CN201937327U - Photovoltaic power generation control system - Google Patents

Abstract

The utility model relates to a group-string type photovoltaic power generation control system, which comprises a system master controller and at least two photovoltaic DC components. Each photovoltaic DC component comprises a solar battery module, a photovoltaic slave controller and storage battery modules, wherein the photovoltaic slave controller is used for tracking the maximum power point of the solar battery module and enabling the DC voltage outputted by the solar battery module to charge and discharge for the storage battery modules; and the at least two storage battery modules are connected in a group-string manner to output the high-voltage DC voltage. The system master controller comprises a control unit and an inversion unit, wherein the control unit is used for controlling the inversion unit to perform inversion to the high-voltage DC voltage, monitoring each photovoltaic DC component in a real-time manner, and switching the abnormal solar battery module and/or the storage battery modules in a real-time manner. By adopting the technical scheme provided by the utility model, the plurality of photovoltaic DC components form a high-voltage DC power supply in a group-string manner, the DC/AC inversion can be directly performed, the traditional step-up transformer is omitted, and the energy conversion efficiency the photovoltaic power generation system is improved.

Description

A kind of photovoltaic power generation control system

Technical field

The utility model relates to technical field of solar, more particularly, relates to a kind of photovoltaic power generation control system.

Background technology

Solar energy is inexhaustible, is the human desirable energy.Before more than 100 years, Einstein has just found photoelectric effect, for human use's solar energy provides theoretical foundation.1954, it was 4.5% single crystal silicon solar cell that U.S.'s Bell Laboratory is developed photoelectric conversion efficiency, made humanly directly to utilize the dream of solar power generation to become a reality.Entered since 21 century, numerous and confused support policy and the development plan formulated such as the U.S., Japan, Germany, photovoltaic industry presents flourish situation.The development speed of photovoltaic industry is fast, is rare in the modern industry, even has surpassed the semi-conductor industry that is celebrated with high speed development.It will be main in the world energy resource consumption part in soon future, and being enough to change is the consumption structure of main energy sources with oil and coal at present.

But the efficient of existing photovoltaic power generation control system is lower, and complex structure.

The utility model content

The technical problems to be solved in the utility model is, at low, the baroque defective of photovoltaic power generation control system efficient of prior art, provides a kind of efficient height, photovoltaic power generation control system simple in structure.

The technical scheme that its technical problem that solves the utility model adopts is: construct a kind of photovoltaic power generation control system, comprising: system master system device and at least two photovoltaic DC assemblies; Wherein,

Each photovoltaic DC assembly comprises solar battery module, battery module and is connected in described solar battery module and battery module, and being used to follow the tracks of the maximum power point of solar battery module and making the direct voltage of described solar battery module output is the photovoltaic slave controller that described battery module discharges and recharges, and the battery module group string data in described at least two photovoltaic DC assemblies connects;

System master system device comprises inversion unit and is connected in inversion unit and the photovoltaic slave controller, and be used to control inversion unit described high-voltage dc voltage is carried out inversion, and monitor each photovoltaic DC assembly in real time and switch the unusual solar battery module of generation and/or the control unit of battery module in real time.

In photovoltaic power generation control system described in the utility model, described control unit passes through the described photovoltaic slave controller of a kind of connection in the following manner: RS485 bus, RS232 bus, RS422 bus.

In photovoltaic power generation control system described in the utility model, described battery module comprises at least two storage batterys, and described at least two batteries string datas connect.

In photovoltaic power generation control system described in the utility model, described photovoltaic DC assembly also comprises and is connected in photovoltaic slave controller and battery module, and is used to switch unusual battery module switch matrix takes place.

In photovoltaic power generation control system described in the utility model, described photovoltaic power generation control system also comprises AC load, AC power and switching device shifter, the first input end of described switching device shifter connects AC power, second input of described switching device shifter connects the output of inversion unit, the output of described switching device shifter connects AC load, and the control end of described switching device shifter connects control unit.

In photovoltaic power generation control system described in the utility model, described photovoltaic power generation control system also comprises the DC load that is connected in battery module.

Implement the technical solution of the utility model, following beneficial effect arranged:

1. many photovoltaic DC component groups conspire to create high-voltage DC power supply, directly carry out the DC/AC inversion, save traditional step-up transformer, have improved the energy conversion efficiency of photovoltaic generating system;

2. system master system device and photovoltaic DC assembly carry out full duplex communication, realize distributed control;

3. photovoltaic generation and civil power can automatically switch, and the real-time working state of online monitoring system;

4. can switch unusual solar module and accumulator cell assembly in real time by switch matrix.

Description of drawings

The utility model is described in further detail below in conjunction with drawings and Examples, in the accompanying drawing:

Fig. 1 is the structural representation of the utility model photovoltaic power generation control system first embodiment;

Fig. 2 is the part-structure schematic diagram of the utility model photovoltaic power generation control system first embodiment;

Fig. 3 is the voltage and current of the utility model storage battery and the curve chart of time;

Fig. 4 is the photovoltaic curve chart that the utility model is followed the tracks of solar battery module maximum power point embodiment one;

Fig. 5 is the photovoltaic curve chart that the utility model is followed the tracks of solar battery module maximum power point embodiment two.

Fig. 6 is the flow chart that the utility model is followed the tracks of solar battery module maximum power point embodiment three.

Embodiment

As shown in Figure 1, in photovoltaic power generation control system first embodiment of the present utility model, this system mainly comprises two photovoltaic DC assemblies 110, system master system device 120, RS485 bus 130, switching device shifter 140, AC power 150, AC load 160 and DC load 170.Wherein, each photovoltaic DC assembly comprises solar battery module 111, photovoltaic slave controller 112 and battery module 113, photovoltaic slave controller 112 is used to follow the tracks of the maximum power point of solar battery module 111, and to make the direct voltage of solar battery module 111 output be that battery module 113 discharges and recharges, and the 113 groups of string datas of battery module in two photovoltaic DC assemblies 110 connect (not shown) with the output high-voltage dc voltage.System master system device 120 comprises control unit 122 and inversion unit 121, wherein, control unit 122 is used to control 113 groups of string datas of 121 pairs of a plurality of battery modules of inversion unit and connects the high-voltage dc voltage of being exported and carry out inversion, and be connected with photovoltaic slave controller 112 by RS485 bus 130, be used for monitoring in real time each photovoltaic DC assembly 110, and switch generation unusual solar battery module 111 and/or battery module 113 in real time.

In addition, control unit 122 makes the inverter voltage of inversion unit 121 outputs or AC power 150 be AC load 160 power supplies by the switching state of control switch device 140.The direct voltage of battery module 113 outputs is DC load 170 power supplies.

Should be noted that at first the mentioned term of the application " the group string data connects " is that connection in series-parallel connects, series connection is to increase voltage, and is in parallel to increase electric current.

In addition, only show two photovoltaic DC assemblies 110 though also should be noted that Fig. 1, the utility model is not limited only to two, also can be plural other quantity.In addition, what the utility model also was not limited to connect control unit 122 and photovoltaic slave controller 112 is the RS485 bus, also can be RS485 bus, RS232 bus, RS422 bus.

Fig. 2 is the part-structure schematic diagram of the utility model photovoltaic power generation control system first embodiment, photovoltaic DC assembly 110 among this embodiment is compared embodiment one, also comprise accumulator cell charging and discharging module 115 and switch matrix 114, photovoltaic slave controller 112 switches the unusual battery module 113 of generation by the on off state of control switch matrix 114.At described battery module 113 just often, photovoltaic slave controller 112 is that battery module 113 discharges and recharges by the direct voltage that control accumulator cell charging and discharging module 115 is exported the solar battery module (not shown).Battery module 113 comprises at least two storage batterys, and these at least two batteries string datas connect.

In this embodiment, detect a certain accumulator cell assembly when unusual when photovoltaic slave controller 112 is online, in time switch corresponding batteries 113 by control switch matrix 114, required to satisfy system's DC load, and by RS485 bus 130 apprizing system master controllers 120, by it inversion unit 121 is adjusted in real time, required to satisfy system's AC load.

Traditional charge in batteries adopts simple strategy such as constant voltage or constant current charge more, and the charging interval is long and efficient is low.Because Various Seasonal intensity of sunshine difference, temperature changes, and phenomenon appears owing to fill in storage battery easily.For avoiding storage battery owing to fill state, batteries is divided into less several groups of capacity, carry out cycle charging by 114 pairs of different batteries modules of photovoltaic slave controller 120 control switch matrixes 113, make each group all reach full state.The electric current that provides with solar battery module 111 is no more than every group storage battery, and maximum to allow charging current and every group storage battery be group forming criterion to the load discharge Current Control in the discharge rate of storage battery producer recommended maximum size separately.For avoiding producing vibration in the charging process, the transmission characteristic of charging control circuit is the hysteresis form, and discharge control electric wire is then in order to control the depth of discharge of storage battery, to prolong its useful life.

This system comprises trickle, constant current, overvoltage, four charging stages of floating charge, as shown in Figure 3, wherein, sets threshold voltage V when the voltage of storage battery is lower than _ChThe time, with electric current I _IrCarry out trickle charge (T0～T1); When battery tension rises to V gradually _ChThe time, then with electric current I _BulkCarry out constant current charge (T1～T2); Battery capacity increases fast, rises to constant voltage V a little more than the storage battery rated voltage up to battery tension _Oc, (T2～T3), charging current then reduces gradually to enter the overvoltage charging stage; When charging current is decreased to I gradually _OctThe time, storage battery is filled and enters the floating charge stage (T3～).In this stage, system provides a constant voltage V who has temperature-compensating _fAccumulators remains unchanged to keep battery capacity, and very little floating current is provided simultaneously, to remedy the capacitance loss that storage battery self-discharge causes.When storage battery drops to V owing to working voltage _Oc90%, system enters trickle charge or constant current charge state automatically.

Fig. 4 and Fig. 5 are respectively the photovoltaic curve charts that the utility model is followed the tracks of solar battery module maximum power point embodiment one and two, for making solar cell always work in best output state, effectively improve the efficient of photovoltaic generation, need rapidly and accurately solar cell to be carried out MPPT maximum power point tracking (MPPT).Purpose for solar cell MPPT is exactly to obtain the maximum of this curve on Fig. 4 and P-V characteristic curve shown in Figure 5.MPPT method commonly used has: constant voltage tracing (CVT), disturbance observation (P﹠amp; O), conductance increment method (IncCond) etc.

Constant-voltage method is regarded as the maximum power point (mpp) of photovoltaic cell at the output of a certain constant voltage, thereby simplified the realization of MPPT greatly, but this method has been ignored the influence of temperature to the photovoltaic cell open circuit voltage, accuracy and adaptability are relatively poor, especially are unfavorable for using in morning and evening and the violent area of four seasons difference variation; The disturbance observation is sought the direction of maximum power point by the working point of continuous disturbed sun energy photovoltaic generating system, tracking is simple, less demanding to sensor accuracy, disturbance parameter is few, but its power output is near the oscillatory operation photovoltaic array maximum power point easily, exists the setting of tracing step to be difficult to take into account the shortcoming of tracking accuracy and response speed; The conductance increment method can make system have good performance for tracking under the fast-changing situation of environment, and when irradiance and variations in temperature, the output voltage of solar battery array can steadily be followed the variation of environment, and the output voltage swing is little.But this algorithm also exists the setting of step-length to be difficult to take into account the situation of tracking accuracy and response speed.Optimum gradient is the numerical method based on the multidimensional unconstrained optimization problem of gradient.

Fig. 6 is the flow chart that the utility model is followed the tracks of solar battery module maximum power point embodiment three.Because solar cell terminal voltage bounded applies to MPPT to gradient method, the maximum power point that is searched must be a universe.For this reason, the utility model has also proposed the conductance increment method based on optimum gradient, dynamically change the step-length of MPPT by optimum gradient, take into account tracking accuracy and the response speed of MPPT, to solve because of fixed step size is provided with the improper problem such as system works inefficiency that causes, this method specifically may further comprise the steps:

The current voltage and the current electric current of the solar battery module of A. sampling output;

B. calculate according to the electric current of the voltage of current voltage, current electric current, previous moment, previous moment that current voltage variety, current current change quantity, current electricity are led, current electricity is led variable quantity, the current power variable quantity, and calculate current gradient according to current power variable quantity and current voltage variety;

C. described gradient be multiply by mutually with the proportionality coefficient of presetting and obtain a voltage change value;

Whether the absolute value of H. judging current voltage variety is zero, if, execution in step D then; If not, execution in step I then;

Whether the absolute value of D. judging current current change quantity is zero, if then return; If not, execution in step E then;

E. judge current current change quantity whether greater than zero, if, execution in step F then; If not, execution in step G then;

F. current voltage is added the above voltage change value, return then;

G. current voltage is deducted described voltage change value, return then;

Whether the absolute value of I. judging the current power variable quantity is zero, if then return; If not, execution in step J then;

J. judge that current electricity leads variable quantity and whether equal current electricity and lead, if then return; If not, execution in step K then;

K. judge that current electricity leads variable quantity and whether lead greater than current electricity, if, execution in step F then; If not, execution in step G then.

Should be noted that and in Fig. 6, look | dP _k|＜ε ₁, | dU _k|＜ε ₂, | dI _k|＜ε ₃Be dP _k, dU _k, dI _kApproximate zero situation.

In the method, establishing positive gradient is g _k, then the iterative algorithm of gradient method may be defined as:

X _k+1＝X _k+a _kg _k (1)

Wherein, a _kBe non-negative constant, the maximum of points of searching function is always along g _kThe direction search.

According to the solar cell electrical characteristic, ignore its series resistance effect, by formula (1) the relation between solar cell power output P and the output voltage U:

$P=U(I_{\mathrm{sc}}-I_0{e}^{\frac{\mathrm{qU}}{\mathrm{AKT}}})---\left(2\right)$

P _PVBe single order continuously differentiable nonlinear function, and with U _PVAs unique variable, it is asked about U _PVGradient:

$g_k=g_{\left(U_k\right)}=\frac{{\mathrm{dP}}_{\mathrm{PV}}}{{\mathrm{dU}}_{\mathrm{PV}}}{|}_{U_{\mathrm{PV}}=U_k}=(I_{\mathrm{sc}}-I_0{e}^{\frac{\mathrm{qU}}{\mathrm{AKT}}}-{\mathrm{<figure-callout\; id="0"\; label="I"\; filenames="HSA00000363605000021.png,HSA00000363605000023.png"\; state="\{\{state\}\}">I</figure-callout>}}_0\frac{\mathrm{qU}}{\mathrm{AKT}}{e}^{\frac{\mathrm{qU}}{\mathrm{AKT}}}){|}_{U=U_k}---\left(3\right)$

Must be based on the voltage iteration formula of optimum gradient by formula (1), (3):

U _k+1＝U _k+a _kg _k (4)

On this basis, establishing the solar cell maximum power point voltage is U _m, get by P=UI:

$\frac{\mathrm{dP}}{\mathrm{dU}}=I+U\frac{\mathrm{dI}}{\mathrm{dU}}---\left(5\right)$

So, when dP/dU＞0, U＜U _m, dI/dU＞-I/U; When dP/dU＜0, U＞U _m, dI/dU＜-I/U; When dP/dU=0, U=U _m, dI/dU=-I/U.

If dU=0, dI=0 then finds maximum power point, and the working point of photovoltaic generating system need not to adjust.If dU=0, dI ≠ 0 is according to the positive and negative Adjustment System reference voltage U of dI _rIf dU ≠ 0, then adjust quiescent potential with the relation the between-I/U, with the realization MPPT maximum power point tracking according to dI/dU.

Depart from maximum power point when far away when the working point, quiescent potential will be with bigger changes in amplitude; When the working point is positioned at maximum power point when nearer, quiescent potential will be with less changes in amplitude; When the working point is positioned at the maximum power point left side, system will increase quiescent potential, then reduce quiescent potential on the contrary.When the working point is very near apart from maximum power point,, the working point is settled out in this very little scope and thinks maximum power point because slope is very little.

Solar cell maximum power point output voltage is greatly about open circuit voltage U _OcAbout 75%, if when system start-up, the output voltage of solar cell directly is set to U _Oc75%, make the working point enter near the maximum power point from the beginning, promptly adopt the CVT start-up mode, wait to enter near the maximum power point back system and automatically switch into based on the conductance increment method of optimum gradient and carry out MPPT control, then can effectively improve the speed that it enters stable state.Wherein, look | dP _k|＜ε ₁, | dU _k|＜ε ₂, | dI _k|＜ε ₃Be dP _k, dU _k, dI _kApproximate zero situation.If satisfy dP _k=0, dU _k=dI _k=0, perhaps Δ G=G, then the output of apparent sun battery is to adjust quiescent potential on the left side or the right side of maximum functional point at maximum power point otherwise come the judgment task point according to the relation of Δ G and G.Work as dU _kEqual zero and dI _kWhen being not equal to zero, then according to dI _kWhether judge and increase or reduce quiescent potential to seek and to reach maximum power point greater than zero.

The above is a preferred embodiment of the present utility model only, is not limited to the utility model, and for a person skilled in the art, the utility model can have various changes and variation.All within spirit of the present utility model and principle, any modification of being done, be equal to replacement, improvement etc., all should be included within the claim scope of the present utility model.

Claims (6)

1. a photovoltaic power generation control system is characterized in that, comprising: system master system device and at least two photovoltaic DC assemblies; Wherein,

Each photovoltaic DC assembly comprises solar battery module, battery module and is connected in described solar battery module and battery module, and being used to follow the tracks of the maximum power point of solar battery module and making the direct voltage of described solar battery module output is the photovoltaic slave controller that described battery module discharges and recharges, and the battery module group string data in described at least two photovoltaic DC assemblies connects;

System master system device comprises inversion unit and is connected in inversion unit and the photovoltaic slave controller, and be used to control inversion unit described high-voltage dc voltage is carried out inversion, and monitor each photovoltaic DC assembly in real time and switch the unusual solar battery module of generation and/or the control unit of battery module in real time.

2. photovoltaic power generation control system according to claim 1 is characterized in that, described control unit passes through the described photovoltaic slave controller of a kind of connection in the following manner: RS485 bus, RS232 bus, RS422 bus.

3. photovoltaic power generation control system according to claim 1 is characterized in that described battery module comprises at least two storage batterys, and described at least two batteries string datas connect.

4. photovoltaic power generation control system according to claim 3 is characterized in that, described photovoltaic DC assembly also comprises and be connected in photovoltaic slave controller and battery module, and is used to switch unusual battery module switch matrix takes place.

5. according to each described photovoltaic power generation control system of claim 1 to 4, it is characterized in that, described photovoltaic power generation control system also comprises AC load, AC power and switching device shifter, the first input end of described switching device shifter connects AC power, second input of described switching device shifter connects the output of inversion unit, the output of described switching device shifter connects AC load, and the control end of described switching device shifter connects control unit.

6. photovoltaic power generation control system according to claim 5 is characterized in that described photovoltaic power generation control system also comprises the DC load that is connected in battery module.

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