KR102672276B1 - The solar power system with auto power-off function by leakage current - Google Patents

Abstract

The present invention relates to electricity caused by poor connection, insulation breakdown, short circuit, or ground fault in related equipment such as positive (+) or negative (-) wiring or module connection box in a direct current power circuit that transmits power generated from a solar module to an inverter. In order to detect accidents or electrical fires at an early stage and prevent their spread, positive (+) and negative (-) currents with opposite directions pass through a circular or square iron core through a positive (+) and negative (-) direct current circuit. When a conductor is placed in a magnetic field in a CT in which a magnetic flux is formed equal to the leakage current size equal to the difference remaining after the magnetic flux is canceled out, and a Hall element installed in a part of the CT is placed in a magnetic field, if a current flows in a direction perpendicular to the magnetic field, a current perpendicular to both the magnetic field and the current Using the Hall effect, which generates a potential difference in one direction, the leakage current caused by the magnetic flux of the difference between the anode (+) and cathode (-) currents is measured, and when a leakage current exceeding the specified value occurs, the DC power is automatically blocked and a notification function is provided. A safe solar power generation system consisting of a modular automobile disconnect panel connection box and inverter monitoring that can prevent the spread of electrical accidents and electrical fires and minimize damage to life and property by realizing the initial suppression of electrical accidents and electrical fires caused by electric leakage, including monitoring functions. It's about.

Description

{The solar power system with auto power-off function by leakage current}

The present invention relates to a solar power generation system having an electric leakage detection function for preventing electrical accidents and fires due to electric leakage and for initially extinguishing fires, an automatic power cutoff function for modules, a manual power cutoff function, a notification function, and a monitoring function. In detail, leakage current is detected when a short circuit occurs due to insulation breakdown or ground fault in facilities such as positive (+) or negative (-) wiring or connection boxes of DC power equipment that transmits power generated from solar modules to the inverter. It determines the degree of insulation and whether there is a ground fault and self-isolates from its own electrical system to prevent additional or expanded insulation breakdown, electrical accidents, casualties and electrical fires, and provides a safe solar power generation system with prompt notification of electrical leakage and automatic power cut-off function. It's about.

Solar power generation generates electricity by irradiating light energy to solar cells (modules) made of semiconductors and converting the light energy into direct current electricity. It uses unlimited and pollution-free solar energy, so there are no fuel costs and no air pollution. It generates little waste, has no mechanical vibration and noise, has a long lifespan of at least 25 years, and is easy to maintain.

In general, a solar power generation system includes a solar module that generates direct current electrical energy, a connection box that collects the multiple circuits of direct current power generated by the solar module into a single direct current power source to transfer it to an inverter, and converts the direct current power into alternating current power. It includes an inverter that converts the AC power, and the AC power converted by the inverter is connected to the power grid system through a separate AC distribution board and is supplied to the premises or customers for use.

Since the amount of electrical energy generated from a unit solar cell is very small, several solar cell groups are usually manufactured as modules. In addition, multiple solar modules are arranged in series to form an array, and these array groups are reorganized into modules. By combining them in parallel, the necessary power is secured as a single circuit power source.

Meanwhile, the junction box is composed of a DC output switch or circuit breaker, lightning protection element, fuse, etc., and performs the function of collecting the DC power generated from multiple solar modules into one circuit and transmitting it to the inverter. It is usually installed near the outdoor module. Therefore, as it is operated for a long period of time in harsh conditions such as rain and high temperature environments, there is always a high possibility of fire occurring, and most of the defects in the solar power generation system currently in operation occur in the connection box.

These solar junction boxes are complicatedly arranged with various electrical components and wiring, so there is a high risk of overheating due to poor contact, arcing due to disconnection or short circuit, and insulation breakdown due to deterioration of the insulating coating material. It can easily spread into a large fire.

In addition, there is a need for constant monitoring of accident-causing conditions that are fatal to electrical safety, such as electric current, ground fault, and short-circuit of the module's DC power and DC distribution equipment. However, due to continuous power supply and connection to the existing power system, insulation resistance was measured regularly by separating the circuit from the power supply. Although safety was determined, it is difficult to respond to the unexpected occurrence of accidents, so facilities with a constant monitoring function for leakage current in the DC system are required.

In addition, since solar modules or junction boxes are installed outdoors, it is not easy to quickly extinguish a fire even if a fire is recognized. In general, early extinguishment is very important in the event of a fire, and even after a fire occurs, direct current power continues to flow from the solar module. There was a problem that could not be easily evolved.

When an electrical fire occurs, damage to property and human life is very significant, so the most important thing is the early detection of electrical accident factors such as leakage current, insulation resistance, temperature, and CO gas. Functional devices, modules, or battery DC power cutoff devices and DC power-related voltages The development of a current measurement system is very urgent.

The present invention is intended to solve the difficult problem of detecting and responding to electric leakage accidents that may occur at any time in a management form that has the disadvantages of the above-described conventional professional technician performing power outages and regular inspections with portable measuring instruments. By detecting the polarity and size of electric leakage in the DC distribution line from the system module to the inverter, the automatic disconnect panel quickly and automatically takes measures such as power off, manual cutoff, automatic notification, etc. to block the DC circuit between the module and the inverter. The purpose is to provide a safe and convenient solar power generation system with an automatic power cut function that can prevent load equipment failure or secondary electrical accidents due to electrical accidents, prevent electrical fires, completely suppress the initial stage, and prevent spread.

In order to achieve the above object, the present invention includes a plurality of solar modules (100) that receive sunlight to generate direct current power; A fuse is installed to block the circuit in case of overcurrent in the positive (+) and negative (-) circuits of several series direct current power generated from the solar module 100, and the circuits are combined into one direct current power circuit to be supplied to the inverter 400 through a circuit breaker. Before transmission, a connection box (300) consisting of a leakage current sensor (350) and an output voltage and current sensor (330); Located between the solar module 100 and the junction box 300, the junction box 300 or the automatic disconnect panel 200 is used to transmit direct current power of the solar module 100 to the junction box 300. According to the information of the leakage current sensor 350 of ), signs of electrical accidents or electrical fires such as electric leaks, ground faults, and short circuits in the DC distribution lines or facilities connected from the module 100 to the connection box 300 are monitored to generate solar energy. A DC power automatic cutoff panel 200 that automatically blocks DC power of the module 100 from being supplied to the connection box 300 or the inverter 400; In addition, an inverter 400 that converts the DC power collected into one circuit from the various DC power of the solar module 100 into AC power for use at actual load by linking it with the existing power system; It is composed of a monitoring system 500 that can monitor power information 330 such as current and voltage of the connection box 300, weather information of the weather sensor, power information of the inverter 400, etc. from a remote location such as a central monitoring room. The DC power distribution line sent from the solar module 100 to the inverter 400 is monitored for signs of electrical accidents or electrical fires such as electric leaks, ground faults, and short circuits, and is automatically or manually blocked at the DC power automatic disconnect panel 200. As a feature, it provides a solar power generation system that can prevent electrical accidents and prevent their spread.

At this time, in order to measure the leakage current of a DC circuit, when a CT and a conductor, which generate a magnetic flux equal to the size of the current passing through a circular or square iron core, are placed in a magnetic field and a current flows in a direction perpendicular to the magnetic field, both the magnetic field and the current It is characterized by measuring leakage current with a leakage current sensor 350 composed of a Hall element using the Hall effect, which generates a potential difference in a vertical direction.

In addition, there is an information processing unit that measures the polarity and size of the leakage current with the leakage current sensor 350 and compares the information with the circuit current and voltage information, a signal generator that sends a blocking signal, and a visual display of information such as current and voltage alarms. It is characterized in that the earth leakage detection CPU (280), which consists of a display unit, a communication circuit unit that transmits information to monitoring, and an alarm generation unit that issues an alarm, is disposed in the automatic disconnect panel (200).

A shunt coil 220 and electronic relay 210 that automatically cut off the direct current power generated by the solar module 100 in connection with the earth leakage detection CPU 280, and a cut-off operation indicator that instructs a cut-off signal to the shunt coil 220. (250), a manual button (240) that can manually give a blocking signal, a notification unit (230) that notifies the outside of the occurrence of leakage current and an abnormal situation in the electric circuit, an earth leakage detection CPU (280) and a blocking operation instruction unit (250) It is characterized by including a power supply unit 290 that supplies power to the automatic disconnect panel 200.

The leakage current sensor 350 can be installed in the automatic disconnect panel 200 for each series circuit of the module, and the electronic relay 210 for each circuit capable of responding to detailed fault circuits can be blocked, and can be designed to be blocked at once. .

According to an embodiment of the present invention, the following effects are achieved.

First, it is possible to monitor signs of electrical accidents or electrical fires, such as electric leaks, ground faults, and short circuits in DC distribution lines or facilities, and quickly block the spread of DC power generated by solar modules to initially extinguish accidents or fires.

Second, physical damage and human damage can be prevented or minimized by quickly shutting off direct current power.

Third, by monitoring and blocking signs of electrical accidents or electrical fires such as electric leaks, ground faults, and short circuits in DC distribution lines or facilities, the cost of restoring facilities is reduced by quickly extinguishing accidents and minimizing burnout, and the recovery period is shortened, resulting in a decrease in power generation. can be minimized.

Fourth, it has the effect of preventing the spread of fire, which could result in a major accident, and preventing the risk of fatal accidents such as electric shock and toxic gas poisoning.

In conclusion, it first detects the initial state of an electrical accident such as a short circuit or ground fault in a DC circuit, warns of the situation, protects the system by blocking the DC power supply from the solar module, and minimizes the spread of damage to reduce recovery costs and recovery time. We can provide a safe and economical solar power generation system that reduces energy consumption.

1 is a diagram for explaining an embodiment of a general solar power generation system according to the present invention.
Figure 2 is a diagram showing the configuration of a solar power generation system including an automatic DC power cutoff panel by detecting electric leakage according to an embodiment of the present invention.
Figure 3 is a diagram illustrating the configuration of a leakage current detection sensor for detecting leakage current and the Hall effect according to the present invention.
Figure 4 is a diagram for explaining the configuration of an earth leakage detection CPU in a solar power generation system according to an embodiment of the present invention.

A preferred embodiment of the present invention will be described in detail with the accompanying drawings as follows. In addition, the specific structural or functional descriptions presented in the embodiments of the present invention are merely illustrative for the purpose of explaining the embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention may be implemented in various forms. there is. Additionally, it should not be construed as being limited to the embodiments described in this specification, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

The terms used in this specification are merely used to describe specific embodiments and are not intended to limit the invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, terms such as "comprise" or "have" are intended to designate the presence of implemented features, numbers, steps, operations, components, parts, or combinations thereof, but are intended to indicate the presence of one or more other features or numbers, It should be understood that this does not exclude in advance the possibility of the presence or addition of steps, operations, components, parts, or combinations thereof.

As such, the terms used in the present invention are general terms that are currently widely used as much as possible. However, in certain cases, there are terms arbitrarily selected by the applicant, and in this case, the meaning is described in detail in the description of the relevant invention, so it is a simple term. We would like to make it clear that the present invention should be understood by the meaning of the term, not by its name.

In addition, when describing the embodiments, descriptions of technical content that is well known in the technical field to which the present invention belongs and that are not directly related to the present invention will be omitted. By omitting unnecessary descriptions, this will not obscure the gist of the present invention and will make it clearer. It is to convey.

1 is a diagram for explaining an embodiment of a general solar power generation system according to the present invention. As shown in FIG. 1, an embodiment of a general solar power generation system is configured to connect a plurality of solar modules 100, a junction box 300, and an inverter 400 in series with the power system and supply power to the load. do. Here, the plurality of solar modules 100 receive sunlight and generate direct current power. In the present invention, the connection box 300 consists of a circuit in series with a certain number of solar modules 100 within the voltage range at which the inverter 400 can operate, and the fuse 310 for circuit protection in case of overcurrent is connected to the positive pole. An array is formed by installing on the over-pole, and several parallel groups of the same voltage configured in this way are gathered into one DC circuit and supplied to the inverter 400 through the breaker 320, and the inverter 400 is connected to the power system. If possible, it is converted into AC power and supplied. At this time, in the case of an independent solar power generation system, an additional reverse voltage diode can be installed in series with the fuse.

Figure 2 is a solar power generation system including a direct current power automatic cutoff panel 200 by detecting electric leakage according to an embodiment of the present invention. The leakage current sensor 350 is placed on the automatic disconnect panel 200. At this time, the DC circuit of the automatic disconnect panel 200 is connected in series to a plurality of modules 100, and the positive electrode (+) is connected to the electronic relay 210 of the shunt coil 220, and the negative electrode (-) is connected to the fuse 310. The circuit is supplied to the inverter 400 in a parallel circuit state of several protected arrays. At this time, a leakage current sensor 350 is placed in each parallel circuit to detect leakage current, so that electrical accidents such as earth leakage and ground fault are detected for each parallel circuit, and an earth leakage detection CPU 280 that can block each parallel circuit and operates a blocking operation. By configuring the indicator unit 250, it is possible to have the advantage of being able to distinguish accident sections for each circuit.

Figure 3 is a diagram illustrating the Hall effect of a leakage current detection sensor for detecting leakage current according to the present invention. It is a diagram of a configuration that can measure direct current leakage current by combining a current transformer CT method and a Hall element, and acts on the Hall element. This is a drawing expressing the Hall effect principle. When the anode (+) and cathode (-) conductors, which are measured direct current conductors, pass through a CT current transformer, the magnetic flux is equal to the difference between the current magnitudes of the anode (+) or cathode (-). After canceling out the polarity of the anode (+) or cathode (-), the remaining magnetic flux acts on this Hall element to produce a Hall voltage due to the Hall effect. The Hall voltage is induced by an extremely low voltage and amplified to produce an anode (+) or cathode ( -) Leakage current can be measured. Here, the Höl effect refers to the phenomenon in which when a magnetic field H _z is applied perpendicularly to a _thin metal or semiconductor plate through which a current I _x flows in the x direction, an electromotive force E _y is generated in a direction perpendicular to H _z and I It is called the effect or electric current effect. It was discovered in 1879 by American physicist EH Hall. This is due to the fact that the carrier carrying electricity receives the Lawrence force in a direction perpendicular to the current and magnetic field, and its movement is bent. _When I ​ _​ ​ _​ ​ _​ ​ _​ That _is , R _H is given as R _{H =} E _Y /( I If the plate thickness is t [m], the hole voltage is V _H [V], the current is I [A], and the magnet density is B [Wb/㎡], the previous equation is R _H = tV _H /( I B )*10 ² It is [㎥/C], and the Hall coefficient is inversely proportional to the carrier density and is affected by the type of material and temperature.

Figure 4 is a diagram to explain the configuration of the earth leakage detection CPU in the solar power generation system according to an embodiment of the present invention. It is a configuration for information processing of the earth leakage detection CPU 280 of the automatic disconnect panel 200, and includes a leakage current sensor and a circuit current. Sensor, voltage sensor, optional fire information, power supply, emergency stop and reset button, blocking signal and monitoring are linked, and internally it is composed of communication unit, display unit, alarm generation unit, signal generation unit and information processing unit. It shows.

Although the present invention has been described with the above examples, the present invention is not necessarily limited to these examples, and various modifications may be made without departing from the technical spirit of the present invention. Accordingly, the examples disclosed in the present invention are not intended to limit the technical idea of the present invention but are for illustrative purposes, and the scope of the technical idea of the present invention is not limited by these examples. The scope of protection of the present invention shall be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope thereof shall be construed as being included in the scope of rights of the present invention.

100: solar module
200: DC power blocking panel
210: Electronic relay 220: Shunt coil (trip operation coil)
230: Notification unit 240: Manual button
250: Blocking operation indicator
280: Earth leakage detection CPU
290: Power supply unit
300: Connected
310: Fuse 320: Circuit breaker/switch
330: Power information instrument
350: Leakage current sensor
400: Inverter
500: Monitoring system

Claims (3)

A leakage current sensor 350 located in each series circuit between the solar module 100 and the connection box 300 or the inverter 400 to sense leakage current,
In connection with the earth leakage detection CPU 280, which determines the leakage current sensing information, the shunt coil 220, the electronic relay 210, and the shunt coil 220 are blocked to automatically cut off the direct current power of the solar module 100. A blocking operation indicator 250 that indicates a signal,
A manual button (240) that can manually give a blocking signal,
A notification unit 230 that notifies the outside world of circuit breakage due to the occurrence of leakage current and abnormal situations in the electric circuit,
It consists of a power supply unit 290 that supplies power to the earth leakage detection CPU 280 and the blocking operation instruction unit 250,
It has a function of selectively blocking only the circuit in which the accident occurred when there are signs of an electrical leakage, ground fault, or short circuit in the DC distribution line or equipment of the solar module 100, and automatically blocking all circuits when detecting signs of an electrical fire. Including DC power automatic disconnect panel (200),
An information processing unit that measures the polarity and size of the leakage current with the leakage current sensor 350 and compares the information with the circuit current information to determine whether there is an abnormality in the information processing unit, a signal generator that sends a blocking signal according to the determination of abnormality in the information processing unit, and current alarm information. The earth leakage detection CPU (280), which consists of a display unit that displays visually, a communication circuit unit that transmits information through communication to monitoring, and an alarm generation unit that issues an alarm, is placed in the automobile disconnect panel (200),
The connection box 300 configures a circuit in series with a certain number of solar modules 100 within the voltage range at which the inverter 400 can operate, and provides a fuse 310 for circuit protection in case of overcurrent, with + and - poles connected. It is installed on a pole to form an array, and several parallel groups of arrays of the same voltage are gathered into one DC circuit and supplied to the inverter (400) through the breaker (320).
The inverter 400 converts and supplies AC power that can be connected to the power system, and in the case of an independent solar power generation system, a reverse voltage diode is additionally installed in series with the fuse and has an automatic power-off function by detecting an earth leakage. A solar power generation system.
According to paragraph 1,
To measure the leakage current of a DC circuit, a conductor is placed in a magnetic field in a CT where a magnetic flux is formed equal to the difference between the anode (+) and cathode (-) currents penetrating a circular or square iron core, and a Hall element installed in a part of the CT. When a current flows in a direction perpendicular to the magnetic field, the leakage current sensor 350 measures the leakage current using the Hall effect, which generates a potential difference in the direction perpendicular to both the magnetic field and the current. The insulation status of the DC circuit is determined and the electrical A solar power generation system characterized by monitoring the risk of accidents.
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