JP2006006019A - Control method of inverter device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To shorten the lifetime of an inverter device by selecting only a specific inverter device if the inverter is selected only on the basis of the number of the starting inverter device determined without considering the selecting order of the inverter devices. <P>SOLUTION: A control method of the inverter device includes the steps of connecting a plurality of the inverter devices in parallel with a DC power supply, determining the number of starting inverter devices based on an output power value, calculating the integrated power value by integrating the output power of each inverter device, selecting only the number of the starting inverter device determined in ascending order, continuing the inverter device as it is when the selected inverter device starts from the previous period, and starting the inverter device when the selected inverter device is stopped. The control method of the inverter device further includes the steps of counting the number of times of changing from the stop to the start of each inverter device for each inverter device, calculating the number of times of the integrated starting by multiplying the integrated power value by the number of times of the integrated starting for each inverter device, and sequentially selecting the inverter device from the inverter device having the small value of the number of times of the integrated power starting. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a power supply system that converts a direct current output from a direct current power source such as a solar cell into an alternating current output by a plurality of inverter devices and supplies the alternating current system to an alternating current system, and particularly relates to a technique for determining a starting order of each inverter device. is there.

  FIG. 4 is a block diagram of a conventional power supply system. In the figure, the power supply system includes a direct current power source DC composed of solar cells, and a first inverter device PS1 to an nth inverter device PSn that are connected in parallel to the direct current power source DC and convert a direct current output into an alternating current output by an inverter. A power detection unit DS that detects an output power value from the DC power source DC, an output control unit SA that controls the inverter devices based on the output power value, and each of the above-described DC power sources DC. The switches SW1 to SWn that open and close the inverter device are formed.

  In FIG. 4, the first inverter device PS1 is formed by a first inverter control circuit CO1 and a first inverter circuit PC1, and the second inverter device PS2 is formed by a second inverter control circuit CO1 and a second inverter circuit PC1. The nth inverter device PSn is formed of an nth inverter control circuit CON and an nth inverter circuit PCn.

  The first inverter control circuit CO1 starts operation when the activation signal is input from the output control unit SA, closes the first switch SW1, supplies the output power from the DC power source DC to the first inverter circuit PC1, and The first inverter circuit PC1 is activated to convert the DC voltage into an AC voltage and supply it to the system power supply AC. The second inverter control circuit CO2 to the nth inverter control circuit CON also perform the same operation as described above.

  The power detector DS detects the output power value from the DC power source DC and inputs it to the output controller SA. The output control unit SA is formed of an output power calculation unit PA and an inverter selection unit CH, and the output power calculation unit PA determines the number of inverter devices to be started based on the output power value. The inverter selection unit CH inputs a start signal to each inverter device based on the determined start number.

  However, in the above-described prior art, the number of inverter devices started is determined based on the output power value, but no consideration is given to the startup order of the inverter devices. For this reason, when the output power value from the DC power source DC is low, for example, only a specific inverter device is operated, and when the other inverter device starts when the output power value increases, the specific inverter device Therefore, the output power value and the number of activations of the specific inverter device are increased.

  Moreover, the prior art described in Patent Document 1 calculates the integrated power value by integrating the output power for each inverter device, and selects only the number of startups determined in order from the inverter device having the smaller integrated power value, This is a method for equalizing the variation in the output power value of each inverter device.

JP 2000-305633 A

  In the above-described prior art, the number of inverter devices to be started is determined based on the output power value, but no consideration is given to the starting order of the inverter devices. Therefore, for example, only a specific inverter device is operated, and the output power amount of the specific inverter device and the number of times the inverter device is activated from a stop state to a start state are increased. When the output power value of the specific inverter device increases, the heat loss of the semiconductor elements forming the inverter circuit of the inverter device increases, and the deterioration of the semiconductor elements is promoted to shorten the life. Furthermore, when the number of activations increases, the number of opening and closing of a specific switch that opens and closes each inverter device connected to the DC power source DC increases, and the contact of the switch deteriorates as the number of opening and closing increases. The lifetime of the specific switch is shortened.

  In FIG. 5, the number of installed inverter devices is, for example, 10 units, the measurement period is 1 month, and the method described in Patent Document 1 is used to integrate the output power for each inverter device to obtain the integrated power value. It is the figure which calculated and selected only the starting number determined in order from the said inverter apparatus with few said integrated electric power values, and measured the variation with the integrated electric power value for every inverter apparatus, and the frequency | count of starting. From the measurement results shown in FIG. 5, the variation in the integrated power value of each inverter device is improved and made uniform. However, variations cannot be made uniform with respect to the number of activations of each of the inverter devices, and the contacts are deteriorated by a switch having a larger number of activations than the above, thereby shortening the life.

  From the above, when the target elements to be averaged are reduced to the integrated power value described in Patent Document 1, and averaged, the target elements are greatly averaged, but for the number of activations that are other target elements There is no desired effect. Then, this invention is providing the control method of the inverter apparatus which can solve the subject mentioned above.

  In order to solve the above-described problem, the first invention is configured such that a plurality of inverter devices are connected in parallel to a DC power source, an output power value from the DC power source is measured at a predetermined cycle, and an output for each cycle is performed. Determine the number of inverter devices to be started based on the power value, integrate the input power and output power of each inverter device to calculate the integrated power value for each inverter device, and reduce the integrated power value Inverter device control method that selects only the determined number of startups in order from the device, continues when the selected inverter device is started from the previous cycle, and changes to the started state when stopped In each of the inverter devices, the number of times that each inverter device has changed from the stopped state to the activated state is counted for each inverter device, Multiply the integrated power value for each inverter device by the integrated activation frequency value to calculate the integrated power activation frequency value, and select only the determined number of activations in order from the inverter device with the smallest integrated power activation frequency value. This is a method for controlling an inverter device.

  In a second aspect of the invention, the integrated power activation frequency value is calculated by integrating the activation time for each inverter device to calculate an integrated activation time value, and the integrated activation time value is used instead of the integrated power value. The method of controlling an inverter device according to claim 1.

  3. The inverter device according to claim 1, wherein the integrated power activation frequency value is calculated by adding the integrated power value and the integrated activation frequency value for each of the inverter devices. It is a control method.

  According to the first invention, the integrated power activation number value is calculated by multiplying the integrated power value and the integrated activation number value for each inverter device, and determined in order from the inverter device having the smallest integrated power activation number value. Starting only the number of startups is effective not only in averaging the integrated power value, but also in averaging the number of startups. The variation in the heat loss of the semiconductor elements forming the inverter circuit is made uniform and each inverter device is opened and closed. The variation in the number of times the switch is started can be made uniform, the life of the semiconductor element and the switch is made uniform, and a highly reliable power supply system is possible.

  According to the second invention, even if the integrated activation time value is replaced with the integrated power value, and the activation order of each inverter device is determined based on the value obtained by multiplying the integrated activation time value and the integrated activation frequency value. There are substantially the same effects as those of the first invention described above.

  According to the third aspect of the invention, the integrated power value and the integrated activation frequency value for each inverter device are added to obtain an integrated power activation frequency value, and each inverter device is activated based on the added integrated power activation frequency value. Even if the order is determined, there are substantially the same effects as those of the first invention.

[Embodiment 1]
FIG. 1 is a block diagram of a power supply system according to an embodiment of the present invention. In the figure, the same reference numerals as those in the block diagram of the prior art power supply system shown in FIG.

  In FIG. 1, the power supply system includes a direct current power source DC composed of solar cells, and a first inverter device PS1 to an nth inverter device PSn that are connected in parallel to the direct current power source DC and convert a direct current output into an alternating current output by an inverter. A power detection unit DS that detects an output power value from the DC power source DC, an output unit control unit SK that determines the number of startups and startup order of each inverter device based on the output power value, and the DC The switches SW1 to SWn that open and close the output power from the DC power source DC connected to the power source DC are formed.

  The power detection unit DS detects the output power from the DC power supply DC and inputs it to the unit control unit SK as an output power value. The number control unit SK is formed by an output power calculation unit PA, an accumulated power number unit MA, and an inverter selection unit CH. The output power calculation unit PA is an inverter device based on an output power value for each predetermined period. Determine the number of startups. The integrated power frequency unit MA calculates the integrated activation frequency value by counting the activation frequency for each inverter device based on the output power value from the DC power source DC and the number of inverter devices activated, and The integrated power value is calculated by integrating the input power and output for each inverter device, and then the integrated power activation number value for each inverter device is obtained by multiplying the integrated activation frequency value by the integrated power value. Calculate and store. And a selection signal is output in order from the thing with little integrated electric power starting value of each said inverter apparatus. The inverter selection unit CH selects the inverter device in descending order of the integrated power activation number value based on the determined activation number and the selection signal.

  The first inverter control circuit CO1 starts operation when a start signal is input from the unit control unit SK, closes the first switch SW1, supplies output power from the DC power source DC to the first inverter circuit PC1, and The first inverter circuit PC1 is activated to convert the DC voltage into an AC voltage and supply it to the system power supply AC. The second inverter control circuit CO2 and the nth inverter control circuit CON also perform the same operation as described above.

  Next, the operation of the present invention will be described with reference to the flowchart shown in FIG.

  In step 100 shown in FIG. 2, the power detector DS detects output power from the DC power source DC at a predetermined cycle and outputs it as an output power value.

  In step 200, the output power calculation unit PA determines the number of inverter devices to be started based on the output power value for each cycle.

  In step 300, the integrated power frequency unit MA sets a predetermined address for storing each data corresponding to each inverter device.

  In step 400, the accumulated power number unit MA calculates the accumulated activation number value by counting the number of times the inverter device has changed from the stopped state to the activated state based on the number of activated units determined for each cycle, and calculating the accumulated activation number value. Memorize at the address.

  In step 500, the integrated power frequency unit MA measures the input power or output power of each inverter device, integrates the measured output power, calculates the integrated power value for each inverter device, and stores it in a predetermined address. To do.

  In step 600, the integrated power activation count value is calculated by multiplying the integrated power value for each inverter device by the integrated activation count value, and the integrated power activation count value is stored at a predetermined address.

  In step 700, only the number of startups determined in order from the inverter device having the smallest cumulative power startup frequency value is selected.

  The routine is thus completed, and the same routine is repeated from the first step 100.

  In FIG. 3, the number of installed inverter devices is, for example, 10 units, the measurement period is set to one month, and the integrated power activation number value for each inverter device is calculated. It is the figure which measured the dispersion | variation in the integrated electric power value for every inverter apparatus, and an integrated starting frequency value when only the startup number determined in order was selected. From the measurement results shown in FIG. 3, when the inverter device is selected in the order from the smallest accumulated power activation number value of each inverter device, not only the variation of the accumulated power value of each inverter device but also the accumulated activation number value Uniform variation can be achieved.

  As described above, when the averaging target elements are narrowed down to one and averaged, the target elements are greatly averaged, but a desirable result cannot be obtained for other elements. On the other hand, if each inverter device is selected based on a value obtained by multiplying the integrated activation number value and the integrated power value of the present invention, the number of activations that has been a problem in the prior art can be made uniform. Become.

[Embodiment 2]
In the second embodiment of the present invention, only operations different from the flowchart shown in FIG. 2 of the first embodiment will be described.

  In step 500 (not shown), the startup time until the inverter device is changed from the startup state to the stop state is measured based on the number of startup units determined for each cycle, and the startup time value is integrated to calculate the integrated startup time value. Is calculated and stored at a predetermined address.

  In step 600, an integrated activation time value is calculated by multiplying the integrated activation time value and the integrated activation frequency value for each inverter device, and the integrated time activation frequency value is stored at a predetermined address.

  In step 700, only the number of activated units determined in order from the inverter device having the smallest accumulated time activation number value is selected.

[Embodiment 3]
In the third embodiment of the present invention, only operations different from the flowchart shown in FIG. 2 of the first embodiment will be described.

  In step 600 (not shown), the integrated power activation count value is calculated by adding the integrated power value and the integrated activation count value for each inverter device, and the integrated power activation count value is stored at a predetermined address.

  In step 700, only the number of startups determined in order is selected from the inverter device having the smallest cumulative power startup frequency value calculated by the addition.

It is a block diagram of the power supply system of the solar cell which concerns on embodiment of this invention. It is a flowchart explaining operation | movement of embodiment of this invention. It is the figure which measured the variation with the integrated electric power value of each inverter apparatus, and the integrated starting frequency value by making the element for averaging into an integrated power starting frequency value. It is a block diagram of the power supply system of the solar cell of a prior art. FIG. 6 is a diagram in which the variation between the integrated power value of each inverter device and the integrated startup frequency value is measured using the averaging target element as the integrated power value.

Explanation of symbols

AC AC system CH Inverter selection unit CO1 First inverter control circuit CO2 Second inverter control circuit CONn nth inverter control circuit DC DC power supply (solar cell)
DS power detection unit MA integrated power frequency unit PA output power calculation unit PC1 first inverter circuit PC2 second inverter circuit PCn nth inverter circuit PS1 first inverter device PS2 second inverter device PSn nth inverter device SA output control unit SK number Control part SW1 1st switch SW2 2nd switch SW3 3rd switch SW4 4th switch SWn-1 n-1 switch SWn nth switch

Claims (3)

  A plurality of inverter devices are connected in parallel to the DC power source, the output power value from the DC power source is measured in a predetermined cycle, and the number of inverter devices started is determined based on the output power value for each cycle, Calculate the integrated power value for each inverter device by integrating the input power or output power of each inverter device, select only the determined number of startups in order from the inverter device with the smallest integrated power value, When the selected inverter device is started from the previous cycle, it continues as it is, and when it is stopped, the inverter device changes from the stopped state to the activated state in the activated state. The integrated activation count value is calculated for each inverter device, and the integrated power value and the product for each inverter device are calculated. A control method for an inverter device, comprising: calculating an integrated power startup frequency value by multiplying the startup frequency value; and selecting only the determined startup number in order from the inverter device having the smallest integrated power startup frequency value .   The integrated power activation frequency value is calculated by integrating the activation time for each inverter device to calculate an integrated activation time value, and the integrated activation time value is used instead of the integrated power value. The control method of the inverter apparatus of 1. 2. The control method for an inverter device according to claim 1, wherein the integrated power activation number value is calculated by adding the integrated power value and the integrated activation number value for each inverter device.

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