JP2950606B2 - Voltage controller for variable speed pumped storage power generation system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial application field) The present invention relates to a variable speed pumped-storage power generation system in which the secondary side of a wound synchronous generator motor is excited by a frequency converter with a variable frequency AC. In particular, when performing a test power transmission operation, the control gain is changed according to the magnitude of the primary voltage of the wound synchronous generator motor, and the output voltage of the frequency converter is controlled so that the gain of the entire voltage control system does not decrease. The present invention relates to a voltage control device for a variable speed pumped storage power generation system.

(Prior art) Since thermal power plants and hydropower plants are easy to control the amount of power generation in response to changes in power demand, they have been spotlighted as power plants for frequency adjustment to control the frequency of the system at a constant level. ing.

However, recently, the number of nuclear power plants has increased, and the number of thermal power plants and hydroelectric power plants that stop at night when power demand is low tends to increase. Therefore, as a method of increasing the nighttime frequency adjustment capacity, the pumping power plant that performs pumping using surplus power at night is made to have a variable speed, and the pumping power is controlled by controlling the rotation speed of the generator motor according to the change in power demand. Adjustable variable speed pumped storage power generation systems are being considered.

By the way, in the case of a pumped-storage power plant, in the event of a wide-area power outage accident for some unexpected reason, so-called trial power transmission operation to supply power within the thermal or nuclear power plant that is to be started for system restoration is implemented. There is this performed. In this test transmission operation, the generator motor of the PSPP is operated in the power generation mode to charge the track to the thermal or nuclear power station, and then power is supplied to the thermal or nuclear power plant's internal load, and the generator is connected to the grid. Until it is paralleled. In this case, it is necessary to maintain the transmission end voltage of the pumped storage power station constant not only during line charging, but also in the process of sequentially applying in-plant loads.

However, as a conventional generator motor of a pumped storage power plant, a synchronous generator motor (hereinafter referred to as a conventional motor) that can be operated only at a constant speed and is excited only by DC is used. And the load connected to the grid. Therefore, the phase of the system voltage is stable when another power supply is connected to the system, but in the case of test transmission operation, for example, when a load is applied to the system or when it is released, the system Because the magnitude and phase of the voltage change,
There is a problem in stabilizing the system.

(Problems to be Solved by the Invention) As described above, when the test power transmission operation is performed by the conventional machine, the phase of the system voltage changes transiently due to a change in the load of the system, the voltage fluctuation increases, and the recovery characteristics are deteriorated. There is a problem of getting worse.

The present invention, in a variable speed pumped storage power generation system equipped with a wound synchronous generator motor, changes the control gain according to the primary voltage of the wound synchronous generator motor so that the gain of the entire voltage control system does not decrease. An object of the present invention is to provide a voltage control device of a variable speed pumped storage power generation system having good voltage control characteristics capable of stably controlling a system voltage and a phase even when a load change or the like occurs.

[Means for Solving the Problems] To achieve the above object, the present invention has a primary side connected to an AC system, a secondary side connected to the AC system via a frequency converter, And a voltage detecting means for detecting a primary voltage of the winding synchronous generator motor and outputting a voltage signal, and a voltage detecting means for detecting a primary voltage of the winding synchronous generator motor driven by the motor. Gain control means for changing the control gain of the voltage control system according to the magnitude of the voltage signal to be supplied; and a voltage signal detected by the voltage detection means and a reference signal of the primary voltage of the winding synchronous generator motor. Voltage control means for comparing and outputting a phase control signal such that the deviation converges with the deviation and the control gain input from the gain adjusting means,
And a phase control means for controlling the output voltage of the frequency converter in accordance with the phase control signal input from the voltage control means so that the gain of the entire voltage control system does not decrease.

(Operation) In the voltage control device of the variable speed pumped storage power generation system having such a configuration, the phase control signal such that the deviation between the voltage signal detected by the voltage detection means and the reference voltage reference signal converges. By changing the control gain of the voltage control system that controls the output voltage of the frequency converter according to the magnitude of the voltage signal, the deterioration of the control characteristics due to the change in the conversion gain of the frequency converter is compensated. In addition to performing voltage control having various control characteristics, it is possible to stabilize the system voltage and phase even when a load change occurs.

(Example) Hereinafter, an example of the present invention will be described with reference to the drawings.

FIG. 1 is a circuit diagram showing a first embodiment of a voltage control device for a variable speed pumped storage power generation system according to the present invention. First
In the drawing, reference numeral 1 denotes a winding synchronous generator motor constituting a variable speed pumped storage power generation system, which is driven by a prime mover such as a water turbine (not shown). The primary winding of the wound synchronous motor 1 is connected to a system 2 which can be approximated by distributed constants of inductance and capacitance, and the secondary winding of the wound synchronous motor 1 is a frequency converter connected to the system 2. 3 to be excited. These constitute a main circuit and are shown by a single crystal.

On the other hand, reference numeral 4 denotes a voltage detector connected to the primary side of the wound synchronous generator motor 1 via an instrumentation transformer PT, and this voltage detector 4 detects the primary voltage of the wound synchronous generator motor 1. ,
The voltage signal is input to the comparator 6 and the gain controller 7
To enter. The comparator 6 compares a voltage signal input from the voltage detector 4 with a voltage reference signal which is a reference of a primary voltage input from the first voltage reference generator 5, and compares the deviation ev with a voltage controller 9. To enter. The gain adjuster 7 changes the control gain of the voltage controller 9 according to the deviation between the second voltage reference signal and the voltage signal detected by the voltage detector 4. The voltage controller 9 receives the deviation ev between the gain from the gain adjuster 7 and the voltage from the comparator 6, and provides a phase control signal obtained by multiplying the deviation by a control gain to the phase controller 10. This phase controller 10 controls the amplitude and phase of the output voltage of the frequency converter 3 according to the phase control signal.

 Next, the operation of the voltage control device having such a configuration will be described.

Now, when the primary voltage of the wound synchronous generator motor 1 is detected by the voltage detector 4 and the voltage signal is input to the comparator 6, the comparator 6 inputs the voltage signal from the first voltage reference generator 5. The deviation ev is input to the voltage controller 9 as compared with the voltage reference signal. When the voltage signal detected by the voltage detector 4 is input to the gain adjuster 7, the gain adjuster 7 outputs the voltage signal and the second voltage reference signal input from the second voltage reference generator 8. , The control gain of the voltage controller 9 is changed. That is, if the voltage signal is lower than the second voltage reference signal, the conversion gain of the frequency converter (the ratio between the input signal of the phase controller that operates the frequency converter and the output voltage of the frequency converter) decreases. , The control gain is increased, and vice versa. In this case, the voltage reference values set by the first reference voltage generator 5 and the second reference voltage generator 8 are not necessarily the same.

A control gain from the gain controller 7 to the voltage controller 9;
When a voltage deviation from the comparator 6 is input, the voltage controller 9 supplies a phase control signal obtained by multiplying the deviation by a control gain to the phase controller 10.

Here, given the general proportional integrator as a voltage regulator 9, there is a proportional gain K _P and the integral gain K _I as a control gain. The phase control signal y calculated from the voltage deviation ev and the control gains K _P and K _I is y = (K _P + K _I / s) × ev. Here, s is a Laplace operator. With this K _P
K _I is input from the gain controller 7. These become larger as the voltage signal becomes larger, and become smaller as the voltage signal becomes smaller.

The phase controller 10 controls the amplitude and phase of the output voltage of the frequency converter 3 according to the phase control signal. If the minor loop has a current control system for controlling the output current of the frequency converter, the current of the frequency converter 3 is detected by a current detector (not shown), and the current signal and the input from the voltage controller 9 are input. A current controller (not shown) that controls the phase control signal based on the current as a current reference may be provided, and the frequency converter 3 may be controlled by the phase controller based on the output signal.

FIGS. 2 and 3 show the case where the control gain is fixed and the case where the control gain is made variable according to the first embodiment of the present invention. 13 shows the result of the simulation. Each figure shows the waveforms of the voltage reference signal and the effective value voltage signal. In FIGS. 2 and 3 Figure, T ₁ is the time which supplied an inductive load to the system, the voltage is indicated by a unit normal. Also,
Voltage before load application, a minimum voltage after load application, each V _init the voltage after 300msec from load application, V _min, and V _300.

When the control gain is fixed, as shown in FIG.
When the load by T ₁ time is turned on, 70% of the voltage before load application
The voltage drops to about 85% after 300 msec.

On the contrary, when the control gain as in the first embodiment is variable, the load by T ₁ time as shown in Figure 3 is turned, the gain to increase the control gain and the voltage drops Is adjusted, the voltage at the time of loading is reduced to 78% of the voltage before loading, and is restored to about 95% after 300 msec.

As described above, the control gain is set to 1 of the winding type synchronous generator motor 1.
By changing the primary voltage in accordance with the magnitude of the secondary voltage, the transient change amount of the primary voltage can be reduced.

FIG. 4 is a circuit diagram showing a second embodiment of the present invention.
The same parts as those in the drawings are denoted by the same reference numerals and description thereof will be omitted.

In the second embodiment, as shown in FIG. 4, a voltage deviation signal from the comparator 6 is input to a gain adjuster 7, and the control gain of the voltage controller 9 is varied according to the value of the deviation signal. It is something to do.

With such a configuration, the voltage reference generator 8 shown in FIG. 1 can be omitted, and in particular, the values of the respective voltage reference signals output from the first and second reference voltage generators in FIG. 1 are made equal. Control characteristics similar to those at the time are obtained.

FIG. 5 is a circuit diagram showing a third embodiment of the present invention.
The same parts as those in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted.

In the third embodiment, and inputs the deviation signal voltage from the comparator 6 to the gain adjuster 7 as shown in FIG. 5, determine the gain K _X that changes according to the deviation. For example K _X is _{K X = 1 + K θ ×} ev. Here, ev is the deviation of the voltage, the K _theta is an arbitrary gain.

Further, the voltage controller 9 consists of a multiplier 92 for multiplying the PI controller 91 and the gain K _X for calculating from the deviation of the control gain and a fixed voltage. The phase of the frequency converter is controlled by the phase controller 10 based on the output of the multiplier 92.

With such a configuration, the proportional integral gains K _P and K _I are fixed. For example, when the voltage is stabilized after another power supply is applied to the system, the normal control gain is set by setting K _θ to zero. Operation can be returned to.

[Effects of the Invention] As described above, according to the present invention, in a variable speed pumped storage power generation system including a wound synchronous generator motor, the primary voltage of the wound synchronous generator motor is detected, and the magnitude of this voltage is determined. The output voltage of the frequency converter is controlled so that the gain of the entire voltage control system does not change.For example, when the terminal voltage of the It is possible to provide a voltage control device for a variable-speed pumped-storage power generation system capable of performing voltage control with good control characteristics by compensating for the conversion gain of the frequency converter not to decrease even when the primary voltage of the synchronous generator motor decreases. .

[Brief description of the drawings]

FIG. 1 is a circuit diagram showing a first embodiment of a voltage control device for a variable speed pumped storage power generation system according to the present invention. FIG. 2 is a response waveform diagram of a voltage when a load is applied when a control gain is fixed. FIG. 3 is a response waveform diagram of a voltage when a load is applied at the time of voltage control according to the first embodiment. FIGS. 4 and 5 are circuit diagrams showing second and third embodiments of the present invention, respectively. . DESCRIPTION OF SYMBOLS 1 ... Winding synchronous generator motor, 2 ... System, 3 ... Frequency converter, 4 ... Voltage detector, 5 ... First voltage reference generator, 6 ... Comparator, 7 ... Gain adjustment Vessel, 8 ... second
Voltage reference generator, 9 ... voltage controller, 91 ... PI controller, 92 ... multiplier, 10 ... phase controller.

──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Hirokazu Kaneko 1-3-1 Uchisaiwai-cho, Chiyoda-ku, Tokyo Inside Tokyo Electric Power Company (72) Inventor Masaru Hirano 1-Toshiba-cho, Fuchu-shi, Tokyo Inside the factory (56) References JP-A-62-239900 (JP, A) JP-A-60-144162 (JP, A) (58) Fields investigated (Int. Cl. ⁶ , DB name) H02P 9/00- 9/48

Claims (1)

(57) [Claims] 1. A variable speed pumped-storage power generation system comprising a winding type synchronous generator motor, a primary side connected to an AC system, a secondary side connected to the AC system via a frequency converter, and driven by a prime mover. Voltage detecting means for detecting a primary voltage of the winding synchronous generator motor and outputting a voltage signal; gain adjusting means for changing a control gain according to the magnitude of the voltage signal input from the voltage detecting means; A voltage signal detected by the voltage detecting means is compared with a reference signal of a primary voltage of the winding synchronous generator motor, and a phase is set such that the deviation converges with the control gain input from the gain adjusting means. A voltage control means for outputting a control signal; and an output voltage of the frequency converter, the gain of the entire voltage control system being low in response to a phase control signal input from the voltage control means. A voltage control device for a variable-speed pumped-storage power generation system, comprising: