KR20130116613A - Solar photovoltaic generating system using series-parallel variable array - Google Patents

Abstract

PURPOSE: A photovoltaic system using series-parallel variable arrays increases the running time of a solar system by changing the series-parallel combination of a solar module array circuit, thereby improving overall utilization. CONSTITUTION: A photovoltaic driver circuit (100) converts light energy from sun into electrical energy. The photovoltaic driver circuit includes a main array part (101), a first secondary array part (102), and a second secondary array part (103). An inverter part (300) converts the electrical energy converted into DC into AC energy and supplies it to a load (500). A detection part (400) measures solar radiation or load delivered through the inverter part. A control part (200) controls the operation of a switch included in the photovoltaic driver circuit. [Reference numerals] (110) First array part; (120) Second array part; (130) Third array part; (140) Fourth array part; (150) Fifth array part; (160) Sixth array part; (170) Seventh array part; (180) Eighth array part; (190) Ninth array part; (200) Control part; (300) Inverter part; (400) Detection part; (500) Load

Description

SOLAR PHOTOVOLTAIC GENERATING SYSTEM USING SERIES-PARALLEL VARIABLE ARRAY}

The present invention relates to a photovoltaic power generation system, and more particularly to a photovoltaic power generation system using a series-parallel variable array that can change the photovoltaic drive circuit according to the detected solar radiation or load.

In general, solar photovoltaic is one of solar energy generation technology. In other words, solar light energy is directly converted into electrical energy using a photoelectric converter called a solar module. Since solar power generation uses light, it is possible to generate electricity at night even on a cloudy day, so the efficiency of using solar energy is higher than that of thermal power generation. If it falls short of the voltage, it cannot generate power, and the array circuit must be designed according to Equation 1 below considering the allowable input voltage range (MPPT) that is different for each inverter manufacturer during initial design.

Inverters are divided into transformer type and transformerless type. In the case of transformer type three-phase inverter, MPPT is 210 ~ 450 [V] or 290 ~ 600 [V], which is narrow in the range of 240 to 310, but operating starting voltage (Vdc) This is the normal MPPT minimum voltage, and in the case of a transformer type, the MPPT is 200 to 800 [V] wide and the range is 600, but the operation start voltage (Vdc) is 400 [V], which is different from the MPPT minimum voltage. In case of transformer type inverter, the starting voltage (Vdc) is usually specified as the MPPT minimum voltage, but the actual module array output must be started at least 10% higher than the inverter MPPT minimum voltage.

Inverter manufacturers around the world, including Korea, are developing technologies to make solar power generation as long as possible by widening the range of MPPT, but above all, design and error of photovoltaic power generation system (output by serial / parallel combination of array modules) In order to increase the uptime and improve the power generation efficiency while minimizing the mismatch between the voltage and the input voltage of the inverter, the conventional fixed and parallel circuit configuration, which is not easy to change after installation, can be developed for more than 25 years after installation. In this regard, MPPT control based on one inverter is limited, and frequent control of the MPPT of the inverter due to external factors such as insolation and load fluctuation is one of the factors of deterioration of inverter durability.

In the solar power generation system according to the prior art, when the operation start voltage is applied to the inverter, the inverter is operated to generate power, and the module output becomes unstable (just before sunset or just after sunrise, or on a cloudy day or a clear day). When applied to the inverter, there is no way to prevent the inverter from shutting down because it exceeds the limit of MPPT control. When the voltage range of the MPPT is extended, the efficiency of the inverter is lowered and the solar radiation is a good factor, thus reducing power generation.

 In addition, if the inverter breaks down after the system installation, due to the different MPPT of each manufacturer, if the inverter reflected in the initial design cannot be obtained, there may be a situation in which a large construction to change the serial / parallel configuration of the fixed module may be required. It is a situation that has arisen as a problem of solar power plant in operation.

The background technology of the present invention is described in Republic of Korea Patent Application Publication No. 10-0934932 (Registration of Jan. 06, 2010).

Therefore, the technical problem to be achieved by the present invention is to provide a photovoltaic power generation system using a variable array that enables the operation of the photovoltaic power generation system without interruption of the inverter even during sunset sunrise and rapidly changing climate without daily shutdown of the inverter. .

The solar power generation system using a series-parallel variable array according to an embodiment of the present invention for achieving the technical problem, a plurality of solar modules in series connected, the first stage is connected to the first pole of the inverter A first to third array comprising a plurality of solar modules connected in series, and a fourth to sixth array connected to the second ends of the first to third arrays, a plurality of solar modules connected in series A first end is connected to the second end of the fourth to sixth arrays, respectively, and a second end is connected to the second pole of the inverter; Sensing unit for measuring the amount of load delivered, and as the measured amount of solar radiation or load decreases, the number of solar modules connected in series in one array increases, and the measured amount of solar radiation or negative The more the amount is increased, and a control unit for controlling the connection between the first to ninth array to increase the number of arrays in parallel connection.

When the measured amount of solar radiation is less than a first reference sun love and greater than a second reference sun love, the controller includes a first pole of the inverter, the first array, the second array, and a second pole of the inverter. A second path including a first path, a first pole of the inverter, the second array, the fifth array, and a second pole of the inverter, a first pole of the inverter, the third array, and the sixth path A third path including an array and a second pole of the inverter, and a fourth path including the first pole, the seventh array, the eighth array, the ninth array, and the second pole of the inverter. You can.

When the measured solar radiation amount is smaller than the second reference sun love and greater than the third reference sun love, the controller may include the first pole, the first array, the fourth array, the seventh array, and the inverter of the inverter. A fifth path including a second pole of the sixth path including a first pole of the inverter, the second array, the fifth array, the eighth array, and a second pole of the inverter, and a A seventh path including the first pole, the third array, the sixth array, the ninth array, and the second pole of the inverter may be formed.

When the measured amount of solar radiation is smaller than the third reference solar radiation, the controller may include the first pole, the first array, the fourth array, the fifth array, the second array, and the first array of the inverter. An eighth path including two poles, and a first pole of the inverter, the seventh array, the eighth array, the ninth array, the third array, a sixth array, and a second pole of the inverter. The ninth path can be formed.

The controller may compare the measured load amount with a first reference load amount when the measured solar radiation amount is greater than a first reference sunray, and when the measured load amount is larger than a first reference load amount, the first pole of the inverter, A tenth path including the first array and the second pole of the inverter, an eleventh path including the first pole of the inverter, the second array and the second pole of the inverter, a first pole of the inverter, A twelfth path including the third array and a second pole of the inverter, a thirteenth path including the first pole of the inverter, the fourth array, a seventh array, and a second pole of the inverter, of the inverter A fourteenth path including a first pole, the fifth array, an eighth array, and a second pole of the inverter; and a first pole of the inverter, the sixth array, a ninth array, and a third pole of the inverter. It is possible to form a fifteenth path comprising.

The controller may form the first to fourth paths when the measured load amount is less than the first reference load amount and is greater than the second reference load amount, and the measured load amount is less than the second reference load amount and is greater than the third reference load amount. If it is large, the fifth to seventh paths may be formed, and if the measured load is smaller than the third reference load, the eighth and ninth paths may be formed.

The number of solar modules included in each of the first to third arrays may be the number of solar modules included in each of the fourth to sixth arrays or the number of solar modules included in the seventh to ninth arrays, respectively. Can be more.

The number of solar modules included in the first to third arrays, the number of solar modules included in the fourth to sixth arrays, and the number of solar modules included in the seventh to ninth arrays, respectively. The ratio of 2: 1: 1 may be.

The sum of the number of photovoltaic modules included in each of the first to third arrays and the number of photovoltaic modules included in each of the fourth to sixth arrays is each of the photovoltaic modules included in the seventh to ninth arrays. It may correspond to N times the number of (N is a natural number).

The number of solar modules included in each of the first to third arrays is the same, and the number of solar modules included in the fourth to sixth arrays is the same, respectively, and included in the seventh to ninth arrays. The number of photovoltaic modules can be the same.

Thus, according to the present invention, by varying the series-parallel combination of the photovoltaic module array circuit to increase the operating time of the photovoltaic system to improve the overall utilization rate, and to prevent the DC voltage drop of the array module whose output is unstable according to the amount of solar radiation or load It prevents the open voltage rise of the array module in winter. In addition, the inverter does not stop due to the module array DC overvoltage, and the durability of the inverter may be increased by improving the inverter MPPT control function. In addition, the compatibility of solar modules and inverters is improved, and the use of spare modules can optimize the output of inverters compared to real-time module outputs.

This will ultimately be linked with the smart grid system (voltage and current control) to compensate for the problem that the generation efficiency is lower in summer and winter than in spring and autumn, which are disadvantages of the photovoltaic power generation system, which is the representative of the distributed power supply. It can help a lot in the management of national electricity supply and demand during the summer and winter when the usage is booming.

1 is a block diagram of a solar power system according to an embodiment of the present invention.
2 is a circuit diagram illustrating a photovoltaic driving circuit according to an embodiment of the present invention.
3 is a flowchart illustrating a control method of a controller according to an exemplary embodiment of the present invention.
4A to 4E illustrate current paths according to a control operation of the controller.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is referred to as being "connected" to another part, it includes not only "directly connected" but also "electrically connected" with another part in between . Also, when an element is referred to as "comprising ", it means that it can include other elements as well, without departing from the other elements unless specifically stated otherwise.

In addition, the expression that voltage is maintained throughout the specification indicates that even if the potential difference between two specific points changes over time, the change is within an allowable range in the design or the cause of the change is due to parasitic components that are ignored in the design practice of those skilled in the art. Include cases by. In addition, since the threshold voltage of a semiconductor device (transistor, diode, etc.) is very low compared to the discharge voltage, the threshold voltage is regarded as 0V and approximated.

In addition, the switches described in the entire specification include all elements used to change the opening and closing state of the electric circuit, and may include power control semiconductor elements such as SCR, GTO thyristor, bipolar transistor, MOSFET, IGBT and the like.

1 is a block diagram of a solar power system according to an embodiment of the present invention. As shown in FIG. 1, the solar power generation system includes a solar power generation driving circuit 100, a control unit 200, an inverter unit 300, and a detection unit 400.

The photovoltaic driving circuit 100 converts and collects light energy incident from the sun into electrical energy, and generates a high voltage by connecting a plurality of photovoltaic modules in series.

The photovoltaic drive circuit 100 includes a main array unit 101, a first auxiliary array unit 102, and a second auxiliary array unit 103, and includes a main array unit 101 and a first auxiliary array unit ( 102 and the second auxiliary array unit 103 includes arrays in which a plurality of solar cell modules are connected in series.

According to the exemplary embodiment of the present invention, the main array unit 101 includes a first array unit 110, a second array unit 120, and a third array unit 130, and includes a first array unit 110, The second array unit 120 and the third array unit 130 are exemplified as including a plurality of solar modules connected in series. In addition, the first auxiliary array unit 102 includes a fourth array unit 140, a fifth array unit 150, and a sixth array unit 160, and the second auxiliary array unit 103 includes the seventh array unit. 170, an eighth array unit 180, and a ninth array unit 190. Likewise, the fourth array unit 140 to the ninth array unit 190 are exemplified as including a plurality of solar modules connected in series.

In addition, first stages of the first array unit 110, the second array unit 120, and the third array unit 130 are connected to the positive poles of the inverter, respectively, and the second stages are the fourth array units, respectively. 140 and the first end of the fifth array unit 150 and the sixth array unit 160. The second ends of the fourth array unit 140, the fifth array unit 150, and the sixth array unit 160 are respectively the seventh array unit 170, the eighth array unit 180, and the ninth array. It is connected to the first end of the part 190. The second ends of the seventh array unit 170, the eighth array unit 180, and the ninth array unit 190 are connected to negative electrodes of the inverter, respectively. ,

The control unit 200 is connected to the photovoltaic drive circuit 100 and the sensing unit 400, and to prevent the DC voltage of the array module whose output is unstable according to the amount of insolation and load detected by the sensing unit 400. In order to control the operation of the switch included in the photovoltaic drive circuit 100. In particular, the controller 200 changes the connection state of the first to ninth array units according to the measured solar radiation or load to form a different number of serial arrays. That is, as the measured solar radiation amount or load decreases, the controller 200 increases the number of photovoltaic modules connected in series in one array, and as the measured solar radiation amount or load increases, the number of arrays connected in parallel. The connection state between the first array unit and the ninth array unit is controlled so as to increase.

In addition, the controller 200 blocks the voltage transmitted from the photovoltaic drive circuit 100 to the inverter unit 300 when the voltage exceeds the allowable voltage.

The inverter unit 300 converts the electric energy converted into direct current by the photovoltaic drive circuit 100 into alternating energy and supplies it to various loads 500, and the sensing unit 400 measures the current solar radiation amount and the load amount. The measured data is transferred to the controller 200.

In this case, when the amount of insolation is large, the magnitude of the DC voltage input to the inverter unit 300 is also large. Therefore, the sensing unit 400 may detect the magnitude of the DC voltage applied to the inverter unit 300 instead of the amount of insolation.

Hereinafter, a photovoltaic driving circuit according to an embodiment of the present invention will be described in detail with reference to FIG. 2.

2 is a circuit diagram illustrating a photovoltaic driving circuit according to an embodiment of the present invention. As shown in FIG. 2, the photovoltaic driving circuit 100 includes a first array unit 110 to a ninth array unit 190 and a plurality of switches.

According to FIG. 2, the first array unit 110, the second array unit 120, and the third array unit 130 corresponding to the main array unit 101 each include ten solar modules connected in series. do. That is, the first array unit 110 has ten solar modules A1, A2, ..., A9, A10 connected in series, and the second array unit 120 has ten solar modules B1, B2. ,..., B9, B10 are connected in series, and in the third array unit 130, ten solar modules C1, C2,..., C9, C10 are connected in series.

Here, the photovoltaic module converts light energy incident from the sun into a direct current voltage. Assuming that the open circuit voltage of the photovoltaic module is 36.9 V, when 10 solar modules are connected in series, the open voltage applied to one array is 369V, equivalent to 36.9V * 10.

The first ends of the first array unit 110, the second array unit 120, and the third array unit 130 are connected to the positive poles of the inverter unit 300, respectively. The first ends of the fourth array unit 140, the fifth array unit 150, and the sixth array unit 160 respectively corresponding to the first auxiliary array unit 102 are connected.

The fourth array unit 140, the fifth array unit 150, and the sixth array unit 160 each include five solar modules connected in series. That is, the fourth array unit 140 has five solar modules D1, ..., D5 connected in series, and the fifth array unit 150 has five solar modules E1, ..., E5 connected in series. In the sixth array unit 160, five solar modules F1,..., F5 are connected in series.

The second ends of the fourth array unit 140, the fifth array unit 150, and the sixth array unit 160 are respectively the seventh array unit 170 and the eighth corresponding to the second auxiliary array unit 103. The first ends of the array unit 180 and the ninth array unit 190 are connected.

The seventh array unit 170, the eighth array unit 180, and the ninth array unit 190 each include five solar modules connected in series. That is, in the seventh array unit 170, five solar modules G1,..., G5 are connected in series, and the eighth array unit 180 includes five solar modules H1,..., H5. In the ninth array unit 190, five solar modules I 1,..., I 5 are connected in series. The second ends of the seventh array unit 170, the eighth array unit 180, and the ninth array unit 190 are connected to the negative pole of the inverter unit 300.

As illustrated in FIG. 2, the plurality of first switches S1 may be disposed between the first array unit 110 and the fourth array unit 140, between the second array unit 120 and the fifth array unit 150. Located between the third array unit 130 and the sixth array unit 160, respectively. Therefore, among the plurality of solar modules included in the first array unit 110, the second array unit 120, and the third array unit 130, the photovoltaic modules A10, B10, and C10 located at the end may be the first. First solar modules D1, E1, and F1 of a plurality of solar modules included in the fourth array unit 140, the fifth array unit 150, and the sixth array unit 160 through the switch S1, respectively. Connected with

The plurality of second switches S2 may be disposed between the fourth array unit 140 and the seventh array unit 170, between the fifth array unit 150 and the eighth array unit 180, and the sixth array unit ( Located between the 160 and the ninth array unit 190, respectively. Therefore, among the plurality of solar modules included in the fourth array unit 140, the fifth array unit 150, and the sixth array unit 160, the solar modules D5, E5, and F5, which are positioned last, are second First solar modules G1, H1, and I1 of the plurality of solar modules included in the seventh array unit 170, the eighth array unit 180, and the ninth array unit 190 through the switch S2, respectively. Connected with

The third switch S3, the fourth switch S4, and the fifth switch S5 are the last solar light of the first array unit 110, the second array unit 120, and the third array unit 130, respectively. The first end is connected to the modules A10, B10, C10. In addition, the sixth switch S6, the seventh switch S7, and the eighth switch S8 are the first sunlight of the fourth array unit 140, the fifth array unit 150, and the sixth array unit 160, respectively. The first stage is connected to the modules D1, E1, and F1, and the second stage is connected to the positive pole of the inverter 300, respectively.

In addition, the ninth switch S9, the tenth switch S10, and the eleventh switch S11 may be the last sunlight of the fourth array unit 140, the fifth array unit 150, and the sixth array unit 160, respectively. The first end is connected to the modules D5, E5, F5.

The twelfth switch S12 is connected between the seventh array unit 170 and the eighth array unit 180, and the thirteenth switch S13 is the eighth array unit 180 and the ninth array unit 190. ) Is connected between. That is, the twelfth switch S12 is connected between the last solar module G5 of the seventh array unit 170 and the first solar module H1 of the eighth array unit 180, and the thirteenth switch S13. ) Is connected between the last solar module H5 of the eighth array unit 180 and the first solar module I1 of the ninth array unit 190. In addition, a first end of the fourteenth switch S14 is connected to the last photovoltaic module I5 of the ninth array unit 190.

In addition, the fifteenth switch S15 is connected between the positive (+) pole of the inverter unit 300 and the first solar module G1 of the seventh array unit 170, and the sixteenth switch S16 is the seventh array. The first end is connected to the last photovoltaic module G5 of the unit 170. In addition, a first stage of the seventeenth switch S17 is connected to the last photovoltaic module H5 of the eighth array unit 180, and a first stage of the eighteenth switch S18 is connected to the sixteenth switch S16. Is connected to the second stage. The first end of the nineteenth switch S19 is connected to the second end of the seventeenth switch S17, and the second end is connected to the negative pole of the inverter unit 300. In addition, the twentieth switch S20 is connected to the negative (-) pole of the inverter unit 300.

In addition, a first end of the twenty-first switch S21 is connected to the second end of the eighteenth switch S18, and a second end of the twenty-first switch S21 is connected to the negative (−) pole of the inverter unit 300. The 22nd switch S22 has a first end connected to the last solar module G5 of the seventh array unit 170 and a second end connected to the negative pole of the inverter unit 300.

In the twenty-third switch S23, a first end is connected to the last solar module H5 of the eighth array unit 180, and a second end is connected to the negative pole of the inverter unit 300. . In addition, the 24 th switch S24 has a first end connected to the last photovoltaic module I5 of the ninth array unit 190, and a second end connected to a negative (−) pole of the inverter unit 300.

The twenty-fifth switch S25 is connected between the first end of the twenty-first switch S21 and the first end of the first solar module B1 of the second array unit 120. A first end is connected to the first end of the twenty-seventh switch S27, and a second end is connected to the second end of the last solar module I5 of the ninth array unit 190. The 27 th switch S27 has a second end connected to the positive pole of the inverter 300, the 28 th switch S28 has a first end connected to the positive pole of the inverter 300, The second end is connected to the first end of the first solar module B1 of the second array unit 120.

Hereinafter, a method of controlling the operation of the controller 200 in response to the detected amount of insolation and load will be described with reference to FIGS. 3 to 4E. 3 is a flowchart illustrating a control method of a controller according to an exemplary embodiment of the present invention, and FIGS. 4A to 4E illustrate current paths according to a control operation of the controller.

First, the control unit 200 receives the measured data from the sensing unit 400 (S310), where the measured data includes the measured solar radiation and the load of the solar power generation system as described above, and the inverter unit 300 It may also include the magnitude of the input DC voltage.

The control unit 200 receiving the measurement data compares the measured solar radiation amount with the first reference solar radiation amount (S320).

If the magnitude of the measured solar radiation is smaller than the first reference solar radiation, the measured solar radiation is compared with the second reference solar radiation (S330).

If the magnitude of the measured insolation amount is smaller than the first reference insolation amount and larger than the second reference insolation amount, the controller 200 may include a plurality of first switches S1, ninth switch S9, tenth switch S10, and 11th switch S11, 12th switch S12, 13th switch S13, 15th switch S15, 18th switch S18, 19th switch S19, 20th switch S20, 21st The switch S21, the 24th switch S24, the 27th switch S27, and the 28th switch S28 are turned on.

Then, as shown in FIG. 4A, 15 solar modules are connected in series to 60 solar modules to form four new solar module arrays (S340).

That is, since the amount of solar radiation is high in the clear weather or hot summer, the magnitude of the DC voltage applied to the inverter unit 300 increases, and the inverter unit 300 may be stably driven. Therefore, according to the embodiment of the present invention, in order to increase the power factor and smooth the flow of the current, a relatively small number of 15 solar modules are connected in series, and the control unit 200 generates the photovoltaic driving circuit so that four parallel connections are generated. Change (100).

By the operation of the control unit 200, the first path through the positive (+) pole of the inverter, the first array unit 110, the fourth array unit 140 and the negative (-) pole of the inverter and the positive ( The second path through the pole, the second array unit 120, the fifth array unit 150 and the negative pole of the inverter, the positive pole of the inverter, the third array unit 130, 6th path through the array unit 160 and the negative (-) pole of the inverter, the positive (+) pole of the inverter, the seventh array unit 170, the eighth array unit 180, the ninth array unit 190 ) And a fourth path through the negative (-) pole of the inverter.

In more detail, the first path includes the positive (+) pole of the inverter unit 300, the ten solar modules A1, A2,..., A9, A10, and first included in the first array unit 110. Five solar modules D1,..., D5 included in the switch S1, the fourth array unit 140, the ninth switch S9, the eighteenth switch S18, the twenty-first switch S21, and an inverter Negative (-) of the negative electrode 300.

The second path includes ten solar modules B1, B2,..., B9, and B10 included in the positive (+) pole of the inverter unit 300, the twenty-eighth switch S28, and the second array unit 120. ), The first switch S1, the five solar modules E1,..., E5 included in the fifth array unit 150, the tenth switch S10, the nineteenth switch S19, and the inverter unit 300. ) Negative pole.

In addition, the third path includes ten solar modules C1, C2,..., C9, and C10 included in the positive pole of the inverter unit 300, the twenty-seventh switch S27, and the third array unit 130. , Five solar modules F1,..., F5 included in the first switch S1, the sixth array unit 160, the eleventh switch S11, the twentieth switch S20, and the inverter unit 300. It includes the negative pole of.

Finally, the fourth path includes five solar modules G1,..., G5, and twelfth included in the positive (+) pole of the inverter unit 300, the fifteenth switch S15, and the seventh array unit 170. Five solar modules included in the switch S12, the eight solar modules H1,..., H5 included in the eighth array unit 180, the thirteenth switch S13, and the five solar modules included in the ninth array unit 190. (I1, ..., I5), the 24th switch S24, and the negative (-) pole of the inverter part 300.

When the measured amount of solar radiation is smaller than the second reference solar radiation, the measured solar radiation is compared with the third reference solar radiation (S350).

Here, the third reference insolation amount is smaller than the second reference insolation amount, and the second reference insolation amount is smaller than the first reference insolation amount, and the first reference insolation amount, the second reference insolation amount and the third reference insolation amount are easy according to weather conditions or power generation environment. Design can be changed.

If the magnitude of the measured solar radiation amount is smaller than the second reference solar radiation amount and larger than the third reference solar radiation amount, the controller 200 may include a plurality of first switches S1, second switches S2, 16th switches S16, and Turn on the seventeenth switch S17, the eighteenth switch S18, the nineteenth switch S19, the twenty first switch S21, the twenty-fourth switch S24, the twenty-seventh switch S27, and the twenty-eighth switch S28 Let's do it.

Then, as shown in FIG. 4B, 20 solar modules are connected in series to 60 solar modules to form three new solar module arrays (S360).

That is, the fifth path through the positive pole of the inverter, the first array unit 110, the fourth array unit 140, the seventh array unit 170, and the negative pole of the inverter and the positive pole of the inverter Sixth path through the positive electrode, the second array unit 120, the fifth array unit 150, the eighth array unit 180, and the negative electrode of the inverter, and the positive electrode of the inverter The seventh path passes through the third array unit 130, the sixth array unit 160, the ninth array unit 190, and the negative electrode of the inverter.

In more detail, the fifth path includes the positive (+) pole of the inverter unit 300, the ten solar modules A1, A2,..., A9 and A10 included in the first array unit 110, and the first. Five solar modules included in the switch S1, the five solar modules D1,..., D5 included in the fourth array unit 140, the second switch S2, and five solar modules included in the seventh array unit 170. (G1, ..., G5), the sixteenth switch S16, the eighteenth switch S18, the twenty-first switch S21, and the negative (-) pole of the inverter unit 300.

In addition, the sixth path includes ten solar modules B1, B2,..., B9, and B10 included in the positive (+) pole of the inverter unit 300, the twenty-eighth switch S28, and the second array unit 120. , Five solar modules E1, ..., E5 included in the first switch S1 and the fifth array unit 150, five switches included in the second switch S2, and the eighth array unit 180. The photovoltaic module (H1, ..., H5), the seventeenth switch (S17), the nineteenth switch (S19) and the negative (-) pole of the inverter unit 300.

The seventh path includes ten solar modules C1, C2,..., C9, and C10 included in the positive electrode, the twenty-seventh switch S27, and the third array unit 130 of the inverter unit 300. ), Five solar modules F1,..., F5 included in the first switch S1 and the sixth array unit 160, five switches included in the second switch S2, and the ninth array unit 190. Photovoltaic modules (I1, ..., I5), the 24th switch (S24) and the negative (-) poles of the inverter unit 300.

If the measured amount of solar radiation is smaller than the third reference solar radiation, that is, when the amount of solar radiation is short, such as immediately before sunrise or in cloudy weather, the controller 200 may include a plurality of first switches S1, ninth switches S9, and 10th switch S10, 11th switch S11, 12th switch S2, 13th switch S13, 15th switch S15, 18th switch S18, 19th switch S19, 20th The switch S20, the twenty fifth switch S25, and the twenty sixth switch S26 are turned on.

Then, as shown in FIG. 4C, 30 new solar modules are connected to 60 solar modules in series to form two new solar module arrays (S370).

That is, since the amount of insolation in cloudy weather or winter is small, the magnitude of the DC voltage applied to the inverter unit 300 is also reduced, which may result in unstable driving of the inverter unit 300. Therefore, according to the embodiment of the present invention, in order to compensate the voltage applied to the inverter unit 300, the highest voltage must be transmitted to the inverter unit 300, and thus 30 solar modules are connected in series and two parallel connections. The control unit 200 changes the photovoltaic driving circuit 100 so as to be generated.

By the operation of the controller 200, the positive (+) pole of the inverter, the first array unit 110, the fourth array unit 140, the fifth array unit 150, the second array unit 120, and the inverter The eighth path passing through the negative pole and the positive pole of the inverter, the seventh array unit 170, the eighth array unit 180, the ninth array unit 190, and the third array unit 130. The ninth path through the sixth array unit 160 and the negative (-) pole of the inverter is formed.

In more detail, the eighth path includes the positive (+) pole of the inverter unit 300, the ten solar modules A1, A2,..., A9 and A10 included in the first array unit 110, and the first. Five solar modules D1,..., D5 included in the switch S1, the fourth array unit 120, the ninth switch S9, the eighteenth switch S18, the twenty-fifth switch S25, and the fifth solar module D1. Ten solar modules B1, B2,..., B9, B10 included in the second array unit 120, the first switch S1, and five solar modules E1 included in the fifth array unit 150. , ..., E5, the tenth switch S10, the nineteenth switch S19, and the negative (−) pole of the inverter unit 300.

In addition, the ninth path includes five solar modules G1,..., G5, and a twelfth switch included in the positive pole of the inverter unit 300, the fifteenth switch S15, and the seventh array unit 170. (S12), five solar modules H1,..., H5 included in the eighth array unit 180, five solar modules included in the thirteenth switch S13, and the ninth array unit 190 ( 10 solar modules C1, C2,..., C14, C15 included in I1,..., I5, 26th switch S26, and third array unit 130, 1st switch S1, 6th Five solar modules F1,..., F5 included in the array unit 160, an eleventh switch S11, a twentieth switch S20, and a negative (−) pole of the inverter unit 300 are included.

Therefore, according to the embodiment of the present invention, when the amount of solar radiation is low or the magnitude of the DC voltage applied to the inverter unit 300 is small, as many solar modules as possible form a serial array of the inverter unit 300. Minimize driving instability.

On the other hand, when the magnitude of the measured solar radiation amount is greater than the first reference solar radiation amount, the controller 200 receives the detected load amount from the detection unit 400 and compares the measured load amount with the first reference load amount (S380).

If the magnitude of the measured load is greater than the first reference load, the controller 200 may include the plurality of second switches S2, the third switch S3, the fourth switch S4, the fifth switch S5, 6th switch S6, 7th switch S7, 8th switch S8, 21st switch S21, 22nd switch S22, 23rd switch S23, 24th switch S24, 27 The switch S27 and the twenty eighth switch S28 are turned on.

Then, as shown in FIGS. 4D and 4E, 10 solar modules are connected in series to 60 solar modules to form six new solar module arrays (S390).

That is, since the amount of solar radiation is high in the clear weather or hot summer, the magnitude of the DC voltage applied to the inverter unit 300 increases, and the inverter unit 300 may be stably driven. Therefore, according to the embodiment of the present invention, in order to increase the power factor and smooth the flow of current, a relatively small number of 10 solar modules are connected in series, and the control unit 200 generates a solar power generation driving circuit such that six parallel connections are generated. Change (100).

By the operation of the control unit 200, a tenth path passing through the positive (+) pole of the inverter, the first array unit 110 and the negative (-) pole of the inverter, the positive (+) pole of the inverter, and the second array unit 11 and the eleventh path through the negative pole of the inverter, the positive pole of the inverter, the third array unit 130 and the twelfth path through the negative pole of the inverter, positive of the inverter ( 13th path through the positive electrode, the fourth array unit 140, the seventh array unit 170 and the negative electrode of the inverter, the positive electrode of the inverter, the fifth array unit 150, 8th path through the array unit 180 and the negative pole of the inverter, the positive pole of the inverter, the sixth array unit 160, the ninth array unit 190, and the negative of the inverter A fifteenth path through the pole is formed.

4D and 4E are actually operating in one circuit, but for convenience of understanding, the tenth path, the eleventh path, and the twelfth path are shown in FIG. 4D, and the thirteenth path, the fourteenth path, and the fifteenth path are shown in FIG. 4e.

In more detail, the tenth path includes the positive (+) pole of the inverter unit 300, the ten solar modules A1, A2,..., A9 and A10 included in the first array unit 110, and the third. The negative electrode (-) of the switch S3, the twenty-first switch S21, and the inverter unit 300 is included.

The eleventh path includes ten solar modules B1, B2,..., B9, and B10 included in the positive electrode, the twenty-eighth switch S28, and the second array unit 120 of the inverter unit 300. ), The fourth switch S4 and the negative (-) pole of the inverter unit 300.

In addition, the twelfth path includes ten solar modules C1, C2,... And a negative (−) pole of the fifth switch S5 and the inverter unit 300.

In addition, the thirteenth path includes five solar modules D1,..., D5, and second included in the positive (+) pole of the inverter unit 300, the sixth switch S6, and the fourth array unit 140. It includes a switch (S2), five solar modules (G1, ..., G5) included in the seventh array unit 170, the 22nd switch (S22) and the negative (-) pole of the inverter unit 300.

In addition, the fourteenth path includes five solar modules E1,..., E5, and the second switch included in the positive pole of the inverter unit 300, the seventh switch S7, and the fifth array unit 150. (S2), five solar modules H1,..., H5 included in the eighth array unit 180, a twenty-third switch S23, and a negative (−) pole of the inverter unit 300.

In addition, the fifteenth path includes five solar modules F1,..., F5, and second included in the positive pole of the inverter unit 300, the eighth switch S8, and the sixth array unit 160. It includes a switch (S2), five solar modules (I1, ..., I5) included in the ninth array unit 190, the negative (-) poles of the twenty-fourth switch (S24) and the inverter unit 300.

On the other hand, if the magnitude of the measured load amount is smaller than the first reference load amount, the controller 200 compares the measured load amount with the second reference load amount (S400). If the magnitude of the measured load amount is smaller than the first reference load amount and larger than the second reference load amount, the controller 200 may connect 15 solar modules in series of 60 solar modules as shown in FIG. The switch is controlled to form the optical module array (S410).

Forming four paths (path 1, path 2, path 3, and path 4) by the controller 200 by controlling the switch has been described with reference to step S340 and FIG. 4A, and thus redundant descriptions thereof will be omitted.

When the magnitude of the measured load amount is smaller than the second reference load amount, the controller 200 compares the measured load amount with the third reference load amount (S420).

Here, the third reference load amount is smaller than the second reference load amount, the second reference load amount is smaller than the first reference load amount, and the first reference load amount, the second reference load amount, and the third reference load amount are easy according to the load capacity or the generation environment. Design can be changed.

If the magnitude of the measured load amount is smaller than the second reference load amount and larger than the third reference load amount, the control unit 200 may connect 20 solar modules in series for 60 solar modules as shown in FIG. The switch is controlled to form the optical module array (S430).

The control unit 200 controls the switch to form three paths (paths 5, 6, and 7), as described above with reference to step S360 and FIG. 4B, and thus descriptions thereof will be omitted.

If the measured load is smaller than the third reference load, the control unit 200 connects 30 solar modules in series to 60 solar modules as shown in FIG. 4C to form two new solar module arrays. To control the switch to (S440).

Forming two paths (path 8 and path 9) by controlling the switch by the control unit 200 has been described with reference to step S370 and FIG. 4C, and thus descriptions thereof will be omitted.

Therefore, according to the embodiment of the present invention, when the amount of solar radiation is high or the amount of load transmitted through the inverter unit 300 is large, the number of solar modules connected in series is reduced and the number of parallel connections is increased for stable current flow. Increase it.

Meanwhile, according to the exemplary embodiment of the present invention, the main array unit 101, the first auxiliary array unit 102, and the third auxiliary array unit 103 have been described as including three array units, respectively, It can be changed according to the surrounding environment.

In addition, the first array unit 110, the second array unit 120, and the third array unit 130 each include ten solar modules connected in series, and the fourth array units 140 to ninth. The array unit 190 is illustrated as including five solar modules connected in series, but the number of solar modules can be changed in design according to the specifications of the solar module or the power generation environment.

However, the number of solar modules included in each of the first array unit 110, the second array unit 120, and the third array unit 130 is the fourth array unit 140 to the ninth array unit 160. It will be seen that the efficiency of the photovoltaic power generation system according to an embodiment of the present invention increases when the number of photovoltaic modules included in each is greater.

In particular, the number of solar modules included in each of the first to third array units (10), the number of solar modules included in the fourth to sixth array units (5), and the seventh to ninth arrays, respectively. The ratio of the number (5) of solar modules included in each part should be 2: 1: 1.

In addition, the sum of the number of photovoltaic modules connected in series to the array included in the main array unit 101 and the number of photovoltaic modules connected in series to the array included in the first auxiliary array unit 102 are the second auxiliary array units 103. Is designed to maintain N times (N is a natural number) the number of photovoltaic modules connected in series to the array.

That is, in the embodiment of the present invention, the number of photovoltaic modules connected in series to the array included in the main array unit 101 is 10, and the number of photovoltaic modules connected in series to the array included in the first auxiliary array unit 102. Is five, and the number of solar modules connected in series to the array included in the second auxiliary array unit 103 is five, and N is three.

Here, the N value should be in multiples of the number of arrays included in the main array unit 101, the first auxiliary array unit 102, and the second auxiliary array unit 103, and according to an embodiment of the present invention, Since the array unit 101, the first auxiliary array unit 102, and the second auxiliary array unit 103 each include three array units, it can be seen that they correspond to N values.

For example, the number of photovoltaic modules connected in series to the array included in the main array unit 101 is 15, and the number of photovoltaic modules connected in series to the array included in the first auxiliary array unit 102 is five. When the number of photovoltaic modules connected in series to the array included in the second auxiliary array unit 103 is 5, N becomes 4, in this case, the main array unit 101 and the first auxiliary array unit 102. The second auxiliary array section 103 preferably includes four, eight, or twelve array sections, each of multiples of four.

As described above, according to the embodiment of the present invention, when the weather is cloudy, or before the sunrise or in winter, when the amount of solar radiation or the voltage applied to the inverter is low, or when the load is small, the solar cell module connected in series is reduced in parallel. By increasing the number, the voltage drop of the inverter can be compensated so that the inverter can be driven stably. On the contrary, in the case of clear and sunny weather, midday or summer, when the amount of solar radiation or the voltage applied to the inverter is high, or when the load is large, the array connected in parallel is increased and the number of solar modules connected in series is reduced. Allow current and voltage to be reliably applied.

Thus, according to the present invention, by varying the series-parallel combination of the photovoltaic module array circuit to increase the operating time of the photovoltaic system to improve the overall utilization rate, and to prevent the DC voltage drop of the array module whose output is unstable according to the amount of solar radiation and load It prevents the open voltage rise of the array module in winter. In addition, the inverter does not stop due to the module array DC overvoltage, and the durability of the inverter may be increased by improving the inverter MPPT control function. In addition, the compatibility of solar modules and inverters is improved, and the use of spare modules can optimize the output of inverters compared to real-time module outputs.

This will ultimately be linked with the smart grid system (voltage and current control) to compensate for the problem that the generation efficiency is lower in summer and winter than in spring and autumn, which are disadvantages of the photovoltaic power generation system, which is the representative of the distributed power supply. It can help a lot in the management of national electricity supply and demand during the summer and winter when the usage is booming.

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of right.

100: photovoltaic drive circuit, 101: main array unit,
102: first auxiliary array portion, 103: auxiliary array portion,
110: first array portion, 120: second array portion,
130: third array portion, 140: fourth array portion,
150: fifth array portion, 160: sixth array portion,
170: seventh array portion, 180: eighth array portion,
190: ninth array unit 200: control unit,
300: inverter unit, 400: detection unit,
500: load

Claims (10)

First to third array comprising a plurality of solar modules connected in series, the first end is connected to the first pole of the inverter,
A fourth to sixth array including a plurality of solar modules connected in series and having a first end connected to the second ends of the first to third arrays, respectively;
A seventh through ninth array including a plurality of solar modules connected in series, each having a first end connected to a second end of the fourth to sixth arrays, and a second end connected to a second pole of the inverter. ,
Detection unit for measuring the amount of solar radiation or the load delivered through the inverter, And
As the measured solar radiation or load decreases, the number of photovoltaic modules connected in series in one array increases, and as the measured solar radiation or load increases, the number of arrays connected in parallel increases. Photovoltaic power generation system using a serial-to-parallel variable array including a control unit for controlling the connection state between the ninth array. The method of claim 1,
When the measured solar radiation amount is less than the first reference sun love and larger than the second reference sun love,
The control unit,
A first path including a first pole of the inverter, the first array, the second array, and a second pole of the inverter,
A second path including a first pole of the inverter, the second array, the fifth array, and a second pole of the inverter,
A third path including a first pole of the inverter, the third array, the sixth array and a second pole of the inverter, and
And a fourth path including a first pole of the inverter, the seventh array, an eighth array, a ninth array, and a second pole of the inverter. 3. The method of claim 2,
When the measured amount of solar radiation is less than the second reference sun love and greater than the third reference sun love,
The control unit,
A fifth path including the first pole of the inverter, the first array, the fourth array, the seventh array, and the second pole of the inverter,
A sixth path including the first pole of the inverter, the second array, the fifth array, the eighth array, and the second pole of the inverter, and
And a seventh path including a first pole of the inverter, the third array, the sixth array, the ninth array, and the second pole of the inverter. The method of claim 3,
When the measured amount of solar radiation is less than the third reference solar love,
The control unit,
An eighth path comprising a first pole of said inverter, said first array, said fourth array, said fifth array, said second array and said second pole of said inverter, and
Parallel-parable variable array forming a ninth path including the first pole of the inverter, the seventh array, the eighth array, the ninth array, the third array, the sixth array, and the second pole of the inverter. Photovoltaic Power Generation System. 5. The method of claim 4,
The control unit,
If the measured solar radiation amount is greater than the first reference sunrays, the measured load amount is compared with the first reference load amount,
If the measured load is greater than the first reference load,
A tenth path including a first pole of the inverter, the first array and a second pole of the inverter,
An eleventh path including a first pole of the inverter, the second array and a second pole of the inverter,
A twelfth path including a first pole of the inverter, the third array and a second pole of the inverter,
A thirteenth path including a first pole of the inverter, the fourth array, a seventh array, and a second pole of the inverter;
A fourteenth path including a first pole of the inverter, the fifth array, an eighth array, and a second pole of the inverter,
The solar power generation system using a series-parallel variable array to form a fifteenth path including the first pole of the inverter, the sixth array, the ninth array and the third pole of the inverter. The method of claim 5,
The control unit,
And forming the first to fourth paths when the measured load amount is smaller than the first reference load amount and larger than the second reference load amount.
Forming the fifth to seventh paths when the measured load amount is smaller than the second reference load amount and larger than a third reference load amount,
And a series and parallel variable array for forming the eighth and ninth paths when the measured load amount is smaller than the third reference load amount. The method of claim 1,
The number of solar modules included in each of the first to third arrays may be the number of solar modules included in each of the fourth to sixth arrays or the number of solar modules included in the seventh to ninth arrays, respectively. PV system with more and more parallel arrays. The method of claim 1,
The number of solar modules included in the first to third arrays, the number of solar modules included in the fourth to sixth arrays, and the number of solar modules included in the seventh to ninth arrays, respectively. Photovoltaic power generation system using a serial-to-parallel variable array with a ratio of 2: 1: 1. 9. The method of claim 8,
The sum of the number of photovoltaic modules included in each of the first to third arrays and the number of photovoltaic modules included in each of the fourth to sixth arrays is each of the photovoltaic modules included in the seventh to ninth arrays. Photovoltaic power generation system using a series-parallel variable array corresponding to N times the number of (N is a natural number). The method of claim 1,
The number of solar modules included in each of the first to third arrays is the same, and the number of solar modules included in the fourth to sixth arrays is the same, respectively, and included in the seventh to ninth arrays. The number of photovoltaic modules used is a photovoltaic power generation system using the same series-parallel variable array.

Images