JP6999510B2 - Power converter - Google Patents

Description

The present invention relates to a power converter.

A design life is defined for a power conversion device that converts input power into output power having desired characteristics. Since the design life is, for example, more than 10 years, which is relatively long, it is difficult for the owner or the like to monitor whether or not the design life has been reached. Therefore, when the power conversion device after installation reaches the design life, the device itself is required to notify the end of the design life.

In order to measure the elapsed time from the installation of the power conversion device, which is used for comparison with the design life, it is necessary to constantly supply power to the controller that manages the power conversion device. The power to the controller of the power converter is supplied from a part of the input power to be converted. For example, in a configuration in which a power converter is used for power conversion of photovoltaic power generation, which is a renewable energy, there is a period during which power generation is completely stopped at night or in unseasonable weather. Therefore, it is difficult to constantly supply power to the controller of the power converter. Therefore, in order to determine the life, it has been proposed to provide a storage battery for a backup power source in the power conversion device and supply power from the storage battery while the power generation is stopped (see Patent Document 1).

Japanese Unexamined Patent Publication No. 2014-171297

However, the design life of the power conversion device is generally longer than the life of the storage battery, and it is difficult to measure the elapsed time until the design life due to the stoppage of the power supply from the storage battery. Therefore, it may not be possible to correctly notify that the design life has been reached.

Therefore, an object of the present disclosure made in view of the above-mentioned problems of the prior art is to provide a power conversion device capable of more accurately notifying the arrival of the design life even if the electric power is not always supplied. be.

In order to solve the above-mentioned problems, the power conversion device from the first viewpoint is
A power supply circuit that converts input power to output power,
The unit operating time until the power supply circuit starts and stops is measured, the cumulative operating time is calculated by integrating the unit operating time, and when the cumulative operating time exceeds the life threshold value, its own life is notified. With a controller,
The controller updates the lifetime threshold based on the unit uptime.
The controller considers the lapse of the unit operating time as the lapse of one day and counts the number of elapsed days.
When the time until the next start-up after the stop of the power supply circuit unit is equal to or less than the interruption time threshold value, the controller determines the elapse of the unit operation time until the stop and the total time of the unit operation time after the start-up. The number of days elapsed is counted as the passage of one day .

As described above, the means for solving the present invention have been described as an apparatus, but the present invention can also be realized as a storage medium in which a method, a program, and a program substantially corresponding to these have been described, and the scope of the present invention. It should be understood that these are also included in.

According to the power conversion device according to the present disclosure configured as described above, it is possible to more accurately notify the arrival of the design life even if the power is not always supplied.

It is a functional block diagram which shows the schematic structure of the power conversion apparatus which concerns on one Embodiment. It is a 1st flowchart for demonstrating the life determination process executed by the controller of FIG. 2 is a second flowchart for explaining a life determination process executed by the controller of FIG. 1. It is a 3rd flowchart for demonstrating the life determination process executed by the controller of FIG.

Hereinafter, one embodiment will be described with reference to the drawings.

As shown in FIG. 1, the power conversion device 10 according to the embodiment is connected to the power source 11 on the input side. The power source 11 in this embodiment is, for example, a solar cell. The power conversion device 10 is connected to the commercial system 12 and the load device 13 on the output side.

The power conversion device 10 includes a power supply circuit unit 14, an interconnection relay 15, a storage unit 16, an acquisition unit 17, and a controller 18. In FIG. 1, the solid line connecting each functional block shows the flow of electric power. The broken line connecting each functional block indicates the flow of control signals or information to be communicated. The communication indicated by the broken line may be wired communication or wireless communication.

The power supply circuit unit 14 converts the input power from the power source 11 into the output power having desired characteristics. In the present embodiment, the power supply circuit unit 14 includes a transformer circuit such as a DC / DC converter and an orthogonal conversion circuit such as an inverter. The transformer circuit adjusts the voltage of the DC power acquired from the power source 11. The orthogonal conversion circuit converts voltage-adjusted DC power into AC power. The power supply circuit unit 14 has sensors such as a current sensor and a voltage sensor, and notifies the controller 18 of the detected value as the drive state of the power supply circuit unit 14. The detected value to be notified may be a DC voltage value or a DC current value of the transformer circuit, or may be an AC current value or an AC voltage value of the orthogonal conversion circuit. Further, the power supply circuit unit 14 may generate a voltage signal indicating that the vehicle is being driven and notify the controller 18.

In order to drive the power supply circuit unit 14, it is necessary that the voltage value and the current value of the input power are constant values or more. Therefore, the power supply circuit unit 14 stops driving when the voltage value or the current value of the input power becomes less than a certain value. The drive stop of the power supply circuit unit 14 may be automatically performed according to a decrease in the voltage value or the current value. Alternatively, the drive stop of the power supply circuit unit 14 may be performed by a command of the controller 18.

The interconnection relay 15 is provided between the power supply circuit unit 14 and the output end of the power conversion device 10, and switches whether or not the output power converted by the power supply circuit unit 14 can be output. The interconnection relay 15 switches the grid linkage and the grid disconnection based on the control command of the controller 18.

The storage unit 16 may be configured by using, for example, a semiconductor memory, a magnetic memory, an optical memory, or the like. The storage unit 16 has various information such as cumulative operating time, unit operating time, life threshold, design life, estimated elapsed days, interruption time threshold, update time, advance notice time, real time, and correction time, which will be described later. May be remembered.

The acquisition unit 17 acquires the real time to be recognized by the controller 18. The real time is, for example, the current date and time. The acquisition unit 17 may include, for example, a communication device that communicates with an external device by wire or wirelessly. The external device may be, for example, a server that monitors the power conversion device 10 or a power management device that manages the power of the consumer facility in which the power conversion device 10 is installed. The server and the power management device acquire the current date and time by timing their own timer or acquiring from the outside. Further, the acquisition unit 17 may include, for example, an input device such as a keyboard, a mouse, and a touch panel that detects an operation input such as a consumer.

In a configuration in which the acquisition unit 17 includes a communication device, the acquisition unit 17 may read the real time from the external device at an arbitrary time while the controller 18 is being driven, for example, when a predetermined time has elapsed after the start of the drive. Further, in a configuration in which the acquisition unit 17 includes a communication device, the acquisition unit 17 may acquire the real time that the external device registered to install the power conversion device 10 periodically notifies the power conversion device 10. Further, in a configuration in which the acquisition unit 17 includes an input device, the acquisition unit 17 may acquire the time input for the operation as real time. The real time may be acquired by a combination of a communication device and an input device.

The controller 18 includes one or more processors. Processors include general-purpose processors that load specific programs to perform specific functions, and dedicated processors that specialize in specific processing. Dedicated processors include application specific integrated circuits (ASICs). Processors include programmable logic devices (PLDs). The PLD includes an FPGA (Field-Programmable Gate Array). The controller 18 may be either a SoC (System on a Chip) in which one or a plurality of processors cooperate, or a SiP (System In a Package).

The controller 18 is driven by DC power supplied from the power source 11. The power supply circuit unit 14 is also driven by the same DC power, but the controller 18 can continue to drive even if the DC power drops and the power supply circuit unit 14 stops, and can maintain the drive until the power generation of the power source 11 stops. .. The power consumption of the controller 18 is relatively low, and it is general that the driving state can be maintained even when the power generated by the solar cell, which is the power source 11, is low, such as in cloudy weather and rainy weather. The controller 18 is stopped when the power supply is stopped due to the stop of the power generation of the power source 11. After the power supply from the power source 11 is stopped, the controller 18 may be able to continue driving for several minutes to ten and several minutes using the power stored in the capacitor provided in the power supply circuit unit 14.

The controller 18 periodically acquires the detection value of the sensor of the power supply circuit unit 14 described above while the DC power is input. The controller 18 grasps the drive state of the power supply circuit unit 14 based on the acquired detection value. In the configuration in which the controller 18 has the control function of the power supply circuit 14, the power conversion of the power supply circuit unit 14 is controlled based on the detected value.

The controller 18 recognizes the start and stop of the power supply circuit unit 14 based on the detected value. For example, the controller 18 can acquire the current value on the AC output side of the power supply circuit unit 14, and can recognize the activation of the power supply circuit unit 14 when the current value exceeds the threshold value for operation determination. Further, for example, the controller 18 can recognize the stop of driving of the power supply circuit unit 14 when the current value is equal to or less than the threshold value. The controller 18 has a timer, and measures a unit operating time, which is a continuous operating time until the power supply circuit unit 14 is started and stopped. In the configuration where the power source 11 is a solar cell, the unit operating time is the power supply per day, except when the power generated temporarily during the day drops and recovers, such as in the evening. It is estimated that the circuit unit 14 has been in operation for a certain period of time.

The controller 18 calculates the cumulative operating time by integrating the measured unit operating times. The cumulative operating time is the total operating time of the power supply circuit unit 14 from the time when the power conversion device 10 is installed on the consumer site to the present. The initial value of cumulative operating time is zero. Specifically, when the controller 18 measures the unit operating time, the controller 18 reads the cumulative operating time from the storage unit 16. The controller 18 updates the cumulative operating time by adding the newly measured unit operating time to the read cumulative operating time. The controller 18 stores the updated cumulative operating time in the storage unit 16. The controller 18 may store the unit operating time in the storage unit 16 each time a new measurement is performed.

The controller 18 reads the life threshold value from the storage unit 16 for comparison. The life threshold is the cumulative operating time estimated to be accumulated when the design life of the power conversion device 10 has elapsed. The design life is a predetermined time based on the useful life of each component constituting the power conversion device 10. In order to calculate the life threshold value, an estimated value of the operating time of the power supply circuit unit 14 per unit time such as one day is predetermined. For example, in the present embodiment, when the design life is 15 years and the estimated operating time is 12 hours / day, the life threshold is calculated as 12 × 365 × 15 = 65,700 hours.

The controller 18 compares the cumulative operating time with the life threshold. When the cumulative operating time exceeds the life threshold value, the controller 18 notifies the consumer of the arrival of its own life. The controller 18 may notify the end of life in various ways. For example, the controller 18 generates a notification signal for notifying the end of life and transmits it to the remote controller of the power conversion device 10, the power management device, or the like, thereby passing through the display unit of the remote controller or the power management device. It may notify the end of its own life.

The controller 18 updates the life threshold based on the unit operating time. Specifically, the controller 18 updates the life threshold value at a time estimated to be integrated when the power supply circuit unit 14 is driven to the design life in a unit operating time. The controller 18 may update the life threshold by various calculation methods.

For example, the controller 18 may update the life threshold by substituting a value obtained by multiplying the unit operating time by the design life. Specifically, when the unit operating time is 9 hours, the controller 18 updates the life threshold to 49,275 hours calculated by 9 × 365 × 15.

Further, for example, the controller 18 sets the life threshold value by multiplying the design life by the difference obtained by subtracting the unit operating time from the estimated value of the operating time of the power supply circuit unit 14 per day and subtracting the product of multiplication from the life threshold value. You may update. Specifically, when the unit operating time is 9 hours, the difference is calculated as 12-9 = 3 hours by subtracting the unit operating time from the estimated value of the operating time per day. By multiplying the difference by the design life, the product of multiplication is calculated as 3 × 365 × 15 = 16,425 hours. Therefore, the lifetime threshold is updated to 65,700-16,425 = 49,275 hours.

When the estimated value of the operating time is longer than the unit operating time, as described above, the update of the life threshold is a change from 65,700 hours to 49,275 hours, and the update is in the direction of decrease. On the other hand, when the estimated value of the operating time is shorter than the unit operating time, the update of the life threshold value may be in the direction of increase. For example, if the estimated daily working time and the unit working time are 9 hours and 12 hours, respectively, the lifetime threshold update is a change from 49,275 hours to 65,700 hours.

Further, for example, the controller 18 calculates the total of the unit operating hours in time units such as January or one year, which will be described later, from the estimated value of the operating time of the power supply circuit unit 14 per time unit. The lifetime threshold may be updated by multiplying the subtracted difference by the design lifetime and subtracting the product of multiplications from the lifetime threshold. Specifically, in a configuration in which one year is an hour unit, when the unit operating time is 9 hours, the total value of the unit operating time in the hour unit of 3,285 hours is set as the operating time per day in the hour unit. The difference obtained by subtracting the estimated value of 4,380 hours is 1,095 hours. The product of multiplication by multiplying the difference by the design life is calculated as 15 × 1,095 = 16,425 hours. Therefore, the lifetime threshold is updated to 65,700-16,425 = 49,275 hours.

Further, for example, the controller 18 may update the life threshold value by multiplying the life threshold value by the ratio obtained by dividing the unit operating time by the estimated value of the operating time of the power supply circuit unit 14 per day. Specifically, when the unit operating time is 9 hours, the ratio obtained by dividing the unit operating time by the estimated value of the operating time per day is calculated as 9/12 = 0.75. Therefore, the lifetime threshold is updated to 65,700 × 0.75 = 49,275 hours.

For example, each time the controller 18 measures the unit operating time, the controller 18 considers the lapse of the unit operating time as the lapse of one day and calculates the estimated number of elapsed days. Further, even if the power supply circuit unit 14 is stopped, the controller 18 has an input of DC power sufficient to continue driving the controller 18 from the power source 11 until the next start-up after the power supply circuit unit 14 is stopped. If the time is measured and the measured time is less than or equal to the interruption time threshold, the estimated number of days elapsed is considered to be the elapsed time of the total time of the unit operating time until the stop and the unit operating time after the activation. May be calculated. The interruption time threshold is the maximum time in which the electric power generated by the power source 11 is assumed to temporarily interrupt the drive of the power supply circuit unit 14 in a day, and is, for example, 6 hours.

The controller 18 may use a unit working time corresponding to a single estimated elapsed day or a unit working time corresponding to a plurality of estimated elapsed days to update the life threshold. The estimated number of elapsed days is the number of days of elapsed time from the installation of the power conversion device 10 in the consumer facility to the present. The initial value of the estimated elapsed days is zero.

The controller 18 may calculate an average value of a plurality of unit operating hours in a configuration using a unit operating time of a plurality of estimated elapsed days, and update the life threshold value using the average value. For example, if the unit operating time is measured and stored at different times (days) and the estimated number of elapsed days is 7 days, the average value obtained by dividing the total value of the stored unit operating time by 7 days is used as the unit operation. The life threshold may be updated using it as time. The controller 18 may use a plurality of estimated elapsed days that are substantially equal to an integral multiple of one year for updating the life threshold value.

Each time the controller 18 calculates the cumulative operating time, the controller 18 may read the update time from the storage unit 16 and compare them. The update time is the time for updating the life time after the power conversion device 10 is installed. The initial value of the update time is predetermined to be shorter than the initial value of the life threshold value. The initial value of the update time is 43,800 hours, which is, for example, 2/3 times the life threshold in the configuration where the life threshold is 65,700 hours. When the controller 18 determines that the cumulative operating time has exceeded the update time, the controller 18 updates the life threshold value. The controller 18 may determine whether or not the cumulative operating time exceeds the update time based on the estimated number of elapsed days. For example, the controller 18 may compare the continuous elapsed time corresponding to the update time, for example 10 years, with the estimated elapsed days.

After updating the life threshold value, the controller 18 may calculate the next update time by adding a predetermined update addition time to the current update time and store it in the storage unit 16. Alternatively, the controller 18 may read the shortest update time, which is equal to or longer than the cumulative operating time, from the plurality of update times stored in the storage unit 16 in advance.

The controller 18 may read the advance notice time from the storage unit 16 each time the cumulative operating time is calculated and compare them. The notice time is a time for notifying the end of life after the installation of the power conversion device 10. The advance notice time is predetermined to be shorter than the initial value of the life threshold. The notice time is, for example, 52.5600 hours to 56,940 hours, which is 4/5 times to 13/15 times the life threshold in the configuration where the life threshold is 65,700 hours. When the controller 18 determines that the cumulative operating time has exceeded the notice time, the controller 18 announces the time of the life of the power conversion device 10. The controller 18 may announce the end of life in various ways, similar to the notification of the end of life. The controller 18 may determine whether or not the cumulative operating time exceeds the notice time based on the estimated number of elapsed days. For example, the controller 18 may compare the continuous elapsed time corresponding to the advance notice time, for example, 12 to 13 years, with the estimated elapsed days. In the configuration in which the expiration date is announced a plurality of times, the controller 18 calculates the next advance notice time by adding a predetermined addition time to the advance announcement time after the announcement of the expiration date, and stores the storage unit 16. You may memorize it.

The controller 18 may estimate the time to reach the end of life, which is the time of the foretold life, based on the cumulative operating time and the life threshold. For example, the controller 18 estimates the elapsed time from the present to the time when the life of the power conversion device 10 is reached by dividing the difference obtained by subtracting the cumulative operating time from the life threshold value by the average value of the unit operating time. good. The life threshold used for estimation may be an initial value or an updated value.

When the acquisition unit 17 acquires the real time, the controller 18 stores the real time and the estimated elapsed days calculated when the real time is acquired in the storage unit 16. The controller 18 may correct at least one of the lifetime threshold and the cumulative operating time using the real-time time intervals acquired at different times.

For example, to correct the life threshold, the controller 18 calculates the converted design life based on the error between the estimated elapsed days and the actual time interval. The converted design life is the number of elapsed days estimated to be calculated when the predetermined design life is reached. More specifically, the controller 18 reads out the two estimated elapsed days associated with the two real times acquired at different times from the storage unit 16 together with the two real times. Next, the controller 18 calculates the time interval between the two real-time reads and the two estimated elapsed days. Next, the controller 18 calculates the actual measurement error that occurred during the time interval of the estimated elapsed days by subtracting the time interval of the estimated elapsed days from the time interval of the actual time. Next, the controller 18 calculates the unit error by dividing the measured error by the time interval in real time. Next, the controller 18 calculates the prediction error by multiplying the unit error by the difference obtained by subtracting the time interval in real time from the design life. Next, the controller 18 calculates the conversion error by summing the actual measurement error and the prediction error. Next, the controller 18 calculates the converted design life by subtracting the conversion error from the design life. When the conversion design life is calculated, the controller 18 stores the corrected conversion design life in the storage unit 16.

The controller 18 corrects the life threshold by using the converted design life when updating the life threshold described above. For example, in the method of updating the life threshold value by multiplying the unit operating time and the design life, which is given as an example of the above-mentioned method of updating the life threshold value, the converted design life is used as the unit operation instead of the predetermined and stored design life. By multiplying by time, the life threshold is corrected.

Specifically, the design life is 15 years, the acquired actual time is 0 days and 3,700 days, and the estimated elapsed days associated with 3,700 days are 3,650 days. The correction when the unit operating time is 9 hours will be described below. In this case, the controller 18 calculates the actual measurement error as 50 days by subtracting the estimated elapsed days of 3,650 hours from the real time interval of 3,700 days. The controller 18 calculates the unit error as 0.0135 by dividing the measured error of 50 days by the estimated elapsed days of 3,650 days. The controller 18 has a prediction error by multiplying 1,775 hours, which is the difference obtained by subtracting the real time interval (3,700 hours) from the design life (5,475 hours), by 0.0135, which is a unit error. Is calculated as 23.9 (= 24) days. The controller 18 calculates the conversion error as 74 days by summing the measured error of 50 days and the prediction error of 24 days. The controller 18 calculates the converted design life as 5,401 days by subtracting the conversion error of 74 days from the design life of 5,475 hours. The controller 18 calculates the corrected life threshold value as 48,609 hours by multiplying the unit operating time of 9 hours by the converted design life of 5,401 days.

Also, for example, to correct at least one of the life threshold and the cumulative uptime, the controller 18 calculates the total uptime miscalculation by multiplying the conversion error by the unit uptime instead of subtracting the conversion error from the design life. You may. In the configuration for calculating the total error of the operating time, the controller 18 corrects the life threshold value by subtracting the total error from the life threshold value. Alternatively, the controller 18 corrects the cumulative uptime by adding the total error to the cumulative uptime. Alternatively, the controller 18 corrects the lifetime threshold and cumulative operating time by subtracting part of the total error from the lifetime threshold and adding the rest to the cumulative operating time.

Specifically, the design life is 15 years, the acquired actual time is 0 days and 3,700 days, and the estimated elapsed days associated with 3,700 days are 3,650 days. The correction when the unit operating time is 9 hours will be described below. In this case, the controller 18 calculates the conversion error as 74 days, as in the calculation of the conversion design life. The controller 18 calculates the total error of the operating time as 666 hours by multiplying the conversion error of 74 days by the unit operating time of 9 hours. The controller 18 calculates the life threshold as 48,609 hours by subtracting the total error of 666 hours from the life threshold of 49,275 (= 15 × 365 × 9) hours. Alternatively, the controller 18 corrects by adding a total error of 666 hours to the current cumulative operating time instead of correcting the life threshold. Alternatively, the controller 18 calculates the life threshold as 48,942 hours by subtracting 333 hours, which is part of the total error, from the life threshold of 49,275 hours, and the remaining of the total error in the current cumulative operating time. Add 333 hours to make corrections.

Further, for example, in order to correct the life threshold value, the controller 18 corrects the unit operating time to be averaged by replacing the estimated elapsed days with the time interval of the real time. More specifically, the controller 18 reads from the storage unit 16 all unit operating times measured during the two estimated elapsed days associated with the two real times acquired at different times. Next, the controller 18 totals all the read unit operating hours. The controller 18 then corrects the unit operating time to average the total value by dividing the real-time time interval instead of the estimated elapsed days. When the unit operating time is corrected, the controller 18 stores the corrected unit time interval in the storage unit 16. The controller 18 corrects the life threshold by using the corrected unit operating time when updating the life threshold described above.

Specifically, the design life is 15 years, the acquired actual time is 0 days and 3,700 days, and the estimated elapsed days associated with 3,700 days are 3,650 days. The correction when the total value of the unit operating hours up to the estimated elapsed days is 32,850 hours will be described below. In this case, the controller 18 calculates 8.88 hours, which is obtained by dividing the total value of 32,850 hours by 3,700 days instead of 36,500 days, as the corrected unit operating time. For example, the controller 18 calculates the corrected life threshold value as 48,618 hours by multiplying the design life of 15 years by the corrected unit operating time of 8.88 hours.

Each time the controller 18 calculates the cumulative operating time, the controller 18 may read the correction time from the storage unit 16 and compare it with the cumulative operating time. The correction time is the time for correcting the estimated elapsed days after the power conversion device 10 is installed. The initial value of the correction time is predetermined to be shorter than the initial value of the life threshold value. The initial value of the correction time is 43,800 hours, which is, for example, 2/3 times the life threshold in the configuration where the life threshold is 65,700 hours. When the controller 18 determines that the cumulative operating time has exceeded the correction time, the controller 18 corrects the estimated elapsed days.

After the first correction, the controller 18 may similarly correct the estimated elapsed days while gradually shortening the execution interval as compared with the initial correction time. For example, the controller 18 corrects the estimated number of elapsed days every six months, in other words, every 2,190 hours obtained by multiplying the life threshold by 1/30 after the cumulative operating time of 43,800 hours, which is 10 years after installation. After the cumulative operating time of 56,940 hours, which is 13 years after installation, is corrected every month, in other words, every 365 hours, which is 1/180 times the life threshold. good.

The controller 18 may calculate the next correction time by adding a predetermined correction addition time to the current correction time after the correction of the estimated elapsed days, and store it in the storage unit 16. Alternatively, the controller 18 may read the shortest correction time, which is equal to or longer than the cumulative operating time, from the plurality of correction times stored in the storage unit 16 in advance.

When the cumulative operating time exceeds the life threshold value, the controller 18 may communicate with an external device and request permission for the life notification. In such a configuration, the controller 18 may notify the above-mentioned life when permission is obtained.

The controller 18 may cause the interconnection relay 15 to perform system disconnection when the cumulative operating time exceeds the life threshold value, when the estimated elapsed days exceed the design life, or when the life is notified.

Next, the life determination process executed by the controller 18 in the present embodiment will be described with reference to the flowcharts of FIGS. 2 to 4. The life determination process starts when DC power capable of starting the controller 18 is supplied from the power source 11. The life determination process ends when the DC power supplied from the power source 11 is less than the DC power that can start the controller 18.

In step S100, the controller 18 resets the interruption determination flag to 0. The interruption determination flag is an index for distinguishing whether or not the drive stop of the power supply circuit unit 14 is the first drive stop after the start start of the controller 18. After the reset, the process proceeds to step S101.

In step S101, the controller 18 reads the cumulative operating time, the estimated elapsed days, the life threshold value, the update time, the advance notice time, and the correction time from the storage unit 16. After reading, the process proceeds to step S102.

In step S102, the controller 18 acquires the detected value from the power supply circuit unit 14. After acquiring the detected value, the process proceeds to step S103.

In step S103, the controller 18 determines whether or not the power supply circuit unit 14 is activated based on the detection value acquired in step S102. If the acquired detected value is a positive value, the controller 18 determines that it is started, and if the detected value is zero, it determines that it is stopped. If not started, the process returns to step S102. If so, the process proceeds to step S104.

In step S104, the controller 18 starts measuring the unit operating time. When the measurement is started, the process proceeds to step S105.

In step S105, the controller 18 acquires the detected value from the power supply circuit unit 14. After acquiring the detected value, the process proceeds to step S106.

In step S106, the controller 18 determines whether or not the drive of the power supply circuit unit 14 is stopped based on the detection value acquired in step S104. If not stopped, the process returns to step S105. If stopped, the process proceeds to step S107.

In step S107, the controller 18 ends the measurement of the unit operating time that started the measurement in step S104. When the measurement is finished, the process proceeds to step S108.

In step S108, the controller 18 updates the cumulative operating time by adding the unit operating time for which the measurement is completed in step S107 to the cumulative operating time read in step S101. After the update, the process proceeds to step S109.

In step S109, the controller 18 determines whether or not the interruption determination flag is 0. If 0, the process proceeds to step S110. If not 0, the process proceeds to step S111.

In step S110, the controller 18 sets the interruption determination flag to 1. After the setting, the process proceeds to step S112.

In step S111, whether or not the elapsed time between the start of the measurement of the unit operating time that most recently completed the measurement and the stop of the measurement of the previous unit operating time is less than the interruption time threshold value in step S111. To determine. If the elapsed time is greater than or equal to the interruption time threshold, the process proceeds to step S112. If the elapsed time is less than the interruption time threshold, the process proceeds to step S113.

In step S112, the controller 18 updates the estimated elapsed days by adding 1 to the estimated elapsed days read in step S101. After the update, the process proceeds to step S113.

In step S113, the controller 18 determines whether or not the real time is acquired via the acquisition unit 17. If the real time is acquired, the process proceeds to step S114. If no real time has been obtained, the process proceeds to step S115.

In step S114, the controller 18 stores the estimated elapsed days updated in step S112 and the acquired real time in the storage unit 16. The association is mainly done in chronological order. After storage, the process proceeds to step S115.

In step S115, the controller 18 determines whether or not the cumulative operating time updated in step S108 exceeds the correction time. If the cumulative uptime exceeds the correction time, the process proceeds to step S116. If the cumulative operating time is less than or equal to the correction time, the process proceeds to step S120.

In step S116, the controller 18 calculates the next correction time of the correction time read in step S101. The controller 18 stores the calculated next correction time in the storage unit 16. After calculating the next correction time, the process proceeds to step S117. In the configuration in which the next correction time is read from the storage unit 16 from the plurality of correction times stored in the storage unit 16, information specifying the correction time to be read as the next correction time is stored. It is written in part 16.

In step S117, the controller 18 determines whether or not a plurality of different real times are stored in the storage unit 16. If a plurality of different real times are stored, the process proceeds to step S118. If a plurality of different real times are not stored, the process proceeds to step S120.

In step S118, the controller 18 is between the latest real time stored in the storage unit 16 and the real time first acquired after the lapse of the previous correction time or the first acquired real time after installation. Calculate the time interval. The controller 18 calculates the time interval between the latest real time and the first real time acquired after installation for the first correction time of the estimated elapsed days. After the calculation, the process proceeds to step S119.

In step S119, the controller 18 calculates the converted design life using the time interval calculated in step S118. After the correction, the process proceeds to step S120. As described above, the controller 18 may correct at least one of the life threshold value and the cumulative operating time, or correct the estimated elapsed days, instead of calculating the converted design life.

In step S120, the controller 18 determines whether or not the cumulative operating time updated in step S108 exceeds the update time. If the cumulative uptime exceeds the update time, the process proceeds to step S121. If the cumulative uptime is less than or equal to the update time, the process proceeds to step S124.

In step S121, the controller 18 calculates the next update time of the update time read in step S101. The controller 18 stores the calculated next update time in the storage unit 16. After calculating the next update time, the process proceeds to step S122. In the configuration in which the next update time is read from the storage unit 16 from the plurality of update times stored in the storage unit 16, information specifying the update time to be read as the next update time is stored. It is written in part 16.

In step S122, the controller 18 calculates an average value of unit operating hours based on the cumulative operating time updated in step S108 and the estimated number of elapsed days stored in the storage unit 16. After the calculation, the process proceeds to step S123.

In step S123, the controller 18 updates the life threshold value based on the life threshold value read in step S101 and the average value of the unit operating time calculated in step S122. The controller 18 stores the updated life threshold value in the storage unit 16. After updating the lifetime threshold, the process proceeds to step S124.

In step S124, the controller 18 determines whether or not the cumulative operating time updated in step S108 exceeds the advance notice time. If the cumulative uptime exceeds the notice time, the process proceeds to step S125. In the present embodiment, the number of advance notices is one, and the controller 18 updates the advance notice time to a time equal to or longer than the life threshold value before proceeding to step S124. If the cumulative uptime is less than or equal to the notice time, the process proceeds to step S127.

In step S125, the controller 18 calculates the next notice time of the notice time read in step S101. The controller 18 stores the calculated next notice time in the storage unit 16.

In step S126, the controller 18 estimates the life arrival time based on the cumulative operating time updated in step S108 and the life threshold stored in the storage unit 16. After estimation, the process proceeds to step S127.

In step S127, the controller 18 foretells the time of life estimated in step S126. After the notice, the process proceeds to step S128.

In step S128, the controller 18 determines whether or not the cumulative operating time updated in step S108 exceeds the life threshold value. If the cumulative uptime exceeds the lifetime threshold, the process proceeds to step S129. If the cumulative operating time is less than or equal to the lifetime threshold, the process returns to step S102.

In step S129, the controller 18 asks the external device for permission to notify the life threshold value. After the query, the process proceeds to step S130.

In step S130, the controller 18 determines whether or not the permission for the inquiry in step S129 has been obtained. If permission is obtained, the process proceeds to step S131. If no permission is obtained, the process returns to step S102. The controller 18 may automatically determine whether or not it is permitted after waiting for a predetermined waiting time.

In step S131, the controller 18 notifies that it has reached the end of its life. After the notification, the process proceeds to step S132.

In step S132, the controller 18 causes the interconnection relay 15 to be system-disconnected. After the system dissociation, the process returns to step S102.

The power conversion device 10 of the present embodiment having the above configuration is configured to notify its own life when the cumulative operating time exceeds the life threshold, and updates the life threshold based on the unit operating time. In other power conversion devices to which power is not always supplied, the arrival at the design life is determined by comparing the cumulative operating time obtained by integrating the operating time of the power supply circuit unit 14 with the life threshold value corresponding to the design life. The configuration is conceivable. The life threshold value corresponding to the design life can be calculated based on the generally assumed daily operating time of the power supply circuit unit 14 and the design life. However, the operating time of the power supply circuit unit 14 per day varies depending on the installation area and installation posture of the power source 11. Therefore, if a fixed life threshold is used, the difference between the elapsed time when the actual cumulative operating time actually reaches the life threshold and the design life can be large. On the other hand, in the power conversion device 10 having the above configuration, since the life threshold value is updated using the unit operating time, the life threshold value according to the installation status of the power source 11 can be used. Therefore, the power conversion device 10 can more accurately notify the arrival of the design life even if the power is not always supplied. Further, since the power conversion device 10 can be manufactured by updating the software with respect to the existing power conversion device, it is possible to prevent the device from becoming complicated and the manufacturing cost from being extremely increased.

Further, in the power conversion device 10 of the present embodiment, the elapsed days are counted by regarding the elapsed time of the unit operating time as one day. With such a configuration, the power conversion device 10 can improve various functions of determining the life of the power conversion device 10.

Further, in the power conversion device 10 of the present embodiment, when the time interval until the next start-up after the power supply circuit unit 14 is stopped is equal to or less than the interruption time threshold value, the unit operating time until the stoppage and the unit after the start-up are performed. The number of elapsed days is counted by regarding the passage of the total operating time as the passage of one day. Even during power generation of the power source 11 in a configuration in which the power source 11 is a solar cell, the operation of the power supply circuit unit 14 may be interrupted due to natural factors such as rainfall and snowfall. If the operation of the power supply circuit unit 14 is interrupted during the same day, the estimated number of elapsed days may be added each time the operation is performed. On the other hand, in the power conversion device 10 having the above configuration, even if the operation of the power supply circuit unit 14 is interrupted during the same day, the elapsed unit operating time measured before and after the interruption can be counted as the number of elapsed days in one day. Therefore, in the power conversion device 10, the accuracy of the estimated elapsed days is improved as long as the power capable of operating the controller 18 is supplied, so that various functions of determining the life of the power conversion device 10 can be further improved.

Further, in the power conversion device 10 of the present embodiment, the life threshold value is updated based on the average value of the unit operating hours corresponding to a plurality of days. With such a configuration, in the power conversion device 10, it is possible to prevent the life threshold value from being updated using an abnormal value of the unit operating time that may vary from measurement to measurement. For example, when the unit operating time of one point arbitrarily selected is 2 hours, which is extremely shorter than the normal time due to bad weather or the like, the updated life threshold value may be shorter than the actual design life. On the other hand, in the power conversion device 10 of the present embodiment, since the average value of the unit operating time can be calculated, the life threshold value more suitable for the design life can be calculated.

Further, in the power conversion device 10 of the present embodiment, the number of days for averaging the unit operating time is substantially equal to an integral multiple of one year. In a configuration in which the power source 11 is a solar cell, the operating time of the power supply circuit unit 14 may vary depending on the sunshine hours. The hours of sunshine can vary from season to season, such as in summer and winter. On the other hand, in the power conversion device 10 having the above configuration, by averaging the unit operating hours corresponding to the elapsed days that are integral multiples of one year, the factors of fluctuation of the unit operating hours depending on the season can be reduced. Therefore, in the power conversion device 10, a life threshold value more suitable for the design life can be calculated.

Further, in the power conversion device 10 of the present embodiment, when it is determined that the cumulative operating time exceeds the initial update time, the first update of the life threshold value is performed. Generally, the design life is relatively long, and the life threshold is generally set to a large value accordingly. Further, if the life threshold value is set at least once before the cumulative operating time reaches the life threshold value, the time when the design life is reached can be determined more accurately. Therefore, in the power conversion device 10 having the above configuration, the initial update time is set in advance at a value lower than the estimated minimum value of the daily operating time, so that the power conversion device 10 is updated at an unnecessary frequency. Instead, the life threshold can be updated at any location where the power source 11 is expected to be installed.

Further, in the power conversion device 10 of the present embodiment, when it is determined that the cumulative operating time exceeds the notice time, the time of the life is announced. With such a configuration, the power conversion device 10 may make the user aware of repair or replacement of the power conversion device 10 before the end of its life.

Further, in the power conversion device 10 of the present embodiment, at least one of the life threshold value and the cumulative operating time is corrected by using the time interval of the real time acquired at different times. With such a configuration, in the power conversion device 10, the error of the deviation between the actual time interval and the interval of the estimated elapsed days is corrected, so that the arrival of the design life of the power conversion device 10 can be notified more accurately. ..

Further, in the power conversion device 10 of the present embodiment, when it is determined that the initial correction time has been exceeded, the first correction is performed, and after the first correction, the correction of the elapsed days is repeated while gradually shortening the execution interval. With such a configuration, in the power conversion device 10, the calculation load of the controller 18 for a long period of time can be reduced, and the accuracy of the estimated elapsed days can be improved as the notification time approaches. Therefore, in the power conversion device 10, since the average value of the unit operating time can be calculated using the estimated elapsed days with improved accuracy, the life threshold value more suitable for the design life can be calculated.

Although the present invention has been described with reference to the drawings and examples, it should be noted that those skilled in the art can easily make various modifications and modifications based on the present disclosure. Therefore, it should be noted that these modifications and modifications are included in the scope of the present invention.

10 Power converter 11 Power source 12 Commercial system 13 Load equipment 14 Power supply circuit section 15 Interconnect relay 16 Storage section 17 Acquisition section 18 Controller

Claims (7)

A power supply circuit that converts input power to output power,
The unit operating time until the power supply circuit unit starts and stops is measured, the cumulative operating time is calculated by integrating the unit operating time, and when the cumulative operating time exceeds the life threshold value, its own life is determined. Equipped with a controller to notify
The controller updates the lifetime threshold based on the unit uptime.
The controller considers the lapse of the unit operating time as the lapse of one day and counts the number of elapsed days.
When the time until the next start-up after the stop of the power supply circuit unit is equal to or less than the interruption time threshold value, the controller determines the elapse of the unit operation time until the stop and the total time of the unit operation time after the start-up. Count the number of days that have passed, assuming that one day has passed.
Power converter. In the power conversion device according to claim 1 ,
The controller is a power conversion device that updates the life threshold value based on the average value of the unit operating hours corresponding to a plurality of days. In the power conversion device according to claim 2 ,
A power converter in which the plurality of days is substantially equal to an integral multiple of one year. The power conversion device according to any one of claims 1 to 3 .
When the controller determines that the cumulative operating time exceeds the initial value of the update time shorter than the life threshold value, the power conversion device performs the first update of the life threshold value. In the power conversion device according to any one of claims 1 to 4 .
When the controller determines that the cumulative operating time exceeds the notice time shorter than the life threshold value, the controller is a power conversion device that announces the cumulative operating time and the time of the life based on the life threshold value. The power conversion device according to any one of claims 1 to 3 .
Further, an acquisition unit for acquiring the real time to be recognized by the controller is provided.
The controller is a power conversion device that performs correction of at least one of the life threshold and the cumulative operating time by using real-time time intervals acquired at different times. In the power conversion device according to claim 6 ,
When the controller determines that the cumulative operating time exceeds the initial correction time shorter than the life threshold value, the first correction is performed, and after the first correction, the correction is performed while gradually shortening the execution interval. Repeated power converter.

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