JP2014068509A - Photovoltaic system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent a firefighter from being electrified even when using a breaking tool to solar modules during firefighting in the event of a building fire.SOLUTION: In the photovoltaic system so configured that a DC/AC inverter 16 in a power conditioner converts DC power generated by solar cell strings 10-1 to 10-n in which a plurality of solar cell modules 12 are connected, to AC power to be supplied to a commercial AC system 18. When receiving a home fire detection signal, a control section 38 switches relays 24 operative in an operating condition of shock prevention circuits 14-1 to 14-n to an inoperative condition, and normally open relay contacts 28, 30 are opened and normally closed relay contacts 32, 34 closed, to connect shock preventing resistors 36 with a predetermined resistance value between output terminals of the solar cell strings 10-1 to 10-n, so that a predetermined safety terminal voltage or less is ensured.

Description

The present invention relates to a photovoltaic power generation system that converts DC power generated by a solar cell module installed on a roof of a building into AC power and supplies the AC power to a load.

  In recent years, the installation of solar power generation systems using solar energy has been expanded, and in particular, the spread to ordinary homes has been rapidly progressing with the nuclear power plant accident in the Great East Japan Earthquake.

  A photovoltaic power generation system converts DC power generated by a solar cell module installed on the roof of a building into AC power by a power conditioner, and supplies power to equipment in the building by cooperating with a commercial power system At the same time, the generated power can be sold to an electric power company.

Here, since the output voltage of a solar cell module alone is low, a unit in which a plurality of solar cell modules are connected in series is referred to as a unit, which is called a solar cell string (solar cell array). One solar power generation system is configured by dividing and arranging in parallel, for example, four systems such as the south surface, north surface, east surface, and west surface of the roof.

JP 2002-238246 A JP 2009-064809 A JP 2011-0447703 A

  With the widespread use of such solar power generation systems in ordinary homes, it is expected that the number of solar power generation systems will also increase in the future when they are installed in buildings that have been hit by fire.

  When a building with a photovoltaic power generation system is hit by a fire, a destruction device may be used for the solar cell module installed on the roof during a fire fighting activity. There is a risk of injury. There have also been reports of cases where firefighters actually got an electric shock, and it is strongly desired to take measures for that in the photovoltaic power generation system.

An object of this invention is to provide the solar power generation system provided with the protection function which does not cause an electric shock accident even if it uses a destruction device for a solar module with the fire of a building.

(Solar power system)
The present invention
A solar cell array that is installed on the roof of the building and receives direct sunlight from a plurality of solar cells connected in series to generate DC power;
Orthogonal conversion means for converting DC power generated by the solar cell array into AC power and supplying it to a load;
In a photovoltaic power generation system equipped with
A fire detection means for detecting a building fire and outputting a fire detection signal;
When a fire detection signal is received from the fire detection means, the output terminal of the solar cell array is disconnected from the orthogonal conversion means side, and a resistance means having a predetermined resistance value is connected between the disconnected output terminals. Electric shock prevention means to make the safety terminal voltage or less,
Is provided.

(Resistor power loss)
The resistance means is a resistor having a rated power corresponding to the DC power supplied by connection between the output terminals of the solar cell array. The resistor is a cement resistor or a wire wound resistor.

(Electric shock prevention means by relay)
Electric shock prevention means
It has a normally open relay contact and a normally closed relay contact to be linked, and the normally open relay contact is inserted and connected to the electric circuit connecting the output terminal of the solar cell array and the input terminal of the orthogonal transformation means, and the normally closed relay contact is A relay inserted and connected to a circuit that connects a resistor between the output terminals of the battery array;
When the relay is operated in a steady operation state, DC power generated by the solar cell array by closing the normally open relay contact is supplied to the orthogonal transformation means, and the resistor is output by opening the normally closed relay contact. When the fire detection signal is received from the fire detection means, the relay is deactivated, the solar cell array is disconnected from the orthogonal conversion means by opening the normally open relay contact, and the resistance is reduced by closing the normally closed relay contact. Control means connected between the output terminals of the solar cell array;
Is provided.

(Separation of positive and negative circuit)
The normally open relay contact of the relay is inserted and connected to each of the positive and negative electric circuits connecting the output terminal of the solar cell array and the input terminal of the orthogonal transformation means.

(Electric shock prevention means by relay and switching means)
Electric shock prevention means
A relay having a normally open relay contact and a normally closed relay contact that are interlocked, the normally open relay contact being inserted and connected to an electric circuit connecting the output terminal of the solar cell array and the input terminal of the orthogonal transformation means,
Switching means in which a resistor is connected in series between the positive and negative circuits on the primary side of the normally open relay contact;
When the relay is operated in the steady operation state, the DC power generated by the solar cell array by closing the normally open relay contact is supplied to the orthogonal transforming means, and the switching means is controlled to be turned off to output the resistance of the solar battery array. When disconnecting from the terminal and receiving a fire detection signal from the fire detection means, the relay is deactivated, the solar cell array is disconnected from the orthogonal conversion means by opening the normally open relay contact, and the switching means is controlled to be turned on to resist Control means for connecting between the output terminals of the solar cell array,
Is provided. Here, the switching means includes a thyristor or a transistor.

(Fire alarm means)
Fire detection means
When a fire is detected, a fire alarm indicating the link source is output and a fire link signal is transmitted wirelessly or by wire, and another fire alarm means transmits a fire link signal transmitted wirelessly or by wire. Fire alarm means to output a fire alarm indicating the link destination when received,
Adapter means for outputting a fire detection signal to an electric shock prevention means when the fire alarm device receives a fire-linked signal transmitted wirelessly or by wire; and
Is provided.

(Automatic fire alarm system)
Fire detection means
An automatic fire alarm facility installed in a warning area in a building, which outputs a fire alarm from a disaster prevention receiver when a fire is detected by a fire detection terminal device, and transmits a fire-linked signal to the outside wirelessly or by wire;
Adapter means for outputting a fire detection signal to an electric shock prevention means when the disaster prevention receiver receives a fire-linked signal transmitted wirelessly or by wire; and
Is provided.

  The solar power generation system of the present invention detects the fire of a building and outputs a fire detection signal. When the fire detection signal is received from the fire detection means, the output terminal of the solar cell array is orthogonally converted by the electric shock prevention means. Since the resistance means having a predetermined resistance value is connected between the disconnected output terminals so as to be equal to or lower than the predetermined safety terminal voltage, even if the solar cell array receives solar energy and generates power By passing a load current close to the short-circuit current at the time of output short-circuit in the VI characteristics (output characteristics) of the solar cell, the voltage between the output terminals (voltage across the resistance means) is suppressed to a safe voltage of 10 volts or less, for example. Even if the fire brigade touches the module electrode etc. using a destructive device to the solar cell module installed on the roof in this state, it flows because the electrode voltage is low. The electric current is small, and it does not lead to an electric shock that can injure firefighters, and it is possible to safely perform firefighting activities without fear of electric shock at high places such as the roof where the solar cell module is installed To do.

Here, the state in which the resistance means is connected between the output terminals of the solar cell array is the case where the VI characteristic (output characteristic) of the solar cell is controlled to an operating point close to the minimum power point at which the power supplied to the load becomes zero. In this way, even if a fire brigade touches a module electrode or the like using a destructive device, there will be no electric shock that could cause injury.

Explanatory drawing showing the photovoltaic power generation system of the present invention installed in a house The block diagram which showed 1st Embodiment of the photovoltaic power generation system by this invention Graph showing the output characteristics of solar cells The block diagram which showed 2nd Embodiment of the solar energy power generation system by this invention. The block diagram which showed 3rd Embodiment of the solar energy power generation system by this invention. Circuit diagram showing an embodiment of an electric shock prevention circuit using a thyristor Circuit diagram showing an embodiment of an electric shock prevention circuit portion using a transistor

[Outline of photovoltaic power generation system]
FIG. 1 is an explanatory view showing a photovoltaic power generation system of the present invention installed in a house. In FIG. 1, a solar power generation system installs a solar cell module 12 on the roof of a house 1, converts solar energy into DC power, and outputs it. The solar cell module 12 is also referred to as a solar cell panel.

  Since the output per solar cell module 12 is small, a plurality of solar cell modules are connected in series to form one group, and this group is a solar cell string. The solar cell strings correspond to the solar cell columns in the claims.

  The power lines from the solar cell strings composed of a plurality of solar cell modules 12 are collected in the connection box 3, and the connection box 3 connects the power lines from the plurality of solar cell strings in parallel to form a power conditioner 4. Sending out.

  The power conditioner 4 has a DC / AC inverter that functions to convert the DC power generated by the solar cell module 12 into AC power that can be used in general electrical equipment, and thus functions as an orthogonal conversion unit. Further, the power conditioner 4 plays a role of matching the voltage, frequency, number of phases, number of lines and the like so that it can be connected to a commercial AC system of an electric power company. Furthermore, the power conditioner 4 performs maximum power point tracking control so that the solar cell module 12 can generate power with the maximum power.

  A monitor device 5 is connected to the power conditioner 4, and the monitor device 5 includes a display unit and an operation unit, and displays an operation state of the photovoltaic power generation system, a failure display, a necessary operation operation, and the like.

  The power line from the power conditioner 4 is connected to the distribution board 6, and the power line from the commercial transformer system 11 of the power company, for example, the pole transformer 11 is connected to the distribution board 6 via the power meter 7. AC power from a solar cell system or a commercial AC system is supplied from the panel 6 to a load such as an electric device installed in the house. In addition, it is possible to sell power by supplying AC power output from the power conditioner 4 to the commercial AC system of the power company through the power meter 7 from the distribution board 6.

  With regard to such a solar power generation system, in the present invention, in the event of a fire, the power generated by the solar cell module 12 is minimized, and a fire brigade member can destroy the solar cell module 12 through a fire fighting activity. For example, the connection box 3 or the power conditioner 4 is provided with an electric shock prevention circuit portion that functions as an electric shock prevention means for reducing the voltage so as not to cause an electric shock even if the battery is used. Since this electric shock prevention circuit unit needs to detect and operate a fire in the house 1, the house 1 includes a wireless interlocking house alarm 8 that functions as a fire detection means and an adapter device 9 that functions as an adapter means. Provided.

  The home alarm 8 is known as a home fire alarm that detects and alerts a fire in a house, etc., operates with a battery power source, and alarms a fire with a sensor unit that detects the temperature or smoke concentration associated with the fire. An alarm unit is integrated, and when a fire is detected based on a temperature or smoke concentration detection signal from the sensor unit, a fire alarm indicating the link source is output from the alarm unit, and the fire link signal is transmitted wirelessly to other housing alarms. The fire alarm sound indicating the interlocking destination is output by the other house alarm device 8.

  The adapter device 9 operates on a battery power supply in the same manner as the home alarm device 8 and receives the fire detection signal as a no-voltage contact signal, for example, when the home alarm device 8 wirelessly transmits a fire-linked signal. Via the power conditioner 4 side to be output and operated.

  In addition, the fire detection means is composed of a wireless interlocking house alarm 8 and an adapter device 9, and a stand-alone house alarm having no interlocking function is installed in the house 1, and is transferred from the house alarm. An electric shock prevention provided on the power conditioner 4 side by connecting the alarm signal line to the monitor device 5 and using the monitor device 9 as a fire detection signal as a fire detection signal when a fire is detected and alarmed You may make it operate | move by outputting to a circuit part.

[First Embodiment]
(Outline of system configuration)
FIG. 2 is a block diagram showing a first embodiment of the photovoltaic power generation system according to the present invention. In FIG. 2, the photovoltaic power generation system of this embodiment includes solar cell strings 10-1 to 10-n that function as solar cell arrays, electric shock prevention circuit units 14-1 to 14-n that function as electric shock prevention means, and backflow. A blocking diode 20, a surge absorber 22, a main switch (breaker) 25, a DC / AC inverter 16 that functions as a cross flow conversion means, a commercial AC system 18, and a control unit 38 are provided.

  Here, the electric shock prevention circuit sections 14-1 to 14-n and the backflow prevention diode 20 are housed in the junction box 3 shown in FIG. 1, and the surge absorber 22, the main switch (breaker) 25, and the DC / AC inverter. 16 is housed in the power conditioner 4 shown in FIG. Further, the commercial AC system 18 corresponds to an AC system in the house that is the output of the distribution board 6 shown in FIG.

  The solar cell strings 10-1 to 10-n and the electric shock prevention circuit units 14-1 to 14-n are hereinafter referred to as the solar cell strings 10 and the electric shock prevention circuit unit 14, respectively.

  The solar cell strings 10-1 to 10-n have a predetermined number of solar cell modules 12 connected in series, and are installed separately on, for example, four sides of the roof of a house, such as east, west, south, and north. In this embodiment, If the solar cell modules 12 constituting the solar cell strings 10-1 to 10-n have the same number, the direct current output from the solar cell strings 10-1 to 10-n is the same as long as the conditions for receiving sunlight are the same. The power is almost the same.

  The backflow prevention diode 20 is also called a blocking diode, and prevents backflow to the lower voltage string even if a voltage difference occurs between the solar cell strings 10-1 to 10-n.

  The power lines drawn from the solar cell strings 10-1 to 10-n are connected in parallel via the backflow prevention diode 20 and further connected to the input of the DC / AC inverter 16 via the main switch 25. A surge absorber 22 is connected to the primary side of the main switch 25, and the lightning surge current received on the solar cell string 10 side is absorbed to protect the ACite / DC inverter 16.

  The DC / AC inverter 16 converts the DC power output from the solar cell string 10 into AC power and is linked to the commercial AC system 18. Further, the DC / AC inverter 16 performs maximum power point tracking control so that the maximum power can be obtained from the solar cell string 10.

(Maximum power point tracking control)
The maximum power point follow-up control by the DC / AC inverter 16 sets the inverter target command value (output current command value) and the target voltage so that the generated power can be obtained most efficiently from the solar cell string 10 with respect to the illuminance that changes depending on the weather. The power generation output voltage and power generation output current of the solar cell string 10 are controlled by setting.

  FIG. 3 is a graph showing the output characteristics of the solar cell, FIG. 3 (A) is a VI characteristic showing the relationship between the output voltage V and the output current I, and FIG. 3 (B) is the generated power P and the output voltage. This is a PV characteristic showing the relationship of V.

  As shown in FIG. 3A, when the output of the solar cell string 10 is opened, the output current I is 0 amperes, so the point a becomes the operating point. The output voltage V at this time is referred to as an open circuit voltage Vc. On the other hand, when the output of the solar cell string 10 is short-circuited, the output voltage V is 0 volts, so the point b is the operating point. The output current I at this time is called a short-circuit current Is.

  When a load resistor is connected to the output terminal of the solar cell string 10, the operating point changes corresponding to the magnitude of the load resistor. If the load resistance is 0 ohm, it is the same as the output short circuit of the solar cell string 14, and the operating point is b point. When the resistance value of the load resistance is gradually increased, the operating point moves from point b to point a through point c.

  Next, referring to the PV characteristics of FIG. 3B, the electric power P extracted from the solar cell string 10 is the product of the output voltage V and the output current I (P = V × I). At point a, V = 0 volts, so 0 watts, and at point b, I = 0 amperes, 0 watts, and the PV characteristics shown in the figure are obtained.

  Here, the point where the rectangular area determined by the product of the voltage V and the current I is maximum, that is, the point where the power P becomes the maximum power Pmax is referred to as the maximum power point c, and the output voltage at the maximum power point c is the maximum power point. The voltage Vp and the output current are referred to as the maximum power point current Ip.

  The DC / AC converter 16 sets an inverter target command value (output current command value) and a target voltage corresponding to the maximum power point c in FIG. 3, and performs control so as to eliminate the deviation between the detected output current and output voltage. The maximum power can be obtained from the solar cell string 10.

(Electric shock prevention circuit)
As shown in FIG. 2, electric shock prevention circuit sections 14-1 to 14-n are provided for the solar cell strings 10-1 to 10-n. The electric shock prevention circuit unit 14 is controlled by a control unit 38 that functions as a control unit. When the fire alarm signal shown in FIG. 1 is detected by the adapter device 9 and the fire detection signal is output by the adapter device 9 when the fire alarm signal is transmitted wirelessly after detecting the fire, the fire detection signal is transmitted via the monitor device 5, for example. The data is received by the control unit 38 provided in the power conditioner 4.

  The control unit 38 that has received the fire detection signal outputs a control signal to the electric shock prevention circuit unit 14, disconnects the output terminal side of the solar cell string 10 from the DC / AC inverter 16, and sets a predetermined value between the output terminals disconnected. An electric shock prevention resistor 36, which is a resistance means having a resistance value, is connected so as to be equal to or lower than a predetermined safety terminal voltage.

  Here, it is known that the dangerous voltage affecting the human body is usually several tens of volts or more, and the voltage below the predetermined safety terminal voltage by the connection of the electric shock prevention resistor 36 is a voltage less than the dangerous voltage. However, it is desirably 20 volts or less, which is not affected even if the human body is wet.

  The electric shock prevention circuit unit 14 includes a relay 24 including two normally-open relay contacts 28 and 30 and normally-closed relay contacts 32 and 34, and the normally-open relay contacts 28 and 30 are connected to the output terminal of the solar cell string 10. In addition to being inserted and connected to an electric circuit connecting the input terminals of the DC / AC inverter 16, the normally closed relay contacts 32 and 34 are inserted and connected to an electric circuit connecting the electric shock prevention resistor 36 between the output terminals of the solar cell strings 10. .

  The control unit 38 operates the relay 24 in a steady operation state where no fire detection signal is received, and the DC power generated by the solar cell string 10 by closing the normally open relay contacts 28 and 30 is supplied to the DC / AC inverter 16. While being supplied, the resistance 36 for preventing electric shock is disconnected from the output terminal of the solar cell string 10 by opening the normally closed relay contacts 32 and 34.

  On the other hand, when the control unit 38 receives a fire detection signal based on the fire detection of the resident alarm 8, the relay 24 is deactivated, and the normally open relay contacts 28 and 30 are opened to connect the solar cell string 10 to the DC / AC inverter. At the same time, the electric shock prevention resistor 36 is connected between the output terminals of the solar cell string 10 by closing the normally closed relay contacts 32 and 34 so as to be equal to or lower than a predetermined safety terminal voltage.

  The operating point when the electric shock prevention resistor 36 is connected between the output terminals of the solar cell strings 10 is the point d in the VI characteristic of FIG. 3A. The point d is called the electric shock prevention point, and this voltage is the electric shock prevention. This is referred to as voltage Vsafe.

  The electric shock prevention point d is an operating point close to the point b when the output is short-circuited, and the electric shock prevention voltage Vsafe is set to be, for example, 1/10 or less of the open voltage Vc at the point a when the output is open.

  If the open circuit voltage Vc corresponding to the nominal maximum output of the solar battery string 14 is 100 volts, for example, the resistance value of the electric shock prevention resistor 36 is determined so that the electric shock prevention voltage Vsafe is 10 volts.

  Further, in the PV characteristics of FIG. 3B, the power corresponding to the electric shock prevention voltage Vsafe is suppressed to a power Psafe that is close to 0 watt when the output is short-circuited, which can be multiplied by the output current Isafe at that time, and low power. . For this reason, it is necessary to use a resistor having a rated wattage equal to or greater than the value of the power Psafe corresponding to the electric shock prevention point d as the electric shock prevention resistor 36, and thus a resistor having a relatively large rated wattage. For example, a cement resistor or a winding resistor is used.

  The relay 24 of the electric shock prevention circuit section 14 is inserted and connected to each of positive and negative electric circuits connecting the normally open relay contacts 28 and 30 of the two circuits, the output terminal of the solar cell string 10 and the input terminal of the DC / AC inverter 16. In this way, the two are completely separated from each other, and even if one or both of them are exposed to a flame caused by a fire and burned out, they do not affect each other.

  In this embodiment, the relay 24 is provided separately for the electric shock prevention circuit units 14-1 to 14-n. However, when a relay with a large number of relay contact circuits is used, a plurality of electric shock prevention circuits are provided. Alternatively, one relay may be assigned.

(Housing fire with a solar power generation system installed)
Control when the house 1 of FIG. 1 in which the photovoltaic power generation system according to the first embodiment of FIG. 2 is installed is hit by a fire is as follows.

  In the unlikely event that a fire occurs in the house 1, the resident alarm 8 installed in the room that became the source of fire detects, for example, the smoke concentration associated with the fire, and if the smoke concentration exceeds a predetermined threshold, it is linked. While outputting the fire alarm sound which shows the origin, the LED mounted in the residential alarm 8 which is an alarm display is lighted, and also a fire interlocking signal is transmitted by radio.

  The fire-linked signal transmitted by the resident alarm 8 that detects and alerts the fire is received by the other resident alarm 8 installed in the house 1 and outputs a fire alarm sound indicating the linked destination and displays an alarm. For example, an LED mounted on a certain house alarm 8 blinks.

  The fire interlocking signal transmitted by the resident alarm 8 that has detected and alarmed the fire is also received by the adapter device 9, and the adapter device 9 outputs a fire detection signal. The fire detection signal is connected to the power condition via the monitor device 5. It is sent to the control unit 38 of FIG.

  During steady operation, the control unit 38 operates by energizing the relay 24 of the electric shock prevention circuit unit 14, closes the normally open relay contacts 28 and 30, and opens the normally closed relay contacts 32 and 34. The DC power output from the string 10 is input to the DC / AC inverter 16 to be converted into AC power, and the electric shock prevention resistor 36 is disconnected from the solar cell string 10.

  In this state, by stopping energization from the control unit 38 that has received the fire detection signal, the relay 24 is switched off, the normally open relay contacts 28 and 30 are opened, the normally closed relay contacts 32 and 34 are closed, The DC power of the battery string 10 is disconnected from the DC / AC inverter 16, the electric shock prevention resistor 36 is connected to the output of the solar cell string 10, and the output terminal voltage is switched to a safe electric shock prevention voltage Vsafe of 20 volts or less, for example.

  In addition, when the fire spreads to the attic of the house 1 and the solar cell strings 10 installed on the roof are also exposed to flames, and the fire is subsequently suppressed by fire fighting activities, The members use water-breaking equipment to break the roof, water is poured from there, and the fire is extinguished. In this case, since the solar cell strings 10 are arranged on the roof, the fire brigade breaks the solar cell strings 10 using a breaker to make a hole in the roof, and pours water into the attic.

  In this case, when a breaker is used for the solar cell string 10, in the conventional solar cell string 10, the output terminal voltage is higher than a dangerous voltage such as 60 to 100 volts corresponding to the open output voltage, for example, When the destruction device touches the solar cell electrode due to the use of the destruction device, an electric shock is caused. In particular, fire brigade members who use destructive equipment are wet with water discharge, are prone to electric shocks, and there is a great danger in fire fighting activities.

  On the other hand, in the photovoltaic power generation system of the present invention, when a fire is detected, the output terminal voltage of the solar cell string 10 is switched to a predetermined safety terminal voltage or less, and the destruction device is used for the solar cell string 10. Even if it comes into contact with electrodes, the voltage is low, so there is no electric shock that affects the human body, and fire fighting activities can be carried out with peace of mind.

  In addition, an electric shock accident when using a destruction device for the solar cell string 10 causes a problem in the daytime fire during which photovoltaic power generation is performed. Electricity is generated in response to light from the solar cell, and electric shock when a destruction device is used for the solar cell string 10 is a problem even at nighttime fire, but the operation of the electric shock prevention circuit unit 14 of this embodiment when a fire is detected is detected. Therefore, it is possible to reliably prevent electric shock accidents of firefighters.

[Second Embodiment]
FIG. 4 is a block diagram showing a second embodiment of the photovoltaic power generation system according to the present invention, in which a DC / DC converter is arranged between the solar cell strings and the D / A inverter so as to make the DC output voltage uniform. It is characterized by that.

  In FIG. 4, the photovoltaic power generation system of the present embodiment includes solar cell strings 10-1 to 10-n, an electric shock prevention circuit unit 14-1 to 14-n, a main switch (breaker) 25, and a cross flow conversion unit. Although the functioning DC / AC inverter 16, the commercial AC system 18, and the control unit 38 are the same as those in the first embodiment of FIG. 2, the DC / AC inverters 14-1 to 14-n are followed by the DC / DC. The difference is that DC converters 42-1 to 42-n are provided, their secondary sides are connected in parallel, and connected to the input of the DC / AC inverter 16 via the main switch 25. The surge absorber 22 is connected to the primary side of the DC / DC converters 42-1 to 42-n.

  The DC / DC converters 42-1 to 42-n assume that the voltages output from the solar cell strings 10-1 to 10-n are different from each other, and after converting this to a predetermined voltage, the DC / AC inverter 16 To enter.

  For example, when four systems of solar cell strings 10-1 to 10-4 are installed separately on four sides of the roof, east, west, north, and south, the arrangement area of all four surfaces is not the same, and the number of solar cell modules 12 is different. As a result, the output characteristics are not the same. Even if the number of the solar cell modules 12 is the same, the output characteristics are not the same because of the difference in the amount of solar radiation on the roof surface. For this reason, as shown in FIG. 2, when the outputs of the solar cell strings 10-1 to 10-n are connected in parallel and inputted to the DC / AC inverter 16, they have different output characteristics, so that they deviate from the maximum power point. There will be solar cell strings that generate electricity at the operating point.

  On the other hand, in this embodiment, solar cell strings 10-1 to 10-n are provided with DC / DC converters 42-1 to 42-n independently and connected to each other. Maximum power point tracking control is performed so that 10-1 to 10-n can generate the maximum power.

  The electric shock prevention circuit units 14-1 to 14-n provided between the solar cell strings 10-1 to 10-n and the DC / DC converters 42-1 to 42-n are the same as the embodiment of FIG. When the control unit 38 receives a fire detection signal, the control unit 38 stops energization of the relay 24 and switches it to non-operation. The control unit 38 opens the normally open relay contacts 28 and 30 and closes the normally closed relay contacts 32 and 34. -1 to 10-n are disconnected from the DC power from the DC / DC inverters 42-1 to 42-n, and the electric shock prevention resistor 36 is connected to the output of the solar cell strings 10-1 to 10-n, and the output terminal voltage Is switched to a safe electric shock prevention voltage vssafe of, for example, 20 volts or less.

  In the present embodiment, the electric shock prevention circuit units 14-1 to 14-n, the surge absorber 22, the DC / DC converters 42-1 to 42-n, the main switch (breaker) 25, the DC / AC inverter 16 and the control part 38 are provided in the power conditioner 4 shown in FIG.

[Third Embodiment]
FIG. 5 is a block diagram showing a third embodiment of the photovoltaic power generation system according to the present invention, in which a DC / DC converter for boosting is arranged on a solar cell string having a smaller number of standard solar cell modules, and a DC output voltage is provided. It is characterized by having arranged.

  In FIG. 5, the solar power generation system of the present embodiment takes two solar cell strings 10-1 and 10-2 as an example, and the solar cell modules 12 of the solar cell strings 10-1 have a predetermined standard number. However, the solar cell modules 12 of the solar cell strings 10-2 are less than the standard number.

  For this reason, even if the solar cell strings 10-1 and 10-2 are connected in parallel and connected to the DC / AC inverter 16, the maximum power point control is performed based on the synthesized PV characteristics because the operating points at which the maximum power is reached are different. Even if it performs, the electric power which added each maximum electric power cannot be output.

  Therefore, by providing a DC / DC converter 42 on the side of the solar cell string 10-2 on which less than the standard number of solar cell modules 12 is provided, and adjusting the output voltage of the solar cell string 10-2 to the solar cell string 10-1, the maximum The maximum power point control is performed with the same operating point as the power, and the generated power of the solar cell strings 10-1 and 10-2 is extracted to the maximum effective.

  Here, the standard number of solar cell strings 10-1 side includes the electric shock prevention circuit unit 14-1 and the backflow prevention diode 20 as in the embodiment of FIG. As in the embodiment of FIG. 3, the second side includes an electric shock prevention circuit unit 14-2, a surge absorber 22, and a DC / DC inverter 42, and then DC / AC is connected via the main switch 25 after the two are connected in parallel. An input connection is made to the inverter 16, and a surge absorber 22 is connected to the primary side of the main switch 25.

  The electric shock prevention circuit units 14-1 and 14-2 provided subsequent to the solar cell strings 10-1 and 10-2 are the same as those in the embodiment of FIG. 2, and the control unit 38 receives the fire detection signal. The energization of the relay 24 is stopped and switched to inactive, the normally open relay contacts 28 and 30 are opened, the normally closed relay contacts 32 and 34 are closed, and the DC power of the solar cell string 10 is disconnected from the DC / AC inverter 16. At the same time, the electric shock prevention resistor 36 is connected to the output of the solar cell string 10, and the output terminal voltage is switched to a safe electric shock prevention voltage vssafe, for example, 20 volts or less.

[Electric shock prevention circuit using switching elements]
FIG. 6 is a circuit diagram showing an embodiment of an electric shock prevention circuit unit using a thyristor as a switching element. In FIG. 6, the electric shock prevention circuit unit 14 inserts and connects the normally open relay contacts 28 and 30 of the relay 24 to the electric circuit from the solar cell string 10, and between the primary side electric circuits of the normally open relay contacts 28 and 30. The electric shock prevention resistor 36 and the thyristor 44 are connected in series. A gate control line is connected to the gate of the thyristor 44 from the same control unit as shown in FIG.

  During steady operation, the relay 24 is in an activated state by energization from the control unit 38, closes the normally open relay contacts 28 and 30, and outputs DC power from solar power generation of the solar cell string 10 to the DC / AC converter. Further, the thyristor 44 is off, and the electric shock prevention resistor 36 is disconnected.

  When a fire is detected, the energization from the control unit is stopped, the relay 24 is deactivated, the normally open relay contacts 28 and 30 are opened, the connection with the DC / AC inverter is disconnected, and at the same time the gate from the control unit 38 The control signal (pulse control signal) E1 is output, the thyristor 44 is turned on, the electric shock prevention resistor 36 is connected between the output terminals of the solar cell strings 10, and the inter-terminal voltage is set to a predetermined safety terminal voltage or less.

  FIG. 7 is a circuit diagram showing an embodiment of an electric shock prevention circuit unit using a transistor as a switching element. In FIG. 7, the electric shock prevention circuit unit 14 inserts and connects the normally open relay contacts 28 and 30 of the relay 24 to the electric circuit from the solar cell string 10, and between the primary side electric circuits of the normally open relay contacts 28 and 30. The electric shock prevention resistor 36 is connected by a transistor 46. A control line from the same control unit as shown in FIG. 2 is connected to the base of the transistor 46.

  During steady operation, the relay 24 is in an activated state by energization from the control unit 38, closes the normally open relay contacts 28 and 30, and outputs DC power from the solar power generation of the solar cell string 10 to the DC / AC converter. Further, the transistor 46 is off, and the electric shock prevention resistor 36 is disconnected.

  When a fire is detected, the energization from the control unit 38 is stopped, the relay 24 is deactivated, the normally open relay contacts 28 and 30 are opened, and the connection with the DC / AC inverter is disconnected. The signal E2 is output, the transistor 46 is turned on, the electric shock prevention resistor 36 is connected between the output terminals of the solar cell strings 10, and the inter-terminal voltage is set to a predetermined safety terminal voltage or less.

[Modification of the present invention]
Although the above embodiment takes a solar power generation system installed in a general house as an example, it can also be applied to a large scale solar power generation system installed in a public facility or factory. In this case as well, an electric shock prevention circuit unit is provided for each solar cell string. The operation of the electric shock prevention circuit unit based on the fire detection is controlled to be performed on the solar cell string in the area where the fire is detected.

  Moreover, although said embodiment has provided the electric shock prevention circuit part for every solar cell string, you may provide an electric shock prevention circuit part for every solar cell module provided in the solar cell string. In this case, since the generated power at the operating point of the solar cell module when the electric shock prevention resistor is connected is small, a small and inexpensive resistor with a small rated wattage can be used as the electric shock prevention resistor.

  Further, in the above embodiment, the fire detection means is exemplified by the wireless interlocking house alarm and the adapter device, but the fire detection signal of the automatic fire alarm facility is used instead of the house alarm. You may do it. The fire detection means in this case is installed in a warning area in the building, and outputs a fire alarm from the disaster prevention receiver when a fire is detected by a fire detection terminal device (fire detector, push button notification device, sprinkler equipment). In addition, an automatic fire alarm system that wirelessly or wiredly transmits a fire-linked signal to the outside, and an adapter device that outputs a fire detection signal to the electric shock prevention circuit when a disaster prevention receiver receives a fire-linked signal transmitted wirelessly or by wire Configure.

The present invention is not limited to the above-described embodiments, includes appropriate modifications that do not impair the objects and advantages thereof, and is not limited by the numerical values shown in the above-described embodiments.

1: Housing 3: Junction box 4: Power conditioner 5: Monitor device 6: Distribution board 7: Power meter 8: House alarm 9: Adapter device 10-1 to 10-n: Solar cell string 12: Solar cell module 14-1 to 14-n: Electric shock protection circuit 16: DC / AC inverter 18: Commercial power system 20: Backflow prevention diode 24: Relay 22: Surge absorber 24: Relay 25: Main switch 28, 30: Normally open relay contact 32, 34: Normally closed relay contact 36: Electric shock prevention resistor 38: Control units 42, 42-1 to 42-n: DC / DC converter 44: Thyristor 46: Transistor

Claims (9)

A solar cell array that is installed on the roof of the building and receives direct sunlight from a plurality of solar cells connected in series to generate DC power;
Cross current conversion means for converting DC power generated by the solar cell array into AC power and supplying it to a load;
In a photovoltaic power generation system equipped with
Fire detection means for detecting a fire in the building and outputting a fire detection signal;
When a fire detection signal is received from the fire detection means, the output terminal of the solar cell array is disconnected from the cross flow conversion means side, and a resistance means having a predetermined resistance value is provided between the output terminals thus disconnected. Electric shock prevention means for connecting to a predetermined safety terminal voltage or less,
A solar power generation system characterized by providing
2. The photovoltaic power generation system according to claim 1, wherein the resistance means is a resistor having a rated power corresponding to direct current power supplied by connection between output terminals of the solar cell array. Solar power system.
2. The photovoltaic power generation system according to claim 1, wherein the resistor is a cement resistor or a winding resistor.
In the solar power generation system according to claim 1,
The electric shock prevention means includes
There are a normally open relay contact and a normally closed relay contact to be linked, and the normally open relay contact is inserted and connected to an electric circuit connecting the output terminal of the solar cell array and the input terminal of the orthogonal transformation means, and the normally closed relay A relay in which a contact is inserted and connected to an electric circuit connecting the resistor between the output terminals of the solar cell array;
The relay is operated in a steady operation state, and the DC power generated by the solar cell array by closing the normally open relay contact is supplied to the orthogonal transformation means, and the resistance is reduced by opening the normally closed relay contact. When disconnecting from the output terminal of the solar cell array and receiving a fire detection signal from the fire detection means, the relay is deactivated and the solar cell array is disconnected from the orthogonal conversion means by opening the normally open relay contact. Both control means for connecting the resistor between the output terminals of the solar cell array by closing the normally closed relay contact,
A photovoltaic power generation system characterized by comprising:
5. The photovoltaic power generation system according to claim 4, wherein the normally open relay contact of the relay is inserted and connected to each of positive and negative electric circuits connecting the output terminal of the solar cell array and the input terminal of the orthogonal transformation means. A solar power generation system.
In the solar power generation system according to claim 1,
The electric shock prevention means includes
A relay having a normally open relay contact and a normally closed relay contact to be linked, the normally open relay contact being inserted and connected to an electric circuit connecting the output terminal of the solar cell array and the input terminal of the orthogonal transformation means;
Switching means in which the resistor is connected in series between positive and negative electric circuits on the primary side of the normally open relay contact;
The relay is operated in a steady operation state, and the DC power generated by the solar cell array by closing the normally open relay contact is supplied to the orthogonal transforming means, and the switching means is controlled to turn off the resistance. Is disconnected from the output terminal of the solar cell array, and when a fire detection signal is received from the fire detection means, the relay is deactivated and the solar cell array is disconnected from the orthogonal conversion means by opening the normally open relay contact. Control means for controlling the switching means to be turned on and connecting the resistor between output terminals of the solar cell array,
A photovoltaic power generation system characterized by comprising:
7. The photovoltaic power generation system according to claim 6, wherein the switching means includes a thyristor or a transistor.
The solar power generation system according to claim 1, wherein the fire detection means includes:
Fire interlock signal that is installed in the warning area of the building and outputs a fire alarm indicating the interlock source when a fire is detected, and transmits a fire interlock signal wirelessly or by wire, and other fire alarm means transmit wirelessly or by wire Fire alarm means that outputs a fire alarm indicating the link destination when receiving
Adapter means for outputting a fire detection signal to the electric shock prevention means when the fire alarm device receives a fire-linked signal transmitted wirelessly or by wire; and
A photovoltaic power generation system characterized by comprising:
The solar power generation system according to claim 1, wherein the fire detection means includes:
An automatic fire alarm facility installed in a warning area in the building, which outputs a fire alarm from a disaster prevention receiver when a fire is detected by a fire detection terminal device and wirelessly or wire-transmits a fire-linked signal to the outside;
Adapter means for outputting a fire detection signal to the electric shock prevention means when the disaster prevention receiver receives the fire-linked signal transmitted wirelessly or by wire,
A photovoltaic power generation system characterized by comprising:

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