JP5822697B2 - Power generation system and operation control method thereof - Google Patents

Description

The present invention includes a stator having a primary winding connected to an electric power system, and a rotor having a secondary winding, and a secondary excitation generator that rotates the rotor with the rotational power of an engine crankshaft. When,
A first power converter having an AC side connected to the power system;
A second power converter having an AC side connected to the secondary winding;
A direct current unit connecting the direct current side of the first power converter and the direct current side of the second power converter;
The present invention relates to a power generation system including control means for controlling operation and an operation control method thereof.

  Power generation systems using secondary excitation generators are mainly used for wind power generation and pumped-storage power generation. "In some cases, it is called" engine speed ".) Can be freely selected, so the operating range can be expanded and the engine can be shared in regions with different commercial frequencies.

  As a power generation system used for wind power generation, a secondary excitation generator having a stator having a primary winding connected to an electric power system and a rotor having a secondary winding, and an AC side is connected to the electric power system. The first power converter, the second power converter whose AC side is connected to the secondary winding, and the DC that connects the DC side of the first power converter and the DC side of the second power converter The thing provided with the part is known (for example, refer patent document 1).

JP 2009-027766 A JP 2006-105075 A

  In the power generation system in which the secondary excitation generator is driven by the engine, the optimum engine speed can be selected according to the power generation output, so it is hoped that the engine can be operated efficiently and stably in a wide range of speeds. It is rare. For example, if the engine speed is reduced when the power generation output is reduced, the supercharger may not work sufficiently and the supply air pressure required by the engine may not be supplied. On the other hand, when the engine speed is increased when the power generation output is increased, the turbocharger compresses the supply air more than necessary, and energy loss may occur due to reduction to an appropriate pressure.

  The present invention has been made paying attention to such points, and its purpose is to change the operating state of the engine in a power generation system that generates power by operating a secondary excitation generator using the engine as a drive source. However, the present invention provides a technique capable of operating the engine efficiently and stably and realizing excellent power generation efficiency.

In order to achieve this object, the power generation system according to the present invention includes:
A secondary excitation generator having a stator with a primary winding connected to the power system and a rotor with a secondary winding, and rotating the rotor with the rotational power of the crankshaft of the engine;
A first power converter having an AC side connected to the power system;
A second power converter having an AC side connected to the secondary winding;
A direct current unit connecting the direct current side of the first power converter and the direct current side of the second power converter;
A power generation system comprising a control means for controlling operation,
The first characteristic configuration is
A motor-generator capable of transmitting and receiving power to a turbocharger provided in the engine with respect to a rotating shaft of the turbocharger;
The operation state of the motor generator includes an electric state in which electric power is supplied to the motor generator from the DC unit and the motor generator is operated as a motor, and electric power is extracted from the motor generator to the DC unit. State switching means for switching between a power generation state in which the motor generator is operated as a generator ;
A rotational speed detection means for detecting the rotational speed of the crankshaft,
When the rotation speed of the crankshaft is in a low rotation speed range, the state switching means sets the operation state of the motor generator to the electric driving state, and the rotation speed of the crankshaft is higher than the low rotation speed range. When the rotational speed is within the range, the motor generator is in the power generation state.
The rotational speed detection means is configured to calculate the rotational speed of the crankshaft from the direction and frequency of excitation power with respect to the secondary winding of the second power converter .

Moreover, the operation control method of the power generation system according to the present invention for achieving this object is as follows:
A secondary excitation generator having a stator with a primary winding connected to the power system and a rotor with a secondary winding, and rotating the rotor with the rotational power of the crankshaft of the engine;
A first power converter having an AC side connected to the power system;
A second power converter having an AC side connected to the secondary winding;
A direct current unit connecting the direct current side of the first power converter and the direct current side of the second power converter;
An operation control method for a power generation system comprising a control means for controlling operation,
Its feature configuration is
The turbocharger provided in the engine is provided with a motor generator capable of transmitting and receiving power to the rotating shaft of the turbocharger,
Based on the rotational speed of the crankshaft calculated from the direction and frequency of the excitation power with respect to the secondary winding of the second power converter, the operating state of the motor generator is determined based on the low rotational speed of the crankshaft. When within a few regions, the motor generator is in an electric state in which electric power is supplied from the DC section to operate the motor generator as a motor, and the crankshaft rotational speed is higher than the low rotational speed region. when the rotational speed region lies in the fact that to the power generating state to operate the motor generator as a generator is taken out of power to the DC portion from the electric generator.

According to the above characteristic configuration, even when the operating state of the engine is changed, supercharging to the engine and recovery of surplus energy of the exhaust gas can be performed in an appropriate state. As a result, the engine can be efficiently operated. In addition, it is possible to realize a power generation system that can operate stably and achieve excellent power generation efficiency.
That is, the operating state of the motor generator connected to the supercharger is changed to the electric state by the state switching means, so that rotational power is applied from the motor generator in the electric state to the rotating shaft of the supercharger. In this state, the rotation power from the motor generator in the electric state is added to the rotation power from the turbine driven by the exhaust gas to rotate the compressor of the turbocharger to maintain the engine supercharging pressure at a high level. Therefore, the engine can be operated efficiently and stably.
On the other hand, the state switching means recovers the rotational power to the motor generator in the power generation state with respect to the rotation shaft of the turbocharger by setting the operating state of the motor generator connected to the supercharger to the power generation state. In this state, the motor generator in the above power generation state can be driven to rotate by surplus rotational power obtained by subtracting rotational power that cannot be consumed by the compressor from the rotational power of the turbine driven by exhaust gas. A lot of generated power can be obtained.
Furthermore, the operating state of the motor generator connected to the supercharger can be switched in accordance with the engine speed (the number of revolutions of the crankshaft), so that the engine operating state can always be maintained in an appropriate state.
Specifically, when the engine speed is too low, the energy of the exhaust gas is reduced and the turbocharger cannot be sufficiently driven to rotate, and problems such as engine efficiency reduction may occur. Therefore, when the engine speed is within a relatively low speed range, the motor generator connected to the turbocharger is set to the electric state and rotated from the motor generator with respect to the rotation shaft of the turbocharger. By applying power, the supercharger can be driven to rotate in an appropriate state to maintain the supercharging pressure at a high state, and problems such as a decrease in engine efficiency can be avoided.
On the other hand, when the engine speed is too high, the exhaust gas energy increases and surplus power is generated in the turbocharger, which may cause problems such as energy loss. Therefore, when the engine speed is in a high speed range higher than the low speed range, the motor generator connected to the supercharger is set to the power generation state, and the electric motor is connected to the rotating shaft of the supercharger. By collecting the rotational power to the generator, problems such as energy loss can be avoided and high power generation efficiency can be realized.
Furthermore, since the direction and frequency of the excitation power with respect to the secondary winding of the second power converter change according to the engine speed (the rotation speed of the crankshaft), the direction and frequency of the excitation power The engine speed is calculated from the engine speed, and the operating state of the motor generator connected to the supercharger is switched from the calculated engine speed, so that the operating state of the engine can always be maintained in an appropriate state.

Schematic configuration diagram of a power generation system according to an embodiment of the present invention The graph which shows the change with respect to the engine speed of the direction of the excitation electric power with respect to the said secondary winding of a 2nd power converter, and a frequency

  An embodiment of a power generation system and an operation control method thereof according to the present invention will be described with reference to the drawings. In addition, this invention is not limited to the structure described in embodiment and drawing demonstrated below, A various modification | change is possible if it is a structure with the same effect.

  FIG. 1 shows a power generation system 1 according to this embodiment. The power generation system 1 includes a secondary excitation generator (or a double-feed winding induction generator) 2, an engine 3 as a power source, a first power converter 11, a second power converter 12, The power storage device 5, the first switch 21, the second switch 22, the third switch 23, and the control device 100 are provided. The secondary excitation generator 2 generates power (three-phase AC power) having the same frequency (for example, 50 [Hz] or 60 [Hz]) as that of the power system (commercial power system) 4 and generates the power. The power 7 is configured to be supplied to the power consuming load 7 and the power system 4. As the load 7, for example, there are an indoor unit, an outdoor unit, an electric lamp and the like provided in the air conditioning equipment.

  The secondary excitation generator 2 includes a stator 2b (stator) having a primary winding (not shown) and a rotor 2a (rotor) having a secondary winding (not shown). . The primary winding included in the stator 2 b is connected to the power system 4 via the first switch 21 and the second switch 22. The primary winding included in the stator 2 b is also connected to the load 7 via the first switch 21 and the third switch 23. On the other hand, the secondary winding included in the rotor 2 a is connected to the filter circuit 10, the second power converter 12, the DC unit 13, the first power converter 11, the filter circuit 10, the transformer 6, and the second switch 22. Connected to the power system 4. The secondary winding included in the rotor 2 a is connected to the filter circuit 10, the second power converter 12, the DC unit 13, the first power converter 11, the filter circuit 10, the transformer 6, and the third switch 23. The load 7 is also connected.

  In the following description, the primary winding side included in the stator 2b is referred to as “primary side of the secondary excitation generator”, and the secondary winding side included in the rotor 2a is referred to as “secondary side of the secondary excitation generator”. To do. Therefore, the frequency of power (voltage, current) generated on the primary side of the secondary excitation generator 2 is the frequency of power supplied to the load 7 and the power system 4.

  The engine 3 is mechanically coupled to the rotor 2a of the secondary excitation generator 2, and drives (rotates) the rotor 2a. In this example, the output shaft of the engine 3 is connected (directly connected) so as to rotate integrally with the rotor 2a, and the rotor 2a rotates at the same rotational speed as the engine rotational speed. In addition, it can also be set as the structure which provides a reduction gear and a speed up gear between the output shaft of the engine 3, and the rotor 2a. In this example, the engine 3 is a gas engine that uses city gas as fuel, and serves as a corner of a cogeneration facility that can supply heat in addition to electric power in parallel in addition to electric power. As such an engine 3, for example, an engine having a rated output of 1 [kW], several tens [kW], or several [MW] can be employed.

  The first power converter 11 is connected to the stator 2b (primary winding) of the secondary excitation generator 2 via the first switch 21 on the AC side (the right side in FIG. 1), and the second switch 22. Is connected to the power system 4 via the third switch 23, and is further connected to the load 7 via the third switch 23. Further, the first power converter 11 has a DC side (left side in FIG. 1) connected to the DC unit 13. The second power converter 12 is connected to the rotor 2a (secondary winding) of the secondary excitation generator 2 on the AC side (left side in FIG. 1). The second power converter 12 is connected to the DC unit 13 on the DC side (right side in FIG. 1). Each of the first power converter 11 and the second power converter 12 has a function as an inverter that converts (reversely converts) DC power on the DC side into AC power and supplies the AC power to the AC side. It is configured to be able to perform both of the function as a converter that converts (forward-converts) AC power into DC power and supplies it to the DC side.

  Such first power converter 11 and second power converter 12 are configured to include a plurality of (for example, six) switching elements. As the switching element, power transistors having various structures such as a MOSFET (Metal Oxide Field Effect Transistor) and an IGBT (Insulated Gate Bipolar Transistor) can be adopted. A PWM (pulse width modulation) signal is input to the first power converter 11 and the second power converter 12, and the switching element performs a switching operation (on / off operation) based on the PWM signal. Note that a PWM signal for operating the first power converter 11 and the second power converter 12 is generated by the control device 100.

  As shown in FIG. 1, a filter circuit 10 including an inductance and a capacitor is provided on both the AC side of the first power converter 11 and the AC side of the second power converter 12. The filter circuit 10 is a filter that removes high-frequency components generated by switching of the switching element, and the output voltage waveform from the first power converter 11 and the second power converter 12 is sinusoidal by the filter circuit 10. Converted.

  Moreover, as shown in FIG. 1, the transformer 6 is provided in the secondary excitation generator 2 side (electric power system 4 side) rather than the filter circuit 10 provided in the alternating current side of the 1st power converter 11. As shown in FIG. . In the following description, “the primary side of the transformer” refers to the first power converter 11 side of the transformer 6, and “the secondary side of the transformer” refers to the secondary excitation generator 2 side of the transformer 6. Point to.

  The DC unit 13 is a part that connects the DC side of the first power converter 11 and the DC side of the second power converter 12. The DC unit 13 includes a capacitor 8 and is connected to the power storage device 5. The power storage device 5 supplies power necessary for starting up the power generation system 1. It is also possible to suppress fluctuations in the power supplied to the load 7 and the power system 4 using the power storage device 5. The power storage device 5 is configured by, for example, a storage battery, an electric double layer capacitor, or the like, and can supply and discharge power to the direct current unit 13 and can be charged by receiving power from the direct current unit 13. Composed. A switch may be interposed between the power storage device 5 and the DC unit 13.

  The first switch 21 selectively connects the stator 2 b (primary winding) of the secondary excitation generator 2 and the first power converter 11. The second switch 22 selectively connects the power system 4 and the first power converter 11. The first switch 21 cooperates with the second switch 22 to selectively connect the stator 2b (primary winding) of the secondary excitation generator 2 and the power system 4 and to cooperate with the third switch 23. In operation, the stator 2b (primary winding) of the secondary excitation generator 2 and the load 7 are selectively connected. In addition, the second switch 22 selectively connects the power system 4 and the load 7 in cooperation with the third switch 23.

  Each of the first switch 21, the second switch 22, and the third switch 23 is controlled to open / close based on an open / close signal generated by a switch control unit (not shown) of the control device 100. These switches can be, for example, electromagnetic contact type switches that open and close by the operation of an electromagnet.

  The power generation system 1 having the above configuration is a system with a high degree of freedom with respect to the frequency (voltage, current frequency) of the generated power. Although detailed description is omitted (for details, see, for example, Patent Document 1), the frequency of the generated power of the power generation system 1 (the frequency of the primary side voltage induced on the primary side of the secondary excitation generator 2) is f1. If the rotation frequency of the rotor 2a is f0 and the frequency of the alternating current (excitation power) supplied to the secondary winding to excite the secondary winding of the rotor 2a is f2, then “f1 = f0 + f2 ". Here, the rotation frequency f0 of the rotor 2a is obtained from “f0 = m × n / 120”, where the number of rotations of the rotor 2a is m [rpm] and the number of magnetic poles of the secondary excitation generator 2 is n.

  Specifically, when the rotational speed of the rotor 2a is 1100 [rpm] and the number of magnetic poles of the secondary excitation generator 2 is “6”, the rotational frequency f0 of the rotor 2a is 55 [Hz]. Become. Therefore, in this case, if the second power converter 12 is controlled to supply excitation power having a frequency of 5 [Hz] to the secondary winding (f2 = 5 [Hz]), the frequency is 60 [Hz]. AC power can be obtained. Conversely, if the second power converter 12 is controlled to extract excitation power having a frequency of 5 [Hz] from the secondary winding (f2 = −5 [Hz]), an alternating current having a frequency of 50 [Hz]. Electric power can be obtained. In addition, the rotation speed of the rotor 2a (namely, the rotation speed of the engine 3) can select arbitrary rotation speeds other than a synchronous rotation speed. The synchronous rotation speed is 1200 [rpm] when the frequency of the power system 4 is 60 [Hz] and the number of magnetic poles of the secondary excitation generator 2 is “6”.

Thus, even if the rotation speed of the rotor 2a (that is, the engine rotation speed) is the same, the frequency f1 of the generated power is changed by changing the frequency f2 and direction of the excitation power supplied to the secondary winding of the rotor 2a. Can be changed. The direction of the excitation power between the second power converter 12 and the secondary winding of the rotor 2a is the supply direction X when the excitation power is supplied from the second power converter 12 to the secondary winding. , And switching between the extraction direction Y when the excitation power is extracted from the secondary winding to the second power converter 12.
Therefore, for example, there is an advantage that the engine 3 having the same specification can be used in an area where the frequency of the AC power supply is 50 [Hz] and an area where the frequency is 60 [Hz]. In addition, by appropriately selecting the engine speed according to the load, it is possible to improve the partial load efficiency of the power source or increase the speed of the power source so that the output of the power generation system 1 as a whole (rated Output) can be increased.
The engine 3 is configured such that the engine speed is changed by controlling the output by adjusting the opening of the throttle valve 16.

As described above, the power generation system 1 can efficiently and stably operate the engine 3 even when the operation state such as the engine speed is changed, and can realize excellent power generation efficiency. For this purpose, the motor generator 15 is mechanically connected in a state where power can be transmitted to and received from the rotating shaft of a turbocharger 9 provided in the engine 3. The apparatus 100 is configured to function as state switching means X that switches the operating state of the motor generator 15.
Although not shown, the motor generator 15 includes a known synchronous motor or induction motor that includes a rotor attached to a rotating shaft and a stator that is rotatably attached around the rotor. The operation state is switched between a power generation state in which the rotational power of the rotary shaft is converted into AC power and an electric state in which the AC power is converted into rotational power of the rotary shaft.
The motor generator 15 is configured to be able to exchange DC power with the DC unit 13 described above via the third power converter 14, and more specifically, the AC generated by the motor generator 15 in the power generation state. The electric power is converted to DC power by the third power converter 14 and then supplied to the DC unit 13. On the other hand, the DC power taken out from the DC unit 13 is converted to AC power by the third power converter 14 and then the electric power is supplied. It is supplied to the motor generator 15 in the state.
And the state switching means X switches the electric power supply direction in the 3rd power converter 14 as mentioned above, and makes the operation state of the motor generator 15 operate the motor generator 15 as an electric motor. And means for switching between the motor generator 15 and a power generation state in which the motor generator 15 is operated as a generator.

  That is, when the state switching means X sets the operating state of the motor generator 15 connected to the supercharger 9 to the electric state, the state where the rotational power is applied from the motor generator 15 to the rotating shaft of the supercharger 9 Become. Then, in the supercharger 9, the rotational power applied from the motor generator 15 in the electric state is added to the rotational power from the turbine 9b driven by the exhaust gas E discharged from the engine 3, and the compressor 9a rotates. Driven. Accordingly, the compressor 9a supplies the fresh air I (mixed air or air) to the engine 3 at a higher pressure than when the motor generator 15 is not operated in the electric state, and the charging efficiency of the fresh air I to the engine 3 and Since the compression rate is improved, the engine 3 is operated with high efficiency and stability.

  On the other hand, when the state switching means X sets the operating state of the motor generator 15 connected to the supercharger 9 to the power generation state, the state switching means X recovers rotational power to the motor generator 15 with respect to the rotating shaft of the supercharger 9. Become. Then, the motor generator 15 generates electric power by being rotationally driven by excess rotational power obtained by subtracting rotational power that cannot be consumed by the compressor 9a from rotational power of the turbine 9b driven by the exhaust gas E. Therefore, as much surplus energy as possible is recovered from the engine 3 to obtain generated power.

Further, the engine 3 is provided with a rotation speed detection means Y for detecting the engine rotation speed.
The rotational speed detection means Y is configured to calculate the engine rotational speed from the direction and frequency of excitation power with respect to the secondary winding included in the rotor 2a of the second power converter 12 by the control device 100. .

Specifically, as shown in FIG. 2, the rotational frequency f0 of the rotor 2a corresponding to the engine speed is within the range of the generated power of the power generation system 1 within the range where the engine speed r is 0 or more and less than the predetermined speed r0. Since the frequency becomes smaller than the frequency f1, the direction of the excitation power between the second power converter 12 and the secondary winding of the rotor 2a is the direction in which the excitation power is supplied to the secondary winding (the supply shown in FIG. 1). Direction X), and the absolute value of the frequency of the excitation power changes in inverse proportion to the engine speed.
On the other hand, when the engine speed r is within the range of the predetermined speed r0 or more, the direction of the excitation power between the second power converter 12 and the secondary winding of the rotor 2a is such that no excitation power is generated or the secondary The excitation power is extracted from the winding (extraction direction Y shown in FIG. 1), and the absolute value of the excitation power changes in proportion to the engine speed.
Then, the control device 100 functioning as the rotational speed detection means Y uses the relationship between the engine rotational speed and the direction and frequency of the excitation power with respect to the secondary winding of the second power converter 12 to rotate the engine. Calculate the number.
The predetermined engine speed r0 is the engine speed when the rotational frequency f0 of the rotor 2a corresponding to the engine speed is equal to the frequency f1 of the generated power of the power generation system 1. When the frequency f1 of the generated power is 60 [Hz] and the number of magnetic poles of the secondary excitation generator 2 is “6”, the predetermined rotational speed r0 is 1200 [rpm].

When the engine speed is within the low speed range Rl, the state switching means X sets the operating state of the motor generator 15 to the electric state, and the engine speed is higher than the low speed range Rl. When in the region Rh, the operation state of the motor generator 15 is set to the power generation state.
That is, the engine speed is in the low rotation range Rl of 0 [rpm] or more and rl [rpm] or less, and is low to sufficiently rotate the turbine 9b of the supercharger 9 with less energy of the exhaust gas E. When too much, the motor generator 15 connected to the supercharger 9 is put into an electric state. Then, rotational power is applied from the motor generator 15 to the rotating shaft of the supercharger 9 to rotate the supercharger 9 in an appropriate state. As a result, the supercharging pressure is maintained at a high level, and the engine 3 A reduction in efficiency is avoided.
On the other hand, when the engine speed is in the high rotation region Rh that is greater than or equal to rh [rpm] and less than or equal to rmax [rpm], the energy of the exhaust gas E increases and surplus in the rotational power of the supercharger 9 occurs. The motor generator 15 connected to the supercharger 9 is brought into a power generation state. Then, rotational power is recovered from the rotary shaft of the supercharger 9 to the motor generator 15, and as a result, energy loss and the like are avoided, and high power generation efficiency is realized.
The lower limit value and the upper limit value of the low rotation range can be set as appropriate as a range in which the motor generator 15 should be operated in an electric state, while the high rotation level set higher than the low rotation range. The lower limit value and the upper limit value of the region can also be appropriately set as a range in which the motor generator 15 should be operated in the power generation state.

[Other Embodiments]
Finally, other embodiments of the present invention will be described. Note that the configuration of each embodiment described below is not limited to being applied independently, and can be applied in combination with the configuration of other embodiments as long as no contradiction arises.

(1) In the above embodiment, the gas engine 3 is used as a drive source of the power generation system 1. Alternatively, an engine using gasoline, light oil, heavy oil or the like as a fuel may be used as a power source of the power generation system 1. I do not care.

[Reference example]
( 1 ) In the embodiment described above, the rotational speed detection means Y for detecting the rotational speed of the engine is controlled by the control device 100 so that the direction and frequency of the excitation power for the secondary winding 2a of the rotor 2a of the second power converter 12 However, it may be configured such that the rotational speed of the crankshaft of the engine 3 is directly detected by a rotational speed sensor or the like.

The present invention includes a stator having a primary winding connected to an electric power system, and a rotor having a secondary winding, and a secondary excitation generator that rotates the rotor with the rotational power of an engine crankshaft. When,
A first power converter having an AC side connected to the power system;
A second power converter having an AC side connected to the secondary winding;
A direct current unit connecting the direct current side of the first power converter and the direct current side of the second power converter;
The present invention can be suitably used for a power generation system including a control unit that controls operation and a startup operation method thereof.

1: Power generation system 2: Secondary excitation generator 2a: Rotor 2a: Secondary winding 3: Engine 4: Power system 9: Supercharger 11: First power converter 12: Second power converter 13: DC Part 15: Motor generator E: Exhaust gas I: Fresh air X: State switching means Y: Rotational speed detection means

Claims (2)

A secondary excitation generator having a stator with a primary winding connected to the power system and a rotor with a secondary winding, and rotating the rotor with the rotational power of the crankshaft of the engine;
A first power converter having an AC side connected to the power system;
A second power converter having an AC side connected to the secondary winding;
A direct current unit connecting the direct current side of the first power converter and the direct current side of the second power converter;
A power generation system comprising a control means for controlling operation,
A motor-generator capable of transmitting and receiving power to a turbocharger provided in the engine with respect to a rotating shaft of the turbocharger;
The operation state of the motor generator includes an electric state in which electric power is supplied to the motor generator from the DC unit and the motor generator is operated as a motor, and electric power is extracted from the motor generator to the DC unit. State switching means for switching between a power generation state in which the motor generator is operated as a generator ;
A rotational speed detection means for detecting the rotational speed of the crankshaft,
When the rotation speed of the crankshaft is in a low rotation speed range, the state switching means sets the operation state of the motor generator to the electric driving state, and the rotation speed of the crankshaft is higher than the low rotation speed range. When the rotational speed is within the range, the motor generator is in the power generation state.
The power generation system , wherein the rotational speed detection means is configured to calculate the rotational speed of the crankshaft from the direction and frequency of excitation power with respect to the secondary winding of the second power converter . A secondary excitation generator having a stator with a primary winding connected to the power system and a rotor with a secondary winding, and rotating the rotor with the rotational power of the crankshaft of the engine;
A first power converter having an AC side connected to the power system;
A second power converter having an AC side connected to the secondary winding;
A direct current unit connecting the direct current side of the first power converter and the direct current side of the second power converter;
An operation control method for a power generation system comprising a control means for controlling operation,
The turbocharger provided in the engine is provided with a motor generator capable of transmitting and receiving power to the rotating shaft of the turbocharger,
Based on the rotational speed of the crankshaft calculated from the direction and frequency of the excitation power with respect to the secondary winding of the second power converter, the operating state of the motor generator is determined based on the low rotational speed of the crankshaft. When within a few regions, the motor generator is in an electric state in which electric power is supplied from the DC section to operate the motor generator as a motor, and the crankshaft rotational speed is higher than the low rotational speed region. An operation control method for a power generation system in which the electric power is taken out from the motor generator to the DC unit when the rotational speed is within a range, and the motor generator is operated as a generator.

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