JP2017127167A - Power conversion system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power conversion system capable of suppressing time and effort for maintenance of a device.SOLUTION: A power conversion system has a power converter and a controller. The power converter has a conversion unit and a detector. The conversion unit converts power supplied from a power supply device. The detector detects the power converted by the conversion unit exceeding a predetermined value. The controller determines whether or not rise time after a start of power supply from the power supply device to the power converter is detected until the detector detects the power converted by the conversion unit exceeding the predetermined value is within reference time, and performs predetermined operation when the rise time is determined to be not within the reference time.SELECTED DRAWING: Figure 1

Description

  Embodiments described herein relate generally to a power conversion system.

  The power conversion device converts the power supplied from the power supply device and supplies it to the load. When an abnormality of the power conversion apparatus is detected, the power conversion apparatus displays an abnormality and outputs a signal for notifying the abnormality to an external device. However, this power conversion device needs to be subjected to maintenance such as inspection of deterioration of components included in the power conversion device before an abnormality occurs, and the labor for maintenance may be complicated.

JP-A 64-12813

  Problem to be solved by the invention is providing the power conversion system which can suppress the effort for the maintenance of an apparatus.

  The power conversion system of the embodiment includes a power conversion device and a control device. The power conversion device includes a conversion unit and a detection unit. The conversion unit converts electric power supplied from a power supply device. The detection unit detects that the power converted by the conversion unit exceeds a predetermined value. The control device detects that the power converted by the conversion unit has exceeded a predetermined value by the detection unit after detecting the start of power supply from the power supply device to the power conversion device It is determined whether the rise time until is within a reference period, and when it is determined that the rise time is not within the reference period, a predetermined operation is performed.

  The power conversion system of the embodiment includes a power conversion device and a control device. The power conversion device includes a conversion unit and a detection unit. The conversion unit converts electric power supplied from a power supply device. The detection unit detects that the power converted by the conversion unit has fallen below a predetermined value. The control device detects a fall from when it is detected that power supply from the power supply device to the power conversion device has been stopped until the power converted by the conversion unit falls below a predetermined value. It is determined whether or not the time is within a reference period, and a predetermined operation is performed when it is determined that the fall time is not within the reference period.

The figure which shows an example of the power conversion system 1 of embodiment. The figure which shows an example of the flow of operation | movement at the time of power activation in the power conversion system 1 of embodiment. Diagram illustrating an example of an output signal S (V _G) of the gate source voltage value V _G of the output voltage of the device _30, and the voltage detection section 35. Diagram showing an example of a voltage value V _F of the output voltage of the fan power supply _50, and the output signal of the voltage detector 55 S (V _F). The figure which shows an example of the flow of operation | movement at the time of the power supply cutoff in the power conversion system 1 of embodiment. In the power conversion system 1 of the embodiment, the voltage value V _{D of} DC power, the voltage value (OV) of the operating voltage of the control unit 28, the voltage value V _G of the output voltage of the gate power supply device 30, and the output signal of the voltage detection unit 35 The figure which shows an example of S (V _G ), voltage value V _F of the output voltage of the fan power supply apparatus 50, and output signal S (V _F ) of the voltage detection unit 55. The figure which shows an example of the flow of the other operation | movement at the time of the power supply cutoff in the power conversion system 1 of embodiment.

  Hereinafter, the power conversion system of an embodiment is explained with reference to drawings.

  The power conversion system 1 according to the embodiment, for example, converts DC power supplied from an overhead line via a pantograph, and supplies the converted power to a motor (not shown) of the vehicle, thereby generating a driving force in the vehicle. Is. Drawing 1 is a figure showing an example of power conversion system 1 of an embodiment. The power conversion system 1 includes, for example, a power supply 10, a control device 20, a gate power supply device 30, a gate amplifier 40, a fan power supply device 50, and a fan 60.

The power supply 10 includes, for example, a vehicle battery and a relay circuit. The power supply 10 is connected to the control device 20, the gate power supply device 30, and the fan power supply device 50 through the power line 1a. The power supply 10 supplies the DC power stored in the battery to the control device 20, the gate power supply device 30, and the fan power supply device 50 by controlling the relay circuit to be in a conductive state. The power supply 10 stops the supply of DC power when the relay circuit is switched from the conductive state to the cut-off state. Voltage value of the DC power supplied to each part from a power source 10 is V _D. V _D is, for example, 100 V.

  The control device 20 includes, for example, a voltage detection unit 22, a diode 24, a capacitor 26, and a control unit 28.

The voltage detector 22 is a voltmeter that measures the voltage value of the DC power supplied from the power supply 10. The voltage detection part 22 is connected between the positive electrode line 20a and the negative electrode line 20b to which the voltage of the DC power supplied from the power supply 10 is applied. The voltage detector 22 detects the voltage value V _D of the DC power supplied from the power supply 10. The voltage detection unit 22 outputs a signal S (V _D ) indicating the detected voltage value V _D to the control unit 28.

  The diode 24 is provided on the positive electrode line 20 a between the power input side of the control device 20 and the control unit 28. The diode 24 prevents the current from flowing from the control unit 28 side to the power supply 10 side by providing the cathode on the control unit 28 side.

  The capacitor 26 is connected between the positive electrode line 20a and the negative electrode line 20b to which the voltage of the DC power supplied from the power supply 10 is applied. Capacitor 26 has a capacity capable of storing power that can be operated by control unit 28 for a predetermined period when supply of DC power from power supply 10 is stopped. That is, the capacity of the capacitor 26 is a capacity calculated based on the power consumption per unit time of the control unit 28 and a predetermined period in which the control unit 28 is operated after the supply of DC power from the power supply 10 is stopped. is there.

  The control unit 28 is realized by a processor such as a CPU (Central Processing Unit) executing a program stored in a program memory. Some or all of these functional units may be realized by hardware such as LSI (Large Scale Integration), ASIC (Application Specific Integrated Circuit), or FPGA (Field-Programmable Gate Array). The control unit 28 generates an enable signal as a control signal for starting or stopping the operation of the DC-AC converter 33 and the DC voltage converter 53. The control unit 28 performs predetermined processing based on the rise time of the output power of the gate power supply device 30 or the fan power supply device 50 when the DC power from the power supply 10 is turned on. The control unit 28 performs predetermined processing based on the fall time of the output power of the gate power supply device 30 or the fan power supply device 50 when the DC power from the power supply 10 is cut off.

  The gate power supply device 30 includes, for example, a resistor 31, an input-side capacitor 32, a DC-AC converter (converter) 33, an output-side capacitor 34, and a voltage detector 35.

  The resistor 31 is provided on the positive electrode line 30a connected to the power line 1a. The resistor 31 suppresses a large inrush current from flowing to the DC-AC converter 33. The input-side capacitor 32 is connected between the positive electrode line 30a and the negative electrode line 30b on the DC-AC converter 33 side of the resistor 31. The input side capacitor 32 is supplied with DC power via the resistor 31. The input side capacitor 32 stores electric power when supply of DC power from the power supply 10 is started. On the other hand, the power stored in the input side capacitor 32 is consumed by the DC-AC converter 33 when the DC power from the power source 10 is cut off.

  The DC-AC converter 33 is a switching circuit including a plurality of semiconductor elements and a control circuit that controls on / off of the plurality of semiconductor elements. The DC-AC converter 33 converts DC power supplied via the input-side capacitor 32 into AC power. The DC-AC converter 33 converts, for example, 100V DC power into AC power having an amplitude of 50V. The enable signal E <b> 1 is supplied to the DC / AC converter 33. The DC-AC converter 33 starts or stops the power conversion operation based on the enable signal E1.

  The output-side capacitor 34 is connected between the positive electrode line 30a and the negative electrode line 30b on the output terminal 30c side of the DC-AC converter 33. The output side capacitor 34 stores the electric power output from the DC / AC converter 33.

Voltage detector 35 is connected between positive electrode line 30a and the negative electrode line 30b, a voltmeter for measuring the output voltage V _G of the gate power supply 30. The voltage detection unit 35 outputs a detection signal S (V _G ) to the control unit 28 when the voltage value V _G exceeds the reference level when the power is turned on. The voltage detection unit 35 outputs a detection signal S (V _G ) to the control unit 28 when the voltage value V _G falls below the reference level when the power is shut off. The voltage detection unit 35 detects that the voltage value V _G exceeds or falls below the reference level. However, the voltage detection unit 35 is not limited to this, and may output a signal indicating the voltage value V _G to the control unit 28. .

  The gate amplifier 40 is supplied with AC power converted by the DC-AC converter 33. The gate amplifier 40 is connected to an inverter circuit (not shown) that supplies driving power to the driving motor of the vehicle. The gate amplifier 40 controls the semiconductor switching element on and off by supplying a control signal to the gate terminal of the semiconductor switching element in the inverter circuit.

  The fan power supply device 50 includes, for example, a resistor 51, an input side capacitor 52, a DC voltage conversion unit (conversion unit) 53, an output side capacitor 54, and a voltage detection unit 55.

  The resistor 51 is provided on the positive electrode line 50a connected to the power line 1a. The resistor 51 suppresses a large inrush current from flowing to the DC voltage conversion unit 53. The input-side capacitor 52 is connected between the positive electrode line 50a and the negative electrode line 50b closer to the DC voltage converter 53 than the resistor 51. The input side capacitor 52 is supplied with DC power via the resistor 51. The input-side capacitor 52 stores electric power when the input of DC power from the power supply 10 is started. On the other hand, the power stored in the input-side capacitor 52 is consumed by the DC voltage converter 53 when the DC power from the power source 10 is interrupted.

  The DC voltage conversion unit 53 is a DC-DC converter including circuit components such as switching elements. The DC voltage converter 53 converts the voltage of DC power supplied via the input side capacitor 52. For example, the DC voltage conversion unit 53 converts a DC voltage of 100 V into a DC voltage of the rated voltage (for example, 24 V) of the fan 60. The DC voltage converter 53 is supplied with an enable signal E2. The DC voltage converter 53 starts or stops the voltage conversion operation based on the enable signal E2.

  The output-side capacitor 54 is connected between the positive electrode line 50a and the negative electrode line 50b on the output terminal 50c side of the DC voltage conversion unit 53. The output side capacitor 54 stores the electric power output from the DC voltage conversion unit 53.

Voltage detector 55 is connected between positive electrode line 50a and the negative electrode line 50b, a voltmeter for measuring the output voltage V _F of the fan power supply 50. The voltage detection unit 55 outputs a detection signal S (V _F ) to the control unit 28 when the voltage value V _F exceeds the reference level when the power is turned on. The voltage detection unit 55 outputs a detection signal S (V _F ) to the control unit 28 when the voltage value V _F falls below the reference level when the power is shut off. The voltage detector 55 is to detect that the voltage value V _F exceeds the reference level, or below were not limited thereto, may output a signal indicating the voltage value V _F to the control unit 28 .

  The fan 60 is a blower mechanism for a heat generating component (for example, an inverter circuit) in the power conversion system 1. The fan 60 is supplied with DC power whose voltage has been converted by the DC voltage converter 53. The fan 60 consumes DC power and performs a blowing operation, thereby suppressing a temperature rise in the heat generating component.

  Hereinafter, in the power conversion system 1 of the embodiment, after detecting that the supply of power from the power source 10 to the gate power source device 30 and the fan power source device 50 is detected, the voltage detection unit 35 and the voltage detection unit 55 perform DC-AC. It is determined whether or not the rise time until it is detected that the power converted by the converter 33 and the voltage detector 35 exceeds a predetermined value is within the reference period, and the rise time is not within the reference period. Will be described below.

Drawing 2 is a figure showing an example of the flow of operation at the time of power activation in power conversion system 1 of an embodiment. First, the control unit 28 waits until power is turned on (step S100). Based on the signal S (V _D ) detected by the voltage detection unit 22, the control unit 28 determines that the power is turned on when it is determined that the DC power having the voltage value V _D is supplied from the power supply 10. .

  When it is determined that the power is turned on, the control unit 28 outputs the enable signal E1 for starting the conversion operation to the DC-AC conversion unit 33 and the enable signal E2 for starting the conversion operation to the DC voltage conversion unit 53. Output (step S102). The DC-AC converter 33 starts an operation of converting DC power supplied from the power supply 10 into AC power in response to the input of the enable signal E1. The DC voltage converter 53 starts an operation of converting the voltage of the DC power supplied from the power supply 10 in response to the input of the enable signal E2.

  Next, the control unit 28 determines whether or not the rise time of the output power of the gate power supply device 30 is within the reference period, and whether or not the rise time of the output power of the fan power supply device 50 is within the reference period. Is determined (step S104). The control unit 28 ends the process when the rise time of the output power of the gate power supply device 30 is within the reference period and the rise time of the output power of the fan power supply device 50 is within the reference period.

  When the rise time of the output power of the gate power supply device 30 is not within the reference period, the control unit 28 performs a predetermined notification (step S106). When the rise time of the output power of the fan power supply device 50 is not within the reference period, the control unit 28 performs a predetermined notification (step S106). The control unit 28 gives a predetermined notification when one of the gate power supply device 30 and the fan power supply device 50 has a rising time that is not within the reference period. The predetermined notification is, for example, a display or audio output informing the user of the deterioration. The predetermined notification is an example of a predetermined operation. The control unit 28 may output a notification signal to the external device as a predetermined operation, not limited to the predetermined notification.

FIG. 3 is a diagram illustrating an example of the voltage value V _G of the output voltage of the gate power supply device 30 and the output signal S (V _G ) of the voltage detection unit 35. When DC power is supplied from the power supply 10 to the gate power supply device 30 (time t1), the input side capacitor 32 is first charged with power. When power is stored in the input side capacitor 32, the DC-AC converter 33 starts an operation of converting the supplied DC power into AC power. As a result, as shown in the upper diagram of FIG. 3, the voltage value V _G of AC power output from the DC-AC converter 33 gradually increases. The DC-AC converter 33 outputs the detection signal S (V _G ) to the controller 28 when the voltage value V _{G of} AC power exceeds a predetermined level TH _G (time t4). The control unit 28 determines whether or not the time at which the detection signal S (V _G ) is input is within the reference period T1 (time t2 to t3). The reference period T1 starts from time t2 when the period T2 ends.

The reference period T1 is set based on the capacitance of the input side capacitor 32. The capacity of the input side capacitor 32 decreases as the deterioration progresses, and the period from when the gate power supply 30 is turned on until the input side capacitor 32 is fully charged is shortened. Therefore, when the input side capacitor 32 is deteriorated, the time when the control unit 28 inputs the detection signal S (V _G ) tends to be before the reference period T1. Thereby, the control unit 28 can determine the rise time of the output power of the gate power supply device 30 in consideration of the deterioration of the input side capacitor 32.

Further, the reference period T <b> 1 may be set based on the rising time of the power output by the preset DC-AC converter 33 in addition to the capacitance of the input-side capacitor 32. When the resistance value of the semiconductor element or the like increases due to deterioration of the semiconductor element or the like included in the DC-AC conversion unit 33, the time at which the control unit 28 inputs the detection signal S (V _G ) is after the reference period T1. Tend to be. Thereby, the control unit 28 can determine the rise time of the output power of the gate power supply device 30 in consideration of the deterioration of the DC-AC conversion unit 33.

Further, the reference period T1 is based on the resistance value in the gate power supply device 30 in addition to (or instead of) the rise time of the power output by the capacitance of the input-side capacitor 32 and the preset DC-AC conversion unit 33. May be set. When the resistance value in the gate power supply device 30 increases due to deterioration of the resistor 31 and the like, the time when the control unit 28 inputs the detection signal S (V _G ) tends to be later than the reference period T1. Thereby, the control unit 28 can determine the rise time of the output power of the gate power supply device 30 in consideration of the deterioration of the resistor 31.

FIG. 4 is a diagram illustrating an example of the voltage value V _F of the output voltage of the fan power supply device 50 and the output signal S (V _F ) of the voltage detection unit 55. When DC power is supplied from the power supply 10 to the fan power supply device 50 (time t11), the input side capacitor 52 is first charged with power. When power is stored in the input side capacitor 52, the DC voltage converter 53 starts an operation of converting the voltage of the supplied DC power. Thereby, as shown in the upper diagram of FIG. 4, the voltage value V _F of the DC power output from the DC voltage conversion unit 53 gradually increases. The DC voltage converter 53 outputs the detection signal S (V _F ) to the controller 28 when the voltage value V _F of the DC power exceeds a predetermined level TH _F (time t14). The control unit 28 determines whether or not the time at which the detection signal S (V _F ) is input is within the reference period T11 (time t12 to t13). The reference period T11 starts from time t12 when the period T12 ends.

The reference period T11 is set based on the capacitance of the input side capacitor 52. The capacity of the input-side capacitor 52 decreases as the deterioration progresses, and the period from when the power to the fan power supply 50 is turned on until the input-side capacitor 52 is fully charged is shortened. Therefore, when the input side capacitor 52 is deteriorated, the time when the control unit 28 inputs the detection signal S (V _F ) tends to be before the reference period T11. Accordingly, the control unit 28 can determine the rise time of the output power of the fan power supply device 50 in consideration of the deterioration of the input side capacitor 52.

Further, the reference period T1 may be set based on the rising time of the power output by the DC voltage converter 53 set in advance in addition to the capacitance of the input side capacitor 52. When the resistance value of the circuit element increases due to the deterioration of the circuit element included in the DC voltage conversion unit 53, the time when the control unit 28 inputs the detection signal S (V _F ) tends to be later than the reference period T11. Become. Similarly, when the resistance value in the fan power supply device 50 increases due to deterioration of the resistor 51 and the like, the time when the control unit 28 inputs the detection signal S (V _F ) tends to be later than the reference period T11. Accordingly, the control unit 28 can determine the rise time of the output power of the fan power supply device 50 in consideration of the deterioration of the DC voltage conversion unit 53, the resistor 51, and the like.

  Hereinafter, in the power conversion system 1 of the embodiment, after detecting that the supply of power from the power supply 10 to the gate power supply device 30 and the fan power supply device 50 is stopped, the power conversion system 1 converts the power supply system 30 and the fan power supply device 50. It is determined whether or not the fall time until it is detected that the power falls below the predetermined value is within the reference period, and the predetermined operation is performed when it is determined that the fall time is not within the reference period This will be explained.

FIG. 5 is a diagram illustrating an example of an operation flow when the power is shut down in the power conversion system 1 of the embodiment. First, the control unit 28 waits until the power is cut off (step S200). When the control unit 28 determines that the supply of the DC power of the voltage value V _D from the power source 10 is stopped based on the signal S (V _D ) detected by the voltage detection unit 22, the control unit 28 determines that the power source is shut off. To do.

  When the control unit 28 determines that the power supply is cut off, the control unit 28 determines whether or not the fall time of the output power of the gate power supply device 30 is within the reference period, and the fall time of the output power of the fan power supply device 50. Is determined to be within the reference period (step S202). The control unit 28 ends the process when the fall time of the output power of the gate power supply device 30 is within the reference period and the fall time of the output power of the fan power supply device 50 is within the reference period.

  When the falling time of the output power of the gate power supply device 30 is not within the reference period, the control unit 28 performs a predetermined notification (step S204). When the falling time of the output power of the fan power supply device 50 is not within the reference period, the control unit 28 performs a predetermined notification (step S204). The control unit 28 gives a predetermined notification when one of the gate power supply device 30 and the fan power supply device 50 falls within the reference period. The predetermined notification is, for example, a display or audio output informing the user of the deterioration. The predetermined notification is an example of a predetermined operation. The control unit 28 may output a notification signal to the external device as a predetermined operation, not limited to the predetermined notification.

6 shows the voltage value V _{D of} DC power, the voltage value (OV) of the operating voltage of the control unit 28, the voltage value V _G of the output voltage of the gate power supply device 30, and the voltage detection unit in the power conversion system 1 of the embodiment. 35 the output signal S _(V G), the output signal S _{(V F)} of the fan power supply voltage value _{V F} of the output voltage of the device 50, and the voltage detection unit 55 is a diagram illustrating an example. When the supply of the output power of the power supply 10 is interrupted (time t21), the power supplied from the power supply 10 to the control device 20, the gate power supply device 30, and the fan power supply device 50 gradually decreases. The voltage detection unit 22 determines that the power is cut off based on a decrease in the power even supplied from the power supply 10.

  After the power is cut off at time t21, the control unit 28 is driven over the period T20 by the power stored in the capacitor 26. The period T20 is a time longer than the fall time of the output power of the gate power supply device 30 and the fall time of the output power of the fan power supply device 50 after the power is cut off at time t21. It is determined by the power consumption of the unit 28 and the capacity of the capacitor 26.

After the power is cut off at time t21, the voltage value V _D of the DC power decreases, and the power of the input side capacitor 32 is extracted by the DC-AC converter 33, whereby the voltage value of the output voltage of the gate power supply device 30 is obtained. V _G gradually decreases. The voltage detector 35 outputs a detection signal S (V _G ) to the controller 28 when the voltage value V _G of the output voltage of the gate power supply device 30 falls below a predetermined level (time t23). The predetermined level is substantially 0 as shown in FIG. 6, but may be the same as the predetermined level when the power is turned on.

The control unit 28 determines whether or not the time t23 when the detection signal S (V _G ) is input is within the reference period T21. The reference period T21 starts from the time when the period T22 ends. The start time and end time of the reference time T21 are set based on the capacitance of the input side capacitor 32. The capacity of the input-side capacitor 32 decreases as the deterioration progresses, and the period from when power supply to the gate power supply device 30 is stopped until the power stored in the input-side capacitor 32 is extracted is shortened. Therefore, when the input side capacitor 32 is deteriorated, the time when the control unit 28 inputs the detection signal S (V _G ) tends to be before the reference period T21. Thereby, the control unit 28 can determine the fall time of the output power in consideration of the deterioration of the input side capacitor 32.

Similarly, after the power is cut off at time t21, the voltage value V _D of the DC power decreases and the power of the input side capacitor 52 is extracted, so that the voltage value V _F of the output voltage of the fan power supply 50 gradually increases. descend. The voltage detection unit 55 outputs a detection signal S (V _F ) to the control unit 28 when the voltage value V _F of the output voltage of the fan power supply device 50 falls below a predetermined level (time t24). The predetermined level is substantially 0 as shown in FIG. 6, but may be the same as the predetermined level when the power is turned on.

The control unit 28 determines whether or not the time t24 when the detection signal S (V _F ) is input is within the reference period T31. The reference period T31 starts from the time when the period T32 ends. The start time and end time of the reference time T31 are set based on the capacitance of the input side capacitor 52. The capacity of the input-side capacitor 52 decreases as the deterioration progresses, and the period from when the power supply to the fan power supply device 50 is stopped until the power stored in the input-side capacitor 52 is extracted is shortened. Therefore, when the input side capacitor 52 is deteriorated, the time when the control unit 28 inputs the detection signal S (V _F ) tends to be before the reference period T31. Thereby, the control unit 28 can determine the fall time of the output power in consideration of the deterioration of the input side capacitor 52.

When the control unit 28 detects that the power supply from the power supply 10 is stopped at the time of the power shutdown described above, the control unit 28 cancels the enable signal E1 that has output the enable signal E1 to the DC-AC conversion unit 33. The enable signal E2 that has output the enable signal E2 to the DC voltage converter 53 may be canceled. Canceling the enable signal corresponds to supplying a control signal for stopping the operation of the DC-AC converter 33 and the DC voltage converter 53. FIG. 7 is a diagram illustrating an example of another operation flow when the power is shut down in the power conversion system 1 of the embodiment. When it is determined that the supply of the DC power of the voltage value V _D from the power supply 10 is cut off based on the signal S (V _D ) detected by the voltage detection unit 22 (Step S200), the control unit 28 -The enable signal output to the AC converter 33 is canceled, and the enable signal output to the DC voltage converter 53 is canceled (step S210).

  The control unit 28 determines whether or not the fall time of each of the gate power supply device 30 and the fan power supply device 50 is within the reference period, starting from the respective times when the enable signals E1 and E2 are canceled (Step S28). S202). That is, the control unit 28 assumes that the time when the period T22 ends from the time when the enable signal E1 is canceled is the start time of the reference time T21. Further, the control unit 28 assumes that the time when the period T32 ends from the time when the enable signal E2 is canceled is the start time of the reference time T31. Then, the control unit 28 determines whether or not the fall time of the output power of the gate power supply device 30 is within the reference period T21, and the fall time of the output power of the fan power supply device 50 is within the reference period T31. It is determined whether or not there is (step S202).

  The operation at the time of current interruption is not the process of canceling the enable signal in step S210, but the control unit 28 determines that the power supply from the power source 10 has been interrupted, the DC-AC conversion unit 33 and the DC The same can be realized by outputting a disable signal indicating that the power supply has been cut off to the voltage converter 53.

  As described above, according to the power conversion system 1 of the embodiment, the predetermined operation is performed when it is determined that the rise time of the output power of the gate power supply device 30 or the fan power supply device 50 is not within the reference period. A predetermined operation can be performed in accordance with the presence of deterioration in the components inside the gate power supply device 30 or the fan power supply device 50. Thereby, according to the power conversion system 1 of the embodiment, it is possible to determine the deterioration of the parts before the abnormality occurs in the gate power supply device 30 or the fan power supply device 50, and as a result, labor for maintenance of the device can be determined. Can be suppressed.

  Further, according to the power conversion system 1 of the embodiment, it is determined that the rise time of the output power of the gate power supply device 30 or the fan power supply device 50 is not within the reference time based on the capacitance of the input side capacitor 32 or the input side capacitor 52. In this case, since the predetermined operation is performed, the deterioration of the input side capacitor 32 or the input side capacitor 52 can be determined.

  Furthermore, according to the power conversion system 1 of the embodiment, a predetermined operation is performed when it is determined that it is not within the reference time based on the rise time of the power output by the DC-AC converter 33 or the DC voltage converter 53. Therefore, it is possible to determine the deterioration of the components in the DC-AC converter 33 or the DC voltage converter 53.

  Furthermore, according to the power conversion system 1 of the embodiment, a predetermined operation is performed when it is determined that it is not within the reference time based on the rise time of the power output by the DC-AC converter 33 or the DC voltage converter 53. Therefore, it is possible to determine the deterioration of the components in the DC-AC converter 33 or the DC voltage converter 53.

  Furthermore, according to the power conversion system 1 of the embodiment, the predetermined operation is performed when it is determined that it is not within the reference time based on the resistance value in the gate power supply device 30 or the resistance value in the fan power supply device 50. The resistance value at 30 or the deterioration of the resistance at the fan power supply device 50 can be determined.

  Furthermore, according to the power conversion system 1 of the embodiment, the time from when the gate power supply device 30 and the fan power supply device 50 start the conversion operation by the enable signal until it is detected that the output power exceeds the predetermined value is set. Since the rise time is calculated, the rise time can be measured with high accuracy, and the accuracy of determination of deterioration can be increased.

  Furthermore, according to the power conversion system 1 of the embodiment, a predetermined operation is performed when it is determined that the falling time of the output power of the gate power supply device 30 or the fan power supply device 50 is not within the reference period. 30 or a predetermined operation can be performed in accordance with the presence of deterioration in the components inside the fan power supply 50. Thereby, according to the power conversion system 1 of the embodiment, it is possible to determine the deterioration of the parts before the abnormality occurs in the gate power supply device 30 or the fan power supply device 50, and as a result, labor for maintenance of the device can be determined. Can be suppressed.

  Further, according to the power conversion system 1 of the embodiment, it is determined that the fall time of the output power of the gate power supply device 30 or the fan power supply device 50 is not within the reference time based on the capacitance of the input side capacitor 32 or the input side capacitor 52. In such a case, since a predetermined operation is performed, it is possible to determine the deterioration of the input side capacitor 32 or the input side capacitor 52.

  Furthermore, according to the power conversion system 1 of the embodiment, from when the gate power supply device 30 and the fan power supply device 50 are stopped by the release of the enable signal until the output power is detected to be lower than the predetermined value. Since the time is calculated as the fall time, the fall time can be measured with high accuracy, and the accuracy of determination of deterioration can be increased.

(Modification)
The power conversion system 1 of the embodiment has determined whether the rise time or the fall time of the output power of the gate power supply device 30 or the fan power supply device 50 is within the reference time. The determination may be made based on information corresponding to a change in output power of the power supply device 30 or the fan power supply device 50. In the power conversion system 1 of the embodiment, for example, when the DC power from the power supply 10 is input, the control device 20 has a rising speed (or a falling speed) of the output voltage of the gate power supply device 30 or the fan power supply device 50. The rise time (or fall time) of the output voltage of the gate power supply device 30 or the fan power supply device 50 may be predicted based on the change in the output voltage.

  In the power conversion system 1 of the above-described embodiment, the operation when the supply of DC power to the gate power supply device 30 and the fan power supply device 50 is started or the supply of DC power is stopped has been described. Are not limited to the gate power supply device 30 and the fan power supply device 50. The power conversion system 1 may supply DC power to a drive circuit of a relay (not shown) in the power source 10 as a supply destination of DC power, and determine deterioration of the relay drive circuit or the like.

  According to at least one embodiment described above, the voltage detection unit 35 or the voltage detection unit 55 detects that the supply of power from the power supply 10 to the gate power supply device 30 or the fan power supply device 50 has been started. It is determined whether the rise time until it is detected that the power converted by the AC converter 33 or the DC voltage converter 53 exceeds a predetermined value is within the reference period, and the rise time is within the reference period By having the control device 20 that performs a predetermined operation when it is determined that it is not, it is possible to determine the soundness of the gate power supply device 30 or the fan power supply device 50, so that the labor for maintenance of the device is suppressed. Can do.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1 ... Power conversion system, 10 ... Power supply, 20 ... Control apparatus, 22 ... Voltage detection part, 26 ... Capacitor, 28 ... Control part, 30 ... Gate power supply device, 31 ... Resistance, 32 ... Input side capacitor, 33 ... DC- AC converter, 35 ... voltage detector, 50 ... fan power supply, 51 ... resistor, 52 ... input side capacitor, 53 ... DC voltage converter, 55 ... voltage detector

Claims (8)

A power converter comprising: a converter that converts power supplied from a power supply device; and a detector that detects that the power converted by the converter exceeds a predetermined value;
The rise time from when it is detected that power supply from the power supply device to the power conversion device is started until when the detection unit detects that the power converted by the conversion unit exceeds a predetermined value Determining whether or not it is within a reference period and performing a predetermined operation when it is determined that the rise time is not within the reference period; and
A power conversion system comprising: The conversion unit includes a conversion circuit that converts electric power supplied from the power supply device, and a capacitor provided between the power supply device and the conversion circuit,
The reference period is set based on the capacitance of the capacitor,
The power conversion system according to claim 1. The reference period is set based on a rise time of power output by the conversion circuit set in advance.
The power conversion system according to claim 2. The reference period includes a conversion circuit that converts electric power supplied from the power supply device, and a resistor provided between the power supply device and the conversion circuit,
The reference period is set based on a resistance value of the resistor,
The power conversion system according to any one of claims 1 to 3. The conversion unit includes a control unit that starts an operation in response to receiving a control signal output by the control device,
When the control device detects that power supply from the power supply device to the power conversion device is started, the control device outputs the control signal to the control unit, and starts the operation of the conversion unit. The time until the detection unit detects that the power converted by the conversion unit exceeds a predetermined value is calculated as the rise time.
The power conversion system according to any one of claims 1 to 4. A power converter comprising: a converter that converts power supplied from a power supply device; and a detector that detects that the power converted by the converter falls below a predetermined value;
The fall time from when it is detected that power supply from the power supply device to the power conversion device is stopped until when the power converted by the conversion unit falls below a predetermined value is a reference period A control device that performs a predetermined operation when it is determined whether or not the fall time is not within the reference period;
A power conversion system comprising: The conversion unit includes a conversion circuit that converts electric power supplied from the power supply device, and a capacitor provided between the power supply device and the conversion circuit,
The reference period is set based on the capacitance of the capacitor,
The power conversion system according to claim 6. The conversion unit includes a control unit that stops operation in response to receiving a control signal output by the control device,
When the control device detects that power supply from the power supply device to the power conversion device has been stopped, the control device outputs the control signal to the control unit, and stops the operation of the conversion unit. The time until the detection unit detects that the power converted by the conversion unit has fallen below a predetermined value is calculated as the fall time.
The power conversion system according to claim 6 or 7.

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