JP2006187071A - Method of operating inverter device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method of operating an inverter device, which leads to the improvement of a power system by leveling the life of each inverter device. <P>SOLUTION: In the method of operating an inverter device, which decides the number of started-up units, based on the output power value in every cycle, out of a plurality of inverter devices and selects each inverter device in order of smaller accumulated power values, a master inverter device is selected at random from the above selected inverter device, and the master device decides the number of started-up inverter devices, based on the output power values in n cycles, and selects the number of started-up units which is decided in order of smaller combination values of at least one or more among the accumulated power value, the number of accumulated times of startup, and the accumulated starting times of the inverter devices, and selects the next master inverter device at random from among these selected inverter devices, and consequently it performs the same treatment as stated above also in (n+1) cycles. <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. The present invention relates to a technique for switching a master inverter device when determining the number of starting devices.

  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. And a power detector DS for detecting an output power value from the DC power source DC, and a first switch SW1 to an n-th switch SWn for opening and closing each inverter device connected to the DC power source DC. ing.

  In FIG. 4, the first inverter device PS1 is formed by a first inverter control circuit CW1 and a first inverter circuit PC1, and the second inverter device PS2 is formed by a second inverter control circuit CW2 and a second inverter circuit PC2. The n-th inverter device PSn is formed of an n-th inverter control circuit CWn and an n-th inverter circuit PCn.

  In the power supply system, based on a predetermined law (for example, an inverter device having a small integrated power value is a master inverter device), the first inverter device PS1 is a master inverter device, and the second inverter device PS2 to the nth inverter device PSn. Is a slave inverter device. Subsequently, the first inverter control circuit CW1 of the first inverter device PS1, which is a master inverter device, determines the number of inverter devices to be started based on the output power value from the DC power source DC and has a low integrated power value. Only the determined number of startups is selected in order from the device.

  Subsequently, the first inverter control circuit CW1 of the first inverter device PS1, which is the master inverter device, activates each of the selected slave inverter devices. In response to the activation, the inverter control circuit of each activated slave inverter device activates the inverter circuit and closes the switch.

  Next, the switching operation of the master inverter device will be described with reference to the switching timing diagram of the master inverter device shown in FIG. At time t = t1 shown in FIG. 5, the master inverter device detects the output power value from the DC power source DC and determines that the solar radiation starts when the output power value exceeds a predetermined reference power value, and outputs power from the DC power source DC. The number of inverter devices to be activated is determined based on the value, and each slave inverter device is activated in the order from the smallest integrated power value. Next, at time t = t2, when the output power value from the DC power source DC is detected and falls below the reference power value, it is determined that the solar radiation has ended, and the master inverter device stops starting each selected slave inverter device. The device having the smallest integrated power value of each slave inverter device is set as the next master inverter device.

  At time t = t3, the output power value from the DC power source DC is detected by the next master inverter device set on the previous day, and when it exceeds the reference power value, it is determined that the solar radiation starts again. The number of inverter devices to be activated is determined based on the output power value from the DC, and each slave inverter device is activated in the order of decreasing integrated power value. Next, at time t = t4, when the output power value from the DC power source DC is detected and becomes equal to or lower than the reference power value, it is determined that the solar radiation has ended, and the master inverter device stops starting each slave inverter device and The device with the smallest integrated power value of the slave inverter device is set again as the next master inverter device. Thereafter, the same processing as above is repeated.

  In the above-described prior art, the switching time of the master inverter device is performed in units of one day. Patent Document 1 discloses a technique in which a master inverter device is switched on a daily basis.

JP 2000-305633 A

  In the above-described prior art, the switching timing of the master inverter device is when the output power value from the DC power supply has decreased to a predetermined reference output value or less, and the time for the master inverter device to switch to the next master inverter device is basically Therefore, it becomes a unit of one day.

  As described above, the master inverter device detects the output power value from the DC power source and determines that the solar radiation starts when the power value exceeds a predetermined reference power value, and starts the number of inverter devices based on the output power value from the DC power source. And start each slave inverter device in ascending order of integrated power value. Next, when the output power value from the DC power supply is detected and becomes equal to or less than the reference power value, it is determined that the solar radiation has ended, and the master inverter device stops the activation of each selected slave inverter device and integrates each slave inverter device. In order to set the device with the lowest power value as the next master inverter device, there will be a difference in the cumulative start-up time between the master inverter device and the slave inverter device. The startup time is not even. Then, this invention is providing the operating 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. In the operation method of the inverter device, which determines the number of starting units based on the power value and selects and starts the determined number of starting units from the inverter device having a small integrated power value of each of the inverter units, the selected inverters One master inverter device is selected at random from the devices, and the master inverter device determines the number of inverter devices to start based on the output power value of n cycles, and the integrated power value and integrated start of each inverter device. Including the master inverter device from the inverter device that is smaller among the combination value of at least one of the number of times and the cumulative activation time The determined startup number is selected, one next master inverter device is randomly selected from the selected inverter devices, and then, at the start of the (n + 1) cycle, the n cycle master inverter device is After starting each selected inverter device and starting each inverter device, the master inverter device is switched to the next master inverter device. Thereafter, the next master inverter device performs the same processing as the previous n cycle. An operation method of an inverter device, characterized in that the master inverter device is sequentially switched repeatedly.

  The second invention maintains the master inverter device selected in the n cycle as the next master inverter device in the (n + 1) cycle when the (n + 1) startup number is equal to the n cycle startup number. The operation method of the inverter device according to claim 1.

  According to a third aspect of the present invention, when the number of startups in (n + 1) is equal to the number of startups in n cycles, the inverter devices selected in the n cycles are maintained in the next inverter devices in the (n + 1) cycles. The operation method of the inverter device according to claim 2.

  According to the first aspect of the invention, since the required number of inverter devices to be started and the master inverter devices are switched based on the output power value for each predetermined cycle from the DC power supply, the same master inverter device is used throughout the day. Since there is no continuous operation and the integrated power value, integrated start time, and integrated start count between the master inverter device and the slave inverter device are made uniform, the life of each inverter device can be averaged. This will improve the reliability of the power supply system.

  According to the second invention, only when the number of (n + 1) startups is equal to the number of startups of n cycles, the processing is performed in order to make the master inverter device of n cycles the next master inverter device of (n + 1) cycles. In addition to being simplified, the life of each inverter device can be improved.

  According to the third aspect of the invention, the master inverter device selected in the n cycle and each slave inverter device are changed to the next master inverter in the (n + 1) cycle only when the number of (n + 1) startup is equal to the number of startups in the n cycle. Since the device and the next slave inverter device are used, the process is greatly simplified and the life of each inverter device can be improved.

[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. And a power detector DS that detects an output power value from the DC power source DC, and a first switch SW1 to an n-th switch SWn that opens and closes the output power from the DC power source DC.

  The first inverter device PS1 is formed by a first inverter main control circuit CO1 and a first inverter circuit PC1, and the second inverter device PS2 is formed by a second inverter main control circuit CO2 and a second inverter circuit PC2. The nth inverter device PSn is formed of an nth inverter main control circuit CON and an nth inverter circuit PCn.

  The first inverter main control circuit CO1 shown in FIG. 1 is formed by the output power calculation circuit PA, the main control circuit MA, and the transmission / reception circuit TC shown in FIG. 2, and the second inverter main control circuit CO2 to the nth inverter main control. The circuit CON is also formed of the same circuit as described above.

  For example, when the first inverter device PS1 of the power supply system is a master inverter device, the output power calculation unit PA of the first inverter main control circuit CO1 calculates the output power value from the DC power source DC at predetermined intervals. Determine the number of startups. Next, the main control circuit MA of the master inverter device has at least one or more of an integrated power value, an integrated activation number, and an integrated activation time calculated by the second inverter device PS2 to the n-th inverter device PSn serving as slave inverter devices. The combination value is detected, and only the determined start-up number including the master inverter device which is itself is selected from the at least one slave inverter device having a small combination value. Subsequently, one of the selected slave inverter devices and master inverter device is randomly selected to select the next master inverter device. The transmission / reception circuit TC of the master inverter device transmits the selection signal of the main control circuit MA to each slave inverter device, receives the reception signal sent from each slave inverter device, and transmits it to the main control circuit MA. .

  When the next master inverter selection signal is transmitted from the first inverter device PS1 which is the master inverter device to the second inverter device PS2 which is the slave inverter device, the second inverter device PS2 determines that it becomes the next master inverter device. A master inverter reception signal is transmitted to the first inverter device PS1. When the first inverter device PS1 receives the master inverter reception signal, the first inverter device PS1 determines that the second inverter device PS2 has become a master inverter device, and the first inverter device PS1 becomes a slave inverter device.

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

  In step 100 shown in FIG. 3, among the inverter devices connected in parallel to a plurality of units, a predetermined inverter device determined in advance is a master inverter device, for example, the first inverter device PS1 is a master inverter device, and the first inverter device PS1 determines the number of slave inverter devices to be activated based on an output power value for each cycle (for example, n cycles), and at least one or more of an integrated power value, an integrated activation count, and an integrated activation time for each slave inverter device. The determined startup number of slave inverter devices including the master inverter device is selected in ascending order of the combination value.

  In step 200, the first inverter device PS1 randomly selects one inverter device from among the slave inverter devices selected in the n period to be the next master inverter device. For example, the second inverter device PS2 is the next master inverter device.

  In step 300, a start command signal or a stop command signal is transmitted to the second inverter device PS to the n-th inverter device PSn that are slave inverter devices selected by the first inverter device PS1 that is an n-cycle master inverter device. To do.

  In step 400, the first inverter device PS1 that is a master inverter device receives a start completion signal or a stop completion signal from the second inverter device PS to the nth inverter device PSn that are slave inverter devices.

  In step 500, it is determined whether the first inverter device PS1, which is an n-cycle master inverter device, becomes the next master inverter device in the (n + 1) cycle. If YES, the process proceeds to the (n + 1) cycle. Each selected slave inverter device is activated, and then the number of activated slave inverter devices is determined based on the output power value of (n + 1) cycles, and the integrated power value, accumulated activation number, and accumulated activation of each slave inverter device are determined. The number of startups determined as described above is selected in ascending order of at least one combination value of time, and then one inverter device is selected at random from the selections to be the next master inverter device. If NO, go to step 600.

  In step 600, a master switching signal is transmitted from the first inverter device PS1, which is the current master inverter device, to the second inverter device PS2, which is the next master inverter device.

  In Step 700, the first inverter device PS1, which is the current master inverter device, receives a master switching completion signal from the second inverter device PS2 which is the next master inverter device.

  In step 800, when the master switching completion signal is received, the first inverter device PS1 is switched from the master inverter device to the slave inverter device at the start of the cycle (n + 1).

  In step 900, if the first inverter device PS1 switched from the master inverter device to the slave inverter device is to be stopped, the process proceeds to step 1000 and the inverter is stopped. The slave inverter device is activated, and then the second inverter device PS2, which becomes the next master inverter device, determines the number of slave inverter devices to be activated based on the output power value of (n + 1) cycles, Select the determined number of starting units in ascending order among at least one combination value of the integrated power value, the integrated starting number and the integrated starting time, and then select one inverter device at random from among the selected items. Then, the next master inverter unit is installed again, and the master inverter unit is subsequently updated. To go.

  From the above, since the number of slave inverter devices to be activated is determined based on the output power value for each predetermined period from the DC power supply, and the next master inverter device is selected from the determined slave inverter devices, the same master It is possible to prevent the inverter device from operating for a long time, for example, all day.

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

  In step 500, when the number of startups in the (n + 1) cycle is equal to the number of startups in the n cycle, the first inverter device PS1 that is the master inverter device selected in the n cycle is maintained as the next master inverter device in the (n + 1) cycle. , (N + 1) cycle, start each slave inverter device selected in the n cycle, and then determine the number of slave inverter devices to be started based on the output power value in the (n + 1) cycle, Select the determined number of starting units in ascending order among at least one combination value of the integrated power value, the integrated starting number and the integrated starting time of the inverter device, and then randomly select one unit from the selected ones. The next master inverter device.

  In step 500, when the number of startups in the n cycle is different from the number of startups in the (n + 1) cycle, the next master inverter device selected at random from the slave inverter devices selected in the n cycle is the master inverter device of the n cycle. Whether it is the same as a certain first inverter device PS1 is determined. If YES, the process proceeds to the (n + 1) cycle, the same processing as described above is performed, and if NO, the process proceeds to step 600.

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

  In step 500, when the number of startups in (n + 1) cycles is equal to the number of startups in n cycles, the first inverter device PS1, which is the master inverter device selected in n cycles, is replaced with the next master inverter device in (n + 1) cycles and the above n Each slave inverter device selected in the cycle continues as it is, proceeds to the (n + 1) cycle, keeps starting each slave inverter device selected in the n cycle, and then sets the output power value in the (n + 1) cycle. And determining the number of slave inverter devices to be activated, and selecting the determined number of activated devices in ascending order of at least one combination value of the accumulated power value, the accumulated number of activation times and the accumulated activation time of each slave inverter device. Subsequently, one unit is selected at random from the above selections to form the next master inverter device.

    In step 500, when the number of startups in the n cycle is different from the number of startups in the (n + 1) cycle, the next master inverter device selected at random among the slave inverter devices selected in the n cycle is the master inverter device of the n cycle. Whether it is the same as a certain first inverter device PS1 is determined. If YES, the process proceeds to the (n + 1) cycle, the same processing as described above is performed, and if NO, the process proceeds to step 600.

It is a block diagram of the power supply system of the solar cell which concerns on Embodiment 1 of this invention. FIG. 2 is a detailed diagram of a first inverter main control circuit shown in FIG. 1. It is a flowchart explaining the operation | movement of Embodiment 1 of this invention. It is a block diagram of the power supply system of the solar cell of a prior art. It is a switching timing diagram of a master inverter.

Explanation of symbols

AC AC system CO1 First inverter main control circuit CO2 Second inverter main control circuit CON nth inverter main control circuit CW1 first inverter control circuit CW2 second inverter control circuit CWn nth inverter control circuit DC DC power supply (solar cell)
DS power detection unit MA main control circuit PA output power calculation circuit PC1 first inverter circuit PC2 second inverter circuit PCn nth inverter circuit PS1 first inverter device PS2 second inverter device PSn nth inverter device SW1 first switch SW2 first 2 switch SW3 3rd switch SW4 4th switch SWn-1 n-1 switch SWn nth switch TC transmission / reception circuit

Claims (3)

  A plurality of inverter devices are connected in parallel to a DC power source, the output power value from the DC power source is measured at a predetermined cycle, the number of startups is determined based on the output power value for each cycle, and each inverter device In the operation method of an inverter device that starts by selecting the determined number of starters from the inverter device having a small integrated power value, a master inverter device is randomly selected from each of the selected inverter devices, The master inverter device determines the number of inverter devices to be started based on an n-cycle output power value, and includes at least one combination value of an integrated power value, an integrated activation count, and an integrated activation time of each inverter device. Select the determined start-up number including the master inverter device from the small inverter device, each selected The next master inverter device is randomly selected from the inverter device, and then, at the start of the (n + 1) cycle, the master inverter device of the n cycle starts each of the selected inverter devices, and each of the inverter devices Is started, the master inverter device is switched to the next master inverter device, and thereafter, the next master inverter device repeats the same processing as the previous n cycle to update the master inverter device sequentially. A method for operating an inverter device.   The master inverter device selected in the n cycle is maintained in the next master inverter device in the (n + 1) cycle when the (n + 1) startup number is equal to the n cycle startup number. The operation method of the inverter apparatus of 1. 2. The inverter devices selected in the n cycle are maintained in the next inverter devices in the (n + 1) cycle when the (n + 1) startup devices are equal to the n cycle startup devices. The operation method of the inverter device according to 2.

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