JP5543736B2 - Power converter - Google Patents

Description

  The present invention relates to a power conversion device, and more particularly to a power conversion device having a redundant control system.

  As one of power converters for driving an AC motor, there is a power converter that converts DC power into AC power. There are several types of power converters depending on the power semiconductor elements and power conversion methods used. Of these, power conversion devices that use an element such as IGBT as a power semiconductor element can use a pulse width modulation method (hereinafter referred to as PWM) as a power conversion method. Since an alternating current with less harmonics can be supplied to a load having a large inductance component such as a motor, it can be used in various application fields.

  Among the application fields using such a power converter, there is a field that requires continuous operation without stopping for several years. Although the continuous operation performance and failure rate of the power converter itself are improving year by year, in general, the failure rate is not zero and the power converter is periodically stopped due to the use of parts with a limited life. Maintenance is required.

  Therefore, in the above application fields, a plurality of power converters are configured in parallel so that even if one power converter stops due to a failure or periodic maintenance, the power converter can be configured in parallel, and part of the power converters In many cases, a so-called redundant system is constructed in which conversion is performed and the rest is in a standby state.

  The normal power converter is composed of at least one power converter in charge of power conversion and a control device that controls the converter. In the redundant system, each of the power converter and the control device is a target for redundancy.

  The power converter redundancy method is to stop some of the power converters that make up the system in a standby state and stop the abnormal power converter when there is an abnormality in the operating power converter. (Disconnect) and operate (incorporate) standby power converters and operate more power converters in parallel than the number of power converters required for the system. There are two types of methods of disconnecting and continuing operation. In both methods, the disconnection and the insertion operation are controlled by the control device.

  In the control device, in addition to a control device failure caused by components of the control device, there is a failure in a sensor system such as a current sensor interfaced to the control device, or an abnormality in a power converter caused by a control abnormality. Therefore, even if the abnormality is detected in the converter, the control device may be the true cause. As a redundant method of the control device, a redundant system is configured in which the control is performed by one control device and the other control device is put on standby. Unlike the case of the power converter, since it can be controlled by one control device, it is common to construct a redundant system with two control devices. (For example, refer to Patent Document 1).

JP 2008-161006 (Overall)

  In the conventional power conversion device described in Patent Document 1, control switching from the control device 1A to the control device 1B can be realized without a common control system for controlling control redundancy. Even if a “control switching request” is requested from 1A, if a “control switching request” cannot be transmitted to the control device 1B, the system is stopped when a failure is detected in the control device 1A. Similarly, even if a “control switching request” is requested from the control device 1A, if the “control switching request answer” from the control device 1B cannot be transmitted to the control device 1A, the system stops when the control device 1A detects a failure. To go.

  Further, when one control device is “select”, the other is “standby” or “maintenance”, and when the two are interlocked so as not to satisfy the “select” condition, for example, the control device 1A selects “select”. "Is not transmitted to the control device 1B, the interlock is not established. Further, when the control device 1A receives the “maintenance” request, the control device 1A cannot accept the “maintenance” request unless it is known that the control device 1B is in the “standby” state.

  Therefore, when it falls into the said state, it will lead to the problem of the total inspection of a control apparatus which is fatal for the redundant system which performs continuous operation.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a power conversion device capable of improving the reliability of signal transmission between control devices and performing highly reliable control device switching. And

In order to achieve the above object, the power conversion device of the present invention includes at least one power converter that converts power by controlling on / off of a switching element, and 2 redundantly arranged to control the operation of the power converter. is composed of a base of the control device, wherein each of the control device, to indicate their operating state "selection", "standby", and stores each status of "maintenance" status storage / read to read the status of the other party Means, a control switching request means for performing a “control switching request” to the counterpart control apparatus, and accepting a control switching request from the counterpart control apparatus and performing a “control switching request answer” to the counterpart control apparatus. Control switching answering means, and when one of the control devices detects an abnormality during operation control of the power converter, the control device stops operation control of the power converter. The other control device requests control switching, and the other control device performs answer back by the control switching answering means and starts operation control of the power converter, Each signal of “request”, “control switching request answer”, “selection” and “standby” is triple connected to each other, and a majority circuit is provided on the receiving side of the triple signal, Even if one of the triple signals is broken or broken, the signal transmission between the control devices is not hindered. Each control device has a microcomputer with a watchdog timer, and the watchdog timer And the power converter is gate-blocked and the "control switching request" signal is forcibly output .

  According to the present invention, it is possible to provide a power conversion device capable of improving the reliability of signal transmission between control devices and performing control device switching with high reliability.

The system block diagram of the power converter device which concerns on Example 1 of this invention. The operation | movement flowchart of the control apparatus which requests | requires the control switch request of the power converter device of this invention. The operation | movement flowchart of the control apparatus which receives the control switching request | requirement of the power converter device of this invention. The operation | movement flowchart of the control apparatus with which the failure recovery of the power converter device of this invention is carried out. FIG. 3 is a detailed diagram illustrating an example of triple signal transmission of the power conversion device according to the first embodiment of the present invention. FIG. 5 is a diagram corresponding to FIG. The system block diagram of the power converter device which concerns on Example 2 of this invention. FIG. 5 is a detailed diagram illustrating an example of triple signal transmission of the power conversion device according to the second embodiment of the present invention. FIG. 9 is a detailed diagram illustrating a control switching control circuit of a control device for a power conversion device according to a third embodiment of the present invention.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a system configuration diagram of the power conversion apparatus according to the first embodiment of the present invention.

  The power conversion device in FIG. 1 includes a control device 1A, a control device 1B, and a power converter 5. The power converter 5 converts an AC voltage obtained from an AC power source into an AC for driving an electric motor by appropriately turning on and off, for example, a plurality of switching elements (not shown) that are constituent elements thereof.

  The control device 1A and the control device 1B are basically the same in configuration, and either one of them is redundantly arranged to control the operation of the power converter 5, and a control power supply (not shown) is provided so that maintenance can be performed individually. It has a separable configuration. The control device 1A and the control device 1B have converter control circuits 2A and 2B, control abnormality detection circuits 3A and 3B, and control switching control circuits 4A and 4B, respectively.

  The converter control circuits 2A and 2B give a gate signal to the switching elements constituting the power converter 5, and this gate signal is obtained, for example, when the speed of an electric motor (not shown) driven by the output of the power converter 5 is a desired speed. The gate signal is determined by control means (not shown) such as PWM control.

  The control switching control circuits 4A and 4B have respective input / output signal interfaces for control switching request, control switching request answer and status exchange, and transmit and receive these signals between the control devices 1A and 1B. The control switching control circuits 4A and 4B supply control start / stop signals to the converter control circuits 2A and 2B, respectively. Here, the “control switch request”, “request answer”, “select”, and “standby” signals input / output to / from the control switch control circuits 4A and 4B are triple signals. Will be described later. In FIG. 1, the status transmission / reception signal is shown as a triple signal, but not all status transmission / reception signals are tripled.

  The control abnormality detection circuits 3A and 3B are each provided with an abnormality signal of their own control system from the converter control circuits 2A and 2B, and a common abnormality signal is provided from the power converter 5. The common abnormality signal is a signal such as an overvoltage abnormality or an overcurrent abnormality of the power converter 5. When the control abnormality detection circuits 3A and 3B receive these signals, the control abnormality detection circuits 3A and 3B output control device abnormality signals to the control switching control circuits 4A and 4B of the control device to which the control abnormality detection circuits 3A and 3B belong, respectively.

  The control devices 1A and 1B basically have means for storing three statuses of “selection”, “standby”, and “maintenance”, each indicating its own state. Since these statuses are read from each other as described above, the control devices 1A and 1B have status storage / reading means. These statuses are automatically updated by their own control device according to their operating history. If one of the control devices is “selected”, the other is “standby” or “maintenance”, and they are mutually interlocked so as not to be “selected”.

  FIG. 2 is a flowchart of control switching when the control device 1A detects a control abnormality in a state where the control device 1A has a status of “selected” and the control device 1B has a “standby” status. FIG.

  In FIG. 2, when a control abnormality is detected in the control device 1A (ST1), first, it is confirmed whether or not the status of the control device 1A is “selected” (ST2). If the status is not “selected”, the control device 1A is checked. Since control of the power converter 5 is not performed, control switching is not necessary. If the status is “selected”, the control device 1A is performing the operation control of the power converter 5, and therefore the control is switched to the control device 1B.

  In order to stop the energization of the power converter 5, the control switching method first blocks all of its own gate commands for the switching elements constituting the power converter 5 (ST 3), and then “controls” the control device 1 B. "Switching request" is transmitted (ST4).

  In FIG. 3, when the control device 1B receives the “control switching request” from the control device 1A (ST5), the control device 1B first checks whether its own status is “standby” (ST6). If the status is not "standby", control switching cannot be performed and control cannot be performed by the control device 1B, and therefore a "control switching request answer" is not returned to the "control switching request".

  If the status of the control device 1B is “standby”, a “control switching request answer” is transmitted to the control device 1A (ST-7). Then, the status of the control device 1B is changed from “standby” to “selected” (ST-8), and the operation control of the power converter 5 is started (ST-9). At the time when the “control switching request” is received, the control device 1A stops the control of the power converter 5, so that a gate signal for operation control of the power converter 5 is between the control devices 1A and 1B. There is no competition.

  Returning to FIG. 2 again, the control device 1A that has transmitted the “control switching request” confirms reception of the “control switching request answer” from the control device 1B (ST-8A), and “selects” the status of the control device 1A. Is changed to “maintenance” (ST-10A). The control device 1A checks whether or not a “control switching request answer” has been returned within a certain time (ST-9A), and if the “control switching request answer” cannot be confirmed within a certain time, The control devices 1A and 1B cannot be controlled, and the system can be stopped (ST-11A). Further, as another method, since control switching could not be performed, it is possible to reset the control device 1A by failure and to try operation control of the power converter 5 again by the control device 1A only once.

  Next, a basic recovery procedure of the control device 1A in the “maintenance” status will be described with reference to the flowchart of the maintenance procedure shown in FIG. 1 A of control apparatuses perform failure recovery operation, after checking the applicable failure part and completing the restoration | recovery operation | work. This operation is automatically detected (ST-12A), and it is checked whether or not its own control device 1A is in the “maintenance” state (ST-13A). If its own control device 1A is in the “maintenance” state, this status is switched to the “standby” status (ST-14A). As a result, the status of the control device A is switched from “maintenance” to “standby”, and the control device A enters a standby state and participates in the system again.

  Further, manual maintenance of the control device can be achieved by providing a maintenance request switch (not shown) in the control devices 1A and 1B and supplying this maintenance request signal to the control switching control circuits 4A and 4B, respectively.

  The configuration and operation will be described below according to the triple circuit configuration example shown in FIG. FIG. 5 illustrates a triple configuration of a “control switching request” signal transmitted from the control device 1A to the control device 1B.

  In FIG. 5, a “control switching request” signal transmitted from the control switching control main circuit 40A provided in the control switching control circuit 4A of the control device 1A is composed of an insulating photocoupler PC and a digital output circuit DO. The output circuits 41A, 42A and 43A are provided in parallel. The output circuits 41A, 42A, and 43A perform the same signal processing, and are provided in the control switching control circuit 4B of the control device 1B, respectively. The receiving circuits 41B, 42B including the insulating photocoupler PC and the digital input circuit DI are provided. And 43B, a control switching request 1 signal, a control switching request 2 signal, and a control switching request 3 signal are respectively provided in parallel. The outputs of these input circuits 41B, 42B and 43B are given to the majority circuit 44B. The control switching request 1 signal, the control switching request 2 signal, and the control switching request 3 signal are subjected to a majority vote of three parties by the majority circuit 44B, and a control switching request signal determined by the majority vote is given to the control switching control main circuit 40B. It is done.

  With the above configuration, it is assumed that one of the output circuits 41A, 42A and 43A of the control switching control circuit 4A of the control device 1A has failed, or the signal lines of the control switching request 1 signal, the control switching request 2 signal and the control switching request 3 Even if one of them is broken or one of the receiving circuits 41B, 42B and 43A of the control switching control circuit 4B of the control device 1B breaks down, the majority circuit 44B can perform accurate signal transmission by majority of two signals. It becomes possible.

  Although not shown in the figure, if a mismatch occurs in the majority circuit 44B, it can be determined that there is an abnormality in the “control switching request” signal from the control device 1A, so the control device 1B can recognize the failure. The signal from the control device 1A of the “control switching request” is preferably subjected to insulation separation for online maintenance. In the example of FIG. 5, the signal insulation is performed by the photocoupler PC, but it may be constructed by a relay that can be insulated. Further, the power supply is insulated and separated, and the control device 1A side uses the internal power supply VCC1 of the control device 1A, and the control device 1B side uses the internal power supply VCC2 on the control device 1B side, and each control device is individually maintained. In this case, it is desirable to create a state where no voltage is applied to the other control device. As described above, in the case of the “control switching request” signal, the request issuance is preferably made in a state where the output circuits 41A, 42A, and 43A are in an unmake state.

  The “control switch request answer”, “select”, and “standby” signals are not shown, but a triple circuit and a majority circuit similar to the “control switch request” are provided.

  As for the “control switching request answer” signal, for example, when the output of the control switching control circuit 40A is in the make state, the request answer is used, and normally the unmake is performed, so that no voltage is applied to the other control device during maintenance. Can create a state.

  Similarly, regarding “selection”, for example, the output of the control switching control circuit 40A is set to “selection” in the make state, and is set to unmake during maintenance, thereby creating a state in which no voltage is applied to the other control device. . Similarly, with respect to “standby”, the output of the control switching control circuit 40A is set to “standby” when in the make state, and the state where no voltage is applied to the other control device can be created by setting the output to “standby” during maintenance.

  By adopting the above circuit configuration, even if a “control switching request” is requested from the control device 1A, which is a conventional problem, if the “control switching request” cannot be transmitted to the control device 1B, the control device 1A The problem that the system is stopped when a failure is detected, and similarly, even if a “control switching request” is requested from the control device 1A, the “control switching request answer” from the control device 1B cannot be transmitted to the control device 1A. The problem that the system is stopped when a failure is detected by the control device 1A can be solved.

  If one control device is “selection”, the other is “standby” or “maintenance”, and when the two are interlocked so as not to satisfy the “selection” condition, for example, the control device 1A selects “selection”. Is not transmitted to the control device 1B, and if the control device 1A receives a “maintenance” request, it cannot be understood that the control device 1B is in the “standby” state. Thus, the control device 1A can solve the problem that it cannot accept the “maintenance” request.

  Therefore, according to the above method, the control switching from the control device 1A to the control device 1B can be realized without the common control system that controls the control redundancy, which is the effect of the conventional example, which overcomes the above-described problems. In addition, since the control device 1A and the control device 1B are basically configured to perform the same operation, it is possible to perform control switching from the control device 1B to the control device 1A in exactly the same manner. it is obvious.

  In the control device for a power converter according to the present invention, the part from the output of one control switching control main circuit to the input of the other control switching control circuit is tripled. This is because the important part other than the part is basically a part processed by software using a microcomputer. Therefore, the location where the hardware intervenes only needs to be a triple location. If a malfunction due to a microcomputer abnormality occurs, a microcomputer abnormality such as a watchdog is detected. For example, as shown in FIG. In the case of FIG. 6, the microcomputer is abnormal at level L) and the control switching request signal (request at level L in FIG. 3) that is the original signal output from the control switching control main circuit is provided in the control switching control circuit 4A1. By taking a negative OR with the OR circuit 45A, the output of the output circuits 41A, 42A and 43A can be unmade when a control switching request is generated. In other words, in this case, when a microcomputer abnormality occurs, the watchdog timer output becomes level L, so that a control switching request signal is forcibly generated.

  In the case of a general power conversion device, a microcomputer abnormality is detected by hardware as a controller abnormality, and the gate signal is blocked. Therefore, when the flow until the control apparatus 1A in which the microcomputer abnormality has occurred becomes a gate signal block is applied to FIG. 2, first, control failure detection = microcomputer abnormality is detected (ST1), and the self-control apparatus “select” Cannot be confirmed, but the gate signal block is performed (ST3). Then, the same signal as the control switching request signal output is output from the watchdog timer (ST4). Even if the self-control value is not “selected”, there is no problem because the operation switching is not performed unless the other party is “standby” in the flowchart of FIG. That is, when the control device 1B receives “control switching request = microcomputer abnormality” from the control device 1A in the flowchart of FIG. 3 (ST5), the control device 1B confirms whether its own status is “standby” (ST6). ). If the status is not “standby”, control switching cannot be performed and control cannot be performed by the control device 1B, and the flow is exited without returning a “control switching request answer” for the “control switching request”.

  If the status is “standby” in step ST6, “control switching request answer” is transmitted to the control device 1A (ST7), but is not received by the control device 1A. However, control device 1B changes the status from “standby” to “selected” (ST8), and starts operation control of power converter 5 (ST9). As described above, since the control device 1A stops the control of the power converter 5 when the “microcomputer abnormality” occurs, the control device 1A and 1B are used for controlling the operation of the power converter 5. The gate signals do not compete.

  Returning to the flowchart of FIG. 2 again, the control device 1A that has transmitted “control switching request = microcomputer abnormality” cannot confirm reception of the “control switching request answer” from the control device 1B, but enters a stopped state. Further, the control device 1A cannot check whether the “control switching request answer” has been returned within a certain time (ST9A), so that the system does not stop.

  The control device 1A having an abnormality performs maintenance and switches the status after inspection and repair to the “standby” status (ST14A). Thus, the status of the control device 1A is switched from “maintenance” to “standby”, and the control device 1A enters the standby state and can participate in the system again.

  In this way, it is possible to avoid the problem of a total inspection of the control device which is fatal for a redundant system which is to be operated continuously.

  Hereinafter, the power converter concerning Example 2 of the present invention is explained with reference to FIG.7 and FIG.8.

  FIG. 7 is a system configuration diagram of the power conversion apparatus according to the second embodiment of the present invention. About each part of this Example 2, the same part as each part of the power converter device which concerns on Example 1 of this invention of FIG. 1 is shown with the same code | symbol, and the description is abbreviate | omitted. The second embodiment is different from the first embodiment in that a circuit abnormality signal is supplied from the control switching control circuits 4A2 and 4B2 of the control devices 1A1 and 1A2 to the control abnormality detection circuits 3A and 3B, respectively. is there.

  FIG. 8 is a detailed diagram illustrating an example of triple signal transmission of the power conversion apparatus according to the second embodiment of the present invention, in which the internal configuration of the circuit abnormality signal in FIG. 7 is described. About each part of this Example 2, the same part as each part of the detailed view which shows the example of the triple signal transmission of the power converter device which concerns on Example 1 of this invention of FIG. 5 is shown with the same code | symbol, The description is abbreviate | omitted To do. The second embodiment is different from the first embodiment in that the control switching control circuit 4A2 receives the output signals of the output circuits 41A, 42A and 43A via the receiving circuits 46A, 47A and 48A, respectively. This is a point of providing a feedback to the abnormality determination circuit 401A provided in the inside. Here, the receiving circuits 46A, 47A and 48A are composed of an insulating photocoupler PC and a digital input circuit DI, like the receiving circuits 41B, 42B and 43B. The abnormality determination circuit 401A compares the control switching request signal transmitted from the control switching control main circuit 40A1 with each of the feedback signals described above, and outputs a circuit abnormality signal if any one of the signal mismatches.

  When a majority signal mismatch occurs due to the feedback signal, in the first embodiment, it was impossible to determine where the failure occurred in the control device 1A or the control device 1B. Alternatively, it is possible to determine whether the failure has occurred between the control device 1A and the control device 1B.

  Here, the reason why the signals are fed back through the receiving circuits 46A, 47A, and 48A is generally dirty because the outputs of the output circuits 41A, 42A, and 43A are connected to signal lines that cross between the control devices. Since it is a signal line, it is inserted for the purpose of preventing noise. If there is no noise problem between the control devices, the receiving circuits 46A, 47A and 48A can be omitted.

  Even if a signal mismatch occurs due to a failure at one location, it is possible to continue operation due to the effect of the majority circuit. Therefore, when there is only one signal mismatch in the majority decision of the feedback signal, only an alarm is output. It may be configured to output a circuit abnormality signal when it becomes.

  FIG. 9 is a detailed diagram illustrating a control switching control circuit of the control device for the power conversion device according to the third embodiment of the present invention. About the parts of this third embodiment, the same parts as those in the detailed diagram showing an example of the triple signal transmission of the power conversion device according to the second embodiment of the present invention in FIG. To do. The third embodiment is different from the second embodiment in that all the triple signals between the control switching control main circuits 40A1 and 40B1 are recorded. Triple signal transmission units 49A1 and 49A2 49A3, 49B1, 49B2, and 49B3 are provided to improve maintenance. The majority decision circuit is collectively described as the majority decision circuit 44A on the control switching control circuit 4A3 side and the majority decision circuit 44B on the control switching control circuit 4B3 side, and the abnormality determination circuit is not shown.

  In FIG. 8, there are three signal lines between the control switching control circuits of the control devices 1A and 1B. This is because only the “control switching request” signal from the control device 1A to the control device 1B is described. On the other hand, in FIG. 9, all signals, that is, “control switching request”, “control switching request answer”, “selection”, and “standby”, and signals transmitted from the control device 1B to the control device 1A are also added. Therefore, the number of signal lines is 3 × 4 (signal) × 2 (reciprocating), which is 24.

  Of these signals, a single portion that handles eight signal lines is unitized as triple signal transmission units 49A1, 49A2, 49A3, 49B1, 49B2, and 49B3. Then, the triple signal transmission unit 49A1 makes a signal exchange with the triple signal transmission unit 49B1. Similarly, the triple signal transmission unit 49A2 performs signal exchange with the triple signal transmission unit 49B2, and the triple signal transmission unit 49A3 performs signal exchange with the triple signal transmission unit 49B3. In this way, each of the triplex signal transmission units 49A1, 49A2, 49A3, 49B1, 49B2, and 49B3 includes four output circuit / feedback receiving circuit pairs, and four receiving circuit corresponding to the output circuit. The same circuit configuration having a total of 8 circuits. Here, the unit of the triple signal transmission unit refers to a substrate, a relay unit, or a complex thereof. It is preferable that the wiring on the input side and the wiring on the output side of the triple signal transmission unit can be connected with one touch via a connector.

  When unitized as described above, the identification and recovery of the failure location described in the second embodiment can be achieved by replacing one unit. For example, if the triple signal transmission unit 49A1 of the control device 1A is determined to be out of order during operation by the control device 1A, the remaining triple signal transmission units 49A2 and 49A3 are connected to the control device 1B. It shows that the power supply to the triplex signal transmission unit 49A1 is stopped while performing signal transmission, and the unit can be replaced.

  For example, in the control device 1A, when three outputs of “control switching request” are arranged in the same unit (board) and the photocoupler is the same (for example, 4 in 1 configuration), one component failure (photocoupler failure) The “control switching request” signal may be completely destroyed. Since it is possible to prevent such troubles by dividing the unit, it is obvious that the control configuration is more reliable.

  Furthermore, for example, in power converter applications where it is necessary to perform motor speed control and minimize speed fluctuations, switching the control device temporarily stops the gate signal, so avoid switching the control device as much as possible. There is a demand for it. By employing this embodiment of the present invention, maintenance / recovery during operation is possible, and switching of the control device can be avoided as much as possible.

1A, 1B, 1A1, 1B1 Control device 2A, 2B Converter control circuit 3A, 3B Control abnormality detection circuit 4A, 4A1, 4A2, 4A3, 4B, 4B2, 4B3 Control switching control circuit 5 Power converters 40A, 40A1, 40B, 40B1 control switching control main circuit 401A abnormality determination circuit 41A, 42A, 43A output circuit 41B, 42B, 43B reception circuit 44A, 44B majority decision circuit 45A negative OR circuit 46A, 47A, 48A reception circuit 49A1, 49A2, 49A3, 49B1, 49B2 , 49B3 Triple signal transmission unit

Claims (7)

At least one power converter for converting power by controlling on / off of the switching element;
It is composed of two control devices arranged redundantly to control the operation of the power converter,
Each of the control devices is
It shows the own operating conditions "select", "waiting", and stores each status of "maintenance", and the status memory / reading means for reading the status of the other party,
Control switching request means for performing a “control switching request” to the counterpart control device;
A control switching response means for accepting a control switching request from the counterpart control device and performing a "control switch request answer" to the counterpart control device;
When one control device detects an abnormality during operation control of the power converter, the control device stops operation control of the power converter and requests control switching from the other control device. The control device performs an answer back by the control switching answering means, and starts operation control of the power converter,
Each of the “control switch request”, “control switch request answer”, “select” and “standby” signals is tripled to connect the control devices to each other,
A majority circuit is provided on the reception side of the triple signal,
Even if one of the triple signals causes disconnection, failure, etc., there is no problem in signal transmission between the control devices ,
Each control device has a microcomputer with a watchdog timer, and when the watchdog timer is activated, the power converter is gate-blocked and the "control switching request" signal is forcibly output. The power converter characterized by having performed. At least one power converter for converting power by controlling on / off of the switching element;
It is composed of two control devices arranged redundantly to control the operation of the power converter,
Each of the control devices is
A status storage / reading means for storing each status of “selection”, “standby”, “maintenance” indicating its own operation state and reading the other party's status,
Control switching request means for performing a “control switching request” to the counterpart control device;
A control switching response means for accepting a control switching request from the counterpart control device and performing a "control switch request answer" to the counterpart control device;
Have
When one control device detects an abnormality during operation control of the power converter, the control device stops operation control of the power converter and requests control switching from the other control device. The control device performs an answer back by the control switching answering means, and starts operation control of the power converter,
Each of the “control switch request”, “control switch request answer”, “select” and “standby” signals is tripled to connect the control devices to each other,
A majority circuit is provided on the reception side of the triple signal,
Even if one of the triple signals causes disconnection, failure, etc., there is no problem in signal transmission between the control devices,
In order to transmit the triple signal,
An output circuit comprising an insulation circuit and a digital output circuit is provided on the signal transmission side, and a first reception circuit comprising an insulation circuit and a digital input circuit is provided on the signal reception side, and the output of the first reception circuit is provided as the majority circuit. The output circuit and the first receiving circuit for one of the signals to be tripled are unitized as a triplex transmission unit, and one of the control devices is this triplex transmission. A power converter having a structure including three units. At least one power converter for converting power by controlling on / off of the switching element;
It is composed of two control devices arranged redundantly to control the operation of the power converter,
Each of the control devices is
A status storage / reading means for storing each status of “selection”, “standby”, “maintenance” indicating its own operation state and reading the other party's status,
Control switching request means for performing a “control switching request” to the counterpart control device;
A control switching response means for accepting a control switching request from the counterpart control device and performing a "control switch request answer" to the counterpart control device;
Have
When one control device detects an abnormality during operation control of the power converter, the control device stops operation control of the power converter and requests control switching from the other control device. The control device performs an answer back by the control switching answering means, and starts operation control of the power converter,
Each of the “control switch request”, “control switch request answer”, “select” and “standby” signals is tripled to connect the control devices to each other,
A majority circuit is provided on the reception side of the triple signal,
Even if one of the triple signals causes disconnection, failure, etc., there is no problem in signal transmission between the control devices,
Each of the “control switching request”, “control switching request answer”, “selection” and “standby” output signals is fed back to its own control device to monitor the failure.
And each of the output signals is fed back via a second receiving circuit comprising an insulating circuit and a digital input circuit,
The second receiving circuit for one of the signals to be tripled is unitized as a triplex transmission unit, and one control device has a configuration including three triplex transmission units. A power converter. In order to transmit the triple signal,
An output circuit comprising an insulation circuit and a digital output circuit is provided on the signal transmission side, and a first reception circuit comprising an insulation circuit and a digital input circuit is provided on the signal reception side, and the output of the first reception circuit is provided as the majority circuit. The power conversion device according to claim 1, wherein the power conversion device is provided. The failure monitoring is performed by feeding back each of the "control switching request", "control switching request answer", "selection", and "standby" output signals to its own control device. Item 3. The power conversion device according to Item 2. Each of the control devices has a microcomputer with a watchdog timer,
4. The device according to claim 2, wherein when the watchdog timer is activated, the power converter is gate-blocked and the “control switching request” signal is forcibly output. 5. Power conversion device. The original signal of the “control switching request” signal is requested at level L,
The watchdog timer is set to level L when the microcomputer is abnormal,
Apply these two signals to the negative OR circuit,
7. The power converter according to claim 1, wherein the output of the negative OR circuit is tripled.

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