JP2015139324A - Power Conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power conditioner capable of preventing breakage and failure of an internal semiconductor element when an improper connection occurs in installation work of a power generation system using an external DC power supply.SOLUTION: A power conditioner comprises an input terminal unit 10, a converter 11, and a current fuse 24 inserted in series between the input terminal unit 10 and the converter 11. The converter 11 connects an anode terminal of a first diode 11c to a connecting point between a reactor 11b and a switching element 11a, connects a cathode terminal of a second diode 11d to a connecting point between the reactor 11b and the switching element 11a, and connects the second diode 11d and the switch element 11a in parallel. The switch element 11a is a wide gap semiconductor element, and the second diode 11d is a semiconductor element made of silicon.

Description

  The present invention relates to a power conditioner used in a power generation system using an external DC power supply.

  Conventionally, there is a solar power generation system as a power generation system using an external DC power source such as a solar cell or a fuel cell. In a solar power generation system, for example, dozens of solar cell modules are arranged in series on the rooftop of a building such as a roof of a house, and the generated power (DC power) is converted into AC power by a power conditioner. Yes. A solar power generation system can supply alternating current power to electrical equipment in a house, and when surplus power is generated, it can reversely flow (sell power to a power company) to a system power supply.

  When installing a solar power generation system, wiring between the output line of the solar cell module laid on the roof and the DC input terminal of the power conditioner, and wiring between the system power supply and the AC output terminal of the power conditioner Construction is required. Here, if wiring is mistaken on the power conditioner side during wiring work, the power conditioner may be damaged or broken. For example, when wiring on the system power supply side that is alternating current is connected to the DC input terminal section, or when the polarity of the wiring on the DC input terminal section and solar cell module side is reversed, it is standard for the elements in the power conditioner Overcurrent exceeding the value may be applied, leading to damage.

  In order to solve such a problem, in Patent Document 1 below, a diode and a semiconductor switch driven by a semiconductor switch driving circuit are inserted in series on the negative electrode side of the positive and negative DC buses, and a reverse voltage is applied. In this state, a technique for turning off the semiconductor switch drive circuit by the semiconductor switch off circuit is disclosed.

International Publication No. 2007/110913

  However, according to the above-mentioned conventional technology, in order to prevent damage or failure of the elements in the power conditioner against erroneous connection during installation work of the photovoltaic power generation system, a diode that blocks reverse voltage is prevented. In addition, a semiconductor switch, a semiconductor switch driving circuit for driving the semiconductor switch, and a semiconductor switch off circuit for controlling the semiconductor switch driving circuit to be turned off when an abnormality occurs are required. For this reason, there is a problem that a protection circuit to be added becomes complicated and increases the cost of the power conditioner. In addition, since the switching means is inserted in the DC input circuit, the current flowing through the DC input causes a power loss by passing through the switching means, causing a power conversion loss of the power conditioner. was there.

  The present invention has been made in view of the above, and is a power conditioner capable of preventing damage and failure of an internal semiconductor element when an erroneous connection occurs in installation work of a power generation system using an external DC power supply. The purpose is to obtain.

  In order to solve the above-described problems and achieve the object, the present invention provides an input terminal portion in which cables connected to a positive output terminal and a negative output terminal of an external DC power supply are detachably connected to corresponding terminals, respectively. A converter that converts output DC power of the external DC power source input from the input terminal unit into DC power of another voltage value, an inverter that converts output DC power of the converter into AC power, and the input terminal unit And a current fuse inserted in series between the converter and the converter, wherein the converter connects one end of the reactor and one end of the switch element, and a first connection point between the reactor and the switch element. An anode terminal of a diode is connected, DC power is input between the other end of the reactor and the other end of the switch element, and the first diode A step-up circuit configuration for outputting electric power from between the cathode terminal of the first switch element and the other end of the switch element, a cathode terminal of a second diode is connected to the connection point of the reactor and the switch element, A second diode and the switch element are connected in parallel, the switch element is a wide gap semiconductor element, and the second diode is a silicon semiconductor element.

  Advantageous Effects of Invention According to the present invention, there is an effect that damage or failure of an internal semiconductor element can be prevented when an erroneous connection occurs during installation work of a power generation system using an external DC power supply.

FIG. 1 is a block diagram illustrating a main configuration of a solar power generation system in which the power conditioner according to the first embodiment is used. FIG. 2 is a block diagram illustrating a main configuration of the power conditioner according to the first embodiment. FIG. 3 is a block diagram illustrating a main configuration of the power conditioner according to the second embodiment.

  Embodiments of a power conditioner according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment 1 FIG.
FIG. 1 is a block diagram illustrating a main configuration of a photovoltaic power generation system in which the power conditioner according to the present embodiment is used. FIG. 2 is a block diagram showing a main configuration of the power conditioner according to the present embodiment.

  First, a solar power generation system will be briefly described with reference to FIG. In FIG. 1, the photovoltaic power generation system includes a solar cell module 1, a connection box 2, a power conditioner 3, and a distribution board 4, and a load 5 and an AC power system 6 are each provided in the distribution board 4. It is the structure connected to the power conditioner 3 via this.

  The solar cell module 1 is obtained by connecting a large number of solar cells in series and parallel to obtain a predetermined power generation output. In the case of a house, a predetermined number of solar cell modules 1 are arranged on the roof of the house. The connection box 2, the power conditioner 3, and the distribution board 4 are respectively arranged at predetermined positions such as a house wall and a house.

  In the solar power generation system, the connection box 2 collects a large number of DC power generated in parallel by the large number of solar cell modules 1 into one predetermined value of generated power and outputs the power to the power conditioner 3. The power conditioner 3 converts the input DC power into AC power. The power conditioner 3 outputs AC power and supplies it to the load 5 and the AC power system 6 via the distribution board 4.

  The load 5 is a home appliance such as a lighting fixture, a refrigerator, a washing machine, or a vacuum cleaner, or an external appliance such as a motor. In the photovoltaic power generation system, when surplus power cannot be consumed by the load 5 and surplus power is generated, the surplus power is reversed to the AC power system 6.

  Next, installation work for the solar power generation system in the house will be described. First, the required number of solar cell modules 1 are installed on the roof, and the tip of each output cable is connected to the input section of the junction box 2 installed under the house eaves or in the house. The connection box 2 has a current collecting function for outputting a plurality of inputs as one output. Since the output part of the connection box 2 is constituted by a positive electrode side output terminal and a negative electrode side output terminal, one end of the pair cable between the positive electrode side and the negative electrode side is connected to the output part of the connection box 2. Then, the other end of the paired cable is drawn into the house where the power conditioner 3 is arranged and connected to the input portion of the power conditioner 3.

  In this connection work, the input part of the power conditioner 3 is composed of a positive terminal (+) and a negative terminal (-), so that the other end of the cable that has been pulled in is not mistaken in polarity. It is necessary to connect to the input part of the inverter 3.

  Moreover, the output end of the power conditioner 3 is connected to the distribution board 4 installed in the house. In the distribution board 4, the AC power system 6 is connected by a cable, and a breaker for connecting the output end of the power conditioner 3 to the AC power system 6 is connected by a cable. Alternating current flows through these cables.

  In the connection work, it is necessary not to connect the paired cable on the side of the connection box 2 to the input part of the power conditioner 3 and to connect the cable connecting the distribution board 4 to the AC power system 6 by mistake.

  In the present embodiment, in the installation work of the photovoltaic power generation system, when an erroneous connection in which AC power is applied to the input terminal portion of the power conditioner 3 occurs, the power conditioner 3 blows the current fuse, and the semiconductor The protection function that prevents the destruction of the element and the occurrence of the failure, and notifies the erroneous connection state to be surely restored can be realized with a simple and inexpensive configuration. This will be specifically described with reference to FIG. The general configuration and operation of the power conditioner 3 are well known, so the description thereof is omitted. Here, “the misconnection occurred in the installation work” which is a part related to the present embodiment. In this case, the description will focus on the protection function that prevents the destruction or failure of the semiconductor element and notifies the erroneous connection state so that the semiconductor element can be reliably repaired.

  In FIG. 2, the power conditioner 3 includes an input terminal unit 10, a converter 11, an inverter 12, an output filter 13, an interconnection switch 14, an AC switch 15, an output terminal unit 16, and control means. As a control circuit 17 and a notification means 18.

  The DC output power of the solar cell module 1 is input to the input terminal unit 10 through a connection box 2 (not shown). The converter 11 has a DC (Direct Current) / DC conversion function for converting DC power applied to the input terminal unit 10 into DC power of another voltage value. The inverter 12 includes a semiconductor switching element such as an FET (Field Effect Transistor) and an IGBT (Insulated Gate Bipolar Transistor) and diodes 12b, 12c, 12d, and 12e, and a DC input from the converter 11 by their switching operation. Convert power to AC power. The output filter 13 is composed of a combination of a reactor and a capacitor, and shapes the pulsed AC waveform output from the inverter 12 into a sinusoidal AC waveform.

  The power converter 3 of the power conditioner 3 is formed by the converter 11, the inverter 12 and the output filter 13 as a whole, and the converted output output from the output filter 13 is connected via the interconnection switch 14 and the AC switch 15. It is output to the output terminal unit 16. The AC power system 6 is connected to the output terminal portion 16 in the illustrated example.

  Although the illustration of the control system of the control circuit 17 is omitted in FIG. 2, the control circuit 17 performs the DC / DC conversion operation by the on / off control of the switch element 11 a of the converter 11 and the PWM in the inverter 12 by program control. A DC / AC (Alternating Current) conversion operation by generating a switching operation command by (Pulse Width Modulation) control, and switching control of the interconnection switch 14 and the AC switch 15 are performed. Note that the AC switch 15 opens the connection with the AC power system 6 to open the inverter 12 from the AC power system 6 when the AC power system 6 has a power failure, for example, so that the operation can be shifted to the independent operation. It is provided for this purpose.

  The operation section (not shown) of the power conditioner 3 is provided with an operation / stop switch for starting and stopping the power conditioner 3 and a changeover switch for the interconnection operation mode / independent operation mode. 17 controls the operation of the power conditioner 3 according to the contents of the operation.

  Although not shown, a sensor circuit for measuring the output voltage and output current from the output terminal unit 16 is provided, and the control circuit 17 calculates the AC output power value based on the measured value from the sensor circuit, The AC output power value is integrated to determine the AC output power amount and stored in the memory.

  The notification means 18 includes both a display and a buzzer. The control circuit 17 displays operation data such as the operation state of the power conditioner 3, the calculated AC output power value, and the AC output power amount stored in the memory on the display. Further, when the normal operation cannot be performed, the control circuit 17 can make an emergency stop and sound a buzzer to notify.

  In the above general configuration, “a protective function that prevents the destruction and failure of semiconductor elements when a misconnection occurs in the installation work of the photovoltaic power generation system, and notifies the misconnection status and reliably restores it” As shown in FIG. 2, the positive terminal (+) of the input terminal unit 10 and the corresponding input terminal of the converter 11 are connected via a current fuse 24 as a configuration for realizing the above.

  In the converter 11, the first diode 11c is connected so that the connection point between the reactor 11b and the switch element 11a becomes the anode. The first diode 11c is a wide gap semiconductor element such as a SiC Schottky barrier diode.

  In the converter 11, the second diode 11d is connected in parallel to the switch element 11a so that the connection point between the reactor 11b and the switch element 11a is a cathode. The second diode 11d is a silicon semiconductor element.

  In the converter 11, a first voltage sensor 22 that measures a voltage applied between the positive terminal (+) and the negative terminal (−) of the input terminal unit 10, and an input from the converter 11 to the inverter 12. And a second voltage sensor 23 that measures the voltage of the DC power (bus voltage). In addition, based on the measured values of the first voltage sensor 22 and the second voltage sensor 23, the control circuit 17 is notified of the function for starting and not starting the converter 11 and the inverter 12, and the notification means 18. The function to be made is added.

  In the following, a description will be given of “a protective function that prevents the destruction and failure of a semiconductor element when an erroneous connection occurs in the installation work of the photovoltaic power generation system, and notifies the erroneous connection state so that it can be reliably repaired”.

  First, a case will be described in which a cable connected to the AC power system 6 from the distribution board 4 is mistakenly connected to the input terminal portion 10 of the power conditioner 3 without connecting the paired cable on the connection box 2 side. At this stage, the operating power supply of the power conditioner 3 is off.

  When the power of the power conditioner 3 is off, the switch element 11a of the converter 11 is off. When the power of the AC power system 6 is supplied with a positive polarity at the positive terminal (+) of the input terminal unit 10, the power conditioner 3 has the positive terminal of the input terminal unit 10 from the AC power system 6. (+), The current fuse 24, the reactor 11b of the converter 11, the first diode 11c of the converter 11, the bus capacitor 12a of the inverter 12 and the path leading to the negative terminal (−) of the input terminal unit 10 is excessive. Current flows. By setting the overcurrent blowing characteristic of the current fuse 24 to be less than the forward overcurrent allowable characteristic of the first diode 11c, the current fuse 24 is blown before the first diode 11c breaks down, and the converter 11 is switched to AC. The product can be protected by disconnecting from the power system 6.

  On the other hand, when the power of the AC power system 6 is supplied with a polarity in which the positive terminal (+) of the input terminal unit 10 is negative, the power conditioner 3 has the negative electrode of the input terminal unit 10 from the AC power system 6. Excessive current flows through the side terminal (−), the second diode 11 d of the converter 11, the reactor 11 b of the converter 11, and the current fuse 24 to the positive terminal (+) of the input terminal unit 10. By setting the overcurrent blowing characteristic of the current fuse 24 to be less than the forward overcurrent allowable characteristic of the second diode 11d, the current fuse 24 is blown before the second diode 11d breaks down, and the converter 11 is switched to AC. The product can be protected by disconnecting from the power system 6.

  Here, in general, a parasitic diode of a semiconductor element such as a SiC MOS-FET has a large voltage drop characteristic with respect to a forward voltage drop of a silicon diode. Therefore, the excessive current mainly flows through the second diode 11d and hardly flows through the switch element 11a formed of a wide gap semiconductor element such as a SiC MOS-FET. Therefore, the failure of the switch element 11a can be avoided. The switch element 11a is not limited to a wide gap semiconductor element, and may be composed of a silicon semiconductor element in relation to the characteristics of the second diode 11d.

  As described above, even when the voltage of the AC power system 6 is applied to the input terminal portion 10 of the power conditioner 3 without noticing the erroneous connection, the current fuse 24 is blown and the constituent elements of the converter 11 fail. Never do. The AC voltage applied to the input terminal unit 10 is detected and measured by the first voltage sensor 22, and the information is input to the control circuit 17. At the same time, the charging voltage of the bus capacitor 12 a is detected and measured by the second voltage sensor 23, and the information is input to the control circuit 17.

  Since the detection voltage of the first voltage sensor 22 is an AC signal, the control circuit 17 can recognize an erroneous connection such as an AC connection based on the detected and measured voltage information. As a result, the control circuit 17 can prevent the converter 11 and the inverter 12 from starting up. Therefore, destruction / failure of the semiconductor element can be prevented.

  In addition, the control circuit 17 displays and outputs an abnormality due to erroneous connection such as AC connection in parallel as an error message on the display unit of the notification unit 18, sounds a buzzer of the notification unit 18, issues an alarm, and notifies the operator. . In this case, the error message on the display unit and the sound of the buzzer indicate what kind of misconnection has occurred. In this example, it is possible to know that an incorrect connection called AC connection has occurred. Can quickly and reliably eliminate erroneous connections.

  Next, the case where the paired cable on the connection box 2 side is connected to the input terminal portion 10 of the power conditioner 3 but the polarity is reversed will be described. At this stage, the operating power supply of the power conditioner 3 is off.

  When the power of the power conditioner 3 is off, the switch element 11a of the converter 11 is off. In this case, the negative terminal (−) of the input terminal 10 from the connection box 2, the second diode 11 d of the converter 11, the reactor 11 b of the converter 11, and the current fuse 24, the positive terminal ( Current flows along the path leading to +). Since there is almost no voltage drop in this path, a short-circuit current flows from the solar cell module 1, but since this current is a constant current proportional to the intensity of sunlight incident on the solar cell module 1, the current fuse 24. The product can be protected by selecting the current fuse 24 and the second diode 11d so as not to exceed the forward current allowable characteristic of the second diode 11d.

  The reverse polarity DC voltage applied to the input terminal unit 10 is detected and measured by the first voltage sensor 22, and the information is input to the control circuit 17. Since the control circuit 17 can recognize the erroneous connection of the reverse polarity connection, the converter 11 and the inverter 12 are not activated.

  In addition, the control circuit 17 displays and outputs an abnormality due to the erroneous connection such as reverse polarity connection in parallel as an error message on the display unit of the notification unit 18, sounds a buzzer of the notification unit 18, issues an alarm, and notifies the operator. To do. In this case, the error message of the display unit and the sound of the buzzer indicate what kind of misconnection has occurred. In this example, it is possible to know that a misconnection of reverse polarity has occurred. The person can quickly and surely eliminate the erroneous connection.

  Next, a case where the installation work is correctly performed will be described. When the paired cable on the connection box 2 side is correctly connected to the input terminal portion 10 of the power conditioner 3, the switch element 11a of the converter 11 is in an off state.

  When the operation power supply of the power conditioner 3 is turned on, the first voltage sensor 22 detects and measures the magnitude and polarity of the DC voltage applied to the input terminal unit 10 and gives the measurement result to the control circuit 17. At the same time, the second voltage sensor 23 detects and measures the charging voltage of the bus capacitor 12 a that is the input voltage of the inverter 12, and gives the measurement result to the control circuit 17.

  Since the voltage detected and measured by the first voltage sensor 22 is direct current and positive, the control circuit 17 next uses the voltage value detected and measured by the first voltage sensor 22 and the second voltage sensor 23. Compare the detected and measured voltage value.

  Here, the potential difference between the converter input voltage detected and measured by the first voltage sensor 22 and the inverter input voltage detected and measured by the second voltage sensor 23 is a voltage drop in the path of the reactor 11b and the first diode 11c. Corresponds to minutes.

  Further, when the voltage at the input terminal unit 10 is lowered after the bus capacitor 12a is once charged with a high voltage, the converter input voltage detected by the first voltage sensor 22 and the second voltage sensor 23 are used. In the potential difference from the detected and measured inverter input voltage, the voltage detected and measured by the voltage sensor 22 is lower than the voltage detected and measured by the voltage sensor 23.

  When the voltage value from the first voltage sensor 22 is equal to or less than the voltage drop in the path of the reactor 11b and the first diode 11c with respect to the voltage value from the second voltage sensor 23, the control circuit 17 Therefore, it is determined that the connection of the input terminal unit 10 is correct, the current fuse 24 is not blown, and it is possible to operate normally. Thereafter, the control circuit 17 issues a switching operation command to the converter 11 and the inverter 12. Thereby, in the power conditioner 3, the power conversion operation is executed.

  In the power conditioner 3, during power conversion operation, unlike the conventional case, there is no open / close means for generating a loss in a path through which the power passes, and therefore loss generation can be eliminated. As a result, it is possible to prevent a decrease in power conversion efficiency of the power conditioner 3 due to the addition of a protection function.

  As described above, according to the present embodiment, in the power conditioner 3, the converter 11 and the inverter 12 are deactivated and the current fuse 24 is installed when there is an erroneous connection in the installation work of the photovoltaic power generation system. I decided to let it open. Thereby, it is possible to prevent the semiconductor element from being damaged or broken due to overcurrent in an expensive power semiconductor or the like with a simple and inexpensive configuration. Further, the power conditioner 3 notifies the misconnection state so that it can be identified what kind of misconnection has occurred, so that the operator can quickly and surely repair it. The operator can easily recover by replacing the current fuse 24. In addition, since the switching means is not inserted in the DC input circuit, it is possible to prevent the power conversion efficiency of the power conditioner 3 from being lowered and to realize high power conversion efficiency.

  When a wide gap semiconductor element such as SiC is used for the switch element 11a or the first diode 11c, high efficiency can be achieved while keeping the chip size small. However, by reducing the chip size, the tolerance to overcurrent can be reduced. Get smaller. On the other hand, when the chip size is increased, there is a problem that the withstand against an overcurrent increases, but the device becomes very expensive.

  In the present embodiment, by adding an inexpensive silicon diode (second diode 11d), high efficiency is achieved by using a wide gap semiconductor element such as SiC, and an excessive connection caused by incorrect connection is generated. There is an effect that the semiconductor element can be protected from the electric current.

Embodiment 2. FIG.
FIG. 3 is a block diagram showing a main configuration of the power conditioner according to the present embodiment. In addition, since the principal part structure of the solar energy power generation system in which the power conditioner 3 is used is the same as that of Embodiment 1 (refer FIG. 1), description is abbreviate | omitted.

  In the present embodiment, in the same manner as in the first embodiment, in the installation work of the photovoltaic power generation system, when an erroneous connection in which AC power is applied to the input terminal portion 10 of the power conditioner 3 occurs, the power conditioner 3 Thus, the protection function capable of fusing the current fuse 24, preventing the destruction and failure of the semiconductor element, and informing the erroneous connection state to be surely repaired is realized with a simple and inexpensive configuration. This will be specifically described with reference to FIG. Since the general configuration and operation of the power conditioner 3 are well known, the description thereof is omitted. Further, a part of the common parts already described in the first embodiment will be omitted, and here, the parts related to the present embodiment will be mainly described.

  In a general configuration, a “protection function that prevents the destruction and failure of semiconductor elements when a connection error occurs during the installation of a solar power generation system, and that can be reliably repaired by reporting the connection error” In this embodiment, as shown in FIG. 3, the positive terminal (+) of the input terminal portion 10 and the corresponding input terminal of the converter 11 are connected via a current fuse 24 as shown in FIG. .

  In the converter 11, the first diode 11c is connected so that the connection point between the reactor 11b and the switch element 11a becomes the anode. The first diode 11c is a wide gap semiconductor element such as a SiC Schottky barrier diode.

  In the converter 11, the second diode 11d is connected in parallel to the switch element 11a so that the connection point between the reactor 11b and the switch element 11a is a cathode. The second diode 11d is a silicon semiconductor element.

  In the converter 11, a third diode 11e having a cathode connected to the cathode terminal of the first diode 11c is connected in parallel with the series circuit of the reactor 11b and the first diode 11c. The third diode 11e is a silicon semiconductor element.

  In the converter 11, a first voltage sensor 22 that measures a voltage applied between the positive terminal (+) and the negative terminal (−) of the input terminal unit 10, and an input from the converter 11 to the inverter 12. And a second voltage sensor 23 that measures the voltage of the DC power (bus voltage). In addition, based on the measured values of the first voltage sensor 22 and the second voltage sensor 23, the control circuit 17 is notified of the function for starting and not starting the converter 11 and the inverter 12, and the notification means 18. The function to be made is added.

  In the following, a description will be given of “a protective function that prevents the destruction and failure of a semiconductor element when an erroneous connection occurs in the installation work of the photovoltaic power generation system, and notifies the erroneous connection state so that it can be reliably repaired”.

  First, a case will be described in which a cable connected to the AC power system 6 from the distribution board 4 is mistakenly connected to the input terminal portion 10 of the power conditioner 3 without connecting the paired cable on the connection box 2 side. At this stage, the operating power supply of the power conditioner 3 is off.

  When the power of the power conditioner 3 is off, the switch element 11a of the converter 11 is off. When the power of the AC power system 6 is supplied with a positive polarity at the positive terminal (+) of the input terminal unit 10, the power conditioner 3 has the positive terminal of the input terminal unit 10 from the AC power system 6. (+), An excessive current flows through a path from the current fuse 24, the third diode 11e of the converter 11 and the bus capacitor 12a of the inverter 12 to the negative terminal (-) of the input terminal unit 10. By setting the overcurrent blowing characteristic of the current fuse 24 to be less than the forward overcurrent allowable characteristic of the third diode 11e, the current fuse 24 is blown before the third diode 11e breaks down, and the converter 11 is switched to AC. The product can be protected by disconnecting from the power system 6.

  In addition, since the third diode 11e is made of silicon, a forward voltage drop when an excessive current flows can be suppressed to a small value. Therefore, the path through the reactor 11b and the first diode 11c is the third The forward voltage drop can be increased with respect to the path passing through the diode 11e, and the current flowing through the first diode 11c can be kept low. Thereby, even when the first diode 11c is formed of a wide gap semiconductor element such as SiC, a failure of the first diode 11c can be avoided.

  On the other hand, when the power of the AC power system 6 is supplied with a polarity in which the positive terminal (+) of the input terminal unit 10 is negative, the power conditioner 3 has the negative electrode of the input terminal unit 10 from the AC power system 6. Excessive current flows through the side terminal (−), the second diode 11 d of the converter 11, the reactor 11 b of the converter 11, and the current fuse 24 to the positive terminal (+) of the input terminal unit 10. By setting the overcurrent blowing characteristic of the current fuse 24 to be less than the forward overcurrent allowable characteristic of the second diode 11d, the current fuse 24 is blown before the second diode 11d breaks down, and the converter 11 is switched to AC. The product can be protected by disconnecting from the power system 6.

  Here, in general, a parasitic diode of a semiconductor element such as a SiC MOS-FET has a large voltage drop characteristic with respect to a forward voltage drop of a silicon diode. Therefore, the excessive current mainly flows through the second diode 11d and hardly flows through the switch element 11a formed of a wide gap semiconductor element such as a SiC MOS-FET. Therefore, the failure of the switch element 11a can be avoided. The switch element 11a is not limited to a wide gap semiconductor element, and may be composed of a silicon semiconductor element in relation to the characteristics of the second diode 11d.

  As described above, even when the voltage of the AC power system 6 is applied to the input terminal portion 10 of the power conditioner 3 without noticing the erroneous connection, the current fuse 24 is blown and the constituent elements of the converter 11 fail. Never do. The AC voltage applied to the input terminal unit 10 is detected and measured by the first voltage sensor 22, and the information is input to the control circuit 17. At the same time, the charging voltage of the bus capacitor 12 a is detected and measured by the second voltage sensor 23, and the information is input to the control circuit 17.

  Since the detection voltage of the first voltage sensor 22 is an AC signal, the control circuit 17 can recognize an erroneous connection such as an AC connection based on the detected and measured voltage information. As a result, the control circuit 17 can prevent the converter 11 and the inverter 12 from starting up. Therefore, destruction / failure of the semiconductor element can be prevented.

  In addition, the control circuit 17 displays and outputs an abnormality due to erroneous connection such as AC connection in parallel as an error message on the display unit of the notification unit 18, sounds a buzzer of the notification unit 18, issues an alarm, and notifies the operator. . In this case, the error message on the display unit and the sound of the buzzer indicate what kind of misconnection occurred. In this example, it is possible to know that an incorrect connection called AC connection has occurred. Can quickly and reliably eliminate erroneous connections.

  Next, the case where the paired cable on the connection box 2 side is connected to the input terminal portion 10 of the power conditioner 3 but the polarity is reversed will be described. At this stage, the operating power supply of the power conditioner 3 is off.

  When the power of the power conditioner 3 is off, the switch element 11a of the converter 11 is off. In this case, the negative terminal (−) of the input terminal 10 from the connection box 2, the second diode 11 d of the converter 11, the reactor 11 b of the converter 11, and the current fuse 24, the positive terminal ( Current flows along the path leading to +). Since there is almost no voltage drop in this path, a short-circuit current flows from the solar cell module 1, but since this current is a constant current proportional to the intensity of sunlight incident on the solar cell module 1, the current fuse 24. The product can be protected by selecting the current fuse 24 and the second diode 11d so as not to exceed the forward current allowable characteristic of the second diode 11d.

  The reverse polarity DC voltage applied to the input terminal unit 10 is detected and measured by the first voltage sensor 22, and the information is input to the control circuit 17. Since the control circuit 17 can recognize the erroneous connection of the reverse polarity connection, the converter 11 and the inverter 12 are not activated.

  In addition, the control circuit 17 displays and outputs an abnormality due to the erroneous connection such as reverse polarity connection in parallel as an error message on the display unit of the notification unit 18, sounds a buzzer of the notification unit 18, issues an alarm, and notifies the operator. To do. In this case, the error message of the display unit and the sound of the buzzer indicate what kind of misconnection has occurred. In this example, it is possible to know that a misconnection of reverse polarity has occurred. The person can quickly and surely eliminate the erroneous connection.

  Next, a case where the installation work is correctly performed will be described. When the paired cable on the connection box 2 side is correctly connected to the input terminal portion 10 of the power conditioner 3, the switch element 11a of the converter 11 is in an off state.

  When the operation power supply of the power conditioner 3 is turned on, the first voltage sensor 22 detects and measures the magnitude and polarity of the DC voltage applied to the input terminal unit 10 and gives the measurement result to the control circuit 17. At the same time, the second voltage sensor 23 detects and measures the charging voltage of the bus capacitor 12 a that is the input voltage of the inverter 12, and gives the measurement result to the control circuit 17.

  Since the voltage detected and measured by the first voltage sensor 22 is DC and positive, the control circuit 17 next uses the voltage value detected and measured by the first voltage sensor 22 and the second voltage sensor 23. Compare the detected and measured voltage value.

  Here, the potential difference between the converter input voltage detected and measured by the first voltage sensor 22 and the inverter input voltage detected and measured by the second voltage sensor 23 corresponds to the voltage drop in the path of the third diode 11e. To do.

  Further, when the voltage at the input terminal unit 10 is lowered after the bus capacitor 12a is once charged with a high voltage, the converter input voltage detected by the first voltage sensor 22 and the second voltage sensor 23 are used. In the potential difference from the detected and measured inverter input voltage, the voltage detected and measured by the voltage sensor 22 is lower than the voltage detected and measured by the voltage sensor 23.

  When the voltage value from the first voltage sensor 22 is substantially zero or lower than the voltage value from the second voltage sensor 23, the control circuit 17 correctly connects the input terminal unit 10 and the current fuse. It is determined that 24 is not melted and can be operated normally. Thereafter, the control circuit 17 issues a switching operation command to the converter 11 and the inverter 12. Thereby, in the power conditioner 3, the power conversion operation is executed.

  In the power conditioner 3, during power conversion operation, unlike the conventional case, there is no open / close means for generating a loss in a path through which the power passes, and therefore loss generation can be eliminated. As a result, it is possible to prevent a decrease in power conversion efficiency of the power conditioner 3 due to the addition of a protection function.

  As described above, according to the present embodiment, in the power conditioner 3, the converter 11 and the inverter 12 are deactivated and the current fuse 24 is installed when there is an erroneous connection in the installation work of the photovoltaic power generation system. I decided to let it open. Thereby, it is possible to prevent the semiconductor element from being damaged or broken due to overcurrent in an expensive power semiconductor or the like with a simple and inexpensive configuration. The operator can easily recover by replacing the current fuse 24. In addition, since the switching means is not inserted in the DC input circuit, it is possible to prevent the power conversion efficiency of the power conditioner 3 from being lowered and to realize high power conversion efficiency.

  When a wide gap semiconductor element such as SiC is used for the switch element 11a or the first diode 11c, high efficiency can be achieved while keeping the chip size small. However, by reducing the chip size, the tolerance to overcurrent can be reduced. Get smaller. On the other hand, when the chip size is increased, there is a problem that the withstand against an overcurrent increases, but the device becomes very expensive.

  In the present embodiment, by adding inexpensive silicon diodes (second diode 11d and third diode 11e), a wide gap semiconductor element such as SiC is used to achieve high efficiency, and an error occurs. There is an effect that the semiconductor element can be protected from an excessive current generated in the connection.

  In the first and second embodiments, a power generation system using solar cells is shown as a power generation system using an external DC power supply. However, a power condition equipped with a protection function against erroneous connection according to the first and second embodiments. Needless to say, the na can be similarly applied to a power conditioner used in a power generation system using a fuel cell.

  As described above, the power conditioner according to the present invention prevents the destruction of the semiconductor element with a simple and inexpensive configuration even if an erroneous connection occurs in the installation work of the power generation system using the external DC power source, and It is useful as a power conditioner having a protection function that can be informed of an erroneous connection state and reliably repaired.

  DESCRIPTION OF SYMBOLS 1 Solar cell module (external DC power supply), 2 Connection box, 3 Power conditioner, 4 Distribution board, 5 Load, 6 AC power system, 10 Input terminal part, 11 Converter, 11a Switch element, 11b Reactor, 11c 1st 11d second diode, 11e third diode, 12 inverter, 13 output filter, 14 interconnection switch, 15 AC switch, 16 output terminal section, 17 control circuit, 18 notification means, 22 first Voltage sensor, 23 Second voltage sensor, 24 Current fuse.

Claims (10)

An input terminal portion in which cables connected to the positive output terminal and the negative output terminal of the external DC power supply are detachably connected to the corresponding terminals,
A converter that converts the output DC power of the external DC power source input from the input terminal unit into DC power of another voltage value;
An inverter that converts the output DC power of the converter into AC power;
A current fuse inserted in series between the input terminal portion and the converter;
With
The converter is
One end of the reactor and one end of the switch element are connected, the anode terminal of the first diode is connected to a connection point between the reactor and the switch element, and the other end of the reactor and the other end of the switch element A step-up circuit configuration in which DC power is input between the cathode terminal of the first diode and the other end of the switch element, and the reactor and the switch element Connecting a cathode terminal of a second diode to a connection point, connecting the second diode and the switch element in parallel;
The switch element is a wide gap semiconductor element,
The second diode is a silicon semiconductor element.
A power conditioner characterized by that. An input terminal portion in which cables connected to the positive output terminal and the negative output terminal of the external DC power supply are detachably connected to the corresponding terminals,
A converter that converts the output DC power of the external DC power source input from the input terminal unit into DC power of another voltage value;
An inverter that converts the output DC power of the converter into AC power;
A current fuse inserted in series between the input terminal portion and the converter;
With
The converter is
One end of the reactor and one end of the switch element are connected, the anode terminal of the first diode is connected to a connection point between the reactor and the switch element, and the other end of the reactor and the other end of the switch element A step-up circuit configuration in which DC power is input between the cathode terminal of the first diode and the other end of the switch element, and the reactor and the switch element Connecting a cathode terminal of a second diode to a connection point, connecting the second diode and the switch element in parallel;
The switch element is a wide gap semiconductor element,
The first diode is a wide gap semiconductor device;
The second diode is a silicon semiconductor element.
A power conditioner characterized by that. An input terminal portion in which cables connected to the positive output terminal and the negative output terminal of the external DC power supply are detachably connected to the corresponding terminals,
A converter that converts the output DC power of the external DC power source input from the input terminal unit into DC power of another voltage value;
An inverter that converts the output DC power of the converter into AC power;
A current fuse inserted in series between the input terminal portion and the converter;
With
The converter is
One end of the reactor and one end of the switch element are connected, the anode terminal of the first diode is connected to a connection point between the reactor and the switch element, and the other end of the reactor and the other end of the switch element A step-up circuit configuration in which DC power is input between the cathode terminal of the first diode and the other end of the switch element, and the reactor and the switch element Connecting a cathode terminal of a second diode to a connection point, connecting the second diode and the switch element in parallel;
An anode terminal is connected to the other end of the reactor, and a third diode is connected to the cathode terminal of the first diode;
The switch element is a wide gap semiconductor element,
The first diode is a wide gap semiconductor device;
The second diode and the third diode are silicon semiconductor elements.
A power conditioner characterized by that. An input terminal portion in which cables connected to the positive output terminal and the negative output terminal of the external DC power supply are detachably connected to the corresponding terminals,
A converter that converts the output DC power of the external DC power source input from the input terminal unit into DC power of another voltage value;
An inverter that converts the output DC power of the converter into AC power;
A current fuse inserted in series between the input terminal portion and the converter;
With
The converter is
One end of the reactor and one end of the switch element are connected, the anode terminal of the first diode is connected to a connection point between the reactor and the switch element, and the other end of the reactor and the other end of the switch element A step-up circuit configuration in which DC power is input between the cathode terminal of the first diode and the other end of the switch element, and the reactor and the switch element Connecting a cathode terminal of a second diode to a connection point, connecting the second diode and the switch element in parallel;
An anode terminal is connected to the other end of the reactor, and a third diode is connected to the cathode terminal of the first diode;
The switch element is a silicon semiconductor element,
The first diode is a wide gap semiconductor device;
The second diode and the third diode are silicon semiconductor elements.
A power conditioner characterized by that. The overcurrent blowing characteristic of the current fuse is less than the forward overcurrent allowable characteristic of the first diode and the second diode.
The power conditioner of Claim 1 or 2 characterized by the above-mentioned. The overcurrent blowing characteristic of the current fuse is less than the forward overcurrent allowable characteristic of the second diode and the third diode.
The power conditioner of Claim 3 or 4 characterized by the above-mentioned. A first voltage sensor for measuring a voltage of the input terminal unit;
A second voltage sensor for measuring the voltage at the output of the converter;
When the external connection connection to the input terminal section is completed and the power conditioner is turned on, the converter and the inverter are controlled to stop operation, and the voltage measured by the first voltage sensor is DC. The voltage of which the polarity matches the polarity of the positive electrode and the negative electrode of the input terminal unit, and the voltage value measured by the second voltage sensor is subtracted from the voltage value measured by the first voltage sensor. Control means for performing control to shift the converter and the inverter from the operation stop state to the respective conversion operations when the voltage difference is equal to or less than the total value of the forward voltage drops of the reactor and the first diode;
The power conditioner according to claim 1, 2, or 5. A first voltage sensor for measuring a voltage of the input terminal unit;
A second voltage sensor for measuring the voltage at the output of the converter;
When the external connection connection to the input terminal section is completed and the power conditioner is turned on, the converter and the inverter are controlled to stop operation, and the voltage measured by the first voltage sensor is DC. The voltage of which the polarity matches the polarity of the positive electrode and the negative electrode of the input terminal unit, and the voltage value measured by the second voltage sensor is subtracted from the voltage value measured by the first voltage sensor. Control means for performing control to shift the converter and the inverter from the operation stop state to the respective conversion operations when the voltage difference is equal to or less than the total value of the forward voltage drops of the third diode;
The power conditioner according to claim 3, 4 or 6. The control means includes
When the voltage measured by the first voltage sensor is a DC voltage but the polarity does not match the polarity of the positive electrode and the negative electrode of the input terminal unit, or the voltage measured by the first voltage sensor is an AC voltage If it is, the operation of the power conditioner is suspended, and the notification means for notifying the operation state of the power conditioner is caused to output information notifying the abnormality,
The power conditioner of Claim 7 or 8 characterized by the above-mentioned. The control means includes
Information notifying the abnormality to be output to the notifying means includes a case where the polarity of the DC voltage measured by the first voltage sensor does not match the polarity of the positive electrode and the negative electrode of the input terminal unit, and the first voltage sensor. Generate the voltage so that it can be distinguished from the case where the measured voltage is an AC voltage.
The power conditioner according to claim 9.

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