CN204441951U - A kind of charge-discharge circuit and charger baby - Google Patents

Abstract

The utility model discloses a kind of charge-discharge circuit and charger baby, comprise charging inlet, electric discharge interface and multiple battery core, described multiple battery cores are divided into M group, each battery core often in group is in parallel, the power input pin of M road charging chip is all connected with charging inlet, and power supply output pin is corresponding with the positive pole of M group battery core respectively to be connected; M group battery core is in parallel when charging, the series connection when discharging, and the positive pole of first group of battery core connects the voltage input end of step-down chip, and the voltage output end of step-down chip connects electric discharge interface by a switching circuit; Described switching circuit when charging inlet accesses without input power by step-down chip with electric discharge orifice.Charger baby of the present utility model is by changing the annexation of battery core in charging and discharging process, thus the BOOST booster circuit can used instead in step-down chip replacement traditional circuit is to meet the conversion requirements between battery core output voltage to the required power supply of exterior terminal equipment, which thereby enhances the conversion efficiency of battery.

Description

A kind of charge-discharge circuit and charger baby

Technical field

The utility model belongs to charge-discharge circuit technical field, specifically, relates to a kind of structural design being applicable to the charge-discharge circuit of the consumer electronics products such as charger baby/portable power source.

Background technology

Along with the continuous renewal of mobile terminal product is regenerated, the flying power of battery electric quantity obtains unprecedented test, therefore a new industry---and charger baby (also can be described as portable power source) is arisen at the historic moment, and is widely applied.

Existing charger baby product, the overwhelming majority is charged to internal battery by the standard USB interface of 5V.In internal battery, be generally all provided with multiple battery core, described multiple battery cores are all connected by parallel way.Because the output voltage of each battery core is usually at about 4.2V, the external equipment (such as mobile terminal product) of power supply is needed then often to need 5V voltage, therefore, when utilizing charger baby to outside equipment charge, need built-in BOOST booster circuit in charger baby, externally export again after cell voltage being boosted to 5V.

Mainly there is tripartite's planar defect in this circuit design of existing charger baby: the first due to the conversion efficiency of BOOST booster circuit low, the loss thus causing internal battery externally to charge is large; It two is that heating is serious, and charger baby becomes hand warmer; It three is because internal battery needs High-current output, thus causes the utilance of internal battery to reduce.

Summary of the invention

The purpose of this utility model is the charge-discharge circuit providing a kind of high efficiency and high battery utilance, by multiple battery core in change circuit in the annexation of charging and discharging process, thus the BOOST booster circuit can used instead in step-down chip replacement traditional circuit is to meet the conversion requirements between battery core output voltage to the required power supply of exterior terminal equipment, which thereby enhances the conversion efficiency of battery.

For solving the problems of the technologies described above, the utility model is achieved by the following technical solutions:

A kind of charge-discharge circuit, comprise the charging inlet for receiving input power, the electric discharge interface for output current and the multiple battery cores for store electrical energy, described multiple battery cores are divided into M group, and each battery core often in group is in parallel, described M be greater than 1 positive integer; In described charge-discharge circuit, be provided with M road charging chip, its power input pin is all connected with described charging inlet, and the power supply output pin of M road charging chip is connected one to one with the positive pole of M group battery core respectively; Described M group battery core is parallel with one another when charging, mutually connect when discharging, and the positive pole of first group of battery core connects the voltage input end of a step-down chip, described step-down chip is used for the supply power voltage voltage transitions that M group battery core exports become needed for exterior terminal equipment, the electric discharge interface described in its voltage output end is connected by a switching circuit; Described switching circuit cuts off the connecting path of step-down chip and electric discharge interface when charging inlet has input power to access, the input power accessed by charging inlet is transferred to described electric discharge interface, when charging inlet accesses without input power, by the voltage output end of described step-down chip and described electric discharge orifice.

Further, in described M group battery core, the negative pole of i-th group of battery core connects the positive pole of the i-th+1 group battery core by a string parallel selecting circuit, the minus earth of last group battery core, described i=1, and 2 ..., M-1; Charging inlet described in described connection in series-parallel selection circuit connects, when described charging inlet has input power to access, the negative pole controlling i-th group of battery core is communicated with the positive pole of the i-th+1 group battery core, when described charging inlet does not have input power to access, controls the minus earth of i-th group of battery core.

As a kind of preferred circuit teaming method of described connection in series-parallel selection circuit, the utility model is provided with three N-channel MOS pipes and two P channel MOS tubes in described connection in series-parallel selection circuit, wherein, the grid of the first N-channel MOS pipe receives the input power accessed by charging inlet, the negative pole of drain electrode connection i-th group of battery core, source ground; The grid of the second N-channel MOS pipe receives the input power accessed by charging inlet, source ground, the grid of drain electrode connection the 3rd N-channel MOS pipe, and connects a DC power supply by the first current-limiting resistance; The source ground of described 3rd N-channel MOS pipe, drains corresponding with the grid of two P channel MOS tubes respectively connection; The drain electrode of the one P channel MOS tube is connected the negative pole of i-th group of battery core, source electrode connects the source electrode of the 2nd P channel MOS tube, and the drain electrode of described 3rd N-channel MOS pipe is connected by a configuration resistance, the drain electrode of described 2nd P channel MOS tube connects the positive pole of the i-th+1 group battery core.

Preferably, the resistance of described configuration resistance is greater than 47k Ω; Described DC power supply can be that the voltage exported by described battery core generates through voltage stabilizing circuit conversion.

As a kind of preferred circuit teaming method of described switching circuit, the utility model is provided with two N-channel MOS pipes and two P channel MOS tubes in described switching circuit, wherein, the grid of the 4th N-channel MOS pipe receives the input power accessed by charging inlet, source ground, the grid of drain electrode connection the 5th N-channel MOS pipe, and connect a DC power supply by the second current-limiting resistance; The source ground of described 5th N-channel MOS pipe, drains corresponding with the grid of the third and fourth P channel MOS tube respectively connection; The voltage output end of the drain electrode of the 3rd P channel MOS tube with described step-down chip is communicated with, source electrode connects the source electrode of the 4th P channel MOS tube, and the drain electrode of the 5th N-channel MOS pipe is connected by another configuration resistance, the drain electrode of the 4th P channel MOS tube is communicated with described charging inlet and electric discharge interface respectively.

Preferably, the resistance of another configuration resistance described is greater than 47k Ω; The voltage that described DC power supply also can directly be exported by described battery core generates through voltage stabilizing circuit conversion.

In order to reduce system energy consumption, the work schedule of the utility model to described step-down chip controls, and transferring to the Enable Pin of step-down chip, carrying out enable control thus to step-down chip by generating an enable signal; In the utility model, one of them of three kinds of modes below preferably adopting carries out enable control to described step-down chip:

(1) Enable Pin of described step-down chip is connected a processor, described processor detect charging inlet without input power access and electric discharge interface have terminal equipment to insert time, generate effective enable signal and export described step-down chip to, enable control is carried out to described step-down chip;

(2) Enable Pin of described step-down chip is connected a key circuit, starting key is provided with in described key circuit, described starting key is pressed by operation when needing startup charge-discharge circuit to power to the terminal equipment be plugged on electric discharge interface, generate starting-up signal and export described step-down chip to as effective enable signal, enable control is carried out to described step-down chip;

(3) Enable Pin of described step-down chip is connected an extrapolation terminal testing circuit, described extrapolation terminal testing circuit is when having detected that terminal equipment is inserted on described electric discharge interface, generate effective enable signal and export described step-down chip to, enable control is carried out to described step-down chip.

In order to reduce system energy consumption further, the work schedule of the utility model to M road charging chip controls, and the enable pin of described M road charging chip is connected an enable control circuit, and passes through the thermistor ground connection of a negative temperature coefficient; Two N-channel MOS pipes are provided with in described enable control circuit, wherein, the grid of the 6th N-channel MOS pipe receives the input power accessed by charging inlet, source ground, the grid of drain electrode connection the 7th N-channel MOS pipe, and connect DC power supply by the 3rd current-limiting resistance; The source ground of the 7th N-channel MOS pipe, drains corresponding with the enable pin of M road charging chip respectively connection.Startup optimization when only having input power to access on charging inlet by enable control circuit control M road charging chip, the input power described in reception, and charging control is carried out to M group battery core.In charging process, if the temperature of circuit system is too high, then can be dragged down the enable pin current potential of charging chip by the resistance of the thermistor reduced gradually, charging chip is closed, protection charging chip avoids it to cross cause thermal damage.

Based on the structural design of above-mentioned charge-discharge circuit, the utility model also proposed a kind of charger baby adopting described charge-discharge circuit to design, comprise processor, for receiving the charging inlet of input power, the electric discharge interface for output current and the multiple battery cores for store electrical energy, described multiple battery cores are divided into M group, each battery core often in group is in parallel, described M be greater than 1 positive integer; In described charge-discharge circuit, be provided with M road charging chip, its power input pin is all connected with described charging inlet, and the power supply output pin of M road charging chip is connected one to one with the positive pole of M group battery core respectively; Described M group battery core is parallel with one another when charging, mutually connect when discharging, and the positive pole of first group of battery core connects the voltage input end of a step-down chip, described step-down chip is used for the supply power voltage voltage transitions that M group battery core exports become needed for exterior terminal equipment, the electric discharge interface described in its voltage output end is connected by a switching circuit; Described switching circuit cuts off the connecting path of step-down chip and electric discharge interface when charging inlet has input power to access, the input power accessed by charging inlet is transferred to described electric discharge interface, when charging inlet accesses without input power, by the voltage output end of described step-down chip and described electric discharge orifice.

Preferably, described multiple battery core is divided into two groups, i.e. M=2; The standard USB interface of described charging inlet and the preferred 5V of electric discharge interface, thus while meeting the charging requirement to current most mobile terminal device, can simplify circuit structure as far as possible, reduces product cost.

Compared with prior art, advantage of the present utility model and good effect are: the utility model is by dividing into groups to the multiple battery cores in charger baby circuit, and design connection in series-parallel selection circuit and control each group of battery core charged in parallel, discharged in series, thus can while quick charge in each battery core of guarantee, utilize the discharged in series of battery core can improve the amplitude of its output voltage, make it higher than the supply power voltage needed for exterior terminal equipment, thus one, just the use of BOOST booster circuit can be saved, then adopt step-down chip to change the charging voltage generated needed for exterior terminal equipment, with overcome use BOOST booster circuit to cause battery outside to fill loss large, the defect such as to generate heat serious.Charger baby circuit of the present utility model compares traditional charger baby scheme, and battery conversion efficiency can improve 15%, and battery utilance can improve 20%, and gross efficiency can promote 35%, greatly improves the performance of charger baby.

After reading the detailed description of the utility model execution mode by reference to the accompanying drawings, other features of the present utility model and advantage will become clearly.

Accompanying drawing explanation

Fig. 1 is the charge-discharge circuit schematic diagram of a kind of embodiment of the charger baby that the utility model proposes;

Fig. 2 is the charge-discharge circuit schematic diagram of another embodiment of the charger baby that the utility model proposes.

Embodiment

Below in conjunction with accompanying drawing, embodiment of the present utility model is described in more detail.

The present embodiment is in order to solve the voltage magnitude of existing charger baby circuit due to its inner battery core output lower than the charging voltage amplitude needed for external devices, therefore need to use BOOST booster circuit to carry out boosting inverter to battery core voltage, then the problem that battery core output current is large, heating is serious, battery utilance is low is caused, propose a kind of charge-discharge circuit structural design without the need to using BOOST booster circuit can meet the external charging requirement of charger baby, to realize the significantly lifting of battery utilance.

Multiple battery core is provided with in the charge-discharge circuit of the present embodiment, the voltage of each battery core is all less than the voltage magnitude exported by the electric discharge interface requirement of charge-discharge circuit, the output voltage of such as each battery core is all at about 4.2V, and the interface that discharges then requires that output voltage is the situation of 5V.In order to be hoisted through the voltage magnitude that battery core group exports, described multiple battery cores are divided into M group by the present embodiment, and described M should get the positive integer being greater than 1.By parallel with one another for the battery core in each group, one group of battery core utilizes a charging chip to carry out charging to it and controls.Design connection in series-parallel selection circuit is connected between M group battery core, control M group battery core is in parallel when charging, the series connection when discharging, and BUCK step-down chip is set decompression transformation is carried out to the discharge voltage that series connection battery core group exports, then under the control of switching circuit, controlled hypotension chip exports supply power voltage, for the terminal equipment of outside charges or provides working power for it when only accessing without input power on charging inlet and electric discharge interface has terminal equipment to insert.

Specifically, the power input pin of M charging chip can be connected to respectively the charging inlet of charge-discharge circuit, the power supply output pin of M charging chip is connected one to one with the positive pole of M group battery core respectively.Between adjacent two groups of battery cores, separately connect a road connection in series-parallel selection circuit, such as, the negative pole of i-th group of battery core is connected to the positive pole of the i-th+1 group battery core by a string parallel selecting circuit, the negative pole of last group battery core then can direct ground connection, described i=1,2 ..., M-1.Like this, when charge-discharge circuit is operated in self-charging process, receives outside input power by charging inlet, and transfer to a described M charging chip, connection in series-parallel selection circuit and switching circuit respectively.Described connection in series-parallel selection circuit is after receiving input power, control the minus earth of connected i-th group of battery core, thus make adjacent two groups of battery cores (i.e. i-th group of battery core and the i-th+1 group battery core) in parallel, input power exports charging current to M group battery core correspondingly via M charging chip, to the battery core synchronous charging in parallel of each in M group battery core, to accelerate the charging rate of battery core.In the process of battery core group charging, the switching circuit interface that will discharge because receiving input power is communicated with charging inlet, and the input power utilizing charging inlet to access is directly the power terminal equipment of outside.Otherwise, when charge-discharge circuit is operated in discharge process, access owing to charging inlet there is no input power, therefore connection in series-parallel selection circuit changes its circuit connected state, connected two adjacent groups battery core (such as i-th group of battery core and the i-th+1 group battery core) is connected, the voltage magnitude exported by battery core group is made to reach 4.2*M volt, higher than the supply power voltage needed for exterior terminal equipment.Start step-down chip, after carrying out decompression transformation to the voltage of series connection battery core group output, generate the supply power voltage needed for exterior terminal equipment, transferring to described electric discharge interface through switching circuit, is the power terminal equipment of outside.Described switching circuit is when accessing without input power, and by the voltage output end of step-down chip and described electric discharge orifice, switching to battery core group is that exterior terminal equipment is powered.

Below for charger baby, the concrete assembling structure of the charge-discharge circuit that the present embodiment proposes and operation principle thereof are described in detail.

Because the battery core voltage in charger baby is generally 4.2V, and connect the charging voltage needed for terminal equipment of charger baby or supply power voltage is generally 5V, for the consideration simplifying circuit structure, reduce costs, for for the charge-discharge circuit in charger baby, preferably the battery core in charger baby is divided into two groups, i.e. M=2.In charger baby, built-in N(N is even number) individual battery core, described N number of battery core is divided into two groups, and N/2 battery core often in group is parallel with one another, respectively called after battery core group A and battery core group B, as shown in Figure 1.

For two groups of battery cores, two charging chips U1, U2 are set, the power input pin VIN of two charging chips U1, U2 is connected to respectively the charging inlet VCHG_5V of charger baby, described charging inlet VCHG_5V preferably adopts the standard USB interface of 5V, receives outside 5V input power.The power supply output pin OUT of charging chip U1, U2 is connected one to one with the positive pole BAT+_A of battery core group A and the positive pole BAT+_B of battery core group B respectively, utilizes two charging chips U1, U2 to carry out Charge Management separately to two groups of battery cores.

In order to effective control system energy consumption, the present embodiment designs the enable pin TS that enable control circuit connects charging chip U1, U2, carries out enable control to two charging chips U1, U2.Two N-channel MOS pipes Q1, Q11 are provided with in the enable control circuit of the present embodiment, wherein, N-channel MOS pipe Q1(the 6th N-channel MOS pipe) grid connected by the bleeder circuit that be made up of resistance R1, R36 described in charging inlet VCHG_5V, receive the input power of outside; The source ground of N-channel MOS pipe Q1, drain electrode connects N-channel MOS pipe Q11(the 7th N-channel MOS pipe) grid, and by current-limiting resistance R3(the 3rd current-limiting resistance) connect DC power supply VLDO.It is a road power supply that processor MCU is powered that described DC power supply VLDO can adopt in charger baby circuit, such as, linear voltage regulator LDO is set in charger baby circuit, the input of LDO is connected to the positive pole BAT+_A of battery core group A, after voltage stabilizing conversion process is carried out to the voltage on BAT+_A, operating voltage needed for generating process device MCU, be generally the direct voltage of 3.3V, on the one hand for processor MCU is powered, on the other hand as DC power supply VLDO, transfer to described enable control circuit, connection in series-parallel selection circuit and switching circuit.By the source ground of described N-channel MOS pipe Q11, the enable pin TS of drain electrode connection two charging chips U1, U2.The enable pin TS high level of described charging chip U1, U2 is effective, and pin inner portions is pulled to high potential.When charging inlet VCHG_5V does not have input power to access, metal-oxide-semiconductor Q1 ends, DC power supply VLDO acts on the grid of metal-oxide-semiconductor Q11 by current-limiting resistance R3, control metal-oxide-semiconductor Q11 saturation conduction, drag down the current potential of the enable pin TS of charging chip U1, U2, control charging chip U1, U2 out of service.When charging inlet VCHG_5V has input power to access, metal-oxide-semiconductor Q1 saturation conduction, drag down the grid potential of metal-oxide-semiconductor Q11, control metal-oxide-semiconductor Q11 cut-off, now the current potential of the enable pin TS of charging chip U1, U2 is high, the enable operation of charging chip U1, U2, utilizes the input power of access to charge for battery core group A and battery core group B.

In order to carry out overtemperature protection to charging chip U1, U2, by the enable pin TS of two charging chips U1, U2 by thermistor Therm ground connection.In the present embodiment, described thermistor Therm selects the thermistor of negative temperature coefficient, along with its resistance of rising gradually of system temperature reduces gradually.The model of thermistor Therm is reasonably selected according to the highest safe working temperature of charging chip U1, U2; when system temperature is too high; the resistance of thermistor Therm is down to lower value; drag down the current potential of the enable pin TS of charging chip U1, U2; control charging chip U1, U2 out of service, realize overtemperature protection.

In order to accelerate the charging rate of N number of battery core, in the process that the present embodiment charges in charger baby self, controlling battery core group A and battery core group B by connection in series-parallel selection circuit in parallel, making N number of battery core synchronous charging in parallel.The present embodiment is provided with three N-channel MOS pipes and two P channel MOS tubes in described connection in series-parallel selection circuit, as shown in Figure 1.The grid of the first N-channel MOS pipe Q5 is connected to described charging inlet VCHG_5V by the bleeder circuit be made up of resistance R5, R88, receives the input power accessed by charging inlet VCHG_5V, drain electrode connects the negative pole BAT-_A of battery core group A, source ground.The grid of the second N-channel MOS pipe Q3 is connected to charging inlet VCHG_5V, receive the input power accessed by charging inlet VCHG_5V, source ground, the grid of drain electrode connection the 3rd N-channel MOS pipe Q7, and be connected to described DC power supply VLDO by the first current-limiting resistance R4.By the source ground of the 3rd N-channel MOS pipe Q7, drain corresponding with the grid of two P channel MOS tubes Q4, Q9 respectively connection.The drain electrode of the one P channel MOS tube Q4 is connected to the negative pole BAT-_A of battery core group A, source electrode connects the source electrode of the 2nd P channel MOS tube Q9, and the drain electrode of the 2nd P channel MOS tube Q9 connects the positive pole BAT+_B of battery core group B.The source electrode of two P channel MOS tubes Q4, Q9 is connected to the drain electrode of the 3rd N-channel MOS pipe Q7 by configuration resistance R6, when the 3rd N-channel MOS pipe Q7 conducting, make the source electrode of first and second P channel MOS tube Q4, Q9 and grid pressure reduction be greater than its cut-in voltage by configuration resistance R6, then make two P channel MOS tube Q4, Q9 saturation conductions.

When charging inlet VCHG_5V has input power to access, metal-oxide-semiconductor Q5 saturation conduction, makes the negative pole BAT-_A of battery core group A by the drain electrode of metal-oxide-semiconductor Q5 and source ground, the direct ground connection of negative pole BAT-_B of battery core group B.Now, two battery core group A, B are in parallel, utilize two charging chips U1, U2 to battery core synchronous charging in parallel.

When charging inlet VCHG_5V does not have input power to access, metal-oxide-semiconductor Q5, Q3 end, DC power supply VLDO acts on the grid of metal-oxide-semiconductor Q7 by current-limiting resistance R4, control metal-oxide-semiconductor Q7 saturation conduction, then the grid potential of two P channel MOS tubes Q4, Q9 is dragged down, when metal-oxide-semiconductor Q7 conducting, battery core group B output current by the drain electrode of the 2nd P channel MOS tube Q9 through body diode to its source electrode, then through configuration resistance R6 and the 3rd N-channel MOS pipe Q7 to.Now, due to the existence of configuration resistance R6, make the gate-source voltage of a P channel MOS tube Q4 be greater than its cut-in voltage, thus meet the unlocking condition of metal-oxide-semiconductor Q4, make metal-oxide-semiconductor Q4 saturation conduction.Thus, the negative pole BAT-_A of battery core group A is communicated with the positive pole BAT+_B of battery core group B by P channel MOS tube Q4, Q9 of two saturation conductions, achieves the discharged in series of two battery core group A, B.

In the present embodiment, the resistance of described configuration resistance R6, more preferably greater than 47k Ω, to ensure that the electric current overwhelming majority exported by the negative pole BAT-_A of battery core group A flow into the positive pole BAT+_B of battery core group B, and then reduces the power consumption produced over resistor r 6.

In the present embodiment, two P channel MOS tubes Q4, Q9 also can adopt a CJL2623 integrated chip U5 to replace, and realize controlling the connection in series-parallel of two groups of battery cores, shown in Figure 2.

The positive pole BAT+_A of battery core group A is connected to the voltage input end VIN of step-down chip U3, as shown in Figure 1, the inductance L 2 connecting valve circuit of voltage output end SW by connecting of step-down chip U3, and under the control of switching circuit, be communicated with electric discharge interface 5V_OUTPUT.In the present embodiment, described electric discharge interface 5V_OUTPUT preferably adopts the standard USB interface of 5V, is connected with current most mobile terminal devices to facilitate, and is its charging.

The switching circuit of the present embodiment adopts two N-channel MOS pipes and two P channel MOS tubes to be formed by connecting, as shown in Figure 1.Wherein, the grid of the 4th N-channel MOS pipe Q2 is connected charging inlet VCHG_5V, receives the input power accessed by charging inlet VCHG_5V, source ground, the grid of drain electrode connection the 5th N-channel MOS pipe Q6, and connect DC power supply VLDO by the second current-limiting resistance R2.By the source ground of described 5th N-channel MOS pipe Q6, drain corresponding with the grid of third and fourth P channel MOS tube Q8, Q10 respectively connection.The Q8 of the 3rd P channel MOS tube drain electrode is communicated with the voltage output end SW of step-down chip by described inductance L 2, source electrode connects the source electrode of the 4th P channel MOS tube Q10, the charging inlet described in drain electrode connection of the 4th P channel MOS tube Q10, and connect electric discharge interface 5V_OUTPUT by resistance R87.The source electrode of two P channel MOS tubes Q8, Q10 is connected to the drain electrode of the 5th N-channel MOS pipe Q6 by the configuration resistance R7 that resistance is greater than 47k Ω, when the 5th N-channel MOS pipe Q6 conducting, make the source electrode of third and fourth P channel MOS tube Q8, Q10 and grid pressure reduction be greater than its cut-in voltage by configuration resistance R7, then make two P channel MOS tube Q8, Q10 saturation conductions.

When charging inlet VCHG_5V has input power to access, 4th N-channel MOS pipe Q2 saturation conduction, drag down the grid potential of the 5th N-channel MOS pipe Q6, control the 5th N-channel MOS pipe Q6 and two P channel MOS tube Q8, Q10 cut-off, cut off the current path of step-down chip U3 and electric discharge interface 5V_OUTPUT.Now, the input power accessed by charging inlet VCHG_5V directly transfers to electric discharge interface 5V_OUTPUT via current-limiting resistance R87, if electric discharge interface 5V_OUTPUT is circumscribed with terminal equipment, then can directly utilize input power for power terminal equipment.

When charging inlet VCHG_5V does not have input power to access, 4th N-channel MOS pipe Q2 ends, DC power supply VLDO acts on the grid of the 5th N-channel MOS pipe Q6 through current-limiting resistance R2, control the 5th N-channel MOS pipe Q6 saturation conduction, then the grid potential of two P channel MOS tubes Q8, Q10 is dragged down, when metal-oxide-semiconductor Q6 conducting, the electric current exported by step-down chip U3 by the drain electrode of the 3rd P channel MOS tube Q8 through body diode to its source electrode, then through the drain electrode of configuration resistance R7 and the 5th N-channel MOS pipe Q6 and source electrode to.Now, due to the existence of configuration resistance R7, make the source-gate voltage of the 4th P channel MOS tube Q10 be greater than its cut-in voltage, thus meet the unlocking condition of P channel MOS tube Q10, make metal-oxide-semiconductor Q10 saturation conduction.After two P channel MOS tube Q8, Q10 saturation conductions, the voltage output end SW of step-down chip U3 is communicated with electric discharge interface 5V_OUTPUT, then make the direct voltage of the about 8.4V exported by battery core group A, the B of series connection via the 5V DC power supply generated after electric capacity C17 filtering and step-down chip U3 decompression transformation, exported by electric discharge interface 5V_OUTPUT, charge for the terminal equipment be external on electric discharge interface 5V_OUTPUT or provide working power for described terminal equipment.

In like manner, described two P channel MOS tubes Q8, Q10 also can adopt a CJL2623 integrated chip U4 to replace, shown in Figure 2, equally can realizing circuit design.

In order to reduce system energy consumption further, the operating state of the present embodiment to step-down chip U3 carries out enable control, to avoid producing unnecessary extra power consumption on step-down chip U3.In order to realize the enable control to step-down chip U3, the present embodiment proposes following three kinds of preferred design, generates enable signal BUCK_EN, transfers to the Enable Pin EN of step-down chip U3, the work schedule of controlled hypotension chip U3.

The first design is, utilizes the enable signal BUCK_EN described in processor MCU generation in charger baby.Specifically, the inserting state of charging inlet VCHG_5V and electric discharge interface 5V_OUTPUT can be detected by processor MCU.When processor MCU to detect on charging inlet VCHG_5V without input power access and electric discharge interface 5V_OUTPUT has terminal equipment to insert, generate the enable signal BUCK_EN of effective enable signal BUCK_EN(such as high level) export the Enable Pin EN of step-down chip U3 to, controlled hypotension chip U3 startup optimization, the voltage transitions that battery core group A, B series connection exports is become 5V voltage, transfer to electric discharge interface 5V_OUTPUT, for the terminal equipment of outside charges.Otherwise, when processor MCU detect charging inlet VCHG_5V has input power access or electric discharge interface 5V_OUTPUT upper endless equipment insertion time, putting enable signal BUCK_EN is disarmed state, such as putting enable signal BUCK_EN is low level, then controlled hypotension chip U3 is out of service, reduces energy consumption.

The second design is, utilizes the enable signal BUCK_EN needed for starting key generation in charger baby.When using charger baby to charge to external terminal equipment, usually needing the starting key clicked in charger baby, charger baby could be controlled and externally discharge.The present embodiment utilizes the enable signal BUCK_EN needed for trigger action compatibility generation step-down chip U3 of starting key in charger baby.Specifically, when needing startup charger baby to charge to external interrupting device, press starting key, the key circuit now connecting starting key generates corresponding push button signalling, i.e. starting-up signal, transfers to processor MCU.Processor MCU is when detecting that starting key is pressed, run according to existing control mode control system circuit start on the one hand, export effective enable signal BUCK_EN on the other hand, transfer to the Enable Pin EN of step-down chip U3, the enable operation of controlled hypotension chip U3.Otherwise when processor MCU detects that terminal equipment is extracted or starting key again presses, putting enable signal BUCK_EN is disarmed state, and U3 is out of service for controlled hypotension chip, no longer externally charges.

The third design is, utilizes the enable signal BUCK_EN needed for the generation of extrapolation terminal testing circuit in charger baby.Namely, whether have terminal equipment insert, if there is terminal equipment to insert, then generate effective enable signal BUCK_EN if being detected on electric discharge interface 5V_OUTPUT by extrapolation terminal testing circuit, transfer to the Enable Pin EN of step-down chip U3, the enable operation of controlled hypotension chip U3.Otherwise putting enable signal BUCK_EN is disarmed state, and U3 is out of service for controlled hypotension chip, reduce energy consumption.

The present embodiment adopts two charging chips to carry out charging respectively to two groups of battery cores and controls; each group battery core is owing to starting just to bind together; therefore cell voltage is consistent; even if two groups of battery cores are after discharged in series; the voltage of two groups of battery cores is different, also there will not be the high-tension battery core when charged in parallel to the problem of the battery core perfusion of low-voltage, to protect the charging safety of battery thus; do not need again at battery core two ends design PCM battery protecting circuit, thus simplify the circuit design of charger baby.

The present embodiment only elaborates for two groups of battery core group A, B, for needing, N number of battery core is divided into the situation that more groups could meet the requirement of exterior terminal equipment charge, only need carry out multichannel and expand described connection in series-parallel selection circuit, charging chip, the present embodiment no longer launches explanation at this.

Certainly; above-mentioned explanation is not to restriction of the present utility model; the utility model is also not limited in above-mentioned citing, the change that those skilled in the art make in essential scope of the present utility model, remodeling, interpolation or replacement, also should belong to protection range of the present utility model.

Claims (10)

1. a charge-discharge circuit, comprise the charging inlet for receiving input power, the electric discharge interface for output current and the multiple battery cores for store electrical energy, it is characterized in that: described multiple battery cores are divided into M group, each battery core often in group is in parallel, described M be greater than 1 positive integer; In described charge-discharge circuit, be provided with M road charging chip, its power input pin is all connected with described charging inlet, and the power supply output pin of M road charging chip is connected one to one with the positive pole of M group battery core respectively; Described M group battery core is parallel with one another when charging, mutually connect when discharging, and the positive pole of first group of battery core connects the voltage input end of a step-down chip, described step-down chip is used for the supply power voltage voltage transitions that M group battery core exports become needed for exterior terminal equipment, the electric discharge interface described in its voltage output end is connected by a switching circuit; Described switching circuit cuts off the connecting path of step-down chip and electric discharge interface when charging inlet has input power to access, the input power accessed by charging inlet is transferred to described electric discharge interface, when charging inlet accesses without input power, by the voltage output end of described step-down chip and described electric discharge orifice.

2. charge-discharge circuit according to claim 1, is characterized in that: in described M group battery core, and the negative pole of i-th group of battery core connects the positive pole of the i-th+1 group battery core by a string parallel selecting circuit, the minus earth of last group battery core, described i=1,2,, M-1; Charging inlet described in described connection in series-parallel selection circuit connects, when described charging inlet has input power to access, the negative pole controlling i-th group of battery core is communicated with the positive pole of the i-th+1 group battery core, when described charging inlet does not have input power to access, controls the minus earth of i-th group of battery core.

3. charge-discharge circuit according to claim 2, it is characterized in that: in described connection in series-parallel selection circuit, be provided with three N-channel MOS pipes and two P channel MOS tubes, wherein, the grid of the first N-channel MOS pipe receives the input power accessed by charging inlet, the negative pole of drain electrode connection i-th group of battery core, source ground; The grid of the second N-channel MOS pipe receives the input power accessed by charging inlet, source ground, the grid of drain electrode connection the 3rd N-channel MOS pipe, and connects a DC power supply by the first current-limiting resistance; The source ground of described 3rd N-channel MOS pipe, drains corresponding with the grid of two P channel MOS tubes respectively connection; The drain electrode of the one P channel MOS tube is connected the negative pole of i-th group of battery core, source electrode connects the source electrode of the 2nd P channel MOS tube, and connects the drain electrode of the 3rd N-channel MOS pipe by a configuration resistance, and the drain electrode of described 2nd P channel MOS tube connects the positive pole of the i-th+1 group battery core.

4. charge-discharge circuit according to claim 3, is characterized in that: the resistance of described configuration resistance is greater than 47k Ω; Described DC power supply is that the voltage exported by described battery core generates through voltage stabilizing circuit conversion.

5. charge-discharge circuit according to claim 1, it is characterized in that: in described switching circuit, be provided with two N-channel MOS pipes and two P channel MOS tubes, wherein, the grid of the 4th N-channel MOS pipe receives the input power accessed by charging inlet, source ground, the grid of drain electrode connection the 5th N-channel MOS pipe, and connect a DC power supply by the second current-limiting resistance; The source ground of described 5th N-channel MOS pipe, drains corresponding with the grid of the third and fourth P channel MOS tube respectively connection; Be communicated with by the voltage output end of the drain electrode of the 3rd P channel MOS tube with described step-down chip, source electrode connects the source electrode of the 4th P channel MOS tube, and connects the drain electrode of the 5th N-channel MOS pipe by another configuration resistance; The drain electrode of the 4th P channel MOS tube is communicated with described charging inlet and electric discharge interface respectively.

6. charge-discharge circuit according to claim 5, is characterized in that: the resistance of another configuration resistance described is greater than 47k Ω; Described DC power supply is that the voltage exported by described battery core generates through voltage stabilizing circuit conversion.

7. charge-discharge circuit according to any one of claim 1 to 6, is characterized in that:

The Enable Pin of described step-down chip connects a processor, described processor detect charging inlet without input power access and electric discharge interface have terminal equipment to insert time, generate effective enable signal and export described step-down chip to; Or

The Enable Pin of described step-down chip connects a key circuit, starting key is provided with in described key circuit, described starting key is pressed by operation when needing startup charge-discharge circuit to power to the terminal equipment be plugged on electric discharge interface, generates starting-up signal and also exports described step-down chip to as effective enable signal; Or

The Enable Pin of described step-down chip connects an extrapolation terminal testing circuit, and described extrapolation terminal testing circuit, when having detected that terminal equipment is inserted on described electric discharge interface, generates effective enable signal and exports described step-down chip to.

8. charge-discharge circuit according to any one of claim 1 to 6, is characterized in that: the enable pin of described M road charging chip connects an enable control circuit, and passes through the thermistor ground connection of a negative temperature coefficient; Two N-channel MOS pipes are provided with in described enable control circuit, wherein, the grid of the 6th N-channel MOS pipe receives the input power accessed by charging inlet, source ground, the grid of drain electrode connection the 7th N-channel MOS pipe, and connect DC power supply by the 3rd current-limiting resistance; The source ground of the 7th N-channel MOS pipe, drains corresponding with the enable pin of M road charging chip respectively connection.

9. a charger baby, is provided with processor, it is characterized in that: be also provided with the charge-discharge circuit any one of claim 1 to 8 as described in claim.

10. charger baby according to claim 9, is characterized in that: described multiple battery core is divided into two groups; Described charging inlet and electric discharge interface are the standard USB interface of 5V.