KR101535513B1 - Extensible switching device for the string channel of the solar power system - Google Patents

Abstract

The present invention relates to an extensible string channel switching device for a solar power system. The present invention provides the extensible string channel switching device for the solar power system which includes an input connector part (10) to which power generated from a multichannel solar cell string (100) formed with n channels is inputted, a power sensing unit (40) which measures an amount of power, a switch control unit (80) which outputs a switching control signal, an output connector part (60), a switch part (50) which is formed between the power sensing unit (40) and the output connector part (60), and an extensible connector part (90) which is connected to a first extension line (91) and a second extension line (92). The present invention changes the scale of a solar power generation system according to the installation area of a solar cell.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a solar cell,

The present invention relates to a solar cell module comprising: an input connector section (10) for receiving power produced from a multi-channel solar cell string (100) formed of n channels (n is a natural number); A power sensing unit 40 for measuring the amount of electric power when the power input to the input connector unit 10 is inputted through the fuse 20 and the reverse current prevention diode unit 30; A switch controller 80 for receiving power amount information sensed by the power sensing unit 40 and outputting a switching control signal; An output connector unit 60 formed at a rear end of the power sensing unit 40 to connect the respective channels to n-channel inverters 200; The power control unit 80 is connected between the power sensing unit 40 and the output connector unit 60 and connects each channel power to the channel output connector unit 60 or the neighboring channel output connector unit 60 according to a control signal of the switch control unit 80 60) connected to the switch unit (50); A first extension line 91 connecting a line to the switch unit 50 and an extension connector unit 90 connecting a second extension line 92 connected and controlled by the switch unit 50; (M is a natural number), when the solar cell string channel is required to be m by m, and the extension connector unit 90 is sequentially connected to the connection line 300 to connect the solar cell string channel To the extended string channel switching device of the photovoltaic power generation system.

Solar cells convert sunlight energy into electrical energy, which can be connected in series and in parallel to be used in a structure that can withstand natural environments and certain external impacts.

A solar cell is the smallest unit cell of a solar cell. A solar cell module containing several solar cells in an airtight package is called a solar cell module. The solar cell modules are connected in series and parallel to obtain a DC voltage and a generated power Is a solar cell array, and a string means a circuit in which the solar cell modules are connected in series so as to satisfy a predetermined output voltage as a circuit meaning of the solar cell array.

Recently, global efforts are being made to expand and spread renewable energy such as solar and wind power due to the surge in oil prices, environmental regulations, and voluntary efforts to preserve the environment by reducing CO2 emissions.

The photovoltaic power generation system converts and supplies the DC power to the usable AC power in the solar cell module. Various string configurations are possible to derive the maximum conversion efficiency according to the local environment characteristics.

In order to improve the system efficiency and simplify the circuit according to the technology trend and inverter unit price, various attempts have been made to construct a string and multiple inverters, and a suitable string and a circuit configuration method of multiple inverters have been derived according to the solar power generation situation .

The circuit suitable for the environment (weather) is divided into a centralized type, a sub-array type, a parallel type, and a string type, and each advantage can be derived according to the configuration method. However, It is impossible to provide it at the same time.

Therefore, it is necessary to preliminarily review the configuration method that best suits the situation in accordance with the site situation, and in some way, there is a problem that the time and cost required for re-operation after the installation of the system is additionally required.

In order to solve the above problem, the prior art 10-1445711 has been filed. The above-mentioned prior art 10-1445711 is a next generation solar power generation technology that simultaneously satisfies the system efficiency and economy, And a system fault is determined through a pattern of a value (a string output value or a sensing value of an environmental sensor) to switch to one of a string type mode, a parallel type mode, and a subarray type mode, And a technique for inducing efficiency.

The above-mentioned prior art 10-1445711 has a disadvantage in that it is constrained to the number of solar cell string outputs and the number of inverters, which vary depending on the installation position of the solar cell, regardless of its effectiveness.

In other words, when a solar cell is installed in a specific place, the number of solar cell string channels varies depending on the area of weather, climate, and latitude. In order to use the above-mentioned registered patent, It is inconvenient to configure each of the switching devices.

According to this, there is a disadvantage that the workload and difficulty level of the solar cell installation site are constrained by the solar cell installation area.

In addition, there is a problem that it is difficult to expand or reduce the already installed switching device depending on the circumstances that occur later.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to improve the solar cell system scale according to the installed area of the solar cell, It is an object of the present invention to provide a solar cell expansion type string channel switching device capable of expanding or reducing the size of a device.

In order to accomplish the above object, the present invention provides a solar cell module comprising: an input connector unit for inputting power generated from a multi-channel solar cell string formed of n channels (n is a natural number); A power sensing unit 40 for measuring the amount of electric power when the power input to the input connector unit 10 is inputted through the fuse 20 and the reverse current prevention diode unit 30; A switch controller 80 for receiving power amount information sensed by the power sensing unit 40 and outputting a switching control signal; An output connector unit 60 formed at a rear end of the power sensing unit 40 to connect the respective channels to n-channel inverters 200; The power control unit 80 is connected between the power sensing unit 40 and the output connector unit 60 and connects each channel power to the channel output connector unit 60 or the neighboring channel output connector unit 60 according to a control signal of the switch control unit 80 60) connected to the switch unit (50); A first extension line 91 for connecting a line to the switch unit 50 and an extension connector unit 90 for connecting a second extension line 92 connected and controlled by the switch unit 50 to a device installed adjacent to the switch unit 50 ; (M is a natural number), when the solar cell string channel is required to be m by m, and the extension connector unit 90 is sequentially connected to the connection line 300 to connect the solar cell string channel And an expansion unit for expanding the string channel switching device of the photovoltaic generation system.

The switch control unit 80 further includes a communication unit 70 for inputting and outputting information about a control command to and from an external device so as to report a control command of the switch control unit 80 to the external device, And the control command of the switch control unit 80 is calculated based on the received information.

The switch unit 50 is formed in n-1 branches d and n nodes c connecting each channel and a neighboring channel and the first extension line 91 of the extension connector unit 90 ) Is a branch connected to the first node and the second extension line 92 of the extension connector unit 90 is a branch connected to the n-th node, and the n-1 branch and the second extension line 92 The switch controller 80 includes a first switching unit 51 for connecting or disconnecting a branch according to a control signal of the switch control unit 80 and a switch control unit 80 formed between the n nodes and the output connector unit 60, And a second switching unit 52 for connecting or disconnecting each channel to or from the output connector unit 60 according to a control signal of the control unit 50. [

In addition, when the m connecting line 300 connects m (m is a natural number) solar power system expansion type string channel switching devices, the xth first extension line 91 is connected to the (x-1) (X: 1, 2, ..., m-1), and the mth second extension line 92 is connected to the (x + 1) th first extension line 91, The second extension line 92 is connected to the first extension line 91. When the output of the n × m solar cell string channels is controlled to be switched to the n × m inverters 200, The solar cell system is preferably a solar cell expansion-type string channel switching device.

According to the present invention described above, it is possible to improve the scale of the photovoltaic power generation system device according to the installation area of the solar cell by improving the patent No. 10-1445711, and after the installation, There is an advantage in that a PV system expansion-type string channel switching device is provided.

1 is a block diagram of the present invention
Figure 2 shows a prior art switching connection schematic
Fig. 3 is a circuit diagram of an embodiment in which two channels of the present invention are used as unit channels
FIG. 4 is a schematic view showing a switch unit according to an embodiment of the present invention,
FIG. 5 is a schematic diagram illustrating a unit-channel switch unit connection scheme for an embodiment using two channels as a unit channel according to the present invention.
6 is a circuit diagram showing the configuration of the entire connection line of the present invention

Hereinafter, the present invention will be described with reference to the drawings. In the following description of the present invention, a detailed description of related arts or configurations will be omitted when it is determined that the gist of the present invention may be unnecessarily obscured will be.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to be exemplary, self-explanatory, allowing for equivalent explanations of the present invention.

3 is a circuit diagram showing an embodiment of the present invention in which two channels are used as a unit channel, and FIG. 4 is a block diagram of a two-channel FIG. 5 is a schematic view illustrating a connection between unit channels of a switch unit according to an embodiment using two channels as a unit channel according to the present invention. Fig.

As shown in the drawing, the present invention includes a solar cell string 100, an input connector unit 10, a fuse 20, a reverse current prevention diode unit 30, a power sensing unit 40, a switch control unit 80, The first extension line 91, the second extension line 92, the extension connector 90, the communication unit 70, and the connection line 300, And a substrate (3).

As described above, the present invention improves on the prior art 10-1445711, and the solar cell string 100 of the present invention is a circuit meaning of the solar cell array. In order to satisfy a predetermined output voltage, Are connected in series to form a single circuit.

The channel of the present invention is a line through which the output of the solar cell string 100 is transmitted. One channel is composed of one + terminal and one terminal.

The present invention enables N multichannel solar cell strings 100 that vary according to the characteristics of installation sites to be formed as a sum of unit channels having a certain scale.

N = n x m (m is a natural number)

n: Number of solar cell string channels forming a unit channel

m: the number of unit channels to be installed

That is, according to the present invention, a total of N solar cell strings 100 are formed by combining unit channels each having n solar cell strings and m unit channels, and the configuration of each unit channel.

The input connector unit 10 of the present invention is an input terminal unit in which n out of N multi-channel solar cell strings are grouped and divided into unit channels.

That is, n (n is a natural number) input to the input connector unit 10, and the n channel determined by the input connector unit 10 of the present invention is a unit channel defined in the present invention.

2 and 3. As shown in FIGS. 3 and 5, the entire channel constructed as shown in FIG. 2 can be formed of unit channels of n = 2. As shown in FIG. 4, n = 3 As shown in FIG.

It is needless to say that n is a natural number, and the minimum channel constituting the unit channel of the present invention is one channel with n = 1.

When the power input to the input connector unit 10 is inputted through the fuse 20 and the reverse current prevention diode unit 30, the power sensing unit 40 outputs the power amount of the solar cell string 100, to be.

The switch control unit 80 of the present invention receives a power amount information sensed by the power sensing unit 40 and outputs a switching control signal.

The switch control unit 80 determines a weather condition and a string fault condition according to a sensing signal of the power sensing unit 40 and then determines the number of connections of the inverter 200 connected to the rear end and outputs a switching signal.

A detailed description of the control operation of the switch control unit 80 is given in Japanese Patent Laid-Open No. 10-1445711, and thus a detailed description thereof is omitted. In the above-mentioned prior art 10-1445711, The present invention is different from the first embodiment in that a switch control unit 80 for controlling each unit channel is formed as shown in FIG.

The output connector unit 60 is formed at a rear end of the power sensing unit 40 and is connected to the n-channel inverters 200.

The present invention is characterized in that an n-channel solar cell string 100 is connected to an input connector 10, and the input connector 10 and the output connector 60 are independently connected to a channel wire, One inverter 200 is connected to each channel in the inverter 60, and each solar cell string 100 channel is connected to the inverter 200 in a one-to-one correspondence.

The switch unit 50 is formed between the power sensing unit 40 and the output connector unit 60 and outputs each channel power to the corresponding channel output connector 60 as shown in FIG. (Eg, ch0 - ch0) or connected to a neighboring channel output connector 60 (eg, ch0 - ch1 or ch2) (described in more detail below).

The switch unit 50 of the present invention is constituted by a unit channel unlike the case of the prior art 10-1445711, There is a need for a connection means.

4, the extension connector 90 of the present invention includes a first extension line 91 connecting the line to the switch unit 50 and a second extension line 91 connected and controlled by the switch unit 50, 92 to an apparatus installed in the neighborhood, which is a constituent element different from the above-described patent document 10-1445711. (More detailed description will be given later.)

4, the switch unit 50 includes an additional line, a first switching unit 51 and a second switching unit 52, which are connection lines between channels, The additional line is formed in n-1 branches and n nodes connecting each channel and a neighboring channel in a unit channel.

For example, when the present invention is composed of three unit channels as shown in Fig. 4, it becomes an additional line consisting of two branches (d) and three nodes (c).

In the case of three unit channels as shown in FIG. 4, the first node (c1) and the second node (c1) are divided into the first node (c1) and the second node (c2), a third node (c3), a first branch (d1), and a second branch (d2).

4, the first extension line 91 of the extension connector unit 90 is a branch connected to the first node c1, and the second extension line 92 of the extension connector unit 90 is a branch And becomes a branch connected to the third node (c3) (the last nth node in n unit channels).

4 and 5, the extension connector portion connected to the first extension line 91 is connected to the first extension connector 90 (hereinafter, referred to as " extension connector 90 " -1) and the extension connector portion connected to the second extension line 92 is divided into the second extension connector 90-2.

Therefore, when the switch unit 50 includes the first extension line 91 and the second extension line 92 in the unit channel of the present invention, the total number of branches of the present invention is n + 1.

In the present invention, when one channel is used as a unit channel, only the first extension line 91 and the second extension line 92 are formed in one branch.

The switch unit 50 of the present invention includes a first switching unit 51 and a second switching unit 52. The first switching unit 51 switches between the n-1 branch d and the second switching unit 52, And is formed of n switches formed on the extension line 92.

The first switching unit 51 is driven according to a control signal of the switch control unit 80 to connect or disconnect each branch.

The second switching unit 52 of the present invention is formed of n switches formed between the n nodes c and the output connector unit 60 and outputs each channel according to a control signal of the switch control unit 80 (60).

Therefore, the output connector unit 60 of each channel line input to the input connector unit 10 according to the control command of the switch control unit 80 is wholly or partially or alternatively selected.

According to the above description, the first extension line 91 of the present invention 'connects the line to the switch unit 50' means that a branch is formed at the first node c1 of the switch unit 50 Means that the second extension line 92 is connected and controlled by the switch unit 50 is connected to the branch at the nth node cn of the switch unit 50, (51).

Therefore, according to the present invention, the outputs of the channels of the solar cell 100 of the n-channel constituting the unit channel are detected and the outputs of the weak channels for driving the one inverter 200 are summed up to 1 The inverter which drives the inverter can be rested.

2, the multi-channel solar cell string is divided into unit channels as shown in FIG. 3, and the extension connector unit 90 Each unit channel is combined to complete a photovoltaic power generation system of a multi-channel solar cell string realizing the technology of the prior art 10-1445711.

The present invention further includes a communication unit 70 connected to the switch control unit 80 for inputting and outputting information on a control command of the switch control unit 80 to and from an external device, as shown in FIG.

The external device is a switch control unit 80 of a unit channel installed adjacent to the external device or an external integrated control device 700 such as a PC or a PNC.

The control unit 70 receives the control information of the neighboring unit channel from the switch control unit 80 and produces control information of the unit channel and transmits the control information to another neighboring unit channel.

Accordingly, the multi-channel solar cell string divided into unit channels by the communication unit 70 is integratedly controlled as in the case of the prior art 10-1445711.

The communication unit 70 reports the control command of the switch control unit 80 to the external integrated control device 700 and receives the information of the external integrated control device 700 to control the switch control unit 80 Command can be operated.

In this case, as shown in FIG. 6, the switch units of the respective unit channels may be integrated by the external integrated controller 700 so as to be controlled as one device.

As described above, according to the present invention, when the solar cell string channel is N (N = n × m (m is a natural number)), m pieces of the present invention having n unit channels are sequentially arranged, And the extension connector 90 is connected.

As shown in FIG. 2, the communication unit 70 can be connected to the wired / wireless communication line 70-1, and the extension connector unit 90 can be connected to the connection line 300.

As shown in FIG. 5, the connection line 300 connects the xth first extension line to the (x-1) th extension line, and the xth second extension line connects the (x + 1) (X: 1, 2 ... m)

In the present invention, the outputs of N (N = nxm) solar cell string channels are connected to N inverters by line connection of the connection line 300, and integrated switching control is performed as in the case of the prior art 10-1445711 .

2, the last m-th second extension line 92 is connected to the first extension connector 90-i connected to the first extension line 91 through the second extension connector 90-2, 1 by a loop connection line 300-1 so that the entire switch section is loop-formed.

Such a loop configuration advantageously eliminates the load imbalance generated in the inverter of the first unit channel and the inverter of the last unit channel, so it is desirable to configure the loop as much as possible.

In addition, since the entire channel is constituted by the sum of the unit channels, the connection line 300 is formed as the board connector 310 as shown in FIG. 7 for the convenience of installation of the unit channel, 3).

The substrate 3 also includes lines for connecting the communication units 70 of the unit channels.

The x-th first extension line of the board connector 310 is connected to the (x-1) th second extension line, and the x-th second extension line is connected to the (x + 1) (X: 1, 2,... M) and the first and the last unit channels are made to be rovings, while arranging m unit channels in the substrate, It becomes possible to constitute a photovoltaic system circuit for controlling switching of the output of the solar cell string channel to n × m inverters.

Accordingly, the present invention is characterized in that the extension connector portion 90 of the present invention having a unit channel is inserted into a prefabricated substrate 3, the output terminal of the solar cell string 100 is connected to the input connector portion 10 of the present invention Channel photovoltaic system according to the prior art can be completed by connecting the input terminal of the inverter 200 to the output connector unit 60 of the present invention.

With this configuration, if the number of unit channels is adjusted according to the installation location, the apparatus can be easily installed in conjunction with the solar cell string at the installation site. If the solar cell string is expanded or removed due to the change of the condition, So that it can be easily changed and installed.

It will be apparent to those skilled in the art that the present invention may be embodied in many other specific forms without departing from the spirit or essential characteristics thereof.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. It is to be understood that the technical spirit of the present invention is to the extent possible.

3: substrate 10: input connector section
20: Fuse 30: Reverse current prevention diode part
40: power sensing section 50: switch section
51: first switching unit 52: second switching unit
60: Output connector part
70: communication unit 70-1: wire / wireless communication line
80: Switch control section
90: extension connector portion
90-1: first extension connector 90-2: second extension connector
91: first extension line 92: second extension line
100: Solar cell string 200: Inverter
300: With connection
300-1: Loop connecting line

Claims (4)

an input connector 10 for receiving power produced from a multi-channel solar cell string 100 formed of n channels (where n is a natural number);
A power sensing unit 40 for measuring the amount of electric power when the power input to the input connector unit 10 is inputted through the fuse 20 and the reverse current prevention diode unit 30;
A switch controller 80 for receiving power amount information sensed by the power sensing unit 40 and outputting a switching control signal;
An output connector unit 60 formed at a rear end of the power sensing unit 40 to connect the respective channels to n-channel inverters 200;
The power control unit 80 is connected between the power sensing unit 40 and the output connector unit 60 and connects each channel power to the channel output connector unit 60 or the neighboring channel output connector unit 60 according to a control signal of the switch control unit 80 60) connected to the switch unit (50);
A first extension line 91 connecting a line to the switch unit 50 and an extension connector unit 90 connecting a second extension line 92 connected and controlled by the switch unit 50;
An apparatus comprising:
When the number of solar cell string channels is n x m (m is a natural number), m solar cell arrays are arranged, and the extension connector units 90 are sequentially connected to the connection line 300 to expand the solar cell string channels A solar cell power system extension string channel switching device.
The apparatus of claim 1, wherein the switch control unit (80)
And a communication unit (70) for inputting and outputting information on the control command to and from an external apparatus
Wherein the control command of the switch control unit (80) is reported to the external device and the control command of the switch control unit (80) is calculated by receiving the information of the external device.
3. The apparatus according to claim 1 or 2, wherein the switch unit (50)
And is formed in n-1 branches d and n nodes c connecting each channel and a neighboring channel
The first extension line 91 of the extension connector 90 is a branch connected to the first node,
The second extension line 92 of the extension connector 90 is a branch connected to the n-th node,
A first switching unit 51 formed on the (n-1) branch and the second extension line 92 for connecting or disconnecting a branch according to a control signal of the switch control unit 80,
And a second switching unit 52 formed between the n nodes and the output connector unit 60 and connecting or disconnecting each channel to or from the output connector unit 60 according to a control signal of the switch control unit 80 Wherein the solar cell system is a solar cell system.
The connector according to claim 3, wherein the connection line (300)
When m (m is a natural number) solar PV system expansion type string channel switching devices are arrayed,
The xth first extension line 91 is connected to the (x-1) th extension line 92,
The x-th second extension line 92 is connected to the (x + 1) -th extension line 91 and is connected to the (x: 1, 2,
The m-th second extension line 92 is connected to the first extension line 91
and the inverter load is equally shared when the outputs of the n x m solar cell string channels are controlled to be switched to the n x m inverters (200).

Images