JP7380206B2 - power converter - Google Patents

Description

The present invention relates to a power conversion device including a semiconductor switch.

There is a known technology that allows continued operation even if a cell converter installed in a modular multilevel cascade converter as a next-generation transformerless power converter suitable for large-capacity, high-voltage applications fails (for example, Patent Document 1).

Japanese Patent Application Publication No. 2012-147613

Conventional power conversion equipment cannot continue rated operation if two or more cell converters in multiple clusters fail simultaneously, or if two or more cell converters in the same cluster fail at the same time. The problem is that it cannot be done.

The purpose of the present invention is to be able to continue rated operation even if two or more cell converters in multiple clusters fail at the same time, or even if two or more cell converters in the same cluster fail at the same time. An object of the present invention is to provide a power conversion device.

In order to achieve the above object, a power conversion device according to one aspect of the present invention includes a power conversion unit having two external output terminals from which a positive voltage and a negative voltage are output, and a power conversion unit that connects the two external output terminals. a plurality of clusters formed by connecting a plurality of cell converters in series each including a bypass switch provided so as to be short-circuitable; a spare cell converter group having a plurality of spare cell converters each having the power conversion section; a switch group having a plurality of switches for connecting a cluster and the spare cell converter group; a failure detection unit that determines a failure of the cell converter and outputs a failure signal; and a failure signal of the failure detection unit. Based on this, the bypass switches of the plurality of cell converters concerned are short-circuited, and a switch selected from the switch group is controlled to connect each of the spare cell converters in place of the short-circuited plurality of cell converters. The spare cell converter group includes a first spare cell converter, a second spare cell converter, and a third spare cell converter, and the switch group is connected to any one of the plurality of clusters. a first switch unit that can be connected to the first spare cell converter; a second switch unit that can connect any one of the plurality of clusters to the second spare cell converter; and one of the plurality of clusters. a third switch unit connectable with the third spare cell converter; and a positive electrode side and a neutral side of any one of the first spare cell converter, the second spare cell converter, and the third spare cell converter. a fourth switch unit that is connectable to the neutral point, and a negative electrode side of any one of the first spare cell converter, the second spare cell converter, and the third spare cell converter to the neutral point. a fifth switch section, a negative side of the first spare cell converter, a positive side of the second spare cell converter, a negative side of the second spare cell converter and a positive side of the third spare cell converter, and a sixth switch part to which at least one of the above can be connected .

According to one aspect of the present invention, rated operation can be maintained even when two or more cell converters across multiple clusters fail simultaneously or when two or more cell converters fail simultaneously within the same cluster. Can be continued.

1 is a circuit block diagram showing an example of a schematic configuration of a power conversion device according to an embodiment of the present invention. FIG. 2 is a circuit diagram showing an example of a schematic configuration of a cell converter and a spare cell converter included in a power conversion device according to an embodiment of the present invention. FIG. 6 is a diagram for explaining example 2 of switching the switch group when a cell converter included in the power conversion device according to an embodiment of the present invention fails. FIG. 7 is a diagram for explaining another example of switching example 2 of the switch group when a cell converter included in the power conversion device according to an embodiment of the present invention fails. FIG. 7 is a diagram for explaining example 3 of switching a switch group when a cell converter included in a power conversion device according to an embodiment of the present invention fails. FIG. 7 is a diagram for explaining another example of switching example 3 of the switch group when a cell converter included in the power conversion device according to an embodiment of the present invention fails. FIG. 7 is a diagram for explaining example 4 of switching the switch group when a cell converter included in the power conversion device according to an embodiment of the present invention fails. FIG. 7 is a diagram for explaining another example of switch group switching example 4 when a cell converter included in the power conversion device according to an embodiment of the present invention fails. FIG. 7 is a diagram for explaining example 5 of switching a switch group when a cell converter included in a power converter according to an embodiment of the present invention fails.

A power conversion device according to an embodiment of the present invention will be described using FIGS. 1 to 9. The power conversion device according to the present embodiment will be described by taking as an example a three-phase modular multilevel converter (MMC) that can be connected to a power grid.

(power control system)
A power control system using the power converter according to this embodiment will be described using FIG. 1. FIG. 1 is a circuit block diagram showing a schematic configuration of a power control system PS in which a power conversion device 1 according to the present embodiment is used.

As shown in FIG. 1, the power control system PS includes a three-phase power system 2, a load device (not shown) that operates using power supplied from the three-phase power system 2, and a load device (not shown) that is connected to the three-phase power system 2. The power converter 1 is equipped with a power converter 1 that is connected to the power converter 1. The three-phase power system 2 includes a three-phase AC power source (not shown) that generates three-phase AC power, and a cable 21 to which the power generated by the three-phase AC power source is supplied. The cable 21 includes a U-phase cable 211 to which U-phase AC power generated by a three-phase AC power source is supplied, and a V-phase cable 212 to which V-phase AC power generated by a three-phase AC power source is supplied. It has a W-phase cable 213 to which W-phase AC power generated by a three-phase AC power supply is supplied.

(Power converter)
Next, the configuration of the power conversion device 1 provided in the power control system PS will be explained using FIGS. 1 and 2.
As shown in FIG. 1, the power converter 1 according to the present embodiment includes a cluster unit 3 connected to a three-phase power system 2, and a spare cell converter group 5 that is used when the cluster unit 3 fails. , a switch group 7 that appropriately connects the cluster unit 3 and the spare cell converter group 5, and a control device (an example of a control unit) 9 that controls the cluster unit 3, the spare cell converter group 5, and the switch group 7. ing.

The cluster unit 3 includes a bypass switch that is provided to short-circuit between the power conversion unit EPC, which has two external output terminals T1 and T2 from which positive voltage and negative voltage are output, and the two external output terminals T1 and T2. Sw_b includes a U-phase cluster (an example of a first cluster) 31u formed by connecting a plurality of cell converters 31u-1, 31u-2, and 31u-3 in series. In addition, in FIG. 1 and FIGS. 3 to 9 described later, the reference numbers of the power conversion unit EPC, external output terminals T1, T2, and bypass switch Sw_b are the cell converter 31u-1 and the first spare cell converter 51 (details). (described later) is attached only to The U-phase cluster 31u has a reactor 31uL connected between the U-phase cable 211 of the three-phase power system 2 and the cell converter 31u-1. More specifically, one terminal of the reactor 31uL is connected to the U-phase cable 211, and the other terminal of the reactor 31uL is connected to the external output terminal T1 of the cell converter 31u-1. External output terminal T2 of cell converter 31u-1 is connected to external output terminal T1 of cell converter 31u-2. External output terminal T2 of cell converter 31u-2 is connected to external output terminal T1 of cell converter 31u-3. In the cell converters 31u-1, 31u-2, and 31u-3, for example, the external output terminal T1 side becomes the positive electrode side, and the external output terminal T2 side becomes the negative electrode side. Although details will be described later, the external output terminal T2 of the cell converter 31u-3 is connected to the switch group 7.

The cluster unit 3 includes a bypass switch that is provided to short-circuit between the power conversion unit EPC, which has two external output terminals T1 and T2 from which positive voltage and negative voltage are output, and the two external output terminals T1 and T2. Sw_b includes a V-phase cluster (an example of a second cluster) 31v formed by connecting a plurality of cell converters 31v-1, 31v-2, and 31v-3 in series. The V-phase cluster 31v has a reactor 31vL connected between the V-phase cable 212 of the three-phase power system 2 and the cell converter 31v-1. More specifically, one terminal of reactor 31vL is connected to V-phase cable 212, and the other terminal of reactor 31vL is connected to external output terminal T1 of cell converter 31v-1. External output terminal T2 of cell converter 31v-1 is connected to external output terminal T1 of cell converter 31v-2. External output terminal T2 of cell converter 31v-2 is connected to external output terminal T1 of cell converter 31v-3. In the cell converters 31v-1, 31v-2, and 31v-3, for example, the external output terminal T1 side becomes the positive electrode side, and the external output terminal T2 side becomes the negative electrode side. Although details will be described later, the external output terminal T2 of the cell converter 31v-3 is connected to the switch group 7.

The cluster unit 3 includes a bypass switch that is provided to short-circuit between the power conversion unit EPC, which has two external output terminals T1 and T2 from which positive voltage and negative voltage are output, and the two external output terminals T1 and T2. A W-phase cluster (an example of a third cluster) 31w is provided in which a plurality of cell converters 31w-1, 31w-2, and 31w-3 each having a cell converter Sw_b are connected in series. The W-phase cluster 31w has a reactor 31wL connected between the W-phase cable 213 of the three-phase power system 2 and the cell converter 31w-1. More specifically, one terminal of the reactor 31wL is connected to the W-phase cable 213, and the other terminal of the reactor 31wL is connected to the external output terminal T1 of the cell converter 31w-1. External output terminal T2 of cell converter 31w-1 is connected to external output terminal T1 of cell converter 31w-2. External output terminal T2 of cell converter 31w-2 is connected to external output terminal T1 of cell converter 31w-3. In the cell converters 31w-1, 31w-2, and 31w-3, for example, the external output terminal T1 side becomes the positive electrode side, and the external output terminal T2 side becomes the negative electrode side. Although details will be described later, the external output terminal T2 of the cell converter 31w-3 is connected to the switch group 7.

The U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w correspond to a plurality of clusters. Regarding the specific configurations of cell converters 31u-1, 31u-2, 31u-3, cell converters 31v-1, 31v-2, 31v-3, and cell converters 31w-1, 31w-2, 31w-3 will be described later.

The power conversion device 1 includes a spare cell converter group 5 having a plurality of spare cell converters each including a power converter EPC having two external output terminals T1 and T2 from which a positive voltage and a negative voltage are output. . In this embodiment, each of the spare cell converters included in the spare cell converter group 5 has a bypass switch Sw_b that is provided to short-circuit between the two external output terminals T1 and T2. The spare cell converter group 5 includes, for example, a first spare cell converter 51, a second spare cell converter 52, and a third spare cell converter 53 as a plurality of spare cell converters. In this embodiment, the spare cell converter group 5 includes, for example, a first spare cell converter 51, a second spare cell converter 52, and a third spare cell converter 53 as a plurality of spare cell converters. There is. In the first spare cell converter 51, the second spare cell converter 52, and the third spare cell converter 53, for example, the external output terminal T1 side becomes the positive electrode side, and the external output terminal T2 side becomes the negative electrode side. The specific configurations of the first spare cell converter 51, the second spare cell converter 52, and the third spare cell converter 53 will be described later.

The power conversion device 1 includes a switch group 7 having a plurality of switches for connecting the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w to the spare cell converter group 5.

More specifically, the switch group 7 includes a first switch unit 71 that can connect the first spare cell converter 51 to any one of the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w. . The switch group 7 also includes a second switch section 72 that can connect the second spare cell converter 52 to any one of the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w. The switch group 7 also includes a third switch section 73 that can connect the third spare cell converter 53 to any one of the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w. Further, the switch group 7 can connect the positive electrode side of any one of the first spare cell converter 51, the second spare cell converter 52, and the third spare cell converter 53 to the neutral point N (details will be described later). It has a fourth switch section 74. Further, the switch group 7 includes a fifth switch unit capable of connecting the positive electrode side of any one of the first spare cell converter 51, the second spare cell converter 52, and the third spare cell converter 53 to the neutral point N. 75. Furthermore, the switch group 7 includes a negative electrode side of the first spare cell converter 51, a positive electrode side of the second spare cell converter 52, a negative electrode side of the second spare cell converter 52, and a positive electrode side of the third spare cell converter 53. It has a sixth switch section 76 to which at least one of the following can be connected.

The first switch unit 71 includes a switch Sw_u1, a switch Sw_v1, and a switch Sw_w1. One terminal of the switch Sw_u1 is connected to an external output terminal T2 of a cell converter 31u-3 provided in the U-phase cluster 31u. One terminal of the switch Sw_v1 is connected to an external output terminal T2 of a cell converter 31v-3 provided in the V-phase cluster 31v. One terminal of the switch Sw_w1 is connected to an external output terminal T2 of a cell converter 31w-3 provided in the W-phase cluster 31w. The other terminal of the switch Sw_u1, the other terminal of the switch Sw_v1, and the other terminal of the switch Sw_w1 are connected to each other and connected to the external output terminal T1 of the first spare cell converter 51.

The second switch unit 72 includes a switch Sw_u2, a switch Sw_v2, and a switch Sw_w2. One terminal of the switch Sw_u2 is connected to the external output terminal T2 of the cell converter 31u-3. One terminal of the switch Sw_v2 is connected to the external output terminal T2 of the cell converter 31v-3. One terminal of the switch Sw_w2 is connected to the external output terminal T2 of the cell converter 31w-3. The other terminal of the switch Sw_u2, the other terminal of the switch Sw_v2, and the other terminal of the switch Sw_w2 are connected to each other and connected to the external output terminal T1 of the second spare cell converter 52.

The third switch unit 73 includes a switch Sw_u3, a switch Sw_v3, and a switch Sw_w3. One terminal of the switch Sw_u3 is connected to the external output terminal T2 of the cell converter 31u-3. One terminal of the switch Sw_v3 is connected to the external output terminal T2 of the cell converter 31v-3. One terminal of the switch Sw_w3 is connected to the external output terminal T2 of the cell converter 31w-3. The other terminal of the switch Sw_u3, the other terminal of the switch Sw_v3, and the other terminal of the switch Sw_w3 are connected to each other and connected to the external output terminal T1 of the third spare cell converter 53.

The fourth switch unit 74 includes a switch Sw_n_u, a switch Sw_n_v, and a switch Sw_n_w. One terminal of the switch Sw_n_u is connected to an external output terminal T2 of the cell converter 31u-3 and one terminal of each of the switches Sw_u1, Sw_u2, and Sw_u3. One terminal of the switch Sw_n_v is connected to an external output terminal T2 of the cell converter 31v-3 and one terminal of each of the switches Sw_v1, Sw_v2, and Sw_v3. One terminal of the switch Sw_n_w is connected to an external output terminal T2 of the cell converter 31w-3 and one terminal of each of the switches Sw_w1, Sw_w2, and Sw_w3. The other terminal of the switch Sw_n_u, the other terminal of the switch Sw_n_v, and the other terminal of the switch Sw_n_w are connected to each other.

The fifth switch unit 75 includes a switch Sw_n_1, a switch Sw_n_2, and a switch Sw_n_3. One terminal of the switch Sw_n_1 is connected to the external output terminal T2 of the first spare cell converter 51. One terminal of the switch Sw_n_2 is connected to the external output terminal T2 of the second spare cell converter 52. One terminal of the switch Sw_n_3 is connected to the external output terminal T2 of the third spare cell converter 53. The other terminal of the switch Sw_n_1, the other terminal of the switch Sw_n_2, and the other terminal of the switch Sw_n_3 are connected to each other and to the other terminals of the switches Sw_n_u, Sw_n_v, and Sw_n_w.

The sixth switch section 76 includes a switch Sw_uv and a switch Sw_vw. One terminal of the switch Sw_uv is connected to the other terminals of the switches Sw_u2, Sw_v2, and Sw_w2 of the second switch section 72. The other terminal of the switch Sw_uv is connected to one terminal of the switch Sw_n_1. The other terminal of the switch Sw_uv is also connected to the external output terminal T2 of the first spare cell converter 51. One terminal of the switch Sw_vw is connected to the other terminals of the switches Sw_u3, Sw_v3, and Sw_w3 of the third switch section 73. The other terminal of the switch Sw_vw is connected to one terminal of the switch Sw_n_2. The other terminal of the switch Sw_vw is also connected to the external output terminal T2 of the second spare cell converter 52.

One terminal of the switch Sw_uv is also connected to the external output terminal T1 of the second spare cell converter 52. One terminal of the switch Sw_vw is also connected to the external output terminal T1 of the third spare cell converter 53. Therefore, the sixth switch section 76 can switch between a connected state and a disconnected state between the external output terminal T2 of the first spare cell converter 51 and the external output terminal T1 of the second spare cell converter 52. Further, the sixth switch section 76 can switch between a connected state and a non-connected state between the external output terminal T2 of the second spare cell converter 52 and the external output terminal T1 of the third spare cell converter 53.

Cell converters 31u-1, 31u-2, 31u-3, cell converters 31v-1, 31v-2, 31v-3, cell converters 31w-1, 31w-2, 31w-3, first spare cell conversion The cell converter 51, the second spare cell converter 52, and the third spare cell converter 53 have the same configuration. Therefore, cell converters 31u-1, 31u-2, 31u-3, cell converters 31v-1, 31v-2, 31v-3, cell converters 31w-1, 31w-2, 31w-3, and the first spare The specific circuit configurations of the cell converter 51, the second spare cell converter 52, and the third spare cell converter 53 will be explained by taking the cell converter 31u-1 as an example.

As shown in FIG. 2, the cell converter 31u-1 includes a power converter EPC having external output terminals T1 and T2, and a bypass switch Sw_b provided to short-circuit between the external output terminals T1 and T2. are doing. The power conversion unit EPC includes a bridge unit BG having a plurality of bridge-connected semiconductor switches Qa, Qb, Qc, and Qd, and a DC capacitor C connected in parallel to the bridge unit BG.

More specifically, the power conversion unit EPC includes a plurality of semiconductor modules Ma and a semiconductor module Mb connected in series (two in this embodiment), and a plurality of semiconductor modules Ma and Mb connected in series (two in this embodiment). It has a semiconductor module Mc and a semiconductor module Md. Semiconductor module Ma and semiconductor module Mb, and semiconductor module Mc and semiconductor module Md are connected in parallel. Further, the cell converter 31u-1 includes a DC capacitor C connected in parallel to the semiconductor modules Ma, Mb and the semiconductor modules Mc, Md.

The semiconductor module Ma includes a semiconductor switch Qa and a freewheeling diode Da connected in antiparallel to the semiconductor switch Qa. The semiconductor module Mb includes a semiconductor switch Qb and a freewheeling diode Db connected in antiparallel to the semiconductor switch Qb. The semiconductor module Mc includes a semiconductor switch Qc and a freewheeling diode Dc connected in antiparallel to the semiconductor switch Qc. The semiconductor module Md includes a semiconductor switch Qd and a freewheeling diode Dd connected in antiparallel to the semiconductor switch Qd.

Therefore, the cell converter 31u-1 includes two semiconductor switches Qa and Qb connected in series and a DC capacitor C connected in parallel to the two semiconductor switches Qa and Qb. Further, the cell converter 31u-1 includes two semiconductor switches Qc, Qc connected in series. Two semiconductor switches Qc, Qc are connected to two semiconductor switches Qa, Qb and a DC capacitor C in parallel.

In this embodiment, the semiconductor switches Qa, Qb, Qc, and Qd are composed of power semiconductor elements, such as n-type SiC-MOSFETs. The drain terminal of the semiconductor switch Qa is connected to the cathode terminal of the freewheeling diode Da, the drain terminal of the semiconductor switch Qc, and the cathode terminal of the freewheeling diode Dc. The source terminal of the semiconductor switch Qa is connected to the anode terminal of the freewheeling diode Da, the drain terminal of the semiconductor switch Qb, and the cathode terminal of the freewheeling diode Db. A gate terminal of the semiconductor switch Qa is connected to a control device 9 (not shown in FIG. 2, see FIG. 1). As a result, the control signal GP_u output from the control device 9 is input to the gate terminal of the semiconductor switch Qa, and the on (conductivity)/off (nonconduction) of the semiconductor switch Qa is controlled.

The source terminal of the semiconductor switch Qb is connected to the source terminal of the semiconductor switch Qd and the anode terminal of the freewheeling diode Dd. A gate terminal of the semiconductor switch Qb is connected to the control device 9. As a result, the control signal GP_u output from the control device 9 is input to the gate terminal of the semiconductor switch Qb, and the on (conductivity)/off (nonconduction) of the semiconductor switch Qb is controlled.

The source terminal of the semiconductor switch Qc is connected to the anode terminal of the freewheeling diode Dc, the drain terminal of the semiconductor switch Qd, and the cathode terminal of the freewheeling diode Dd. A gate terminal of the semiconductor switch Qc is connected to the control device 9. As a result, the control signal GP_u output from the control device 9 is input to the gate terminal of the semiconductor switch Qc, and the on (conductivity)/off (nonconduction) of the semiconductor switch Qc is controlled.

A gate terminal of the semiconductor switch Qd is connected to the control device 9. As a result, the control signal GP_u output from the control device 9 is input to the gate terminal of the semiconductor switch Qd, and the on (conduction)/off (non-conduction) of the semiconductor switch Qd is controlled. Control signals GP_u input to the respective gate terminals of semiconductor switches Qa, Qb, Qc, and Qd are mutually different and independent signals.

One electrode of the DC capacitor C is connected to the drain terminal of the semiconductor switch Qa, the cathode terminal of the freewheeling diode Da, the drain terminal of the semiconductor switch Qc, and the cathode terminal of the freewheeling diode Dc. The other electrode of the DC capacitor C is connected to the source terminal of the semiconductor switch Qb, the anode terminal of the freewheeling diode Db, the source terminal of the semiconductor switch Qd, and the anode terminal of the freewheeling diode Dd.

A connecting portion between the semiconductor module Ma and the semiconductor module Mb is connected to an external output terminal T1 and one terminal of the bypass switch Sw_b. The connection portion between the semiconductor module Mc and the semiconductor module Md is connected to the external output terminal T2 and the other terminal of the bypass switch Sw_b. In this way, the two external output terminals T1 and T2 are connected to the connection part where the DC capacitor C is not connected among the connection parts where the terminals of the plurality of semiconductor switches Qa, Qb, Qc, and Qd are connected. has been done.

Cell converters 31u-1, 31u-2, 31u-3, cell converters 31v-1, 31v-2, 31v-3, cell converters 31w-1, 31w-2, 31w-3, first spare cell conversion The bypass switch Sw_b provided in each of the cell converter 51, the second spare cell converter 52, and the third spare cell converter 53 is composed of, for example, a mechanical switch.

As shown in FIG. 2, the power conversion device 1 includes failure detection units 41a, 41b, 41c, and 41d that determine a failure in the cell converter 31u-1 and output failure signals Fd_a, Fd_b, Fd_c, and Fd_d. There is. The failure detection unit 41a is configured, for example, to output a voltage signal between the drain and source of the semiconductor switch Qa as the failure signal Fd_a. The failure detection unit 41b is configured, for example, to output a voltage signal between the drain and source of the semiconductor switch Qb as the failure signal Fd_b. The failure detection unit 41c is configured, for example, to output a voltage signal between the drain and source of the semiconductor switch Qc as the failure signal Fd_c. The failure detection unit 41a is configured, for example, to output a voltage signal between the drain and source of the semiconductor switch Qa as the failure signal Fd_a. Although illustration is omitted, all the cell converters provided in the power conversion device 1 are equipped with failure detection units 41a, 41b, 41c, and 41d.

Returning to FIG. 1, in the power converter 1, current flows in each of the U-phase cluster 31u, V-phase cluster 31v, and W-phase cluster 31w, and the current flows in each cell of the U-phase cluster 31u, V-phase cluster 31v, and W-phase cluster 31w. It is configured such that the DC voltage of a DC capacitor C provided in the converter is detected and input to the control device 9. The control device 9 outputs the control signal GP_u generated using these currents and voltages to each of the cell converters 31u_1, 31u_2, and 31u-3 provided in the U-phase cluster 31u individually, and outputs the control signal GP_u generated using these currents and voltages to the semiconductor switches Qa, Qb. , Qc, and Qd. Similarly, the control device 9 outputs a control signal GP_v generated using these currents and voltages to each of the cell converters 31v_1, 31v_2, and 31v-3 provided in the V-phase cluster 31v, and outputs the control signal GP_v generated using these currents and voltages to the semiconductor switch. Controls on/off of Qa, Qb, Qc, and Qd. Similarly, the control device 9 outputs the control signal GP_w generated using these currents and voltages to each of the cell converters 31w_1, 31w_2, and 31w-3 provided in the W-phase cluster 31w, and outputs the control signal GP_w generated using these currents and voltages to the semiconductor switch. Controls on/off of Qa, Qb, Qc, and Qd.

Based on the failure signals Fd_a, Fd_b, Fd_c, and Fd_d from the failure detection units 41a, 41b, 41c, and 41d, the control device 9 short-circuits the bypass switches Sw_b of the plurality of corresponding cell converters, and also short-circuits the bypass switches Sw_b selected from the switch group 7. It is configured to control the switches and connect the first spare cell converter 51, the second spare cell converter 52, and the third spare cell converter 53, respectively, in place of the plurality of short-circuited cell converters. The control device 9 controls, for example, semiconductor switches Qa, Qb, Qc, and Qd provided in each of the cell converters 31u-1 to 31u-3, 31v-1 to 31v-3, and 31w-1 to 31w-3. It is determined whether the failure signals Fd_a, Fd_b, Fd_c, Fd_d output from the failure detection unit 41a in response to the control signals GP_u, GP_v, GP_w are at desired voltages. The control device 9 includes failure detection units 41a, 41b, 41c, which output failure signals Fd_a, Fd_b, Fd_c, and Fd_d when at least one of the failure signals Fd_a, Fd_b, Fd_c, and Fd_d is not at a desired voltage. It is determined that the cell converters 31u-1 to 31u-3, 31v-1 to 31v-3, and 31w-1 to 31w-3 having semiconductor switches Qa, Qb, Qc, and Qd, which are detected by 41d, are malfunctioning. do.

The control device 9 outputs a control signal GP_b to each of the U-phase cluster 31u, V-phase cluster 31v, and W-phase cluster 31w individually to control ON (conduction)/off (non-conduction) of the bypass switch Sw_b. It is configured. The control signal GP_b is input to a drive section of a mechanical switch that constitutes the bypass switch Sw_b. When the control device 9 detects the presence or absence of a failure in any of the semiconductor switches Qa, Qb, Qc, and Qd, it turns on the bypass switch Sw_b provided in the cell converter having the failed semiconductor switch. A control signal GP_b is output for this purpose. As a result, the bypass switch Sw_b is turned on, and the external output terminals T1 and T2 to which the bypass switch Sw_b is connected are short-circuited. Therefore, the current flowing through the cell converter having the bypass switch Sw_b does not pass through the power conversion unit EPC but flows through the bypass switch Sw_b. As a result, the power conversion device 1 can exclude a cell converter having a failed semiconductor switch from the cell converters for power conversion.

The control device 9 individually outputs a control signal GP_br to each of the first spare cell converter 51, the second spare cell converter 52, and the third spare cell converter 53 of the spare cell converter group 5 to switch the bypass switch Sw_b. It is configured to control on (conductivity)/off (non-conduction) of.

The control device 9 controls whether or not there is a failure in the semiconductor switches Qa, Qb, Qc, and Qd provided in the U-phase cluster 31u, V-phase cluster 31v, and W-phase cluster 31w (i.e., a failure in the cell converter). A control signal GP_br is output for turning off the bypass switch Sw_b provided in each of the spare cell converter 51, the second spare cell converter 52, and the third spare cell converter 53. The first spare cell converter 51, the second spare cell converter 52, and the third spare cell converter 53 are electrically separated from the cluster unit 3 by the switch group 7 when not in use.

When a failure occurs in a cell converter, the control device 9 controls the U-phase that has the failed cell converter among the first spare cell converter 51, second spare cell converter 52, and third spare cell converter 53. In order to control the power converter EPC of the spare cell converter connected to the cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w, a control signal GP_r is output to the spare cell converter. The spare cell converter to which the control signal GP_r is input can operate in place of the failed cell converter. Since the spare cell converter group 5 has three spare cell converters, the power converter 1 includes the cell converters 31u-1 to 31u-3, 31v-1 to 31v-3, 31w-1 to Even if three of 31w-3 fail at the same time, stable operation can be maintained.

The control device 9 controls the switches Sw_u1, Sw_v1, Sw_w1, Sw_u2, Sw_u2, Sw_v2, Sw_w2, Sw_u3, Sw_v3, Sw_w3, Sw_n_u, Sw_n_v, Sw_n_w, Sw_n_1, Sw_n_2, Sw_n_3, Sw_uv, Sw_vw ( Below, “ The control signal GP_sg is individually output to each of the switches Sw_7 (sometimes collectively referred to as "switch Sw_7") to individually control on (conduction) and off (non-conduction) of the switch Sw_7.

For example, the control device 9 changes any of the switches Sw_7 from an off state to an on state or an on state in response to a failure of the cell converters 31u-1 to 31u-3, 31v-1 to 31v-3, and 31w-1 to 31w-3. A switch group control table that specifies whether to switch from to to off state is stored. When the control device 9 detects a failure in any of the cell converters 31u-1 to 31u-3, 31v-1 to 31v-3, and 31w-1 to 31w-3, it refers to the switch group control table. and select the switch whose state is to be changed from switch Sw_7. The control device 9 outputs a control signal GP_sg to turn on the selected switch. As a result, the necessary number of spare cell converters provided in the spare cell converter group 5 are connected in series to the U-phase cluster 31u, V-phase cluster 31v, and W-phase cluster 31w that have a failed cell converter. . As a result, the power converter 1 can maintain the same number of cell converters connected in series in the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w before and after the failure of the cell converter, and is therefore stable. Can maintain operation.

The control device 9 controls the switch group 7 based on the failure signals Fd_a, Fd_b, Fd_c, and Fd_d from the failure detection units 41a, 41b, 41c, and 41d, and controls the switch group 7 among the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w. A first connection in which a plurality of first spare cell converters 51, second spare cell converters 52, and third spare cell converters 53 are connected in series to one of the U-phase clusters 31u, V-phase clusters 31v, and W-phase The cluster 31w is configured to be able to select a second connection for connecting different first spare cell converters 51, second spare cell converters 52, and third spare cell converters 53 to the cluster 31w.

In the control device 9, the failure detection units 41a, 41b, 41c, and 41d detect the cell converters in the first cluster (one of the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w). If a failure is detected, the first connection is selected, a plurality of selected spare cell converters of the spare cell converter group 5 are connected in series to the first cluster, and the spare cell converter group 5 and the corresponding spare cell converter group 5 are connected in series. The cluster is configured to be connected in series with the first cluster.

For example, when the failure detection units 41a, 41b, 41c, and 41d detect a failure in the cell converters 31u-1 and 31u-2, the control device 9 selects the first connection and selects the spare cell converter group 5. For example, the first spare cell converter 51 and the second spare cell converter 52 are connected in series to the U-phase cluster 31u as the first cluster, and the spare cell converter group 5 and the U-phase cluster are connected in series. . In this case, the control device 9 connects the same number of spare cell converters as the failed cell converters to the cluster having the failed cell converters.

In the control device 9, the failure detection units 41a, 41b, 41c, and 41d are connected to a single cell converter in the first cluster (one cluster among the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w). If a failure of a single cell converter in the second cluster (other clusters among the U-phase cluster 31u, V-phase cluster 31v, and W-phase cluster 31w) is detected, the second connection is selected. The selected first spare cell converter of the spare cell converter group 5 (one spare cell among the first spare cell converter 51, the second spare cell converter 52, and the third spare cell converter 53) converters) are connected in series to the first cluster, and the other of the second spare cell converters (the first spare cell converter 51, the second spare cell converter 52, and the third spare cell converter 53) is connected in series to the first cluster. A spare cell converter) is configured to be connected in series to the second cluster.

For example, when the failure detection units 41a, 41b, 41c, and 41d detect a failure in the cell converters 31u-1 and 31v-1, the control device 9 selects the second connection and selects the spare cell converter group 5. The selected first spare cell converter (for example, the first spare cell converter 51) is directly connected to the U-phase cluster 31u, and the selected second spare cell converter (for example, the second spare cell converter) of the spare cell converter group 5 is connected directly to the U-phase cluster 31u. A spare cell converter 52) is directly connected to the V-phase cluster 31v.

Furthermore, the control device 9 is configured to be able to select the first connection and the second connection simultaneously. In other words, the control device 9 detects that a plurality of cell converters have failed in any one of the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w, and the U-phase cluster 31u, the V-phase cluster 31v, and If a single cell converter (that is, one cell converter) fails in any one of the other clusters among the W-phase clusters 31w, the first connection and the second connection are selected at the same time. In this case, the power conversion device 1 is configured to operate after the cell converter fails, on the condition that the total number of failed cell converters is within the range of the number of spare cell converters provided in the spare cell converter group 5. can also maintain stable operation.

<Maintaining control of stable operation of power converter>
Next, a specific switching example of the switch Sw_7 provided in the switch group 7 for maintaining stable operation when a failure occurs in the cell converter in the power conversion device 1 according to the present embodiment will be explained in FIGS. 1 and 3. This will be explained using FIG.

(Switching example 1)
Switching example 1 is a switch group when none of the cell converters 31u-1 to 31u-3, 31v-1 to 31v-3, and 31w-1 to 31w-3 is out of order (that is, at the start of initial operation). 7 is an example of a switching mode of the switch Sw_7 provided in FIG.

As shown in FIG. 1, the control device 9 provided in the power converter 1 has malfunctioned in all of the cell converters 31u-1 to 31u-3, 31v-1 to 31v-3, and 31w-1 to 31w-3. If not (that is, at the start of the initial operation), the switch Sw_7 provided in the switch group 7 is controlled to be in the following state by referring to the switch group control table, for example.
Switch Sw_u1: Off state Switch Sw_v1: Off state Switch Sw_w1: Off state Switch Sw_u2: Off state Switch Sw_v2: Off state Switch Sw_w2: Off state Switch Sw_u3: Off state Switch Sw_v3: Off state Switch Sw_w3: Off state Switch Sw_n_u: On state Switch Sw_n_v: On state Switch Sw_n_w: On state Switch Sw_n_1: Off state Switch Sw_n_2: Off state Switch Sw_n_3: Off state Switch Sw_uv: Off state Switch Sw_vw: Off state

That is, only the fourth switch section 74 provided in the switch group 7 is turned on. As a result, the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w are connected in a star connection (Y connection). In this way, the switch group 7 can star-connect the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w.

(Switching example 2)
Switching example 2 is an example of a switching mode of the switch Sw_7 provided in the switch group 7 when one cell converter fails. Switching example 2 will be explained using FIG. 3. FIG. 3 shows a case where, for example, the cell converter 31u-1 provided in the U-phase cluster 31u has failed.

As shown in FIG. 3, when the control device 9 determines that the cell converter 31u-1 has failed, it controls the bypass switch Sw_b provided in the cell converter 31u-1 to be on, and also With reference to the control table, the switch Sw_7 provided in the switch group 7 is controlled to be in the following state.
Switch Sw_u1: On state Switch Sw_v1: Off state Switch Sw_w1: Off state Switch Sw_u2: Off state Switch Sw_v2: Off state Switch Sw_w2: Off state Switch Sw_u3: Off state Switch Sw_v3: Off state Switch Sw_w3: Off state Switch Sw_n_u: Off state Switch Sw_n_v: On state Switch Sw_n_w: On state Switch Sw_n_1: On state Switch Sw_n_2: Off state Switch Sw_n_3: Off state Switch Sw_uv: Off state Switch Sw_vw: Off state

As a result, the external output terminal T1 of the first spare cell converter 51 is connected to the external output terminal T2 of the cell converter 31u-3 provided in the U-phase cluster 31u via the switch Sw_u1. As a result, the first spare cell converter 51 is connected in series to the U-phase cluster 31u, so the number of operable cell converters provided in the U-phase cluster 31u is maintained at three. Further, by turning off the switch Sw_n_u and turning on the switch Sw_n_1, the external output terminal T2 of the cell converter 31u-3 is electrically disconnected from the neutral point N, and the first spare cell converter The external output terminal T2 of the device 51 is electrically connected to the neutral point N. The external output terminal T2 of the first spare cell converter 51 corresponds to the end of the U-phase cluster 31u. Therefore, the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w can maintain their star-connected state even after switching the state of the switch Sw_7 provided in the switch group 7. As a result, the power conversion device 1 can operate at the rated value and maintain stable operation even after the cell converter 31u-1 has failed.

(Other examples of switching example 2)
Another example of switching example 2 will be described using FIG. 4. FIG. 4 shows a case where, for example, the cell converter 31v-1 provided in the V-phase cluster 31v has failed.

As shown in FIG. 4, when the control device 9 determines that the cell converter 31v-1 has failed, it controls the bypass switch Sw_b provided in the cell converter 31v-1 to be on, and also With reference to the control table, the switch Sw_7 provided in the switch group 7 is controlled to be in the following state.
Switch Sw_u1: Off state Switch Sw_v1: On state Switch Sw_w1: Off state Switch Sw_u2: Off state Switch Sw_v2: Off state Switch Sw_w2: Off state Switch Sw_u3: Off state Switch Sw_v3: Off state Switch Sw_w3: Off state Switch Sw_n_u: On state Switch Sw_n_v: Off state Switch Sw_n_w: On state Switch Sw_n_1: On state Switch Sw_n_2: Off state Switch Sw_n_3: Off state Switch Sw_uv: Off state Switch Sw_vw: Off state

As a result, the external output terminal T1 of the first spare cell converter 51 is connected to the external output terminal T2 of the cell converter 31v-3 provided in the V-phase cluster 31v via the switch Sw_v1. As a result, the first spare cell converter 51 is connected in series to the V-phase cluster 31v, so the number of operable cell converters provided in the U-phase cluster 31u is maintained at three. Further, by turning off the switch Sw_n_v and turning on the switch Sw_n_1, the external output terminal T2 of the cell converter 31v-3 is electrically disconnected from the neutral point N, and the first spare cell converter The external output terminal T2 of the device 51 is electrically connected to the neutral point N. The external output terminal T2 of the first spare cell converter 51 corresponds to the end of the V-phase cluster 31v. Therefore, the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w can maintain their star-connected state even after switching the state of the switch Sw_7 provided in the switch group 7. As a result, the power conversion device 1 can operate at the rated value and maintain stable operation even after the cell converter 31v-1 has failed.

(Switching example 3)
Switching example 3 is an example of a switching mode of the switch Sw_7 provided in the switch group 7 when cell converters provided in different clusters fail one by one. Switching example 3 will be explained using FIG. 5. For example, FIG. 5 shows a case where the cell converter 31u-1 provided in the U-phase cluster 31u and the cell converter 31v-1 provided in the V-phase cluster 31v fail.

As shown in FIG. 5, when the control device 9 determines that the cell converters 31u-1 and 31v-1 have failed, the control device 9 switches the bypass switch Sw_b provided in each of the cell converters 31u-1 and 31v-1. At the same time, the switch Sw_7 provided in the switch group 7 is controlled to be in the following state by referring to the switch group control table, for example.
Switch Sw_u1: On state Switch Sw_v1: Off state Switch Sw_w1: Off state Switch Sw_u2: Off state Switch Sw_v2: On state Switch Sw_w2: Off state Switch Sw_u3: Off state Switch Sw_v3: Off state Switch Sw_w3: Off state Switch Sw_n_u: Off state Switch Sw_n_v: Off state Switch Sw_n_w: On state Switch Sw_n_1: On state Switch Sw_n_2: On state Switch Sw_n_3: Off state Switch Sw_uv: Off state Switch Sw_vw: Off state

As a result, the external output terminal T1 of the first spare cell converter 51 is connected to the external output terminal T2 of the cell converter 31u-3 provided in the U-phase cluster 31u via the switch Sw_u1. As a result, the first spare cell converter 51 is connected in series to the U-phase cluster 31u, so the number of operable cell converters provided in the U-phase cluster 31u is maintained at three. Further, by turning off the switch Sw_n_u and turning on the switch Sw_n_1, the external output terminal T2 of the cell converter 31u-3 is electrically disconnected from the neutral point N, and the first spare cell converter The external output terminal T2 of the device 51 is electrically connected to the neutral point N.

Further, external output terminal T1 of second spare cell converter 52 is connected to external output terminal T2 of cell converter 31v-3 provided in V-phase cluster 31v via switch Sw_v2. As a result, the second spare cell converter 52 is connected in series to the V-phase cluster 31v, so the number of operable cell converters provided in the V-phase cluster 31v is maintained at three. Further, by turning off the switch Sw_n_v and turning on the switch Sw_n_2, the external output terminal T2 of the cell converter 31v-3 is electrically disconnected from the neutral point N, and the second spare cell converter An external output terminal T2 of the device 52 is electrically connected to the neutral point N.

In this way, the switch group 7 connects the first spare cell converter 51 to the U-phase cluster 31u of the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w, and connects the first spare cell converter 51 to the V-phase cluster 31v. It is possible to connect a cell converter 52. That is, the control device 9 short-circuits the bypass switches Sw_b of the cell converters 31u-1 and 31v-1 based on the failure signals Fd_a, Fd_b, Fd_c, and Fd_d of the failure detection units 41a, 41b, 41c, and 41d, and also shorts the bypass switches Sw_b of the cell converters 31u-1 and 31v-1, and The switches Sw_u1, Sw_v2, Sw_n_u, Sw_n_v, Sw_n_1, Sw_n_2 selected from group 7 are controlled, and the first spare cell converter 51 and the second spare cell converter 51 are used instead of the cell converters 31u-1 and 31v-1, which have short-circuited the bypass switch Sw_b. The spare cell converter 52 is connected. In this way, the control device 9 connects a single cell converter to one of the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w (an example of the first cluster, in this example, the U-phase cluster 31u). (in this example, the cell converter 31u-1) and one of the U-phase cluster 31u, V-phase cluster 31v, and W-phase cluster 31w (an example of the second cluster, in this example, the V-phase cluster) If a failure is detected in a single cell converter (cell converter 31v-1 in this example) of the U-phase cluster 31u and V-phase cluster 31v, a different spare cell converter (in this example, the first A second connection is selected to connect the spare cell converter 51 and the second spare cell converter 52). The control device 9 selects the second connection and connects the selected first spare cell converter of the spare cell converter group 5 (first spare cell converter 51 in this example) in series to the U-phase cluster 31u. , a second spare cell converter (second spare cell converter 52 in this example) is connected in series to the V-phase cluster 31v.

The external output terminal T2 of the first spare cell converter 51 corresponds to the end of the U-phase cluster 31u. Further, the external output terminal T2 of the second spare cell converter 52 corresponds to the end of the V-phase cluster 31v. Therefore, the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w can maintain their star-connected state even after switching the state of the switch Sw_7 provided in the switch group 7. As a result, the power conversion device 1 has a cell converter 31u-1 provided in the U-phase cluster 31u and a cell converter 31v-1 provided in the V-phase cluster 31v (that is, a cell converter 31v-1 provided in the V-phase cluster 31v). ), it is possible to operate at the rated value even after failure, and stable operation can be maintained.

(Other examples of switching example 3)
Another example of switching example 3 will be explained using FIG. 6. In FIG. 6, for example, a cell converter 31u-1 provided in the U-phase cluster 31u, a cell converter 31v-1 provided in the V-phase cluster 31v, and a cell converter 31w-1 provided in the W-phase cluster 31w. 1 is shown in the figure.

As shown in FIG. 6, when it is determined that the cell converters 31u-1, 31v-1, and 31w-1 have failed, the control device 9 controls each of the cell converters 31u-1, 31v-1, and 31w-1. The bypass switch Sw_b provided in the switch group 7 is controlled to be on, and the switch Sw_7 provided in the switch group 7 is controlled to be in the following state, for example, by referring to the switch group control table.
Switch Sw_u1: On state Switch Sw_v1: Off state Switch Sw_w1: Off state Switch Sw_u2: Off state Switch Sw_v2: On state Switch Sw_w2: Off state Switch Sw_u3: Off state Switch Sw_v3: Off state Switch Sw_w3: On state Switch Sw_n_u: Off state Switch Sw_n_v: Off state Switch Sw_n_w: Off state Switch Sw_n_1: On state Switch Sw_n_2: On state Switch Sw_n_3: On state Switch Sw_uv: Off state Switch Sw_vw: Off state

As a result, the external output terminal T1 of the first spare cell converter 51 is connected to the external output terminal T2 of the cell converter 31u-3 provided in the U-phase cluster 31u via the switch Sw_u1. As a result, the first spare cell converter 51 is connected in series to the U-phase cluster 31u, so the number of operable cell converters provided in the U-phase cluster 31u is maintained at three. Further, by turning off the switch Sw_n_u and turning on the switch Sw_n_1, the external output terminal T2 of the cell converter 31u-3 is electrically disconnected from the neutral point N, and the first spare cell converter The external output terminal T2 of the device 51 is electrically connected to the neutral point N.

Further, external output terminal T1 of second spare cell converter 52 is connected to external output terminal T2 of cell converter 31v-3 provided in V-phase cluster 31v via switch Sw_v2. As a result, the second spare cell converter 52 is connected in series to the V-phase cluster 31v, so the number of operable cell converters provided in the V-phase cluster 31v is maintained at three. Further, by turning off the switch Sw_n_v and turning on the switch Sw_n_2, the external output terminal T2 of the cell converter 31v-3 is electrically disconnected from the neutral point N, and the second spare cell converter An external output terminal T2 of the device 52 is electrically connected to the neutral point N.

Further, external output terminal T1 of third spare cell converter 53 is connected to external output terminal T2 of cell converter 31w-3 provided in W-phase cluster 31w via switch Sw_w3. As a result, the third spare cell converter 53 is connected in series to the W-phase cluster 31w, so the number of operable cell converters provided in the W-phase cluster 31w is maintained at three. Further, by turning off the switch Sw_n_w and turning on the switch Sw_n_3, the external output terminal T2 of the cell converter 31w-3 is electrically disconnected from the neutral point N, and the third spare cell converter The external output terminal T2 of the device 53 is electrically connected to the neutral point N.

In this way, the switch group 7 connects the first spare cell converter 51 to the U-phase cluster 31u of the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w, and connects the first spare cell converter 51 to the V-phase cluster 31v. It is possible to connect the cell converter 52 and connect the third spare cell converter 53 to the W-phase cluster 31w. That is, the control device 9 shorts the bypass switches Sw_b of the cell converters 31u-1, 31v-1, 31w-1 based on the failure signals Fd_a, Fd_b, Fd_c, Fd_d of the failure detection units 41a, 41b, 41c, 41d. At the same time, the cell converters 31u-1, 31v-1, 31w- control the switches Sw_u1, Sw_v2, Sw_w3, Sw_n_u, Sw_n_v, Sw_n_w, Sw_n_1, Sw_n_2, Sw_n_3 selected from the switch group 7, and short-circuit the bypass switch Sw_b. 1, a first spare cell converter 51, a second spare cell converter 52, and a third spare cell converter 53 are connected. In this way, the control device 9 connects a single cell converter to one of the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w (an example of the first cluster, in this example, the U-phase cluster 31u). (In this example, cell converter 31u-1) failure and different first spare cell converter 51, second spare cell converter 52 and third spare cell converter 51, second spare cell converter 52 and third spare cell converter Select the second connection to which the cell converter 53 is connected. The control device 9 selects the second connection and connects the selected first spare cell converter of the spare cell converter group 5 (first spare cell converter 51 in this example) in series to the U-phase cluster 31u. , a second spare cell converter (second spare cell converter 52 in this example) is connected in series to the V-phase cluster 31v, and a second spare cell converter (third spare cell converter 53 in this example) is connected in series to the V-phase cluster 31v. It is connected in series to the W-phase cluster 31w.

The external output terminal T2 of the first spare cell converter 51 corresponds to the end of the U-phase cluster 31u. Further, the external output terminal T2 of the second spare cell converter 52 corresponds to the end of the V-phase cluster 31v. Furthermore, the external output terminal T2 of the third spare cell converter 53 corresponds to the end of the W-phase cluster 31w. Therefore, the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w can maintain their star-connected state even after switching the state of the switch Sw_7 provided in the switch group 7. As a result, the power converter 1 includes a cell converter 31u-1 provided in the U-phase cluster 31u, a cell converter 31v-1 provided in the V-phase cluster 31v, and a cell converter 31v-1 provided in the W-phase cluster 31w. Even after cell converter 31w-1 (that is, a cell converter provided in a different cluster) fails, rated operation is possible and stable operation can be maintained.

(Switching example 4)
Switching example 4 is an example of a switching mode of the switch Sw_7 provided in the switch group 7 when a plurality of cell converters in one cluster fail. Switching example 4 will be explained using FIG. 7. For example, FIG. 7 shows a case where cell converter 31u-1 and cell converter 31u-2 provided in U-phase cluster 31u fail.

As shown in FIG. 7, when the control device 9 determines that the cell converters 31u-1 and 31u-2 have failed, the control device 9 switches the bypass switch Sw_b provided in each of the cell converters 31u-1 and 31u-2. At the same time, the switch Sw_7 provided in the switch group 7 is controlled to be in the following state by referring to the switch group control table, for example.
Switch Sw_u1: On state Switch Sw_v1: Off state Switch Sw_w1: Off state Switch Sw_u2: Off state Switch Sw_v2: Off state Switch Sw_w2: Off state Switch Sw_u3: Off state Switch Sw_v3: Off state Switch Sw_w3: Off state Switch Sw_n_u: Off state Switch Sw_n_v: On state Switch Sw_n_w: On state Switch Sw_n_1: Off state Switch Sw_n_2: On state Switch Sw_n_3: Off state Switch Sw_uv: On state Switch Sw_vw: Off state

As a result, the external output terminal T1 of the first spare cell converter 51 is connected to the external output terminal T2 of the cell converter 31u-3 provided in the U-phase cluster 31u via the switch Sw_u1. Further, the external output terminal T1 of the second spare cell converter 52 is connected to the external output terminal T2 of the first spare cell converter 51 via the switch Sw_uv. As a result, the first spare cell converter 51 and the second spare cell converter 52 are connected in series to the U-phase cluster 31u, so the number of operable cell converters provided in the U-phase cluster 31u is 3. Individually maintained. Further, the switch Sw_n_u and the switch Sw_n_1 are in the off state, and the switch Sw_n_2 is in the on state. Therefore, the external output terminal T2 of the cell converter 31u-3, the external output terminal T2 of the first spare cell converter 51, and the external output terminal T1 of the second spare cell converter 52 are electrically disconnected from the neutral point N. At the same time, the external output terminal T2 of the second spare cell converter 52 is electrically connected to the neutral point N.

In this way, the switch group 7 connects the first spare cell converter 51 and the second spare cell converter 52 to the U-phase cluster 31u of the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w. is possible. That is, the control device 9 short-circuits the bypass switches Sw_b of the cell converters 31u-1 and 31u-2 based on the failure signals Fd_a, Fd_b, Fd_c, and Fd_d of the failure detection units 41a, 41b, 41c, and 41d, and also shorts the bypass switches Sw_b of the cell converters 31u-1 and 31u-2. The first spare cell converter 51 and the second spare cell converter control the switches Sw_u1, Sw_n_v, Sw_n_2, and Sw_uv selected from the group 7 and replace the cell converters 31u-1 and 31u-2 in which the bypass switch Sw_b is short-circuited. 52 are connected to each other. In this way, the control device 9 controls a plurality of cell converters in one of the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w (an example of the first cluster, in this example, the U-phase cluster 31u). If a failure in cell converters 31u-1 and 31u-2 is detected, a plurality of spare cell converters (in this example, the first spare cell A first connection is selected to connect the converter 51 and the second spare cell converter 52). The control device 9 selects the first connection and connects the selected spare cell converters of the spare cell converter group 5 (in this example, the first spare cell converter 51 and the second spare cell converter 52) to the first connection. A plurality of units (two units in this example) are connected in series to a cluster (in this example, U-phase cluster 31u), and the spare cell converter group 5 and U-phase cluster 31u are connected in series.

The external output terminal T2 of the second spare cell converter 52 corresponds to the end of the U-phase cluster 31u. Therefore, the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w can maintain their star-connected state even after switching the state of the switch Sw_7 provided in the switch group 7. As a result, the power converter 1 can operate after the cell converter 31u-1 and cell converter 31u-2 provided in the U-phase cluster 31u (that is, multiple cell converters provided in the same cluster) fail. It also enables rated operation and maintains stable operation.

In this manner, the power conversion device 1 includes the sixth switch section 76 in the switch group 7, thereby allowing the first spare cell converter 51 and the second spare cell converter 52 to be connected in series. As a result, even if two cell converters in one cluster fail, the power conversion device 1 can perform rated operation and maintain stable operation.

(Other examples of switching example 4)
Another example of switching example 4 will be explained using FIG. 8. For example, FIG. 8 shows a case where cell converter 31u-1, cell converter 31u-2, and cell converter 31u-3 provided in U-phase cluster 31u fail.

As shown in FIG. 8, when the control device 9 determines that the cell converters 31u-1, 31u-2, and 31u-3 have failed, each of the cell converters 31u-1, 31u-2, and 31u-3 The bypass switch Sw_b provided in the switch group 7 is controlled to be on, and the switch Sw_7 provided in the switch group 7 is controlled to be in the following state, for example, by referring to the switch group control table.
Switch Sw_u1: On state Switch Sw_v1: Off state Switch Sw_w1: Off state Switch Sw_u2: Off state Switch Sw_v2: Off state Switch Sw_w2: Off state Switch Sw_u3: Off state Switch Sw_v3: Off state Switch Sw_w3: Off state Switch Sw_n_u: Off state Switch Sw_n_v: On state Switch Sw_n_w: On state Switch Sw_n_1: Off state Switch Sw_n_2: Off state Switch Sw_n_3: Off state Switch Sw_uv: On state Switch Sw_vw: On state

As a result, the external output terminal T1 of the first spare cell converter 51 is connected to the external output terminal T2 of the cell converter 31u-3 provided in the U-phase cluster 31u via the switch Sw_u1. Further, the external output terminal T1 of the second spare cell converter 52 is connected to the external output terminal T2 of the first spare cell converter 51 via the switch Sw_uv. Further, external output terminal T1 of third spare cell converter 53 is connected to external output terminal T2 of second spare cell converter 52 via switch Sw_vw. As a result, the first spare cell converter 51, the second spare cell converter 52, and the third spare cell converter 53 connected in series are connected in series to the U-phase cluster 31u. The number of operational cell converters configured is maintained at three. Further, the switch Sw_n_u, the switch Sw_n_1, and the switch Sw_n_2 are in the off state, and the switch Sw_n_3 is in the on state. Therefore, the external output terminal T2 of the cell converter 31u-3, the external output terminal T2 of the first spare cell converter 51, the external output terminal T1 of the second spare cell converter 52, and the external output terminal T2 of the third spare cell converter 53 are The output terminal T1 is electrically disconnected from the neutral point N, and the external output terminal T2 of the third spare cell converter 53 is electrically connected to the neutral point N.

In this way, the switch group 7 connects the U-phase cluster 31u of the U-phase cluster 31u, V-phase cluster 31v, and W-phase cluster 31w to the first spare cell converter 51, the second spare cell converter 52, and the third spare cell converter. It is possible to connect a cell converter 53. That is, the control device 9 shorts the bypass switches Sw_b of the cell converters 31u-1, 31u-2, 31u-3 based on the failure signals Fd_a, Fd_b, Fd_c, Fd_d of the failure detection units 41a, 41b, 41c, 41d. At the same time, the switches Sw_u1, Sw_n_v, Sw_n_2, Sw_uv, Sw_vw selected from the switch group 7 are controlled, and the first spare cell is used instead of the cell converters 31u-1, 31u-2, 31u-3 that short-circuit the bypass switch Sw_b. The converter 51, the second spare cell converter 52, and the third spare cell converter 53 are connected, respectively. In this way, the control device 9 controls a plurality of cell converters in one of the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w (an example of the first cluster, in this example, the U-phase cluster 31u). If a failure in cell converters 31u-1, 31u-2, and 31u-3 is detected, multiple spare cell converters are installed in the U-phase cluster 31u that includes the failed cell converters 31u-1, 31u-2, and 31u-3. A first connection is selected to connect three (in this example, three first spare cell converters 51, second spare cell converters 52, and third spare cell converters 53). The control device 9 selects the first connection and connects the selected spare cell converters of the spare cell converter group 5 (in this example, the first spare cell converter 51, the second spare cell converter 52, and the third spare cell converter A plurality of (three in this example) converters 53) are connected in series to the first cluster (in this example, U-phase cluster 31u), and the spare cell converter group 5 and U-phase cluster 31u are connected in series.

The external output terminal T2 of the third spare cell converter 53 corresponds to the end of the U-phase cluster 31u. Therefore, the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w can maintain their star-connected state even after switching the state of the switch Sw_7 provided in the switch group 7. As a result, the power converter 1 has cell converter 31u-1, cell converter 31u-2, and cell converter 31u-3 provided in U-phase cluster 31u (that is, a plurality of cells provided in the same cluster). Even after a converter (converter) fails, rated operation is possible and stable operation can be maintained.

In this way, the power conversion device 1 includes the sixth switch section 76 in the switch group 7, so that the first spare cell converter 51, the second spare cell converter 52, and the third spare cell converter 53 are connected in series. Can be connected. Thereby, even if three cell converters in one cluster fail, the power conversion device 1 can perform rated operation and maintain stable operation.

(Switching example 5)
Switching example 5 is switching of the switch Sw_7 provided in the switch group 7 when a failure of a cell converter between a plurality of clusters and a failure of a plurality of cell converters within one cluster occur in combination. This is an example of a mode. Switching example 5 will be explained using FIG. 9. In FIG. 9, for example, there is a case where cell converter 31u-1 and cell converter 31u-2 provided in U-phase cluster 31u fail, and cell converter 31w-1 provided in W-phase cluster 31w fails. Illustrated.

As shown in FIG. 9, when it is determined that the cell converters 31u-1, 31u-2, and 31w-1 have failed, the control device 9 controls each of the cell converters 31u-1, 31u-2, and 31w-1. The bypass switch Sw_b provided in the switch group 7 is controlled to be on, and the switch Sw_7 provided in the switch group 7 is controlled to be in the following state, for example, by referring to the switch group control table.
Switch Sw_u1: On state Switch Sw_v1: Off state Switch Sw_w1: Off state Switch Sw_u2: Off state Switch Sw_v2: Off state Switch Sw_w2: Off state Switch Sw_u3: Off state Switch Sw_v3: Off state Switch Sw_w3: On state Switch Sw_n_u: Off state Switch Sw_n_v: On state Switch Sw_n_w: On state Switch Sw_n_1: Off state Switch Sw_n_2: On state Switch Sw_n_3: On state Switch Sw_uv: On state Switch Sw_vw: Off state

As a result, the external output terminal T1 of the first spare cell converter 51 is connected to the external output terminal T2 of the cell converter 31u-3 provided in the U-phase cluster 31u via the switch Sw_u1. Further, the external output terminal T1 of the second spare cell converter 52 is connected to the external output terminal T2 of the first spare cell converter 51 via the switch Sw_uv. As a result, the first spare cell converter 51 and the second spare cell converter 52 are connected in series to the U-phase cluster 31u, so the number of operable cell converters provided in the U-phase cluster 31u is 3. Individually maintained. Further, external output terminal T1 of third spare cell converter 53 is connected to external output terminal T2 of cell converter 31w-3 provided in W-phase cluster 31w via switch Sw_w3. As a result, the third spare cell converter 53 is connected in series to the W-phase cluster 31w, so the number of operable cell converters provided in the W-phase cluster 31w is maintained at three.

The switch Sw_n_u and the switch Sw_n_1 are in an off state, and the switch Sw_n_2 is in an on state. Therefore, the external output terminal T2 of the cell converter 31u-3, the external output terminal T2 of the first spare cell converter 51, and the external output terminal T1 of the second spare cell converter 52 are electrically disconnected from the neutral point N. At the same time, the external output terminal T2 of the second spare cell converter 52 is electrically connected to the neutral point N. Further, the switch Sw_n_w is in the off state, and the switch Sw_n_3 is in the on state. Therefore, the external output terminal T2 of the cell converter 31w-3 is electrically disconnected from the neutral point N, and the external output terminal T2 of the third spare cell converter 53 is electrically connected to the neutral point N. be done.

In this way, the switch group 7 connects the first spare cell converter 51 and the second spare cell converter 52 to the U-phase cluster 31u of the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w, It is possible to connect the third spare cell converter 53 to the W-phase cluster 31w.

That is, the control device 9 short-circuits the bypass switches Sw_b of the cell converters 31u-1 and 31u-2 based on the failure signals Fd_a, Fd_b, Fd_c, and Fd_d of the failure detection units 41a, 41b, 41c, and 41d, and also shorts the bypass switches Sw_b of the cell converters 31u-1 and 31u-2. The switches Sw_u1, Sw_w3, Sw_n_v, Sw_n_w, Sw_n_2, Sw_n_3, and Sw_uv selected from group 7 are controlled, and the first spare cell converter 51 and The second spare cell converters 52 are respectively connected, and the third spare cell converter 53 is connected in place of the cell converter 31w-1 whose bypass switch Sw_b is short-circuited. In this way, the control device 9 controls a plurality of cell converters in one of the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w (an example of the first cluster, in this example, the U-phase cluster 31u). If a failure in cell converters 31u-1 and 31u-2 is detected, a plurality of spare cell converters (in this example, the first spare cell A first connection is selected to connect the converter 51 and the second spare cell converter 52). The control device 9 selects the first connection and connects the selected spare cell converters of the spare cell converter group 5 (in this example, the first spare cell converter 51 and the second spare cell converter 52) to the first connection. A plurality of units (two units in this example) are connected in series to a cluster (in this example, U-phase cluster 31u), and the spare cell converter group 5 and U-phase cluster 31u are connected in series.

Furthermore, the control device 9 short-circuits the bypass switch Sw_b of the cell converter 31w-1 based on the failure signals Fd_a, Fd_b, Fd_c, and Fd_d of the failure detection units 41a, 41b, 41c, and 41d, and selects one from the switch group 7. The third spare cell converter 53 is connected in place of the cell converter 31w-1 with the bypass switch Sw_b shorted by controlling the switches Sw_w3, Sw_n_w, and Sw_n_3. In this way, the control device 9 converts at least a single cell into one of the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w (an example of the first cluster, in this example, the U-phase cluster 31u). (cell converters 31u-1, 31u-2 in this example) and another one of the U-phase cluster 31u, V-phase cluster 31v, and W-phase cluster 31w (an example of the second cluster, in this example) In this case, if a failure is detected in a single cell converter (cell converter 31w-1 in this example) in the W-phase cluster 31w, different spare cell converters (in the U-phase cluster 31u and W-phase cluster 31w) are In this example, the second connection is selected to connect the set of the first spare cell converter 51 and the second spare cell converter 52 and the third spare cell converter 53). The control device 9 selects the second connection and connects the selected first spare cell converter of the spare cell converter group 5 (in this example, the first spare cell converter 51 and the second spare cell converter 52). It is connected in series to the U-phase cluster 31u, and a second spare cell converter (in this example, the third spare cell converter 53) is connected in series to the W-phase cluster 31w. In this way, the control device 9 can simultaneously select the first connection and the second connection.

The external output terminal T2 of the second spare cell converter 52 corresponds to the end of the U-phase cluster 31u. The external output terminal T2 of the third spare cell converter 53 corresponds to the end of the W-phase cluster 31w. Therefore, the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w can maintain their star-connected state even after switching the state of the switch Sw_7 provided in the switch group 7. As a result, the power converter 1 can operate after the cell converter 31u-1 and cell converter 31u-2 provided in the U-phase cluster 31u (that is, multiple cell converters provided in the same cluster) fail. It also enables rated operation and maintains stable operation.

In the power conversion device 1, when one of the cell converters 31u-1 to 31u-3, 31v-1 to 31v-3, and 31w-1 to 31w-3 is out of order, another cell converter is out of order. In this case, the switch Sw_7 of the switch group 7 is temporarily returned to the switching mode at the start of the initial operation (see FIG. 3). Thereafter, the power conversion device 1 can appropriately change the connection mode of the switch Sw_7 of the switch group 7 by referring to the switch group control table, for example, to enable rated operation and maintain stable operation.

As described above, the power conversion device 1 according to the present embodiment includes a U-phase cluster 31u having cell converters 31u-1 to 31u-3, and a V-phase cluster 31v having cell converters 31v-1 to 31v-3. and a W-phase cluster 31w having cell converters 31w-1 to 31w-3. The power conversion device 1 also includes a spare cell converter group 5 including a first spare cell converter 51, a second spare cell converter 52, and a third spare cell converter 53. Further, the power conversion device 1 includes a switch group 7 having a plurality of switches for connecting the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w to the spare cell converter group 5. Further, the power conversion device 1 includes failure detection units 41a, 41b, 41c, and 41d that determine a failure of the cell converter and output a failure signal. Further, the power conversion device 1 short-circuits the bypass switches of the plurality of corresponding cell converters based on the failure signals from the failure detection units 41a, 41b, 41c, and 41d, and controls the switch selected from the switch group 7, A control device 9 is provided that connects a first spare cell converter 51, a second spare cell converter 52, and a third spare cell converter 53, respectively, in place of the plurality of short-circuited cell converters.

The power conversion device 1 having such a configuration can continue rated operation even if two or more cell converters in the same cluster fail at the same time. Further, the power conversion device 1 can continue rated operation even if a cell converter failure occurs in each of the plurality of clusters. Furthermore, the power conversion device 1 can continue rated operation even if two or more cell converters in the same cluster fail at the same time and a cell converter failure occurs in a cluster other than the cluster. .

The present invention is not limited to the above-described embodiments, and various modifications are possible.
In the above embodiment, in the switch group 7, the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w are star-connected, but the present invention is not limited to this. By appropriately controlling the switching state of the switch Sw_7, the control device 9 can set the switch group 7 to a state in which the U-phase cluster 31u, the V-phase cluster 31v, and the W-phase cluster 31w are connected in a delta manner.

In the embodiment described above, the failure detection section is arranged in each cell converter, but the present invention is not limited to this. For example, the control device may be configured to perform the function of monitoring the cell converter as a whole for failure.

In the above embodiment, the failure detection section is configured to output the voltage between the drain and source of the semiconductor switch as a failure signal, but it is also possible to detect other voltage signals or current signals such as the current between the drain and source of the semiconductor switch. It may be configured to do so.

In the above embodiment, the first spare cell converter 51, the second spare cell converter 52, and the third spare cell converter 53 have the bypass switch Sw_b, but they may not have the bypass switch Sw_b. .

Although the power conversion device 1 according to the embodiment described above has semiconductor switches Qa, Qb, Qc, and Qd configured with SiC-MOSFETs, the present invention is not limited thereto. The power conversion device 1 includes, for example, an insulated gate bipolar transistor (IGBT), a gate turn-off thyristor (GTO), or an integrated gate commutated thyristor (Integrated Gate Co., Ltd.). mutated turn-off thyristor :GCT) or the like, or a plurality of these may be combined as appropriate.

Although the power conversion device 1 according to the embodiment described above includes a cell converter having a bridge section BG formed of an H bridge, the present invention is not limited thereto. The cell converter may be, for example, a neutral point clamp three-level full bridge converter cell, as long as it can output a positive voltage and a negative voltage.

The scope of the invention is not limited to the exemplary embodiments shown and described, but also includes all embodiments which give equivalent effects to the object of the invention. Moreover, the scope of the invention is not limited to the combinations of inventive features delineated by the claims, but is defined by any desired combinations of specific features of each and every disclosed feature. sell.

1 Power conversion device 2 Three-phase power system 3 Cluster section 5 Spare cell converter group 7 Switch group 9 Control device 21 Cable 31u U-phase cluster (first cluster)
31u_1, 31u_2, 31u-1, 31u-2, 31u-3, 31v_1, 31v_2, 31v-1, 31v-2, 31v-3, 31w-1, 31w-2, 31w-3 Cell converter 31uL, 31vL, 31wL reactor 31v V phase cluster (second cluster)
31w W phase cluster (third cluster)
51 First spare cell converter 52 Second spare cell converter 53 Third spare cell converter 71 First switch part 72 Second switch part 73 Third switch part 74 Fourth switch part 75 Fifth switch part 76 Sixth switch Section 211 U-phase cable 212 V-phase cable 213 W-phase cable BG Bridge section C DC capacitors Da, Db, Dc, Dd Freewheeling diodes GP_b, GP_br, GP_r, GP_sg, GP_u, GP_v, GP_w Control signals Ma, Mb, Mc, Md Semiconductor module EPC Power converter N Neutral point PS Power control system Qa, Qb, Qc, Qd Semiconductor switch Sw_7, Sw_n_1, Sw_n_2, Sw_n_3, Sw_n_u, Sw_n_v, Sw_n_w, Sw_u1, Sw_u2, Sw_u3, Sw_uv, Sw_v1, Sw_v2, Sw_v3, Sw_vw, Sw_w1, Sw_w2, Sw_w3 Switch Sw_b Bypass switch T1, T2 External output terminal

Claims (6)

A plurality of cell converters are connected in series, each of which includes a power converter having two external output terminals that output a positive voltage and a negative voltage, and a bypass switch that is provided to short-circuit between the two external output terminals. multiple clusters,
a spare cell converter group having a plurality of spare cell converters each having the power conversion unit;
a switch group having a plurality of switches for connecting the plurality of clusters and the spare cell converter group;
a failure detection unit that determines a failure of the cell converter and outputs a failure signal;
Based on the failure signal from the failure detection section, the bypass switches of the plurality of corresponding cell converters are short-circuited, and a switch selected from the switch group is controlled to replace the short-circuited plurality of cell converters with the spare cell. a control unit that connects each converter;
Equipped with
The spare cell converter group includes a first spare cell converter, a second spare cell converter, and a third spare cell converter,
The switch group is
a first switch unit capable of connecting any one of the plurality of clusters to the first spare cell converter;
a second switch unit capable of connecting any one of the plurality of clusters to the second spare cell converter;
a third switch unit capable of connecting any one of the plurality of clusters to the third spare cell converter;
a fourth switch unit capable of connecting the positive electrode side of any one of the first spare cell converter, the second spare cell converter, and the third spare cell converter to a neutral point;
a fifth switch unit capable of connecting the negative electrode side of any one of the first spare cell converter, the second spare cell converter, and the third spare cell converter to the neutral point;
At least one of the negative electrode side of the first spare cell converter and the positive electrode side of the second spare cell converter, and the negative electrode side of the second spare cell converter and the positive electrode side of the third spare cell converter can be connected. Sixth switch part and
have
Power converter. The control unit controls the switch group based on a failure signal from the failure detection unit, and connects a plurality of spare cell converters in series to one of the plurality of clusters; and a second connection that connects the different spare cell converters to the cluster.
The power conversion device according to claim 1. The control unit includes:
If the failure detection unit detects a failure of a plurality of cell converters in a first cluster, selecting the first connection;
A plurality of selected spare cell converters of the spare cell converter group are connected in series to the first cluster, and the spare cell converter group and the first cluster are connected in series.
The power conversion device according to claim 2. The control unit includes:
If the failure detection unit detects a failure of a single cell converter in a first cluster and a failure of a single cell converter in a second cluster, selecting the second connection;
A selected first spare cell converter of the group of spare cell converters is connected in series to the first cluster, and a second spare cell converter is connected in series to the second cluster.
The power conversion device according to claim 2 or 3. The power conversion device according to any one of claims 2 to 4, wherein the control unit selects the first connection and the second connection at the same time. The power conversion device according to any one of claims 1 to 5 , wherein the switch group connects the plurality of clusters in a star connection or a delta connection.

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