JP2018183006A - Power conversion device and abnormality detection method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To appropriately detect an abnormality of a DC voltage detector in a power conversion device.SOLUTION: A power conversion device 100, including a converter unit 2 for converting AC into a plurality of potentials and an inverter unit 3 for converting the voltages of a plurality of potentials into AC, includes: smoothing capacitors 22, 23, 32, 33, connected between two potentials among the plurality of potentials, for suppressing each potential fluctuation among the potentials; DC voltage detectors 25, 26, 35, 36 for detecting potential differences among the potentials to which the smoothing capacitors are connected; and an abnormal determination units 72 which determines the abnormality of the DC voltage detectors 25, 26, 35, 36 on the basis of the detection values of the DC voltage detectors 25, 26, 35, 36 at the charge of the smoothing capacitors 22, 23, 32, 33.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a power conversion device including a converter and an inverter, and an abnormality detection method for detecting an abnormality in the power conversion device, and more particularly to a technology for detecting an abnormality in a DC voltage detector in the power conversion device.

  There is known a power converter that converts the power of an AC power supply into power of a variable voltage variable frequency. In the power conversion device, the DC circuit is provided with a smoothing capacitor and a DC voltage detector that measures the voltage across the smoothing capacitor, and the output DC voltage is controlled to be constant.

  For example, as a technique for confirming the soundness of a smoothing capacitor, one that determines an abnormality from the behavior of the charge voltage at the time of initial charge is known (see, for example, Patent Document 1). In addition, among power conversion devices that convert power of an AC power supply into power of a variable voltage variable frequency, a power conversion device provided with a plurality of DC voltage detectors is known (for example, see Patent Document 2).

JP 2005-354789 A JP 2008-011606 A

  Patent Document 1 discloses a technology for judging an abnormality from the behavior of a DC voltage at the time of initial charge in order to confirm the soundness of a smoothing capacitor, but judges an abnormality of a DC voltage detector in a power conversion device. There is no disclosure of technology to do this. The DC voltage detector is essential to control the DC voltage of the power converter, and the abnormality of the DC voltage detector leads to the instability of the operation of the system, and in the worst case the unplanned shutdown of the system Cause serious damage.

  This invention is made in view of the said situation, The objective is to provide the technique which can detect abnormality of the DC-voltage detector in a power converter appropriately.

  In order to achieve the above object, a power conversion device according to one aspect is a power conversion device including a converter that converts alternating current to a plurality of potentials, and an inverter that converts voltages of a plurality of potentials to alternating current. A smoothing capacitor connected between two of the potentials and used to suppress potential fluctuation between the potentials, a DC voltage detector detecting a potential difference between the potentials to which the smoothing capacitor is connected, and charging of the smoothing capacitor And an abnormality determiner that determines an abnormality of the direct current voltage detector based on a detection value of the direct current voltage detector in the above.

  According to the present invention, it is possible to appropriately detect an abnormality in the DC voltage detector in the power conversion device.

FIG. 1 is an entire configuration diagram of the power conversion device according to the first embodiment. FIG. 2 is a diagram for explaining a DC voltage value detected by the DC voltage detector at the time of charging in the first embodiment. FIG. 3 is a flowchart of abnormality determination processing by the abnormality determiner according to the first embodiment. FIG. 4 is an entire configuration diagram of a power conversion device according to a second embodiment. FIG. 5 is an entire configuration diagram of a power conversion device according to a third embodiment. FIG. 6 is an entire configuration diagram of a power conversion device according to a fourth embodiment. FIG. 7 is an entire configuration diagram of a power conversion device according to a fifth embodiment. FIG. 8 is a configuration diagram of a part including an output estimator of the power conversion device according to the fifth embodiment. FIG. 9 is an entire configuration diagram of a power conversion device according to a sixth embodiment.

  Several embodiments will be described with reference to the drawings. The embodiments described below do not limit the invention according to the claims, and all of the elements described in the embodiments and their combinations are essential to the solution means of the invention. There is no limit.

  First, the power conversion device according to the first embodiment will be described.

  FIG. 1 is an entire configuration diagram of the power conversion device according to the first embodiment.

  Power converter 100 converts AC power supply 1, a converter unit (also referred to as a converter) 2 for converting AC power from AC power supply 1 into DC power, and DC power output from converter unit 2 into desired AC power. An inverter unit (also referred to as an inverter) 3, a motor 4 driven by AC power output from the inverter unit 3, a converter control device 5 for controlling the converter unit 2, and an inverter control device 6 for controlling the inverter unit 3; Equipped with

  Converter unit 2 is a so-called three-level converter, which converts AC power into a positive potential (first potential) level, a neutral point (zero) potential (second potential) level, and a negative potential (third potential). Convert to DC power with level. The inverter unit 3 is a so-called three level inverter, and is a direct current of positive potential (first potential) level, neutral point (zero) potential (second potential) level, and negative potential (third potential) level. The power is converted into AC power for the motor 4. Positive potential levels of converter unit 2 and inverter unit 3 are connected by P wiring 40, neutral point potential levels are connected by C wiring 41, and negative potential levels are connected by N wiring 42 There is.

  Converter unit 2 includes converter power conversion unit 21 and converter P-side smoothing capacitor 22 (a first converter-side smoothing capacitor, a first smoothing converter, a converter-side smoothing capacitor: a smoothing capacitor 22) for suppressing fluctuations in DC voltage. The converter N-side smoothing capacitor 23 (the second converter-side smoothing capacitor, the second smoothing converter, the converter-side smoothing capacitor: sometimes referred to as the smoothing capacitor 23), and the converter P-side smoothing capacitor 22 Converter P-side DC voltage detector 25 (first converter-side DC voltage detector: sometimes referred to as DC voltage detector 25) for measuring inter-terminal voltage, and inter-terminal voltage of converter N-side smoothing capacitor 23 Converter N-side DC voltage detector 26 (second Converter side direct current voltage detector: provided that there is) if referred to as the DC voltage detector 26 is connected to the C line 41, the converter neutral point resistor 24 for suppressing the dc resonance, the.

  The inverter unit 3 includes an inverter power conversion unit 31, an inverter P-side smoothing capacitor 32 (a first inverter-side smoothing capacitor, a first smoothing converter, and an inverter-side smoothing capacitor: sometimes referred to as a smoothing capacitor 32), and an inverter N Inverter for measuring the inter-terminal voltage of the second smoothing capacitor 33 (second inverter-side smoothing capacitor, second smoothing converter, inverter-side smoothing capacitor: sometimes referred to as smoothing capacitor 33), and the inverter P-side smoothing capacitor 32 P side DC voltage detector 35 (first inverter side DC voltage detector: sometimes referred to as DC voltage detector 35) and inverter N side DC for measuring voltage between terminals of inverter N side smoothing capacitor 33 Voltage detector 36 (2nd inverter side DC voltage detector: direct Provided that there may be referred to a voltage detector 36) is connected to the C line 41, the inverter neutral point resistor 34 for suppressing the dc resonance, the.

  Converter control device 5 controls converter power conversion unit 21 such that the DC power to be converted has a desired value. The inverter control device 6 controls the inverter power control unit 31 so that the output torque and the speed of the motor 4 satisfy desired characteristics.

  Power converter 100 detects a current output from converter unit 2 and outputs current detector 7, a speed detector 8 directly connected to motor 4 and detecting and outputting a speed of motor 4, and an inverter unit 3. And a current detector 9 for detecting and outputting the output current.

  The signal (output signal) of the detection value detected by the current detector 7 and the DC voltage detectors 25, 26 is input to the converter control device 5. Converter control device 5 performs various arithmetic processing based on the input detected value, and outputs a signal for controlling converter power conversion unit 21.

  The signal (output signal) of the detection value detected by the speed detector 8, the current detector 9, and the DC voltage detectors 35 and 36 is input to the inverter control device 6. The inverter control device 6 performs various arithmetic processing based on the input detection value, and outputs a signal for controlling the inverter power conversion unit 31.

  Converter control device 5 includes a DC voltage command generator 51, a DC voltage controller 52, a current controller 53, a pulse generator 54, a neutral point voltage controller 55, and a charge controller 56.

  The direct current voltage command generator 51 outputs a direct current voltage command value indicating a voltage value of the direct current voltage output from the converter unit 2 to the direct current voltage controller 52.

  The DC voltage controller 52 converts the converter output current command value based on the DC voltage command value input from the DC voltage command generator 51 and the detection value of the DC voltage input from the DC voltage detectors 25 and 26. It calculates and outputs to the current controller 53. Specifically, DC voltage controller 52 calculates the converter output current command value such that the total value of the detected values of DC voltages input from DC voltage detectors 25 and 26 matches the DC voltage command value. Do.

  The neutral point voltage controller 55 calculates a voltage command such that the neutral point voltage becomes zero, based on the difference between the detected values of the DC voltage input from each of the DC voltage detectors 25 and 26, It outputs to the controller 53.

  Current controller 53 calculates a converter voltage command value so that the converter output current detection value output from current detector 7 matches the converter output current command value input from DC voltage controller 52, and generates a pulse. Output to the output unit 54. At this time, the current controller 53 calculates a converter voltage command value in consideration of the voltage command input from the neutral point voltage controller 55.

  The pulse generator 54 performs on / off control of each switching element of the converter power conversion unit 21 such that the output voltage of the converter power conversion unit 21 matches the converter output voltage command value input from the current controller 53. The pulse signal is calculated, and the pulse signal is output to converter power conversion unit 21.

  Before the operation of converter unit 2 and inverter unit 3 is started, charge controller 56 performs converter P-side smoothing capacitor 22, converter N-side smoothing capacitor 23, inverter P-side smoothing capacitor 32, and inverter N-side. Control is performed to charge the smoothing capacitor 33 (initial charge). Specifically, when performing the initial charge, the charge controller 56 notifies the charging circuit 71 described later and the abnormality determiner 72 the start of the initial charge.

  The inverter controller 6 includes a speed command generator 61, a speed controller 62, a current controller 63, a pulse generator 64, and a neutral point voltage controller 65.

  The speed command generator 61 outputs, to the speed controller 62, a speed command value indicating the speed at which the motor 4 is operated.

  The speed controller 62 calculates the inverter output current command value so that the speed detection value input from the speed detector 8 matches the speed command value input from the speed command generator 61, and the inverter output current command value Is output to the current controller 63.

  The neutral point voltage controller 65 calculates a voltage command such that the neutral point voltage becomes zero based on the difference between the detected values of the DC voltage input from each of the DC voltage detectors 35 and 36, and It outputs to the controller 63.

  The current controller 63 calculates the inverter voltage command value so that the inverter output current detection value input from the current detector 9 matches the inverter output current command value input from the speed controller 62, and generates a pulse generator. Output to 64. At this time, the current controller 63 calculates an inverter voltage command value in consideration of the voltage command input from the neutral point voltage controller 65.

  The pulse generator 64 performs on / off control of each switching element of the inverter power conversion unit 31 such that the output voltage from the inverter power conversion unit 31 matches the inverter output voltage command value input from the current controller 63. The pulse signal is calculated, and the pulse signal is output to the inverter power conversion unit 31.

  Next, a configuration related to abnormality determination in power conversion device 100 will be described.

  Power converter 100 includes charging power supply 70, charging circuit 71, abnormality determiner 72, and display 73.

  The charging power supply 70 is a power supply for charging the smoothing capacitors 22, 23, 32, 33. The charging power supply 70 is, for example, an AC power supply.

  The charging circuit 71 is a circuit that charges the smoothing capacitors 22, 23, 32, and 33 with the power input from the charging power source 70. The charging circuit 71 includes, for example, a contactor for opening and closing a wiring with the charging power supply 70, a diode for rectifying alternating current, a fuse for circuit protection, and the like. In the present embodiment, when the charging circuit 71 receives an instruction to start the initial charge from the charge controller 56, the contactor closes the wiring with the charging power supply 70.

  The display 73 is, for example, a display device capable of displaying information such as a liquid crystal display, and displays various information.

  The abnormality determiner 72 includes DC voltage values (detected values) input from the DC voltage detectors 25, 26, 35, 36, and DC voltage values stored in the memory 72a (storage unit) at the time of initial charge. The data (DC voltage data: reference data) relating to time change (behavior) is compared to determine whether or not the DC voltage detectors 25, 26, 35, 36 have an abnormality. For example, when the difference between the detected value and the value of the reference data (reference value: reference value) at the time corresponding to the time of detection of the detected value exceeds the predetermined threshold value, the abnormality determiner 72 detects the detected value. It is determined that the DC voltage detector that is detecting is abnormal. Here, the reference data regarding the behavior of the DC voltage detected at the time of initial charge can be calculated based on the charging power, the capacity of the smoothing capacitor, and the constant determined by the configuration of the charging circuit 71. . Therefore, reference data may be calculated in advance, and the calculated reference data may be stored in the memory 72a.

  When the abnormality determiner 72 detects a DC voltage detector having an abnormality, information related to the abnormality (for example, information that can specify the DC voltage detector having an abnormality (for example, device number)), inspection, replacement, etc. Are displayed on the display unit 73. The abnormality determiner 72 may be configured by a processor (not shown) executing a program stored in the memory.

  Next, abnormality determination by the abnormality determiner 72 according to the first embodiment will be specifically described.

  FIG. 2 is a diagram for explaining a DC voltage value detected by the DC voltage detector at the time of charging in the first embodiment.

  FIG. 2 shows DC voltage values (detected values) detected from the DC voltage detectors 25, 26, 35, and 36, and reference data for determining an abnormality of the DC voltage detector. In addition, in FIG. 2, the example in case the direct current voltage detector 26 is abnormal is shown.

  The reference data is a DC voltage value from the charge start time T0 obtained by calculating in advance using the charging power supply 70, the charging circuit 71, and the capacities of the smoothing capacitors 22, 23, 32, and 33. . The reference data is stored in advance in the memory 72a. In the present embodiment, a DC voltage value at each time from the start of charging may be used as reference data, and at multiple points (eight points from T1 to T8 in FIG. 2) at predetermined time intervals from the start of charging. A DC voltage value may be used as reference data.

  If there is no abnormality in the DC voltage detector, the detection value of the DC voltage detector matches or approximates the reference data, but if there is an abnormality, it is indicated at the output of the DC voltage detector 26 in FIG. As a result, a large deviation from reference data occurs.

  Therefore, the abnormality determiner 72 compares the detection values of the four DC voltage detectors 25, 26, 35, 36 with the DC voltage value (reference value) of the reference data at that time from the start of the first charge, Whether the difference between the detected value and the reference value exceeds the predetermined threshold value, it is determined that the DC voltage detector that detects the detected value is abnormal. The display 73 displays that the DC voltage detector is abnormal and a message recommending inspection and replacement of the DC voltage detector.

  Here, even if the detected value of the DC voltage detector deviates from the reference value, it may not necessarily be an abnormality of the DC voltage detector. Therefore, the abnormality determiner 72 according to the present embodiment performs the following abnormality determination processing in order to reduce the risk that the DC voltage detector is erroneously determined to be abnormal due to factors other than the abnormality of the DC voltage detector. It is carried out.

  FIG. 3 is a flowchart of abnormality determination processing by the abnormality determiner according to the first embodiment.

  The abnormality determiner 72 determines whether all detected values of the four DC voltage detectors 25, 26, 35, 36 are zero (or values close to zero) (step S11). In the present embodiment, the abnormality determiner 72 detects detected values of the four DC voltage detectors 25, 26, 35, 36 at all of a plurality of time points (for example, eight time points T1 to T8 shown in FIG. 2). Is determined to be all zero.

  As a result, if all the detection values of the DC voltage detectors 25, 26, 35, 36 are zero (step S11: Yes), for example, there is a possibility that the charging circuit 71 has an abnormality such as disconnection. Therefore, the abnormality determiner 72 determines that the charging circuit 71 has an abnormality, and causes the display 73 to display information indicating that the charging circuit has an abnormality ("charging circuit abnormality") (step S12). To step S19.

  On the other hand, when all the detection values of the DC voltage detectors 25, 26, 35, 36 are not zero (Step S11: No), the abnormality determiner 72 selects one of the DC voltage detectors 25, 26, 35, 36. It is determined whether or not there is zero in the detected value of (step S13).

  As a result, when any of the detection values of the DC voltage detectors 25, 26, 35, 36 has a zero (Step S13: Yes), the DC voltage used by the DC voltage detector whose detection value is zero Since abnormality due to disconnection or loosening of the loop (DC voltage detection loop: wiring) for performing voltage detection is considered, the abnormality determiner 72 determines that the DC voltage detection loop has abnormality, and the DC voltage detection loop Information ("DC voltage detection loop abnormality") indicating that there is an abnormality is displayed on the display 73 (step S14), and the process proceeds to step S19.

  On the other hand, when none of the detection values of the DC voltage detectors 25, 26, 35, 36 has zero (step S13: No), the abnormality determiner 72 measures the amount of fluctuation of the voltage of the charging power supply 70, DC From the detection values of the voltage detectors 25, 26, 35, 36, it is determined whether or not there is an abnormality in the charging power supply 70 (step S15). The amount of fluctuation of the voltage of the charging power source 70 may be acquired from, for example, a higher-level device that supplies the charging power source 70, and a sensor that measures the amount of fluctuation of the voltage of the charging power source 70 in the power conversion device 100. May be provided and acquired from the sensor.

  As a result, when there is an abnormality in the charging power supply 70 (step S15: Yes), the abnormality determiner 72 determines that there is an abnormality in the charging power supply, and indicates that the charging power supply has an abnormality ("charging power supply "Abnormal" is displayed on the display 73 (step S16), and the process proceeds to step S19.

  On the other hand, when there is no abnormality in the charging power supply 70 (step S15: No), the abnormality determiner 72 compares the reference value with the detection values of the respective DC voltage detectors 25, 26, 35, 36, It is determined whether there is a deviation greater than a predetermined threshold between the reference value and the detection value (step S17). In the present embodiment, the abnormality determiner 72 detects detected values of the four DC voltage detectors 25, 26, 35, 36 at all of a plurality of time points (for example, eight time points T1 to T8 shown in FIG. 2). And the difference between the reference value and the reference value.

  As a result, when there is a deviation larger than the predetermined threshold between the reference value and the detection value (step S17: Yes), the abnormality determiner 72 detects the detected value having the deviation larger than the predetermined threshold. The controller 73 determines that the DC voltage detector that has output a fault is abnormal, and causes the display 73 to display information ("DC voltage detector fault") indicating that the DC voltage detector is faulty (step S18). To step S19.

  In step S19, the abnormality determiner 72 causes the display 73 to display the sentence "Please check and replace the abnormal part", and the process ends.

  On the other hand, when there is only deviation between the reference value and the detected value (step S17: No), it means that there is no abnormality in each of the DC voltage detectors 25, 26, 35, 36. Because of this, the abnormality determiner 72 ends the abnormality determination process.

  As described above, in the power conversion device 100 according to the first embodiment, the abnormality of the DC voltage detector is determined from the behavior of the output (detected value) of the DC voltage detector at the time of initial charge, which is normally performed, and there is an abnormality. Since the display to recommend the inspection and replacement of the DC voltage detector is performed, it is possible to encourage the DC voltage detector to be inspected and replaced before the operation, and also the system of the system due to the abnormality of the DC voltage detector. Unplanned shutdown can be prevented in advance.

  In the first embodiment described above, for example, in the case where data calculated in advance is used as reference data, the condition assumed at the time of calculation in advance differs from the condition assumed at the actual place where the power conversion device 100 is arranged. There is a possibility. In this case, if reference data calculated in advance is used, there is a risk that the abnormality judgment of the DC voltage detector may be erroneous due to an error of the reference data.

  On the other hand, for example, when the DC voltage detection value of power conversion device 100 is normal (for example, at the time of installation of power conversion device 100, etc.), the behavior (time Data of changes (for example, values at a plurality of points in time) may be acquired and stored in the memory 72a, and this data may be used as reference data. In this way, the reference data can be data adapted to the actual state of the power conversion device 100, and the risk of misjudgment can be reduced.

  Further, in the above-described first embodiment, for example, since the outputs of the DC voltage detectors 25, 26, 35, 36 are affected by the fluctuation of the voltage of the charging power supply 70, the DC voltage is changed by the fluctuation of the voltage of the charging power supply 70. There is a risk that the detector's abnormality is misjudged.

  On the other hand, for example, the fluctuation amount of the voltage of the charging power supply 70 at the time of charging is input to the abnormality judging unit 72, and the abnormality judging unit 72 calculates the value of the reference data according to the input fluctuation amount. The correction may be made by (for example, a coefficient may be multiplied) and the abnormality of the DC voltage detector may be determined using the corrected value (correction reference value). In this way, the risk of misjudgment due to the amount of fluctuation of the voltage of the charging power supply 70 during charging can be reduced.

  In the first embodiment described above, the reference data is compared with the detection values of the DC voltage detectors 25, 26, 35, 36 to detect an abnormality in the DC voltage detectors 25, 26, 35, 36. For example, the abnormality of the four DC voltage detectors 25, 26, 35, 36 is detected by comparing the detection values of the DC voltage detectors 25, 26, 35, 36 with each other. You may do it.

  This is based on the fact that the behavior of the detection values of the DC voltage detectors 25, 26, 35, 36 basically agrees if normal, even if the voltage of the charging power supply 70 fluctuates. If the behavior of the detection value of one DC voltage detector differs from the behavior of the detection values of many other DC voltage detectors, then the DC voltage detector that outputs detection values of different behavior is abnormal. It can be judged.

  Specifically, the abnormality determiner 72 includes all combinations of two DC voltage detectors in all the DC voltage detectors 25, 26, 35, 36 (in the case of four DC voltage detectors, six ways). The difference (or ratio) of the detection values of the two DC voltage detectors is calculated, and if there are a plurality of combinations in which the difference (or ratio) of the detection values exceeds a predetermined range, the plurality of combinations are common It is determined that the direct current voltage detector is abnormal. In this way, an abnormal DC voltage detector can be identified without storing reference data, and there is no influence even if the voltage of the charging power supply 70 fluctuates during charging.

  Next, a power converter according to a second embodiment will be described.

  FIG. 4 is an entire configuration diagram of a power conversion device according to a second embodiment. The same components as those of the power conversion device according to the first embodiment shown in FIG. 1 are denoted by the same reference numerals.

  The power conversion device 101 according to the second embodiment is the power conversion device 100 according to the first embodiment, except that the converter neutral point resistor 24 and the inverter neutral point resistor 34 are removed, and a converter-side smoothing capacitor 22; The potential between the electrodes of the smoothing capacitor 32 on the inverter side is detected by the common DC voltage detector 43, and the potential between the electrodes of the smoothing capacitor 23 on the converter side and the smoothing capacitor 33 on the inverter side is common DC voltage Detector 44 to detect.

  Also in the power conversion device 101, the abnormality judgment unit 72 performs processing similar to that in the first embodiment (for example, comparison with reference data) based on the detection values by the DC voltage detector 43 and the DC voltage detector 44 during charging. By performing the above, it is possible to appropriately determine the abnormality of the DC voltage detectors 43 and 44.

  Next, a power converter according to a third embodiment will be described.

  FIG. 5 is an entire configuration diagram of a power conversion device according to a third embodiment. The same components as those of the power conversion device according to the first embodiment shown in FIG. 1 are denoted by the same reference numerals.

  In the power conversion device 100 according to the first embodiment, the power conversion device 102 according to the third embodiment uses the inverter unit 2 as a two-level inverter, the converter unit 3 as a two-level converter, and the smoothing capacitors 22 and 23 on the converter side. The potential between the electrodes of the above is detected by the direct current voltage detector 27, and the potential between the electrodes of the smoothing capacitors 32 and 33 on the inverter side is detected by the direct current voltage detector 37.

  Also in the power conversion device 102, the abnormality judgment unit 72 performs the same processing (for example, comparison with reference data) as in the first embodiment based on the detection values by the DC voltage detector 27 and the DC voltage detector 37 at the time of charging. By performing the above, it is possible to appropriately determine the abnormality of the DC voltage detectors 27, 37.

  Next, a power converter according to a fourth embodiment will be described.

  FIG. 6 is an entire configuration diagram of a power conversion device according to a fourth embodiment. The same components as those of the power conversion device according to the third embodiment shown in FIG. 5 are designated by the same reference numerals.

  The power conversion device 103 according to the fourth embodiment is the same as the power conversion device 102 according to the third embodiment, except that the potential between the electrodes of the smoothing capacitors 22 and 23 on the converter side and the voltage between the electrodes of the smoothing capacitors 32 and 33 on the inverter side. And a common DC voltage detector 27 for detecting the electric potential of the

  Also in the power conversion device 103, the abnormality determiner 72 performs the same processing (for example, comparison with reference data) as in the first embodiment based on the detection value by the DC voltage detector 27 at the time of charging. An abnormality of the DC voltage detector 27 can be appropriately determined.

  Next, a power converter according to a fifth embodiment will be described.

  FIG. 7 is an entire configuration diagram of a power conversion device according to a fifth embodiment. The same components as those of the power conversion device according to the first embodiment shown in FIG. 1 are denoted by the same reference numerals.

  The power conversion device 104 according to the fifth embodiment is obtained by newly providing an output estimator 74 in the power conversion device 100 according to the first embodiment.

  The output estimator 74 accurately detects the detection target of the abnormal DC voltage detector based on the detected values from the plurality of DC voltage detectors 25, 26, 35, 36. Estimate the detected value). The output estimator 74 may be configured by a processor (not shown) executing a program stored in the memory.

  Here, in the method of estimating the accurate detection value of the detection target of the DC voltage detector that has become abnormal, in the power conversion device 104, if each DC voltage detector is in a normal state, the DC current on the converter side The composite DC voltage value obtained by adding the detection values of the voltage detectors 25 and 26 uses the relationship that it matches the composite DC voltage value obtained by adding the detection values of the DC voltage detectors 35 and 36 on the inverter side. Due to such a relationship, when any one DC voltage detector becomes abnormal, a combined DC voltage value obtained by adding the detection values of the two DC voltage detectors on the sound side (converter side or inverter side) From the above, by subtracting the detection value of one healthy DC voltage detector on the other side, the accurate detection value of the measurement object of the abnormal DC voltage detector can be estimated.

  Next, the specific configuration and operation of the output estimator 74 will be described.

  FIG. 8 is a configuration diagram of a part including an output estimator of the power conversion device according to the fifth embodiment. In FIG. 8, the detection value of the DC voltage detector 25 is EPFB_c, the detection value of the DC voltage detector 26 is ENFB_c, the detection value of the DC voltage detector 35 is EPFB_i, and the detection value of the DC voltage detector 36 is ENFB_i. And Further, FIG. 8 shows an example in the case where the direct current voltage detector 26 has an abnormality.

  The abnormality determiner 72 includes a detection value (EPFB_c) of the DC voltage detector 25, a detection value (ENFB_c) of the DC voltage detector 26, a detection value (EPFB_i) of the DC voltage detector 35, and a DC voltage detector 36. When it is determined that one of the DC voltage detectors is abnormal, the output estimation unit 74 outputs abnormality determination information indicating the abnormal DC voltage detector to the output estimator 74. In FIG. 8, abnormality determiner 72 determines that DC voltage detector 26 is abnormal and outputs information (ENFB_c abnormality determination information) indicating that DC voltage detector 26 is abnormal to output estimator 74. .

  The output estimator 74 adds the detection value (EPFB_c) of the DC voltage detector 25 and the detection value (ENFB_c) of the DC voltage detector 26 to calculate a combined DC voltage value (VDC_c) on the converter side. Further, the output estimator 74 adds the detection value (EPFB_i) of the DC voltage detector 35 and the detection value (ENFB_i) of the DC voltage detector 36 to calculate a composite DC voltage value (VDC_i) on the inverter side. Do.

  The output estimator 74 subtracts the detection value (EPFB_c) of the DC voltage detector 25 from the combined DC voltage value (VDC_i) on the inverter side, and is estimated to be detected by the DC voltage detector 26 if normal. Calculate the estimated value (EPFB_c).

  The selector 74a of the output estimator 74 receives the detected value (ENFB_c) of the DC voltage detector 26 and the estimated value (EPFBH_c) of the DC voltage detector 26 as input, and the DC voltage detector 26 receives When there is an input of information that it is abnormal (ENFB_c abnormality judgment information), the estimated value (EPFBH_c) of the DC voltage detector 26 is selected, and to the predetermined transmission destination (in this example, converter control device 5) If it outputs and does not input information (ENFB_c abnormality determination information) indicating that the DC voltage detector 26 is abnormal from the abnormality determiner 72, the detection value (ENFB_c) of the DC voltage detector 26 is selected and predetermined. Output to the destination of

  With such a configuration, when there is an abnormality in the DC voltage detector 26, it is possible to change to the detection value of the DC voltage detector 26 and output an appropriate estimated value. Although FIG. 8 shows the related configuration when there is an abnormality in DC voltage detector 26, the same configuration is applied to other DC voltage detectors, and an appropriate estimation is performed when there is an abnormality. You can output the value.

  For example, the DC voltage detector 25 may be replaced with the DC voltage detector 25. Also, in the case of the DC voltage detector 35 or the DC voltage detector 36, the detection value of the DC voltage detector is subtracted from the combined DC voltage value (VDC_c) on the converter side to estimate the DC voltage detector A value may be calculated and input to the selection unit 74a, and the value selected by the selection unit 74a may be output to the inverter control device 6.

  As described above, in the power conversion device 104 according to the fifth embodiment, when it is determined that there is an abnormality in the DC voltage detector, the detected value of a healthy DC voltage detector other than the DC voltage detector having an abnormality is used. Since the normal detection value of the detection target in the abnormal DC voltage detector is estimated on the basis of the abnormality, the power converter 104 can be used without replacing the abnormal DC voltage detector, for example, And, the continuous operation of the power conversion device can be performed until the next periodical inspection, and the continuous operation can be performed. Thus, there is no need to stop the power conversion device 104 unplanned.

  Next, a power converter according to a sixth embodiment will be described.

  FIG. 9 is an entire configuration diagram of a power conversion device according to a sixth embodiment. The same components as those of the power conversion device according to the fifth embodiment shown in FIG. 7 are denoted by the same reference numerals.

  The power conversion device 105 according to the sixth embodiment is configured to include a plurality of inverter units 3 (3a, 3b, 3c,...) In the power conversion device 104 according to the fifth embodiment.

  In the present embodiment, the output estimator 74 detects a plurality of DC voltage detectors 25, 26, 35 (35a, 35b, 35c, ...), 36 (36a, 36b, 36c, ...). Based on the value, an accurate detection value of the abnormal detection target of the DC voltage detector is estimated. In the sixth embodiment, there are a plurality of methods for estimating the accurate detection value of the detection target of the DC voltage detector that has become abnormal as shown below.

  In power converter 105, if each DC voltage detector is in a normal state, a composite DC voltage value obtained by adding the detection values of DC voltage detectors 25 and 26 on the converter side, and DC voltage on each inverter side There is a relationship that all of the combined DC voltage values obtained by adding the detection values of the detectors 35 (35a, 35b, 35c,...) And 36 (36a, 36b, 36c,...) Match. This indicates that there are a plurality of candidates for obtaining the combined DC voltage value required to estimate the detected value. As described above, since the number of candidates for obtaining the combined DC voltage value increases, it is possible to improve the possibility that the detection value of the detection target of the abnormal DC voltage detector can be estimated.

  According to the output estimator 74 in the present embodiment, when any one of the DC voltage detectors becomes abnormal, the detection values of two healthy DC voltage detectors on the converter side or on either inverter side are added. By subtracting the detection value of one healthy DC voltage detector disposed on the same side as the abnormal DC voltage detector from the combined DC voltage value, the abnormal DC voltage detector is to be measured. Accurate detection values can be estimated.

  Thus, for example, even if one DC voltage detector on any inverter side is abnormal, and one DC voltage detector on the converter side is abnormal, either inverter side If the two DC voltage detectors are normal, the combined DC voltage value obtained by adding the detection values of the two DC voltage detectors is used to detect the detection target of one abnormal DC voltage detector on the inverter side. Accurate detection values can be estimated.

  Also in the power conversion device 105, the abnormality of the DC voltage detector can be appropriately determined by the same processing as the power conversion device 100 according to the first embodiment. Further, in the power conversion device 105 as well as the power conversion device 104 according to the fifth embodiment, the detection value of the detection target of the abnormal DC voltage detector is detected from the detection values of the plurality of sound DC voltage detectors. It can be properly estimated.

  In the sixth embodiment, the power conversion device 105 is provided with the plurality of inverter units 3. However, for example, a plurality of converter units 2 may be provided. Properly detect the abnormality of the direct current voltage detector, and appropriately estimate the detection value of the detection target of the abnormal direct current voltage detector from the detection values of the plurality of sound direct current voltage detectors it can. Moreover, the candidate which can obtain the synthetic | combination DC voltage value required in order to estimate the detection value of the detection object of an abnormal DC voltage detector can be extended to two DC voltage detectors on either converter side. The possibility of being able to estimate the detection value of the detection target of the abnormal DC voltage detector can be improved.

  The present invention is not limited to the embodiments described above, and can be appropriately modified and implemented without departing from the spirit of the present invention.

  For example, in the above embodiment, a part or all of the processing performed by the abnormality determiner 72 and the output estimator 74 may be performed by a hardware circuit.

  Further, in any of the above-described embodiments, the abnormality determiner 72 stores the history (for example, the execution date and time and the detected value) of the detection value by the DC voltage detector at a plurality of charging times, and based on the history of the detection value. To determine the change in detection value by the DC voltage detector, and to predict the period until the detection value by the DC voltage detector exceeds a predetermined threshold for judging abnormality, that is, the period until abnormality occurrence, The prediction result may be displayed on the display 73. In this way, it is possible to know in advance the time of occurrence of an abnormality, and to prevent the occurrence of an abnormality and prepare in advance to cope with the occurrence of an abnormality.

  DESCRIPTION OF SYMBOLS 2 ... Converter unit, 3 ... Inverter unit, 4 ... Electric motor, 5 ... Converter control apparatus, 6 ... Inverter control apparatus, 22 ... Converter P side smoothing capacitor, 23 ... Converter N side smoothing capacitor, 24 ... Converter neutral point resistance, 25: converter P side DC voltage detector 26: converter N side DC voltage detector 32: inverter P side smoothing capacitor 33: inverter N side smoothing capacitor 34: inverter neutral point resistance 35: inverter P side DC Voltage detector, 36: inverter N side DC voltage detector, 72: abnormality determiner, 73: display, 74: output estimator, 100, 101, 102, 103, 104, 105: power converter

Claims (15)

A power converter comprising: a converter for converting alternating current into a plurality of potentials; and an inverter for converting voltages of the plurality of potentials into alternating current,
A smoothing capacitor connected between two of the plurality of potentials for suppressing potential fluctuation between the potentials;
A DC voltage detector for detecting a potential difference between the potentials to which the smoothing capacitor is connected;
An abnormality determiner that determines an abnormality of the DC voltage detector based on a value detected by the DC voltage detector when the smoothing capacitor is charged;
Power converter comprising: The abnormality determiner includes a storage unit that stores a reference value of the detection value of the DC voltage detector when the smoothing capacitor is charged,
The power conversion device according to claim 1, wherein the abnormality determination unit determines an abnormality of the direct current voltage detector based on the reference value stored in the storage unit and the detection value. The power conversion device according to claim 2, wherein the abnormality determiner stores the detection value of the DC voltage detector at the time of charging of the smoothing capacitor at a predetermined time point as the reference value in the storage unit. The power conversion device according to claim 2, wherein the abnormality determiner stores reference values of detection values of the DC voltage detector at a plurality of time points during the charging in a storage unit. The abnormality determiner acquires voltage information indicating a charging voltage at the time of charging, calculates a correction reference value obtained by correcting the reference value based on the voltage information, and determines the direct current based on the correction reference value. The power converter according to any one of claims 2 to 4 which judges abnormalities of a voltage detector. The smoothing capacitor is a converter-side smoothing capacitor connected between two of the plurality of potentials on the converter side, and an inverter-side smoothing connected between two of the plurality of potentials on the inverter side Including a capacitor
The DC voltage detector includes a converter DC voltage detector for detecting a potential difference between potentials connected with the converter smoothing capacitor, and an inverter DC for detecting a potential difference between potentials connected with the inverter smoothing capacitor A voltage detector, and
The abnormality determiner is based on a value detected by the converter-side DC voltage detector and a value detected by the inverter-side DC voltage detector when charging the converter-side smoothing capacitor and the inverter-side smoothing capacitor. The power conversion device according to any one of claims 1 to 5, which determines an abnormality between a converter-side DC voltage detector and the inverter-side DC voltage detector. The converter converts the alternating current into a first potential, a second potential lower than the first potential, and a third potential lower than the second potential.
The inverter converts voltages of the first potential, the second potential, and the third potential into alternating current,
A first smoothing capacitor connected between the first potential and the second potential;
A second smoothing capacitor connected between the second potential and the third potential;
A first DC voltage detector that detects a potential difference between the potentials to which the first smoothing capacitor is connected;
A second DC voltage detector for detecting a potential difference between the potentials to which the second smoothing capacitor is connected,
The abnormality determiner determines the first direct current voltage based on values detected by the first direct current voltage detector and the second direct current voltage detector when charging the first smoothing capacitor and the second smoothing capacitor. The power converter according to any one of claims 1 to 5 which judges abnormalities of a detector and the 2nd direct current voltage detector. The abnormality determiner determines that the charging circuit is abnormal when the voltage values by the first DC voltage detector and the second DC voltage detector at a plurality of time points during the charging are zero or near zero. The power converter according to claim 7, which determines that When the voltage value by any one of the first DC voltage detector and the second DC voltage detector at a plurality of time points during the charging is zero, the abnormality determiner determines whether the voltage value is zero or near zero. The power converter according to claim 7, which judges that the wiring connected to the DC voltage detector is abnormal. And a resistor connected between the second potential on the inverter side and the second potential on the converter side,
The first smoothing capacitor includes a first converter-side smoothing capacitor connected between the first potential and the second potential on the converter side, and the first potential and the second potential on the inverter side. And a first inverter-side smoothing capacitor connected between
The second smoothing capacitor includes a second converter-side smoothing capacitor connected between the second potential and the third potential on the converter side, and the second potential and the third potential on the inverter side. And a second inverter-side smoothing capacitor connected between
The first DC voltage detector detects a potential difference between potentials to which the first converter side smoothing capacitor is connected, and a potential between the first inverter side smoothing capacitor is connected to the first converter side DC voltage detector. A first inverter-side DC voltage detector for detecting a potential difference between
The second DC voltage detector detects a potential difference between the potentials to which the second converter side smoothing capacitor is connected, and a potential between the second inverter side smoothing capacitor to which the second converter side smoothing capacitor is connected. And a second inverter-side DC voltage detector for detecting a potential difference between
The abnormality determiner is configured to charge the first converter-side smoothing capacitor, the second converter-side smoothing capacitor, the first inverter-side smoothing capacitor, and the second inverter-side smoothing capacitor. A first converter-side DC voltage detector based on values detected by a detector, the second converter-side DC voltage detector, the first inverter-side DC voltage detector, and the second inverter-side DC voltage detector; The abnormality determination method according to any one of claims 7 to 9, wherein abnormality of the second converter side DC voltage detector, the first inverter side DC voltage detector, and the second inverter side DC voltage detector is determined. Power converter. The abnormality determiner detects each of the first converter side DC voltage detector, the second converter side DC voltage detector, the first inverter side DC voltage detector, and the second inverter side DC voltage detector. Values of the first converter side DC voltage detector, the second converter side DC voltage detector, the first inverter side DC voltage detector, or the second inverter side DC voltage detector The power converter according to claim 10, wherein the abnormal DC voltage detector is identified. Occurrence of abnormality based on detection values by the first converter side DC voltage detector, the second converter side DC voltage detector, the first inverter side DC voltage detector, and the second inverter side DC voltage detector The power conversion device according to claim 10, further comprising: an output estimation unit configured to estimate a detection value of a detection target of the DC voltage detector. The power conversion device according to any one of claims 1 to 12, wherein the abnormality determiner causes the display device to display information related to the abnormality when determining the occurrence of the abnormality. The abnormality determiner stores a history of values detected by the DC voltage detector at a plurality of times of charging, and predicts, based on the history of the detected values, a period until an abnormality occurs in the DC voltage detector. The power conversion device according to claim 13, wherein the result is displayed on the display device. A converter for converting alternating current to a plurality of potentials, an inverter for converting voltages of a plurality of potentials to an alternating current, and two of the plurality of potentials, which are connected between two potentials and smoothed to suppress potential fluctuations among the potentials. A method of detecting an abnormality in a power conversion device, comprising: a capacitor; and a DC voltage detector that detects a potential difference between the potentials to which the smoothing capacitor is connected,
Acquiring a detection value by the DC voltage detector at the time of charging of the smoothing capacitor;
The abnormality detection method which judges the abnormality of the said DC voltage detector based on the acquired said detected value.