CN109546684A - Micro-capacitance sensor power supply system - Google Patents

Abstract

Micro-capacitance sensor power supply system belongs to power supply system technical field more particularly to a kind of micro-capacitance sensor power supply system.The present invention provides a kind of reliable micro-capacitance sensor power supply system.The present invention includes master switch, step-up transformer, first switch, photovoltaic DC-to-AC converter, photovoltaic module, second switch, blower inverter, wind-driven generator, third switch, energy storage inverter, energy-storage battery, 4th switch and Active Power Filter-APF, master switch one terminates secondary bus, the master switch other end is connected with step-up transformer output end, step-up transformer input terminal respectively with first switch one end, second switch one end, third switchs one end, 4th switch one end is connected, first switch one end other end is connected with the output end of photovoltaic DC-to-AC converter, the output end of the input termination photovoltaic module of photovoltaic DC-to-AC converter.

Description

Micro-capacitance sensor power supply system

Technical field

The invention belongs to power supply system technical field more particularly to a kind of micro-capacitance sensor power supply systems.

Background technique

With the high speed development of new-energy automobile, people pay close attention to the charging technique of new-energy automobile further, therefore have Necessity researches and develops a kind of safe and reliable charging equipment, and safe and reliable charging equipment then needs a kind of reliable micro-capacitance sensor to supply Electric system.

Summary of the invention

The present invention addresses the above problem, provides a kind of reliable micro-capacitance sensor power supply system.

To achieve the above object, the present invention adopts the following technical scheme that, the present invention includes master switch, step-up transformer, One switch, photovoltaic DC-to-AC converter, photovoltaic module, second switch, blower inverter, wind-driven generator, third switch, energy storage inversion Device, energy-storage battery, the 4th switch and Active Power Filter-APF, master switch one terminate secondary bus, the master switch other end and boosting Transformer output end be connected, step-up transformer input terminal respectively with first switch one end, second switch one end, third switch one End, the 4th switch one end be connected, first switch one end other end is connected with the output end of photovoltaic DC-to-AC converter, photovoltaic DC-to-AC converter it is defeated Enter to terminate the output end of photovoltaic module；

Second switch one end other end is connected with the output end of blower inverter, and the input terminal of blower inverter is given a dinner for a visitor from afar power generator Output end；

Third switchs one end other end and is connected with the output end of energy storage inverter, and the input of energy storage inverter terminates energy-storage battery；

One end is another is terminated with active power filter for 4th switch.

As a preferred embodiment, the invention also includes micro-capacitance sensor controller, micro-capacitance sensor controller signals transmission ports point It is not passed with the signal of the signal transmission port of photovoltaic DC-to-AC converter, the signal transmission port of Active Power Filter-APF, energy storage inverter Defeated port, the signal transmission port of blower inverter, the signal transmission port of microgrid energy power system are connected.

As another preferred embodiment, microgrid energy power system of the present invention uses computer.

As another preferred embodiment, micro-capacitance sensor controller of the present invention includes MCU, DSP, the signal transmission end of MCU Mouth is connected with the signal transmission port of DSP, and the control signal output mouth of MCU is connected with the input port of the first IPM module, the The output port of one IPM module is connected with the control port of DC/DC module, input port and the photovoltaic module phase of DC/DC module Even, the output port of DC/DC module is connected with the input port of the first AC/DC module；

The control signal input parallel port of first AC/DC module is connected with the output port of the 2nd IPM module, the 2nd IPM module Input port connect dsp control signal output port, dsp control signal output port connects the control signal of two-way AC/DC module Input port be connected, two-way AC/DC module respectively with battery group, the output port of the first AC/DC module, first contactor one End is connected, the signal input port and the signal output port phase of photovoltaic power generation, wind-power electricity generation load condition sampling module of DSP Even；

The control signal input mouth of first contactor is connected by relay with the control signal output mouth of DSP, and first connects The tentaculum other end is connected with the input terminal of AC load, the 2nd AC/DC module respectively, and the output termination of the 2nd AC/DC module is straight Current load, AC load are given a dinner for a visitor from afar power generator by second contactor, the control signal input mouth of second contactor by after Electric appliance connects the control signal output mouth of DSP.

As another preferred embodiment, microgrid energy power system of the present invention includes data Layer, management level and tune Spend layer, data Layer to each generator unit generated output and load realtime power the real-time dynamic acquisition of variation, acquisition data send to Management level do data analysis and optimization, then the distribution of each unit is carried out by dispatch layer.

Secondly, data Layer of the present invention includes information collection part, data management part, status predication part, energy rate Predicted portions, Network topology part；Management level include load switching part, system administration part, energy storage administrative section, tide Stream calculation part, idle work optimization part, economic optimization part；Dispatch layer includes generating set scheduling portion, energy storage charge and discharge fulgurite Reason part, load management and scheduling portion.

In addition, the invention also includes micro-capacitance sensor battery management system, micro-capacitance sensor battery management system include host module, from Machine module, protection plate module, display module；

Slave module and host module measurement cell voltage and temperature, balancing battery energy；Plate module is protected to carry out SOC meter It calculates, SOH is calculated, generates alert data；The charge and discharge of host module control protection board count battery pack information, to being System state is detected, is controlled system mode；Display module shows the data of battery, provides sound-light alarm, record number According to.

Beneficial effect of the present invention.

The present invention can provide stable, reliable electric energy by the mutual cooperation of each section for follow-up equipment.

Detailed description of the invention

The present invention will be further described with reference to the accompanying drawings and detailed description.The scope of the present invention not only limits to In the statement of the following contents.

Fig. 1 is the system block diagram of the centralized high-voltage rectifying electric current distribution charging heap of the present invention.

Fig. 2 is high voltage protective system block diagram of the invention.

Fig. 3 is rectifier transformer block diagram of the invention.

Fig. 4 is block diagram of high-voltage rectifying system of the invention.

Fig. 5 is that commutation spike of the invention absorbs molten Zapping circuit figure fastly.

Fig. 6 is PLC CPU control unit figure of the invention.

Fig. 7 is touch screen of the invention, ethernet module unit figure.

Fig. 8 is overvoltage of direct current absorption of the invention, DC voltage sampling unit figure.

Fig. 9 is switching overvoltage absorptive unit figure of the invention.

Figure 10 is PLC unit figure of the invention.

Figure 11 is bridge arm temperature alarm of the invention, and bridge arm overheats trip unit figure.

Figure 12 is fast fusing alarm of the invention, trip unit figure.

Figure 13 is instrument separator system unit figure of the invention.

Figure 14 is high voltage rectifier stack control system power supply unit figure of the invention.

Figure 15 is charging pile Control system architecture unit figure of the invention.

Figure 16 is charging pile control system principle elements figure of the invention.

Figure 17 is charging pile control system flow chart of the invention.

Figure 18 is intelligent charging spot semibridge system binary channels crisscross parallel charging chopper circuit unit figure of the invention.

Figure 19 is intelligent charging spot dynamic allocation system regulating loop circuit unit figure of the invention.

Figure 20 is high-voltage rectifying transformer (diode) system unit figure of the invention.

Figure 21 is high-voltage rectifying transformer (thyristor) system unit figure of the invention.

Figure 22 is 12 pulse wave rectifier system unit figures of the invention.

Figure 23 is micro-capacitance sensor power supply system block diagram of the invention.

Figure 24 is micro-capacitance sensor controller of the invention.

Figure 25 is microgrid energy power system of the invention.

Figure 26 is micro-capacitance sensor battery management system of the invention.

Figure 27 is tap changer structural schematic diagram of the present invention.

Specific embodiment

As shown, present invention can apply to centralized high-voltage rectifying electric currents to distribute charging heap, centralized high-voltage rectifying electricity Stream distribution charging heap includes high voltage protective unit, high-voltage rectifying transformer unit, high-voltage rectifying unit and charging pile group electric current point With unit, the output port of high voltage protective unit is connected with the input port of high-voltage rectifying transformer unit, high-voltage rectifying transformation The output port of device unit is connected with the input port of high-voltage rectifying unit, the output port and charging pile group of high-voltage rectifying unit The input port of current distribution unit is connected.

Centralization high-voltage rectifying electric current distribution charging heap of the invention is cooperated by each unit, and the peace of charging heap can be improved Full property and reliability, convenient for the distribution of charging current.

The output port of the high-voltage rectifying transformer unit exports 12 pulse wave 840V/1500A pulse voltages.

The middle straightening stream of the output port output 750V/1500A of the high-voltage rectifying unit.

The charging pile group current distribution unit includes multiple charging piles, and each charging pile is in parallel, each charging pile electric energy input End is connected with the output port of high-voltage rectifying unit.

The output port of the high-voltage rectifying unit is connected by closing busbar with charging pile electrical energy inputs.

The high voltage protective unit includes incoming line cabinet, metering cabinet, PT cabinet, house transformer and outgoing line cabinet, incoming line cabinet it is defeated The input of outlet and metering cabinet terminates a bus, the input terminal of the output termination PT cabinet of metering cabinet, the output termination two of PT cabinet Secondary bus, secondary bus are connected with the input terminal of the input terminal of house transformer, outgoing line cabinet respectively, and the output of outgoing line cabinet terminates high The input terminal of voltage adjustment rectifier transformer unit.House transformer can for all devices control power supply and entire charging field illumination and Communication equipment power supply.

The invention also includes the electric energy output ends of micro-capacitance sensor power supply system to be connected with secondary bus.

In the insufficient situation of local network load, the 500KW micro-grid system that system support can be selected carries out load benefit It fills.

The rectifier transformer pair side of the high-voltage rectifying transformer unit uses star, triangle output-parallel structure.Rectification becomes Star and delta connection is respectively adopted in depressor secondary side winding, makes phase shifting between two groups of three-phase alternating-current supplies, size phase Deng, so that output rectified voltage is made to pulse 12 times in each AC mains cycle, the rectification change of high-voltage rectifying transformer unit After depressor secondary winding is respectively connected to T1 and T2 high-voltage rectifier bridge, exported after two groups of direct current outputs are in parallel.

The turn ratio of the rectifier transformer first winding and secondary winding is 1: 1: 3, wherein secondary winding star structure It is 1, delta connection structure 3.

The iron core of the rectifier transformer uses silicon steel sheet 30Q130, is bound using 45 ° of full bias seams without latitude glass tape Structure.Structure modulation flux density < 1.58T of the present invention, it can be ensured that when voltage ripple of power network+5%, iron core not overexcitation；Pressure regulation model Still output rated voltage when enclosing consideration voltage ripple of power network -5%；Whole change flux density < 1.65T.

Micro-capacitance sensor power supply system includes master switch, step-up transformer, first switch, photovoltaic DC-to-AC converter, photovoltaic module, second Switch, blower inverter, wind-driven generator, third switch, energy storage inverter, energy-storage battery, the 4th switch and active electric power filter Wave device, master switch one terminate secondary bus, and the master switch other end is connected with step-up transformer output end, step-up transformer input terminal One end, the 4th switch one end are switched with first switch one end, second switch one end, third respectively to be connected, first switch one end is another One end is connected with the output end of photovoltaic DC-to-AC converter, the output end of the input termination photovoltaic module of photovoltaic DC-to-AC converter；

Second switch one end other end is connected with the output end of blower inverter, and the input terminal of blower inverter is given a dinner for a visitor from afar power generator Output end；

Third switchs one end other end and is connected with the output end of energy storage inverter, and the input of energy storage inverter terminates energy-storage battery；

One end is another is terminated with active power filter for 4th switch.

The high-voltage rectifying transformer unit includes high-pressure side winding, low-pressure side star parallel winding and low-pressure side triangle Parallel winding.

The high-voltage rectifying transformer unit further includes the voltage sensor for detecting low-pressure side voltage, the letter of voltage sensor Number output port is connected with the detection signal input port of controller, the control signal output mouth of controller and adjusts high-pressure side The control signal input mouth of the tap changer of umber of turn is connected.

The present invention uses 7 segmentation tap changers, and the AC energy of power grid is by entering tap changer, pressure regulation after high-voltage switch gear Switch can be operated by tap switch with carrying.The gear of tap changer shows that signal is transmitted to commutation system control cabinet, and energy Receive control cabinet has load boosting, has load to be depressured and have load emergency stop operation signal.Transformation tap is carried out to the primary side of transformer The operation of voltage is adjusted, to guarantee that secondary side exports one compared with stable voltage.When system detection to direct current primary voltage When lower than voltage rating 10%, control system adjust tap changer, by reduce first winding the number of turns, reach improve it is secondary around The purpose of group output voltage.

When the controller detects low-pressure side voltage lower than voltage rating 10%, controller controls tap changer and reduces height Press the number of turns of side winding.

High-pressure side winding includes U phase winding, V phase winding and W phase winding, tap changer group include the first tap changer of U phase, The second tap changer of U phase, the first tap changer of V phase, the second tap changer of V phase, the first tap changer of W phase, the second pressure regulation of W phase are opened It closes,

U phase winding centre cap is U phase input terminal and opens respectively with the first terminals of the first tap changer of W phase, the second pressure regulation of W phase The first terminals are closed to be connected；

V phase winding centre cap is V phase input terminal and opens respectively with the first terminals of the first tap changer of U phase, the second pressure regulation of U phase The first terminals are closed to be connected；

W phase winding centre cap is W phase input terminal and opens respectively with the first terminals of the first tap changer of V phase, the second pressure regulation of V phase The first terminals are closed to be connected；

The second wiring of the first tap changer of U phase terminates U phase winding one end, another the second tap changer of termination U phase second of U phase winding Terminals；

The second wiring of the first tap changer of V phase terminates V phase winding one end, another the second tap changer of termination V phase second of V phase winding Terminals；

The second wiring of the first tap changer of W phase terminates W phase winding one end, another the second tap changer of termination W phase second of W phase winding Terminals.

The low-pressure side star parallel winding includes 2a winding, 2b winding and 2c winding, low-pressure side triangle parallel winding Including 3a winding, 3b winding and 3c winding, 2a winding one end, 2b winding one end, 2c winding one end are connected, the 2a winding other end, The 2b winding other end, the 2c winding other end are electric energy output end；

3a winding one end is electric energy output end and be connected with 3c winding one end, the 3c winding other end be electric energy output end simultaneously and 3b around Group one end is connected, and the 3b winding other end is electric energy output end and is connected with the 3a winding other end.

The high-voltage rectifying unit uses T1 high-voltage rectifier bridge (1) and T2 high-voltage rectifier bridge (2), T1 high-voltage rectifier bridge (1) It is connected with the input terminal of T2 high-voltage rectifier bridge (2) with the output end of high-voltage rectifying transformer unit；

Or pulse wave rectifier circuit is used, the input terminal of pulse wave rectifier circuit is connected with the output end of high-voltage rectifying transformer unit.

The pulse wave rectifier circuit includes diode V7~V12, diode V1~V6, diode V7 anode respectively with 2a around Group electric energy output end, diode V8 cathode be connected, diode V7 cathode respectively with diode V9 cathode, diode V12 cathode, arteries and veins Wave rectification circuit output cathode, diode V1 cathode, diode V3 cathode, diode V5 cathode are connected；

Diode V8 anode respectively with diode V10 anode, diode V11 anode, diode V2 anode, diode V4 anode, Diode V6 anode, pulse wave rectifier circuit output cathode are connected；

Diode V10 cathode is connected with 2b winding electric energy output end, diode V9 anode respectively, diode V11 cathode respectively with 2c winding electric energy output end, diode V12 anode are connected；

Diode V1 anode is connected with 3a winding electric energy output end, diode V2 cathode respectively, diode V3 anode respectively with 3b Winding electric energy output end, diode V4 cathode are connected, and diode V5 anode is negative with 3c winding electric energy output end, diode V6 respectively Extremely it is connected.

Figure 22 pulse wave rectifier circuit, two 30 ° of three-phase thyristor bridge rectification circuit phase shift connections in parallel form pulse wave rectifier Circuit makes between two groups of three-phase alternating-current supplies 30 ° of phase shifting, and output rectified voltage is made to pulse 12 times in a power cycle. T1 and T2 is two groups of rectifier bridges in parallel.

The T1 high-voltage rectifier bridge (1) and T2 high-voltage rectifier bridge (2), T1 high-voltage rectifier bridge (1) includes L, K, J, I, H, G Arm, T2 high-voltage rectifier bridge (2) include F, E, D, C, B, A arm；L, K arm one terminates 2a winding electric energy output end, and another termination of L arm is defeated Outlet cathode, another termination output head anode of K arm；

J, I arm one terminates 2b winding electric energy output end, another termination negative pole of output end of J arm, another termination output head anode of I arm；

H, G arm one terminates 2c winding electric energy output end, another termination negative pole of output end of H arm, another termination output head anode of G arm；

F, E arm one terminates 3a winding electric energy output end, another termination negative pole of output end of F arm, another termination output head anode of E arm；

D, C arm one terminates 3b winding electric energy output end, another termination negative pole of output end of D arm, another termination output head anode of C arm；

B, A arm one terminates 3c winding electric energy output end, another termination negative pole of output end of B arm, another termination output head anode of A arm.

The L arm is composed in series by diode V12-1~2 and fuse FU12-1~2；

K arm is composed in series by diode V11-1~2 and fuse FU11-1~2；

J arm is composed in series by diode V10-1~2 and fuse FU10-1~2；

I arm is composed in series by diode V9-1~2 and fuse FU19-1~2；

H arm is composed in series by diode V8-1~2 and fuse FU8-1~2；

G arm is composed in series by diode V7-1~2 and fuse FU7-1~2；

F arm is composed in series by diode V6-1~2 and fuse FU6-1~2；

E arm is composed in series by diode V5-1~2 and fuse FU5-1~2；

D arm is composed in series by diode V4-1~2 and fuse FU4-1~2；

C arm is composed in series by diode V3-1~2 and fuse FU13-1~2；

B arm is composed in series by diode V2-1~2 and fuse FU2-1~2；

A arm is composed in series by diode V11-1~2 and fuse FU1-1~2.

The high-voltage rectifying unit further include commutation spike absorb Zapping circuit, commutation spike absorb Zapping circuit with The arm of high-voltage rectifier bridge is connected.

It includes resistance R11 that the commutation spike that connect with K arm, which absorbs Zapping circuit, the one end resistance R11 respectively with K arm, two Pole pipe V11-3 anode, diode V11-2 anode, diode V11-1 anode are connected, and the resistance R11 other end passes sequentially through capacitor C11, fuse FU21 connect the end L+, and the signal output end of fuse FU21 connects the detection signal input part of PLC CPU control unit Mouthful；

Diode V11-3 cathode connects the end L+ by fuse FU11-3, and diode V11-2 cathode meets L+ by fuse FU11-2 End, diode V11-31 cathode connect the end L+ by fuse FU11-1；

The fuse FU11-3 signal output end detection signal with the one end resistance R81-3, fast molten fusing alarm trip unit respectively Input port is connected, and resistance R81-3 mono- terminates the detection signal input port of fast fusing alarm trip unit；

The fuse FU11-2 signal output end detection signal with the one end resistance R81-2, fast molten fusing alarm trip unit respectively Input port is connected, and resistance R81-2 mono- terminates the detection signal input port of fast fusing alarm trip unit；

The fuse FU11-1 signal output end detection signal with the one end resistance R81-1, fast molten fusing alarm trip unit respectively Input port is connected, and resistance R81-1 mono- terminates the detection signal input port of fast fusing alarm trip unit.

It includes resistance R1 that the commutation spike that connect with A arm, which absorbs Zapping circuit, the one end resistance R1 respectively with A arm, two poles Pipe V1-3 anode, diode V1-2 anode, diode V1-1 anode are connected, and the resistance R1 other end passes sequentially through capacitor C1, fusing Device FU21 connects the end L+, and the signal output end of fuse FU21 connects the detection signal input port of PLC CPU control unit；

Diode V1-3 cathode connects the end L+ by fuse FU1-3, diode V1-2 cathode by fuse FU1-2 connect the end L+, Diode V1-31 cathode connects the end L+ by fuse FU1-1；

Fuse FU1-3 signal output end is defeated with the detection signal of the one end resistance R71-3, fast fusing alarm trip unit respectively Inbound port is connected, and resistance R71-3 mono- terminates the detection signal input port of fast fusing alarm trip unit；

Fuse FU1-2 signal output end is defeated with the detection signal of the one end resistance R71-2, fast fusing alarm trip unit respectively Inbound port is connected, and resistance R71-2 mono- terminates the detection signal input port of fast fusing alarm trip unit；

Fuse FU1-1 signal output end is defeated with the detection signal of the one end resistance R71-1, fast fusing alarm trip unit respectively Inbound port is connected, and resistance R71-1 mono- terminates the detection signal input port of fast fusing alarm trip unit.

The PLC CPU control unit includes CPU226 A1, and the signal that the end .0 of A1 and 1.4 terminate fuse FU21 is defeated Outlet.

The high-voltage rectifying unit further includes touch screen ethernet module unit.

The high-voltage rectifying unit further includes switching overvoltage absorptive unit, and switching overvoltage absorptive unit includes pressure-sensitive electricity RV1~6 are hindered, varistor RV1 connects 2a winding electric energy output end by fuse FU41, and varistor RV2 passes through fuse FU42 connects 2b winding electric energy output end, and varistor RV3 connects 2c winding electric energy output end by fuse FU43, and fuse 41~ 43 signal output end connects the detection signal input port of fast fusing alarm trip unit, bridge arm temperature alarm bridge arm mistake respectively The detection signal input port of thermal tripping unit, the detection signal input port of PLC CPU control unit are connected；

Varistor RV4 connects 3a winding electric energy output end by fuse FU44, and varistor RV5 meets 3b by fuse FU45 Winding electric energy output end, varistor RV6 connect 3c winding electric energy output end, the signal of fuse 44~46 by fuse FU46 Detection signal input port, the bridge arm temperature alarm bridge arm that output end connects fast fusing alarm trip unit respectively cross thermal tripping list The detection signal input port of member, the detection signal input port of PLC CPU control unit are connected.

The high-voltage rectifying unit further includes overvoltage of direct current absorptive unit, and overvoltage of direct current absorptive unit includes in parallel connects Resistance R31, the R32 and DC voltage sampling module connect, resistance R31 and R32 parallel circuit one end respectively with the end L+, fuse The one end FU53 be connected, the fuse FU53 other end respectively with the one end varistor RV13, resistance R91 and R92 parallel circuit one end It is connected, resistance R91 and R92 the parallel circuit other end is connected with the parallel circuit of capacitor C41~45 one end, and capacitor C41~45 is in parallel The circuit other end is connected with the varistor RV13 other end, the one end fuse FU54 respectively, the fuse FU54 other end respectively with Resistance R31 is connected with the R32 parallel circuit other end, the end L-；The signal output port of fuse FU53 and FU54 are melted with fast respectively The detection signal input of the detection signal input port, bridge arm temperature alarm bridge arm overheat trip unit of fusing alarm trip unit Port, the detection signal input port of PLC CPU control unit are connected；

The high-voltage rectifying unit further includes DC voltage sampling unit, and DC voltage sampling unit includes DC voltage sampling mold The detection input first port of block, DC voltage sampling module is connected by fuse FU55, FU56 with the end L+, the end L-, direct current The detection input second port of voltage sampling module is connected with the end L2+, the end L2-, and the detection signal of DC voltage sampling module is defeated Exit port is connected with the detection signal input port of PLC unit.

The PLC unit uses EM231 A3, and A+, A- foot of A3 connects the detection signal output end of DC voltage sampling module Mouthful.

Bridge arm temperature alarm bridge arm overheat trip unit includes QBBJ04 P2,19 feet of P2 respectively with L arm, J arm, H Arm, F arm, D arm, B arm, the one end switch L105, the one end switch J105, the one end switch H105, the one end switch F105, switch D105 mono- End, the one end switch B105 are connected, and the switch L105 other end, the switch J105 other end, the switch H105 other end, switch F105 are another End, the switch D105 other end, the switch B105 other end are corresponding with 18~13 feet of P2 respectively to be connected；

1~6 foot of P2 respectively with the one end switch A105, the one end switch C105, the one end switch E105, the one end switch G105, switch The one end I105, the one end switch K105 are corresponding connected, and the switch A105 other end, the switch E105 other end, is opened the switch C105 other end It is corresponding with A, C, E, G, I, K arm connected respectively to close the G105 other end, the switch I105 other end, the switch K105 other end, A, C, E, G, I, K arm connect 7 feet of P2；8 feet of P2 connect the end .3 of A1.

The bridge arm temperature alarm bridge arm overheat trip unit includes QBBJ04 P3, and 11,12 feet of P3 are respectively with P2's 11,12 feet are corresponding is connected；

19 feet of P3 respectively with L arm, J arm, H arm, F arm, D arm, B arm, the one end switch L115, the one end switch J115, switch H115 One end, the one end switch F115, the one end switch D115, the one end switch B115 are connected, and the switch L115 other end, switch J115 are another End, the switch H115 other end, the switch F115 other end, the switch D115 other end, the switch B115 other end respectively with the 18 of P3~ 13 feet are corresponding to be connected；

1~6 foot of P3 respectively with the one end switch A115, the one end switch C115, the one end switch E115, the one end switch G115, switch The one end I115, the one end switch K115 are corresponding connected, and the switch A115 other end, the switch E115 other end, is opened the switch C115 other end It is corresponding with A, C, E, G, I, K arm connected respectively to close the G115 other end, the switch I115 other end, the switch K115 other end, A, C, E, G, I, K arm connect 7 feet of P3；8 feet of P3 connect the end .2 of A1.

The fast fusing alarm trip unit includes KRBJO4 P1, and 5 feet of P1 pass through control fuse alarm tripping Relay K14 connects instrument separator system unit, and 6 feet of P1 connect instrument separator system unit, and 3,4 feet of P1 meet PLC CPU Control unit.

The instrument separator system unit includes that direct current part PV1, DC current part PA1, in-cabinet temperature are adopted Collect part, DC current part E1, in-cabinet temperature part E2 and fan section, the input of PV1 terminates DC voltage sampling unit.

In Fig. 6, each foot output of PLC carries out controlling various signals, each intermediate relay by multiple intermediate relay K The contact of device K is marked with terminal number, and each terminal is according to number connected to external hardware (such as: each button, indicator light, air draft Fan etc.).

Autotransducer includes control winding, displacement winding (offset winding), spare winding, Figure 20.DC power supply is defeated The magnetic density for changing autotransducer to one of winding is sent, adjusts AC energy indirectly, reaches the mesh of steady-state adjustment 's.

Have and carry the alternating voltage that tap changer is inputted in the primary-side-control of rectifier transformer, controls in a certain range defeated D. C. value out.There is load tap changer to be used in combination with the saturable reactor being connected in rectifier output circuit.By DC current is introduced in reactor, makes to generate a variable impedance in route.It is defeated by controlling the voltage drop at reactor both ends Value can control in narrow range out.

The high-voltage rectifying unit further includes high voltage rectifier stack control system power supply unit, high voltage rectifier stack control system electricity Source unit includes PLC touch screen working power part, PLC DI power unit, isolator instrument power part, probe power Partially, alarm power unit, voltage sample isolator power unit, control power failure part, PLC touch screen working power Partially, PLC DI power unit, isolator instrument power part, probe power part, alarm power unit, voltage sample The input terminal of isolator power unit is connected with the end L1+, L1-.

The charging pile includes charging pile control system, charging pile control system include controller, semibridge system chopper circuit, Sensing module, optical coupling isolation circuit, photoelectrical coupler and charging gun electronic lock, the detection signal input port of controller respectively with The signal transmission port of input power, controller is defeated with the control signal of power output contactor respectively by optical coupling isolation circuit Inbound port, the control signal input mouth of indicator light, the control signal input mouth of charging gun electronic lock, the user of charging gun are logical Casually, the signal transmission port of touch screen is connected；

The detection signal input port of controller switchs tube temperature with detection semibridge system chopper circuit respectively by photoelectrical coupler The signal output port of the temperature sensor of degree, the signal output port of the temperature sensor of detection charging gun temperature, CC1 control The detection signal output port of voltage detecting circuit is connected；

The control signal output mouth of controller is connected with the control signal input mouth of semibridge system chopper circuit.

The charging pile control system further includes logic combination circuit, the input terminal acquisition control system of logic combination circuit Power failure information, charging gun electronic lock feedback information, contacts of contactor information, electric leakage information, emergency stop information, Insulation monitoring electricity Road information, panel-switch information, indicator light information and latch feedback information, and according to failure priority, control each information security Alarm signal.

The logic combination circuit uses STM32F03 single-chip microcontroller.

It is defeated that the controller passes sequentially through SG3525 chip, Fiber isolation circuit and the control signal of semibridge system chopper circuit Inbound port is connected.

The charging pile control system further includes semibridge system chopper circuit short-circuit alarming circuit.

The semibridge system chopper circuit short-circuit alarming circuit is using the insulating monitoring connect in semibridge system chopper circuit output end Device.

The semibridge system chopper circuit includes IGBT S1~S4, the gate pole of IGBT S1~S4 respectively with the control of controller Signal output port is connected, and the source electrode of S1 is connected with the drain electrode of S2, the one end inductance L2 respectively, and the drain electrode of S1 is cut with semibridge system respectively Wave circuit electrical energy inputs anode, the one end capacitor C1, S3 drain electrode be connected, the capacitor C1 other end respectively with semibridge system chopper circuit Electrical energy inputs cathode, the source electrode of S2, the source electrode of S4, the one end capacitor C2, semibridge system chopper circuit electric energy output end cathode are connected, The capacitor C2 other end is connected with the inductance L2 other end, semibridge system chopper circuit electric energy output end anode, the one end inductance L1 respectively, electricity The sense L1 other end is connected with the drain electrode of the source electrode of S3, S4 respectively.

Figure 18, the switching tube driving signal of each bridge arm is limited by constant output voltage and is exported in each multichannel copped wave module The Double-closed-loop control circuit of electric current generates, which includes voltage PI adjuster, electric current PI adjuster, moves Phase device and m carrier wave, which are handed over, cuts comparator, and m carrier wave hands over the m bridge arm cut in comparator and the multichannel copped wave module It corresponds, the positive input terminal input reference voltage of voltage PI adjuster, the negative input end input of voltage PI adjuster should The output voltage of multichannel copped wave module, the positive input terminal of the output end connection electric current PI adjuster of voltage PI adjuster, The negative input end of electric current PI adjuster inputs the output electric current of the multichannel copped wave module, the output end of electric current PI adjuster M carrier wave of connection hands over the positive input terminal for cutting comparator, and phase shifter exports m phase successively staggeredly 2 π/m carrier signal The negative input end for cutting comparator is handed over to m carrier wave, each carrier wave hands over the switching tube for cutting the corresponding bridge arm of comparator output to drive letter Number.

Uin is the DC voltage that transformer rectifying part provides, and C1 is input filter capacitor, S1, S2, L2 composition one and half Bridge power topology, S3, S4, L2 form another half-bridge power topology, and C2 is output filter capacitor, and IL is inductive current sampling (average value is equivalent to charging current), Uo are charging output voltage.G1-g4 corresponds to the driving signal of S1-S4, passes through g1-g4's The constant current voltage limiting control of charge power supply is realized in pulsewidth modulation.

Figure 19, including intelligent charging spot dynamic allocation system regulating loop, charging voltage gives Uref and charging current is given Determine a reference value of charging voltage and electric current that Iref is setting, it is charge power supply that output voltage, which samples Uo and inductive current sampling IL, Controlled volume.The modulating wave obtained by voltage regulator and current regulator, with two staggeredly 180 ° triangular carrier carry out Carrier wave, which is handed over, to be cut, and driving signal g1-g4, the final stability contorting for realizing charge power supply are generated.Wherein, g1/g2 and g3/g4 difference is mutual Mend work.

The sensing module includes the voltage sensor for detecting input voltage, the voltage sensor for detecting output voltage, inspection Survey the current sensor of input current, the current sensor of detection output electric current, the voltage sensor for detecting vehicle battery voltage.

The controller uses STM32F103 chip, the end ADC of STM32F103 chip respectively with detection input voltage The detection signal output port of voltage sensor, the detection signal output port of the voltage sensor of detection output voltage, detection The detection signal output of the detection signal output port, the current sensor of detection output electric current of the current sensor of input current Port, the detection signal output port for the voltage sensor for detecting vehicle battery voltage are connected.

The charging pile control system further includes temperature-compensation circuit

The photoelectrical coupler uses HCNR201 module.

The charging pile control system further includes accessory power supply, the signal biography of accessory power supply signal transmission port and controller Defeated port is connected, and the power output port of accessory power supply is connected by contactor KM5 with the auxiliary electric energy input port of charger, The control signal input mouth of contactor KM5 is connected with the control signal output mouth of controller.

The accessory power supply uses digital switch power supply.

The accessory power supply passes sequentially through discharge module, air switch QF2 and AC/380V phase by residual current operated protective device Even.

The semibridge system chopper circuit electrical energy inputs anode respectively with the one end resistance R1, contactor KM2 first is normally opened opens Close one end be connected, the first normal open switch of contactor KM2 other end respectively with the first normal open switch of contactor KM1 one end, fuse The one end FU1 is connected, another terminating resistor R1 other end of the first normal open switch of contactor KM1；The fuse FU1 other end respectively with change Resistance one end device RV1, air switch QF1 first switch one end, the one end Surge Protector SPD1 are connected, and air switch QF1 first is opened Close another termination DC/840V, Surge Protector SPD1 other end ground connection；The rheostat RV1 other end respectively with fuse FU2 mono- End, air switch QF1 second switch one end, the one end Surge Protector SPD2 are connected, Surge Protector SPD2 other end ground connection, empty Another termination DC/840V of air cock QF1 second switch；The fuse FU2 other end respectively with the second normal open switch of contactor KM1 one End, the second normal open switch one end contactor KM2 are connected, and contactor KM1 the second normal open switch other end and contactor KM2 second are normal Switch the other end, semibridge system chopper circuit electrical energy inputs cathode is connected.

Contact switch KV and the detection of charging gun return being mounted on the invention also includes monitoring device door state on machine box door The detection signal output port of contact switch Kl, KV and Kl are connected with the detection signal input port of controller.

The semibridge system chopper circuit electric energy output end anode respectively with contactor KM3 normal open switch one end, varistor The one end RV2, insulated monitor LMD positive terminal, the first normal open switch one end contactor KM4 are connected, and contactor KM3 normal open switch is another One end by resistance R3 respectively with semibridge system chopper circuit electric energy output end cathode, the varistor RV2 other end, insulated monitor LMD negative pole end, the second normal open switch one end contactor KM4 are connected, the control signal input mouth of contactor KM4 and controller The defeated place port of signal is controlled to be connected；

Contactor KM4 the first normal open switch other end is connected with voltmeter positive terminal, charging gun positive terminal respectively, contactor KM4 The second normal open switch other end is connected with voltmeter negative pole end, charging gun negative pole end respectively, the detection signal output end of voltmeter Mouth is connected with the detection signal input port of controller.

The charge step of the charging pile is successively are as follows: precharge, connection confirmation, self-test stage, configuration phase, charging stage And ending phase.

Connect verification step successively are as follows: controller is powered to preliminary filling rifle electronic lock, and it is anti-that controller detects preliminary filling rifle electronic lock Feedback signal, controller detect CC1 signal；

Self-test stage etch is successively are as follows: closure contactor KM3, detection insulating monitoring signal, leadage circuit；

Configuration phase step is successively are as follows: charging pile controller and vehicle control device carry out handshake message, closure contactor KM4；

Charging stage step is successively are as follows: charging pile controller and vehicle control device carry out communication packet；Charging pile controller is adjusted The voltage and current of semibridge system chopper circuit power output；Judge whether charge rest, if not recharge stage etch, if into Enter ending phase；

Ending phase step is successively are as follows: charging pile controller and vehicle control device carry out charge rest message, disconnect contactor KM4, leadage circuit, disconnect contactor KM3, unlock charging gun electronic lock, detection charging gun whether return.

The leadage circuit is to bleed off the charge stored on semibridge system chopper circuit output filter capacitor quickly, makes capacitor Voltage on device reduces immediately, and by varistor RV2, the charge stored on filter capacitor is bled off quickly.

The detection charging gun whether the mode of return are as follows: by K1 test point, when charging gun, which is extracted, to charge, K1 is normally closed Become normally opened, K1 is normally opened when charging gun return becomes normally closed.

The mode for judging whether charge rest are as follows: by the preset charging modes of user by electricity, by the amount of money Or it is full of, the charging pile charge rest when reaching setting condition.

The charging pile controller storage Vehicular battery model, characteristic and charging curve mathematical model, work as vehicle control device When communicating with charging pile controller, charging pile controller reads the battery information of the vehicle, and charging pile controller is according to the electricity of the vehicle Pond information, recalls and the matched mathematical model of vehicle battery behavior, provides charging current and voltage.

The switching tube driving signal of each bridge arm of semibridge system chopper circuit limits output electric current by constant output voltage Double-closed-loop control circuit generate, the Double-closed-loop control circuit include voltage PI adjuster, electric current PI adjuster, phase shifter with And m carrier wave is handed over and cuts comparator, m carrier wave hands over the m bridge arm one cut in comparator and the multichannel copped wave module a pair of It answers, the negative input end of the positive input terminal input reference voltage of voltage PI adjuster, voltage PI adjuster inputs the multichannel The output voltage of copped wave module, the positive input terminal of the output end connection electric current PI adjuster of voltage PI adjuster, electric current PI The negative input end of adjuster inputs the output electric current of the multichannel copped wave module, and the output end of electric current PI adjuster connects m A carrier wave hands over the positive input terminal for cutting comparator, and phase shifter exports m phase and successively interlocks 2 π/m carrier signal to m Carrier wave hands over the negative input end for cutting comparator, and each carrier wave, which is handed over, cuts the switching tube driving signal that comparator exports corresponding bridge arm.

The control signal output mouth of the controller passes sequentially through low pressure and adjusts part, constant current clipped portion, electric current tune Section device is handed over first carrier cut comparator positive input terminal respectively, the second carrier wave hands over a section comparator positive input terminal to be connected, first carrier Hand over a section comparator negative input end, the second carrier wave that a section comparator negative input end is handed over to be connected respectively with the output end of phase-shifting carrier wave part, The input terminal of phase-shifting carrier wave part is connected with the output end of carrier wave generating portion, the control signal input of carrier wave generating portion with The control signal output mouth of controller is connected；

First carrier hands over a section comparator output terminal to be connected respectively with the gate pole of S1, the first input terminal for negating circuit, and first negates The gate pole of the output termination S2 of circuit；Second carrier wave hands over a section comparator output terminal to negate circuit with the gate pole of S3, second respectively Input terminal is connected, and second negates the gate pole of the output termination S4 of circuit；

Detection of the detection signal input port of controller respectively with the sensor of detection semibridge system chopper circuit output voltage is believed Number output port, detection semibridge system chopper circuit output the signal output port of sensor be connected.

The invention also includes unit microcomputer protection monitor part, transformer cooling system, rectification cooling system, detection rectifications The direct current transducer of transformer output current voltage, direct current banister S1~S4, PLC signal transmission port protected respectively with group microcomputer Protect the signal transmission port, the signal transmission port of transformer cooling system, the signal transmission for rectifying cooling system of monitor portion Port, the signal transmission port of direct current transducer, the signal transmission port of direct current banister are connected.

The invention also includes PWM drive part, the control signal input mouth of PWM drive part and the control signal of PLC Output port is connected, the control signal output mouth of PWM drive part control signal input mouth, the B with the control section A respectively The control signal input mouth of control section is connected.

The control section A and the control section B include the displacement that reactor is arrived to reactor control winding and one Winding, DC power supply are delivered to one of winding, change the magnetic density of autotransducer, adjust AC energy indirectly；A TA1 is controlled, B controls TA2；TA1, TA2 respectively correspond secondary winding star structure part and delta connection structure division.

The control section A is connect with transformer TA1 output end reactor, the control section B and transformer TA2 output end electricity Anti- device connection.

The invention also includes A phase shift diode and B phase shift diode, A phase shift diode and TA1 reactor are displaced winding terminal Mouth connection, B phase shift diode and transformer TA2 reactor displacement winding port connect.

The invention also includes control conversion section, control conversion section detects the work of direct current major loop by direct current transducer Whether normal make voltage, such as off-rating ± 10%, control system will issue instructions to tap changer and be adjusted.

The rectification cooling system includes the temperature sensor and rectification part cooling fan for detecting rectification part, and temperature passes The detection signal output port of sensor is connected with the detection signal input port of PLC, the control signal output mouth of PLC and rectification The control signal input mouth of component cooling fan is connected.

The transformer cooling system includes the temperature sensor and fan for cooling transformer for detecting transformer operating temperature, The detection signal output port of temperature sensor is connected with the detection signal input port of PLC, the control signal output mouth of PLC It is connected with the control signal input mouth of fan for cooling transformer.

Described group of microcomputer protection monitor part uses single-chip microcontroller, and the detection signal input port of single-chip microcontroller is pressed off with height respectively Close the detection signal output port of cabinet detection part, detection signal output port, the transformer of on-load voltage regulating switch detection part Detection signal output port, the detection signal output port of commutation system temperature detection part, the direct current of temperature detection part return The detection signal output port of the detection part on road.

The invention also includes exchange intelligent collector, the signal input port for exchanging intelligent collector is connected with TA1, TA2 Detection signal output port be connected with the signal input port of exchange conversion part,

Exchange the signal output port of intelligent collector respectively with the signal input port of the first synchronization detecting section, second synchronous The signal input port of detection part is connected, the signal input part of the signal output port of the first synchronous test section and the first MCU Mouth is connected, and the signal output port of the second synchronous test section is connected with the signal input port of the 2nd MCU, the control of the first MCU Signal output port is connected with the control signal input mouth of the first pulse amplifier part, the control letter of the first pulse amplifier part Number output port is connected with the gate pole of the first thyristor of control tap changer；

The control signal output mouth of 2nd MCU is connected with the control signal input mouth of the second pulse amplifier part, the second arteries and veins The control signal output mouth for rushing power amplifier part is connected with the second gate circuit transistor gate of control tap changer；First thyristor cathode The end L+ is connect by switch QS2, the first thyristor anode is connected with the second thyristor cathode, and the second thyristor anode passes through switch QS3 connects the end L-.

The invention also includes first passage monitoring, second monitor portion, the first LCD to show that keyboard portion, the 2nd LCD are aobvious Show keyboard portion, the first communication interface part, the second communication interface part, the first A/D variable part, the 2nd A/D variable part, The part first switch amount I/O, the part second switch amount I/O, the first MCU are shown with first passage monitor portion, the first LCD respectively Keyboard portion, the first communication interface part, the first A/D variable part, the part first switch amount I/O are connected；

2nd MCU shows keyboard portion, the second communication interface part, the 2nd A/ with second channel monitor portion, the 2nd LCD respectively D variable part, the part second switch amount I/O are connected；

First communication interface part, the second communication interface part are connected with machine set PLC monitor portion respectively；First A/D variable portion Point, the 2nd A/D variable part respectively with the turn on thyristors rate control unit phase on exchange conversion part, the first thyristor cathode Even；

TA1, TA2 respectively correspond secondary winding star structure part and delta connection structure division.

First pulse amplifier part and the second pulse amplifier part use signal amplifier.

The exchange conversion part uses A/D variable module.Exchange conversion part acquires AC signal and direct current major loop Signal.

The synchronism of synchronization detecting section detection commutation system.

In Figure 21, TV is voltage transformer, detects busbar voltage.Channel monitoring include external switch amount, analog quantity detection, Forceful electric power source voltage detecting, pulse detection monitoring, two-node cluster hot backup channel monitoring.

The system that controller is made of digital processing unit, synchronization signal enter processor (MCU) by transformation, pulse letter It number is exported by processor, the phase sequence of trigger pulse can be set in LCD touch display screen.

Synchronous detection: detecting power grid PT three-phase synchronous signal, in number control device starting work, is guaranteeing to synchronize Under the frequency signal distortion factor, just start digital triggering pulse, otherwise issues lock-out signal.

Pulse amplifier: the pulse wave signal of output high-power in bandwidth range carries out power setting, gain adjustment, determines When test.

Channel monitoring: monitoring pulse transmittance process and pulse amplifier tubulose state.To controller Working Status Monitoring, issue Channels operation normal state signal.When the work of service aisle digital control implement is abnormal or has internal fault, channel failure letter is issued Number, start alternate channel.

Triggering power supply: to pulse amplifier output be monitored, when voltage fluctuation or be lower than an amplitude when, issue lose triggering electricity The alarm of source status fault, pulse blocking are simultaneously stopped status signal working properly.

Exchange conversion: being the voltage for mutual inductor being collected power grid, current signal, by being transformed into A/D variable module institute After the signal format needed, it is input to A/D transformer module.

When transformer secondary voltage is lower than rated value, there is load to adjust to upper end, reduce the first winding of transformer, thus Achieve the purpose that improve voltage.When transformer secondary voltage is higher than rated value, there is load to adjust to lower end, increase the one of transformer Secondary winding, to achieve the purpose that reduce voltage.

The micro-capacitance sensor power supply system includes micro-capacitance sensor controller, micro-capacitance sensor controller signals transmission port respectively with photovoltaic Signal transmission port, the signal transmission port of Active Power Filter-APF, the signal transmission port of energy storage inverter, wind of inverter Signal transmission port, the signal transmission port of microgrid energy power system of machine inverter are connected,

The microgrid energy power system uses computer.

The micro-capacitance sensor controller includes MCU, DSP, and the signal transmission port of MCU is connected with the signal transmission port of DSP, The control signal output mouth of MCU is connected with the input port of the first IPM module, the output port and DC/DC of the first IPM module The control port of module is connected, and the input port of DC/DC module is connected with photovoltaic module, the output port of DC/DC module and the The input port of one AC/DC module is connected；

The control signal input parallel port of first AC/DC module is connected with the output port of the 2nd IPM module, the 2nd IPM module Input port connect dsp control signal output port, dsp control signal output port connects the control signal of two-way AC/DC module Input port be connected, two-way AC/DC module respectively with battery group, the output port of the first AC/DC module, first contactor one End is connected, the signal input port and the signal output port phase of photovoltaic power generation, wind-power electricity generation load condition sampling module of DSP Even；

The control signal input mouth of first contactor is connected by relay with the control signal output mouth of DSP, and first connects The tentaculum other end is connected with the input terminal of AC load, the 2nd AC/DC module respectively, and the output termination of the 2nd AC/DC module is straight Current load, AC load are given a dinner for a visitor from afar power generator by second contactor, the control signal input mouth of second contactor by after Electric appliance connects the control signal output mouth of DSP.

The microgrid energy power system includes data Layer, management level and dispatch layer, and data Layer sends out each generator unit Electrical power and the real-time dynamic acquisition of variation for loading realtime power, acquisition data are sent to management level and do data analysis and optimization, then The distribution of each unit is carried out by dispatch layer.

Data Layer of the present invention includes information collection part, data management part, status predication part, energy rate prediction section Divide, Network topology part；Management level include load switching part, system administration part, energy storage administrative section, Load flow calculation Partially, idle work optimization part, economic optimization part；Dispatch layer include generating set scheduling portion, energy storage management of charging and discharging part, Load management and scheduling portion.

Microgrid energy power cell Figure 25 energy work rate system of the present invention is by data acquisition, system administration And electricity consumption scheduling composition.Data acquisition mainly to each generator unit generated output and loads the variation realization of realtime power in real time Dynamic acquisition, acquisition data are sent to system management layer and do data analysis and optimization, then carry out each unit by system call layer Distribution, to the full extent guarantee micro-grid system be in optimal economical operation

Figure 24, sampling module sample photovoltaic power generation, wind-power electricity generation and loading condition, send to DSP, by preset excellent First grade carries out photovoltaic and wind-powered electricity generation switching, and since generated output and bearing power are larger, DSP drives contact by control relay Device.MCU pass through and DSP embedded scm cross complaint by IPM module (intelligent power module) to photovoltaic power generation direct current output into Row control.

The invention also includes micro-capacitance sensor battery management system, micro-capacitance sensor battery management system includes host module, slave mould Block, protection plate module, display module；

Slave module and host module measurement cell voltage and temperature, balancing battery energy；Plate module is protected to carry out SOC meter It calculates, SOH is calculated, generates alert data；The charge and discharge of host module control protection board count battery pack information, to being System state is detected, is controlled system mode；Display module shows the data of battery, provides sound-light alarm, record number According to.

Battery management system provides cell voltage monitoring and alarm, and battery pack temperature monitoring and alarm, battery capacity are balanced. Battery management system is responsible for monitoring each group series-connected cell unit, different according to battery composition mode, and monitored battery unit can be with It is a high capacity cell monomer, is also possible to the assembly of multiple Small And Medium Capacity battery parallel connections.Figure 26, main control module pass through 485 bus interface are communicated with acquisition module, and BMS formulates battery by the real-time collection analysis to battery pack data, dynamic Management strategy controls battery work in suitable work by means such as balanced management, Charge Management, electric discharge management, border controls Condition.System has external interface abundant, can satisfy the application demand of a variety of occasions, these interfaces include: that voltage acquisition is defeated Incoming interface, temperature acquisition input interface, host communication interface, slave communicate, select to switch from host address；Protection board has electric current Sensor interface, temperature sensor interface, battery electrode interface, communication interface.

It is understood that being merely to illustrate the present invention above with respect to specific descriptions of the invention and being not limited to this Technical solution described in inventive embodiments, those skilled in the art should understand that, still the present invention can be carried out Modification or equivalent replacement, to reach identical technical effect；As long as meet use needs, all protection scope of the present invention it It is interior.

Claims (7)

1. micro-capacitance sensor power supply system, including master switch, step-up transformer, first switch, photovoltaic DC-to-AC converter, photovoltaic module, second Switch, blower inverter, wind-driven generator, third switch, energy storage inverter, energy-storage battery, the 4th switch and active electric power filter Wave device, it is characterised in that master switch one terminates secondary bus, and the master switch other end is connected with step-up transformer output end, and boosting becomes Depressor input terminal switchs one end, the 4th switch one end with first switch one end, second switch one end, third respectively and is connected, and first Switch one end other end is connected with the output end of photovoltaic DC-to-AC converter, the output end of the input termination photovoltaic module of photovoltaic DC-to-AC converter；

Second switch one end other end is connected with the output end of blower inverter, and the input terminal of blower inverter is given a dinner for a visitor from afar power generator Output end；

Third switchs one end other end and is connected with the output end of energy storage inverter, and the input of energy storage inverter terminates energy-storage battery；

One end is another is terminated with active power filter for 4th switch.

2. micro-capacitance sensor power supply system according to claim 1, it is characterised in that further include micro-capacitance sensor controller, micro-capacitance sensor control Device signal transmission port respectively with the signal transmission port of photovoltaic DC-to-AC converter, the signal transmission port of Active Power Filter-APF, storage The signal transmission of the energy signal transmission port of inverter, the signal transmission port of blower inverter, microgrid energy power system Port is connected.

3. micro-capacitance sensor power supply system according to claim 2, it is characterised in that the microgrid energy power system is using meter Calculation machine.

4. micro-capacitance sensor power supply system according to claim 2, it is characterised in that the micro-capacitance sensor controller includes MCU, DSP, The signal transmission port of MCU is connected with the signal transmission port of DSP, the control signal output mouth of MCU and firstIPM module's Input port is connected, and firstIPM moduleOutput port be connected with the control port of DC/DC module, the input terminal of DC/DC module Mouth is connected with photovoltaic module, and the output port of DC/DC module is connected with the input port of the first AC/DC module；

The control signal input parallel port and second of first AC/DC moduleIPM moduleOutput port be connected, secondIPM module Input port connect dsp control signal output port, dsp control signal output port connects the control signal of two-way AC/DC module Input port be connected, two-way AC/DC module respectively with battery group, the output port of the first AC/DC module, first contactor one End is connected, the signal input port and the signal output port phase of photovoltaic power generation, wind-power electricity generation load condition sampling module of DSP Even；

The control signal input mouth of first contactor is connected by relay with the control signal output mouth of DSP, and first connects The tentaculum other end is connected with the input terminal of AC load, the 2nd AC/DC module respectively, and the output termination of the 2nd AC/DC module is straight Current load, AC load are given a dinner for a visitor from afar power generator by second contactor, the control signal input mouth of second contactor by after Electric appliance connects the control signal output mouth of DSP.

5. micro-capacitance sensor power supply system according to claim 2, it is characterised in that the microgrid energy power system includes number According to layer, management level and dispatch layer, data Layer dynamically adopts the variation of each generator unit generated output and load realtime power in real time Collection, acquisition data are sent to management level and do data analysis and optimization, then the distribution of each unit is carried out by dispatch layer.

6. micro-capacitance sensor power supply system according to claim 5, it is characterised in that the data Layer includes information collection part, number According to administrative section, status predication part, energy rate predicted portions, Network topology part；Management level include load switching part, System administration part, energy storage administrative section, Load flow calculation part, idle work optimization part, economic optimization part；Dispatch layer includes hair Motor group scheduling part, energy storage management of charging and discharging part, load management and scheduling portion.

7. micro-capacitance sensor power supply system according to claim 1, it is characterised in that further include micro-capacitance sensor battery management system, micro- electricity Net battery management system includes host module, slave module, protection plate module, display module；

Slave module and host module measurement cell voltage and temperature, balancing battery energy；Plate module is protected to carry out SOC meter It calculates, SOH is calculated, generates alert data；The charge and discharge of host module control protection board count battery pack information, to being System state is detected, is controlled system mode；Display module shows the data of battery, provides sound-light alarm, record number According to.