KR102323827B1 - Building integrated junction box for solar power, including module mornitering - Google Patents

Abstract

Disclosed is a building-integrated junction box for solar power generation. The building-integrated junction box for solar power generation comprises: an integrated control device arranged in the junction box for solar power generation to control an emergency situation of a solar power generation system; a module monitoring device arranged in the junction box for solar power generation to monitor the voltage of a solar cell module; and a fire detection module arranged in the junction box for solar power generation to detect the inside situation of the junction box. At least one first processor included in the integrated control device, if the voltage value of one or more modules is discerned to be lower by a predetermined difference value than the voltage value of the other modules, raises the voltage value of the module to the voltage value of the other modules by driving a buck-boost mode, receives detection data from a fire detection module, discerns a fire in the junction box for solar power generation based on the received detection data, opens the power transmission line of an inverter or the solar cell module in response to the discernment of a fire in the junction box, and notifies at least one among one or more electronic devices of a fire alarm through a first communication module at the same time of opening the transmission line.

Description

Junction box for building-integrated photovoltaic power generation including a module monitoring device

Various embodiments relate to a junction box for a building-integrated photovoltaic power generation including a power cut-off device. Specifically, the building-integrated photovoltaic junction box including the module monitoring device controls the voltage of the module based on the voltage value of the module measured from the processors installed inside the junction box.

Power generation using fossil fuels can cause air pollution due to the generation of fine dust and ultrafine dust. Due to an increase in interest in the environment, interest in eco-friendly development is increasing. Among eco-friendly power generation, a power generation method widely known to the public may be solar power generation.

The solar power generation equipment may include a solar cell module, an inverter, and a connection panel. The connection panel included in the photovoltaic power generation equipment may be disposed between the solar cell module and the inverter to protect the inverter, and may perform a collision prevention and protection function between a plurality of solar cell modules.

In consideration of the efficiency of power generation, solar power generation facilities tend to be installed in areas where there is no wind and high sunlight. Solar power generation facilities installed in dry areas with high sunlight may be vulnerable to fire. Solar power generation facilities installed in dry areas without wind always pose a risk of fire due to dew condensation caused by temperature differences and sparks caused by foreign substances inside the junction panel. Due to this, the photovoltaic power generation facility may generate an overvoltage due to damage to the power generation module or the junction board, thereby increasing the possibility of a fire.

When a fire occurs in the junction panel in the photovoltaic power generation system, the photovoltaic device including the junction panel may generate a reverse current in the wiring connected to the photovoltaic module as well as burnout inside the junction panel, resulting in a solar cell module may cause damage to

In addition, in the case of monitoring the voltage in units of strings, it is difficult to directly solve the problem that the voltages of the strings do not match due to the non-uniformity of the strings, the installation direction, the difference in the installation angle, and the abnormal voltage of the module.

Accordingly, there is a need for a method for controlling the voltage value by monitoring the voltage of each photovoltaic cell module in the photovoltaic power generation system and protecting the photovoltaic module from fire occurring in the junction box.

The building-integrated photovoltaic power generation junction box according to various embodiments includes: an integrated control device disposed in the building-integrated photovoltaic power generation junction box to control an emergency situation of the photovoltaic system; a module monitoring device disposed in the building-integrated photovoltaic power generation junction box to monitor one or more solar cell modules to which sunlight is incident for photovoltaic power generation; and a fire detection module disposed in the building-integrated photovoltaic power generation junction box to detect an internal situation of the junction box, wherein the integrated control device includes a communication processor (CP) for communicating with one or more electronic devices. A first communication module comprising: a memory in which detection data of the fire detection module is stored; A power cut-off unit for cutting off a power transmission line connected to a solar cell module or an inverter based on the sensed data, and at least one first processor operably coupled to the first communication module and the memory Including, wherein the module monitoring device includes a communication processor for communicating with one or more electronic devices, and communicating with the first communication module to transmit monitoring data for the one or more solar cell modules to the integrated control device a second communication module, and at least one second processor operatively coupled to the second communication module for monitoring the one or more solar cell modules, wherein the fire detection module is configured to detect an internal condition of the junction box. and a third communication module for transmitting the sensor data of the plurality of sensors to the integrated control device by communicating with the first communication module, wherein the memory includes a plurality of instructions store, and when the plurality of instructions are executed by the at least one first processor, the at least one first processor receives the voltage values of the one or more solar cell modules from the second processor, and the one or more Among the modules, when the voltage value of any one or more solar cell modules is identified as less than a predetermined difference value than the voltage value of one or more other solar cell modules, the buck-boost mode is driven to drive the one or more boosting the voltage value of the solar cell module to the voltage value of the one or more other solar cell modules, receiving detection data from the fire detection module, and based on the received detection data, whether the solar power generation junction box is on fire and, in response to the identification of whether the junction box is fire, open the power transmission line of the inverter or the solar cell module, and simultaneously with the opening of the transmission line, through the first communication module, the one or more It is possible to control to notify a fire alarm to at least one electronic device among the self devices.

A photovoltaic device according to various embodiments may include a solar cell module; a building-integrated photovoltaic power generation junction box whose one end is connected to the solar cell module; and an inverter connected to the other end of the building-integrated photovoltaic power generation junction box, wherein the building-integrated photovoltaic power generation junction box is disposed in the building-integrated photovoltaic power generation junction box, and sunlight is incident for photovoltaic power generation and a module monitoring device for monitoring one or more modules being It is disposed in the photovoltaic power generation junction box and includes a fire detection module for detecting an internal situation of the junction box, wherein the integrated control device includes a communication processor (CP) for communicating with one or more electronic devices. a first communication module, a memory in which detection data of the fire detection module is stored; A power cut-off unit for cutting off a power transmission line connected to the solar cell module or the inverter based on the sensed data, a fuse disposed between the solar cell module and the power cut-off unit, and the first communication module and the memory; at least one first processor operably coupled to, wherein the module monitoring device comprises a communication processor for communicating with one or more electronic devices, and in communication with the first communication module, a second communication module for transmitting monitoring data for one or more modules to the integrated control device, and at least one second processor for monitoring the one or more modules and operatively coupled to the second communication module, the second communication module comprising: The fire detection module includes a plurality of sensors for detecting an internal condition of the junction box, and a third communication module for communicating with the first communication module and transmitting the detection data of the plurality of sensors to the integrated control device and the memory stores a plurality of instructions, and when the plurality of instructions are executed by the at least one first processor, the at least one first processor When the voltage value of one or more modules is received, and the voltage value of one or more of the one or more modules is identified as less than a predetermined difference value than the voltage value of one or more other modules, buck-boost mode (buck-boost mode) ) to boost the voltage value of the one or more modules to the voltage value of the one or more other modules, receive detection data from the fire detection module, and connect the solar power generation based on the received detection data Identifies whether the box is on fire, and, in response to the identification of whether the junction box is on fire, opens the power transmission line of the inverter or the solar cell module, and simultaneously with the opening of the transmission line, through the first communication module, the one or more electrons It is possible to control to notify a fire alarm to at least one of the devices.

A junction box for a building-integrated photovoltaic power generation including a module monitoring device according to various embodiments may measure a voltage for each solar cell module, thereby effectively boosting a low voltage module to a voltage value of another module.

A junction box for photovoltaic power generation including a power cut-off device according to various embodiments may detect a junction board fire danger signal early. In addition, when the junction box according to various embodiments detects a danger signal, in order to protect the solar cell module and the inverter, the power of the solar cell module stage and the inverter stage may be cut off.

The junction box for photovoltaic power generation including a power cut-off device according to various embodiments may notify a fire hazard alarm to an operator when a junction panel fire danger signal is detected, so that the operator may prepare an early countermeasure for a fire.

1 is a block diagram of a solar power generation system according to various embodiments.
2 is a schematic circuit diagram of an integrated control device included in a building-integrated photovoltaic power generation junction box according to various embodiments.
3 is a schematic circuit diagram of a fire detection module included in a photovoltaic junction box according to various embodiments.
4 is a flowchart illustrating a step-up algorithm of a module monitoring device included in a building-integrated photovoltaic power generation junction box according to various embodiments of the present disclosure.
5 is a diagram illustrating a relationship between a maximum output and voltage of a module monitoring device included in a building-integrated photovoltaic power generation junction box according to various embodiments of the present disclosure.
6 is a flowchart illustrating the operation of a building-integrated photovoltaic power generation junction box according to various embodiments.
7 is a flowchart illustrating an operation algorithm of a building-integrated photovoltaic junction box according to various embodiments.

Specific structural or functional descriptions of the embodiments according to the concept of the present invention disclosed herein are only exemplified for the purpose of explaining the embodiments according to the concept of the present invention, and the embodiment according to the concept of the present invention These may be embodied in various forms and are not limited to the embodiments described herein.

Since the embodiments according to the concept of the present invention may have various changes and may have various forms, the embodiments will be illustrated in the drawings and described in detail herein. However, this is not intended to limit the embodiments according to the concept of the present invention to specific disclosed forms, and includes changes, equivalents, or substitutes included in the spirit and scope of the present invention.

Terms such as first or second may be used to describe various elements, but the elements should not be limited by the terms. The above terms are used only for the purpose of distinguishing one element from another element, for example, without departing from the scope of rights according to the concept of the present invention, a first element may be named as a second element, Similarly, the second component may also be referred to as the first component.

When a component is referred to as being “connected” or “connected” to another component, it may be directly connected or connected to the other component, but it is understood that other components may exist in between. it should be On the other hand, when it is mentioned that a certain element is "directly connected" or "directly connected" to another element, it should be understood that the other element does not exist in the middle. Expressions describing the relationship between elements, for example, “between” and “between” or “directly adjacent to”, etc., should be interpreted similarly.

The terminology used herein is used only to describe specific embodiments, and is not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In this specification, terms such as “comprise” or “have” are intended to designate that the described feature, number, step, operation, component, part, or combination thereof exists, and includes one or more other features or numbers, It should be understood that the possibility of the presence or addition of steps, operations, components, parts or combinations thereof is not precluded in advance.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present specification. does not

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. However, the scope of the patent application is not limited or limited by these examples. Like reference numerals in each figure indicate like elements.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. However, the scope of the patent application is not limited or limited by these examples. Like reference numerals in each figure indicate like elements.

1 is a block diagram of a solar power generation system according to various embodiments. The solar power generation system 10 may generate electricity from the solar cells included in the solar cell module. The generated electricity may be direct current, and the produced electricity is efficiently collected through a connection panel and transmitted to the inverter, and the inverter converts the direct current into alternating current and transmits it.

Referring to FIG. 1 , a solar power generation system 10 may include a junction box 100 , an inverter 150 , a solar cell module 170 , and an electronic device 190 .

According to various embodiments, the solar power generation system 10 may include all devices in the process of generating electricity from sunlight and transmitting the generated electricity. The building-integrated photovoltaic power generation junction box 100 may be located between the solar cell module 170 and the inverter 150 . The junction box 100 may efficiently collect DC electricity produced by the solar cell module 170 and transmit it to the inverter. A plurality of solar cell modules 170 may be formed. When electricity generated by each solar cell module 170 is directly transmitted to the inverter, the load of the inverter 150 may suddenly increase. In order to reduce the load on the inverter 150 , the junction box 100 may transmit electricity transmitted from the solar cell module 170 to the inverter 150 through each channel. Each solar cell module 170 may have a difference in power generation amount due to an external natural environment such as the position of the sun and wind, and a collision may occur due to a difference in electrical energy. The junction box 100 may prevent an electrical collision that may occur between the respective solar cell modules 170 . In addition, the junction box 100 can prevent reverse current of power.

The solar cell module 170 may collect a basic unit of solar cells and arrange them in a frame.

The solar cell module may include a high-efficiency single-crystal or low-efficiency polycrystalline structure. The high-efficiency single-crystal solar cell module is composed of octagonal cells and may include a pattern inside, and the low-efficiency polycrystalline module is composed of rectangular cells and may not include a separate pattern inside.

According to various embodiments, one or more solar cell modules 170 may be formed. One or more solar cell modules 170 may be connected to form one or more module groups, and one or more module groups may be electrically connected in series and arranged to form a string.

The inverter 150 may convert the direct current generated by the solar cell module 170 into alternating current to transmit power. The inverter 150 may communicate with the electronic device 190 and may include a monitoring system interworking with a mobile phone through the electronic device 190 .

The electronic device 190 may receive a notification signal of a fire or emergency situation occurring in the junction box 100 , and may monitor power generated by the inverter 150 .

According to various embodiments, the junction box 100 may include an integrated control device 110 , a module monitoring device 120 , and a fire detection module 130 . The integrated control device 110 may detect a risk of fire occurring while the junction box 100 is operating, and notify the user to the electronic device 190 or cut off the power. The fire detection module 130 may detect the environment inside the junction box 100 and transmit data related to whether or not a fire has occurred to the integrated control device 110 . The integrated control device 110 and the fire detection module 130 may be connected by wire to transmit information, and separate communication modules (eg, the first communication module 111 , the second communication module 121 , and the third communication module). The module 131) may be used to transmit/receive data.

According to various embodiments, the integrated control device 110 may include a first communication module 111 , a first processor 113 , a memory 115 , a power cut-off unit 117 , and an alarm system 118 . . At least one of the first communication module 111 , the first processor 113 , the memory 115 , the power cut-off unit 117 or the alarm system 118 is an electronic component such as a communication bus. ) may be electrically and/or operatively coupled to each other by (electronically and/or operably coupled with each other).

The first communication module 111 transmits and/or receives electrical signals between the junction box 100 and the electronic device 190 and the integrated control device 110 and the module monitoring device 120 and the integrated control device 110 . and a hardware component for supporting transmission and/or reception of an electrical signal between the fire detection module 130 and the fire detection module 130 . For example, the first communication module 111 may include at least one of a modem (MODEM), an antenna, and an O/E (Optic/Electronic) converter. The first communication module 111 is, Ethernet (ethernet), ZigBee (ZigBee) LAN (Local Area Network), WAN (Wide Area Network), WiFi (Wireless Fidelity), LTE (Long Term Evolution), 5G NR (New Radio) ) may support transmission and/or reception of electrical signals based on various types of protocols such as

The first processor 113 of the integrated control apparatus 110 according to an embodiment may include a hardware component for processing data based on one or more instructions. Hardware components for processing data may include, for example, an Arithmetic and Logic Unit (ALU), a Field Programmable Gate Array (FPGA), and/or a Central Processing Unit (CPU). The number of processors 210 may be one or more. For example, based on a dual core, a quad core, or a hexa core, the plurality of first processors 113 may be included in the integrated control device 110 .

The memory 115 of the integrated control device 110 according to an embodiment may include a hardware component for storing data and/or instructions input and/or output to the first processor 113 . The memory 115 may include, for example, volatile memory such as random-access memory (RAM) and/or non-volatile memory such as read-only memory (ROM). have. The volatile memory may include, for example, at least one of a dynamic RAM (DRAM), a static RAM (SRAM), a cache RAM, and a pseudo SRAM (PSRAM). The non-volatile memory may include, for example, at least one of a programmable ROM (PROM), an erasable PROM (EPROM), an electrically erasable PROM (EEPROM), a flash memory, a hard disk, a compact disk, and an embedded multi media card (eMMC). can

In the memory 115 , one or more instructions indicating an operation to be performed on data by the first processor 113 may be stored. A set of instructions may be referred to as firmware, an operating system, a process, a routine, a sub-routine, and/or an application. For example, the first processor 113 executes a set of a plurality of instructions distributed in the form of an application, detects sparks, smoke, and temperature in the junction box 100 , and connects It is possible to determine the internal environment of the box (100).

According to various embodiments, the power cut-off unit 117 may block a transmission line connected to the inverter 150 or the solar cell module 170 when a fire occurs in the junction box 100 . The power cutoff unit 117 may be a switch formed of a semiconductor device, and may be controlled by the first processor 113 . The power cutoff unit 117 may be designed using a MOSFET. When the fire information of the connection board fire information is received through the first wireless communication module 111, the power cutoff unit 117 applies the received signal to the power cutoff receiving unit, the power may be cut off. The power cutoff unit 117 may be disposed in the junction box 100 located outside the inverter.

The first processor 113 determines whether the voltage value of the solar cell module is abnormal based on the voltage value of the one or more solar cell modules 170 transmitted from the module monitoring device 120, and the one or more solar cell modules ( 170) can be controlled.

According to various embodiments, the first processor 113 may receive a voltage value of the one or more solar cell modules 170 monitored by the one or more solar cell modules 170 from the second processor 122 , When it is determined that the voltage value of any of the above solar cell modules is smaller than the voltage value of any one or more solar cell modules, that is, the voltage value of one or more other solar cell modules? When it is determined to be less than or equal to a predetermined difference value, an abnormal state of one or more solar cell modules may be recognized. When such an abnormal state is recognized, the first processor 113 may implement a buck-boost mode for unifying the generated voltages of one or more strings by adjusting the voltages of one or more solar cell modules 170 .

4 is a flowchart illustrating a step-up algorithm of a module monitoring device included in a building-integrated photovoltaic power generation junction box according to various embodiments of the present disclosure.

Referring to FIG. 4 , one or more solar cell modules 170 may be boosted as a boost mode mainly in a buck-boost mode.

According to various embodiments, the module monitoring device 120 may measure the string voltage ( S310 ). The first processor 113 collects the voltages between one or more strings received from the module monitoring device 120, and when the voltages between the one or more strings do not match, the non-matched string, in particular, the generated voltage is higher than the one or more other strings. One or more low strings may be identified (S311), and voltages of one or more solar cell modules 170 connected in series within the strings may be measured (S312). It can be determined whether the voltage value of the one or more solar cell modules 170 whose voltage value is measured lower than that of the one or more other solar cell modules 170 is temporarily low, or whether a difference has occurred within a predetermined difference value. can be (S320). When the voltage value of the one or more solar cell modules 170 measured to be low is temporarily low or the difference is within a predetermined difference value range, the voltage value of the one or more modules 170 is recovered by waiting a certain time. can be (S321).

On the other hand, when the voltage value of the one or more solar cell modules 170 measured to be low is continuously measured to be low or a difference out of a predetermined difference value range occurs, the one or more solar cell modules 170 measured to be low ) of step-up the voltage, that is, a buck-boost mode can be realized (S330).

According to various embodiments, referring to FIG. 4 , the process of boosting the voltage of one or more solar cell modules 170 measured low collects generation voltage information for each string in a buck-boost mode, The voltage of one or more modules 170 included in the low-measured string may be boosted (S331). Accordingly, it may be determined whether the boosted voltage of one or more modules 170 matches the voltage of one or more other strings (S332).

According to various embodiments, when the voltages between one or more strings match through the step-up process, a maximum power pointer tracking (MPPT) and a current control algorithm may be executed (S333). MPPT is an algorithm that controls the voltage, which means that the voltage is adjusted so that the maximum output can be obtained.

5 is a diagram illustrating a relationship between a maximum output and voltage of a module monitoring device included in a building-integrated photovoltaic power generation junction box according to various embodiments of the present disclosure.

5, the high voltage is reduced by controlling the current to reach the voltage value (Vmas) that produces the maximum output in the photovoltaic power generation, and the low voltage is boosted by boosting the voltage to adjust the voltage of the entire string. The voltage may be adjusted to a voltage value at which the maximum output can be produced in the solar tube power generation (S334).

According to various embodiments, when the voltage of the module is not boosted even through the step-up process, the module 170 is determined as a faulty module so that a physical defect can be checked in the module 170 and the power cut-off unit 117 performs the module 170 It is possible to cut off the power of (S335).

According to various embodiments, when the voltage value of the one or more solar cell modules 170 is measured low and the voltage value of the one or more solar cell modules 170 measured low through the buck-boost mode is adjusted, the first processor ( 113) may not be applied to one or more solar cell modules 170 that are measured to be low. In this case, the first processor 113 may determine the solar cell module 170 as a faulty module. When it is determined that one or more solar cell modules 170 are faulty modules, the first processor 113 cuts off the power of the faulty module through the power cutoff unit 117 to prevent unnecessary current from flowing to the faulty module. have.

According to various embodiments, a faulty module may be determined through the second processor 122 of the module monitoring device 120 . When the second processor 122 monitors the voltage value of the one or more solar cell modules 170, and the measured voltage value of the one or more solar cell modules 170 is maintained at a voltage value below the set range for a predetermined time, the second 1 Without executing the buck-boost mode by the processor 113, it can be determined as a faulty module immediately. In this case, the second processor 122 transmits the ID of the faulty module to the first processor 113 through the second communication module 121, and the first processor 113 receiving the ID of the faulty module cuts off power. The unit 117 may cut off the power of one or more faulty modules corresponding to the IDs of the one or more faulty modules.

In addition, the first processor 113 may determine whether a fire has occurred based on the measured value transmitted from the fire detection module 130 , and if it is determined that a fire has occurred, the first processor 113 may transmit a signal to the power cutoff unit 117 . can The power cut-off unit 117 may block a transmission line connected to the inverter 150 or the solar cell module 170 in response to the received signal. The power cut-off unit 117 cuts off power when a fire occurs in the junction box, thereby reducing sudden power fluctuations in the solar cell module 170 and the inverter 150 to protect it.

According to various embodiments, the alarm system 118 may notify the outside of an emergency situation occurring inside the junction box 100 . The alarm system 118 may notify the state of the access box 100 to the user's electronic device 190 through the first communication module 111 . According to one embodiment, when the temperature of the junction box 100 changes rapidly, the alarm system 118 may transmit an alarm according to the sudden temperature change, and when the temperature continues to rise or smoke or sparks are detected, a fire alarm is issued. may be transmitted to the electronic device 190 . According to another embodiment, the alarm system 118 may visually or aurally access information related to a rise in temperature or a fire alarm through a device installed inside or outside the access box 100 (eg, the display 180 ). information can be conveyed.

The access box 100 according to various embodiments may include a display 180 for outputting visualized information to a user. In one embodiment, the display 180 is controlled by a controller such as the first processor 113 (eg, a graphic processing unit (GPU) included in the first processor 113 ) to be visualized by the user. Information (visualized information) can be output. The display 180 may include a cathode ray tube (CRT), a flat panel display (FPD), and/or electronic paper. The FPD may include a liquid crystal display (LCD), a plasma display panel (PDP), and/or one or more light emitting diodes (LEDs). The LED may include an organic LED (OLED). In an embodiment, the display 180 may provide a visual alarm according to the real-time generation voltage and current measurement values, the temperature inside and outside the junction box, the current generation state, or the temperature inside and outside the junction box.

Although not shown, the junction box 100 according to an embodiment may include an output means for outputting information in a form other than a visualized form. For example, the junction box 100 may include a speaker (not shown) for outputting an alarm situation as an acoustic signal.

According to various embodiments, the fire detection module 130 may acquire data related to the environment inside the junction box and transmit it to the integrated control device 110 . The transmitted data is processed by the integrated control device 110 , and the first processor 113 may be used to determine the internal environment of the junction box 100 .

The second communication module 131 may include a hardware component for supporting transmission and/or reception of an electrical signal between the integrated control device 110 and the fire detection module 130 . For example, the second communication module 131 may include at least one of a modem (MODEM), an antenna, and an O/E (Optic/Electronic) converter. The second communication module 131 is, Ethernet (ethernet), ZigBee (ZigBee) LAN (Local Area Network), WAN (Wide Area Network), WiFi (Wireless Fidelity), LTE (Long Term Evolution), 5G NR (New Radio) ) may support transmission and/or reception of electrical signals based on various types of protocols such as The second communication module 131 may transmit/receive data obtained from various sensors of the fire detection module 130 to the integrated control device 110 through the first communication module 111 .

The fire detection module 130 may include a plurality of sensors. For example, the plurality of sensors may include a flame detection sensor 133 , a smoke detection sensor 135 , and a temperature detection sensor 137 . The flame detection sensor 133 may detect a spark generated inside the junction box 100 . The flame detection sensor 133 may detect a spark such as a flame by using the flicker of a specific wavelength (185 nm to 260 nm) that occurs only in the flame. The flame detection sensor 133 may perform detection using infrared rays or detection using ultraviolet rays. The flame detection sensor 133 may detect the occurrence of a flame or a spark by using an image sensor to change the amount of an image.

According to an embodiment, the smoke detection sensor 135 may include a sensor such as a smoke detector or a fine dust detector. The smoke detection sensor 135 according to various embodiments may include an optical sensor for detecting a concentration of dust particles. Dust particles contained in air may have optical properties such as scattering, refraction, reflection and/or absorption when exposed to light. For example, dust particles having a relatively small size may scatter a relatively large amount of light. For another example, dust particles having a relatively large size may focus a relatively large amount of light. The optical sensor comprises a laser light emitter that emits laser light towards the air in which the dust particles are present and at least one that detects the degree to which the laser light is diffracted, refracted and/or reflected by the dust particles. of a laser light receiver (eg, a photo diode (PD)). The optical sensor may acquire the concentration of dust particles contained in the air based on the degree of diffraction, refraction and/or reflection by the dust particles detected based on the laser light receiver.

According to various embodiments, the flame detection sensor 133 and the smoke detection sensor 135 may be integrally formed. When the flame detection sensor 133 and the smoke detection sensor 135 are measured using light, they are integrally formed to detect flame and smoke.

According to various embodiments, the temperature sensor 137 may be a thermometer, and may be formed of a material having high heat resistance.

The electronic device 190 may include a notebook computer, a tablet PC, a PC, or a mobile device. The electronic device 190 may check information transmitted through the first communication module 111 . The electronic device 190 may display the situation inside the junction box 100 on the display of the electronic device 190 through a push. The electronic device 190 may receive information of the junction box 100 or the photovoltaic system 10 through a pre-installed application. The electronic device 190 may display various information such as power, current, or voltage generated by the photovoltaic power generation system 10 and transmit it to the user, and measure the internal temperature, temperature change, fire risk, etc. of the junction box 100 . It can be displayed and communicated to the user. The electronic device 190 may check connection board information, fire risk information, fire occurrence information, and the like through an installed application or software. In addition, the electronic device 190 transmits a cutoff signal to the first communication module 111 through wireless communication, so that the user can cut off the power directly. The electronic device 190 may check monitoring information and control power off for convenience of management.

2 is a schematic circuit diagram of an integrated control device included in a photovoltaic junction box according to various embodiments, and FIG. 3 is a schematic circuit diagram of a fire detection module included in a photovoltaic power generation junction box according to various embodiments.

Referring to FIG. 2 , the integrated control device 110 may be installed between the inverter 150 and the solar cell module 170 . The integrated control device 110 may constitute an emergency power off system. The emergency power cutoff system may cut off the power after receiving the fire information of the junction box, and may notify an alarm at the same time as the power cutoff.

According to various embodiments, the output terminal of the solar cell module 170 may include a fuse 119 for preventing overvoltage and overcurrent. The fuse 119 may prevent an electric shock of the inverter 150 or the junction box 100 by abruptly increasing the current flowing from the solar cell module 170 .

According to various embodiments, the alarm system 118 and the first communication module 111 are electrically connected, and when an alarm is generated, it may be transmitted to the user's electronic device 190 . In addition, the first communication module 111 and the power cutoff unit 117 may be electrically connected or operatively connected. When a fire-related signal is transmitted to the power cut-off unit 117 through the first communication module 111 , the power cut-off unit 117 blocks the transmission line flowing to the inverter based on the signal or the solar cell module 170 . Connected power can be cut off. According to various embodiments, the first communication module 111 , the power cut-off unit 117 , and the alarm system 118 may be electrically or operatively connected to the first processor 113 . The first processor 113 may be included in the first communication module 111 or the alarm system 118 . As described with reference to FIG. 1 , the alarm system 118 may visually express an alarm on the outside of the junction box or transmit information through sound in another way.

Referring to FIG. 3 , the second communication module 131 may be connected to the flame detection sensor 133 . Data measured by the flame detection sensor 133 may be transmitted to the first communication module through the second communication module 131 . According to various embodiments, the flame detection sensor 133 may be replaced with other types of sensors (eg, the smoke detection sensor 135 and the temperature detection sensor 137 ). According to another embodiment, all of the flame detection sensor 133 , the smoke detection sensor 135 , and the temperature detection sensor 137 may be electrically connected to the second communication module 131 . Data in the junction box acquired through various sensors may be transmitted to the integrated control device 110 through the second communication module 131 .

6 is a flowchart illustrating an operation of a photovoltaic junction box according to various embodiments, and FIG. 5 is a flowchart illustrating an operation algorithm of a photovoltaic power generation junction box according to various embodiments.

Referring to FIG. 6 , the first processor 113 included in the integrated control device 110 of the junction box may receive data from the fire detection module 130 ( S410 ). The data may be data collected through the flame detection sensor 133 , the smoke detection sensor 135 , and the temperature detection sensor 137 included in the fire detection module 130 . When data is received from the fire detection module, the received data may be stored in an allocated area of the memory 115 .

According to various embodiments, the first processor 113 may identify whether the junction box is on fire based on the received data (S430). The operation of identifying whether the junction box is fire will be described based on FIG. 7 .

Referring to FIG. 7 , among the data stored in the memory, the first processor 113 may determine whether the temperature is higher than or equal to the reference temperature based on the temperature inside the junction box collected from the temperature sensor 137 ( S431 ). ). The reference temperature may be a temperature preset by a user. The reference temperature may be stored in the memory 115 . The reference temperature may be set differently depending on the season or day and night. For example, the reference temperature in winter may be set lower than the reference temperature in summer. If it is set as the reference temperature for summer in winter, early detection of fire may be difficult. In the case of day and night, it can be set similarly. According to various embodiments, the reference temperature may be set to be changed based on the real-time measured external temperature.

According to various embodiments, the first processor 113 may transmit fire sign information when the temperature inside the junction box is high based on the reference temperature ( S432 ). The fire sign information may be an alarm related to a suspected fire. The first processor 113 may transmit the fire sign information to the user electronic device 190 through the first communication module 111 , and visually notify or output a sound such as a speaker through the display 180 . An alarm can sound through the device. For example, the first processor 113 may display the screen of the display 180 in orange or red color, and may notify a warning text.

According to various embodiments, the first processor 113 may monitor a change in the temperature inside the access box based on data received in real time from the fire monitoring module 130 . The first processor 113 may determine whether the internal temperature of the junction box decreases (S433).

If the temperature inside the junction box is lowering, the first processor 113 may compare the temperature with the reference temperature in the temperature data obtained in real time (S434). When the acquired temperature is equal to or greater than the reference temperature, the first processor 113 may repeat operation S433. When the acquired temperature is equal to or less than the reference temperature, the first processor 113 may transmit the risk release information and the inspection request information (S439). According to various embodiments, when the temperature obtained from the temperature sensor is lower than the reference temperature, the first processor 113 determines that a fire has not occurred, and transmits risk release information to prevent a fire from occurring. It can indicate that it is not. According to various embodiments, the first processor 113 may transmit the risk release information to the user electronic device 190 through the first communication module 111 , and visually notify the user through the display 180 . or a sound output device such as a speaker may sound an alarm. For example, the first processor 113 may display the screen of the display 180 by blinking green a plurality of times, and may notify that the alarm is released with a text. After a certain period of time, the display 180 may be switched to a screen informing of internal information such as the temperature of the access box.

The first processor 113 may transmit the inspection request information to the user electronic device 190 through the first communication module 111 , and visually notify or output a sound such as a speaker through the display 180 . An alarm can sound through the device. The user electronic device 190 may be a preset electronic device of a user designated as an inspection person.

According to an exemplary embodiment, the first processor 113 may display the phrase "check request" on a predetermined area of the screen of the display 180 or display a color promised as the maintenance request on the display screen.

According to various embodiments, when the obtained temperature is equal to or greater than the reference temperature, the first processor 113 may block the transmission line connected to the solar cell module 170 ( S435 ). According to various embodiments, when power is continuously supplied from the solar cell module 170, a fire may be further caused, and even before a fire, the temperature may be increased by the power supplied to the line. In addition, the power supplied from the solar cell module 170 should be efficiently transmitted to the inverter, but due to a failure of the junction box, there is a risk that the amount of power sent to the inverter may change rapidly. In order to prevent the failure of the inverter, the first processor 113 may cut off the power transmitted from the solar cell module 170 .

According to various embodiments, the first processor 113 may determine whether the internal temperature of the junction box is lowered (S436). If the temperature inside the junction box falls, the first processor 113 repeats operation S436 if the temperature in the data transmitted from the temperature sensor is above the reference temperature (S437), and if it is below the reference temperature, the solar cell module side power supply It can be opened (S438). When the temperature rises above the reference temperature, the first processor 113 may determine that there is a risk of fire and repeat operation S436 of determining whether the temperature inside the junction box has decreased. When the temperature falls below the reference temperature, the first processor 113 may determine that a fire does not occur, and reconnect the open transmission line of the solar cell module. When the transmission line of the solar cell module is connected, it is possible to transmit the risk release information and the inspection request information (S439). According to various embodiments, the first processor 113 may transmit the risk release information to the user electronic device 190 through the first communication module 111 , and visually notify the user through the display 180 . or a sound output device such as a speaker may sound an alarm. For example, the first processor 113 may display the screen of the display 180 by blinking green a plurality of times, and may notify that the alarm is released with a text. After a certain period of time, the display 180 may be switched to a screen informing of internal information such as the temperature of the access box.

According to various embodiments, if the internal temperature of the junction box does not drop, the first processor 113 determines that a fire occurs, and the first processor 113 opens and closes the inverter or module power supply based on identification of whether the junction box fire occurs. A fire alarm can be notified (S450). The first processor 113 may cut off the power by opening the transmission line in order to reduce the influence on the inverter due to a reverse current applied to the inverter or a fire.

The fire information may be an alarm related to the occurrence of a fire. The first processor 113 may transmit the fire information to the user electronic device 190 through the first communication module 111 , and visually notify or output a sound such as a speaker through the display 180 . An alarm can sound through the device. For example, the first processor 113 may display the screen of the display 180 in red color and notify a warning text. According to various embodiments, the first processor 113 may transmit fire information to the user electronic device 190 and, at the same time, transmit fire details to a public office such as a fire station.

As described above, the building-integrated photovoltaic power generation junction box according to the various embodiments described above is disposed in the photovoltaic power generation junction box, an integrated control device for controlling an emergency situation of the photovoltaic power generation system, and the photovoltaic power generation junction box A first communication module including a fire detection module disposed in the junction box to detect an internal condition of the junction box, and wherein the integrated control device includes a communication processor (CP) for communicating with one or more electronic devices, the a memory in which detection data of the fire detection module is stored; A power cut-off unit for cutting off a power transmission line connected to a solar cell module or an inverter based on the sensed data, and at least one processor operably coupled to the first communication processor and the memory, , The fire detection module includes a plurality of sensors for detecting the internal situation of the junction box, and communicates with the first communication module, a second communication module for transmitting the detection data of the plurality of sensors to the integrated control device wherein the memory stores a plurality of instructions, and when the plurality of instructions are executed by the at least one processor, the at least one processor receives detection data from the fire detection module and , based on the received detection data, identify whether the photovoltaic power generation junction box fire, and in response to the identification of whether the junction box fire, open the power transmission line of the inverter or the solar cell module, and the transmission Simultaneously with the opening of the line, a fire alarm may be controlled to be notified to at least one of the one or more electronic devices through the first communication module.

According to various embodiments, the plurality of sensors may include a flame detection sensor, a smoke detection sensor, or a temperature detection sensor, and the detection data may include temperature data, spark detection data, or smoke detection data.

According to various embodiments, when the plurality of instructions are executed by the at least one processor, when the at least one processor identifies whether the photovoltaic power generation junction box is on fire, the inside of the junction box obtained from the temperature data It is identified whether the temperature of the junction box is equal to or greater than the reference temperature, and in response to the identification of the internal temperature of the junction box, a first signal related to fire information is transmitted to the at least one electronic device through the first communication module, and the sun Control to block the transmission line connected to the battery module, the first signal may include a signal related to a fire suspicion notification.

According to various embodiments, when the plurality of instructions are executed by the at least one processor, after the at least one processor transmits the fire indication information, the temperature inside the junction box obtained from the temperature data is the reference temperature When it is lowered to below, it is controlled to transmit a second signal related to fire information to the at least one electronic device through the first communication module, and the second signal is a signal related to a fire risk release and a junction box maintenance request may include.

According to various embodiments, when the plurality of instructions are executed by the at least one processor, the at least one processor may When the temperature is lowered below the reference temperature, the transmission line of the solar cell module may be connected.

According to various embodiments, when the plurality of instructions are executed by the at least one processor, the at least one processor may When the temperature is maintained or increased, the transmission line of the inverter may be opened.

According to various embodiments, a fuse disposed between the solar cell module and the power cutoff unit may be further included.

According to various embodiments, it includes a solar cell module, a photovoltaic junction box having one end connected to the solar cell module, and an inverter connected to the other end of the photovoltaic power generation junction box, wherein the photovoltaic power generation junction box is the solar cell module. It is disposed in the photovoltaic power generation junction box, including an integrated control device for controlling the emergency situation of the photovoltaic power generation system, and a fire detection module disposed in the photovoltaic power generation junction box to detect the internal condition of the junction box, the integrated control The device includes: a first communication module including a communication processor (CP) for communicating with one or more electronic devices, a memory in which detection data of the fire detection module is stored; A power cut-off unit for cutting off a power transmission line connected to the solar cell module or the inverter based on the sensed data, a fuse disposed between the solar cell module and the power cut-off unit, and the first communication processor and the memory; at least one processor operably coupled to, wherein the fire detection module includes a plurality of sensors for sensing an internal condition of the junction box, and in communication with the first communication module, the plurality of a second communication module for transmitting the sensing data of the sensors to the integrated control device, wherein the memory stores a plurality of instructions, and when the plurality of instructions are executed by the at least one processor, The at least one processor receives detection data from the fire detection module, and based on the received detection data, identifies whether the photovoltaic power generation junction box is on fire, and in response to the identification of whether the junction box fire, A power transmission line of the inverter or the solar cell module may be opened, and a fire alarm may be notified to at least one of the one or more electronic devices through the first communication module at the same time as the transmission line is opened.

Methods according to the embodiments described in the claims or specifications of the present disclosure may be implemented in the form of hardware, software, or a combination of hardware and software.

When implemented in software, a computer-readable storage medium storing one or more programs (software modules) may be provided. One or more programs stored in the computer-readable storage medium are configured for execution by one or more processors in an electronic device (device). The one or more programs include instructions for causing an electronic device to execute methods according to embodiments described in a claim or specification of the present disclosure.

In the specific embodiments of the present disclosure described above, elements included in the disclosure are expressed in the singular or plural according to the specific embodiments presented. However, the singular or plural expression is appropriately selected for the context presented for convenience of description, and the present disclosure is not limited to the singular or plural element, and even if the element is expressed in plural, it is composed of the singular or singular. Even an expressed component may be composed of a plurality of components.

Meanwhile, although specific embodiments have been described in the detailed description of the present disclosure, various modifications are possible without departing from the scope of the present disclosure. Therefore, the scope of the present disclosure should not be limited to the described embodiments and should be defined by the claims described below as well as the claims and equivalents.

Claims (12)

In the building-integrated photovoltaic power generation access box,
an integrated control device disposed in the building-integrated photovoltaic power generation junction box to control an emergency situation of the photovoltaic power generation system;
a module monitoring device disposed in the building-integrated photovoltaic power generation junction box to monitor one or more solar cell modules to which sunlight is incident for photovoltaic power generation; and
It is disposed in the building-integrated photovoltaic power generation junction box, including a fire detection module for detecting the internal situation of the junction box,
The integrated control device may include: a first communication module including a communication processor (CP) for communicating with one or more electronic devices; a memory storing detection data of the fire detection module; A power cut-off unit for cutting off a power transmission line connected to a solar cell module or an inverter based on the sensed data, and at least one first processor operably coupled to the first communication module and the memory including,
The module monitoring device includes a communication processor for communicating with one or more electronic devices, and communicates with the first communication module to transmit monitoring data for the one or more solar cell modules to the integrated control device. a module, and at least one second processor monitoring the one or more solar cell modules and operatively coupled to the second communication module;
The fire detection module includes a plurality of sensors for detecting an internal situation of the junction box, and a third communication module for communicating with the first communication module to transmit the detection data of the plurality of sensors to the integrated control device do,
The memory stores a plurality of instructions,
When the plurality of instructions are executed by the at least one first processor, the at least one first processor
receiving the voltage values of the one or more solar cell modules from the second processor;
The second processor monitors one or more strings on which the one or more solar cell modules are arranged, and monitors the voltages of the one or more solar cell modules when the voltages of the one or more strings do not match,
The second processor assigns an ID to each of the one or more solar cell modules, monitors the one or more solar cell modules by the ID, and generates power generation information and temperature information of the one or more solar cell modules for each of the one or more solar cell modules. , to generate the monitoring data including a voltage value and a current value,
Among the one or more modules, when the voltage value of any one or more solar cell modules is identified as a predetermined difference value or less than the voltage values of one or more other solar cell modules, the voltage value is measured lower than that of the one or more other solar cell modules It is determined whether the voltage value of the one or more solar cell modules is temporarily low, or whether a difference is generated within a predetermined difference value, and the voltage value of the one or more solar cell modules measured low is temporarily If it is measured low or is a difference within a predetermined difference value range, waiting for a certain time so that the voltage value of the one or more solar cell modules is restored to the voltage value of the one or more other solar cell modules,
When the voltage value is not recovered, the buck-boost mode is driven to boost the voltage value of any one or more solar cell modules to the voltage value of the one or more other solar cell modules,
When the voltage value of the boosted one or more solar cell modules matches the voltage of the one or more other strings, maximum power pointer tracking (MPPT) and current control so that the maximum output can be generated by adjusting the voltage of the one or more strings An algorithm is executed to reduce the high voltage by controlling the current and boost the low voltage to adjust the voltage so that the voltage value that produces the maximum output in the photovoltaic power generation is reached, thereby reducing the voltage of the entire string in the photovoltaic power generation. It is adjusted to the voltage value that produces the maximum output,
Receive detection data from a third communication module of the fire detection module,
In response to the determination of whether a junction box fire occurs, a first signal related to fire information is transmitted to the at least one or more electronic devices through the first communication module, and a power transmission line connected to the solar cell module is opened,
After the opening of the transmission line of the solar cell module, when the temperature inside the junction box obtained from the temperature data is maintained or increased, controlling to open the transmission line of the inverter,
The first signal is a building-integrated photovoltaic power generation junction box including a signal related to a notification of suspected fire.
delete delete The method of claim 1,
When the second processor detects one or more faulty modules in the one or more solar cell modules, the building-integrated photovoltaic power generation transmits the ID of the one or more faulty modules to the first processor through the second communication module connected.
5. The method of claim 4,
When the plurality of instructions are executed by the at least one first processor, the at least one first processor
When receiving the ID of the one or more faulty modules from the second communication module,
A building-integrated photovoltaic power generation junction box that cuts off the power of the one or more faulty modules corresponding to the IDs of the one or more faulty modules.
6. The method of claim 5,
The plurality of sensors include a flame detection sensor, a smoke detection sensor, or a temperature detection sensor,
The sensing data is a building-integrated photovoltaic power generation junction box including temperature data, spark sensing data, or smoke sensing data.
delete 7. The method of claim 6,
When the plurality of instructions are executed by the at least one first processor, the at least one first processor
After transmitting the fire sign information, when the temperature inside the junction box obtained from the temperature data falls below the reference temperature, a second signal related to the fire information is transmitted to the at least one electronic device through the first communication module controlled to transmit,
The second signal is a building-integrated photovoltaic power generation junction box including a signal related to a fire risk release and a junction box maintenance request.
7. The method of claim 6,
When the plurality of instructions are executed by the at least one first processor, the at least one first processor
After the transmission line of the solar cell module is cut off, when the temperature inside the junction box obtained from the temperature data falls below the reference temperature, a building-integrated photovoltaic power generation junction box that connects the transmission line of the solar cell module.
delete According to claim 1,
A building-integrated photovoltaic power generation junction box further comprising a fuse disposed between the solar cell module and the power cutoff unit.
In the building-integrated photovoltaic device,
solar module;
a building-integrated photovoltaic power generation junction box whose one end is connected to the solar cell module; and
Including; an inverter connected to the other end of the building-integrated photovoltaic power generation junction box;
The building-integrated photovoltaic power generation junction box includes a module monitoring device disposed in the building-integrated photovoltaic power generation junction box to monitor one or more modules to which sunlight is incident for photovoltaic power generation,
The building-integrated photovoltaic power generation junction box is disposed in the building-integrated photovoltaic power generation junction box, and is disposed in the integrated control device and the photovoltaic power generation junction box to control the emergency situation of the photovoltaic system, the interior of the junction box A fire detection module for detecting the situation,
The integrated control device may include: a first communication module including a communication processor (CP) for communicating with one or more electronic devices; a memory storing detection data of the fire detection module; A power cut-off unit for cutting off a power transmission line connected to the solar cell module or the inverter based on the sensed data, a fuse disposed between the solar cell module and the power cut-off unit, and the first communication module and the memory; at least one first processor operably coupled to;
The module monitoring device includes a communication processor for communicating with one or more electronic devices, and a second communication module communicating with the first communication module to transmit monitoring data for the one or more modules to the integrated control device; and at least one second processor monitoring the one or more modules and operatively coupled to the second communication module;
The fire detection module includes a plurality of sensors for detecting the internal situation of the junction box, and communicates with the first communication module to transmit the detection data of the plurality of sensors to the integrated control device. including,
The memory stores a plurality of instructions,
When the plurality of instructions are executed by the at least one first processor, the at least one first processor
receiving the voltage values of the one or more solar cell modules from the second processor;
The second processor monitors one or more strings on which the one or more solar cell modules are arranged, and monitors the voltages of the one or more solar cell modules when the voltages of the one or more strings do not match,
The second processor assigns an ID to each of the one or more solar cell modules, monitors the one or more solar cell modules by the ID, and generates power generation information and temperature information of the one or more solar cell modules for each of the one or more solar cell modules , to generate the monitoring data including a voltage value and a current value,
Among the one or more modules, when the voltage value of any one or more solar cell modules is identified as a predetermined difference value or less than the voltage values of one or more other solar cell modules, the voltage value is measured lower than that of the one or more other solar cell modules It is determined whether the voltage value of the one or more solar cell modules is temporarily low, or whether a difference is generated within a predetermined difference value, and the voltage value of the one or more solar cell modules measured low is temporarily If it is measured low or is a difference within a predetermined difference value range, waiting for a certain time so that the voltage value of the one or more solar cell modules is restored to the voltage value of the one or more other solar cell modules,
When the voltage value is not recovered, the buck-boost mode is driven to boost the voltage value of the one or more solar cell modules to the voltage value of the one or more other solar cell modules,
When the voltage value of the boosted one or more solar cell modules matches the voltage of the one or more other strings, maximum power pointer tracking (MPPT) and current control so that the maximum output can be generated by adjusting the voltage of one or more strings An algorithm is executed to reduce the high voltage by controlling the current to reach the voltage value that produces the maximum output in the photovoltaic power plant, and boost the lower voltage to adjust the voltage, thereby reducing the voltage of the entire string in photovoltaic power generation. It is adjusted to the voltage value at which the maximum output is produced,
Receive detection data from a third communication module of the fire detection module,
In response to the determination of whether the junction box is in fire, a first signal related to fire information is transmitted to the at least one or more electronic devices through the first communication module, and a power transmission line connected to the solar cell module is opened, and ,
After opening the transmission line of the solar cell module, when the temperature inside the junction box obtained from the temperature data is maintained or increased, controlling to open the transmission line of the inverter,
The first signal is a building-integrated photovoltaic power generation junction box including a signal related to a notification of suspected fire.

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