JP2004357390A - Power supply device including system interconnection inverter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power supply device including a system interconnection inverter which can accurately supply momentarily fluctuating excess power to a dummy load while preventing reverse power flow to a system power supply with a simple facility constitution. <P>SOLUTION: The power supply device 10 including the system interconnection inverter 13 is for supplying a current to the load 100 connected to the system power supply 200 by inversely converting DC power from a DC power supply 11 to AC power. It is provided with the dummy load 31 connected to a DC input of the system interconnection inverter, a DC voltage detecting circuit 32 for detecting a DC link voltage of the DC input, and control units 15, 33 for controlling the power supply to the dummy load on the basis of the DC link voltage detected by the DC voltage detecting circuit. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a power supply device including a grid-connected inverter, and in particular, is connected to a commercial AC system power supply (hereinafter, referred to as a system power supply) by transforming DC power and converting it back to AC power. The present invention relates to a power supply device including a grid-connected inverter that supplies AC power to a load.
[0002]
[Prior art]
In recent years, small-scale power generation equipment such as a solar cell, a fuel cell, or a gas turbine generator has been widely used. In these power generation facilities, DC power generated by a solar cell, a fuel cell, or the like, or DC power obtained by rectifying AC power generated by a gas turbine generator, a wind power generator, or the like, is converted into a DC / DC converter or the like. In many cases, power is supplied to a load by converting the voltage by a chopper circuit or the like and then performing reverse conversion to AC power by an inverter. In such a case, the load is connected to a system power supply, and when power is not supplied from the power generation equipment or when the supplied power is insufficient, the load is supplemented with the power from the system power supply.
[0003]
As described above, in a power generation facility including a system interconnection inverter that supplies DC power by converting DC power back to AC power to a load also connected to the system power supply, various types of power supply are also connected to the system power supply. Regulations are in place. One of the restrictions is the restriction of reverse power flow. An example of this regulation is "to prevent the flow (tidal flow) of active power from the premises of the power generation facilities toward the system power supply from occurring in the banks of the distribution substations". That is, the active power generated by the power generation equipment is all supplied to the line load in the premises where the power generation equipment is present, and the active power is restricted from flowing out to the system power supply side.
[0004]
By the way, the required power of the line load in the power generation facility premises fluctuates every moment. On the other hand, the power generation capacity of the power generation equipment is determined, for example, by the sunshine conditions of a solar cell or the like, and the generated power cannot immediately follow the required power of the line load. For this reason, when the required power of the line load is lower than the generated power, surplus power is generated, and the surplus generated power is directed toward the system power supply, resulting in a so-called reverse power flow. Therefore, a method is generally adopted in which the generated power is kept approximately constant, a pseudo load (for example, a power resistor such as a heater) is provided, and the surplus power is absorbed by the pseudo load according to the fluctuation of the line load (for example, Patent Documents 1 and 2).
[0005]
[Patent Document 1]
JP 2000-320401 A [Patent Document 2]
JP-A-2002-281672
However, since the line load changes every moment, it cannot be predicted in advance. In addition, the size of the pseudo load actually includes a manufacturing error and the like, and fluctuates depending on the environment such as temperature and humidity. Then, it is not always easy to accurately supply surplus power other than that consumed by the line load to the pseudo load, out of the power generation output generated at a substantially constant pace.
[0007]
[Problems to be solved by the invention]
The present invention has been made in view of the above-described circumstances, and it is possible to accurately supply surplus power that fluctuates every moment to a pseudo load with a simple facility configuration while preventing reverse power flow to a system power supply. It is another object of the present invention to provide a power supply device including a system interconnection inverter.
[0008]
[Means for Solving the Problems]
The power supply device of the present invention is a power supply device that includes a system interconnection inverter that converts a DC power from a DC power supply into an AC power and supplies a current to a load connected to the system power supply, A pseudo load connected to the DC input of the inverter, a DC voltage detection circuit for detecting a DC link voltage of the DC input, and a load to the pseudo load based on the DC link voltage detected by the DC voltage detection circuit. And a control unit for controlling power supply.
[0009]
Here, it is preferable that the control unit controls power supply to the pseudo load so that the DC link voltage is adjusted to a constant value. Further, it is preferable that the system interconnection inverter controls its output power so that active power flowing to the system power supply side is not generated.
[0010]
Further, the control method of the power supply device according to the present invention is configured such that the DC power from the DC power supply is inversely converted into AC power by the system interconnection inverter, and the system interconnection is performed so that the reverse power flow in which the active power flows out to the system power supply does not occur. The output power of the inverter is adjusted, and the surplus power is supplied to a pseudo load connected to the input side of the grid interconnection inverter when surplus power occurs in the DC power supply. .
[0011]
According to the present invention, the power supplied to the load connected to the system power is controlled by the system interconnection inverter based on the voltage on the system power and the current flowing into and out of the system power. On the other hand, when surplus power is generated on the DC power supply side, the DC power is supplied as it is to the pseudo load connected in front of the system interconnection inverter. Therefore, with a simple configuration, the surplus power can be absorbed by the pseudo load in the previous stage of the system interconnection inverter, while preventing the reverse power flow from going to the system power supply side.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. FIG. 1 is a diagram illustrating an example of a power generation facility to which an embodiment of a power supply device including a system interconnection inverter according to the present invention is applied.
[0013]
In FIG. 1, a power generation facility 10 includes a DC power supply such as a solar cell or a fuel cell, or a DC power supply 11 for rectifying an AC output of a gas turbine generator to obtain a DC output. Since the output voltage of the DC power supply 11 is generally low, the DC / DC converter 12 or the like boosts the voltage to a voltage sufficient to form an AC voltage of the system power supply, and then supplies the boosted DC voltage to the inverter 13. To generate an AC output and supply power to a load 100 such as desired equipment. When the output voltage of the DC power supply 11 is high, the voltage may be reduced as necessary. Further, here, the power generation facility 10 including the DC power supply 11 will be described as an example, but it goes without saying that the DC power supply may be an external facility.
[0014]
The inverter 13 is provided with a power switching element, and is turned on / off by a pulse width modulation (PWM) signal supplied from a controller (control unit) 15, for example, so that the power is inverted from the DC power. The converted AC power is output from the output terminal. Since the output voltage waveform of the inverter 13 is formed by a pulse width modulation (PWM) signal, it contains a large amount of harmonic components. For this reason, the sine wave voltage of the inverter output is supplied to the load line 18 connected to the load 100 so that the harmonic component is removed by the filter 16 and connected to the system power supply 200.
[0015]
Here, the power supply equipment from the DC power supply 11 of the power generation equipment 10 to the load 100 is arranged in the premises of the power generation equipment installer. The load line 18 to which the load 100 is connected is connected to a system power source 200 outside the premises of the power generation facility installer. Therefore, for example, during a time period when the DC power supply 11 such as a solar cell does not generate power, power is supplied to the load 100 by power transmission from the system power supply 200 side. Also, when the amount of power generated by the DC power supply 11 is less than the required power amount of the load equipment 100, part of the power consumed by the load equipment 100 is transmitted from the system power supply 200 side.
[0016]
By the way, when the amount of power generated by the DC power supply 11 exceeds the required power amount of the load equipment 100, surplus power is transmitted to the system power supply 200 side, that is, so-called power selling may be performed. In some cases, transmission to the side may not be recognized as reverse power flow at all. The power generation equipment 10 to which the power supply device of this embodiment is applied is suitable when such a reverse power flow is not recognized at all. That is, when the amount of power generated by the DC power supply 11 exceeds the required power amount of the load 100, the controller 15 controls the output of the inverter 13 so that the inverter output power does not flow backward to the system power supply 200. . That is, the controller 15 detects the reverse power flow and controls the inverter 13 to output power corresponding to the power consumed by the load 100.
[0017]
Specifically, the reverse power flow of the power flowing from the load 100 to the system power supply 200 is detected by a current detector (ACCT) 23 and a voltage detector (ACPT) 24 constituting a system power detection circuit. The current detector 23 is connected to the current sensor circuit 25, and inputs a detected current value to the controller 15. Further, the voltage detector 24 is connected to the voltage sensor circuit 26, and similarly inputs the detected voltage value to the controller 15. The current detector 23 is arranged at a connection to the system power supply, and detects a current flowing into and out of the system power supply. The voltage detector 24 is arranged on the output side of the filter 16, and detects the voltage of the system power supply.
[0018]
The controller 15 integrates the detected current value and voltage value every AC cycle or half cycle to detect the power flow flowing in and out between the system power supply 200 and the load 100 side. That is, by detecting the direction of the current flow by the current detector 23, the power flow is a forward flow from the system power supply 200 to the load 100, or the power flow from the load 100 (the inverter 13 side). It is possible to detect whether the power flow is a reverse flow in which the power flow is flowing to the power supply 200 and to detect the magnitude (power value) thereof.
[0019]
When detecting the magnitude (power value) of the reverse power flow, the controller 15 reduces the output of the inverter 13 so as to reduce the output of the inverter 13 by the reverse power flow or the sum of the reverse power flow and a preset offset. (PWM signal) to the inverter 13. Thus, the inverter 13 can supply only the power consumed by the load 100 and not supply the active power to the system power supply 200 side (there is no reverse power flow).
[0020]
In other words, the controller 15 easily calculates the output power control signal to the inverter 13 from the direction and magnitude of the power flow in the load line 18 connected to the system power supply 200 so as to supply power only to the load 100. -Can be generated. In other words, the required power can be supplied only to the load 100 while preventing a reverse power flow to the system power supply 200 with a simple configuration in which a microcomputer or the like is operated by a very simple program processing.
[0021]
Here, simply controlling the AC power supplied from the inverter 13 or the like to the load 100 or the system power supply 200 to a desired power amount may cause a case where the generated power amount from the DC power supply 11 exceeds the required power amount of the load 100. As long as the output of the DC power supply 11 is not lowered, surplus power is stored in a capacitor on the output side (input side of the inverter) of the DC / DC converter 12. If it is left as it is, the DC link voltage of the DC / DC converter 12 gradually rises and becomes an overvoltage.
[0022]
For this reason, in the power generation facility 10, a pseudo load 31 is connected in parallel between the DC / DC converter 12 and the inverter 13, and the surplus power from the DC power supply 11 exceeding the required power amount of the load 100 is simulated. It is supplied to the load 31 and absorbed.
[0023]
Here, as the dummy load 31, a device capable of storing energy, such as a battery charger or a flywheel, or a power resistor such as a heater may be used. That is, in the case of a battery charger or the like, surplus power can be stored and absorbed as power energy. In the case of a heater, etc., the power energy is converted into heat energy by supplying a load current to the power resistor, and surplus power is consumed and absorbed by heating water or the like disposed around the power resistor, You can make hot water.
[0024]
The DC link voltage of the DC / DC converter 12 is detected by a DC voltage sensor circuit (link voltage detection circuit) 32 connected to the wiring between the DC / DC converter 12 and the inverter 13, and is input to the controller 15. Is done. The controller 15 controls the power control element 33 interposed between the wiring between the DC / DC converter 12 and the inverter 13 and the pseudo load 31 based on the detected DC link voltage value, DC power is supplied to the dummy load 31 to adjust power supply to the inverter 13. That is, the controller 15 also configures a control unit together with the power control element 33.
[0025]
Specifically, the controller 15 controls the power control element 33 so that the DC link voltage of the DC / DC converter 12 is maintained at a preset value. Specifically, a switch (switching element) is used as the power control element 33, and when the voltage exceeds a predetermined voltage, the switch is turned on to supply power to the dummy load 31 and the DC link voltage decreases, and the DC link voltage falls below a predetermined value. In this case, the supply of power to the dummy load 31 is cut off.
[0026]
For example, with respect to the rated DC link voltage, +30 V is set as the upper limit, and -20 V is set as the lower limit. In this case, by sending an ON control signal to the power control element 33 when the DC link voltage of the DC / DC converter 12 becomes higher than the upper limit value of +30 V, the pseudo load 31 is placed before the inverter 13. Input (connect) to absorb excess power. On the other hand, after that, by sending an off control signal to the power control element 33 when the DC link voltage falls below the lower limit value of −20 V, the dummy load 31 is disconnected from the preceding stage of the inverter 13, thereby turning off the inverter 13. So as not to interfere with the desired power supply.
[0027]
Thereby, the controller 15 easily turns on / off the power control element 33 only by determining whether the DC link voltage of the DC / DC converter 12 is within the set range, and reduces the power to the dummy load 31. Can be supplied and shut off. In addition, since the inverter 13 and the filter 16 are not interposed in the path for supplying power to the dummy load 31, power loss can be reduced, and the current capacity of each part becomes excessively large, resulting in cost reduction. The height can be prevented. Further, since the inverter 13 and the filter 16 are not interposed, it is possible to prevent a harmonic wave interference leaking outside through the pseudo load.
[0028]
In the above example, an example was described in which a switch (switching element) was used as the power control element and the on / off control was performed. However, for example, the surplus power was applied to the pseudo load while the DC link voltage was maintained at a constant value. You may make it supply. Thus, when power equal to or higher than the power output from the inverter is input from the DC power supply 11 side, surplus power is supplied to the dummy load 31 so as to keep the DC link voltage constant. Further, it is preferable that the detection of the power flow and the control of the power control element 33 be performed every half cycle or one cycle of the AC. This makes it possible to grasp the power flow that fluctuates from time to time in every half cycle or one cycle of the AC, and to perform appropriate control of the power control element, in other words, control of power supply to the dummy load.
[0029]
As described above, in the present embodiment, power is supplied from the inverter 13 to the load 100 based on the voltage and current of the system power supply 200 so that reverse power flow does not occur. The surplus power is absorbed by controlling the power supply to the pseudo load 31. Therefore, the DC link voltage can be supplied from the DC / DC converter 12 to the inverter 13 while keeping the DC link voltage substantially constant.
[0030]
Accordingly, the required power can be supplied to the load 100 by simply controlling the inverter 13, and the surplus power from the DC power supply 11 can be simply connected and disconnected based on the DC link voltage. Power can be absorbed. As a result, with a simple configuration, while supplying necessary power to the load 100 connected to the system power supply 200 without generating a reverse power flow, the surplus power that fluctuates from time to time is accurately absorbed by the pseudo load 31, It is possible to prevent an increase in the DC ring voltage and prevent damage to equipment or occurrence of an overvoltage error due to overvoltage.
[0031]
It should be noted that the above-described embodiment describes one mode of the embodiment of the present invention, and it is needless to say that various modifications can be made without departing from the spirit of the present invention.
[0032]
【The invention's effect】
According to the present invention, the AC power supplied from the system interconnection inverter to the system power supply and the load side is controlled based on the system voltage and the current, while the DC power converted to the AC power is applied to the DC link voltage. In this case, the adjustment is performed by supplying or interrupting the supply to the dummy load. As a result, it is possible to accurately supply surplus power that fluctuates from time to time to the dummy load and absorb the DC power, pass the DC power to the grid-connected inverter, and supply only the necessary power to the load connected to the grid power supply. it can.
[0033]
Therefore, with a simple configuration, it is possible to prevent the reverse power flow of the surplus power, absorb the surplus power at the front stage of the system interconnection inverter, and prevent the occurrence of overvoltage. As a result, compared to the conventional method of connecting a pseudo load to the inverter output side, surplus power does not flow to the inverter, the filter circuit, and the like, so that these devices can be reduced in size and size.
[0034]
Further, since an increase in the DC link voltage is detected and power is supplied to the dummy load, it is possible to accurately supply surplus power to the dummy load. In general, according to the present invention, it is possible to reduce the size and size of the device and to perform reverse power flow prevention control capable of accurately supplying surplus power to a dummy load.
[Brief description of the drawings]
FIG. 1 is a diagram showing an example of a power generation facility to which an embodiment of a power supply device including a system interconnection inverter according to the present invention is applied, and is a block diagram showing an outline thereof.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 Power generation equipment 11 DC power supply 12 DC / DC converter 13 Inverter 15 Controller 16 Filter 18 Load line 23 Current detector 24 Voltage detector 25 Current sensor circuit 26 Voltage sensor circuit 31 Pseudo load 32 DC voltage sensor circuit 33 Power control element 100 Load (Facility)
200 system power supply

Claims (4)

A power supply device including a grid-connected inverter that converts a DC power from a DC power supply into an AC power and supplies a current to a load connected to the system power supply,
A pseudo load connected to a DC input unit of the grid interconnection inverter, a DC voltage detection circuit for detecting a DC link voltage of the DC input unit, and a DC link voltage detected by the DC voltage detection circuit. A power supply device comprising: a control unit that controls power supply to a dummy load. The power supply device according to claim 1, wherein the control unit controls power supply to the pseudo load such that the DC link voltage is adjusted to a constant value. The power supply device according to claim 1, wherein the grid-connected inverter controls output power of the grid-connected inverter so that active power flowing to a grid power supply is not generated. The DC power from the DC power supply is inversely converted into AC power by the grid-connected inverter, and the output power of the grid-connected inverter is adjusted so that a reverse power flow in which active power flows out to the grid power does not occur. A control method of a power supply device, wherein when a surplus power is generated, the surplus power is supplied to a pseudo load connected to an input side of the grid interconnection inverter.

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