CN202210690U - Negative temperature coefficient adjustable resistance type constant voltage charging circuit - Google Patents

Negative temperature coefficient adjustable resistance type constant voltage charging circuit Download PDF

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Publication number
CN202210690U
CN202210690U CN2011203075054U CN201120307505U CN202210690U CN 202210690 U CN202210690 U CN 202210690U CN 2011203075054 U CN2011203075054 U CN 2011203075054U CN 201120307505 U CN201120307505 U CN 201120307505U CN 202210690 U CN202210690 U CN 202210690U
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charging
constant voltage
voltage
storage battery
circuit
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CN2011203075054U
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田畴
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Guangdong Kennede Electronics Manufacturing Co Ltd
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Guangdong Kennede Electronics Manufacturing Co Ltd
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Abstract

Disclosed is a negative temperature coefficient adjustable resistance type constant voltage charging circuit. The constant voltage charging circuit of the utility model comprises a stabilized power supply and a circuit composed of a resistor, a triode, a Zener diode, and a ceramic capacitor. The constant voltage charging circuit of the utility model constantly changes the charging current that the storage battery can accept at different states by changing the internal resistance of the circuit in a gap type constant voltage and current manner and makes the charging curve of the constant voltage charging circuit infinitely approach the optimum charging curve of the storage battery. The intelligent type control system of the utility model can effectively solve a plurality of problems affecting the service lifetime of a battery amid the process of charging a storage battery with the constant voltage charging technology, such as failure to adjust the charging current, heavy charging current and high temperature at initial charging stage, easy shedding of the active substances, complicated control circuit, low cost performance, heavy charging current at the later charging stage under high temperature environment, and the like, thereby providing a best charging scheme for the storage battery.

Description

A kind of negative temperature coefficient variableimpedance formula constant voltage charging circuit
Technical field
The utility model relates to a kind of charging circuit of storage battery, especially a kind of negative temperature coefficient variableimpedance formula constant voltage charging circuit.
Background technology
In our daily life, storage battery is widely used, and because the particularity of storage battery, charging modes has very big influence to its life-span and performance.
One, our the charge in batteries theoretical foundation used always is:
1, the rated voltage of lead-acid battery monomer is 2V; The positive polarity material is a brown lead oxide; The negative polarity material is the pure lead of sponginess; Electrolyte is dilute sulfuric acid; Material on the positive and negative pole plate of discharge end of a period is lead sulfate, and typical chemical equation is:
Figure 229194DEST_PATH_IMAGE001
For making charging current Ic flow through storage battery, the voltage U c of charge power supply must overcome the electromotive force E of storage battery and the pressure drop IcR that internal resistance R produces, that is:
Uc=E+IcR
2, U.S. scientist Maas the sixties in 20th century pairs of openings storage battery charging process done a large amount of experiments and systematic research, having proposed with minimum gas efficiency is that the storage battery optimal charge of prerequisite is accepted curve, as shown in Figure 1.The exponential relationship that electric current I and charging interval t are accepted in its charging is:
I=I 0e -at
In the following formula: I 0--storage battery can receptible charging current maximum when t=0.
The a--maximum charging current is with the variation coefficient in charging interval, i.e. ratio is accepted in charging.
Two, constant voltage charge technology
Voltage remains constant technology and is the constant voltage charge technology in the process of battery charge, and figure is as shown in Figure 2 for its charging characteristic curve, and its advantage has: at the charging initial stage; Charging current is bigger; Charging rate is fast, and the whole charging interval is very fast, and its charging current curve is near idealized characteristic.Its shortcoming has: 1, voltage constant, and charging current can not be regulated; 2, the charging initial stage, battery polarization is comparatively serious, and temperature is high, and bubble is many; 3, charging later stage electric current is less, and the active material of pole plate depths can not fully recover, so can not guarantee the thorough full charge of battery; 4, under hot environment, battery is because of the variation of its internal resistance, and the later stage charging current that causes charging is high, and this situation has departed from the storage battery optimal charge and accepted curve, and battery electricity useful life in serious threat.
Three, gap time variant voltage--constant voltage charge technology
The gap time variant voltage--the constant voltage charge performance diagram is as shown in Figure 3.In each constant voltage charge stage, charging current descends according to index law, makes whole charging curve meet the optimal charge curve more.This charging technique has advantages such as the charging interval is short, and efficient is high, and the battery capacity recovery is thorough, but its shortcoming has: 1, control circuit is complicated, price is high; 2, charging current is big, temperature is high; 3, be prone to produce the active material obscission; 4, charge shortens the useful life of battery often.
The utility model content
In order to overcome the deficiency of above technology; The purpose of the utility model is to provide a kind of negative temperature coefficient variableimpedance formula constant voltage charge technology; And it is applied in the emergency light power supply--in the charging lead-acid cells field; With a kind of comparatively succinct technology, utilize the negative temperature coefficient feature of charging circuit itself, change the circuit internal resistance and solve lead-acid battery and under high ambient temperature, diminish and cause the problem that overvoltage protection voltage raises by its internal resistance.
The technical scheme that the utility model is taked is:
A kind of negative temperature coefficient variableimpedance formula constant voltage charging circuit; Comprise that output voltage is higher than the stabilized voltage power supply of battery tension; The positive pole of the output of said stabilized voltage power supply is connected with base stage with the collector electrode of NPN type triode respectively with second resistance through first resistance; The emitter of said triode directly is connected with the positive pole of storage battery; Between the base stage of said triode and emitter, be parallel with ceramic disc capacitor; The base stage of said triode also is connected with the anode of negative temperature coefficient diode, and the negative electrode of said negative temperature coefficient diode is connected with the negative electrode of voltage stabilizing didoe, and the negative pole of the anode of said voltage stabilizing didoe and the negative pole of storage battery and said output end of stabilized voltage supply links together.
As a kind of improvement of above technical scheme, said stabilized voltage power supply can adopt linear transformer or Switching Power Supply.
The beneficial effect of the utility model is:
The charging circuit that the utility model proposed is with the mode of clearance-type constant pressure and flow; Through changing the circuit internal resistance; Constantly adjust storage battery its receptible charging current under different state, at the charging initial stage, charging current is adjusted to the receptible maximum charging current of battery; And remain unchanged, thereby shorten charging interval of battery to greatest extent; Under charging later stage and hot conditions; Charging current is reduced to the receptible maximum charging current of battery institute this moment gradually and finally ends, and this intelligent controlling system effectively solves constant voltage charge technology and gap time variant voltage---charging current that the constant voltage charge technology produces in to battery charging process can not transfer, charge the initial stage charging current big and temperature is high, be prone to produce be prone to produce the active material obscission, control circuit is complicated, cost performance is low and hot environment under charging later stage charging current is high etc. influences the problem that battery recycles the life-span.The utility model is the charging scheme that storage battery provides a kind of the best, has infinitely the characteristic near the optimal charge curve of storage battery.
Description of drawings
Below in conjunction with accompanying drawing and embodiment the utility model is described further.
Fig. 1 is to be that the storage battery optimal charge of prerequisite is accepted curve chart with minimum gas efficiency;
Fig. 2 is the charging characteristic curve figure of constant voltage charge technology;
Fig. 3 is the gap time variant voltage--the constant voltage charge performance diagram;
Fig. 4 is the circuit diagram of the utility model.
Embodiment
With reference to Fig. 4, the utility model provides a kind of negative temperature coefficient variableimpedance formula constant voltage charging circuit, it is that circuit provides a metastable VCC voltage through linear transformer or Switching Power Supply at first, this voltage will be higher than the voltage of storage battery.
The VCC positive source that is provided is connected to two resistance (first resistance R 1 and second resistance R 2); The collector electrode of another termination NPN triode Q1 of R1 wherein; The base stage of another termination NPN triode Q1 of R2; The emitter of NPN triode Q1 directly is connected with the positive pole of battery, and ceramic disc capacitor C1 is across between the base stage and emitter of NPN triode Q1, and the anode of negative temperature coefficient diode D1 connects the base stage of NPN triode Q1; Its negative electrode links to each other with the negative electrode of voltage stabilizing didoe Z1, and the anode of voltage stabilizing didoe Z1 and the negative pole of battery and stabilized voltage power supply VCC negative pole connect together.
Provide when being higher than cell voltage at VCC, NPN triode Q1 provides the electric current of its conducting through second resistance R 2, and size through adjustment R1, R2 resistance and the voltage stabilizing value of voltage stabilizing didoe Z1 change the operating state of NPN triode Q1; As the pressure drop at first resistance R, 1 two ends pressure drop, i.e. U1 greater than resistance R 2 two ends>U2, when diode Z1 does not also puncture conducting; NPN triode Q1 gets into saturated, and this moment, the circuital current direction was: the NPN triode Q1 base current that VCC provides is through the base stage of second resistance R, 2 inflow NPN triode Q1, NPN triode Q1 conducting; Produce collector current; Direction is that VCC flows through the collector electrode that first resistance R 1 flows into NPN triode Q1, and base stage and the collector electrode of NPN triode Q1 converge together, from the emitter outflow of NPN triode Q1; Flow into the positive pole of storage battery again, to charge in batteries.The battery charge of this moment can be adjusted to the receptible maximum charging current of battery, and this maximum charging current remains unchanged at the charging initial stage, thereby shortens the charging interval of battery to greatest extent.
Come the electric weight of reaction cell to lead-acid battery with the height of cell voltage, in charging process, storage battery is stored electric weight gradually, and cell voltage raises gradually.The charging later stage; Cell voltage is raising; The emitter voltage that is NPN triode Q1 is raising, and causes the base stage of NPN triode Q1 and emitter voltage drop to descend, and the base current of NPN triode Q1 reduces; NPN triode Q1 withdraws from saturation condition gradually and gets into magnifying state, and NPN triode Q1 collector current is along with the electric current of base stage reduces and reduces.Because reducing of load current; The VCC output voltage of linear transformer or Switching Power Supply rises, and causes the base voltage of NPN triode Q1 to increase, when the base voltage of NPN triode Q1 reaches the conducting voltage sum of negative temperature coefficient diode D1 and voltage stabilizing didoe Z1; This branch road conducting; And discharge the base current that offers NPN triode Q1 by VCC, cause NPN triode Q1 to end charging termination.This process cell voltage remains unchanged basically, and charging current reduces gradually, the charging current that makes this stage reasonably is set is the receptible maximum charging current of battery this moment.
Under hot environment, owing to reducing of accumulator internal resistance, making has bigger charging current under identical VCC voltage.Under common constant voltage charge technology, owing to reducing of the internal resistance of cell, cell voltage is lower than the cell voltage under the normal temperature condition under the equal electric weight; This causes battery to be in the large current charge state for a long time; Internal temperature of battery raises, and causes that battery quickens water decomposition, the dry inefficacy; Even cause battery to leak acid, seriously shorten the useful life of battery.Negative temperature coefficient variableimpedance formula constant voltage charge technology can solve this type of problem fully, and process is following: in the charging later stage, cell voltage raises; The emitter voltage of NPN triode Q1 is raising, and the base stage of NPN triode Q1 and emitter voltage drop descend, and the base current of NPN triode Q1 reduces; NPN triode Q1 withdraws from saturation condition gradually and gets into magnifying state, and owing to reducing of load current, the VCC output voltage of linear transformer or Switching Power Supply rises; Cause the base voltage of NPN triode Q1 to increase; Because the rising of ambient temperature, the conduction voltage drop of negative temperature coefficient diode D1 and voltage stabilizing didoe Z1 has all descended, and makes that littler NPN triode Q1 base voltage all can make this branch road conducting; NPN triode Q1 is ended; Make battery break away from charging later stage large current charge state, and then the protection battery, prolong battery useful life.
Reasonably select voltage stabilizing value and the negative temperature coefficient diode D1 of voltage stabilizing didoe Z1, the just right voltage that the battery overvoltage protection is set is that the essence of this circuit will belong to.
The core circuit of the negative temperature coefficient variableimpedance formula constant voltage charge technology that the utility model proposed is with the mode of clearance-type constant pressure and flow; Through changing the circuit internal resistance; Continuous adjustment storage battery its receptible charging current under different state, this intelligent controlling system effectively solves constant voltage charge technology and gap time variant voltage---charging current that the constant voltage charge technology produces in to battery charging process can not transfer, charge the initial stage charging current big and temperature is high, be prone to produce be prone to produce the active material obscission, control circuit is complicated, cost performance is low and hot environment under charging later stage charging current remain high etc. and to influence the problem that battery recycles the life-span.The utility model is the charging scheme that storage battery provides a kind of the best, has infinitely the characteristic near the optimal charge curve of storage battery.
The above be the utility model preferred embodiment, it does not constitute the restriction to the utility model protection range, so long as realize that with essentially identical means the purpose of the utility model all should belong to the protection range of the utility model.

Claims (2)

1. negative temperature coefficient variableimpedance formula constant voltage charging circuit; Comprise that output voltage is higher than the stabilized voltage power supply of battery tension; It is characterized in that: the positive pole of the output of said stabilized voltage power supply is connected with base stage with the collector electrode of NPN type triode (Q1) respectively with second resistance (R2) through first resistance (R1); The emitter of said triode (Q1) directly is connected with the positive pole of storage battery; Between the base stage of said triode (Q1) and emitter, be parallel with ceramic disc capacitor (C1); The base stage of said triode (Q1) also is connected with the anode of negative temperature coefficient diode (D1), and the negative electrode of said negative temperature coefficient diode (D1) is connected with the negative electrode of voltage stabilizing didoe (Z1), and the anode of said voltage stabilizing didoe (Z1) and the negative pole of storage battery and the negative pole of said output end of stabilized voltage supply link together.
2. a kind of negative temperature coefficient variableimpedance formula constant voltage charging circuit according to claim 1, it is characterized in that: said stabilized voltage power supply can adopt linear transformer or Switching Power Supply.
CN2011203075054U 2011-08-23 2011-08-23 Negative temperature coefficient adjustable resistance type constant voltage charging circuit Expired - Fee Related CN202210690U (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104600796A (en) * 2014-12-30 2015-05-06 惠州Tcl移动通信有限公司 Quickly-charger mobile terminal, method and system

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104600796A (en) * 2014-12-30 2015-05-06 惠州Tcl移动通信有限公司 Quickly-charger mobile terminal, method and system
CN104600796B (en) * 2014-12-30 2019-09-20 惠州Tcl移动通信有限公司 The mobile terminal and method of quick charge, system

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Address after: 529000 Guangdong city of Jiangmen Province Jin Tong Road Tangxia town Pengjiang District No. 21

Patentee after: Guangdong Kennede Electronics Co., Ltd.

Address before: 529000 Guangdong city of Jiangmen Province High Street No. 22

Patentee before: Guangdong Kennede Electronics Co., Ltd.

CP02 Change in the address of a patent holder
CF01 Termination of patent right due to non-payment of annual fee

Granted publication date: 20120502

Termination date: 20180823

CF01 Termination of patent right due to non-payment of annual fee