CN102624024A - Micro-power consumption clean energy storage system - Google Patents
Micro-power consumption clean energy storage system Download PDFInfo
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- CN102624024A CN102624024A CN2011101795572A CN201110179557A CN102624024A CN 102624024 A CN102624024 A CN 102624024A CN 2011101795572 A CN2011101795572 A CN 2011101795572A CN 201110179557 A CN201110179557 A CN 201110179557A CN 102624024 A CN102624024 A CN 102624024A
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Abstract
The invention discloses a micro-power consumption clean energy storage system, which comprises a direct current/direct current (DC/DC) power converter, an alternating current/direct current (AC/DC) power converter and a DC/AC power converter. Each converter adopts a micro-power consumption power electronic conversion technology, and the high-quality and high-efficiency storage and grid connection of clean energy are realized. The micro-power consumption clean energy storage system is mainly characterized in that: all output power can be obtained only by performing power conversion on an extremely small part of input power, namely a majority of the input power does not require actual power conversion, also is not required to be transmitted through a magnetic core transformer or an inductor, and directly reaches an output end to serve as the output power; and all the devices work at power frequency, and electromagnetic interference (EMI) is avoided. Therefore, the micro-power consumption clean energy storage system is quite low in power consumption, quite long in service life, safe, reliable, energy-saving and environment-friendly, the distortion of output sinusoidal waves is avoided, and the cost, size, weight and power consumption of the micro-power consumption clean energy storage system are one tenth of those of the conventional energy storage system.
Description
Technical field
The present invention relates to a kind of little power consumption clean energy resource storage system.
Background technology
In the tradition energy storing system, DC/DC, AC/DC, three kinds of power inverters of DC/AC all adopt the PWM pulse modulation technology, no matter are the acquisitions of electric energy storage side charge power; Still electric energy discharges the acquisition of the power that is incorporated into the power networks of side, all adopts the PWM pulse-width modulation, and circuit topography has bridge-type, semibridge system, push-pull type, positive activation type, inverse-excitation type or the like; Also have circuit forms such as Boost, Buck, Cuk; Its method of work is, at first all is transformed into high frequency square wave to input direct voltage, uses big capacitor filtering then; Become another kind of direct current or alternating voltage, this method has following defect:
1) method of employing pulse-width modulation, the production process of high-frequency, high-power square wave, just strong EMI disturbs the process that produces, and the high power DC converter is equivalent to a high frequency power transmitting station, can infer, and the interference that is produced is what serious.
2) in the power conversion process, the whole of input power must carry out actual Power Conversion, and the power of all conversion must could arrive output through core transformers or inductance transmission, and loss is big, and efficient is low.
Fig. 1 is a traditional energy storage system block diagram; Both sides power total losses are near 30%, for clean energy resource, such as photovoltaic generation; Its efficient is original just very low; Not at all easyly spend big cost to be transformed into electric energy to solar energy, but let the power inverter of electric energy storage system both sides waste so many, unfortunately tangible.
Adopt the PWM pulse-width modulation, with core transformers or inductance transmitted power, electrical network produced strong the pollution be all power inverters of its main characteristic; Be referred to as conventional power converters; Correspondingly with conventional power converters be, little power consumption power inverter, or claim the green power converter; What little power consumption power inverter adopted is little power consumption Technics of Power Electronic Conversion technology; Little power consumption Technics of Power Electronic Conversion technology is a very strict definition, the most importantly loss during Power Conversion, and that yes is very little, very little and near zero for little implication.Adopt the PWM pulse modulation technology to carry out the conventional power converters of Power Conversion; There are two kinds of power losss at least: the one, device is saturated, end quiescent dissipation into; The 2nd, the dynamic loss of high-frequency process, there is a fixing ratio in these two kinds of power losss with the input gross power.For example the loss of core transformers or inductance transmitted power is 2%, and the direct current loss of rectifier bridge is 1.2%, in the conventional power conversion; These two kinds of losses are definitely bound, even if do not consider other losses, calculate according to the ratio of input gross power; The requirement of all not very little and little power consumption of its power loss is relatively claimed not on very little, very little or near zero certainly; So; Conventional power converters on the ordinary meaning, even if adopt soft switch technique, that also all can not little at last power consumption Technics of Power Electronic Conversion technology.In fact, the dynamic loss that soft switch technique has reduced in the device high-frequency process is not false, and but then, the main switch in the soft switch circuit has auxiliary switch, and that auxiliary switch all gets is saturated, end, so device quiescent dissipation saturated, that end has increased by one times.
Summary of the invention
Fig. 1 is the theory diagram of little power consumption clean energy resource storage system; Partly form by three: little power consumption inversion of little power consumption charging of charged side, storage battery, the side that is incorporated into the power networks; Little power consumption charging comprises: the direct current stabilizer of generation constant current constant voltage, power factor corrector, harmless charging etc., little power consumption inversion comprises: single-phase or three-phase inverter.
Little power consumption clean energy resource storage system comprises DC/DC, AC/DC, three kinds of power inverters of DC/AC, and little power consumption Technics of Power Electronic Conversion technology is all adopted in every kind of conversion, has realized high-quality, the high efficiency storage of clean energy resource and is incorporated into the power networks; The maximum characteristics of this little power consumption clean energy resource storage system are as long as carry out Power Conversion to very small portion in the input power, just can obtain whole power outputs; Be greatly partly both to have carried out actual Power Conversion in the input power, also needn't pass through core transformers or inductance transmission, directly arrive output; Become power output, device all is operated in power frequency, does not produce EMI and disturbs; Therefore power consumption is minimum and the life-span is extremely long, and sine wave output is undistorted, and is safe and reliable; Energy-conserving and environment-protective, cost, volume, weight, power consumption all are 1/10th of traditional energy storing systems.
Little power consumption Technics of Power Electronic Conversion technology is to have the loss of fixed proportion to reduce to minimum with the input gross power, as long as carry out Power Conversion to very small portion in the input power; Just can obtain whole power outputs, promptly greatly partly both needn't carry out actual Power Conversion in the input power, also needn't pass through core transformers or inductance transmission; Directly arrive output, become power output, device all is operated in power frequency; Do not produce EMI and disturb, so power consumption is minimum and the life-span is extremely long.All power losss here; Only relevant with the input power of very small portion; And irrelevant with the input gross power, for example slippages of saturated, the quiescent dissipation, the loss of HF switch DYNAMIC PROCESS, core transformers or the inductance that end of power device or the like is all only relevant with the very small portion input power; Exhausted most input power directly arrives output, becomes power output.
In charged side, can accept alternating voltage from electrical network paddy electricity, wind power generation, also can accept from solar power generation; The direct voltage of tidal power generation, geothermal power generation for alternating voltage, at first will carry out power factor correction; For direct voltage, obtain constant current, constant voltage charge power; In the side that is incorporated into the power networks, carry out single-phase or three-phase inversion,, be connected to the grid then to exchanging by DC converting, storage battery can be lithium ion power storage battery, the horizontal storage battery of thousand nets, common lead acid accumulator, other types storage battery.
Little power consumption charging can be accepted alternating voltage, also can accept direct voltage; If input ac voltage, if admission rate factor correcting device is input direct voltage; Get into direct current stabilizer; Produce constant-current constant-voltage charging power, what no matter import is alternating voltage or direct voltage, all adopts harmless charging modes; In the side that is incorporated into the power networks, for single phase alternating current (A.C.) output, a single-phase DC inverter is arranged, for three-phase alternating current output, a three-phase dc inverter is arranged.
Little power consumption clean energy resource storage system partly is in series by little power consumption charging part, storage battery, little power consumption inversion successively.Little power consumption charging partly is in series by direct current stabilizer, power factor corrector, harmless charger successively.Little power consumption inversion partly is made up of single-phase or three-phase dc inverter.
Power factor corrector is by FET Q1, Q2, inductance L 1, and capacitor C 1 is formed; The drain electrode of FET Q1 connects the positive pole of capacitor C 1, and its source electrode connects the drain electrode of FET Q2, the source ground of FET Q2; The source electrode of inductance L 1 one termination FET Q1, the negative pole of a termination capacitor C1, the negative pole of capacitor C 1 constitutes end points Vi; Input voltage is connected between Vi and the ground, and output voltage V o is by the positive pole output of capacitor C 1; FET Q1 can use a diode D1 to replace, and the negative electrode of diode D1 connects the positive pole of capacitor C 1, and its anode connects the drain electrode of FET Q2.
Direct-flow inverter is made up of a voltage cutting circuit and a N rank capacitance network, the input of the output termination voltage cutting circuit of N rank capacitance network.The voltage cutting circuit is made up of FET Q9, Q12; Their source electrode is connected together; Through resistance R 1 ground connection, capacitor C 8 and resistance R 1 parallel connection, the drain electrode of FET Q9 connects the positive pole of capacitance network; The drain electrode of FET Q12 connects the negative pole of capacitance network, and the drive signal V12 of FET Q9, Q12 is the sine wave signal of amplitude 310V.N rank capacitance network is made up of positive and negative both arms:
The positive arm of capacitance network is made up of capacitor C 1, C3, C5, C7 and FET Q3, Q6, Q8, Q11; The positive pole of capacitor C 1 connects the source electrode of FET Q3, and the drain electrode of FET Q3 connects the negative electrode of diode D1, and the positive pole of capacitor C 3 connects the source electrode of FET Q6; The drain electrode of FET Q6 connects the anode of diode D1 and the negative pole of capacitor C 1; The positive pole of capacitor C 5 connects the source electrode of FET Q8, and the drain electrode of FET Q8 connects the anode of diode D3 and the negative pole of capacitor C 3, and the positive pole of capacitor C 7 connects the source electrode of FET Q11; The drain electrode of FET Q11 connects the anode of diode D5 and the negative pole of capacitor C 5; The minus earth of capacitor C 7, the negative electrode of diode D1, D3, D5 connects the positive pole of capacitance network simultaneously, i.e. the drain electrode of field effect pipe Q9;
The negative arm of capacitance network is made up of capacitor C 2, C4, C6, C9 and FET Q1, Q5, Q7, Q10; The negative pole of capacitor C 2 connects the source electrode of FET Q1, and the drain electrode of FET Q1 connects the anode of diode D2, and the negative pole of capacitor C 4 connects the source electrode of FET Q6; The drain electrode of FET Q5 connects the negative electrode of diode D2 and the positive pole of capacitor C 2; The negative pole of capacitor C 6 connects the source electrode of FET Q7, and the drain electrode of FET Q7 connects the negative electrode of diode D4 and the positive pole of capacitor C 4, and the negative pole of capacitor C 9 connects the source electrode of FET Q10; The drain electrode of FET Q10 connects the negative electrode of diode D3 and the positive pole of capacitor C 6; The plus earth of capacitor C 9, the anode of diode D2, D4, D6 connects the negative pole of capacitance network simultaneously, i.e. the drain electrode of field effect pipe Q12;
Its positive pole of minus earth of input positive direct-current voltages V4 connects the drain electrode of FET Q4; The source electrode of FET Q4 connects the drain electrode of FET Q9; The plus earth of input negative dc voltage V6, its negative pole connects the drain electrode of FET Q2, and the source electrode of FET Q2 connects the drain electrode of FET Q12;
Gate drive signal V1, V2 are the civil power synchronous square-wave signals; Positive arm drive signal V13, V10, V8, V5 and negative arm drive signal V11, V9, V7, V3 also are the civil power synchronous square-wave signals; But pulsewidth is successively decreased with every 2ms; Time-delay increases progressively with every 1ms, and the drive signal V12 of FET Q9, Q12 is the sine wave signal of amplitude 310V.
Description of drawings
Fig. 1 is little power consumption clean energy resource storage system block diagram;
Fig. 2 is the direct current stabilizer schematic circuit;
Fig. 3 is each point voltage simulation waveform of direct current stabilizer schematic circuit;
Fig. 4 is a direct current stabilizer practical circuit of introducing UC1925;
Fig. 5 is each point voltage simulation waveform of direct current stabilizer practical circuit of introducing UC1925;
Fig. 6 is single-phase little power consumption power factor corrector;
Fig. 7 is single-phase each point voltage simulation waveform of little power consumption power factor corrector;
Fig. 8 is single-phase little power consumption power factor corrector;
Fig. 9 is single-phase each point voltage simulation waveform of little power consumption power factor corrector;
Figure 10 is the positive and negative symmetrical dc output power factor correcting circuit of single-phase input;
Figure 11 is positive and negative each the point voltage simulation waveform of symmetrical dc output power factor correcting circuit of single-phase input;
Figure 12 is the three-phase power factor correcting circuit of star connection;
Figure 13 is each point voltage simulation waveform of three-phase power factor correcting circuit of star connection;
The whole series connection of Figure 14 constant current, each point voltage simulation waveform of monomer parallel connection constant voltage charge schematic circuit;
The whole series connection of Figure 15 constant current, monomer parallel connection constant voltage charge schematic circuit;
Figure 16 lossless charger discharge principle circuit diagram;
The simulation waveform of Figure 17 electrocar 96V lithium-ion-power cell group charging voltage;
Figure 18 is a direct-flow inverter operation principle sketch map;
Figure 19 is that turriform ripple (4 rank) produces circuit;
Figure 20 is that turriform ripple (4 rank) produces each point voltage simulation waveform of circuit;
Figure 21 is inverter (16 a rank) pagoda wave voltage drive signal side circuit;
Figure 22 is single-phase inverter (16 a rank) pagoda wave voltage drive signal simulation waveform;
Figure 23 is turriform ripple (8 a rank) output voltage simulation waveform;
Figure 24 is turriform ripple (8 a rank) cutting process simulation waveform;
Figure 25 is turriform ripple (16 a rank) output voltage simulation waveform;
Figure 26 is the voltage cutting circuit;
Figure 26 is each point voltage simulation waveform of voltage cutting circuit;
Figure 28 is little power consumption clean energy resource storage system side circuit;
Fig. 2 is the schematic circuit that direct current is pinched depressor, establishes input voltage Vi=10.5V, requires output voltage V o=12V, and this circuit produces a bucking voltage Vc=1.5V, is superimposed upon on the input voltage, makes output voltage equal 12V.V2 is the square wave driving signal of the grid 100KHz of power MOS pipe Q2, and V1 is an input direct voltage.Behind the circuit start, the Q2 saturation conduction, cell voltage V1 charges to inductance L 1 through the drain-source utmost point of Q2, and inductive current is linear to be increased, and the energy that stores in the inductance is on the increase, and meanwhile, the voltage on the capacitor C 2 discharges to load R2.After the half period, Q2 ends, and the electric energy that is stored in the inductance L 1 charges to capacitor C 1 through diode in the body of Q1.The last voltage of C1 is superimposed upon on the cell voltage V1, in load resistance R2 power supply, also to capacitor C 2 chargings.Fig. 3 is the simulation waveform of each point voltage, is successively from top to bottom: output voltage V o, input voltage Vi, bucking voltage Vc.Can see that from figure output voltage V o (12V) is input voltage Vi (10.5V) and bucking voltage Vc (1.5V) sum.
Power MOS pipe Q1 does not have drive signal, only utilizes the forward characteristic of diode in the power MOS pipe Q1 body, and its saturation voltage drop is little, and is big through electric current.
Different with traditional direct current power conversion is not to be that row all is transformed into square-wave voltage to input voltage without forethought here, but according to circumstances, only to be transformed into square-wave voltage to the very small portion in the input voltage.For example: input voltage is 10.5V, and output voltage is 12V, should on the input voltage of 10.5V, compensate 1.5V, therefore, only need only be transformed into square-wave voltage to this 1.5V that should compensate and get final product.Fig. 2 the right is the simulation waveform of each point voltage, is successively from top to bottom: output voltage V o, input voltage Vi, bucking voltage Vc.
Fig. 4 is the voltage compensating circuit that is connected to UC 1825; Just the same at the right of control chip UC1825 circuit and Fig. 4, just the gate drive signal V2 of Q1 has changed UC1825 output signal OUT_A into, when load or input voltage variation; Regulate pulsewidth by UC1825, keep output voltage V o constant.
Regulating the pulsewidth of UC1825 output signal OUT_A comes control output voltage Vo constant; Only regulate by TX1 and pay the limit rectification and the direct voltage of that very small portion of coming; And exhausted most direct voltage; Be that exhausted most voltage on the load resistance R6 is direct by input voltage, without any Power Conversion.
Fig. 5 is each the point voltage simulation waveform of voltage compensating circuit that connects the UC1825 chip, and is similar with the simulation waveform of Fig. 3.
Power factor corrector is exactly a direct current regulation circuit, when input voltage is interchange, is exactly circuit of power factor correction, when input voltage is direct current, is exactly direct current regulation circuit,
Fig. 6 is the schematic circuit of single-phase power factor correcting device; The steamed bun wave voltage Vd that replaces the battery V2 in Fig. 2 direct current regulation circuit after the rectification gets final product; Make output voltage V o become direct voltage, the shape that must on steamed bun wave voltage Vd, superpose is like the bucking voltage of (1-Sinx), and we expect its result for it just; The process that DC offset circuit compensates the steamed bun wave voltage, the process of power factor correction just.
In this process; Why input steamed bun wave voltage Vd becomes straight line output voltage V o; That is that bucking voltage Vc is through Power Conversion because superposeed bucking voltage Vc above that, but input steamed bun wave voltage Vd needn't pass through any Power Conversion; Directly arrive output, become power output.The maximum characteristics of this little just power consumption power factor corrector: as long as carry out Power Conversion to very small portion in the input power (acquisition of bucking voltage); Just can obtain whole power outputs; Be that very big partly (whole steamed bun wave voltage) both needn't carry out actual Power Conversion in the input power; Also needn't pass through core transformers or inductance transmission, directly arrive output, become power output.Its conversion efficiency can be considered 100%.
In Fig. 6 circuit, V2 is a civil power, behind the rectifier bridge of being made up of D3-D6; Become steamed bun wave voltage Vd, parallelly connected with capacitor C 4, the process of the process of steamed bun wave voltage compensation and the compensation of Fig. 4 direct voltage is identical; Fig. 7 is the simulation waveform of each point voltage of steamed bun wave voltage compensating circuit, electric current; Be successively from top to bottom: input voltage Vi, bucking voltage Vc, input current Ii, single from geometric figure understanding, bucking voltage Vc is an inverted steamed bun ripple; Be superimposed upon this inverted steamed bun ripple on the forward steamed bun ripple; Its result becomes straight line certainly, because inverted steamed bun ripple and forward steamed bun ripple are complementary on geometric figure, this is the true essence of formula Vo=Vi+Vc=Sinx+ (1-Sinx)=1 in fact.
Fig. 8 is the practical circuit of single-phase little power consumption power factor corrector, and MOS power tube drive signal is provided by control chip UC1825, does not need the special chip of UC3854 constant power factor correcting.
Carry out little power consumption power factor correction, do not need all to be transformed into square-wave voltage to input power, only need compensate into direct voltage to input steamed bun wave voltage and get final product.Through the steamed bun wave voltage behind the voltage compensation; Become straight line, mean and corresponding all moment of all amplitudes of civil power that input current all has an opportunity filter capacitor is charged; Promptly all there is electric current to go out from the net effluent; The input current nature is synchronous with input voltage, and nethermost waveform can be found out from Fig. 6 the right, and input current waveform is sinusoidal wave fully.In fact the compensating circuit of the steamed bun wave voltage of Fig. 4 is exactly the schematic circuit of micropower consumption power factor corrector.Can see that in the circuit of power factor correction, big capacitor C 2 filtering that load resistance R1 is parallelly connected are not pure resistor load.
Fig. 9 is the simulation waveform of single-phase little each point voltage of power consumption power factor corrector practical circuit, electric current; Be successively from top to bottom: output voltage V o, input voltage Vi, steamed bun wave voltage Vd, bucking voltage Vc, input current Ii; After compensating into direct voltage to steamed bun wave voltage Vd, the waveform of input current becomes sine waveform naturally.
The definition of power factor is
[1]: PF=P/S, for a closed system, the maximum of PF equals 1, because active power P is the some of apparent power S, when reactive power that and if only if is null, S=P is arranged, thus PF=1.The so just closed system of above-mentioned voltage compensating circuit, bucking voltage Vc wherein is from steamed bun wave voltage Vd.But for an open system, situation is just different: if produce the power P of bucking voltage Vc
OutOutside system, behind voltage compensation, input current waveform and input voltage waveform are synchronous fully, and system only absorbs active power from the net side, and the net side waveform does not distort yet, and reactive power is zero, and P=S is then arranged, but this moment power factor PF=(P+P
Out)/S obviously, has PF>1 this moment, and promptly power factor is greater than 100%, and little power consumption power factor correction is adopted in this formula explanation, and PFC can be greater than 100%.
In Figure 10 circuit; Civil power carries out voltage multiplying rectifier; Have positive and negative symmetrical voltage output, positive and negative symmetrical voltage is connected to the circuit of power factor correction of symmetry, is symmetry axis with ground; The two part circuit up and down of symmetry are all identical with Fig. 5, and diode reverse, the power MOS pipe in the part circuit changes P type device into only down.Laterally zygomorphic positive and negative circuit of power factor correction is respectively handled the input voltage of 10ms, does not disturb mutually.The simulation waveform of input ac voltage, alternating current when Figure 11 is positive and negative symmetrical voltage, the waveform of input current Ii are sinusoidal wave, and be synchronous fully with input voltage.Have the circuit of power factor correction of positive and negative symmetrical voltage output, can be applicable to the inverter circuit that needs positive and negative symmetric circuit to import.
Figure 12 is the practical circuit that adopts the little power consumption power factor corrector of three-phase of star connection; Replace the steamed bun wave voltage Vd of the battery V2 in Fig. 4 direct voltage compensating circuit after with the three phase rectifier of star connection; The drive signal of power MOS pipe Q1 is provided by chip UC1825; Operation principle and single-phase little power consumption power factor corrector circuit are identical, no longer repeat here.
Figure 13 is the simulation waveform of each point voltage, electric current; Be successively from top to bottom: commutating voltage Vd; Input current Ia, Ib, Ic can see from simulation waveform, and the simulation waveform of the input current of the input current simulation waveform of part and Fig. 2 middle lower portion part is identical under Fig. 8 the right; Explain through behind the three-phase activity coefficient adjustment; Input current waveform is identical when input current waveform and pure resistor load, that is explanation adopt voltage compensating circuit to carry out power factor correction to have reached power factor be 1, and total harmonic distortion THD is zero effect.Mandatory declaration be; The load resistance R1 of the little power consumption power factor corrector of three-phase is parallel with big capacitor C 3; Be not pure resistor load, but the simulation waveform of its input current and the star connection three-phase input current simulation waveform when not controlling the pure resistor load of rectification is just the same.
Lithium ion power battery lossless charger adopts the charging method of whole series connection constant current, monomer parallel connection constant voltage; Battery is realized harmless charging; Harmless connotation has two-layer, and the one, charge efficiency is near 100%, and charge power is lossless basically; The 2nd, according to the characteristic curve (please refer to Fig. 1) of battery, battery is originally harmless fully in the charge and discharge process fully in charge and discharge.This lossless charger is exempted battery management system, is only realized all functions of battery system, charging system, discharge system and maintaining-managing system by simple circuit, do not have overcharge, overheated, cross put, overcurrent, short circuit phenomenon; The charging at the end terminal voltage of all cells is equal fully; Need not carry out equalizing charge, not have the complicated control chip and the software that are subject to disturb simultaneously, safe and reliable; Simple and practical, its cost, volume, weight, power consumption all are 1/10th of traditional chargers.
The implication of whole series connection constant current charge is: for cell integrated, carry out serial connection charge, charge power supply adopts the constant current constant voltage DC power supply; The implication of monomer parallel connection constant voltage control is: all directly parallelly connected shunt regulating circuit of each cell; All shunt regulating circuits are directly connected, be appreciated that into, when integral battery door is connected constant current charge; Also to the parallel circuits of all series connection constant current charge of connecting; The serial connection charge electric current is the battery of flowing through, the shunt regulating circuit of still flowing through, the real time end voltage when depending on battery charge.The output voltage of shunt regulating circuit is adjusted into battery charge final voltage value 3.75V; Cell terminal voltage of parallel connection is when being charged to this magnitude of voltage with it when certain, and parallel circuits starts, the series connection constant current charge electric current shunt regulating circuit of flowing through; And the battery of no longer flowing through; This cell charging stops, and other cells are proceeded the constant current charge of connecting, and the constant current charge of connecting seemingly charges the same to the integral battery door of direct series connection and these two branch roads of shunt regulating circuit of directly series connection simultaneously; Only the object of charging is controlled by shunt regulating circuit, thereby the monomer parallel connection constant voltage control of gaining the name.The charging method of above-mentioned whole series connection constant current charge, the control of monomer parallel connection constant voltage possesses all advantages that series, parallel charges, and has exempted all shortcomings of series, parallel charging fully.When charging at the end, the terminal voltage of all cells all equals the output voltage set point 3.75V of the shunt regulating circuit of parallel connection with it.Between the lithium ion single battery, on performances such as capacity, internal resistance, decay, self discharge, deposited difference originally, after harmless charging, this species diversity complete obiteration between the individuality overcharges, superheating phenomenon certainly never again.
Figure 14 is the schematic circuit of lossless charger charging; E1=2.5V wherein, E2=2.0V is the monomer lithium ion battery, V1 is the direct current constant voltage supply; Form 2 shunt regulating circuit Va and Vb by Q1, Q2, D1, R2 and Q3, Q4, D2, R3, respectively with battery E1, E2 parallel connection.Directly to lithium ion battery E1, E2 serial connection charge, as a battery, for example the terminal voltage of E1 is charged to rated value to V1 through resistance R 1; When promptly arriving the voltage stabilizing value of shunt regulating circuit Va setting; Zener diode D1 is open-minded, and shunt regulating circuit Va starts, the serial connection charge electric current triode Q2 that flows through; No longer to the E1 charging, the terminal voltage of E1 also no longer rises; Meanwhile the serial connection charge electric current continues the charging to E2, and when E2 was charged to rated value, charge power supply V1 just broke off, and the series connection constant current charge stops.
Figure 15 is respectively the simulation waveform of lithium ion battery E1, E2 charging voltage, and E1 begins charging from 2.5V, and after its terminal voltage was charged to 3.75V, charging curve was in line, and terminal voltage no longer rises, and rate is introduced into and is full of and the parallel voltage-stabilizing state, and V1 continues E2 is charged; E2 begins charging from 2.0V, when its terminal voltage is charged to rated value, charging curve also in line and the charging curve of E1 overlap because E2 initiation of charge voltage is lower, the constant current charge time is longer, the back gets into and is full of and the parallel voltage-stabilizing state.
Figure 16 is the schematic circuit of lossless charger discharge (comprising charging), access and the disconnection of Q5 control charge power supply V1, the discharge overall process of Q6 control battery pack.Switch S 3 and S4 form two switching circuit SW1 and SW2 together with D3, R6 and D5, the R8 on control limit, and respectively with cell E1, E2 parallel connection, in discharge process, the terminal voltage of E1, E2 is always greater than the puncture voltage of D3, D5, and switch S 3, S4 are closed; As a same reason, the parallel connection of the control limit of switch S 2 (comprising D4, R7) and whole battery group, in discharge process, the terminal voltage of whole battery group is always greater than the puncture voltage of D4, switch S 2 closures.The control limit of switch S 1 is through resistance R 5 and switch S 2, S3, S4 and whole battery group parallel connection, so switch S 1 is also closed, driving voltage V2 is added in the grid source electrode of Q6, the Q6 conducting, and battery pack is discharged to load R4.
In discharge process, a cell is arranged in battery pack, for example the terminal voltage of E1 is lower than specified discharge voltage; When promptly being lower than the puncture voltage of Zener diode D3, S3 control limit dead electricity, S3 breaks off; So S1 control limit is dead electricity also, S1 breaks off, and driving voltage V2 adds the grid less than Q6; Q6 turn-offs, and battery power discharge stops.Cross when battery pack put, when overcurrent or external short circuit, the battery pack terminal voltage is less than the puncture voltage of D1, S2 control limit dead electricity, S2 breaks off; So S1 control limit is dead electricity also, S1 breaks off, and driving voltage V2 adds the grid less than Q6, and Q6 turn-offs; Battery pack stops discharge, and after overcurrent or external short circuit trouble shooting, it is normal that the batteries terminal voltage is recovered, and is higher than the puncture voltage of D4; S2 control limit gets electric, and S2 is closed, and if cell is no overdischarge, then S3, S4 closure simultaneously; So S1 is also closed, V2 is added to the grid source electrode of Q6, and Q6 is open-minded, and battery pack continues load discharge.
Cell E1, together with the shunt regulating circuit Va and the switching circuit SW1 of parallel connection with it, this unit of primordial, the cascade arbitrarily of this elementary cell, the battery pack that the lithium ion power cell of arbitrary number is formed discharges and recharges.
Figure 17 is the simulation waveform of electrocar 96V lithium-ion-power cell group charging voltage, 26 of cells, terminal voltage 3.7V; 26 cell terminal voltages do not wait from 2V to 3.3V, differ 0.05V successively, and charging at the end; Each cell terminal voltage is equal fully; All equal the set point 3.75V of the stabilized voltage power supply output voltage parallelly connected with each cell, cell charging termination terminal voltage equals the set point of the shunt regulating circuit output voltage parallelly connected with it; This set point can artificially be adjusted, so cell charging termination terminal voltage can artificially be controlled.
Electrocar adopts three phase electric machine to drive; Then lithium-ion-power cell group terminal voltage is 288V; Need 78 series connection of 3.7V cell, the charging circuit somewhat complicated, but owing to whole charging circuit is formed by identical ball bearing made using cascade fully; And do not have the make-break operation of big electric current, high-voltage switch, implement very easy.
1), common lead acid accumulator
The structure of maintenance-free lead accumulator is not owing on the self structure, need replenish distilled water in length of life basically; Have characteristics such as shatter-proof, high temperature resistant, that volume is little, self discharge is little, behind the employing lead-calcium alloy grid frame, the water decomposition amount that produces during charging is few; The water evaporates amount is low, adds that shell adopts hermetically-sealed construction, and the sulfuric acid gas that discharges also seldom; So it is compared with traditional storage battery, do not have and need add any liquid, butted line pile crown, electric wire corrosion are lacked; Advantages such as anti-over-charging electric energy power is strong, and starting current is big, and the electric weight storage time is long.
Therefore; Maintenance-free lead accumulator has very large advantage with respect to general storage battery, but in use the depletion phenomenon can take place, and this is because the antimony on the grid frame can pollute the spongy pure lead on the negative plate; Back storage battery interior back electromotive force fully charges; Cause the excessive decomposition of water, a large amount of oxygen and hydrogen are overflowed from positive/negative plate respectively, and electrolyte is reduced.Owing to its structural reason, in normal the use, can only be with the following multiplying power charge and discharge of 3C, its specific energy, specific power, cycle life etc. are difficult to adapt to the requirements of the times in fields such as electric automobile, intelligent grid, clean energy resource system stored energy.
2), lithium ion power storage battery
The requirement of lithium-ions battery to discharging and recharging, different fully with reversible electrochemical response class storage batterys such as plumbic acids.Because lithium-ions battery application technology, system integration key technology and key components and parts and product research in groups; Seriously lag behind the development of lithium-ions battery; Battery in groups the back overcharge, overdischarge, overtemperature and mistake flow problem; Cause in groups lithium-ions battery significantly to shorten useful life, fail safe declines to a great extent, in addition burn, serious accident such as blast; Having become the subject matter of restriction lithium-ions battery industry development, also is the technical bottleneck of current energy-conservation and new-energy automobile industry development.
China's electric vehicle engineering develops into today, in fields such as Vehicular dynamic battery, motor, fax are moving, has obtained a collection of good achievement.Though the Vehicular dynamic battery technology also is not very ripe, the speed of development is not slow compared with developed countries.When battery cell was measured, each item index that demonstrates reached designing requirement basically.But, really be integrated into a power assembly, when perhaps being integrated on the car load, the situation when but finding with the monomer measurement has a tremendous difference.The Vehicular dynamic battery assembly be not with cell serial or parallel connection one by one together just so simple.Dozens of even up to a hundred batteries are integrated, and they are integrated on the car, worldwide portion is a new and high technology, never is to seem to be easy to so thing, and the unit or the individual of this difficult problem of solution of having the ability neither be too many.The lithium-ions battery system mainly comprises battery system, charging system, discharge system and maintaining-managing system, is the high-tech integrated system that a letter is drawn together a plurality of technical fields and industry
[6]
In sum, with regard to present power electronic technology, the application of lithium-ion-power cell still is in development, does not also form the system of a commercial operation, in foreseeable future, also can not form market.
3), the horizontal storage battery of thousand nets
Seeing that the world energy sources crisis is coming,,, thousand net the opportune moment that horizontal storage battery is a dark horse just now in view of the present Research of lithium-ion-power cell application technology in view of the powerful advantages of the horizontal storage battery of thousand nets with respect to traditional storage battery.The horizontal storage battery of produced worldwide thousand nets has only two places, and one in the U.S., and one in packet header; But the market demand is unlimited; Electric powered motor, intelligent grid energy storage, clean energy resource system energy storage or the like, these all are related to strategy, destiny, the future of a country, and the horizontal storage battery of thousand nets can take root in packet header; Then Chinese very fortunate indeed, the people are very fortunate indeed.
Table 1 thousand net horizon batteries and conventional batteries are relatively
Project | Thousand net horizon batteries | The tradition lead accumulator |
The material technology | It is the plumbous net that strengthens compound spongy lead braiding with the glass that solid-state extrusion forms that grid is adopted. | Grid is that the perfusion of lead pig heating and melting forms, and consumptive material is many. |
Structure technology | Battery pole plates is vertically placed the modify-water placing flat, and frame structure is adopted in the pole plate assembling. | The vertical modes of emplacement of battery pole plates has electrolyte stratification phenomenon. |
Internal voids | Battery change into complete after, inject curing agent and make inner tight, the higher seismic force of tool. | Fix utmost point crowd with fixed strip, come off because of vibrations cause active material. |
Battery weight | Reduce the weight of pole plate, than with the light approximately 30-50% of the common plumbic acid battery weight of capacity. | Grid is solid lead, and the connection in series-parallel lead of each interpolar can't omit, and consumptive material is many. |
The production environmental protection | Extrusion modling of composite glass fiber spongy lead and the unleaded steam of braiding process, pollution-free. | Plumbous material adopts heating for dissolving, can produce plumbous steam, and environmental pollution is arranged. |
Properties of product | Gravimetric specific energy>=10wh kg, cycle-index>=400 charging intervals short (0.75hr). | Gravimetric specific energy 33wh kg, cycle- |
The advantage of the horizontal storage battery of thousand nets
1) because pole plate adopts horizontal positioned, can avoid the polarization phenomena of the concentration of electrolyte difference of battery, and the polarization phenomena of concentration of electrolyte difference is the one of the main reasons of the traditional lead accumulator capacity decline and the lost of life.
2) the pole plate negative and positive directly are communicated with, so internal resistance is little, and the utilization of pole plate active material is more even, and save the plumbous material of utmost point crowd parallel connection, heavy-current discharge, and voltage drop is smaller.
3) adopt plumbous net to substitute traditional screen (grid), alleviate battery weight and save consumptive material, let the gravimetric specific energy of battery greatly improve (>=40wh/kg), the charge acceptance of battery also improves simultaneously, therefore helps quick charge.
4) because plumbous net tensile strength is big, the change of shape of pole plate active material in the ability charge and discharge cycles, so the cycle life number of times also improves relatively.
5) Horizon uses proprietary material and manufacturing equipment, and continuity is produced Horizon high power environmental protection lead-acid battery fast, only needs 4 hours approximately to assembling finished product, last about 3 days of the formation charging time from lead-sheathing, knitmesh.And the manufacturing time of conventional batteries must expend 7 days, changes into the longest 15 day time that needs at last.
6) through a plurality of individual tests, no problem is answered in the production technology and the performance of its entire cell to this product in the past.Only company imports automatic mass equipment, still needs the time adjustment to raise the efficiency after setting up factories.
7) product environmental protection: employing glass fiber compound material gate plate the earth has reduced the weight of battery pole plates, than common lead acid accumulator light about 30%.
8) production environmental protection: extrusion modling of compound glass galvanized wire and weaving that horizon battery adopts do not have lead steam to produce in the process; Adopt to be internalized into completely, avoided the outer generation that changes into acid mist; Whole production line is in enclosed environment, and the strictness of production line air process is purified treatment efficiently, and the waste water that the pole plate drying produces and flushing device produces all recycles behind neutralization, deposition, filtration, purification, and environment is not polluted.
9) processing procedure of thousand net horizon batteries itself is recyclable fully, probably can reclaim with the scrap of present factory, and the refuse battery that present present situation is scrapped reclaims factory all with the substituting transportation fuel market of the high U.S..
10) 1 high power environmental protection lead-acid battery can support 4 Group 31 conventional batteries (like figure below), can reduce the truck weight loading more than 200 pounds, and weight saving can reduce the fuel oil consume, improves the reliability of startup ability and increase load capacity.
11) battery possesses light weight, high current capacity, deep discharge and quick charge characteristic.
Direct-flow inverter adopts simple capacitance network, has realized the inversion of direct voltage, and its maximum characteristics are that circuit is simple; All devices are operated in power frequency, do not produce EMI and disturb, so power consumption is minimum and the life-span is extremely long, safe and reliable; Energy-conserving and environment-protective, cost is low, and fabrication and installation are easy.
7.1 direct-flow inverter operation principle
Figure 18 is little power consumption direct-flow inverter operation principle sketch map, and the course of work is following:
1) sinusoidal wave preceding 10ms area is along Y axle N five equilibrium, and this sentences 4 and is divided into example;
2) every five equilibrium serves as to make 4 rectangles on one side to go to the bottom, and heap tires out into turriform like diagram;
3) utilize capacitance network to produce the turriform ripple by input direct voltage, this is the first step of implementing dc inversion;
4) cut this turriform internally with sine wave, sinusoidal wave amplitude selection principle is to make sinusoidal wave just tangent with the right-angle side of turriform ripple in inside;
5) the turriform ripple is cut the entity after the unnecessary part, is the sine voltage Va of output just;
6) the unnecessary part that scales off of turriform ripple is broken up, is integrated, and is transformed into sine voltage Vb, exports simultaneously with aforementioned Va, produces the preceding 10ms waveform of output voltage V o;
7) sine wave back 10ms processing method is the same, produces the back 10ms waveform of output voltage V o.
7.2 quadravalence turriform wave generation circuit
The turriform wave generation circuit is actually a capacitance boost network, and Figure 19 is 4 rank turriform wave generation circuits; For the purpose of simplifying the description, represent the voltage on the network capacitance with power supply V3, V5, V7, V9, V11, V13, V15, V17, among Fig. 2; Metal-oxide-semiconductor Q4, Q6, Q8, Q10 etc. form the positive arm of 4 rank capacitance networks; Metal-oxide-semiconductor Q2, Q5, Q7, Q9 etc. form the negative arm of 4 rank capacitance networks, and wherein Q6, Q5, V7, V9, D3, D4 have formed the single order of capacitance network, and exponent number increases progressively from top to bottom.
Preceding 10ms; The positive arm of capacitance network starts; Each rank metal-oxide-semiconductor gate drive signal ON time increases with exponent number and successively decreases by each 2ms, and each rank metal-oxide-semiconductor gate drive signal delay time increases progressively by each 1ms, and the ON time of the drive signal V16 of the first rank metal-oxide-semiconductor Q10 is 10ms; Delay time is 0ms, and the rest may be inferred.Q1, Q3 drive signal that grid adds are the constant amplitude square voltage of cycle 20ms, during the preceding 10ms, and the Q1 saturation conduction.Between the V16 high period (pulsewidth 10ms, time-delay 0ms), the drain-source utmost point of the drain-source utmost point through Q10 of Q10 saturation conduction, the last voltage of V15, D2, Q1 produces duration 10ms, amplitude is the square voltage S1 of V15 on load resistance R1; (pulsewidth 8ms between the V12 high period; Time-delay 1ms), the drain-source utmost point of the drain-source utmost point through Q8 of Q8 saturation conduction, the last voltage of V11, D6, Q1; Generation duration 8ms, amplitude are the square voltage S2 of V11 on load resistance R1, and ground piles up on the S1 with claiming about S2; (pulsewidth 6ms between the V8 high period; Time-delay 2ms), the drain-source utmost point of the drain-source utmost point through Q6 of Q6 saturation conduction, the last voltage of V7, D3, Q1; Generation duration 6ms, amplitude are the square voltage S3 of V7 on load resistance R1, and the S3 left and right symmetrically piles up on the S2; Between the V4 high period (pulsewidth 4ms, time-delay 3ms), the drain-source utmost point of the drain-source utmost point through Q4 of Q4 saturation conduction, the last voltage of V3, D1, Q1 produces duration 4ms, amplitude is the square voltage S4 of V3 on load resistance R1, and the S left and right symmetrically piles up on the S3; In the last moment that preceding 10ms arrives, on load resistance R1, form S1 down, S4 is at the pagoda wave voltage last, that the duration successively decreases.
During the back 10ms, the negative arm of capacitance network starts, and as a same reason, on load resistance R1, forms S1 at negative direction pagoda wave voltage last, that S4 successively decreased in following, duration.The last moment that 20ms arrives has formed a complete pagoda wave voltage on resistance R 1, Figure 20 is the simulation waveform of the pagoda wave voltage that produced.
Figure 21 is that the little power consumption in 16 rank divides inverter to drive the side circuit of signal; Circuit is made up of 4 16 LM339 comparators, and reference voltage V2 is a direct voltage, and 16 resistance series connection backs that resistance is identical are parallelly connected with V2; The end of oppisite phase of 16 comparators order, be connected on the series resistance successively; The 1st comparator connects 1 resistance, and the 2nd comparator connects 2 resistance, and the rest may be inferred by analogy like Fig. 8.Other has the reference voltage of interchange V1, directly receives the in-phase input end of each comparator after the full-wave rectification, and the amplitude of establishing AC and DC reference voltage V1, V2 simultaneously all is 16V.
Before 10ms, when the amplitude that exchanges reference voltage V1 during less than 1V, the in-phase end voltage of neither one comparator is greater than end of oppisite phase voltage; All comparators are output low level all, and when the amplitude of V1 during more than or equal to 1V, the in-phase end voltage of the 1st comparator is greater than its end of oppisite phase voltage; The output high level, when the amplitude of V1 during more than or equal to 2V, the in-phase end voltage of the 2nd comparator is greater than its end of oppisite phase voltage; The output high level, the rest may be inferred by analogy for it.When last, promptly the 16th comparator exported after the high level, exchanges reference voltage V1 and will arrive extreme value, and As time goes on, V1 will descend.When the amplitude that exchanges reference voltage V1 dropped to less than 16V, the in-phase end voltage of the 16th comparator was less than its end of oppisite phase voltage, and its output end voltage produces negative saltus step; Voltage is by high step-down; Produced the 1st, also be the shortest pulse signal of duration, when the amplitude that exchanges reference voltage V1 dropped to less than 15V, the in-phase end voltage of the 15th comparator was less than its end of oppisite phase voltage; Its output end voltage produces negative saltus step; Voltage has produced the 2nd pulse signal by high step-down, and the rest may be inferred by analogy for it.When the amplitude that exchanges reference voltage V1 drops to less than 1V; The in-phase end voltage of the 1st comparator is less than its end of oppisite phase voltage; Its output end voltage produces negative saltus step, and voltage is by high step-down, produced the 16th, also be last 1, be the longest pulse signal of duration simultaneously; When second 10ms arrives, repeat the above-mentioned course of work.16 duration pulse drive signals from short to long that produced just form each differential voltage of pagoda voltage, please refer to the simulation waveform of Figure 22.
Obviously; The duration of the pulse signal that the frequency that exchanges reference voltage V1 has determined to be produced has promptly determined the frequency of differential inverter output AC voltage, and the height of the pulse signal that the amplitude of reference voltage V1, V2 has determined to be produced; Promptly determined the amplitude of differential inverter output AC voltage; The frequency of V1 and V1, V2 amplitude can be regulated arbitrarily, so the frequency and the amplitude of differential inverter output AC voltage also can be regulated arbitrarily.
Figure 23 is little power consumption direct-flow inverter (8 rank) output voltage simulation waveform; The left side is sine wave output voltage Vo, and the right is the cutting process of pagoda ripple, can see from figure; When the exponent number N of pagoda ripple increases; N=8 for example, the pagoda ripple that is produced very near sinusoidal wave, can save this link of voltage cutting.
Can find out that from Figure 24 simulation waveform the leftover pieces that cut down from the pagoda ripple are along with the increase of exponent number N; The gross area is more and more littler, and this is because the pagoda ripple can be regarded N differential superimposed forming on the longitudinal axis as, when N is tending towards infinite; It is sinusoidal wave that the pagoda ripple is tending towards; At this time, with sinusoidal wave cutting pagoda ripple, the leftover pieces gross area that scales off equals zero.
General many level FBI inverter
[1]For example tri-level inversion, five level inverse conversions, seven level inverse conversions etc. increase the purpose that output-voltage levels is counted N; Be in order to reduce the harmonic content in the output voltage waveforms; But power demand device and circuit complexity are shown off index increase, N isolate, voltage source independently must be arranged, and among each FBI the drive signal of power device also be isolation, independently.The three-phase two-level inversion, 6 of power devices, three-phase tri-level inversion, 12 of power devices, three-phase five level inverse conversions, 24 of power devices.If realize 16 level inverse conversions, power demand device P=2
N=2
16=65536, need to isolate, 65536 of drive signals independently, the inverter circuit of this empty talk can not be realized being actually fully.The textbook of all relevant inverters is all mentioned multi-level inverse conversion, but does not have can the draw side circuit of the above inverter of five level of which textbook, because too complicated, draws also that picture does not come out, and how can actually work it out.
SPWM full bridge inverter (FBI) is not only that power device is shown off the problem that index increases, and what more kill is; When carrying out many level stacks; Also will in each level, carry out the SPWM pulse-width modulation, the SPWM control of a FBI is enough complicated, now will be to reaching 2
N=65536 SPWM drive signals are controlled, and the complexity of its space vector is not imaginable.
Little merit direct current consumption inverter power demand device is shown off linear increase with circuit complexity, i.e. power demand device P=2N, and wherein N is a level number.Fig. 4 is the side circuit of the little power consumption direct-flow inverter of 4 level; Power demand device P=2N=2*4=8; Realize 16 electrical level inverters, power demand device P=2N=2*16=32 is limited to the article length; This place should not paint whole circuit diagram, only at the drawn pagoda wave voltage drive signal simulation waveform of little power consumption direct-flow inverter (16 rank) pagoda wave voltage drive signal generation circuit and Fig. 6 of Fig. 5.Figure 25 is direct-flow inverter (16 a rank) pagoda wave voltage simulation waveform, and curve can be seen among the figure, and the pagoda ripple of N=16 convergence is sinusoidal wave, does not need to carry out voltage cutting at all.
With sine waveform cutting pagoda ripple, establishing and cutting the left part area in sinusoidal wave back is S0, when the exponent number N=1 of pagoda ripple; S0=A (1-Sinx), wherein A is the amplitude of input voltage, according to calculating; This partly area account for 36% of the gross area, as the exponent number N=16 of pagoda ripple, or during greater than certain positive integer; Pagoda ripple convergence is sinusoidal wave, does not need to carry out voltage cutting at all.When exponent number N 1 and certain positive integer between the time, the power ratio of the area S0 representative that cuts down is more considerable, must be through Power Conversion, or feedback, or output, improve overall efficiency.
Figure 26 is the voltage cutting circuit; Power MOS pipe Q5, Q6 and core transformers TX1 have formed main circuit, and the square wave driving signal V1 of 100KHz, V5 are added in the grid of Q5, Q6, and V2 is input sine wave voltage Vi; Vi is the sine voltage of amplitude 360V, and load R6 is connected on the source electrode of Q6.
The positive half cycle of input voltage, when driven square wave voltage V5 was high level, Q6 saturation conduction, input voltage Vi were added in the former limit of load resistance R5 and transformer TX1 through the drain-source utmost point of diode and Q6 in the body of Q5; At the negative half period of input voltage, when driven square wave voltage V1 was high level, Q5 saturation conduction, input voltage Vi were added in the former limit of load resistance R5 and transformer TX1 through the drain-source utmost point of diode and Q5 in the body of Q6.The pulsewidth of the inductance value on the former limit of suitable selection transformer and drive signal V1, V5, just the voltage on the load resistance R5 is the amount of exports definite value.
The felling of transformer TX1 is connected to the active rectification circuit of being made up of Q1-Q4
[1]Can be sine voltage for sinusoidal wave double-side band square-wave voltage Vs rectification with the envelope that the TX1 felling produces, suitably select the no-load voltage ratio of TX1 and the pulsewidth of drive signal V1, V5, can make that the sine voltage (source electrode by Q3, Q4 takes out) of active rectification circuit output is a rated output voltage; This voltage and input voltage are with frequency, homophase, synchronous;, homophase same frequently with the rated voltage that resistance R 5 produces, the same width of cloth forms output voltage V o jointly.Because complete machine does not adopt iron core, do not utilize the magnetic saturation phenomenon to stablize alternating voltage, thereby can not produce the sine waveform distortion, the argumentation of relevant active rectification please refer to document [2].
Figure 27 is the simulation waveform of each point voltage of clipper circuit; Outermost layer is the input voltage Vi of amplitude 360V; Be the output voltage V o that is cut the common formation of active rectification voltage that input voltage and TX1 felling behind the head produce on the resistance R 5 below; The innermost layer is that the envelope that the former limit of transformer produces is sinusoidal wave double-side band square-wave voltage Vp, and felling voltage Vs is n a times of Vp by the no-load voltage ratio decision of TX1.
Embodiment
Figure 28 is little power consumption clean energy resource storage system side circuit; Wherein charge constant current, constant voltage source accomplished by the positive negative rectifier stepup transformer that Q3, Q8 etc. forms; Charge in batteries is partly formed lossless charger by Q1, Q2 and Q19, Q20 etc. and is accomplished the three-phase differential inverter completion that inversion partly is made up of Q12, Q13, Q14, Q16, Q17, Q18 etc.
Single phase alternating current (A.C.) voltage V4 gets into A, B 2 points with the voltage multiplying rectifier mode, and positive and negative symmetrical rectification stepup transformer is accomplished the boosting of positive negative dc voltage, stablized, constant current, constant voltage, and input direct voltage stable and boosting precedingly details.The constant current function is that the direct voltage that detects on the resistance R 11 is accomplished; Height according to the positive and negative symmetrical direct voltage of input; Select the number N of optimal charge battery, the principle of selection is to make the terminal voltage of N storage battery be equal to or higher than input direct voltage, and the rectification stepup transformer can reach steady state value according to the adjustment of the direct voltage on the resistance R 11 charging stream electric current like this; If the terminal voltage of N storage battery is lower than input direct voltage, then charging current will be out of hand.The constant voltage function is that the direct voltage that detects 2 of C, D is accomplished; The terminal voltage different according to various storage batterys; Confirm the breakover point of constant current commentaries on classics constant voltage, constant voltage charge; According to the height of the positive and negative symmetrical direct voltage of input, select the number N of optimal charge battery, the principle of selection is identical with the situation of above-mentioned constant current.
Input voltage shown in Figure 180 is a single-phase voltage doubling rectifier circuit, and positive and negative symmetrical 310V is if positive and negative symmetrical direct voltage directly inserts A, B 2 points, if three-phase alternating voltage inserts A, B 2 points with the double half-wave rectification mode.
Constant current, the constant voltage source that rectification boosting circuit produces directly gets into the harmless charging part of being made up of Q1, Q2 and Q19, Q20; The three-phase differential inverter of being made up of Q12, Q13, Q14, Q16, Q17, Q18 etc. obtains the positive and negative symmetrical direct voltage of battery from E, 2 of F; Here pagoda wave generation circuit and voltage cutting circuit omit, and harmless charging, inversion principle are in aforementioned.
Adopt the PWM pulse-width modulation, with core transformers or inductance transmitted power, electrical network produced strong the pollution be all power inverters of its main characteristic; Be referred to as conventional power converters; Corresponding with conventional power converters is little power consumption power inverter; Or claim the green power converter, what little power consumption power inverter adopted is little power consumption Technics of Power Electronic Conversion technology.
Little power consumption Technics of Power Electronic Conversion technology is to have the loss of fixed proportion to reduce to minimum with the input gross power, as long as carry out Power Conversion to very small portion in the input power; Just can obtain whole power outputs, promptly greatly partly both needn't carry out actual Power Conversion in the input power, also needn't pass through core transformers or inductance transmission; Directly arrive output, become power output, device all is operated in power frequency; Do not produce EMI and disturb, so power consumption is minimum and the life-span is extremely long.All power losss here; Only relevant with the input power of very small portion; And irrelevant with the input gross power, for example slippages of saturated, the quiescent dissipation, the loss of HF switch DYNAMIC PROCESS, core transformers or the inductance that end of power device or the like is all only relevant with the very small portion input power; Exhausted most input power directly arrives output, becomes power output.
Adopt the PWM pulse-width modulation, with core transformers or inductance transmitted power, electrical network produced strong the pollution be all power inverters of its main characteristic; Be referred to as conventional power converters; Corresponding with conventional power converters is little power consumption power inverter; Or claim the green power converter, what little power consumption power inverter adopted is little power consumption Technics of Power Electronic Conversion technology.
Little power consumption Technics of Power Electronic Conversion technology is to have the loss of fixed proportion to reduce to minimum with the input gross power, as long as carry out Power Conversion to very small portion in the input power; Just can obtain whole power outputs, promptly greatly partly both needn't carry out actual Power Conversion in the input power, also needn't pass through core transformers or inductance transmission; Directly arrive output, become power output, device all is operated in power frequency; Do not produce EMI and disturb, so power consumption is minimum and the life-span is extremely long.All power losss here; Only relevant with the input power of very small portion; And irrelevant with the input gross power, for example slippages of saturated, the quiescent dissipation, the loss of HF switch DYNAMIC PROCESS, core transformers or the inductance that end of power device or the like is all only relevant with the very small portion input power; Exhausted most input power directly arrives output, becomes power output.
In Figure 28 circuit, the three-phase differential inverter by Q12, Q13, Q14, Q16, Q17, Q18 etc. form if remove the inverter of Q14, Q16, Q17, Q18 composition, then becomes a single-phase inverter, and its principle and the course of work are in aforementioned.
Explain: all circuit diagrams of this paper all come from the SIMetrix/SIMPLIS 6.0a of power electronics simulation software, can not add to revise direct emulation, obtain identical output waveform.
Claims (7)
1. little power consumption clean energy resource storage system is characterized in that: little power consumption clean energy resource storage system is in series by little power consumption charging part, storage battery, little power consumption inversion part successively.
2. a kind of little power consumption clean energy resource storage system as claimed in claim 1 is characterized in that: little power consumption charging partly is in series by direct current stabilizer, power factor corrector, harmless charger successively.
3. a kind of little power consumption clean energy resource storage system as claimed in claim 1 is characterized in that: little power consumption inversion partly is made up of single-phase or three-phase dc inverter.
4. like claim 1 or the described a kind of little power consumption clean energy resource storage system of claim 2, it is characterized in that: power factor corrector is by FET Q1, Q2, inductance L 1; Capacitor C 1 is formed, and the drain electrode of FET Q1 connects the positive pole of capacitor C 1, and its source electrode connects the drain electrode of FET Q2; The source ground of FET Q2; The source electrode of inductance L 1 one termination FET Q1, the negative pole of a termination capacitor C1, the negative pole of capacitor C 1 constitutes end points Vi; Input voltage is connected between Vi and the ground, and output voltage V o is by the positive pole output of capacitor C 1; FET Q1 can use a diode D1 to replace, and the negative electrode of diode D1 connects the positive pole of capacitor C 1, and its anode connects the drain electrode of FET Q2.
5. like claim 1 or the described a kind of little power consumption clean energy resource storage system of claim 3; It is characterized in that: direct-flow inverter is made up of a voltage cutting circuit and a N rank capacitance network, the input of the output termination voltage cutting circuit of N rank capacitance network.
6. like claim 1 or the described a kind of little power consumption clean energy resource storage system of claim 5; It is characterized in that: the voltage cutting circuit is made up of FET Q9, Q12, and their source electrode is connected together, through resistance R 1 ground connection; Capacitor C 8 and resistance R 1 parallel connection; The drain electrode of FET Q9 connects the positive pole of capacitance network, and the drain electrode of FET Q12 connects the negative pole of capacitance network, and the drive signal V12 of FET Q9, Q12 is the sine wave signal of amplitude 310V.
7. like claim 1 or the described a kind of little power consumption clean energy resource storage system of claim 5, it is characterized in that: N rank capacitance network is made up of positive and negative both arms:
A) the positive arm of capacitance network is made up of capacitor C 1, C3, C5, C7 and FET Q3, Q6, Q8, Q11; The positive pole of capacitor C 1 connects the source electrode of FET Q3, and the drain electrode of FET Q3 connects the negative electrode of diode D1, and the positive pole of capacitor C 3 connects the source electrode of FET Q6; The drain electrode of FET Q6 connects the anode of diode D1 and the negative pole of capacitor C 1; The positive pole of capacitor C 5 connects the source electrode of FET Q8, and the drain electrode of FET Q8 connects the anode of diode D3 and the negative pole of capacitor C 3, and the positive pole of capacitor C 7 connects the source electrode of FET Q11; The drain electrode of FET Q11 connects the anode of diode D5 and the negative pole of capacitor C 5; The minus earth of capacitor C 7, the negative electrode of diode D1, D3, D5 connects the positive pole of capacitance network simultaneously, i.e. the drain electrode of field effect pipe Q9;
B) the negative arm of capacitance network is made up of capacitor C 2, C4, C6, C9 and FET Q1, Q5, Q7, Q10; The negative pole of capacitor C 2 connects the source electrode of FET Q1, and the drain electrode of FET Q1 connects the anode of diode D2, and the negative pole of capacitor C 4 connects the source electrode of FET Q6; The drain electrode of FET Q5 connects the negative electrode of diode D2 and the positive pole of capacitor C 2; The negative pole of capacitor C 6 connects the source electrode of FET Q7, and the drain electrode of FET Q7 connects the negative electrode of diode D4 and the positive pole of capacitor C 4, and the negative pole of capacitor C 9 connects the source electrode of FET Q10; The drain electrode of FET Q10 connects the negative electrode of diode D3 and the positive pole of capacitor C 6; The plus earth of capacitor C 9, the anode of diode D2, D4, D6 connects the negative pole of capacitance network simultaneously, i.e. the drain electrode of field effect pipe Q12;
C) its positive pole of minus earth of input positive direct-current voltages V4 connects the drain electrode of FET Q4; The source electrode of FET Q4 connects the drain electrode of FET Qg; The plus earth of input negative dc voltage V6, its negative pole connects the drain electrode of FET Q2, and the source electrode of FET Q2 connects the drain electrode of FET Q12;
D) gate drive signal V1, V2 are the civil power synchronous square-wave signals; Positive arm drive signal V13, V10, V8, V5 and negative arm drive signal V11, V9, V7, V3 also are the civil power synchronous square-wave signals; But pulsewidth is successively decreased with every 2ms; Time-delay increases progressively with every 1ms, and the drive signal V12 of FET Q9, Q12 is the sine wave signal of amplitude 310V.
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
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CN112878960A (en) * | 2021-01-15 | 2021-06-01 | 邓惠荣 | Direct current ignition method for underground petroleum coal |
CN116760270A (en) * | 2023-08-11 | 2023-09-15 | 西南交通大学 | Boost-PFC converter for stabilizing voltage secondary ripple |
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CN1160941A (en) * | 1996-03-29 | 1997-10-01 | 龙顺游 | New-type charge and discharge device |
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CN2128023Y (en) * | 1992-07-22 | 1993-03-10 | 张向东 | AC voltage transformer |
CN1127949A (en) * | 1993-12-24 | 1996-07-31 | 欧姆龙株式会社 | Uninterruptible power supply |
CN1160941A (en) * | 1996-03-29 | 1997-10-01 | 龙顺游 | New-type charge and discharge device |
CN201623500U (en) * | 2010-01-22 | 2010-11-03 | 广东天富风光潮发电设备有限公司 | Small shunt-connected wind power generation system with storage battery |
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CN112878960A (en) * | 2021-01-15 | 2021-06-01 | 邓惠荣 | Direct current ignition method for underground petroleum coal |
CN116760270A (en) * | 2023-08-11 | 2023-09-15 | 西南交通大学 | Boost-PFC converter for stabilizing voltage secondary ripple |
CN116760270B (en) * | 2023-08-11 | 2023-11-07 | 西南交通大学 | Boost-PFC converter for stabilizing voltage secondary ripple |
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