CN109541988A - A kind of intelligent recharge and discharge tooling device - Google Patents

Abstract

The invention discloses a kind of intelligent recharge and discharge tooling devices, including main control module (100), power module (200), charge control module (300), control of discharge module (400) and communication module (500), wherein: power module (200), respectively with main control module (100), charge control module (300), control of discharge module (400), communication module (500) is connected, for for main control module (100), charge control module (300), control of discharge module (400) and communication module (500) provide work electricity consumption；Main control module (100) is connected with charge control module, control of discharge module and communication module respectively, for passing through communication module uploading detection information to external host computer.The present invention can carry out automatically controlling the charge and discharge process of more intelligent movable power supplies, record the detection data in charge and discharge process in real time, improve detection efficiency.

Description

A kind of intelligent recharge and discharge tooling device

Technical field

The present invention relates to charge and discharge electro-technical fields, more particularly to a kind of intelligent recharge and discharge tooling device.

Background technique

Currently, with electronic product, such as the extensive use of mobile phone, tablet computer, need of the people to intelligent movable power supplies The amount of asking is higher and higher, and while demand is continuously increased, the output of intelligent movable power supplies also can constantly increase.

In process of production, it before intelligent movable power supplies product export, needs to do a large amount of performance test, degradation, uses It is whether up to standard to detect power supply product performance.

In the prior art, the independent charging or individually electric discharge of separate unit are only limitted to the performance detection of intelligent movable power supplies, And manually come record charge and discharge process time and corresponding data, this makes in the detection process, can not only occupy big The time of amount and manpower, it is also possible to can occur unnecessary mistake because of manual operation.Therefore, if carried out to power supply product Large batch of charging, discharge process need to put into a large amount of time and manpower, and data record and deterministic process are very numerous It is trivial.

Therefore, there is an urgent need to develop a kind of equipment out at present, can be to the charge and discharge process of more intelligent movable power supplies It carries out automatically controlling, and records the detection data in charge and discharge process in real time, improve detection efficiency.

Summary of the invention

In view of this, the object of the present invention is to provide a kind of intelligent recharge and discharge tooling device, it can be to more intelligent slidings The charge and discharge process of dynamic power supply carries out automatically controlling, and records the detection data in charge and discharge process in real time, improves detection efficiency, Be conducive to widely apply, be of great practical significance.

For this purpose, including main control module, power module, charge control the present invention provides a kind of intelligent recharge and discharge tooling device Module, control of discharge module and communication module, in which:

Power module is connected with main control module, charge control module, control of discharge module, communication module respectively, is used for Work electricity consumption is provided for main control module, charge control module, control of discharge module and communication module；

Charge control module, for carrying out charging operations to external mobile power source, and in real time output charging voltage value and Charging current value is to main control module；

Control of discharge module for carrying out discharge operation to external mobile power source, and exports discharge voltage value and electric discharge Current value is to main control module；

Main control module is connected with charge control module, control of discharge module and communication module respectively, described for receiving The charging voltage value and charging current value that charge control module is sent, and receive the electric discharge electricity that the control of discharge module is sent Pressure value and discharge current value, and charging time and discharge time are recorded in real time, discharge power and charge power are obtained, is then passed through Communication module is uploaded to external host computer.

Wherein, the power module includes first order voltage conversion circuit and second level voltage conversion circuit, in which:

First order voltage conversion circuit, the DC voltage for inputting external power supply module carry out stablizing decompression, conversion For the first DC output voltage, second level voltage conversion circuit, and output are then output to charge control module and electric discharge Control module；

Second level voltage conversion circuit is connected with first order voltage conversion circuit, for the first step voltage to be converted electricity First DC output voltage of road output, carries out stablizing decompression, is converted to the second DC output voltage, be then output to master control mould Block and charge control module.

Wherein, first order voltage conversion circuit, including DC decompression chip U4, in which:

7 feet of the DC decompression chip U4 respectively with shunt capacitance C33, C34, C35 and external power input POWER It is connected, external power input POWER is connected by conducting wire with external power supply module；

8 feet of the DC decompression chip U4 are connected with one end of resistance R39, the other end of resistance R39 respectively with electricity The one end for holding C37 is connected with 2 feet of DC decompression chip U4, the other end ground connection of capacitor C37；

1 foot of the DC decompression chip U4 connects with one end of resistance R40, and the other end of resistance R40 distinguishes connecting resistance One end of R41 and one end of resistance R47, the other end ground connection of resistance R47, the other end of resistance R41 meet the one of inductance L1 respectively End, the first DC output voltage output end vo ut1 and capacitor C30, C31 and C32；

Capacitor C30, C31 and C32 ground connection；The other end of inductance L1 connects 6 feet and electricity of the DC decompression chip U4 respectively One end of R38 is hindered, the other end of resistance R38 is connected by a capacitor C25 with 4 feet of the DC decompression chip U4；

3 feet of the DC decompression chip U4 are connected by a resistance R46 with 7 feet of the DC decompression chip U4 It connects；

3 feet of the DC decompression chip U4 pass through a resistance R48 ground connection；

3 feet of DC voltage DC interface are hanging；

5 feet of the DC decompression chip U4 are grounded；

Second level voltage conversion circuit, including DC decompression chip U9, in which:

5 feet of DC decompression chip U9 respectively with the first DC output voltage output end vo ut1 and shunt capacitance C64 phase It connects；

2 feet of DC decompression chip U9 are grounded；

1 foot of DC decompression chip U9 is connected by a capacitor C57 with 6 feet；

6 feet of DC decompression chip U9 connect with the cathode of one end of an inductance L2, voltage-stabiliser tube D31 respectively, voltage-stabiliser tube The plus earth of D31；

The other end of inductance L2 respectively with the second DC output voltage output end vo ut2, one end of resistance R94, capacitor C6 1 one end and one end of C62 connect；

The other end of resistance R94 also connects with one end of 3 feet of DC decompression chip U9 and resistance R97 respectively, resistance R97 The other end ground connection；

The both ends of resistance R94 are parallel with a capacitor C60；

The other end of capacitor C61 and C62 are grounded；

4 feet of DC decompression chip U9 one end with resistance R95 and R96 respectively, the other end and shunt capacitance of resistance R95 C64 and C65 connect；

Shunt capacitance C64 and C65 ground connection, resistance R96 ground connection.

Wherein, the charge control module includes four groups of charge control relay circuits and four groups of voltage amplifier acquisition electricity Road, in which:

Every group of charge control relay circuit controls the relay wherein having for the control according to main control module Switch state；

Every group of voltage amplifier Acquisition Circuit, is connected with charge control relay circuit, for acquiring and exporting charging Voltage value is to main control module.

Wherein, the charge control relay circuit includes: DC voltage DC interface；

DC voltage DC interface is connected with external power supply module；

2 feet, 4 feet and 5 feet of DC voltage DC interface are grounded after confluence；

1 foot of DC voltage DC interface connects with 3 feet of relay J1；

4 feet of relay J1 connect with one end of a capacitor C1, capacitor C8 and resistance R1 respectively；

The other end of capacitor C1 and resistance R1 after confluence, respectively with a charge control connecting terminal and a capacitor C5 It is connected；

The other end of capacitor C5 and C8 are grounded；

The coil both ends of relay J1 are parallel with a diode D1；

The both ends of diode D1 are parallel with resistance R5 and light emitting diode D4；

The cathode of diode D1 is also exported with the first DC output voltage of first order voltage conversion circuit in power module End Vout1 connects；

The cathode of light emitting diode D4 is connected with the collector of triode Q1, the emitter ground connection of triode Q1, three poles 1 foot of the single-chip microcontroller that the base stage of pipe Q1 has by a resistance R9 and main control module connects.

Wherein, the voltage amplifier Acquisition Circuit includes: current monitoring chip U2；

1 foot of current monitoring chip U2 is grounded；

2 feet of current monitoring chip U2 are grounded；

3 feet of current monitoring chip U2 and the second DC output voltage of second level voltage conversion circuit in power module are defeated Outlet Vout2 connects；

4 feet and 5 feet of current monitoring chip U2, are separately connected the both ends of the resistance R1 in charge control relay circuit, For input difference voltage；

6 feet of current monitoring chip U2 connect with 40 feet of the single-chip microcontroller that main control module has.

Wherein, the control of discharge module includes four groups of control of discharge relay exchange signal acquisition synthetic circuits；

Wherein, every group of control of discharge relay exchange signal acquisition synthetic circuit, for the control according to main control module, control The switch state for the relay wherein having is made, and acquires and exports discharge voltage value to main control module；

The control of discharge relay exchange signal acquisition synthetic circuit includes the first discharge connection terminal and the second electric discharge Connecting terminal；

First discharge connection terminal is connected with the AC output interface of mobile power source；

First discharge connection terminal also connects with 3 feet of resistance R19 and relay J7 respectively；

Second discharge connection terminal is connected by conducting wire with discharge load module；

Resistance R19 connects with 3 feet of rectifier bridge U3；

A voltage-stabiliser tube D19 is connected between 1 foot and 2 feet of rectifier bridge U3；

1 foot of rectifier bridge U3 is connected with 1 foot of an optocoupler U2；

2 feet of rectifier bridge U3 are connected with 2 feet of an optocoupler U2；

A capacitor C23 is connected between 1 foot and 2 feet of optocoupler U2；

3 feet of optocoupler U2 are grounded；

30 pins of the single-chip microcontroller that 4 feet of optocoupler U2 have by a pull-up resistor R31 and main control module are connected；

4 feet of relay J7 connect with the second discharge connection terminal；

The coil both ends of relay J7 are parallel with a diode D11；

The both ends of diode D11 are parallel with resistance R23 and light emitting diode D14；

The cathode of diode D11 is also exported with the first DC output voltage of first order voltage conversion circuit in power module End Vout1 connects；

The cathode of light emitting diode D14 is connected with the collector of triode Q7, the emitter ground connection of triode Q1, three poles 34 feet of the single-chip microcontroller that the base stage of pipe Q1 has by a resistance R27 and main control module connect.

Wherein, the communication module includes communication module circuit, in which:

Communication module circuit includes power level conversion chip U5；

Second direct current output of the second pole tension conversion circuit in 16 feet and power module of power level conversion chip U5 Voltage output end Vout2 is connected, to provide operating voltage for chip；

10 feet of power level conversion chip U5 are connected with 7 feet of the single-chip microcontroller that main control module has；

9 feet of power level conversion chip U5 are connected with 5 feet of the single-chip microcontroller that main control module has；

7 feet of power level conversion chip U5 are connected with 2 feet of communication port DB9；

8 feet of power level conversion chip U5 are connected with 3 feet of communication port DB9；

A capacitor C8 is connected between 1 foot and 3 feet of power level conversion chip U5；

A capacitor C7 is connected between 4 feet and 5 feet of power level conversion chip U5；

6 feet of power level conversion chip U5 pass through 15 feet (lower margin) of a capacitor C9 and power level conversion chip U5 It is connected；

15 feet of power level conversion chip U5 are grounded；

16 feet of power level conversion chip U5 are connected by a capacitor C6 with 2 feet of power level conversion chip U5 It connects；

Capacitor C6 also passes through a capacitor C5 ground connection；

Communication port DB9 is connected by patchcord with host computer.

Wherein, further include indicating lamp module, be connected with main control module, it is corresponding aobvious for the control according to main control module Show the mode of operation to external mobile power source；

At this point, power module, is also connected with indicating lamp module, for providing work electricity consumption for indicating lamp module；

Indicating lamp module includes four groups of indicator light circuits, in which:

Every group of indicator light circuit includes resistance R34, first order voltage conversion circuit in one end of resistance R34 and power module The first DC output voltage output end vo ut1 connect；

The other end of resistance R34 is connected by light emitting diode 21 with the collector of triode Q9；

The emitter of triode Q9 is grounded；

19 feet of the single-chip microcontroller that the base stage of triode Q9 has by a resistance R42 and main control module are connected.

Wherein, the discharge load module is preset powerful load resistance by muti-piece and is formed, for each mobile electricity Source provides discharge load；

Each load resistance of discharge load module is connected by conducting wire with the second discharge connection terminal；The intelligence is filled The tooling device that discharges further includes temperature control modules, and temperature control modules include cabinet air conditioner and radiator fan.

By the above technical solution provided by the invention as it can be seen that compared with prior art, the present invention provides a kind of intelligence Charge and discharge tooling device can carry out automatically controlling the charge and discharge process of more intelligent movable power supplies, and record fills in real time Detection data in discharge process improves detection efficiency, is conducive to widely apply, be of great practical significance.

Detailed description of the invention

Fig. 1 is a kind of structural block diagram of intelligent recharge and discharge tooling device provided by the invention；

Fig. 2 is any one group of first order that power module has in a kind of intelligent recharge and discharge tooling device provided by the invention The schematic diagram of voltage conversion circuit；

Fig. 3 is any one group of second level that power module has in a kind of intelligent recharge and discharge tooling device provided by the invention The schematic diagram of voltage conversion circuit；

Fig. 4 is that charge control module has in a kind of intelligent recharge and discharge tooling device provided by the invention any one group fills The schematic diagram of electric control relay circuit；

Fig. 5 is any one group of electricity that charge control module has in a kind of intelligent recharge and discharge tooling device provided by the invention Press the schematic diagram of amplifier Acquisition Circuit；

Fig. 6 is that control of discharge module has in a kind of intelligent recharge and discharge tooling device provided by the invention any one group is put The schematic diagram of electric control relay exchange signal acquisition synthetic circuit；

Fig. 7 is the schematic diagram of communication module circuit in a kind of intelligent recharge and discharge tooling device provided by the invention；

Fig. 8 is the schematic diagram of one group of indicator light circuit in a kind of intelligent recharge and discharge tooling device provided by the invention；

Fig. 9 is the circuit diagram of main control module in a kind of intelligent recharge and discharge tooling device provided by the invention.

Specific embodiment

In order to enable those skilled in the art to better understand the solution of the present invention, with reference to the accompanying drawing with embodiment to this Invention is described in further detail.

Referring to Fig. 1 to Fig. 9, the present invention provides a kind of intelligent recharge and discharge tooling devices, including main control module 100, power supply Module 200, charge control module 300, control of discharge module 400 and communication module 500, in which:

Power module 200, respectively with main control module 100, charge control module 300, control of discharge module 400, communicate mould Block 500 is connected, for mentioning for main control module 100, charge control module 300, control of discharge module 400 and communication module 500 For the electricity consumption that works；

Charge control module 300 for carrying out charging operations to external mobile power source, and exports charging voltage value in real time With charging current value to main control module；

Control of discharge module 400 for carrying out discharge operation to external mobile power source, and exports discharge voltage value and puts Electric current value is to main control module 100；

Main control module 100 is connected with charge control module 300, control of discharge module 400 and communication module 500 respectively, The charging voltage value and charging current value sent for receiving the charge control module 300, and receive the control of discharge The discharge voltage value and discharge current value that module 400 is sent, and charging time and discharge time are recorded in real time, obtain discharge power And charge power, external host computer (such as industrial computer) is then uploaded to by communication module 500.

It should be noted that according to the needs of users, main control module also upload above-mentioned charge and discharge essential information (including Charging voltage value and charging current value, discharge voltage value and discharge current value, charging time and discharge time and discharge power And charge power) except, other information can also be uploaded to host computer, for example, may include the detection time started, at the end of Between, discharge power, charge power, radiator fan start time, radiator fan start-up temperature, overheating protection time, overheating protection The charge and discharge relevant information that temperature, the output information such as electric current and output voltage and other users need.

Referring to fig. 2, shown in Fig. 3, in the present invention, the power module 200 includes first order voltage conversion circuit (Fig. 2 It is shown) and second level voltage conversion circuit (shown in Fig. 3), in which:

First order voltage conversion circuit, the DC voltage for being used to input external power supply module (such as external power supply) (such as 12V~36V) it carries out stablizing decompression, the first DC output voltage (such as 12V) is converted to, the second step voltage is then output to and turns Circuit, and output are changed to charge control module 300 and control of discharge module (relay specially in them)；

Second level voltage conversion circuit is connected with first order voltage conversion circuit, for the first step voltage to be converted electricity Road output the first DC output voltage (such as 12V), carry out stablizing decompression, be converted to the second DC output voltage (such as 5V), main control module 100 and charge control module 300 are then output to.

In specific implementation, first order voltage conversion circuit, including DC decompression chip U4, in which:

7 feet (i.e. input pin) of the DC decompression chip U4 respectively with shunt capacitance C33, C34, C35 and external electrical Source input terminal POWER is connected, and external power input POWER is connected by conducting wire with external power supply module；

8 feet (i.e. output well judges foot) of the DC decompression chip U4 are connected with one end of resistance R39, resistance The other end of R39 is connected with 2 feet (i.e. supply pin) of one end of capacitor C37 and DC decompression chip U4 respectively, capacitor C37's Other end ground connection；

1 foot (i.e. feedback foot) of the DC decompression chip U4 connects with one end of resistance R40, the other end of resistance R40 One end of one end of connecting resistance R41 and resistance R47 respectively, the other end ground connection of resistance R47, the other end of resistance R41 connect respectively One end of inductance L1, the first DC output voltage output end vo ut1 (specifically exporting 12V) and capacitor C30, C31 and C32；

Capacitor C30, C31 and C32 ground connection；6 feet that the other end of inductance L1 meets the DC decompression chip U4 respectively (are opened Measure output pin in pass) and resistance R38 one end, the other end of resistance R38 passes through a capacitor C25 and DC decompression chip U4 4 feet (i.e. bootstrapping pin) be connected；

3 feet (i.e. enabled foot) of the DC decompression chip U4 pass through a resistance R46 and DC decompression chip U4 7 feet (i.e. input pin) be connected；

3 feet (i.e. enabled foot) of the DC decompression chip U4 pass through a resistance R48 ground connection；

5 feet (lower margin) of the DC decompression chip U4 are grounded.

In specific implementation, second level voltage conversion circuit, including DC decompression chip U9, in which:

5 feet (i.e. input pin) of DC decompression chip U9 are (specific with the first DC output voltage output end vo ut1 respectively Output 12V) and shunt capacitance C64 connect；

2 feet (i.e. lower margin) of DC decompression chip U9 are grounded；

1 foot (i.e. bootstrapping pin) of DC decompression chip U9 passes through a capacitor C57 and 6 feet (i.e. switching node pin) phase Connection；

6 feet (i.e. switching node pin) of DC decompression chip U9 respectively with one end of an inductance L2, voltage-stabiliser tube D31 Cathode connects, the plus earth of voltage-stabiliser tube D31；

The other end of inductance L2 respectively with the second DC output voltage output end vo ut2, one end of resistance R94, capacitor C6 1 one end and one end of C62 connect；

The other end of resistance R94 also one end with 3 feet (i.e. the feedback pin) and resistance R97 of DC decompression chip U9 respectively Connect, the other end ground connection of resistance R97；

The both ends of resistance R94 are parallel with a capacitor C60；

The other end of capacitor C61 and C62 are grounded；

4 feet (i.e. enabled input pin) of DC decompression chip U9 one end with resistance R95 and R96 respectively, resistance R95's The other end connects with shunt capacitance C64 and C65；

Shunt capacitance C64 and C65 ground connection, resistance R96 ground connection.

It should be noted that fully taking into account the stable voltage of equipment need of work for the present invention, different modules is needed The voltage wanted is different, therefore, as needed, devises two-stage voltage conversion circuit in the power module.Wherein, the first order Direct current 12V~36V voltage that outside provides is converted into stable 12V voltage by voltage conversion circuit.Second step voltage conversion electricity The 12V voltage that the first order is converted to is converted into stable 5V voltage by road.

In specific implementation, DC decompression chip U4 in Fig. 2 can specifically use U.S. Xin Yuan System Co., Ltd (MPS) the DC decompression chip MP4423HGQ-Z produced.7 feet (i.e. input pin) of U4 pass through shunt capacitance C33, C34, C35 It is connected with external power input POWER, external power input POWER is connected by conducting wire with external power supply module, So as to receive direct current 12V~36V voltage provided by external power supply module, it is then converted into stable 12V voltage.

In specific implementation, DC decompression chip U9 in Fig. 3 can specifically use U.S. Xin Yuan System Co., Ltd (MPS) the DC decompression chip MP2451DT-LF-Z produced.5 feet (i.e. input pin) of U9 pass through shunt capacitance C64 and first The 12V voltage that step voltage switching current obtains is connected, and by foregoing circuit, 12V voltage is converted to stable 5V voltage.

Referring to fig. 4, shown in Fig. 5, in the present invention, the charge control module 300 includes four groups of charge control relays Circuit and four groups of voltage amplifier Acquisition Circuits, in which:

Every group of charge control relay circuit (shown in Fig. 4), for the control according to main control module 100, control wherein has The switch state of some relays；

Every group of voltage amplifier Acquisition Circuit (shown in Fig. 5), is connected with charge control relay circuit, for acquiring simultaneously Charging voltage value is exported to main control module 100.

Shown in Figure 4 in specific implementation, the charge control relay circuit includes: DC voltage DC interface；

DC voltage DC interface is connected with external power supply module (such as external power supply)；

2 feet (i.e. lower margin) of DC voltage DC interface, 4 feet (i.e. shell connection pin) and 5 feet (i.e. shell connects pin) It is grounded after confluence；

3 feet (i.e. reed pin) of DC voltage DC interface are hanging；

1 foot of DC voltage DC interface connects with 3 feet (i.e. input pin) of relay J1；

4 feet (i.e. output pin) of relay J1 connect with one end of a capacitor C1, capacitor C8 and resistance R1 respectively；

The other end of capacitor C1 and resistance R1 after confluence, respectively with a charge control connecting terminal and a capacitor C5 It is connected；

The other end of capacitor C5 and C8 are grounded；

The coil both ends of relay J1 are parallel with a diode D1；

The both ends of diode D1 are parallel with resistance R5 and light emitting diode D4；

The cathode of diode D1 is also defeated with the first DC output voltage of first order voltage conversion circuit in power module 200 Outlet Vout1 (specifically exporting 12V) connects；

The cathode of light emitting diode D4 is connected with the collector of triode Q1, the emitter ground connection of triode Q1, three poles 1 foot (i.e. input and output pin 1) for the single-chip microcontroller that the base stage of pipe Q1 has by resistance R9 and main control module 100 connects.

It should be noted that in the present invention, shown in Figure 9,1 foot, 2 feet, 3 feet, 4 feet of main control module 100, respectively Connect one group of charge control relay circuit as shown in Figure 4.

For the present invention, it is also necessary to which explanation, the DC voltage DC interface in Fig. 4 connects external power supply module, to fill Electricity provides power supply.The operating voltage of relay J1 is the 12V voltage that first order voltage conversion circuit is converted to.Control port J- C1 is connected with 1 foot (i.e. J-C1) of single-chip microcontroller (Fig. 9), when control port J-C1 is high level (5V), triode Q1 conducting, after By electric current in the coil and light emitting diode D4 of electric appliance J1, J1 is attracted, and light emitting diode D4 is bright；When control port J-C1 is low When level (0V), triode Q1 is turned off, and does not have electric current in the coil and light emitting diode D4 of relay J1, and J1 is opened, and luminous two Pole pipe D4 goes out.

For the present invention, resistance R1 resistance value is 0.01 ohm in Fig. 4, is current sampling resistor, cooperates the voltage amplification of Fig. 5 Electric current in device Acquisition Circuit.Charge control connecting terminal in Fig. 4 connects the charging input end of mobile power source by conducting wire.

Shown in Figure 5 in specific implementation, the voltage amplifier Acquisition Circuit includes: current monitoring chip U2；

1 foot (i.e. reference voltage pin) of current monitoring chip U2 is grounded；

2 feet (i.e. lower margin) of current monitoring chip U2 are grounded；

The of second level voltage conversion circuit in 3 feet (i.e. power pins) of current monitoring chip U2 and power module 200 Two DC output voltage output end vo ut2 (specifically exporting 5V) connect；

4 feet (i.e. input pin) and 5 feet (i.e. input pin) of current monitoring chip U2 are separately connected charging shown in Fig. 4 The both ends of resistance R1 in control relay circuit, for input difference voltage；

40 feet of the single-chip microcontroller that 6 feet (i.e. output pin) of current monitoring chip U2 have with main control module 100 (are simulated Digital voltage converts ADC input pin, the i.e. end ADC1) connect, for allowing single-chip microcontroller that can read the voltage amplifier acquisition The voltage value that circuit exports after amplifying to voltage.

It should be noted that in the present invention, shown in Figure 9,40 feet, 41 feet, 42 feet, 43 feet of main control module 100, It is separately connected one group of voltage amplifier Acquisition Circuit as shown in Figure 5.

For the present invention, it should be noted that the operating voltage of current monitoring chip U2 is the second pole tension conversion circuit The 5V voltage being converted to.

In specific implementation, the current monitoring chip U2 can be using the current monitoring chip of Texas Instrument TI production INA199A2DCKR is exported after the differential voltage of input being amplified 50 times.

Shown in Figure 6, in the present invention, the control of discharge module 400 includes four groups of control of discharge relay exchanges Signal acquisition synthetic circuit；

Wherein, every group of control of discharge relay exchange signal acquisition synthetic circuit, for the control according to main control module 100 System, controls the switch state for the relay wherein having, and acquires and export discharge voltage value to main control module 100.

Shown in Figure 6 in specific implementation, the control of discharge relay exchange signal acquisition synthetic circuit includes first Discharge connection terminal and the second discharge connection terminal；

First discharge connection terminal is connected with the AC output interface of mobile power source；

First discharge connection terminal also connects with 3 feet (i.e. input pin) of resistance R19 and relay J7 respectively；

Resistance R19 connects with 3 feet (ac input end) of rectifier bridge U3；

A voltage-stabiliser tube is connected between 1 foot (direct current output anode) and 2 feet (direct current output cathode) of rectifier bridge U3 D19；

1 foot (direct current output anode) of rectifier bridge U3 is connected with 1 foot (input anode) of an optocoupler U2；

2 feet (direct current output cathode) of rectifier bridge U3 are connected with 2 feet (input cathode) of an optocoupler U2；

A capacitor C23 is connected between 1 foot (input anode) and 2 feet (input cathode) of optocoupler U2；

3 feet (output negative pole) of optocoupler U2 are grounded；

The single-chip microcontroller (Fig. 9) that 4 feet (output cathode) of optocoupler U2 have by a pull-up resistor R31 and main control module 30 pins (i.e. V-AC1, input and output pin) are connected；

4 feet (i.e. output pin) of relay J7 connect with the second discharge connection terminal；

The coil both ends of relay J7 are parallel with a diode D11；

The both ends of diode D11 are parallel with resistance R23 and light emitting diode D14；

First DC output voltage of the cathode of diode D11 also with first order voltage conversion circuit in power module 200 Output end vo ut1 (specifically exporting 12V) connects；

The cathode of light emitting diode D14 is connected with the collector of triode Q7, the emitter ground connection of triode Q1, three poles The single-chip microcontroller that the base stage of pipe Q1 has by resistance R27 and main control module 100 34 feet (i.e. input and output pin 34, i.e., The end V-AC1) connect.

It should be noted that in the present invention, shown in Figure 9,34 feet, 35 feet, 36 feet, 37 feet of main control module 100, It is separately connected one group of control of discharge relay exchange signal acquisition synthetic circuit as shown in FIG. 6.

It should be noted that the connecting terminal 1 in Fig. 6 is by conducting wire, with exchanging for mobile power source product for the present invention Output interface is connected, and the alternating voltage of mobile power source output is input to the exchange input of rectifier bridge U3 after resistance R19 partial pressure 3 feet and 4 feet are held, obtain DC voltage through over commutation；

Then, the input terminal of optocoupler U2,1 foot and light of rectifier bridge U3 are input to by voltage-stabiliser tube D19 and electrolytic capacitor C23 1 foot of coupling N2 is connected, and 2 feet of rectifier bridge U3 are connected with 2 feet of optocoupler N2, and the 3 feet ground connection of optocoupler N2,4 feet of optocoupler N2 pass through One pull-up resistor R31 is connected with the V-AC1 of single-chip microcontroller (Fig. 9).

Therefore, when the first discharge connection terminal has alternating current input, optocoupler U2 conducting, single-chip microcontroller reads low from V-AC1 Level (0V)；When the first discharge connection terminal does not have alternating current input, optocoupler U2 is not turned on, and single-chip microcontroller reads high from V-AC1 Level (5V).

In Fig. 6, the operating voltage of relay J7 is the 12V voltage that first order voltage conversion circuit is converted to.Control Port J-AC1 is connected with the J-AC1 of single-chip microcontroller (Fig. 9), when control port J-AC1 is high level (5V), triode Q7 conducting, By electric current in the coil and light emitting diode D14 of relay J7, J7 is attracted, and light emitting diode D14 is bright；As control port J- When AC1 is low level (0V), triode Q7 is turned off, and does not have electric current in the coil and light emitting diode D14 of relay J7, J1 is beaten It opens, light emitting diode D14 goes out.

In Fig. 6, the second discharge connection terminal is connected by conducting wire with external discharge load module.

In specific implementation, the rectifier bridge U3 can be micro- (FMS) the semiconductor limited liability company production of Taiwan beauty Rectifier bridge MB6M.

Shown in Figure 7, in the present invention, the communication module 500 includes communication module circuit, in which:

Communication module circuit includes power level conversion chip U5；

The of second pole tension conversion circuit in 16 feet (supply pin) and power module 200 of power level conversion chip U5 Two DC output voltage output end vo ut2 (the 5V output voltage of specifically Fig. 3) are connected, to provide operating voltage for chip；

Single-chip microcontroller (the figure that 10 feet (data transmission input pin) and main control module 100 of power level conversion chip U5 have 9) 7 feet (connect serial ports and send data pin TXD) are connected；

The single-chip microcontroller (Fig. 9) that 9 feet (data receiver output pin) and main control module 100 of power level conversion chip U5 have 5 feet (serial ports receive data pin RXD) be connected；

7 feet (data transmission output pin) of power level conversion chip U5 are connected with 2 feet of communication port DB9；

8 feet (data receiver input pin) of power level conversion chip U5 are connected with 3 feet of communication port DB9；

It is connected between 1 foot (capacitor C1 anode pin) and 3 feet (capacitor C1 negative pin) of power level conversion chip U5 There is a capacitor C8；

It is connected between 4 feet (capacitor C2 anode pin) and 5 feet (capacitor C2 negative pin) of power level conversion chip U5 There is a capacitor C7；

6 feet (negative charge pump output) of power level conversion chip U5 pass through a capacitor C9 and power level conversion chip 15 feet (lower margin) of U5 are connected；

15 feet (lower margin) of power level conversion chip U5 are grounded；

16 feet (supply pin) of power level conversion chip U5 pass through the 2 of a capacitor C6 and power level conversion chip U5 Foot (positive charge pump output) is connected；

Capacitor C6 also passes through a capacitor C5 ground connection；

Communication port DB9 is connected by patchcord with host computer.

In specific implementation, power level conversion chip U5 can be the RS232 chip of (TI) company, Texas Instrument production MAX232 is single supply electrical level transferring chip.

It should be noted that communication module 500 (Fig. 7) is communicated using RS232, it mainly include single supply electrical level transferring chip The Transistor-Transistor Logic level of serial ports is converted into RS232 level, communicated with host computer by MAX232.Single-chip microcontroller (Fig. 9) is to intelligent movable power supplies Each data in charge and discharge process are monitored, and the detection of each intelligent movable power supplies during charging and discharging is believed Breath, such as charging time, discharge time, charge-discharge electric power, overheating protection time and corresponding temperature, output Current Voltage information are led to It crosses communication module and is transferred to smart memory, calling and real-time display that host computer realizes information.

In addition, intelligent recharge and discharge tooling device provided by the invention, further includes indicating lamp module, with 100 phase of main control module Connection, for the control according to main control module 100, corresponding display to the mode of operation of external mobile power source (such as charged state, Discharge condition or overheating protection state)

At this point, power module 200, is also connected with indicating lamp module, for providing work electricity consumption for indicating lamp module.

Shown in Figure 8, indicating lamp module includes four groups of indicator light circuits, in which:

Every group of indicator light circuit includes resistance R34, and first step voltage is converted in one end of resistance R34 and power module 200 First DC output voltage output end vo ut1 (specifically exporting 12V) of circuit connects；

The other end of resistance R34 is connected by light emitting diode 21 with the collector of triode Q9；

The emitter of triode Q9 is grounded；

19 foot (its of the single-chip microcontroller (Fig. 9) that the base stage of triode Q9 has by a resistance R42 and main control module 100 For input and output pin, i.e. LED1 pin) it is connected.

It should be noted that for the present invention, the 12V of indicator light circuit and first order voltage conversion circuit (Fig. 2) output It is connected, provides operating voltage for LED light.Control pin LED1 in Fig. 8 is connected with the LED1 pin of single-chip microcontroller (Fig. 9), works as end When mouth LED1 is high level, triode Q9 is connected, and light emitting diode D21 is bright；When port LED1 is low level, triode Q9 is closed Disconnected, light emitting diode D21 goes out.

It should be noted that in the present invention, shown in Figure 9,19 feet, 20 feet, 21 feet, 22 feet of main control module 100, It is separately connected one group of indicator light circuit as shown in Figure 8.

In the prior art, only a kind of state of indicator light prompt mobile power source charge and discharge, the i.e. bright expression of lamp are recycling In charge and discharge, lamp, which goes out, to be indicated to complete charge and discharge process, and the practicability is poor.The present invention designs indicating lamp module, integrates a variety of indicator lights, It can be charging, electric discharge or overheating protection state with the process of each mobile power source of real-time prompting.

In the present invention, shown in Figure 9, the circuit of the main control module 100 is as shown, main control module 100 passes through Charge control module and control of discharge module are controlled, cycle charge-discharges are carried out to more mobile power sources, more mobile power sources follow Ring charge and discharge process can synchronize progress, can also be different step and carry out, and can pass through the biography at detection mobile power source access port Sensor, perceives the access situation of mobile power source, while controlling being connected for communication module and host computer, thus output test result, Corresponding status display is carried out at the same time it can also control instructions lamp module.Keep entire charge and discharge tooling device more intelligent, real With change.

Shown in Figure 9, in specific implementation, the single-chip microcontroller U1 that main control module 100 uses can be the production of macrocrystalline science and technology STC12C5A60S2。

In Fig. 9, capacitor C1, capacitor C2 and 11.0592 megahertzs of crystal oscillator Y1 form crystal oscillating circuit, 1 foot of crystal oscillator Y1 It is connected with 15 feet (i.e. crystal oscillator pin XTAL1) of single-chip microcontroller, 2 feet of crystal oscillator Y1 and 14 feet (the i.e. crystal oscillator pin of single-chip microcontroller XTAL2) it is connected, provides work clock for single-chip microcontroller.

38 feet (the i.e. power pins VC) C of single-chip microcontroller U1 and the second pole tension conversion circuit (Fig. 3) be converted to second DC output voltage output end vo ut2 (specifically exporting 5V) is connected, and 16 pins (i.e. lower margin GND) and is integrally connected to single-chip microcontroller Power supply.

7 feet (i.e. serial ports receives data pin RXD) and the MAX232 chip of communication module (shown in Fig. 7) of single-chip microcontroller U1 9 feet (i.e. the second circuit-switched data receive output pin R2O) are connected, 5 feet (i.e. serial ports receives data pin TXD) of single-chip microcontroller U1 with it is logical Believe that 10 feet (i.e. the second tunnel sends data-out pin T2I) of the MAX232 chip of module (shown in Fig. 7) are connected, passes through MAX232 Chip and host computer interaction data.

1 foot, 2 feet, 3 feet and 4 feet of single-chip microcontroller U1 are common input and output pin, respectively with four groups of charge control relays 1 foot (i.e. base stage) of triode Q1 is connected by one resistance of series connection in device circuit (Fig. 4), and the level by controlling pin becomes Change, carrys out turning on and off for relay J1 in control figure 4.

34 feet, 35 feet, 36 feet and 37 feet of single-chip microcontroller U1 are common input and output pin, respectively with four groups of control of discharge 1 foot (i.e. base stage) of triode Q7 is connected by one resistance R27 of series connection in module (Fig. 6), and the level by controlling pin becomes Change, relay J7's turns on and off in control figure 6.

40 feet, 41 feet, 42 feet and 43 feet of single-chip microcontroller U1 be analog to digital voltage convert (ADC) input pin, respectively with 6 feet (i.e. output pin OUT) of voltage amplifier IAN199 pass through series connection one in four groups of voltage amplifier Acquisition Circuits (Fig. 5) Resistance R13 is connected with one capacitor C17 of bypass, by analog-to-digital conversion, reads amplified voltage.

30 feet, 31 feet, 32 feet and 33 feet of single-chip microcontroller U1 are common input and output pin, respectively with four groups of control of discharge 4 feet of optocoupler EL817 in module (Fig. 6) are connected, and read the level change of 4 foot of optocoupler.

19 feet, 20 feet, 21 feet and 22 feet of single-chip microcontroller U1 are common input and output pin, electric with four groups of indicator lights respectively 1 foot (i.e. base stage) of triode Q9 in road (Fig. 8) is connected by one resistance R42 of series connection, and the level by controlling pin becomes Change, the instruction state of control instructions lamp.

In the present invention, in specific implementation, the external power supply module, for line voltage 220V to be converted into intelligent electricity The charging voltage of source need of work.

In specific implementation, external power supply module can be by the HLG- of multiple bright latitude (Guangzhou) Electronics Co., Ltd. productions 240H-24A power supply composition.

In specific implementation, external power supply module passes through charge control relay in charge control module shown in conducting wire and Fig. 4 DC voltage DC interface in circuit is connected, for providing the DC charging voltage of 24V.

External power supply module is connected by conducting wire with the external power input POWER in power module shown in Fig. 2, is led to Overvoltage conversion provides operating voltage for master control borad (specially power module).

In the present invention, in specific implementation, the discharge load module, discharge load module is preset powerful by muti-piece Resistance composition, for providing discharge load to each mobile power source product.

Each load resistance of discharge load module is connected by conducting wire with the second discharge connection terminal of Fig. 6.

It in the present invention, further include temperature control for intelligent recharge and discharge tooling device provided by the invention in specific implementation Molding block, temperature control modules include cabinet air conditioner and radiator fan；

Radiator fan is mounted on two enclosure tops, can be by the heat generated in intelligent power charging process and electric discharge The heat that resistance generates is discharged in time on the outside of cabinet, is reduced interior of equipment cabinet temperature, is guaranteed the normal operation of equipment.

Cabinet air conditioner is mounted on by external power supply module, and the local temperature of power supply module can be effectively reduced.It avoids in inflammation Under the conditions of thermal condition, power supply module local temperature overheat causes power supply that overheating protection occurs, makes complete equipment that event occur Barrier.

In the present invention, in specific implementation, the host computer is by VB language development, and display interface is succinctly understandable, but function It can be complete.

Interface on the host computer can show product testing tables of data, which may include inspection Survey time started, end time, discharge power, charge power, radiator fan starting time, radiator fan start-up temperature, overheat Guard time, overheating protection temperature, the output information such as electric current and output voltage can also show other according to the needs of users Content, such as may include product type, batch number and operator and communication port and baud rate, make to be supplied to Industry person selects the configuration of communication.

The interface of the host computer may include two set product detection data tables, when slave computer will test data be sent to it is upper When machine, this interface will show data, and operator is allowed to understand the overall process of detection visual and clearly.The every receiving of host computer One group of detection data is finished, whole group data are immediately stored in local data base, then the tables of data on interface will be emptied, etc. It arrives to next group of data.The method that this host computer uses real time data to separate with remote server data library, the data on the same day It can be successively stored in local data base, on the day of after all detection work, by the whole day number of storage in the local database According to, move in remote server data library, this method compared to by data real-time storage into remote server data library Method, can effectively avoid the problem that in transmission process network connection etc. due to and caused by loss of data.

It should be noted that for the present invention, for existing charging/discharging apparatus man efficiency it is low, detection time is long, The problems such as data are unstable, can be for multiple intelligent movable power supplies while the tooling device of automatic charging and electric discharge, instead of people Work industry, improves detection efficiency.

Intelligent recharge and discharge tooling device provided by the invention can simultaneously charge and discharge multiple intelligent movable power supplies Detection, and to testing result, for example, the charging time, discharge time, charge-discharge electric power, radiator fan starting time and temperature, Overheating protection time and corresponding temperature export Current Voltage and scan the information such as SN code by barcode scanning gun, are passed by host computer It is defeated, to realize the smart memory of information, calling and real-time display.

In the present invention, the present invention includes main control module, power module, charge control module, control of discharge module, communication Module and indicating lamp module.Entire master control borad each road relay, DC current acquisition module, ac signal acquisition with MCU Module is completed to switch the charging and discharging state of multi-way intelligence mobile power source, and to each intelligence during charging and discharging The detection information of mobile power source is monitored and uploads to host computer, to complete entire charge and discharge cycles, and records related ginseng Number.

In conclusion compared with prior art, a kind of intelligent recharge and discharge tooling device provided by the invention can be right The charge and discharge process of more intelligent movable power supplies carries out automatically controlling, and records the detection data in charge and discharge process in real time, mentions High detection efficiency is conducive to widely apply, be of great practical significance.

The above is only a preferred embodiment of the present invention, it is noted that for the ordinary skill people of the art For member, various improvements and modifications may be made without departing from the principle of the present invention, these improvements and modifications are also answered It is considered as protection scope of the present invention.

Claims (10)

1. a kind of intelligent recharge and discharge tooling device, which is characterized in that including main control module (100), power module (200), charging Control module (300), control of discharge module (400) and communication module (500), in which:

Power module (200), respectively with main control module (100), charge control module (300), control of discharge module (400), logical Letter module (500) is connected, and is used for as main control module (100), charge control module (300), control of discharge module (400) and leads to Believe that module (500) provide work electricity consumption；

Charge control module (300), for carrying out charging operations to external mobile power source, and in real time output charging voltage value and Charging current value is to main control module；

Control of discharge module (400) for carrying out discharge operation to external mobile power source, and exports discharge voltage value and electric discharge Current value gives main control module (100)；

Main control module (100), respectively with charge control module (300), control of discharge module (400) and communication module (500) phase Connection, the charging voltage value and charging current value sent for receiving the charge control module (300), and put described in reception The discharge voltage value and discharge current value that electric control module (400) is sent, and charging time and discharge time are recorded in real time, it obtains Then discharge power and charge power are uploaded to external host computer by communication module (500).

2. intelligent recharge and discharge tooling device as described in claim 1, which is characterized in that the power module (200) includes the Voltage order one conversion circuit and second level voltage conversion circuit, in which:

First order voltage conversion circuit, the DC voltage for inputting external power supply module carry out stablizing decompression, are converted to One DC output voltage is then output to second level voltage conversion circuit, and output to charge control module (300) and electric discharge Control module；

Second level voltage conversion circuit is connected with first order voltage conversion circuit, for first order voltage conversion circuit is defeated The first DC output voltage out carries out stablizing decompression, is converted to the second DC output voltage, is then output to main control module (100) and charge control module (300).

3. intelligent recharge and discharge tooling device as claimed in claim 2, which is characterized in that first order voltage conversion circuit, including DC decompression chip U4, in which:

7 feet of the DC decompression chip U4 are connected with shunt capacitance C33, C34, C35 and external power input POWER respectively It connects, external power input POWER is connected by conducting wire with external power supply module；

8 feet of the DC decompression chip U4 are connected with one end of resistance R39, the other end of resistance R39 respectively with capacitor C37 One end be connected with 2 feet of DC decompression chip U4, the other end of capacitor C37 ground connection；

1 foot of the DC decompression chip U4 connects with one end of resistance R40, the other end difference connecting resistance R41's of resistance R40 One end of one end and resistance R47, the other end ground connection of resistance R47, the other end of resistance R41 connect one end of inductance L1, the respectively One DC output voltage output end vo ut1 and capacitor C30, C31 and C32；

Capacitor C30, C31 and C32 ground connection；The other end of inductance L1 connects 6 feet and resistance R38 of the DC decompression chip U4 respectively One end, the other end of resistance R38 is connected by a capacitor C25 with 4 feet of the DC decompression chip U4；

3 feet of the DC decompression chip U4 are connected by a resistance R46 with 7 feet of the DC decompression chip U4；

3 feet of the DC decompression chip U4 pass through a resistance R48 ground connection；

5 feet of the DC decompression chip U4 are grounded；

Second level voltage conversion circuit, including DC decompression chip U9, in which:

5 feet of DC decompression chip U9 connect with the first DC output voltage output end vo ut1 and shunt capacitance C64 respectively；

2 feet of DC decompression chip U9 are grounded；

1 foot of DC decompression chip U9 is connected by a capacitor C57 with 6 feet；

6 feet of DC decompression chip U9 connect with the cathode of one end of an inductance L2, voltage-stabiliser tube D31 respectively, voltage-stabiliser tube D31's Plus earth；

The other end of inductance L2 respectively with the second DC output voltage output end vo ut2, one end of resistance R94, capacitor C61 one End and one end of C62 connect；

The other end of resistance R94 also connects with one end of 3 feet of DC decompression chip U9 and resistance R97 respectively, and resistance R97's is another One end ground connection；

The both ends of resistance R94 are parallel with a capacitor C60；

The other end of capacitor C61 and C62 are grounded；

4 feet of DC decompression chip U9 one end with resistance R95 and R96 respectively, the other end and shunt capacitance C64 of resistance R95 Connect with C65；

Shunt capacitance C64 and C65 ground connection, resistance R96 ground connection.

4. intelligent recharge and discharge tooling device as claimed in claim 3, which is characterized in that charge control module (300) packet Include four groups of charge control relay circuits and four groups of voltage amplifier Acquisition Circuits, in which:

Every group of charge control relay circuit controls the relay wherein having for the control according to main control module (100) Switch state；

Every group of voltage amplifier Acquisition Circuit, is connected with charge control relay circuit, for acquiring and exporting charging voltage It is worth and gives main control module (100).

5. intelligent recharge and discharge tooling device as claimed in claim 4, which is characterized in that the charge control relay circuit packet It includes: DC voltage DC interface；

DC voltage DC interface is connected with external power supply module；

2 feet, 4 feet and 5 feet of DC voltage DC interface are grounded after confluence；

1 foot of DC voltage DC interface connects with 3 feet of relay J1；

4 feet of relay J1 connect with one end of a capacitor C1, capacitor C8 and resistance R1 respectively；

The other end of capacitor C1 and resistance R1 are connected with a charge control connecting terminal and a capacitor C5 respectively after confluence It connects；

The other end of capacitor C5 and C8 are grounded；

The coil both ends of relay J1 are parallel with a diode D1；

The both ends of diode D1 are parallel with resistance R5 and light emitting diode D4；

The cathode of diode D1 is also exported with the first DC output voltage of first order voltage conversion circuit in power module (200) End Vout1 connects；

The cathode of light emitting diode D4 is connected with the collector of triode Q1, the emitter ground connection of triode Q1, triode Q1 1 foot of single-chip microcontroller that has by resistance R9 and main control module (100) of base stage connect.

6. intelligent recharge and discharge tooling device as claimed in claim 5, which is characterized in that the voltage amplifier Acquisition Circuit packet It includes: current monitoring chip U2；

1 foot of current monitoring chip U2 is grounded；

2 feet of current monitoring chip U2 are grounded；

Second DC output voltage of second level voltage conversion circuit in 3 feet of current monitoring chip U2 and power module (200) Output end vo ut2 connects；

4 feet and 5 feet of current monitoring chip U2, are separately connected the both ends of the resistance R1 in charge control relay circuit, thus For input difference voltage；

6 feet of current monitoring chip U2 connect with 40 feet of the single-chip microcontroller that main control module (100) has.

7. intelligent recharge and discharge tooling device as claimed in claim 3, which is characterized in that control of discharge module (400) packet Include four groups of control of discharge relay exchange signal acquisition synthetic circuits；

Wherein, every group of control of discharge relay exchange signal acquisition synthetic circuit is used for the control according to main control module (100), The switch state for the relay wherein having is controlled, and acquires and exports discharge voltage value and give main control module (100)；

The control of discharge relay exchange signal acquisition synthetic circuit includes the first discharge connection terminal and the second discharge connection Terminal；

First discharge connection terminal is connected with the AC output interface of mobile power source；

First discharge connection terminal also connects with 3 feet of resistance R19 and relay J7 respectively；

Second discharge connection terminal is connected by conducting wire with discharge load module；

Resistance R19 connects with 3 feet of rectifier bridge U3；

3 feet of DC voltage DC interface are hanging；

A voltage-stabiliser tube D19 is connected between 1 foot and 2 feet of rectifier bridge U3；

1 foot of rectifier bridge U3 is connected with 1 foot of an optocoupler U2；

2 feet of rectifier bridge U3 are connected with 2 feet of an optocoupler U2；

A capacitor C23 is connected between 1 foot and 2 feet of optocoupler U2；

3 feet of optocoupler U2 are grounded；

30 pins of the single-chip microcontroller that 4 feet of optocoupler U2 have by a pull-up resistor R31 and main control module are connected；

4 feet of relay J7 connect with the second discharge connection terminal；

The coil both ends of relay J7 are parallel with a diode D11；

The both ends of diode D11 are parallel with resistance R23 and light emitting diode D14；

The cathode of diode D11 is also defeated with the first DC output voltage of first order voltage conversion circuit in power module (200) Outlet Vout1 connects；

The cathode of light emitting diode D14 is connected with the collector of triode Q7, the emitter ground connection of triode Q1, triode Q1 34 feet of single-chip microcontroller that have by resistance R27 and main control module (100) of base stage connect.

8. intelligent recharge and discharge tooling device as claimed in claim 3, which is characterized in that the communication module (500) includes logical Interrogate modular circuit, in which:

Communication module circuit includes power level conversion chip U5；

Second direct current output of the second pole tension conversion circuit in 16 feet and power module (200) of power level conversion chip U5 Voltage output end Vout2 is connected, to provide operating voltage for chip；

10 feet of power level conversion chip U5 are connected with 7 feet of the single-chip microcontroller that main control module (100) has；

9 feet of power level conversion chip U5 are connected with 5 feet of the single-chip microcontroller that main control module (100) has；

7 feet of power level conversion chip U5 are connected with 2 feet of communication port DB9；

8 feet of power level conversion chip U5 are connected with 3 feet of communication port DB9；

A capacitor C8 is connected between 1 foot and 3 feet of power level conversion chip U5；

A capacitor C7 is connected between 4 feet and 5 feet of power level conversion chip U5；

6 feet of power level conversion chip U5 are connected by a capacitor C9 with 15 feet (lower margin) of power level conversion chip U5 It connects；

15 feet of power level conversion chip U5 are grounded；

16 feet of power level conversion chip U5 are connected by a capacitor C6 with 2 feet of power level conversion chip U5；

Capacitor C6 also passes through a capacitor C5 ground connection；

Communication port DB9 is connected by patchcord with host computer.

9. intelligent recharge and discharge tooling device as claimed in claim 3, which is characterized in that further include indicating lamp module, with master control Module (100) is connected, for the control according to main control module (100), mode of operation of the corresponding display to external mobile power source；

At this point, power module (200), is also connected with indicating lamp module, for providing work electricity consumption for indicating lamp module；

Indicating lamp module includes four groups of indicator light circuits, in which:

Every group of indicator light circuit includes resistance R34, the first step voltage conversion electricity in one end and power module (200) of resistance R34 The first DC output voltage output end vo ut1 on road connects；

The other end of resistance R34 is connected by light emitting diode 21 with the collector of triode Q9；

The emitter of triode Q9 is grounded；

19 feet of the single-chip microcontroller that the base stage of triode Q9 has by resistance R42 and main control module (100) are connected.

10. intelligent recharge and discharge tooling device as claimed in claim 7, which is characterized in that the discharge load module is by muti-piece Powerful load resistance composition is preset, for providing discharge load to each mobile power source；

Each load resistance of discharge load module is connected by conducting wire with the second discharge connection terminal；

The intelligent recharge and discharge tooling device further includes temperature control modules, and temperature control modules include cabinet air conditioner and radiation air Fan.