KR101569199B1 - Photovoltaic power generation system having fire prevention apparatus - Google Patents

Abstract

The present invention relates to a fire prevention-type photovoltaic power generation system through a bypass circuit and impedance measurement. According to the present invention, a connection board comprises: a solar panel (S1) producing electric power; an input terminal (S2) receiving electric power from the solar panel (S1); a fuse (S3) and a circuit breaker receiving electric power outputted from the input terminal (S2); a diode (S4) outputting onto an output terminal (S5) by receiving electric power; an output terminal (S5) outputting onto an inverter by receiving electric power outputted from the diode (S4); and a system monitoring internal situations. in addition, the photovoltaic power generation system of the present invention comprises: a bypass track (110) allowing electric power inputted into the input terminal (S2) to be outputted through the output terminal by taking a detour; a bypass switch (115) opening and closing the bypass track (110) in accordance with a controlling signal from the controlling part (130); a voltage detecting track (140) provided on the input terminal (S2) and the output terminal; and a measurement part (120) monitoring a state of voltage value existing on the voltage detecting track (140).

Description

PHOTOVOLTAIC POWER GENERATION SYSTEM HAVING FIRE PREVENTION APPARATUS BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a photovoltaic

FIELD OF THE INVENTION The present invention relates to a photovoltaic power generation system using impedance measurement and a bypass circuit, and more particularly, to a fire prevention diagnosis system that continuously monitors the cause of a fire inside a connection box, The impedance (resistance value) value is measured between the input terminal and the output terminal

When the measured resistance value and the voltage value are within the preset resistance range, it is determined that the electric and / or electronic elements connected to the line between the input terminal and the output terminal are normally connected to the line,

When the measured resistance and voltage value exceed the preset resistance range, it is judged that the electric and electronic elements connected to the line in the input terminal and the output terminal are abnormally connected to the line

A technique of transmitting data of the abnormality of the line to the manager side in the ecology where the bypass switch is turned on and the power is output to the output terminal via the bypass line

In addition, if the voltage value of the line of the first and second line sections is unbalanced by dividing the input terminal and the output terminal into the first and second line sections, it is determined that there is a problem in the line where the voltage exceeding the reference value is generated to provide.

Generally, the solar cell connecting unit collects the direct current generated from a plurality of solar cell modules included in the solar power generation system and outputs the collected direct current to the inverter included in the solar power generation system.

Such a photovoltaic connection module is composed of an input terminal, a fuse, a diode, and an output terminal

In this solar power generation, the inverter converts the direct current produced by the solar panel into the alternating current and supplies it to each customer.

In addition, a monitoring function is provided so that the entire solar power generation system can be determined in the situation room.

In this monitoring system, a group is designated in a solar panel composed of a plurality of solar cells, and a communication unit is provided for each group or each cell, and the abnormality is monitored in the management server through a communicator.

In addition, a flame detection sensor is provided on the connection panel to detect the presence or absence of a fire. That is, there is a flame detection sensor for detecting a fire when there is a risk of fire when an overload is applied to the connection panel due to excessive power generation of the photovoltaic power generation

Among these fire detection devices, there are bimetal type, thermal semiconductor type and thermocouple type. Smoke detectors have both photoelectric and ionic

When a fire occurs in the switchboard, an automatic fire hydrant for suppressing is installed.

In such a situation, when a topic occurs in the connection panel for various reasons, the fire detection sensor detects the fire through the control device and proceeds to extinguish the fire with the fire hydrant.

However, no matter how much digestive juice is injected during the suppression process, it is not suppressed.

The inventors of the present invention have confirmed through experiments that the cause of the suppression failure is that the power generated from the solar panel is dc power and the power is continuously output, so that the spark is continuously generated, There was a problem with fire suppression due to fire. Eventually, the entire inside of the connection box was burned down.

In order to prevent such a problem, a monitoring apparatus for a solar cell panel equipped with a flame sensor, which is registered with Registration No. 10-1298559 on Aug. 14, 2013,

There is provided a solar panel capable of easily detecting the flame of the connection board and capable of promptly detecting and maintaining the abnormality of the solar battery panel. However, if a problem occurs in the connection board, Sparks are continuously generated and fire suppression is impossible (see FIG. 1)

1, and the conventional connection panel (including the full speed plate, etc.) generally detects the cause of the fire by the detection sensor which detects the internal temperature of the connection panel, and the position of the detection sensor is located at the protruding portion of the connection panel .

Therefore, there is a problem that if a fire occurs at a position more than the distance between the detection sensor and the constant (nearest to the detection sensor)

2, and depending on the area and the installation site, the internal temperature of the connection panel sometimes reaches 60 ° C in summer. In this case, there is a problem that the temperature monitoring sensor malfunctions

3, To conclude here,

Prior art techniques for monitoring internal connection fires and suppressing fire by a temperature sensor

It is not useless to apply the technology to the connection board because it is the same as the system which is suppressed after the inside of the connection board is burned down.

Finally, as can be seen from the name of the invention, the connecting panel for the solar panel, and the control method thereof, the power output from the input terminal 210 is transmitted through the circuit And the switch unit 230 outputs the power to the diode 240 and the output terminal 250, if necessary.

As a result, the total amount of electric power output from the input terminal 210 goes through the switch portion, so that an arc is generated at the contact portion of the switch portion 230, and the arc is generated as a spark to burn the entire connection portion.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a fire prevention diagnosis system for continuously monitoring the cause of a fire inside a junction box, By measuring the value

When the measured voltage value is within the predetermined voltage value range, it is judged that the electric and / or electronic elements connected to the line between the input terminal and the output terminal are normally connected to the line, and the bypass switch is maintained in the off state

When the measured voltage value is out of the preset voltage value range, it is judged that the electric and electronic elements connected to the line in the input terminal and the output terminal are abnormally connected to the line

And the A / S is carried out by transmitting data of the abnormality of the line to the manager side in the ecology where the power is outputted to the output terminal via the bypass line by turning on the bypass switch,

If the voltage value of the line of the first and second line sections is unbalanced, it is determined that there is a problem in the line where the voltage exceeding the reference value is generated It is an assignment.

Even if it is within the predetermined set value range, it is judged that there is a problem in the case of inequality, and the management object is determined.

It is another object of the present invention to prevent an arc from being generated by turning on and off a switch in a state where power output from an input terminal is dispersed by a diode and a bypass switch.

The power dissipated in the direction of the diode is dispersed to the bypass line to minimize the heat generated from the diode, so that the power consumed by the heat can be saved and the service life of the component shortened due to heat can be prolonged.

The above-mentioned problems are further clarified in the concrete contents.

Referring to FIG. 2,

A solar panel S1 for generating electric power, an input terminal S2 for inputting electric power from the solar panel S1, a fuse S3 for receiving power output from the input terminal S2, A diode S4 for receiving the power output from the circuit breaker and outputting the power to the output terminal and an output terminal S5 for receiving the power output from the diode S4 and outputting the power to the inverter,

A bypass line 110 for bypassing the power input to the input terminal S2 and outputting to the output terminal S5;

The bypass line 110 is opened and closed in accordance with a control signal from the controller 130

A bypass switch 115;

A voltage sensing line 140 formed on the input terminal S2 and the output terminal S5;

A measuring unit 120 for monitoring a state of a voltage present in the voltage sensing line 140;

And is connected to the measurement unit 120 to determine the state of the voltage sensing line 140

When the measured voltage value is within the predetermined voltage value range, it is judged that the electronic and electric elements connected to the line between the input terminal S2 and the output terminal S5 are normally connected to the contact normal line, (115) is maintained in the off-state

When the measured voltage value is out of the predetermined voltage value range, it is determined that the electronic or electric element is connected to the line between the input terminal S2 and the output terminal S5 in an abnormal (bad contact) line

The bypass switch 115 is turned on to output the power to the output terminal S5 via the bypass line 110. [

In another embodiment

3, a line between the input terminal S2 and the output terminal S5 is divided into a first line section 300 and a second line section 400, A first bypass line 190 bypassing the first bypass line 300 and outputting to the rear end 300 'of the first line interval 300

A second bypass line 191 receiving power output to the rear end 300 'of the first bypass line 190 and bypassing to the output terminal S5,

First and second bypass switches 190 'and 191' for opening and closing the first bypass line 190 and the second bypass line 191 in accordance with a control signal from the controller 192,

The first and second voltage sensing lines 150 and 160 formed at the rear ends A and C of the first line section 300 and the rear ends B and D of the second line section 400,

First and second measuring units 170 and 180 for monitoring a state of resistance existing in the first and second voltage sensing lines 150 and 160,

The state of the first and second voltage sensing lines 150 and 160 is determined by being connected to the first and second measuring units 170 and 180

When the measured voltage value is within the predetermined voltage value range, it is determined that the electrical and / or electronic elements connected to the lines in the first and second line sections 300 and 400 are normally connected to the line, and the first and second bypass switches 190 ' 191 ') < / RTI >

When the measured voltage value of the first and second line sections 300 and 400 is out of the predetermined voltage value range, the electronic electricity abnormally reaches the line out of the range of the first and second line sections 300 and 400 Judged to be connected

The first and second detour switches 190 'and 191' are turned on to output power to the other section input unit or the output terminal S5 via the first and second detour line 190.191.

The present invention provides a fire prevention diagnosis system that continuously monitors the cause of a fire inside a junction box. In the present invention, the impedance (referred to as resistance value) is measured between an input terminal and an output terminal to which power is input from a solar panel

When the measured voltage value is within the predetermined voltage value range, it is judged that the electric and / or electronic elements connected to the line between the input terminal and the output terminal are normally connected to the line, and the bypass switch is maintained in the off state

When the measured voltage value is out of the preset voltage value range, it is judged that the electric and electronic elements connected to the line in the input terminal and the output terminal are abnormally connected to the line

When the bypass switch is turned on and the power is output to the output terminal via the bypass circuit, the resistance value is lowered because the bypass circuit is passed through the bypass circuit, so that the contact defect does not proceed any more. The fire will automatically evolve. In this situation, it is possible to send data of the abnormality of the line to the manager side to enable the A / S to be performed and to use without any interruption of power generation, so that the loss of property due to the failure of the solar power plant and the power generation loss It is possible to prevent both, and also to prevent the fire in advance.

The above-mentioned effects are disclosed in detail in more detail.

FIG. 1 is a schematic view of an entire system of a solar cell panel according to a conventional example,
FIG. 2 is a flow chart of a fire prevention type photovoltaic power generation system through impedance measurement and a bypass circuit of the present invention,
FIG. 3 is a flow chart of another embodiment of the photovoltaic power generation system using the impedance measurement and the bypass circuit of the present invention,
FIG. 4 is a reference diagram showing a state in which an arc is generated as a connection half generated in a research process of the present invention.
FIG. 5 is another flow chart of the fire prevention solar power generation system using the impedance measurement and the bypass circuit of the present invention.

The following will be described with reference to the flowchart of Fig.

An input terminal S2 to which a current is inputted from the solar panel S1; A fuse S3 and a breaker (hereinafter referred to as a breaker) through which the current output from the input terminal S2 passes;

The diode S4 input to the diode via the circuit breaker S3;

In the connection circuit S6 in which the current output from the diode S4 is output to the inverter via the output terminal S5,

Such a technical arrangement is a general conventional connection panel.

The solar panel produces a current by the sunlight and outputs it to the inverter via the input terminal S2, the breaker S3, the diode S4 and the output terminal S5 .

The input terminal S2 can not be connected to a simple electric wire (copper plate or the like) into which a current generated from the solar panel S1 flows. When the electric current output line including the solar panel generates a short circuit or the like And the diode S4 functions as a check valve function for blocking reverse current.

And the output terminal S5 is a copper wire that is connected to the inverter.

The diode S4 is in contact with a heat radiating plate for discharging heat generated from the diode on one side thereof, thereby discharging the heat of the diode to the outside.

Hereinafter, the technical contents invented by the present invention will be described.

A bypass line (110) bypassing the power input to the input terminal (S2) and outputting to the output terminal (S5);

The bypass line 110 is opened and closed in accordance with a control signal from the controller 130

A bypass switch 115;

A voltage sensing line 140 formed on the input terminal S2 and the output terminal S5;

A measuring unit 120 for monitoring a state of a voltage present in the voltage sensing line 140;

And is connected to the measurement unit 120 to determine the state of the voltage sensing line 140

When the measured voltage value is within the predetermined voltage value range, it is judged that the electronic and electric elements connected to the line between the input terminal S2 and the output terminal S5 are normally connected to the contact normal line, (115) is maintained in the off-state

It is determined that the electronic or electric element is abnormally connected to the line between the input terminal (S2) and the output terminal (S5) when the measured voltage value is out of the preset voltage value range,

The bypass switch 115 is turned on to output the power to the output terminal S5 via the bypass line 110. [

An embodiment of such a structure will be described below.

As described above, in the input terminal S2 and the output terminal S5,

A voltage sensing line 140 is newly formed, and a voltage sensing line 120 is formed in the voltage sensing line 140, which is controlled by a control unit.

Therefore, when the measuring unit 120 is within the predetermined voltage value range between the input terminal S2 and the output terminal S5 in the corresponding line 600, the measuring unit 120 is connected between the input terminal S2 and the output terminal S5 It is judged that the electronic or electric device connected to the line of the circuit (for example, a circuit breaker soldered on a line coated on the substrate) is connected to the line with normal (contact normal).

At this time, the controller 130 keeps the bypass switch 115 in the off-state.

However, when the voltage value preset in the corresponding line 600 between the input terminal S2 and the output terminal S5 is out of the preset voltage range, the measuring unit 120 outputs the output terminal S2 and the output It is judged that the electronic or electric element is abnormally connected to the line between the terminals S5 and S5.

At this time, the control unit 130 turns on the bypass switch 115 so that the electric power is outputted to the output terminal S5 via the bypass line 110.

Supplementing the above description, for example, when the circuit breaker soldered to the line 600 is left for a long time, the soldering portion becomes thin or shaky unlike the first.

If left untouched, an arc is generated as shown in Fig.

However, when the thickness is reduced as described above, a resistance is generated in the soldering portion as described above, and the voltage is increased, so that the raised voltage is measured by the measuring unit and the measured value is transmitted to the manager side by data communication.

Once these data values reach the set range, the administrator can send them to the site and perform the A / S.

Turns on the bypass switch 115 through the control unit 130 at the same time of the data communication and outputs the power inputted to the input terminal S2 to the output terminal S5 through the bypass line 110. [

Hereinafter, another embodiment of the present invention will be described.

A line between the input terminal S2 and the output terminal S5 is divided into a first line section 300 and a second line section 400 so as to receive power from the input terminal S2, A first bypass line 190 which is output to the rear end 300 'of the section 300

A second bypass line 191 receiving power output to the rear end 300 'of the first bypass line 190 and bypassing to the output terminal S5,

First and second bypass switches 190 'and 191' for opening and closing the first bypass line 190 and the second bypass line 191 in accordance with a control signal from the controller 192,

The first and second voltage sensing lines 150 and 160 formed at the rear ends A and C of the first line section 300 and the rear ends B and D of the second line section 400,

First and second measuring units 170 and 180 for monitoring a state of resistance existing in the first and second voltage sensing lines 150 and 160,

The state of the first and second voltage sensing lines 150 and 160 is determined by being connected to the first and second measuring units 170 and 180

When the measured voltage value is within the predetermined voltage value range, it is determined that the electrical and / or electronic elements connected to the lines in the first and second line sections 300 and 400 are normally connected to the line, and the first and second bypass switches 190 ' 191 ') < / RTI >

When the measured voltage value of the first and second line sections 300 and 400 is out of the predetermined voltage value range, the electronic electricity is abnormally connected to the line out of the range of the first and second line sections 300 and 400 Judged to be

The bypass switch 191 "in the line 600 out of the set value range of the first and second bypass switches 190 ', 191' is turned on so that the power is passed through the bypass line 190".

The division may further be divided into a plurality.

Hereinafter, embodiments according to the present invention will be described.

The line between the input terminal S2 and the output terminal S5 is divided into the first line section 300 and the second line section 400 as described above.

First and second detour lines 190 and 191 are newly formed as shown in the front and rear ends of the lines, respectively, and the first and second detour lines 190 and 191 are

First and second bypass switches 190 'and 191' are provided.

The first and second bypass switches 190 'and 191' are controlled by the controller 192.

Further, first and second voltage sensing lines 150 and 160 are formed at the front and rear ends of the first line section 300 and the second line section 400, respectively, and the first and second voltage sensing lines 150 and 160 are connected to the first And two measuring units 170 and 180 are installed.

In this state, when the first measuring unit 170 is within the voltage value range preset in the line corresponding to the first line section 300, the first measuring section 170 is connected to the line of the first line section 300 It is judged that the electronic or electric element connected to the line (for example, a circuit breaker solder) is connected to the line in a normal (contact normal) state.

At this time, the controller 192 maintains the first bypass switch 190 'to be in the off-state.

However, when the measuring unit 120 is out of the predetermined voltage value range for the line 600 corresponding to the first line section 300, the electronic and electric elements are abnormally placed in the line between the first line sections 300 (Contact failure) is judged to be connected to the line.

At this time, the controller 192 turns on the first bypass switch 190 'so that the power is outputted to the second line section 191 via the first bypass line 190.

Next, the second line section 191 will be described.

Since the second line section 191 is the same as the first line section 190, a detailed description thereof will be omitted.

If the voltage values present in the lines of the first and second line sections 300 and 400 are unbalanced, it is determined that there is a problem in the line where the voltage exceeding the reference value is generated.

Supplementing the description of the first and second line sections 190 and 191,

The first and second line sections 190 and 191 may compare the voltage values of the first and second line sections 190 and 191 and determine that there is a problem with the connection section if the voltage value is constantly unbalanced even if the preset value is within the preset tolerance range.

The flow chart of FIG. 5 will be described below.

5, the first line section is changed in comparison with FIG.

The modified line is a section between the input terminal S2 and the output terminal S5 in the first line section 300 and the second line section 400 is the same as in Fig.

In addition, the varistors and Zener diodes described later are newly installed. It is preferable that the newly installed varistor and Zener diode are installed in the first and second voltage sensing lines 150 and 160 of FIG.

First, when the voltage value measured by the first measuring unit 170 is within the predetermined voltage value range, the first input terminal S2 and the output terminal S5 (the input terminal and the output terminal line) ) And the first bypass switch (190 ', 191') is maintained in the off-state, while the first bypass switch (190 ', 191'

If any one of the first and second bypass switches 190 'and 191' is selectively bypassed when the voltage measured in the first line section 300 is outside the predetermined voltage value range, .

3, when the measured value of the two sections deviates from the preset voltage value range, the measuring section for measuring the two sections, i.e., the first and second line sections 300, 190 ', and 191', it is possible to determine which line is abnormal.

If a varistor element is provided on the substrate of the present invention, a voltage higher than the rated voltage of the varistor reduces the resistance of the varistor and suppresses a high voltage by flowing to the varistor even if a transient noise flows into the line.

The reason for installing the varistor in this way is that the input pin of the microcomputer (trouble) occurs when the voltage rises due to a high resistance value. It is desirable to attach a varistor or a protective zener diode to protect the input pin.

A large number of large current contact points are generated when the circuit is fabricated, and a plurality of bypass circuits can be constructed for this purpose.

Finally, once again the effects described in the effect are presented here,

When the bypass switch is turned on and the power is output to the output terminal via the bypass circuit, the resistance value is lowered because the bypass circuit is passed through the bypass circuit, so that the contact defect does not proceed any more. The fire will automatically evolve. In this situation, it is possible to transmit the data of the abnormality of the line to the manager side and to enable the A / S to be performed without interruption of the power generation, so that the property loss due to the failure of the power plant and the damage of the power plant (solar panel, It is possible to prevent power generation loss due to power generation interruption.

Supplementing the above description, the detour switch of the present invention has an effect of preventing a disconnection until A / S when a trouble occurs in a line.

As previously mentioned above. It is a very beneficial invention that has the advantage of preventing fire as well as power failure.

Finally, the microprocessor (included in the control section of the present invention) includes an interface for receiving a digital value corresponding to the A / D-converted current and voltage from the power measuring means, a unique identification number, Unique from the interface

An arithmetic unit for storing a digital voltage / current measurement value of an identification number in a storage device, correcting and calculating an amount of electric power, calculating an abnormality when the power value deviates from a predetermined deviation value, And a microprocessor having an apparatus.

The communication unit may include a wireless module for transmitting to an administrator or a user's mobile communication terminal using a WAP (Wireless Application Protocol) when the result of the arithmetic processing of the microprocessor is determined to be abnormal, To the administrator of the remote place or to the user's mobile communication terminal, the alarm number determined in correspondence with the unique number and the abnormal state of the connection module and the measurement data stored in the storage device to the administrator or the user of the remote place

This allows the user to know remotely whether the status of an access panel or access panel is abnormal.

The active operation of the remote monitoring system will now be described briefly. An administrator or a user who wants to perform remote monitoring drives an application program installed in the mobile communication terminal to connect to the microprocessor,

The microprocessor transmits the current or past result extracted by the administrator or the user from the status confirmation request to the administrator or the user's mobile communication terminal.

In the present embodiment, remote monitoring can be performed without a separate device by using a WAP (wireless application protocol) installed in a microprocessor, an administrator, or a user's mobile communication terminal and enabling wireless data communication between the two devices .

The WAP acts as a communication emulator, which converts signals received and demodulated from the other party into meaningful information according to a predetermined protocol, so that the mobile communication terminal can detect an abnormal state of a solar power plant at a remote place It allows you to monitor.

S1; Solar panel S2; Input terminal
S3; Fuse S4; diode
S5; Output terminal
110; Bypass track 115; Bypass switch
120; A measuring unit 130; The control unit
140; Voltage sensing line

Claims (3)

A solar panel S1 for generating electric power, an input terminal S2 for inputting electric power from the solar panel S1, a fuse S3 for receiving power output from the input terminal S2, A diode S4 for receiving the power output from the circuit breaker and outputting the power to the output terminal, an output terminal S5 for receiving the power output from the diode S4 and outputting it to the inverter, In the access panel,

A line between the input terminal S2 and the output terminal S5 is divided into a first line section 300 and a second line section 400 so as to receive power from the input terminal S2, A first bypass line 190 which is output to the rear end 300 'of the line section 300

A second bypass line 191 receiving power output to the rear end 300 'of the first bypass line 190 and bypassing to the output terminal S5,

First and second bypass switches 190 'and 191' for opening and closing the first bypass line 190 and the second bypass line 191 in accordance with a control signal from the controller 192,

The first and second voltage sensing lines 150 and 160 formed at the rear ends A and C of the first line section 300 and the rear ends B and D of the second line section 400,

A Zener diode or a varistor element selectively installed on the first and second voltage sensing lines 150 and 160,

First and second measuring units 170 and 180 for monitoring a state of resistance existing in the first and second voltage sensing lines 150 and 160,
The state of the first and second voltage sensing lines 150 and 160 is determined by being connected to the first and second measuring units 170 and 180

When the measured voltage value is within the predetermined voltage value range, it is determined that the electrical and / or electronic elements connected to the lines in the first and second line sections 300 and 400 are normally connected to the line, and the first and second bypass switches 190 ' 191 ')< / RTI >

When the measured voltage value of the first and second line sections 300 and 400 is out of the predetermined voltage value range, the electronic electricity is abnormally connected to the line out of the range of the first and second line sections 300 and 400 Judged to be
The bypass switch 191 "in the line 600 out of the set value range of the first and second bypass switches 190 'and 191' is turned on to bypass the bypass line 190" And the power is outputted to the output terminal (S5) via the bypass circuit line (110) by turning on the photovoltaic power generation system (15) through the impedance measurement and the bypass circuit Fire protection type photovoltaic power generation system through bypass circuit.

delete The method according to claim 1,
It is determined that there is a problem in the line where the high voltage is generated when the voltage value existing in the line of the first and second line sections 300 and 400 is unbalanced. Photovoltaic system.

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