CN201181853Y - Solar alkaline zinc-manganese dry cell charger and its mobile phone charger - Google Patents

Abstract

The utility model relates to a solar alkaline zinc-manganese dioxide cell charger and a cell-phone charger thereof. A solar cell board is arranged at one side of a charger shell; an over-charging control circuit and a voltage-increasing circuit are arranged inside the charger shell; the cathode and the anode output ends of the solar cell board are connected with the cathode and the anode of an alkaline zinc-manganese dioxide cell inside the charger shell through an inverse-prevention diode and the over-charging control circuit; the voltage increasing circuit is directly arranged between the cathode and the anode of the alkaline zinc-manganese dioxide cell or is arranged between the cathode and the anode of the alkaline zinc-manganese dioxide cell through a discharging control circuit; the output voltage of the voltage increasing circuit is matched with the charging voltage of the cell phone; the output end, which is connected with the charger shell, of the voltage increasing circuit is provided with a plug that is matched with the charging hole of the cell phone. The alkaline zinc-manganese dioxide cell is adopted as the energy storage element that can be repeatedly charged and discharged, so that the ordinary alkaline zinc-manganese dioxide cell can be recycled for use, thereby greatly reducing the waste rate of the alkaline zinc-manganese dioxide cell, and reducing the cost of the solar cell-phone charger, and favoring the environmental protection.

Description

Solar alkalescent Zn-Mn dry battery charger and charger for mobile phone thereof

(1), technical field:

The utility model relates to a kind of solar charger, particularly relate to a kind of solar alkalescent Zn-Mn dry battery charger and a kind of cheaply, energy-storage travelling wave tube adopts the solar mobile phone charging device of built-in alkaline zinc-manganese dioxide cell.

(2), background technology:

Traditional charger or charger for mobile phone need adopt 220 volts of ac power supplies of standard usually, the place shelter must have mains supply, and for mobile crowds such as tourist, field works, their communication tool is not often because the environment shelter has alternating current and can not adopt conventional charger in time to charge.Along with the appearance of solar charger and solar mobile phone charging device, its advantage is more and more obvious, and progressively enters huge numbers of families.The problem that present various solar chargers exist is, energy-storage travelling wave tube built-in rechargeable batteries or lithium ion batteries of adopting wherein, charger cost are than higher more, in actual use can be because of overcharging or misoperation is brought potential safety hazard.China utility model patent ZL 03258227.7 (Granted publication CN 2648680Y, October 13 2004 Granted publication day) disclosed a kind of solar mobile phone charging device, comprise Mobile phone plug, shell, described shell is provided with photovoltaic cell, and described photovoltaic cell is connected with electrical storage device by reaction diode, and described electrical storage device is connected with Mobile phone plug by booster circuit, easy to use, and can prolong useful life of charger, utilize solar energy to give cell-phone charging, environmental protection, energy-conservation.But which type of electrical storage device application documents specifically openly do not adopt, because we know, not all electrical storage device can be used as the energy-storage travelling wave tube that can be recycled charge and discharge.Present in addition some solar charger, because it is technical immature, sometimes in order to give the internal battery full charge, also need to dispose an AC adapter and utilize civil power to give charging mobile phone battery to remedy the deficiency of solar recharging ability, this has limited it undoubtedly and has promoted the use of.

China utility model patent ZL 200620071339.1 (notification number CN 2904322Y, May 23 2007 Granted publication day) a kind of solar energy dry battery charger has been proposed, this charger comprises integrated circuit voltage regulator and box body, integrated circuit voltage regulator is positioned at the box body front portion, the box body rear portion is provided with battery case, charging is anodal to be positioned at battery case with the charging negative pole, box cover top is connected with solar panel, the input of integrated circuit voltage regulator is connected with negative electricity with the positive pole of solar panel by input lead, and the output of integrated circuit voltage regulator is connected with the charging negative electricity by output lead and charging are anodal.Utilize solar panel to charge, be not subjected to the restriction of AC power by integrated circuit voltage regulator.Having under the situation of sunlight, can charge at any time, easy to use, energy savings.The economic backward area and the rural area hillman that are particularly suitable for AC-less power charge to dry cell.With aforementioned same reason, this patent application does not have concrete open how the realization that dry cell is realized charging, because offer some clarification in the dry cell application notice: charge, lay in mistake or the input fire, all easily cause battery explosion or leakage.

A kind of quick charger is arranged in the market, and it is to utilize the energy of dry cell is applied to the purpose that reaches in the battery of mobile phone to charging mobile phone battery.Bringing for so the moving group of outgoing stream must be convenient, but used for dry cell crosses once and just can only throw away, and has caused the wasting of resources and environmental pollution.In fact, present alkaline zinc-manganese dioxide cell can be recharged, and it is made with complete charged state.But the main active substances of alkaline zinc-manganese dioxide cell is an electrolytic manganese dioxide, and the discharge that it has been generally acknowledged that first electronics is the homogeneous reaction that a proton and electronics move in lattice.Cause MnO _xX value only drops to 1.5 from 2.In this reaction, the MnO of solid ₂Be converted into the another kind of solid structure MnOOH of trivalent:

MnO ₂+H ₂O+e→MnOOH+OH ^-

If continue discharge, particularly when reaching the low voltage of second electron discharge, will generate the manganese component of solubility, manganese ion can arrive the zinc negative pole, causes corrosion reaction and will cause cathode expansion, destroys filling property of battery.Simultaneously, when manganese dioxide charges, when charging voltage surpasses certain voltage, can produce sexavalence manganate and oxygen.The manganate disproportionation of solubility is the MnO of tetravalence ₂With a kind of manganous compound of not rechargeable, thereby cause the loss of circulation volume, usually can destroy the filling property of alkaline zinc-manganese dioxide cell.Therefore make present alkaline zinc-manganese dioxide cell to be gone out of use then, caused energy waste and environmental pollution by disposable use.

The advantage of alkaline zinc-manganese dioxide cell is that to compare cost lower with other rechargeable type battery (lithium ion battery, ni-mh, nickel-cadmium cell etc.), if can make full use of the chargeable performance of alkaline zinc-manganese dioxide cell, making it can be recycling, that can reduce consumer's use cost undoubtedly widely, be used for solar charger, bring conveniently for large tracts of land utilization and extention solar energy, have extremely strong society and economic worth.Regrettably at present for the recycling mature technique that also lacks of alkaline zinc-manganese dioxide cell, alkaline zinc-manganese dioxide cell also can't use as the built-in energy-storage travelling wave tube of solar charger.

(3), utility model content:

Technical problem to be solved in the utility model: at the problem of prior art existence, a kind of alkaline zinc-manganese dioxide cell solar charger and a kind of built-in alkaline zinc-manganese dioxide cell solar mobile phone charging device as energy-storage travelling wave tube is provided, can be used for the charging of alkaline zinc margunese cell, make the alkaline zinc-manganese dioxide cell can be recycling, reduce the scrappage of alkaline zinc-manganese dioxide cell greatly, reduce the cost of solar mobile phone charging device.

The technical solution adopted in the utility model:

A kind of solar alkalescent Zn-Mn dry battery charger, contain solar panel, the charger housing, be provided with anti-overcharge control circuit and battery case in the charger housing, solar panel is arranged on charger housing one side, the corresponding battery case of charger housing opposite side is provided with the battery case cover plate, it is characterized in that: solar panel just, cathode output end by alkaline zinc-manganese dioxide cell in reaction diode and anti-overcharge control circuit and the battery case just, the negative pole bonding conductor connects, and after described anti-overcharge control circuit output voltage distributes the charging voltage of every alkaline zinc margunese cell is controlled between 1.65～1.70V.

Described solar alkalescent Zn-Mn dry battery charger, anti-overcharge control circuit adopt the integrated voltage stabilizing voltage stabilizing circuit of MAX1843 series, and the solar panel cathode output end is through reaction diode and input end grounding electric capacity (C ₃) inserting the input (Vin) of MAX1843, the output end of pressure-stabilizing of MAX1843 is by inductance coil (L ₂) and output head grounding electric capacity (C ₇) connecting the anodal bonding conductor of alkaline zinc-manganese dioxide cell in the battery case, the negative pole bonding conductor of alkaline zinc-manganese dioxide cell connects the negative pole of solar panel, and the power end of MAX1843 (VCC) is by a resistance (R ₁) connect the positive pole of alkaline zinc-manganese dioxide cell, be connected a filter capacitor (C between the negative pole of the power end of MAX1843 (VCC) and solar panel ₄).

Described solar alkalescent Zn-Mn dry battery charger, anti-overcharge control circuit adopt overflow diode (D ₂), the solar panel cathode output end is through reaction diode (D ₂) connect the anodal bonding conductor of alkaline zinc-manganese dioxide cell in the battery case, the negative pole bonding conductor of alkaline zinc-manganese dioxide cell connects the negative pole of solar panel in the battery case, the overflow diode is in parallel with alkaline zinc-manganese dioxide cell, and overflow diode overflow voltage is complementary with alkaline zinc-manganese dioxide cell voltage in parallel.

Described solar alkalescent Zn-Mn dry battery charger, anti-overcharge control circuit comprises voltage detecting circuit and charging control electronic switch, voltage detecting circuit adopts TC51, AN051AD17S, any one voltage checking chip of AN051AD34S or AN051AD20S, electronic switch adopts field-effect transistor, the solar panel cathode output end connects the anodal bonding conductor of alkaline zinc-manganese dioxide cell through reaction diode, the negative pole bonding conductor of alkaline zinc-manganese dioxide cell connects the negative pole of solar panel by charging control electronic switch, the input of voltage checking chip (Vin) is connected the interior alkaline zinc margunese of battery case respectively with earth terminal (GND) to be done, the pond just, the negative pole bonding conductor, the output of voltage checking chip is by transistor amplifier circuit control connection charging control electronic switch.

A kind of solar mobile phone charging device, contain solar panel, charger housing, solar panel are arranged on charger housing one side, be provided with anti-overcharge control circuit and booster circuit in the charger housing, the positive and negative electrode output of solar panel is by reaction diode (D ₁) and anti-overcharge control circuit and charger housing in energy-storage travelling wave tube just, negative pole connects, described booster circuit directly or be connected in parallel on by charge/discharge control circuit between the positive pole and negative pole of energy-storage travelling wave tube, the output voltage of booster circuit and cell-phone charging voltage are complementary, on the charger housing, connect the booster circuit output and be provided with the plug that mates with the cell-phone charging jointing holes, it is characterized in that: described energy-storage travelling wave tube adopts alkaline zinc-manganese dioxide cell, after described anti-overcharge control circuit output voltage distributes the charging voltage of every alkaline zinc margunese cell is controlled between 1.65～1.70V; Described charge/discharge control circuit is limited between 0.9～1.1V every alkaline zinc margunese cell discharge voltage.

Described solar mobile phone charging device, anti-overcharge control circuit adopt MAX1843 series integrated stable voltage circuit, and the solar panel cathode output end is through reaction diode and input end grounding electric capacity (C ₃) inserting the input (Vin) of MAX1843, the output end of pressure-stabilizing of MAX1843 is by inductance coil (L ₂) and output head grounding electric capacity (C ₇) connect the positive pole of alkaline zinc-manganese dioxide cell, the negative pole of alkaline zinc-manganese dioxide cell connects the negative pole of solar panel, the power end of MAX1843 (VCC) connects the positive pole of alkaline zinc-manganese dioxide cell, is connected a filter capacitor (C between the negative pole of the power end of MAX1843 (VCC) and solar panel ₄).

Described solar alkalescent Zn-Mn dry battery charger, anti-overcharge control circuit adopt overflow diode (D ₂), the solar panel cathode output end is through reaction diode (D ₂) connecting the positive pole of alkaline zinc-manganese dioxide cell, the negative pole of alkaline zinc-manganese dioxide cell connects the negative pole of solar panel, and described overflow diode is in parallel with alkaline zinc-manganese dioxide cell, and overflow diode overflow voltage is complementary with alkaline zinc-manganese dioxide cell voltage in parallel.

Described solar mobile phone charging device; between the two poles of the earth of alkaline zinc-manganese dioxide cell, be connected with charge/discharge control circuit; described charge/discharge control circuit adopts S-8261, S-8232, S-8261AAJMD-G2J-T2, R5402, S-8254 or any one charge and discharge protection chip of Li-801; the discharge control electronic switch of charge/discharge control circuit is connected in the discharge loop; discharge control electronic switch adopts field-effect transistor, and the positive pole of alkaline zinc-manganese dioxide cell is by a current-limiting resistance (R ₁) and a filter capacitor (C ₁) connecting the power input (VDD) of charge and discharge protection chip, the negative pole of alkaline zinc-manganese dioxide cell connects the earth terminal (VSS) of charge and discharge protective chip, the control output end of charge and discharge protection chip (DO) control connection discharge control electronic switch.

Described solar mobile phone charging device, anti-overcharge control circuit and charge/discharge control circuit include the electronic switch of voltage detecting circuit and control charge or discharge, voltage detecting circuit can adopt TC51, AN051AD17S, any one voltage checking chip of AN051AD34S or AN051AD20S, electronic switch adopts field-effect transistor, the solar panel cathode output end connects the alkaline zinc-manganese dioxide cell positive pole through reaction diode, the negative pole of alkaline zinc-manganese dioxide cell is connected the negative pole of solar panel by charging and discharge control electronic switch, the input of two-way voltage checking chip (Vin) just is being connected alkaline zinc-manganese dioxide cell respectively with earth terminal (GND), negative pole, the output of charging voltage detection chip is by transistor amplifier circuit control connection charging control electronic switch, and electronic switch is controlled in the direct control connection discharge in the control output end of discharge voltage detection chip.

Described solar mobile phone charging device, be provided with the battery case of connection energy-storage travelling wave tube alkaline zinc-manganese dioxide cell in the charger housing, the corresponding battery case of the relative opposite side of solar panel is provided with the match battery lid plate on the charger housing, is provided with the positive and negative electrode bonding conductor that connects energy-storage travelling wave tube in the battery case.

The beneficial effects of the utility model:

1, the utility model charger can utilize solar energy to give the charging of mobile phone or alkaline zinc-manganese dioxide cell fast, timely and effectively, and is easy to use, reduced charger construction cost and use cost greatly.The utility model utilizes solar panel by control circuit alkaline zinc-manganese dioxide cell to be charged; perhaps utilize alkaline zinc-manganese dioxide cell as the energy-storage travelling wave tube of solar charger by filling; charge/discharge control circuit charges to mobile phone; filling; in the discharge process; discharge voltage by control alkaline zinc-manganese dioxide cell every cell is between 0.9～1.1V; charging voltage is limited between 1.65～1.70V; make alkaline zinc-manganese dioxide cell keep chargeable performance; can be recycling; reduced consumer's use cost effectively; can save the energy and greatly reduce the discarded rate of alkaline zinc-manganese dioxide cell, help environmental protection.

2, the utility model charger for mobile phone adopts a large amount of at present alkaline zinc-manganese dioxide cells that use to do internal battery, has reduced cost; Utilize solar panel by charging control circuit alkaline zinc-manganese dioxide cell to be charged, make script once obtain recycling with regard to abandoning the alkaline zinc-manganese dioxide cell of scrapping after the use, it is promoted the use of and will produce good society and economic worth.The utility model charger can charge at any time having under the situation of sunlight, is not subjected to the restriction of AC power.Simple in structure, with low cost.Charge to dry cell or mobile phone in the place that is particularly suitable for AC-less power.

3, the utility model charger for mobile phone is not having under the situation of sunlight, can use common dry cell to be cell-phone charging, very convenient and practical, particularly out on tours or operation in the open air can use various dry cells to use the device charging of storage battery as mobile phone or other.The utility model prevents effectively that by the charge and discharge control circuit alkaline zinc-manganese dioxide cell is too high or discharge voltage is low excessively because of charging voltage, thereby the filling property that has kept alkaline zinc-manganese dioxide cell, make original disposable alkaline zinc-manganese dioxide cell become reusable rechargeable alkaline battery, both save resource, reduced environmental pollution, also reduced consumer's use cost, environmental protection, energy-conservation.

(4), description of drawings:

Fig. 1 is the utility model charger for mobile phone structure block diagram;

Fig. 2 is one of charger circuit schematic diagram of the utility model two joint alkaline zinc-manganese dioxide cell parallel connections;

Fig. 3 be the parallel connections of the utility model two joint alkaline zinc-manganese dioxide cell the charger circuit schematic diagram two;

Fig. 4 is one of charger circuit schematic diagram of the utility model two joint alkaline zinc-manganese dioxide cell series connection;

Fig. 5 be the series connection of the utility model two joint alkaline zinc-manganese dioxide cells the charger circuit schematic diagram two;

(5), embodiment:

Embodiment one: referring to Fig. 1, Fig. 2, the utility model solar mobile phone charging device, contain solar panel, the charger housing, solar panel is arranged on charger housing one side, be provided with anti-overcharge control circuit and booster circuit in the charger housing, the positive and negative electrode output of solar panel is by reaction diode D ₁Be connected with the positive and negative electrode of energy-storage travelling wave tube in the charger housing with anti-overcharge control circuit, booster circuit directly or be connected in parallel on by charge/discharge control circuit between the positive pole and negative pole of energy-storage travelling wave tube, the output voltage of booster circuit and cell-phone charging voltage are complementary, on the charger housing, connect the booster circuit output and be provided with the plug that mates with the cell-phone charging jointing holes, described energy-storage travelling wave tube adopts alkaline zinc-manganese dioxide cell, after described anti-overcharge control circuit output voltage distributes the charging voltage of every alkaline zinc margunese cell is controlled between 1.65～1.70V; By described charge/discharge control circuit every alkaline zinc margunese cell discharge voltage is limited between 0.9～1.1V,, reaches the purpose that recycles with this filling property that keeps alkaline zinc-manganese dioxide cell.

Present embodiment solar mobile phone charging device, anti-overcharge control circuit adopt MAX1843 series integrated stable voltage circuit, and the solar panel cathode output end is through reaction diode D ₁With the input end grounding capacitor C ₃Insert the input Vin of MAX1843, the output end of pressure-stabilizing Vout of MAX1843 is by inductance coil L ₂With the output head grounding capacitor C) be connected the positive pole of alkaline zinc-manganese dioxide cell, the negative pole of alkaline zinc-manganese dioxide cell connects the negative pole of solar panel, the power end VCC of MAX1843 connects the positive pole of alkaline zinc-manganese dioxide cell, is connected filter capacitor C between the power end VCC of MAX1843 and the negative pole of solar panel ₄, the reference voltage terminal VREF of MAX1843 passes through capacitor C ₅The negative pole that connects solar panel, the TOFF end of MAX1843 passes through resistance R ₂The negative pole that connects solar panel, the earth terminal GND of MAX1843 and PGND also are connected the negative pole of solar panel.

Here booster circuit adopts integrated circuit (IC) chip 7NFD, and the positive pole of alkaline zinc-manganese dioxide cell is by inductance coil L ₁Be connected the power end VDD of 7NFD with diode D2, be connected to filter capacitor C between the positive and negative electrode of alkaline zinc-manganese dioxide cell ₁, inductance coil L ₁And be connected between the negative pole of the contact of diode D2 and alkaline zinc-manganese dioxide cell and expand flow field effect pipe BT1, the control end that expands flow field effect pipe BT1 connects the external control port EXT of 7NFD, the ground connection termination solar panel negative pole of 7NFD, the output of 7NFD connects the cell-phone charging jointing holes.Among Fig. 2, save alkaline zinc-manganese dioxide cells charging in parallel (also can directly charge simultaneously) to two after the voltage stabilizing of solar panel process voltage stabilizing circuit to consuming devices such as mobile phones.Here adopted MAX1843 series integrated regulator, output voltage is adjusted to 1.68V; Thereby reach the purpose of additives for overcharge protection.During use solar charger and the mobile phone that needs charging (or other adopts the consuming device of storage battery) are connected, after the booster circuit that the voltage of alkaline zinc-manganese dioxide cell that this moment is built-in or solar panel output is made up of the 7NFD chip boosts, battery of mobile phone (or other consuming device) is charged.

Present embodiment solar mobile phone charging device, if do not connect booster circuit, be solar alkalescent Zn-Mn dry battery charger merely just, as long as limited charging voltage, and the discharge voltage of alkaline zinc-manganese dioxide cell is not when reaching 1.1V under the general user mode, and electrical equipment has just quit work.For convenience battery is installed or is satisfied the multi-functional instructions for use of charger for mobile phone, in the charger housing, be provided with the battery case of connection alkaline zinc-manganese dioxide cell, the corresponding battery case of the relative opposite side of solar panel is provided with the match battery lid plate on the charger housing, is provided with the positive and negative electrode bonding conductor that connects energy-storage travelling wave tube in the battery case.The battery case that present embodiment solar mobile phone charging device can use common dry cell to put into setting uses as charger for emergency.

Embodiment two: referring to Fig. 1, Fig. 3, and present embodiment solar alkalescent Zn-Mn dry battery charger or charger for mobile phone, different with embodiment one is: anti-overcharge control circuit adopts overflow diode D ₂, the solar panel cathode output end is through reaction diode D ₂The positive pole that connects alkaline zinc-manganese dioxide cell, the negative pole of alkaline zinc-manganese dioxide cell connects the negative pole of solar panel, and described overflow diode is in parallel with alkaline zinc-manganese dioxide cell, and overflow diode overflow voltage is complementary with alkaline zinc-manganese dioxide cell voltage in parallel.

Here adopt red light emitting diodes (LED) D2 that two joints alkaline zinc-manganese dioxide cell in parallel is carried out the overflow charging.Diode can conducting under given voltage, and when battery is full of electricity charging current being shunted provides additives for overcharge protection.LED begins conducting with 1mA when 1.62V, along with the increase electric current increase of voltage, electric current is almost all shunted when 1.68V.Thereby reach the purpose of additives for overcharge protection.Other is with embodiment one.

Embodiment three: referring to Fig. 1, Fig. 4, what present embodiment solar mobile phone charging device and embodiment two were different is, solar panel is to the alkaline zinc-manganese dioxide cell charging (also can directly charge to consuming devices such as mobile phones simultaneously) of two joint series connection, each alkaline zinc-manganese dioxide cell overflow diode in parallel.Here charge/discharge control circuit has adopted NSK lithium electric protection IC chip S-8261 series.S-8261 series is the lithium ion/chargeable lithium polymer battery protection IC of built-in high-accuracy voltage testing circuit and delay circuit.This IC is suitable for joint the overcharging of lithium ion/chargeable lithium polymer battery, overdischarge and overcurrent protection most.It is 1.70V ± 80mV～2.60V ± 80mV (corresponding 50mV advance rank unit) that overdischarge detects voltage; (overdischarge detects voltage and is set at 2.00V～2.20V) protection and overcurrent protection to be used for that just in time two joint alkaline zinc-manganese dioxide cells are carried out overdischarge; after discharge control voltage reaches; the control output end output control signal of protection IC chip S-8261 makes discharge control electronic switch FET1 cut off discharge loop.Here adopt overflow diode (LED) D1, D2 that two joint alkaline zinc-manganese dioxide cells are carried out the overflow charging, the function of overcharging of protection IC chip S-8261 is lain idle.

Embodiment four: referring to Fig. 1, Fig. 5, present embodiment solar mobile phone charging device and alkalescent Zn-Mn dry battery charger, different with embodiment three is: anti-overcharge control circuit and charge/discharge control circuit adopt voltage detecting circuit and charge or discharge control electronic switch, voltage detecting circuit adopts TC51, AN051AD17S, any one voltage checking chip of AN051AD34S or AN051AD20S, electronic switch adopts field-effect transistor, the solar panel cathode output end connects the alkaline zinc-manganese dioxide cell positive pole through reaction diode, the negative pole of alkaline zinc-manganese dioxide cell is connected the negative pole of solar panel by charging and discharge control electronic switch, the input Vin of two-way voltage checking chip just is being connected the interior alkaline zinc-manganese dioxide cell of battery case respectively with earth terminal GND, negative pole or just, the negative pole bonding conductor, the output of charging voltage detection chip is by transistor amplifier circuit control connection charging control electronic switch, and electronic switch is controlled in the direct control connection discharge in the control output end of discharge voltage detection chip.The cmos voltage detector TC51 that present embodiment has adopted open-drain output detects the overcharge voltage of battery.TC51 is the cmos voltage detector of low-power consumption, open-drain output, circuit is made up of program control voltage divider, delay circuit of comparator, the high-precision reference voltage circuit of little electric current, laser and the output driver that has a digital delay timer, the output of employing open-drain, and have built-in delay feature.During work, need only Vin greater than Vdet-, the output Vout of TC51 just keeps logic high state; When Vin was lower than Vdet-, output became the logic low shape immediately.During less than Vdet-and hysteresis Vhyst sum, Vout keeps low level at Vin.Otherwise Vout gets back to high level once more.In the present embodiment; Vdet-is set at 3.30V～3.40V as overcharging detection voltage; overcharge when detecting voltage when charging voltage reaches, TC51 outputs a control signal to electronic switch FET2 and cuts off charging circuit, and two joint alkaline zinc-manganese dioxide cells are carried out additives for overcharge protection.The present embodiment booster circuit adopts integrated circuit (IC) chip LTC3401, after the booster circuit that alkaline zinc-manganese dioxide cell is made up of the LTC3401 chip boosts, mobile phone (or other consuming device) is charged.Booster circuit adopts also can adopt ML1890.

Claims (10)

1, a kind of solar alkalescent Zn-Mn dry battery charger, contain solar panel, the charger housing, be provided with anti-overcharge control circuit and battery case in the charger housing, solar panel is arranged on charger housing one side, the corresponding battery case of charger housing opposite side is provided with the battery case cover plate, it is characterized in that: solar panel just, cathode output end by alkaline zinc-manganese dioxide cell in reaction diode and anti-overcharge control circuit and the battery case just, the negative pole bonding conductor connects, and after described anti-overcharge control circuit output voltage distributes the charging voltage of every alkaline zinc margunese cell is controlled between 1.65～1.70V.

2, solar alkalescent Zn-Mn dry battery charger according to claim 1, it is characterized in that: described anti-overcharge control circuit adopts the integrated voltage stabilizing voltage stabilizing circuit of MAX1843 series, and the solar panel cathode output end is through reaction diode and input end grounding electric capacity (C ₃) inserting the input (Vin) of MAX1843, the output end of pressure-stabilizing of MAX1843 is by inductance coil (L ₂) and output head grounding electric capacity (C ₇) connecting the anodal bonding conductor of alkaline zinc-manganese dioxide cell in the battery case, the negative pole bonding conductor of alkaline zinc-manganese dioxide cell connects the negative pole of solar panel, and the power end of MAX1843 (VCC) is by a resistance (R ₁) connect the positive pole of alkaline zinc-manganese dioxide cell, be connected a filter capacitor (C between the negative pole of the power end of MAX1843 (VCC) and solar panel ₄).

3, solar alkalescent Zn-Mn dry battery charger according to claim 1 is characterized in that: anti-overcharge control circuit adopts overflow diode (D ₂), the solar panel cathode output end is through reaction diode (D ₂) connect the anodal bonding conductor of alkaline zinc-manganese dioxide cell in the battery case, the negative pole bonding conductor of alkaline zinc-manganese dioxide cell connects the negative pole of solar panel in the battery case, the overflow diode is in parallel with alkaline zinc-manganese dioxide cell, and overflow diode overflow voltage is complementary with alkaline zinc-manganese dioxide cell voltage in parallel.

4, solar alkalescent Zn-Mn dry battery charger according to claim 1, it is characterized in that: described anti-overcharge control circuit comprises voltage detecting circuit and charging control electronic switch, voltage detecting circuit adopts TC51, AN051AD17S, any one voltage checking chip of AN051AD34S or AN051AD20S, electronic switch adopts field-effect transistor, the solar panel cathode output end connects the anodal bonding conductor of alkaline zinc-manganese dioxide cell through reaction diode, the negative pole bonding conductor of alkaline zinc-manganese dioxide cell connects the negative pole of solar panel by charging control electronic switch, the input of voltage checking chip (Vin) just is being connected the interior alkaline zinc-manganese dioxide cell of battery case respectively with earth terminal (GND), the negative pole bonding conductor, the output of voltage checking chip is by transistor amplifier circuit control connection charging control electronic switch.

5, a kind of solar mobile phone charging device, contain solar panel, charger housing, solar panel are arranged on charger housing one side, be provided with anti-overcharge control circuit and booster circuit in the charger housing, the positive and negative electrode output of solar panel is by reaction diode (D ₁) and anti-overcharge control circuit and charger housing in energy-storage travelling wave tube just, negative pole connects, described booster circuit directly or be connected in parallel on by charge/discharge control circuit between the positive pole and negative pole of energy-storage travelling wave tube, the output voltage of booster circuit and cell-phone charging voltage are complementary, on the charger housing, connect the booster circuit output and be provided with the plug that mates with the cell-phone charging jointing holes, it is characterized in that: described energy-storage travelling wave tube adopts alkaline zinc-manganese dioxide cell, after described anti-overcharge control circuit output voltage distributes the charging voltage of every alkaline zinc margunese cell is controlled between 1.65～1.70V; Described charge/discharge control circuit is limited between 0.9～1.1V every alkaline zinc margunese cell discharge voltage.

6, solar mobile phone charging device according to claim 5 is characterized in that: described anti-overcharge control circuit adopts MAX1843 series integrated stable voltage circuit, and the solar panel cathode output end is through reaction diode and input end grounding electric capacity (C ₃) inserting the input (Vin) of MAX1843, the output end of pressure-stabilizing of MAX1843 is by inductance coil (L ₂) and output head grounding electric capacity (C ₇) connect the positive pole of alkaline zinc-manganese dioxide cell, the negative pole of alkaline zinc-manganese dioxide cell connects the negative pole of solar panel, the power end of MAX1843 (VCC) connects the positive pole of alkaline zinc-manganese dioxide cell, is connected a filter capacitor (C between the negative pole of the power end of MAX1843 (VCC) and solar panel ₄).

7, solar mobile phone charging device according to claim 5 is characterized in that: anti-overcharge control circuit adopts overflow diode (D ₂), the solar panel cathode output end is through reaction diode (D ₂) connecting the positive pole of alkaline zinc-manganese dioxide cell, the negative pole of alkaline zinc-manganese dioxide cell connects the negative pole of solar panel, and described overflow diode is in parallel with alkaline zinc-manganese dioxide cell, and overflow diode overflow voltage is complementary with alkaline zinc-manganese dioxide cell voltage in parallel.

8, solar mobile phone charging device according to claim 7; it is characterized in that: between the two poles of the earth of alkaline zinc-manganese dioxide cell, be connected with charge/discharge control circuit; described charge/discharge control circuit adopts S-8261, S-8232, S-8261AAJMD-G2J-T2, R5402, S-8254 or any one charge and discharge protection chip of Li-801; the discharge control electronic switch of charge/discharge control circuit is connected in the discharge loop; discharge control electronic switch adopts field-effect transistor, and the positive pole of alkaline zinc-manganese dioxide cell is by a current-limiting resistance (R ₁) and a filter capacitor (C ₁) connecting the power input (VDD) of charge and discharge protection chip, the negative pole of alkaline zinc-manganese dioxide cell connects the earth terminal (VSS) of charge and discharge protection chip, the control output end of charge and discharge protection chip (DO) control connection discharge control electronic switch.

9, solar mobile phone charging device according to claim 5, it is characterized in that: described anti-overcharge control circuit and charge/discharge control circuit include the electronic switch of voltage detecting circuit and control charge or discharge, voltage detecting circuit adopts TC51, AN051AD17S, any one voltage checking chip of AN051AD34S or AN051AD20S, electronic switch adopts field-effect transistor, the solar panel cathode output end connects the alkaline zinc-manganese dioxide cell positive pole through reaction diode, the negative pole of alkaline zinc-manganese dioxide cell is connected the negative pole of solar panel by charging and discharge control electronic switch, the input of two-way voltage checking chip (Vin) just is being connected the interior alkaline zinc-manganese dioxide cell of battery case respectively with earth terminal (GND), negative pole, the output of charging voltage detection chip is by transistor amplifier circuit control connection charging control electronic switch, and electronic switch is controlled in the direct control connection discharge in the control output end of discharge voltage detection chip.

10, according to each described solar mobile phone charging device of claim 5～9, it is characterized in that: the battery case that is provided with connection energy-storage travelling wave tube alkaline zinc-manganese dioxide cell in the charger housing, the corresponding battery case of the relative opposite side of solar panel is provided with the match battery lid plate on the charger housing, is provided with the positive and negative electrode bonding conductor that connects energy-storage travelling wave tube in the battery case.

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