), its inlet circuit connect the output of described current rectifying and wave filtering circuit (1023) and single-chip microcomputer (1011), and its circuit of output terminal connects described pulse width modulation circuit (1021) and storage battery (100);

Described current sampling circuit (1025), its inlet circuit connects storage battery (100), and its output circuit respectively connects described pulse width modulation circuit (1021) and single-chip microcomputer (1011);

Described testing circuit comprises battery detection circuit (1031), reversal connection testing circuit (1032), battery voltage detection circuit (1033) and automatic polar circuit (1034);

The inlet circuit of described battery detection circuit (1031) connects described storage battery (100), and the circuit of output terminal of this battery detection circuit (1031) connects described single-chip microcomputer (1011);

The inlet circuit of described reversal connection testing circuit (1032) connects described storage battery (100);

The inlet circuit of described battery voltage detection circuit (1033) connects described storage battery (100), and the circuit of output terminal of this battery voltage detection circuit (1033) connects described single-chip microcomputer (1011);

The inlet circuit of described automatic polar circuit (1034) connects described single-chip microcomputer (1011), and the circuit of output terminal of this automatic polar circuit (1034) connects described storage battery (100).

2. a kind of intelligent high-frequency accumulator charger as claimed in claim 1 is characterized in that, described button display circuit (1013) comprises plurality of keys and the some display lamps that circuit connects, and indicates the operating state of whole battery charger.

3. a kind of intelligent high-frequency accumulator charger as claimed in claim 1 is characterized in that, described pulse width modulation circuit (1021) comprises pulse width modulation chip and peripheral circuit; This peripheral circuit connects described pulse width modulation chip.

4. a kind of intelligent high-frequency accumulator charger as claimed in claim 3; it is characterized in that; described pulse width modulation circuit (1021) also comprises current-limiting protection circuit, and this current-limiting protection circuit connects described current sampling circuit (1025) and drive circuit (1022).

5. a kind of intelligent high-frequency accumulator charger as claimed in claim 1 is characterized in that, described drive circuit (1022) comprises some driving transformers, drive logic and some power switch pipes of circuit connection successively.

6. a kind of intelligent high-frequency accumulator charger as claimed in claim 1 is characterized in that, described charging control circuit also comprises temperature sensing circuit (1026);

Described temperature sensing circuit (1026) connects described single-chip microcomputer (1011).

7. a kind of intelligent high-frequency accumulator charger as claimed in claim 1 is characterized in that, described charging control circuit also comprises battery discharging circuit (1027);

Described battery discharging circuit (1027) circuit respectively connects described single-chip microcomputer (1011) and storage battery (100).

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