JP2014096966A - Power conditioner, power conditioner system, and control method of power conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power conditioner, a power conditioner system, and a control method of the power conditioner in which influences of an area on broadcasting frequency can be reduced.SOLUTION: The power conditioner has: an area specifying section which specifies an installation area of a solar battery panel on the basis of electric output of the solar battery panel; and an exciting frequency controlling section which controls exciting frequency (switching frequency) of a converter or an inverter for applying voltage conversion or current conversion to the electric output of the solar battery panel. The exciting frequency controlling section controls the exciting frequency (switching frequency) so as not to have an influence on broadcasting frequency in the specified installation area.

Description

  The present invention relates to a power conditioner, a power conditioner system, and a control method for the power conditioner.

  There is a standard established by VCCI (Voluntary Control Council for Information Technology Equipment) as a technical standard on the maker side that suppresses radiation noise to AM radio of general electrical equipment and information equipment. However, this criterion is self-regulating for manufacturers of power conditioner products for photovoltaic power generation and is not binding. Even if this criterion is satisfied, the frequency band considered by VCCI is from 30 MHz to 1 GHz, and the lower AM frequency band of 500 kHz to 1600 kHz is not considered.

  In addition, since the inverter may generate noise in the cited document 1, a device that suppresses noise by providing a noise filter in the input / output unit of the inverter is disclosed.

JP 2001-65463 A

  In the conventional power conditioner for photovoltaic power generation, semiconductor switching noise is generated during operation of the power conditioner, and in order to suppress radiation noise to the AM radio due to this semiconductor switching noise, there are cases in which circuits and mechanisms are considered, It may affect development time and cost.

  Therefore, in a power conditioner for photovoltaic power generation, it is desirable to avoid the use of frequencies that may affect harmonics on AM radio etc. in order to reduce the time and cost for measures against radiation noise.

  The present invention has been made in view of such problems, and an object of the present invention is to provide a power conditioner, a power conditioner system, and a power conditioner that can reduce the influence on the broadcast frequency in the region. It is to provide a control method.

  In order to achieve the above object, the present invention provides a power conditioner connected to a commercial power system by voltage-converting or current-converting the electrical output of a solar cell panel, based on the electrical output of the solar cell panel. And an excitation frequency control unit for controlling an excitation frequency of a converter or an inverter for converting the electrical output of the solar cell panel into a voltage or current, and specifying an area where the panel is installed. The unit controls the excitation frequency based on the installation area.

  The power conditioner of the present invention further includes a storage unit that stores the association between a region and the broadcast frequency of the region, and the excitation frequency control unit does not affect the broadcast frequency of the region corresponding to the installation region. Thus, it is preferable to control the excitation frequency.

  It is preferable that the area specifying unit specifies an area by detecting at least one of sunrise time and sunset time according to the electrical output.

  Further, the present invention provides a power conditioner system comprising a solar cell panel and a power conditioner connected to a commercial power system by voltage-converting or current-converting the electrical output of the solar cell panel. Is an area specifying unit for specifying an installation area of a solar cell panel based on an electrical output of the solar cell panel, and an excitation frequency of a converter or an inverter for converting the electrical output of the solar cell panel into a voltage or current. And an excitation frequency control unit for controlling, wherein the excitation frequency control unit controls the excitation frequency based on the installation area.

  Further, the present invention provides a method for controlling a power conditioner that is connected to a commercial power system by voltage-converting or current-converting the electrical output of the solar panel, based on the electrical output of the solar panel. And a step of controlling an excitation frequency of a converter or an inverter for performing voltage conversion or current conversion of an electrical output of the solar cell panel based on the installation area. .

  The present invention can reduce the influence on the broadcast frequency in the area.

It is a lineblock diagram of a power conditioner system concerning an embodiment of the invention. It is a flowchart explaining the process sequence which specifies the area | region of an installation position. It is a figure which shows an example of the time database of the sunrise of Japan utilized for an area | region identification. It is a figure which shows an example of the Japanese sunset time database utilized for an area | region identification. It is a flowchart explaining the process sequence which selects a switching frequency. It is a conceptual diagram of the AM radio station database utilized when selecting a switching frequency. It is a conceptual diagram of the radiation noise frequency characteristic for every switching frequency of a power conditioner.

  Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a configuration diagram of a power conditioner system according to an embodiment of the present invention. The power conditioner system shown in FIG. 1 includes a solar cell (PV) panel 1, a connection unit 2, a power conditioner 3 that converts the electrical output of the solar cell panel 1 into a voltage and a current, and an AC that is a commercial power source. It is comprised by the system | strain 4.

  The power conditioner 3 includes a DC / DC converter 11, a DC / AC inverter 12, a switch 13, a control unit 14 (region specifying unit, excitation frequency control unit), and a data storage device 15 (storage unit). Prepare.

  The DC / DC converter 11 converts the voltage generated by the solar battery panel 1 into a DC voltage that can be used by the DC / AC inverter 12. The DC / AC inverter 12 converts a direct current voltage into a commercial 50 Hz or 60 Hz alternating current. The switch 13 is turned off when disconnected from the AC system 4 as necessary.

  The control unit 14 is operated by the power supply from the AC system 4 or the power supply from the solar cell panel 1, and identifies the region where the power conditioner system is installed by automatically observing and analyzing sunrise and sunset. At the same time, a switching frequency that does not affect the AM radio in the installation area is automatically selected.

  The data storage device 15 is a radio frequency characteristic data composed of switching frequency (excitation frequency), power conversion efficiency, and radiation noise test data obtained at the time of a factory shipment test, and a nationwide AM radio composed of a region and a broadcasting frequency of the region. The station frequency database and the national sunrise and sunset time database are stored. These radiation noise frequency characteristic data, AM radio station frequency database, and nationwide sunrise / sunset time database are recorded in the data storage device 15 at the time of factory shipment.

  First, a processing procedure for specifying the area of the system installation position at the time of system installation (operation start) will be described based on the flowchart of FIG.

  The control part 14 confirms the raise of the input voltage from the solar cell panel 1 (S101). At this time, the power conditioner is not operating (direct current to alternating current conversion) in fear of the operation of the switch 13 with unstable power. The sun has not risen yet, and the surroundings have begun to brighten.

  The control unit 14 determines that sunrise occurs when the input voltage from the solar cell panel 1 exceeds a specific voltage (for example, 50V) (S102), and stores the date and time by the calendar function provided in the power conditioner. Recording is performed in the device 15 (S103).

  Based on the recorded sunrise time, the control unit 14 searches the sunrise time database stored in the data storage device 15 for an area corresponding to the sunrise time near the same date and time (S104). FIG. 3 is a diagram illustrating an example of a Japanese sunrise time database used for specifying a region. In FIG. 3, for example, when sunrise is 4:55, an area from Kanagawa to Gunma to Niigata is extracted. Since the area cannot be specified until the next sunset, the control unit 14 starts operation at a switching frequency (factory shipment value) with an emphasis on efficiency when the voltage rises to a voltage that can be generated. The control unit 14 may tentatively determine an area that can be considered at this time, and perform the following noise avoidance procedure based on the area.

  The control unit 14 determines that the sunset is when the input voltage from the solar cell panel 1 falls below a specific voltage (for example, 30 V) (S105), and the date and time is recorded by the calendar function provided in the power conditioner. Record in the storage device (S106).

  Based on the recorded sunset time, the control unit 14 searches the sunrise time database stored in the data storage device 15 for a region corresponding to the sunset time near the same date (S107). FIG. 4 is a diagram showing an example of a Japanese sunset time database used for specifying a region. In FIG. 4, for example, when the sunset is 18:40, areas of Kanagawa, Saitama, Tochigi, and Fukushima are extracted. The control unit 14 specifies the area where the system is installed from the point where the sunrise / sunset line intersects based on the result of the search for the area corresponding to the sunrise time and the search for the area corresponding to the sunset time (S109).

  When the area is specified, the control unit 14 selects a switching frequency that is a frequency characteristic of radiation noise that has little influence on the AM radio station in the specified area. Next, a processing procedure for selecting a switching frequency that is a frequency characteristic of radiation noise that has little influence on an AM radio station will be described with reference to the flowchart of FIG.

  The control unit 14 determines whether or not the power conditioner is set to prioritize efficiency over measures against radiation noise (S201). If the priority is set for efficiency (in the case of Yes), the switching (SW) frequency is kept at the time of factory shipment (S202).

  If priority is given to “radiation noise countermeasures” (in the case of No), the control unit 14 performs the area specifying process described in FIG. 2 (S203), and selects the AM radio station of the specified area. Reference is made from the AM radio station database stored in the data storage device 15 (S204). FIG. 6 is a conceptual diagram of an AM radio station database used when selecting a switching frequency.

  The control unit 14 further refers to the radiation noise data in the case of the switching frequency at the time of shipment from the factory (S205), and whether or not there is noise that causes the radiation noise to exceed the threshold value in the radio station frequency of the specified region. Is determined (S206). When there is no noise to be hit (in the case of No), the control unit 14 determines the switching frequency not giving this noise as the switching frequency of the DC / DC converter 11 or the DC / AC inverter 12 (S207). When there is noise to hit (in the case of Yes), the control unit 14 counts the frequency (radio station) at which the noise hits (S208).

  FIG. 7 is a conceptual diagram of radiation noise frequency characteristics for each switching frequency of the power conditioner. In FIG. 7, a wavy line represents a threshold value of radiation noise, and a hatched region represents a frequency region where a radio station exists. The control part 14 counts the location where the area | region where radiation noise exceeds a threshold value, and the area | region (frequency area | region where a radio station exists) where hatching was performed overlap.

  Next, the control unit 14 determines whether or not the frequency (radio station) at which noise hits at all switching frequencies has been counted (S209). When the control unit 14 does not perform the process of counting the frequency (radio station) where the noise hits at all the switching frequencies (in the case of No), the switching frequency is shifted, and the radiation noise when the frequency is shifted Refer to the data (S210), and return to S206.

  When the control unit 14 performs a process of counting the frequency (radio station) at which the noise hits at all switching frequencies (in the case of Yes), the control unit 14 selects the switching frequency with the smallest number of radio stations at which the noise hits DC The switching frequency of the DC / DC converter 11 or the DC / AC inverter 12 is determined (S211).

  In S211, if the number of radio stations hit by noise is the same, the switching frequency with high power conversion efficiency is determined as the switching frequency of the DC / DC converter 11 or the DC / AC inverter 12. Therefore, the present invention can avoid the influence of radiation noise on the AM radio without reducing the power conversion efficiency of the power conditioner as much as possible.

  Further, in the above-described embodiment, the radiation noise frequency characteristic data for each switching frequency shown in FIG. 7 is recorded in the data storage device 15 of the power conditioner at the time of factory shipment, but the radiation noise for each switching frequency at the time of factory shipment. If the frequency characteristic data is taken more finely, the number of patterns that can avoid noise increases.

  In the present invention, the installation area of the inverter is specified without a device such as GPS, and the switching frequency is selected in accordance with the frequency usage situation of the AM radio station in the installation area of the inverter. The impact can be suppressed in a short time at a low cost. Further, since these are all performed automatically, the present invention can avoid the influence of radiation noise on the AM radio without allowing the user or installer to input position information and the like during installation and relocation. .

DESCRIPTION OF SYMBOLS 1 Solar cell panel 2 Connection unit 3 Power conditioner 4 AC system 11 DC / DC converter 12 DC / AC inverter 13 Switch 14 Control part 15 Data storage device

Claims (5)

In the power conditioner connected to the commercial power system by converting the electrical output of the solar panel to voltage or current,
An area specifying unit for specifying an installation area of the solar panel based on an electrical output of the solar panel;
An excitation frequency control unit for controlling an excitation frequency of a converter or an inverter for voltage conversion or current conversion of the electrical output of the solar cell panel;
The power conditioner, wherein the excitation frequency control unit controls the excitation frequency based on the installation area.   The storage unit further stores a link between a region and the broadcast frequency of the region, and the excitation frequency control unit controls the excitation frequency so as not to affect the broadcast frequency of the region corresponding to the installation region. The power conditioner according to claim 1.   The power conditioner according to claim 1 or 2, wherein the area specifying unit specifies an area by detecting at least one of a sunrise time and a sunset time according to the electrical output. In a power conditioner system comprising a solar cell panel and a power conditioner connected to a commercial power system by voltage-converting or current-converting the electrical output of the solar cell panel,
The inverter is
An area specifying unit for specifying an installation area of the solar cell panel based on an electrical output of the solar cell panel;
An excitation frequency control unit for controlling an excitation frequency of a converter or an inverter for voltage conversion or current conversion of the electrical output of the solar cell panel;
The power conditioner system, wherein the excitation frequency control unit controls the excitation frequency based on the installation area. In the control method of the power conditioner that is connected to the commercial power system by converting the electrical output of the solar cell panel into a voltage or current,
Identifying an installation area of the solar panel based on the electrical output of the solar panel;
And a step of controlling an excitation frequency of a converter or an inverter for converting the electrical output of the solar cell panel into a voltage or a current based on the installation area.

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