CN100347928C - Photovoltaic parallel network device having reactive and harmonic compensation function - Google Patents
Photovoltaic parallel network device having reactive and harmonic compensation function Download PDFInfo
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- CN100347928C CN100347928C CNB2005100114319A CN200510011431A CN100347928C CN 100347928 C CN100347928 C CN 100347928C CN B2005100114319 A CNB2005100114319 A CN B2005100114319A CN 200510011431 A CN200510011431 A CN 200510011431A CN 100347928 C CN100347928 C CN 100347928C
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- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/50—Photovoltaic [PV] energy
- Y02E10/56—Power conversion systems, e.g. maximum power point trackers
Abstract
The present invention relates to a three-phase photovoltaic parallel network device with an idle work function and a harmonic compensation function, which belongs to the technical field of multifunction photovoltaic parallel network devices. The present invention is characterized in that a main power circuit of the three-phase photovoltaic parallel network device with an idle work function and a harmonic compensation function is composed of a photovoltaic array, a parallel network inverter and a parallel network filter inductor, wherein the structure of the inverter part can have various forms, such as a two-level structure, a three-level, a three-phase bus capacitance separated chain structure with a transformer, a three-phase uniform capacitance chain structure with a transformer and a chain structure without a transformer. When at work, the three-phase photovoltaic parallel network device not only can transmit active power to an electric network, but also can compensate idle work and harmonic components of current in the electric network in a real-time mode. The present invention enhances the utilization ratio of a solar energy battery board in photovoltaic generation, and at the same time, solves the working mode problems of a photovoltaic generation system at a time interval with bad light irradiation conditions namely that the photovoltaic generation system can not be idle but is used for compensating harmonic waves and idle work.
Description
Technical field
The present invention relates to a kind of multifunctional photovoltaic parallel Design of device, belong to multifunctional photovoltaic parallel device technique field.
Background technology
Exhaustion day by day along with traditional energy, huge change will take place in world energy sources 21 century, will progressively change the diversity of the regenerative resource unlimited based on resource, that cleaning is clean, compound energy resource structure into based on the energy resource structure of resource-constrained, with serious pollution fossil energy.Solar energy power generating belongs to the regenerative resource of cleaning, develops photovoltaic power generation technology and it is widely used to have important function for the shortage of alleviating conventional energy resource and minimizing environmental pollution.Under such prerequisite, the development of solar photovoltaic technology and application will become the focus that makes common people attract attention.
There are abundant solar energy resources and potential great market in China, painstaking efforts through more than 20 years, photovoltaic generation is all to have obtained very big progress aspect industrialization or in application facet, and has brought into play important function in the power construction away from the electrical network area.1996-2020 country solar photoelectric development plan according to portion of former State Grid formulates will reach 300MWp to the year two thousand twenty China solar photoelectric total capacity, and wherein the family expenses sunlight energy is 50MWp, and builds up 5 MW class sunlight power stations.At present, the commercialized degree of China's solar energy power generating application system is very low, and also there is a big difference with international advanced level in laboratory research work.Solar energy power generating is used in the past the generating network that isolates mostly, the generating on daytime, and by battery stores, use night.The storage battery loss is big, storage battery difficult treatment (pollution), and its characteristics also have: system effectiveness is low, operating cost is high, the electric poor stability.Therefore the basic outlet and the prospect of photovoltaic generation are to be incorporated into the power networks, and electrical network receives the photovoltaic energy as infinitely great stocking system.
Solar power generation will become a kind of important generation mode, but the cost of present solar cell also is not reduced to the stage of large-scale application, and most in the world pv grid-connected plants all are by government-funded, slower development.The function of photovoltaic grid-connected device and static compensator electric devices such as (STATCOM) is combined, help reducing the cost of photovoltaic plant, it can be applied in advance.Because mains by harmonics such as the STATCOM of the structure of photovoltaic combining inverter and broad research at present and reactive power compensator is very approaching, make photovoltaic grid-connected device both can provide certain active power, can realize the harmonic wave of function compensation electrical network of STATCOM and idle again to a certain extent.Can finish multinomial comprehensive function like this, reduce system synthesis indirectly, improve cost performance once the cover photovoltaic grid-connected device.The present invention has proposed three-phase photovoltaic grid-connected Design of device and control method under such background.Multinomial function is integrated: as to carry active power comprising the MPPT maximum power point tracking of photovoltaic array, compensation network reactive power, offset current harmonic wave with to electrical network.Power grid security and economical operation at present, very big to the STATCOM demand, especially the D-STATCOM demand of distribution system is bigger.With capacitor and mend and to compare, STATCOM uses electrolytic capacitor and does not need to use the expensive full membrane capacitance of nonpolarity aluminium foil, and desired volume is little, and the electric capacity cost is extremely low, both can send continuously adjustablely or absorbs idle.STATCOM can also improve electric network transportation ability, improves power supply quality and waveform, and control and influence trend improves power factor etc., realizes the purpose of economizing on electricity.
Summary of the invention
Primary and foremost purpose of the present invention is: at present photovoltaic power generation apparatus cost height, the shortcoming of function singleness proposes to have both photovoltaic grid-connected device idle and harmonic compensation function and meritorious output function, improves the cost performance of photovoltaic grid-connected device.Promote photovoltaic generation applying in China.
Technical scheme of the present invention is:
Have both idle and harmonic compensation function and meritorious output function photovoltaic grid-connected device, it is characterized in that, comprise photovoltaic array, described photovoltaic array provides the DC side of DC power supply to the three-phase multi-level inverter circuit, insert A, B, the C three-phase of electrical network behind three output series connection three-phase breakers of three-phase multi-level inverter circuit respectively, control this three-phase multi-level inverter circuit by the control circuit generation control signal of this photovoltaic grid-connected device.
Three-phase multi-electrical level inverter wherein can be any one in two kinds of multi-electrical level inverters of the following stated:
1. be with the discrete chain structure of three-phase bus electric capacity of transformer: a three-phase multi winding transformer, its former limit three-phase breaker of winding three-phase outlet series connection inserts electrical network, at least two windings that its every phase secondary all has quantity to equate, inductance of each secondary windings in series, perhaps use transformer self leakage inductance, in parallel with a H bridge circuit; The DC side parallel of every all mutually H bridge circuit connects, shared same electric capacity of every all mutually H bridges and photovoltaic array, and really good three-phase has three cover electric capacity and photovoltaic arrays.
2. the three-phase of band transformer is unified the electric capacity chain structure: a three-phase multi winding transformer, its former limit three-phase breaker of winding three-phase outlet series connection inserts electrical network, at least two windings that its every phase secondary all has quantity to equate, inductance of each secondary windings in series, perhaps use transformer self leakage inductance, in parallel with a H bridge circuit; The DC side parallel of the H bridge circuit that three-phase is all connects, shared same electric capacity of H bridge and photovoltaic array that three-phase is all.
Three-phase voltage current waveform THD was less than 0.5% when experimental result: Figure 10 showed the three-phase photovoltaic grid-connected device of two level that the present invention proposes to send out pure meritorious, Figure 11 show this device send perceptual when idle three-phase voltage current waveform THD less than 0.5%, Figure 12 shows that three-phase voltage current waveform THD was less than 0.5% when this device sent capacitive reactive power, Figure 13 shows the dynamic process that the three phase network electric current changed when this device dropped into electrical network, its response time is less than 0.5ms, and transient process is steadily reliable, is better than traditional indirect current control method.
Description of drawings
Fig. 1 is the overall schematic (two level structures) of three-phase photovoltaic grid-connected device;
Fig. 2 is among Fig. 1 100, i.e. the schematic diagram of two-level inverter;
Fig. 3 is the overall schematic (three level structures) of three-phase photovoltaic grid-connected device;
Fig. 4 is among Fig. 3 200, i.e. the schematic diagram of three-level inverters;
Fig. 5 is the overall schematic (the discrete chain structure of three-phase bus electric capacity of band transformation) of the three-phase photovoltaic grid-connected device that proposes of the present invention;
Fig. 6 is the overall schematic (three-phase of band transformation is unified the electric capacity chain structure) of the three-phase photovoltaic grid-connected device that proposes of the present invention;
Fig. 7 is the overall schematic chain structure of transformer (not with) of three-phase photovoltaic grid-connected device;
Fig. 8 is the schematic diagram of chain structure unit H bridge;
Fig. 9 is the structure composition diagram of model machine;
Figure 10 is that three-phase photovoltaic grid-connected device that the present invention proposes sends pure three-phase voltage current waveform figure when meritorious;
Figure 11 is that three-phase photovoltaic grid-connected device that the present invention proposes sends perceptual three-phase voltage current waveform figure when idle;
Figure 12 is three-phase photovoltaic grid-connected device that the present invention proposes a three-phase voltage current waveform figure when sending capacitive reactive power;
Figure 13 is three-phase photovoltaic grid-connected device that the present invention proposes a three phase network electric current variation diagram when dropping into electrical network;
Embodiment
Embodiment one
Referring to the overall schematic of three-phase photovoltaic grid-connected device shown in Figure 9, its inverter adopts three-phase two-level inverter shown in Figure 1.Whole device mainly is made up of photovoltaic array 9, inversion master power circuit device 800, output inductor 3, DSP control board 400.Make up a 25kVA, gaining merit is the three-phase two level photovoltaic grid-connected devices of 15kW (photovoltaic array peak power), if incorporate three-phase 380V power distribution network into, photovoltaic array 9 is composed as follows:
Need peak power 75W, 222 in the solar cell of open circuit voltage 23V;
Adopt 37 and be connected into row, then 6 row are together in parallel, form embodiment one needed photovoltaic array.Photovoltaic array is exported the Schottky diode 8 of will connect 50A, a reverse withstand voltage 1200V, to prevent that reverse current is to the damage of photovoltaic array under the abnormal conditions.The energy-storage travelling wave tube of photovoltaic array output adopts the electrochemical capacitor series connection of two 4700uF, withstand voltage 500V to use.Output inductor 3 is equivalent to a variable current source with the output current filtering in addition of photovoltaic grid-connected device.The design of inductance will be considered many-sided factor, and the peak value of output active current is
Inductance value is designed to 2mH, and this installs maximum reactive capability can arrive 20kVar.The main bridge circuit of two-level inverter can select for use 100A/1200V IGBT6 pipe integration module (take into account reactive capability, if simple for meritorious capacity can, also can use the integrated IPM of 6 pipes.Their difference is that mainly the IGBT module itself does not have drive circuit, needs user's own driver module that designs six road PWM drive circuits or buy some producer in the design combining inverter; IPM is an Intelligent Power Module, and it has been integrated in inside modules with No. six drive circuits, does not need the user to do unnecessary design work.All there is production in the many companies of IPM, for example can select FUJI company: 6MBP100RA120 for use.Too not near from saturation magnetic induction point when it should be noted that the design inductance, the sense value of inductance just can not change with the electric current by inductance like this, and promptly the linearity is good.
Embodiment two
According to the design of embodiment one, referring to the overall schematic of three-phase photovoltaic grid-connected (the band transformer) of employing shown in Figure 1 two level topologys device.The two level three-phase photovoltaic grid-connected devices of topology (band transformer) mainly are made up of photovoltaic array 9, two-level inverter 100, output inductor 3, the transformer 11 that is incorporated into the power networks, DSP control board 400.Make up the three-phase photovoltaic grid-connected device of a 15kW (photovoltaic array peak power), incorporate three-phase 380V power distribution network into if use transformer, and the former edge joint of transformer is gone into electrical network, and secondary connects three-phase photovoltaic grid-connected device output inductor 3, and no-load voltage ratio is 2: 1.Photovoltaic array 9 is composed as follows:
Need peak power 75W, 228 in the solar cell of open circuit voltage 23V;
Adopt 19 and be connected into row, then 12 row are together in parallel, form embodiment one needed photovoltaic array.Photovoltaic array is exported the Schottky diode 8 of will connect 100A, a reverse withstand voltage 600V, to prevent that reverse current is to the damage of photovoltaic array under the abnormal conditions.The energy-storage travelling wave tube of photovoltaic array output adopts the electrochemical capacitor of 4700uF, a withstand voltage 500V.Maximum reactive capability is 20kVar, takes into account reactive capability, selects the IGBT module of 200A/600V.The benefit that is incorporated into the power networks by transformer is:
If it is photovoltaic grid-connected device breaks down, little to the influence of electrical network;
The sense value of output inductor can be decreased to the 1/n among the embodiment one
2(n is a transformer voltage ratio) electric current only increases n doubly, and the design volume of output inductor will reduce greatly.
Embodiment three
The photovoltaic grid-connected device of many level structure is fit to be used in the jumbo device, incorporates the electrical network of mesohigh into.Fig. 3 has shown the photovoltaic grid-connected device that adopts the three-phase tri-level inverter.It contains:
A three-phase bridge 200 is made of A, B, three single-phase brachium pontis parallel connections of C, and each is single-phase to be made of four IGBT single tube serial connections that have an anti-phase diode, and the series connection mid point of each brachium pontis is connected in series with above-mentioned each three pole reactor 3 as the output of three-phase;
Bus capacitor, it is made of two electrochemical capacitors 231 and 232 serial connections, and this bus capacitor is connected to above-mentioned three level combining inverter DC side;
A phase, B phase, C be totally three catching diode series arms mutually: 221 and 222 series arms, 223 and 224 series arms, 225 and 226 series arms, two catching diode serial connections of above-mentioned every route constitute, the series connection mid point of every catching diode branch road is connected with the serial connection mid point of above-mentioned bus capacitor after linking to each other again, and the two ends of every catching diode branch road divide mid point to link to each other with the upper and lower half of every brachium pontis of IGBT mutually respectively.
The concrete connected mode of three-level inverters is referring to Fig. 4.
Embodiment four
The photovoltaic grid-connected device of many level structure is fit to be used in the jumbo device, incorporates the electrical network of mesohigh into.Fig. 5 has shown the three-phase photovoltaic grid-connected device of the discrete chain structure of three-phase bus electric capacity of band transformation, and it contains:
The discrete capacitor chain structure combining inverter 7 of band transformer, it is a three phase inverter bridge, each phase inverter bridge is made up of a plurality of H bridges 300, each H bridge is to be made of two two-tube series connection structure parallel connections of IGBT that have anti-phase diode, two serial connection mid points link to each other with the secondary input of transformer 11 by inductance 3 as output, and every all mutually its DC side parallels of H bridge get up;
Three bus capacitors 305,306,307, the electric capacity of three-phase respectively with every bridge DC side parallel of H mutually;
Three photovoltaic arrays, the photovoltaic array 9 of every phase, in parallel with above-mentioned three bus capacitors respectively;
Three Switching Power Supplies 13, their input are in parallel with above-mentioned three bus capacitors respectively, and Switching Power Supply provides power supply for the drive circuit of power switch;
A three-phase multi winding transformer 11, each winding of secondary link to each other with the output of corresponding single H bridge respectively; Wherein the H bridge circuit is referring to Fig. 8.
Embodiment five
The photovoltaic grid-connected device of many level structure is fit to be used in the jumbo device, incorporates the electrical network of mesohigh into.Fig. 6 has shown that the three-phase of band transformation unifies the three-phase photovoltaic grid-connected device of electric capacity chain structure, and it contains:
The three-phase of band transformation is unified electric capacity chain structure combining inverter, it is a three phase inverter bridge, each phase inverter bridge is made up of a plurality of H bridges, each H bridge is to be made of two two-tube series connection structure parallel connections of IGBT that have anti-phase diode, two serial connection mid points link to each other with the secondary input of transformer by inductance as output, and all its DC side parallels of H bridge of three-phase get up;
Bus capacitor 308, same electric capacity respectively with every bridge DC side parallel of H mutually;
A photovoltaic array 9, its bus capacitor parallel connection;
A Switching Power Supply 13, its input is in parallel with above-mentioned bus capacitor, and Switching Power Supply provides power supply for the drive circuit of power switch;
A three-phase multi winding transformer 11, each winding of secondary link to each other with the output of corresponding single H bridge respectively;
Wherein the H bridge circuit is referring to Fig. 8.
Embodiment six
The photovoltaic grid-connected device of many level structure is fit to be used in the jumbo device, incorporates the electrical network of mesohigh into.Fig. 7 has shown that not it contains with the three-phase photovoltaic grid-connected device of the chain structure of transformer:
The structure that three-phase H bridge circuit 300 is composed in series, whenever, be composed in series by at least two H bridges, three-phase H bridge series circuit three outputs separately couple together, three-phase H bridge series circuit another output separately three inductance 3 of connecting respectively, and the three-phase breaker 2 of connecting again inserts electrical networks; The all H bridge circuit dc bus sides of three-phase all have photovoltaic array 9 and electric capacity separately respectively.
Wherein the principal character of chain structure combining inverter 300 is Fig. 8: drawn by IGBT single tube 301, the 302 series connection back mid point X that have the inverse parallel diode, 303,304 series connection back mid point Y draw, and constitute a H bridge circuit.
In order to satisfy the power supply needs of power switch driver circuit, the dc bus of each H bridge is all as the direct current input side of the required Switching Power Supply 13 of this H bridge circuit.
Claims (2)
1, have both idle and the photovoltaic grid-connected device harmonic compensation function, it is characterized in that, comprise photovoltaic array, described photovoltaic array provides the DC side of DC power supply to the three-phase multi-level inverter circuit, insert the A of electrical network behind three-phase multi-level inverter circuit series transformer and the three-phase breaker respectively, B, the C three-phase, control circuit generation control signal by this photovoltaic grid-connected device is controlled this three-phase multi-level inverter circuit, three-phase multi-level inverter circuit wherein comprises: a three-phase multi winding transformer, connect described three-phase breaker of the three-phase outlet of its former limit winding inserts electrical network, at least two windings that the every phase secondary of described transformer all has quantity to equate, each secondary windings in series inductance, perhaps use transformer self leakage inductance, in parallel with a H bridge circuit; The DC side parallel of every all mutually H bridge circuit connects, shared same electric capacity of every all mutually H bridge circuits and described photovoltaic array, three-phase has three cover electric capacity and described photovoltaic arrays, and described photovoltaic array provides the DC side of DC power supply to the three-phase multi-level inverter circuit.
2, have both idle and the photovoltaic grid-connected device harmonic compensation function, it is characterized in that, comprise at least one photovoltaic array, this photovoltaic array provides the DC side of DC power supply to the three-phase multi-level inverter circuit, insert the A of electrical network behind three-phase multi-level inverter circuit series transformer and the three-phase breaker respectively, B, the C three-phase, control circuit generation control signal by this photovoltaic grid-connected device is controlled this three-phase multi-level inverter circuit, three-phase multi-level inverter circuit wherein comprises: a three-phase multi winding transformer, connect described three-phase breaker of its former limit winding three-phase outlet inserts electrical network, at least two windings that the every phase secondary of described transformer all has quantity to equate, inductance of each secondary windings in series, perhaps use transformer self leakage inductance, in parallel with the H bridge circuit; The DC side parallel of the H bridge circuit that three-phase is all connects, shared same electric capacity of H bridge and described photovoltaic array that three-phase is all, and described photovoltaic array provides the DC side of DC power supply to the three-phase multi-level inverter circuit.
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Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US5373433A (en) * | 1992-05-05 | 1994-12-13 | Trace Engineering | Power inverter for generating voltage regulated sine wave replica |
CN1271207A (en) * | 1999-04-20 | 2000-10-25 | 三洋电机株式会社 | Operation method for power supply system with parallel connected invertor and power change-over system |
JP2002354679A (en) * | 2001-05-29 | 2002-12-06 | Kyocera Corp | Power conversion device, and power supply system using it |
US6750391B2 (en) * | 2001-10-25 | 2004-06-15 | Sandia Corporation | Aternating current photovoltaic building block |
-
2005
- 2005-03-15 CN CNB2005100114319A patent/CN100347928C/en not_active Expired - Fee Related
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US5373433A (en) * | 1992-05-05 | 1994-12-13 | Trace Engineering | Power inverter for generating voltage regulated sine wave replica |
CN1271207A (en) * | 1999-04-20 | 2000-10-25 | 三洋电机株式会社 | Operation method for power supply system with parallel connected invertor and power change-over system |
JP2002354679A (en) * | 2001-05-29 | 2002-12-06 | Kyocera Corp | Power conversion device, and power supply system using it |
US6750391B2 (en) * | 2001-10-25 | 2004-06-15 | Sandia Corporation | Aternating current photovoltaic building block |
Non-Patent Citations (2)
Title |
---|
A multilevel voltage-source inverter with separate DCsourcesfor static var generation. Fang Zheng Peng,Jih.ShengLai,JohnW.McKeever,et al.IEEE Transactions on Industry Applications,Vol.第32卷 No.第5期. 1996 * |
Design considerations for three-phase gridconnectedphotovoltaic inverters. Raymond M.Hudson,Michael R.Behmke,et al.Proceedings of Twenty.Ninth IEEE Photovoltaic Specialists Conference. 2002 * |
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
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WO2009137969A1 (en) * | 2008-05-15 | 2009-11-19 | Xuan Kun | A photovoltaic grid-connected inverter device without a transformer and its control method |
US8125807B2 (en) | 2008-05-15 | 2012-02-28 | Xuan Kun | Transformerless photovoltaic grid-connecting inverting device and control method thereof |
CN102185533A (en) * | 2011-05-23 | 2011-09-14 | 北京交通大学 | Stored energy type standard-Z source photovoltaic power generation control system and method |
CN102185533B (en) * | 2011-05-23 | 2013-05-15 | 北京交通大学 | Stored energy type standard-Z source photovoltaic power generation control system and method |
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