JP4362084B2 - AC excitation type synchronous machine stop control method - Google Patents

Description

  The present invention relates to, for example, a stop control method for an AC excitation type synchronous machine for causing two AC excitation type synchronous machines to regeneratively brake power in an electric power system.

In the conventional AC excitation type synchronous machine stop control method, when two AC excitation type synchronous machines are controlled to stop, after stopping one AC excitation type synchronous machine, the other AC excitation type synchronous machine is synchronized. There is something that stops the machine.
A power converter for AC excitation of this AC excitation type synchronous machine is connected to the rotor winding of the AC excitation type synchronous machine, and AC winding is connected to the stator winding of this AC excitation type synchronous machine. Connected is a thyristor starter that converts AC power having a frequency proportional to the rotational speed of the excitation type synchronous machine into AC power synchronized with the system frequency.
During stop control, the AC excitation type synchronous machine is excited by the power converter and the thyristor starter is activated to regenerate the rotational energy of the AC excitation type synchronous machine to the power system. Is regeneratively braked (see, for example, Patent Document 1).

JP 47-40118 (2nd page-3rd page, Fig. 1)

However, according to the AC excitation type synchronous machine stop control method described above, when regenerative braking of a plurality of AC excitation type synchronous machines is attempted by the thyristor starter, unsynchronized AC power is input to the thyristor starter and the thyristor starter is started. The device cannot convert power.
Therefore, it is necessary to stop the AC excitation type synchronous machines one by one with the thyristor starter, and it takes time to stop all the AC excitation type synchronous machines. Is generated or consumed, and it takes time to switch from the power generation operation to the pumping operation, so that there is a problem that the contribution to the improvement of the system stability is delayed.

  An object of the present invention is to solve the above-described problems. The two AC excitation type synchronous machines are simultaneously stopped and quickly stopped and controlled to perform unnecessary power generation / pumping operation. It is an object of the present invention to obtain a stop control method for an AC excitation type synchronous machine that can reduce the generation or consumption of unnecessary power and improve the system stability.

  The AC excitation type synchronous machine stop control method according to the present invention is the AC excitation type synchronous machine which makes the first and second AC excitation type synchronous machines connected to the power system stop by regenerative braking in response to the stop command. This is a machine stop control method, in which the first power converter that converts the power of the first AC excitation type synchronous machine is stopped and the second AC excitation type synchronous machine is converted at the same time. A step of stopping the power converter, a step of starting a thyristor starter for exciting the first and second AC-excited synchronous machines after the first and second power converters are stopped, and a thyristor starter After starting the first and second power converters, and after starting the first and second power converters, the thyristor starter is used to switch the first and second AC excitation type synchronous machines. Excited, first and A step of regenerating rotational energy of the two AC-excited synchronous machines to the power system via the first and second power converters, and a rotational speed of one of the first and second AC-excited synchronous machines. A step of stopping the first and second power conversion devices, a step of stopping the thyristor starting device after the first and second power conversion devices are stopped, and And a step of mechanically stopping the first and second AC excitation type synchronous machines after the starter is stopped.

  According to the AC excitation type synchronous machine stop control method according to the present invention, the first and second AC excitation type synchronous machines are simultaneously DC-excited by the thyristor starter, and the first and second AC excitation type synchronous machines are controlled. Rotational energy is regenerated to the power system by the first and second power converters, so that the two AC excitation type synchronous machines are stopped at the same time to quickly stop and reduce unnecessary power generation and pumping operations. While generating or consuming unnecessary power, it is possible to improve system stability.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the drawings, the same or equivalent members and parts are described with the same reference numerals.

Embodiment 1 FIG.
FIG. 1 is a configuration diagram showing a variable speed pumped storage power generator equipped with an AC excitation type synchronous machine according to Embodiment 1 of the present invention.
In FIG. 1, the variable speed pumped-storage power generator 30 is controlled in power generation, pumping operation and shutdown by a control signal output from the control device 31 based on a command from a command room (not shown). Yes.

  In the variable speed pumped storage power generator 30, a parallel circuit breaker is provided in a stator winding of a first AC excitation type synchronous machine 1 (hereinafter referred to as "first synchronous machine") for generating and pumping water. 2 is connected. Between the parallel circuit breaker 2 and the low voltage winding of the main transformer 3, a power generation operation disconnector 4 and a pumping operation disconnector 5 are connected in parallel. The high-voltage winding of the main transformer 3 is connected to the power system 7 via the power line breaker 6.

  A first power converter 8 for exciting the first synchronous machine 1 is connected to the rotor winding of the first synchronous machine 1. The one current converter 8 converts AC power having a frequency proportional to the rotational speed of the first synchronous machine 1 into AC power synchronized with the system frequency. An excitation breaker 9 and an excitation transformer 10 are connected in series between the first power converter 8 and the low-voltage winding of the main transformer 3.

  A parallel circuit breaker 12 is connected to a stator winding of a second AC-excited synchronous machine 11 (hereinafter referred to as “second synchronous machine”) for generating and pumping water. Between the parallel circuit breaker 12 and the low voltage winding of the main transformer 13, a power generation operation disconnector 14 and a pumping operation disconnector 15 are connected in parallel. The high voltage winding of the main transformer 13 is connected to the power system 7 via a power line breaker 16.

  A second power converter 17 for exciting the second synchronous machine 2 is connected to the rotor winding of the second synchronous machine 2. The second current converter 17 converts AC power having a frequency proportional to the rotational speed of the second synchronous machine 11 into AC power synchronized with the system frequency. An excitation breaker 18 and an excitation transformer 19 are connected in series between the second power converter 17 and the low voltage winding of the main transformer 13.

  A starter circuit breaker 20 is connected to the low voltage winding of the main transformer 3. A starter transformer 21 and a thyristor starter 22 are connected to the starter circuit breaker 20 in series. A starter disconnector 23 is connected between the thyristor starter 22 and the stator winding of the first synchronous machine 1.

  A starter disconnector 24 is connected between the low voltage winding of the main transformer 13 and the starter transformer 21. A starter disconnector 25 is connected between the thyristor starter 22 and the stator winding of the second synchronous machine 11.

Next, an example of a stop control method for an AC excitation type synchronous machine according to Embodiment 1 of the present invention will be described.
FIG. 2 is a flowchart showing the control operation of the first and second synchronous machines 1 and 11 of FIG. The AC excitation type synchronous machine stop control method includes the following steps S1 to S8.

  In a state in which the first and second synchronous machines 1 and 11 are operating, the parallel circuit breakers 2 and 12 and the excitation circuit breakers 9 and 18 are closed, and the power generation operation disconnectors 4 and 14 and the pumping water One of the operation disconnectors 5 and 15 is open and the other is closed. The first synchronous machine 1 is excited by the first power converter 8 and the second synchronous machine 11 is excited by the second power converter 17.

  Stop control of the first and second synchronous machines 1 and 11 is started when a signal based on a stop command from the control room is input to the control device 31.

Receiving the stop command, the control device 31 outputs a signal and controls the first synchronous machine 1 and the second synchronous machine 11 to shift to the stop operation independently of each other.
First, based on the output signal of the control device 31, the parallel breaker 2 and the parallel breaker 12 are opened, and the first power converter 8 and the second power converter 17 are controlled to stop (step). S1). Control is performed after the first power converter 8 and the second power converter 17 are stopped and the stator voltage induced in the stator windings of the first and second synchronous machines 1 and 11 becomes zero. The starter disconnectors 23 and 25 are turned on by the device 31, and then the starter breakers 20 and 24 are turned on.

Next, based on the output signal of the control device 31, the thyristor starter 22 for direct current excitation of the first and second synchronous machines 1 and 11 is started (step S2).
After the thyristor starter 22 is started, the control device 31 is started in a regenerative mode that is an operation mode for regenerative braking of the first and second power converters 8 and 17 (step S3).

  After the activation of the first and second power conversion devices 8 and 17, the control device 31 causes the first and second synchronous machines 1 and 11 to be simultaneously DC-excited by the thyristor starter 22, and the first and second synchronizations are performed. The rotational energy of the machines 1 and 11 is converted through the first and second power converters 8 and 17 and regenerated simultaneously in the power system 7 (step S4). That is, the rotational energy of the first synchronous machine 1 is the first power converter 8 and the excitation transformer 10, and the rotational energy of the second synchronous machine 11 is the second power converter 17 and the excitation transformer. It will be regenerated simultaneously to the electric power system 7 via the device 19.

Next, the rotational speeds of the first and second synchronous machines 1 and 11 decrease while performing regenerative braking. Here, the first and second synchronous machines 1 and 11 are controlled by the control device 31. It is confirmed whether or not any of the rotation speeds is equal to or lower than a speed at which the first and second power conversion devices 8 and 17 can regenerate (approximately 10% or less of the rated rotation speed) (step S5).
When the rotational speed of any one of the first and second synchronous machines 1 and 11 is equal to or lower than the regenerative speed, the control circuit 31 stops the first and second power converters 8 and 17. (Step S6).
If the rotational speeds of the first and second synchronous machines 1 and 11 are not less than the regenerative speed, the control circuit 31 returns to step S4 and continues the regenerative braking control.

After stopping the first and second power converters 8, 17, the control device 31 stops the thyristor starter 22, opens the starter breakers 9, 18, and then opens the starter disconnector 23, 25 is opened and regenerative braking is stopped (step S7).
After step S7, the control device 31 mechanically brakes the first and second synchronous machines 1 and 11 with a mechanical brake (not shown) to complete the stop (step S8), whereby the first and second synchronizations are performed. The stop control of the machines 1 and 11 will end.

  As described above, according to the AC excitation type synchronous machine stop control method of the first embodiment, the first and second synchronous machines 1 and 11 are simultaneously DC-excited by the thyristor starter 22, and the first and first Since the rotational energy of the two synchronous machines 1 and 11 is regenerated in parallel with the power system 7 by the first and second power converters 8 and 17, the two first and second synchronous machines 1 and 11 are connected to each other. At the same time, there is an effect that the system can be stopped and controlled quickly to reduce unnecessary power generation / pumping operation, thereby generating or consuming unnecessary power, and improving system stability.

Embodiment 2. FIG.
In the first embodiment, the AC excitation type synchronous machine is stopped in order to set the stator voltage to 0. However, the excitation current output from the power converter may be controlled to 0. Hereinafter, a stop control method for the AC excitation type synchronous machine according to the second embodiment of the present invention in which the operation of the power converter is different will be described. The configuration of the variable speed pumped storage power generator is the same as that of the first embodiment.

  FIG. 3 is a flowchart showing a stop control method for an AC excitation type synchronous machine according to Embodiment 2 of the present invention. The AC excitation type synchronous machine stop control method includes the following steps S1a to S8.

  As in the first embodiment, when the first and second synchronous machines 1 and 11 are operating, the parallel circuit breakers 2 and 12 and the excitation circuit breakers 9 and 18 are closed, and the power generation operation is performed. One of the disconnectors 4 and 14 and the disconnectors 5 and 15 for pumping operation is open and the other is closed. The first synchronous machine 1 is excited by the first power converter 8 and the second synchronous machine 11 is excited by the second power converter 17.

  Receiving the stop command from the control room, the control device 31 outputs a signal and controls the first synchronous machine 1 and the second synchronous machine 11 to independently shift to the stop operation.

  First, based on the output signal of the control device 31, the parallel breaker 2 and the parallel breaker 12 are opened. Thereafter, the control device 31 prohibits the supply of the excitation current from the first power conversion device 8 that converts the power of the first synchronous machine 1 to the first synchronous machine 1, and the second synchronous machine 11 The supply of excitation current from the second power conversion device 17 that converts power to the second synchronous machine 11 is prohibited (step S1a). Each control circuit (not shown) in the first and second voltage converters 8 and 17 receives the signal prohibiting the supply of the excitation current of the control device 31 and controls the excitation current to be zero. To do. Thus, after the supply of exciting current is prohibited and the stator voltage induced in the stator windings of the first and second synchronous machines 1 and 11 becomes zero, the control device 31 disconnects the starter. 23 and 25 are turned on, and then the starter circuit breakers 20 and 24 are turned on, respectively.

Next, the control device 31 activates the thyristor starter 22 for direct current excitation of the first and second synchronous machines 1 and 11 (step S2).
After starting the thyristor starter 22, the control device 31 switches the operation mode of the first and second power converters 8 and 17 to the regeneration mode (step S3a).
Hereinafter, the flow after step S4 is the same as that of the first embodiment, and the first and second synchronous machines 1 and 11 are mechanically controlled to stop after regenerative braking.

  As described above, according to the AC excitation type synchronous machine stop control method of the second embodiment, the supply of excitation current is prohibited and induced in the stator windings of the first and second synchronous machines 1 and 11. Since the thyristor starting device 22 is started after the stator voltage becomes zero, the first and second disconnectors 23 and 25 can be turned on quickly, and the first and second synchronous machines 1 and 2 Since 11 starts regenerative braking at a higher rotational speed, there is an effect that a larger amount of regenerative electric power can be obtained.

Embodiment 3 FIG.
In the first embodiment, the disconnector is used to disconnect between the power conversion device and the thyristor starter, but a breaker may be used. Hereinafter, a configuration for cutting off the current between the AC excitation type synchronous machine and the thyristor starter and a stop control method for the AC excitation type synchronous machine according to Embodiment 3 of the present invention in which operations related to this configuration are different will be described. To do.

FIG. 4 is a block diagram showing a variable speed pumped storage power generator equipped with an AC excitation type synchronous machine according to Embodiment 3 of the present invention.
As shown in FIG. 4, a starter circuit breaker 26 is connected between the low voltage winding of the main transformer 13 and the starter transformer 21. A starter circuit breaker 27 is connected between the thyristor starter 22 and the stator winding of the second synchronous machine 11.

Next, an example of a stop control method for the first and second synchronous machines 1 and 11 according to Embodiment 3 of the present invention will be described.
FIG. 5 is a flowchart showing the control operation of the first and second synchronous machines 1 and 11 shown in FIG. The AC excitation type synchronous machine stop control method includes the following steps S9 to S19.

  As in the first embodiment, when the first and second synchronous machines 1 and 11 are operating, the parallel circuit breakers 2 and 12 and the excitation circuit breakers 9 and 18 are closed, and the power generation operation is performed. One of the disconnectors 4 and 14 and the disconnectors 5 and 15 for pumping operation is open and the other is closed. The first synchronous machine 1 is excited by the first power converter 8 and the second synchronous machine 11 is excited by the second power converter 17.

  Stop control of the first and second synchronous machines 1 and 11 is started when a signal based on a stop command from the control room is input to the control device 31.

Receiving the stop command, the control device 31 outputs a signal and controls the first synchronous machine 1 and the second synchronous machine 11 to shift to the stop operation independently of each other.
First, based on the output signal of the control device 31, the parallel breaker 2 and the parallel breaker 12 are opened, and the first power converter 8 and the second power converter 17 are controlled to stop (step). S9). Control is performed after the first power converter 8 and the second power converter 17 are stopped and the stator voltage induced in the stator windings of the first and second synchronous machines 1 and 11 becomes zero. The starter circuit breakers 26 and 27 are respectively turned on by the device 31, and then the starter breakers 20 and 24 are turned on respectively.

Next, based on the output signal of the control device 31, the thyristor starter 22 for direct current excitation of the first and second synchronous machines 1 and 11 is started (step S10).
After starting the thyristor starter 22, the controller 31 starts the first and second power converters 8 and 17 in the regeneration mode (step S11).

  After the activation of the first power converter 8, the control device 31 DC-excites the second synchronous machine 1 using the thyristor starter 22, and converts the rotational energy of the first synchronous machine 1 into the first power converter 8. Through the power system 7 (step S12).

Next, it is confirmed by the control apparatus 31 whether the rotational speed of the 1st synchronous machine 1 is below the speed which the 1st power converter device 8 can reproduce (step S13).
When the rotation speed of the first synchronous machine 1 is equal to or lower than the regenerative speed, the control circuit 31 stops the first power converter 8 (step S14).
If the rotation speed of the first synchronous machine 1 is not less than the recyclable speed, the control circuit 31 returns to step S12 and continues the regenerative braking control of the first synchronous machine 1.

  In parallel with step S <b> 12, after starting the second power converter 17, the control device 31 DC-excites the second synchronous machine 11 by the thyristor starter 22, and converts the rotational energy of the second synchronous machine 11 to the first The power is regenerated in the power system 7 via the second power converter 17 (step S15).

Next, it is confirmed by the control device 31 whether or not the rotational speed of the second synchronous machine 11 is equal to or lower than the speed at which the second power conversion device 17 can be regenerated (step S16).
When the rotation speed of the second synchronous machine 11 is equal to or lower than the regenerative speed, the control circuit 31 stops the second power conversion device 17 (step S17).
If the rotational speed of the second synchronous machine 11 is not less than the recyclable speed, the control circuit 31 returns to step S15 and continues the regenerative braking control of the second synchronous machine 11.

  After the first and second power converters 8 and 17 are stopped, the control device 31 stops the thyristor starter 22, opens the starter breakers 9 and 18, and opens the starter breakers 26 and 27. Is opened to stop regenerative braking (step S18).

  After the first and second power conversion devices 8 and 17 are stopped, the control device 31 mechanically brakes the first and second synchronous machines 1 and 11 with a mechanical brake (not shown) to complete the stop (step S19). ), The stop control of the first and second synchronous machines 1 and 11 is completed.

  As described above, according to the AC excitation type synchronous machine stop control method according to the third embodiment of the present invention, power is regenerated until the rotational speeds of the first and second synchronous machines are equal to or lower than the regenerative rotational speeds. Therefore, the amount of regenerative power can be increased.

Embodiment 4 FIG.
In the third embodiment, the AC excitation type synchronous machine is stopped in order to set the stator voltage to 0. However, the excitation current output from the power converter may be controlled to 0. Hereinafter, a stop control method for an AC excitation type synchronous machine according to Embodiment 3 of the present invention in which the operation of the power conversion device is different will be described. The configuration of the variable speed pumped storage power generator is the same as that of the first embodiment.

  FIG. 6 is a flowchart showing a stop control method for an AC excitation type synchronous machine according to Embodiment 4 of the present invention. The AC excitation type synchronous machine stop control method includes the following steps S9a to S19.

  As in the third embodiment, when the first and second synchronous machines 1 and 11 are operating, the parallel circuit breakers 2 and 12 and the excitation circuit breakers 9 and 18 are closed, and the power generation operation is performed. One of the disconnectors 4 and 14 and the disconnectors 5 and 15 for pumping operation is open and the other is closed. The first synchronous machine 1 is excited by the first power converter 8 and the second synchronous machine 11 is excited by the second power converter 17.

  Receiving the stop command from the control room, the control device 31 outputs a signal and controls the first synchronous machine 1 and the second synchronous machine 11 to independently shift to the stop operation.

  First, based on the output signal of the control device 31, the parallel breaker 2 and the parallel breaker 12 are opened. Thereafter, the control device 31 prohibits the supply of the excitation current from the first power conversion device 8 that converts the power of the first synchronous machine 1 to the first synchronous machine 1, and the second synchronous machine 11 The supply of the excitation current from the second power converter 17 that converts power to the second synchronous machine 11 is prohibited (step S9a). Each control circuit (not shown) in the first and second voltage converters 8 and 17 receives the signal prohibiting the supply of the excitation current of the control device 31 and controls the excitation current to be zero. To do. After the supply of the excitation current is prohibited in this way and the stator voltage induced in the stator windings of the first and second synchronous machines 1 and 11 becomes 0, the controller 31 starts the circuit breaker for the starter. 26 and 27 are turned on, and then the starter circuit breakers 20 and 24 are turned on, respectively.

Next, the control device 31 activates the thyristor starter 22 for direct current excitation of the first and second synchronous machines 8 and 17 (step S10).
After starting the thyristor starter 22, the control device 31 switches the operation mode of the first and second synchronous machines 1 and 11 to the regeneration mode (step S11a).
Hereinafter, the flow after step S12 is the same as that in the third embodiment, and the first and second synchronous machines 1 and 11 are mechanically controlled to stop after regenerative braking.

  As described above, according to the AC excitation type synchronous machine stop control method according to the fourth embodiment of the present invention, the supply of the excitation current is prohibited and the stator windings of the first and second synchronous machines 1 and 11 are prohibited. After the induced stator voltage becomes zero, the thyristor starter 22 is started, and the electric power can be regenerated until the rotation speeds of the first and second synchronous machines are equal to or lower than a recyclable rotation speed. Therefore, more regenerative electric energy can be obtained.

  In each of the embodiments described above, the thyristor starter 22 has been described with respect to the case where the first and second synchronous machines 1 and 11 are DC-excited for regenerative braking. The same regenerative braking can be performed even if the first and second synchronous machines 1 and 11 are AC-excited.

  In each of the above embodiments, the case where two first and second synchronous machines 1 and 11 are simultaneously regeneratively braked has been described. However, the case where three or more synchronous machines are simultaneously regeneratively braked is also described. The same application can be made by exciting a plurality of synchronous machines simultaneously with a thyristor starter.

It is a block diagram which shows the variable speed pumped-storage power generator provided with the alternating current excitation type | mold synchronous machine which concerns on Embodiment 1 of this invention. It is a flowchart which shows the stop control method of the AC excitation type synchronous machine which concerns on Embodiment 1 of this invention. It is a flowchart which shows the stop control method of the AC excitation type synchronous machine which concerns on Embodiment 2 of this invention. It is a block diagram which shows the variable speed pumped-storage power generator provided with the alternating current excitation type synchronous machine which concerns on Embodiment 3 of this invention. It is a flowchart which shows the stop control method of the AC excitation type synchronous machine which concerns on Embodiment 3 of this invention. It is a flowchart which shows the stop control method of the AC excitation type synchronous machine which concerns on Embodiment 4 of this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 1st AC excitation type | mold synchronous machine, 7 Electric power system, 8 1st power converter device, 11 2nd AC excitation type | mold synchronous machine, 17 2nd power converter device, 22 Thyristor starting device, 31 Control apparatus.

Claims (5)

In response to a stop command, a stop control method for an AC excitation type synchronous machine that stops the first and second AC excitation type synchronous machines connected to the power system by regenerative braking,
Stopping the first power converter that converts the power of the first AC excitation type synchronous machine and simultaneously stopping the second power conversion apparatus that converts the power of the second AC excitation type synchronous machine When,
Activating a thyristor starter for exciting the first and second AC-excited synchronous machines after the first and second power converters are stopped;
Starting the first and second power converters after starting the thyristor starter;
After activation of the first and second power converters, the thyristor starter excites the first and second AC excitation type synchronous machines, and the first and second AC excitation type synchronous machines Regenerating rotational energy to the power system via the first and second power converters;
Stopping the first and second power converters when the rotational speed of one of the first and second AC-excited synchronous machines is equal to or lower than a regenerative speed;
Stopping the thyristor starter after stopping the first and second power converters;
And a step of mechanically stopping the first and second AC excitation type synchronous machines after the thyristor starter is stopped. In response to a stop command, a stop control method for an AC excitation type synchronous machine that stops the first and second AC excitation type synchronous machines connected to the power system by regenerative braking,
The supply of the excitation current from the first power conversion device for converting the power of the first AC excitation type synchronous machine to the first AC excitation type synchronous machine is prohibited, and at the same time, the second AC excitation type synchronous machine Prohibiting the supply of the excitation current from the second power conversion device for converting the power of the power to the second AC excitation type synchronous machine;
Starting a thyristor starting device for exciting the first and second AC excitation type synchronous machines after prohibiting the supply of the excitation current to the first and second AC excitation type synchronous machines;
After the thyristor starter is started, the first and second AC excitation type synchronous machines are excited by the thyristor starter, and rotational energy of the first and second AC excitation type synchronous machines is changed to the first and second AC excitation type synchronous machines. Regenerating to the power system via a second power converter;
Stopping the first and second power converters when the rotational speed of one of the first and second AC-excited synchronous machines is equal to or lower than a regenerative speed;
Stopping the thyristor starter after stopping the first and second power converters;
And a step of mechanically stopping the first and second AC excitation type synchronous machines after the thyristor starter is stopped. In response to a stop command, a stop control method for an AC excitation type synchronous machine that stops the first and second AC excitation type synchronous machines connected to the power system by regenerative braking,
Stopping the first power converter that converts the power of the first AC excitation type synchronous machine and simultaneously stopping the second power conversion apparatus that converts the power of the second AC excitation type synchronous machine When,
Activating a thyristor starter for exciting the first and second AC-excited synchronous machines after the first and second power converters are stopped;
Starting the first and second power converters after starting the thyristor starter;
After activation of the first and second power converters, the thyristor starter excites the first and second AC excitation type synchronous machines, and the first and second AC excitation type synchronous machines Regenerating rotational energy to the power system via the first and second power converters;
Stopping the first power converter when the rotational speed of the first AC-excited synchronous machine is less than a regenerative speed;
After stopping the first power converter, stopping the first AC excitation type synchronous machine;
Stopping the second power conversion device when the rotational speed of the second AC-excited synchronous machine is less than a regenerative speed;
And a step of mechanically stopping the second AC excitation type synchronous machine after stopping the second power conversion device. In response to a stop command, a stop control method for an AC excitation type synchronous machine that stops the first and second AC excitation type synchronous machines connected to the power system by regenerative braking,
The supply of the excitation current from the first power conversion device for converting the power of the first AC excitation type synchronous machine to the first AC excitation type synchronous machine is prohibited, and at the same time, the second AC excitation type synchronous machine Prohibiting the supply of the excitation current from the second power conversion device for converting the power of the power to the second AC excitation type synchronous machine;
Starting a thyristor starting device for exciting the first and second AC excitation type synchronous machines after prohibiting the supply of the excitation current to the first and second AC excitation type synchronous machines;
After the thyristor starter is started, the first and second AC excitation type synchronous machines are excited by the thyristor starter, and rotational energy of the first and second AC excitation type synchronous machines is changed to the first and second AC excitation type synchronous machines. Regenerating to the power system via a second power converter;
Stopping the first power converter when the rotational speed of the first AC-excited synchronous machine is less than a regenerative speed;
Mechanically stopping the first AC-excited synchronous machine after stopping the first power converter;
Stopping the second power conversion device when the rotational speed of the second AC-excited synchronous machine is less than a regenerative speed;
And a step of mechanically stopping the second AC excitation type synchronous machine after stopping the second power conversion device.   5. The AC excitation type synchronous machine stop control method according to claim 3, further comprising a step of stopping the thyristor starter after the first and second power converters are stopped. 6.

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