KR102608835B1 - Bipv system and method for correcting voltage difference of each of bipv panels - Google Patents

Abstract

The BIPV system of the present invention is installed integrally on at least one of the windows, exterior walls, and roof of a house, and includes a plurality of BIPV panels that are different from each other in at least one of the installation direction, angle of incidence, and area of incidence; Analyze the output voltage of each of the BIPV panels to determine a target voltage that the BIPV panels should commonly output, transform the output voltage of each of the BIPV panels to the target voltage, and then apply DC power to each of the BIPV panels. A voltage difference correction unit that integrates and outputs integrated DC power; And a BIPV inverter that converts the integrated DC power into AC power and supplies it to the load, thereby correcting the voltage difference between each of the plurality of BIPV panels and converting the generated power of strings or BIPV panels with different output voltages into one inverter. It can be integrated using , which has the effect of improving the power generation efficiency of the BIPV system.

Description

BIPV system and method for correcting the voltage difference between a plurality of BIPV panels {BIPV SYSTEM AND METHOD FOR CORRECTING VOLTAGE DIFFERENCE OF EACH OF BIPV PANELS}

The present invention relates to a BIPV system, and in particular, to a BIPV system and method for correcting the voltage difference between a plurality of BIPV panels that differ in at least one of the installation direction, incident angle, and incident area.

The Building-Integrated Photo-Voltaics System (hereinafter referred to as the 'system') is a solar system that not only produces electricity from solar energy and supplies it to consumers, but also uses building-integrated photovoltaic modules as exterior materials for buildings. It refers to a photovoltaic power generation system. In other words, the BIPV system refers to a system that integrates and installs solar modules on the roof, exterior walls, or windows of a building, unlike the existing installation of solar modules attached to large flat areas or roofs.

In relation to this, Korean Patent No. 10-1642684 discloses a system and method for diagnosing abnormal modules in BIPV. According to the patent, the voltage value of the solar module installed on each wall of the building is measured, the average voltage value of each wall is calculated, and this is compared with the average voltage value of each wall during normal operation to reduce the average voltage value. By selecting the wall with the least voltage as the inspection target area, it is possible to diagnose abnormalities in solar modules excluding walls where the voltage value has dropped due to a decrease in solar radiation, thereby enabling more accurate fault detection.

In this way, the BIPV system can achieve the effect of electricity supply and energy independence through the building's own power generation, reduce construction costs by not attaching solar modules separately, and reduce energy loss by using the produced electric energy directly in the building. There are various advantages, such as minimizing the need for a separate installation site to install solar modules, and increasing the added value of the building.

However, in the case of a BIPV system including a plurality of BIPV panels installed in various forms with different installation directions, angles of incidence, and incident areas, such as windows, exterior walls, and roofs of houses (e.g., residential BIPV systems, etc.), the BIPV panels Since the output voltages of the strings or at least one BIPV panel are different from each other, there was a problem in integrating them using one inverter.

In particular, in the case of general residential BIPV systems, unlike BIPV systems installed in large buildings or apartments, BIPV panels of various sizes are installed in various positions and directions such as windows, walls, and roofs, but a small number of BIPV panels are installed. By implementing a small-scale BIPV system using

Korean Patent No. 10-1642684

Therefore, in the BIPV system, the present invention can integrate the generated power of strings or BIPV panels with different output voltages using one inverter by correcting the voltage difference between each of a plurality of BIPV panels, thereby enabling BIPV The goal is to provide a BIPV system and method that can improve the power generation efficiency of the system.

In addition, the present invention analyzes the output voltage of each of a plurality of BIPVs to determine a target voltage that the BIPV panels should commonly output, taking into account the amount of transforming power consumed for boosting or depressurizing each of the output voltages. The aim is to provide a BIPV system and method that can correct the voltage difference between BIPV panels without reducing power generation efficiency by determining the target voltage in a direction that minimizes the amount of transformed power.

In order to achieve the above object, the BIPV system provided by the present invention includes a plurality of BIPV panels that are integrally installed on at least one of the windows, exterior walls, and roof of a house, and at least one of the installation direction, angle of incidence, and incident area is different from each other; Analyze the output voltage of each of the BIPV panels to determine a target voltage that the BIPV panels should commonly output, transform the output voltage of each of the BIPV panels to the target voltage, and then apply DC power to each of the BIPV panels. A voltage difference correction unit that integrates and outputs integrated DC power; And a BIPV inverter that converts the integrated DC power into AC power and supplies it to the load.

Preferably, the voltage difference correction unit includes a target voltage determination unit that analyzes the output voltage of each of the BIPV panels and determines a target voltage that the BIPV panels should commonly output; and a transformer MPPT unit that boosts or reduces each of the output voltages to the target voltage and then performs MPPT to follow the target voltage.

Preferably, the target voltage determination unit may determine the target voltage in a direction that minimizes the amount of transformer power based on the amount of transformer power consumed for boosting or depressurizing each of the output voltages.

Preferably, the BIPV system includes three or more BIPV panels, and the target voltage determination unit selects one of at least one voltage value excluding the maximum and minimum values among the output voltages of each of the BIPV panels as the target voltage. You can decide.

Meanwhile, in order to achieve the above object, the method of correcting the voltage difference between each of the plurality of BIPV panels provided by the present invention is a method of correcting the voltage difference between each of the plurality of BIPV panels included in the BIPV system. An output voltage collection step of collecting the output voltage of each of the plurality of BIPV panels, which are integrally installed on at least one of a window, an exterior wall, and a roof, and have different installation directions, angles of incidence, and areas of incidence; A target voltage determination step of analyzing the output voltages to determine a target voltage that the BIPV panels should commonly output; And a voltage difference correction step of transforming the output voltage of each of the BIPV panels to the target voltage and then outputting the integrated DC power of each of the BIPV panels.

Preferably, the target voltage determining step may determine the target voltage in a direction that minimizes the amount of transformer power based on the amount of transformer power consumed for boosting or depressurizing each of the output voltages.

Preferably, when the BIPV system includes three or more BIPV panels, the target voltage determining step sets one of at least one voltage value excluding the maximum and minimum values among the output voltages of each of the BIPV panels to the target. It can be determined by voltage.

Preferably, the voltage difference correction step includes a transforming step of boosting or reducing the output voltage of each of the BIPV panels to the target voltage; A transform MPPT step of performing MPPT so that the output of each of the BIPV panels follows the target voltage; And it may include an integrated DC power output step of integrating and outputting the DC power of each of the BIPV panels output after the transform MPPT step.

As described above, the BIPV system and method for correcting the voltage difference between the plurality of BIPV panels of the present invention are, in the BIPV system, correcting the voltage difference between the plurality of BIPV panels, so that the output voltages are different from each other. The generated power of strings or BIPV panels can be integrated using a single inverter, which has the effect of improving the generation efficiency of the BIPV system.

In addition, the present invention analyzes the output voltage of each of a plurality of BIPV panels to determine a target voltage that the BIPV panels should commonly output, taking into account the amount of transforming power consumed for boosting or depressurizing each of the output voltages. By determining the target voltage in a direction that minimizes the amount of transformed power, there is an effect of correcting the voltage difference between each BIPV panel without reducing power generation efficiency.

1 is a schematic system configuration diagram of a BIPV system according to an embodiment of the present invention.
Figure 2 is a schematic block diagram of a voltage difference correction unit according to an embodiment of the present invention.
Figures 3 and 4 are process flowcharts of a method for correcting the voltage difference between BIPV panels according to an embodiment of the present invention.

Below, embodiments of the present invention will be described with reference to the attached drawings, and will be described in detail so that those skilled in the art can easily practice the present invention. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein. Meanwhile, in order to clearly explain the present invention in the drawings, parts unrelated to the description are omitted, and similar parts are given similar reference numerals throughout the specification. In addition, descriptions of parts that can be easily understood by those skilled in the art are omitted even if detailed descriptions are omitted.

Throughout the specification and claims, when it is said that a part includes a certain component, this means that other components may be further included rather than excluding other components unless specifically stated to the contrary.

1 is a schematic system configuration diagram of a BIPV system according to an embodiment of the present invention.

Referring to FIG. 1, a residential BIPV system according to an embodiment of the present invention includes a BIPV panel unit 100, a voltage difference correction unit 200, an inverter 300, and a BIPV meter 400.

The BIPV panel unit 100 may include a plurality of building-integrated solar panels 110, 120, and 130. That is, the BIPV panel unit 100 is installed integrally on at least one of the windows, exterior walls, and roof of the house, and as illustrated in FIG. 1, the BIPV panel unit 100 has size (i.e. incident area), installation direction, and installation angle (i.e. , angle of incidence) may include a plurality of BIPV panels 110, 120, and 130 that are different from each other.

At this time, each of the BIPV panels 110, 120, and 130 may include a plurality of human body detection sensors 111, 121, and 131 to detect whether a human body is approaching. This is to prevent safety accidents such as electric shock from occurring as people approach the BIPV panels 110, 120, and 130, so that people do not approach within a predetermined radius of each of the BIPV panels 110, 120, and 130. This is to detect this and issue a warning or block the output of the target panel.

In addition, each of the BIPV panels 110, 120, and 130 further includes a warning unit 112, 122, and 132 for warning when a dangerous condition (e.g., failure, occurrence of leakage current, etc.) of the corresponding panel occurs. can do. For example, each of the BIPV panels 110, 120, and 130 is equipped with a buzzer to output a warning sound or an LED lamp to display the warning state in color for each level, and can display a dangerous state. In particular, the warning units 112, 122, and 132 are composed of lamps that display two or more colors and are installed inside the tempered glass forming the surface of each of the BIPV panels 110, 120, and 130 to respond to color changes. It can be implemented to express the risk level.

The voltage difference correction unit 200 corrects the voltage difference between the output voltages output from each of the BIPV panels 110, 120, and 130, and then integrates the DC power generated from each of the BIPV panels 110, 120, and 130. After generating integrated DC power, it is delivered to the inverter 300. At this time, the voltage difference correction unit 200 may use known technology to generate the integrated DC power.

Meanwhile, the voltage difference correction unit 200 analyzes the output voltage of each of the BIPV panels 110, 120, and 130 to correct the voltage difference between the output voltages and determines whether the BIPV panels 110, 120, or 130 have a common After determining the target voltage to be output, the output voltage of each of the BIPV panels 110, 120, and 130 can be transformed to the target voltage and MPPT can be performed to follow the target voltage.

For example, when 11 kW of power at 1100 V is output from the BIPV panel 110, 9 kW of power at 900 V is output from the BIPV panel 120, and 7 kW of power at 700 V is output from the BIPV panel 130, The voltage difference correction unit 200 can transform the output voltage of the BIPV panels 110, 120, and 130 to 900V and perform MPPT to follow 900V.

For this purpose, an example of the configuration of the voltage difference correction unit 200 is illustrated in FIG. 2. Therefore, a more detailed description of the BIPV panel management unit 200 will be described later with reference to FIG. 2.

The inverter 300 converts the integrated DC power into AC power and delivers it to the load 10. The operation of the inverter 300 for this purpose can use known technologies.

The BIPV meter 400 measures the amount of power delivered to the load 10 through the inverter 300 (i.e., the amount of power generated through BIPV). This is for KEPCO to use as a reference when calculating billing information for the relevant customer's electricity usage. In other words, KEPCO can only charge for a limited amount of power equal to the amount of power measured by the BIPV meter 400 out of the total amount of power used by the relevant consumer. Alternatively, the BIPV meter 400 may measure and display both the amount of power generation and the amount of consumption in order to measure the remaining unconsumed power among the power generated in the BIPV system.

Figure 2 is a schematic block diagram of a voltage difference correction unit according to an embodiment of the present invention. Referring to FIG. 2, the voltage difference correction unit 200 may include a target voltage determination unit 210 and a transformer 220 including a plurality of transformer MPPT units 221, 222, and 223.

The target voltage determination unit 210 analyzes the output voltage of each of the BIPV panels 110, 120, and 130 and determines a target voltage that the BIPV panels 110, 120, and 130 should commonly output. To this end, the target voltage determination unit 210 may determine the target voltage in a direction that minimizes the amount of transformation power based on the amount of transformation power consumed for boosting or reducing each of the output voltages.

In particular, when the BIPV system includes three or more BIPV panels 110, 120, and 130, as illustrated in FIG. 1, the target voltage determination unit 210 determines the voltage of each of the BIPV panels 110, 120, and 130. Any one of at least one voltage value excluding the maximum and minimum output voltages may be determined as the target voltage.

For example, when 11 kW of power at 1100 V is output from the BIPV panel 110, 9 kW of power at 900 V is output from the BIPV panel 120, and 7 kW of power at 700 V is output from the BIPV panel 130, The target voltage determination unit 210 may determine the intermediate value of 900V excluding the maximum value of 1100V and 700V as the target voltage.

This means that when the maximum value among the output voltages is determined as the target voltage, the amount of power consumed to boost (i.e. boosting) the output voltage of the string that outputs the minimum value to the maximum value is large, and the minimum value among the output voltages is set as the target voltage. This is because the amount of power consumed to reduce (i.e. buck) the output voltage of the string that outputs the maximum value to the minimum value is large.

In the above example, when reducing 1100V to 900V by 200V, the power may be reduced by approximately 2% compared to before reducing the pressure, and when increasing 700V by 200V to 900V, the power may be reduced by approximately 4% compared to before increasing the voltage. This is because if 1100V is determined as the target voltage, the power may be lowered further to boost both the 700V and 900V voltages to 1100V.

Meanwhile, even when the BIPV system further includes a BIPV panel outputting 13 kW of power of 1300 V in addition to the three BIPV panels 110, 120, and 130 illustrated in FIG. 1, the target voltage determination unit 210 outputs 900 V. It can be determined as the target voltage, because the amount of power consumed to boost the voltage of 700V to 900V is greater than the amount of power consumed to reduce the voltage of 1300V to 900V.

In this way, the target voltage determination unit 210 considers the amount of transformative power consumed for boosting or depressurizing each of the output voltages, the maximum output voltage, and the minimum output voltage together, and determines the amount of transformer power consumed for boosting or depressurizing, and The target voltage can be determined in a way that minimizes the loss of generated power.

For example, the target voltage determination unit 210 determines the output voltage closest to the point that is 1/3 of the minimum value among the points between the maximum and minimum values of the output voltage of each of three or more BIPV panels as the target voltage. You can.

The plurality of transformer MPPT units 221, 222, and 223 constituting the transformer 220 boost or reduce the output voltage of each of the corresponding BIPV panels 110, 120, and 130 to the target voltage, and then MPPT is performed to track the voltage. For example, the transformer MPPT unit 221 corresponding to the BIPV panel 110 that outputs 11 kW of power at 1100 V reduces the voltage of 1100 V to 900 V, then performs MPPT to follow 900 V, and 7 kW of 700 V. The voltage transformer MPPT unit 223 corresponding to the BIPV panel 130 that outputs power can boost the voltage from 700V to 900V and then perform MPPT to follow 900V. As a result, the plurality of BIPV panels 110, 120, and 130 all output a voltage of 900V, allowing them to be connected in parallel to one inverter 300.

To this end, the transformer 220 may include a buck converter and a boost converter, or may include a buck-boost converter.

Figures 3 and 4 are process flowcharts of a method for correcting the voltage difference between BIPV panels according to an embodiment of the present invention. 1 to 4, a BIPV system including a plurality of BIPV panels 110, 120, and 130 sends the output of each of the plurality of BIPV panels 110, 120, and 130 to one inverter 300. To connect in parallel, the method to compensate for the voltage difference is as follows.

First, in step S110, the voltage difference correction unit 200 collects the output voltage of the BIPV panel. That is, in step S110, the voltage difference correction unit 200 is integrally installed on at least one of the windows, exterior walls, and roof of the house, and the plurality of BIPVs differ from each other in at least one of the installation direction, angle of incidence, and incident area. Collect the output voltage of each panel.

In step S120, the target voltage determination unit 210 of the voltage difference correction unit 200 analyzes the output voltages and determines a target voltage that the BIPV panels should commonly output. To this end, the target voltage determination unit 210 determines the target voltage in a direction that minimizes the amount of transformer power based on the amount of transformer power consumed for boosting or depressurizing each of the output voltages, and the BIPV system has 3 When more than one BIPV panel is included, one of at least one voltage value excluding the maximum and minimum values among the output voltages of each of the BIPV panels can be determined as the target voltage.

In step S130, the transformer 220 of the voltage difference correction unit 200 corrects the voltage difference between each BIPV panel based on the target voltage. That is, in step S130, the plurality of transformer MPPT units 221, 222, and 223 constituting the transformer 220 boost or boost the output voltage of each of the corresponding BIPV panels 110, 120, and 130 to the target voltage. After reducing the pressure, MPPT is performed to follow the target voltage.

To this end, each of the plurality of transformer MPPT units 221, 222, and 223, in step S131, boosts or reduces the output voltage of the corresponding BIPV panel to the target voltage, and in step S132, the output of the corresponding BIPV panel is MPPT is performed to follow the target voltage.

Meanwhile, in step S133, the voltage difference correction unit 200 integrates the DC power output as a result of performing the transform MPPT of each of the plurality of transform MPPT units 221, 222, and 223 and outputs the integrated DC power.

In this way, the BIPV system and method for correcting the voltage difference between the plurality of BIPV panels of the present invention are, in the BIPV system, by correcting the voltage difference between the plurality of BIPV panels, the output voltages are different from each other. The generated power of BIPV panels can be integrated using a single inverter, which has the feature of improving the generation efficiency of the BIPV system.

In addition, the present invention analyzes the output voltage of each of a plurality of BIPVs to determine a target voltage that the BIPV panels should commonly output, taking into account the amount of transforming power consumed for boosting or depressurizing each of the output voltages. By determining the target voltage in a direction that minimizes the amount of transformed power, the voltage difference between each BIPV panel can be corrected without reducing power generation efficiency.

Although the embodiments of the present invention have been described above, the scope of the rights of the present invention is not limited thereto, and the present invention can be easily modified from the embodiments by those skilled in the art in the technical field to which the present invention belongs and is recognized as equivalent. Includes all changes and modifications to the extent permitted.

100: BIPV panel part 110, 120, 130: BIPV panel
200: voltage difference compensation unit 210: target voltage determination unit
220: Transformer unit 221, 222, 223: Transformer MPPT unit
300: Inverter 400: BIPV meter
10: load

Claims (8)

Three or more BIPV panels that are integrally installed on at least one of the windows, exterior walls, and roof of a house, and at least one of the installation direction, angle of incidence, and incident area is different from each other;
Based on the output voltage of each of the BIPV panels, a target voltage that the BIPV panels should commonly output is determined, and the output voltage of each of the BIPV panels is transformed to the target voltage, and then MPPT is used to follow the target voltage. a voltage difference correction unit that outputs integrated DC power by integrating the DC power of each of the BIPV panels; and
Including a BIPV inverter that converts the integrated DC power into AC power and supplies it to the load,
The voltage difference correction unit
By comparing and analyzing the output voltages of each of the BIPV panels, one of at least one voltage value excluding the maximum and minimum values among the output voltages of each of the BIPV panels is determined as the target voltage, wherein each of the output voltages BIPV system, characterized in that the target voltage is determined in a direction that minimizes the amount of transformer power based on the amount of transformer power consumed for voltage boosting or depressurization. The method of claim 1, wherein the voltage difference correction unit
a target voltage determination unit that analyzes the output voltage of each of the BIPV panels and determines a target voltage that the BIPV panels should commonly output; and
A BIPV system comprising a transformer MPPT unit that boosts or reduces each of the output voltages to the target voltage and then performs MPPT to follow the target voltage. delete delete In a method of correcting the voltage difference between three or more BIPV panels included in a BIPV system,
An output voltage collection step of collecting the output voltage of each of the BIPV panels, which are integrally installed on at least one of the windows, exterior walls, and roof of the house, and have different installation directions, angles of incidence, and incident areas;
A target voltage determination step of determining a target voltage to be commonly output by the BIPV panels based on the output voltage of each of the BIPV panels; and
A voltage difference correction step of transforming the output voltage of each of the BIPV panels to the target voltage and then performing MPPT to follow the target voltage to output integrated DC power that integrates the DC power of each of the BIPV panels, ,
The target voltage determination step is
By comparing and analyzing the output voltages of each of the BIPV panels, one of at least one voltage value excluding the maximum and minimum values among the output voltages of each of the BIPV panels is determined as the target voltage, wherein each of the output voltages A method for correcting the voltage difference between each of a plurality of BIPV panels, characterized in that the target voltage is determined in a direction that minimizes the amount of transformed power based on the amount of transformed power consumed for voltage boosting or reducing voltage. delete delete The method of claim 5, wherein the voltage difference correction step is
A transforming step of boosting or reducing the output voltage of each of the BIPV panels to the target voltage;
A transform MPPT step of performing MPPT so that the output of each of the BIPV panels follows the target voltage; and
A method for correcting the voltage difference between a plurality of BIPV panels, comprising an integrated DC power output step of integrating and outputting the DC power of each of the BIPV panels output after the transform MPPT step.

Images