KR101543768B1 - 3-input photovoltaic inverter apparatus - Google Patents

Abstract

The present invention relates to a three-input photovoltaic inverter apparatus having two maximum power tracking controllers, which does not form a plurality of input terminals, respectively receiving DC power outputted from a photovoltaic module, as connection boards separate from the inverter apparatus; can be used as a one-input, a two-input, a three-input photovoltaic inverter without an additional hardware change by realizing a connection board function by embedding a diode and a fuse in the inverter apparatus; and enhances the efficiency of the inverter by removing a loss of diodes when using the apparatus as the one-input.

Description

A three-input photovoltaic inverter apparatus includes:

The present invention relates to an inverter-related technology for converting a DC power source to an AC power source, and more particularly, to a three-input solar inverter apparatus having two maximum power follower controllers.

If a part of the battery cells does not operate due to environmental factors, mechanical faults or breakage, DC power input from the photovoltaic module is input to the inverter unit. I can not.

In order to solve such a problem, methods of multiplexing the DC power outputted from the solar module with the inverter device are used. However, when the inverter is used for each of the multiple input DC power sources, a problem that the cost increases greatly occurs.

Therefore, a technology capable of obtaining desired AC power while minimizing the number of inverters through maximum power point tracking (MPPT) control proposed in Korean Patent Laid-Open No. 10-2009-0046327 (2009. 05.11) Were developed.

Korean Patent Laid-Open No. 10-2009-0046327 discloses a solar cell module comprising an input unit having a plurality of input channels having mutually different input voltages so as to be able to receive a primary DC voltage outputted differently from a plurality of solar cell modules, A plurality of DC / DC converters provided in the housing corresponding to input channels so as to convert a voltage input through each of the plurality of DC / DC converters into a set target DC voltage and output through a common output unit; And a plurality of MPPT controllers for controlling driving of the DC / DC converter so as to follow the maximum power output point of each of the solar cell modules to be inputted, a DC converter for converting the target DC voltage output from the converter into a commercial AC voltage, / AC inverter.

The present inventors have realized that a solar inverter having two maximum power follower controllers is not implemented as a separate connection module but a diode and a fuse are built in an inverter device to realize a connection function, 2-input and 3-input solar inverters.

Korean Patent Publication No. 10-2009-0046327 (2009. 05. 11)

The present invention has been made in view of the above-described circumstances, and it is an object of the present invention to provide a solar battery module in which a plurality of input terminals, each of which receives DC power output from a solar module, The present invention provides a 1-input, 2-input, and 3-input solar inverter apparatus having a built-in inverter unit and a built-in inverter unit.

According to an aspect of the present invention, a three-input solar inverter device includes a first DC input terminal connected to a DC output terminal of a first group of battery cells of a solar module, A second DC input terminal connected to a DC output terminal of a battery cell of a second group of photovoltaic modules; A third DC input terminal connected to a DC output terminal of a battery cell of a third group of photovoltaic modules; Two diodes forwardly connected to the positive input terminals of the first DC input terminal and the second DC input terminal, respectively; Two fuses connected in common to the positive input terminal of the first DC input terminal and the positive input terminal of the second DC input terminal and the other connected to the positive input terminal of the third DC input terminal; A first maximum power follower controller having a positive input terminal commonly connected to the two diodes and a negative input terminal commonly connected to a negative input terminal of the first DC input terminal and a negative input terminal of the second DC input terminal; A second maximum power follower controller having a positive input terminal connected to the positive input terminal of the third DC input terminal and a negative input terminal connected to the negative input terminal of the third DC input terminal; An inverter for converting DC power controlled by maximum power point tracking (MPPT) by the first maximum power follower controller and the second maximum power follower controller to AC power; At least one AC output terminal for outputting AC power converted by the inverter; And the like.

According to a further aspect of the present invention, the second DC input terminal and the third DC input terminal are arranged side by side, and the first DC input terminals are arranged to be shifted.

According to a further aspect of the present invention, the two diodes are disposed at the front end of the first DC input terminal arranged to be shifted.

According to a further aspect of the present invention, there is provided a three-input solar inverter device comprising: a protection pad for protecting two diodes fixed to a housing at a front end of the first DC input terminal and being leaded to a PCB substrate; A fixing clip for pressing and fixing the protection pad; And further comprising:

The present invention is characterized in that a plurality of input terminals receiving DC power from the solar module is not implemented as a connection unit separate from the inverter unit, but a diode and a fuse are built in the inverter unit, 3 input photovoltaic inverter is implemented so that 1 input, 2 input and 3 input can be installed at installation site, and the first DC input terminal is arranged to be shifted from the second DC input terminal and the third DC input terminal, 2 DC input terminal and the third DC input terminal can be easily identified.

1 is a schematic diagram of a three-input solar inverter device according to the present invention.
2 is a block diagram showing the configuration of an embodiment of a three-input solar inverter according to the present invention.
3 is a perspective view showing a configuration of an input stage structure of a three-input solar inverter device according to an embodiment of the present invention.
4 is a diagram for explaining adaptive input stage selection of a three-input solar inverter system according to the present invention.
5 is a view illustrating an example of a PCB substrate on which a three-input solar inverter device according to the present invention is modularized.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The terms used throughout the specification of the present invention have been defined in consideration of the functions of the embodiments of the present invention and can be sufficiently modified according to the intentions and customs of the user or operator. It should be based on the contents of.

1 is a schematic diagram of a three-input solar inverter device according to the present invention. 1, a three-input solar inverter 100 according to the present invention is connected between a solar module 200 and a power meter 300, and is generated by a solar module 200, DC power is converted into rated AC power and output. At this time, the output rated AC power is metered by power generation meter 300.

2 is a block diagram showing the configuration of an embodiment of a three-input solar inverter according to the present invention. 2, the three-input solar inverter device 100 according to this embodiment includes a first DC input terminal 110a, a second DC input terminal 110b, a third DC input terminal 110c, Two fuses 125a and 125b, a first maximum power follower controller 130a, a second maximum power follower controller 130b, an inverter 140, And at least one AC output stage (150).

The first DC input terminal 110a is connected to the DC output terminal of the first group of battery cells of the solar module 200 to generate a DC power generated and output by the first group of battery cells of the solar module 200 Receive input.

The second DC input terminal 110b is connected to the DC output terminal of the second group of battery cells of the solar module 200 to generate DC power generated by the battery cells of the second group of the solar modules 200 Receive input.

The third DC input terminal 110c is connected to the DC output terminal of the third group of battery cells of the solar module 200 to generate a DC power generated and output by the battery cells of the third group of the solar module 200 Receive input.

The two diodes 120a and 120b are forward-connected to the positive input terminals of the first DC input terminal 110a and the second DC input terminal 110b, (+) Input terminals to prevent reverse current.

That is, the DC current inputted through the first DC input terminal 110a and passed through the diode 120a does not flow in the reverse direction by the diode 120b, but is inputted through the second DC input terminal 110b and flows through the diode 120b The passed DC current does not flow in the reverse direction by the diode 120a.

One fuse 125a of the two fuses is commonly connected to the positive input terminal of the first DC input terminal and the positive input terminal of the second DC input terminal and the other fuse 125b is connected to the positive terminal of the third DC input terminal, ) Input.

At this time, the fuse 125a is cut off when an overcurrent flows to the first DC input terminal 110a and / or the second DC input terminal 110b, thereby cutting off the power input to the first maximum power follower controller 130a. Meanwhile, when the overcurrent flows to the third DC input terminal 110c, the fuse 125b cuts off the power input to the second maximum power follower controller 130b.

The positive input terminal of the first maximum power follow-up controller 130a is commonly connected to the two diodes 120a and 120b and the negative input terminal thereof is connected to the first DC input terminal 110a and the second DC And a negative input terminal of the input terminal 110b.

Accordingly, the DC current input through the first DC input terminal 110a and passed through the diode 120a or the DC current input through the second DC input terminal 110b and passing through the diode 120b is the first maximum power The tracking controller 130a controls the maximum power follow-up (MPPT) to output the maximum power at a specific voltage and current.

The second maximum power follow-up controller 130b has a positive input terminal connected to the positive input terminal of the third DC input terminal 110c and a negative input terminal connected to the negative terminal of the third DC input terminal 110c -) input.

Accordingly, the DC current input through the third DC input terminal 110c is controlled by the second maximum power follow-up controller 130b by the maximum power follow-up (MPPT) to output the maximum power at a specific voltage and current.

The solar cell usually produces the maximum power at a certain voltage and current. The maximum power point tracking (MPPT) control controls the point voltage that produces the maximum power to keep this voltage band. If the voltage is out of range (if the voltage is lowered by flowing a lot of current, or if the current is too little, the voltage is increased so much), the production power is decreased.

The inverter 140 converts DC power controlled by maximum power point tracking (MPPT) by the first maximum power follower controller 130a and the second maximum power follower controller 130b to AC power.

The AC output stage 150 outputs AC power converted by the inverter 140. The rated AC power output by the AC output stage 150 is metered by the power generation meter 300.

According to the present invention, a plurality of input terminals for respectively receiving DC power from the solar module is not implemented as a connection unit separate from the inverter unit, but a diode and a fuse are built in the inverter unit Semi-function can be implemented.

3 is a perspective view showing a configuration of an input stage structure of a three-input solar inverter device according to an embodiment of the present invention. As shown in FIG. 3, the second DC input terminal 110b and the third DC input terminal 110c may be arranged side by side, and the first DC input terminal 110a may be arranged to be shifted. In this case, the two diodes 120a and 120b may be disposed at the front end of the first DC input terminal 110a.

That is, in this embodiment, the first DC input terminal 110a is arranged to be shifted from the second DC input terminal 110b and the third DC input terminal 110c to secure a space for installing the diodes 120a and 120b, And the first maximum power follower controller 130a and the second maximum power follower controller 130b are lead from the front end of the first DC input terminal 110a to the module PCB substrate And the diodes 120a and 120b are disposed.

According to a further aspect of the invention, the three-input solar inverter device 100 may include a protective pad 160 and a securing clip 170. The protection pad 160 is for protecting two diodes 120a and 120b which are fixed to the housing at the front end of the first DC input terminal 110a and lead to the PCB substrate, For example by screwing one end of the fixing clip 170 to the housing by pressing the protection pad 160 in close contact therewith so that two diodes 120a ) 120b.

The insulation distance of the diodes 120a and 120b can be ensured by fixing the diodes 120a and 120b to the housing and forming leads on the separated PCB substrate and the diodes 120a and 120b, The diode lead terminal can be spaced apart from the housing where heat is generated.

4 is a diagram for explaining adaptive input stage selection of a three-input solar inverter system according to the present invention. For example, the DC output terminal of the solar module 200 may be connected only to the first DC input terminal 110a, the DC output terminal of the solar module 200 may be connected to the second DC input terminal 110b alone, An error occurs when the DC output terminal of the solar module 200 is connected to only the first DC input terminal 110a and the second DC input terminal 110b and the DC output terminal of the solar module 200 is connected to the third DC input terminal 110c The DC output terminal of the solar module 200 is connected to the third DC input terminal 110c and the second DC input terminal 110b or the third DC input terminal 110c and the second DC input terminal 110b and the first DC input terminal 110b are connected, (110a) are effective when the DC output terminal of the solar module (200) is connected. Thus, the diode loss can be eliminated by not using a diode when using as one input.

That is, in consideration of the photovoltaic power generation environment, the user connects the DC output terminal of the solar module 200 to the third DC input terminal 110c or connects the DC output terminal of the solar module 200 to the third DC input terminal 110c and the second DC input terminal 110b, The DC output terminal of the module 200 is connected or the DC output terminal of the solar module 200 is connected to both the third DC input terminal 110c, the second DC input terminal 110b and the first DC input terminal 110a, Input, 2 input and 3 input selection.

5 is a view illustrating an example of a PCB substrate on which a three-input solar inverter device according to the present invention is modularized. Referring to FIG. 5, a plurality of input terminals receiving DC power from the photovoltaic module are not implemented as a separate connection unit from the inverter unit, but a diode and a fuse are built in the inverter unit, Function is implemented.

According to the present invention, a plurality of input terminals for respectively receiving DC power from the solar module is not implemented as a connection unit separate from the inverter unit, but a diode and a fuse are built in the inverter unit The efficiency of the solar inverter can be improved by controlling the DC power input outputted from the solar module through the 1 input, 2 input and 3 input selection, so that the object of the present invention can be achieved. Can be achieved.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. .

INDUSTRIAL APPLICABILITY The present invention is industrially applicable in the field of inverter technology for converting a DC power source to an AC power source and its application field.

100: 3 input solar inverter unit
110a: first DC input terminal
110b: second DC input terminal
110c: Third DC input terminal
120a, 120b: Diodes
125a, 125b: fuse
130a: a first maximum power follower controller
130b: the second maximum power follower controller
140: Inverter
150: AC output
160: Protection pad
170: Fixing clip

Claims (3)

A first DC input terminal connected to a DC output terminal of the battery cell of the first group of the photovoltaic module;
A second DC input terminal connected to a DC output terminal of a battery cell of a second group of photovoltaic modules;
A third DC input terminal connected to a DC output terminal of a battery cell of a third group of photovoltaic modules;
Two diodes forwardly connected to the positive input terminals of the first DC input terminal and the second DC input terminal, respectively;
A fuse connected in series with a common connection point of the positive input terminal of the first DC input terminal and the positive input terminal of the second DC input terminal;
Another fuse (FUSE) connected in series with the positive input terminal of the third DC input terminal;
A first maximum power follower controller having a positive input terminal commonly connected to the two diodes and a negative input terminal commonly connected to a negative input terminal of the first DC input terminal and a negative input terminal of the second DC input terminal;
A second maximum power follower controller having a positive input terminal connected to the positive input terminal of the third DC input terminal and a negative input terminal connected to the negative input terminal of the third DC input terminal;
An inverter for converting DC power controlled by maximum power point tracking (MPPT) by the first maximum power follower controller and the second maximum power follower controller to AC power;
At least one AC output terminal for outputting AC power converted by the inverter; 1. A three-input solar inverter apparatus comprising:
Wherein the second DC input terminal and the third DC input terminal are arranged side by side and the first DC input terminal is arranged in a shifted state and the connection half function is built up by using the diode and the fuse . delete The method according to claim 1,
Wherein the three-input photovoltaic inverter unit comprises:
A protection pad secured to the housing at a front end of the first DC input terminal and for protecting two diodes that are lead to the PCB substrate;
A fixing clip for pressing and fixing the protection pad;
Further comprising: a photocoupler for receiving the photocoupler;

Images