KR101253750B1 - An apparatus controlling extraction steam of a top heater to improve speed regulation rate of power plant - Google Patents

Abstract

The bleeding flow control device for improving the power plant speed adjustment rate according to the present invention is located between the high pressure turbine and the high pressure tower heater, the flow rate control valve for adjusting the flow rate of water vapor supplied from the high pressure turbine to the high pressure tower heater; And a valve control unit for controlling valve opening and closing of the flow regulating valve, in response to a fluctuation value of the frequency error signal of the power grid and the possibility of frequency following operation of the power plant.

Description

An apparatus controlling extraction steam of a top heater to improve speed regulation rate of power plant}

The present invention relates to a power plant control device including a multi-stage bleed heater device for improving thermal efficiency, such as a nuclear power plant and a thermal power plant. More specifically, a power grid connected to a generator by improving a speed regulation rate of the power plant The present invention relates to a technology that effectively contributes to the stability of the frequency and achieves a reduction in the cost of constructing and maintaining a peak load power plant through a low speed adjustment rate.

In general, the speed adjustment rate of a power plant expressed as a rate of change when the turbine output is reduced from full load (100 [%] Load) to 3 [%] for internal combustion power and hydro power plants, and 4 to 4 for thermal power plants 6 [%] of nuclear power plants and 8 [%] of nuclear power plants. The low speed adjustment rate means that the output change rate of the load according to the frequency change of the grid is large, and the high speed adjustment rate means that the load change rate of the load according to the frequency change is small. Indicates that it has load adjustment capability.

1 is a configuration of a power plant equipped with a conventional multi-stage scavenging heater (Heater) system. The speed regulation rate of a power plant performing grid frequency following operation is higher than the frequency droop value set in the turbine control system. In particular, the speed adjustment of the power plant in response to the frequency increase is not a big problem due to the throttling operation of the Governor. do. This is because the boiler output increase request signal due to the frequency error is shown as the final steam increase because of the dynamic characteristics of the boiler with a significant delay time. In terms of individual power plants, the high speed regulation rate contributes to the system frequency stability, which results in lower subsidies for power generation compared to the low speed regulation rate plant, and low speed regulation rate in terms of the total power system to which each power plant is linked. There is a problem of additionally constructing and operating a peak load power plant with a separate power generation unit having a high cost.

The present invention is installed in the power plant including a multi-stage bleed heater device for improving the thermal efficiency, such as nuclear power plants and thermal power plants installed flow control valve for adjusting the flow rate in the bleed pipe coming into the top heater (Top Heater), the system frequency Therefore, by additionally configuring a control circuit that automatically adjusts the flow control valve to the control equipment, when the system frequency decreases, the flow control valve is throttled to increase the steam flow rate to the turbine very rapidly, thereby reducing the generator output without reducing the main steam pressure. Provides a way to increase the rate of regulation of the power plant by increasing the momentarily.

In order to solve the above problems, the bleeding flow rate control device for improving the power plant speed adjustment rate according to the present invention is located between the high-pressure turbine and the high-pressure tower heater, the flow rate of the water vapor supplied from the high-pressure turbine to the high-pressure tower heater Flow control valve for; And a valve control unit for controlling opening and closing of the valve of the flow regulating valve, in response to a fluctuation value of the frequency error signal of the power grid.

Preferably, the valve control unit, PID control module for outputting a control signal corresponding to the change value of the frequency error signal; An output determination module for determining whether to output the control signal to the PID control module according to whether the frequency following operation for the power plant is normal; And a gain adjustment module for controlling opening and closing of the valve of the flow regulating valve by adjusting a gain value of the control signal.

Preferably, the output determination module is configured to output the control signal when the frequency following operation of the power plant is possible, and limits the output of the control signal when the frequency following operation is not possible.

Preferably, the gain adjustment module, characterized in that for adjusting the gain value of the control signal in accordance with the change in the output value of the power plant.

Preferably, the valve control unit, characterized in that it further comprises a lower limit value setting module for setting the lower limit value for the closing position of the flow control valve.

Preferably, the lower limit value setting module, characterized in that for setting the closing position lower limit value of the flow control valve to any one of automatic and manual.

According to the present invention, the rate adjustment rate of the power plant can be kept relatively low, which contributes significantly to the stability of the power system frequency. In addition, it is possible to increase profits by additionally acquiring an auxiliary service fee due to a decrease in speed rate in an individual power plant.

In addition, it is possible to operate a coal-fired or nuclear power plant operated at a lower fuel cost for peak load control instead of operating a high fuel cost internal power and a hydro power plant, thereby reducing the fuel cost and maintenance cost of the power plant.

1 is an example of a configuration of a power plant equipped with a conventional multi-stage shunt heater system.
2 is an example of a configuration of a power plant equipped with a bleeding flow rate control device for improving the speed regulation rate of the power plant according to the present invention.
FIG. 3 is a block diagram illustrating detailed components of the valve control unit illustrated in FIG. 2.
4 is a graph illustrating a gain value according to a change in power plant output value.

Hereinafter, a bleeding flow rate control apparatus for improving the power plant speed regulation rate according to the present invention will be described with reference to the accompanying drawings.

Figure 2 is an example of a power plant configuration with a bleeding flow rate control device for improving the speed regulation rate of the power plant according to the present invention, the valve control unit 100 and the flow control valve 102 as the main components of the bleeding flow rate control device It is provided.

As shown in FIG. 2, the apparatus for improving the speed adjustment rate is additionally provided in the multi-stage scavenging heater system, which is different from the conventional configuration, the scavenging pipe that enters the top heater from the multistage scavenging heater. In the flow rate control valve 102 for adjusting the flow rate is installed. In addition, according to the system frequency, the flow control valve 102 additionally configures the valve control unit 100 for opening and closing positioning in a unit load demand circuit (ULD: Unit Load Demand Controller) to reduce the flow rate control valve when the system frequency decreases. Throttling (102) allows the steam flow to the turbine to be increased very rapidly, allowing the generator output to be instantaneously increased without reducing the main steam pressure.

The flow control valve 102 is positioned between the high pressure turbine 104 and the high pressure tower heater 106, and controls the flow rate of water vapor supplied from the high pressure turbine 104 to the high pressure tower heater 106.

The valve controller 100 controls opening and closing of the valve of the flow regulating valve 102 in response to the variation value of the frequency error signal. The frequency error signal corresponds to an error signal according to a degree outside the frequency set value of the power grid (for example, a signal of 60 [Hz]). The valve controller 100 controls the opening and closing of the flow regulating valve 102 in response to the variation value of the frequency error signal input through the input terminal IN1.

FIG. 3 is a block diagram showing the detailed components of the valve control unit 100 shown in FIG. 2 and includes a PID control module 200, an output determination module 202, and a gain adjustment module 204.

When the PID control module 200 receives the change value of the frequency error signal through the input terminal IN1, the PID control module 200 outputs a control signal corresponding to the change value to the output determination module 202.

The frequency error signal is provided as a variable of the valve control unit 100 for improving the speed regulation rate, apart from being provided as a load change signal in a conventional power plant load control circuit. For this frequency error signal, the calculated value of the PID control module 200 for removing the frequency error value when the generator is below the maximum output and the frequency following operation mode is on is the valve of the flow control valve 102. It is output as a control signal for opening and closing.

The output determination module 202 determines whether to output the control signal provided from the PID control module 200 according to whether the frequency following operation for the power plant is normal, and if the output of the control signal is determined, adjusts the gain of the control signal. Output to module 204. However, if a decision is made to limit the output of the control signal, the control signal is not output.

In particular, the output determination module 202 outputs the control signal when the frequency following operation is possible, and limits the output of the control signal when the frequency following operation is not possible. The output determination module 202 determines that the output value of the PID control module 200 is output 100 [%] in the load section in which the frequency following operation is smooth, but the section in which frequency tracking is impossible (for example, below or below the frequency minimum load or maximum) is determined. In the load error), the bias value becomes "0" to limit the output value of the PID control module 200. Frequency following Minimum Load is the minimum load that can be operated by frequency following operation and is already set as constant value in all power plants. Maximum Load means the maximum load that a generator can produce regardless of frequency following operation.

The gain adjustment module 204 adjusts the gain value of the control signal with respect to the control signal provided from the output determination module 202, and outputs the control signal whose gain value is adjusted to the flow rate control valve 102. In particular, the gain adjustment module 204 adjusts the gain value of the control signal in accordance with the change of the output value of the power plant.

The lower limit value setting module 206 sets a lower limit value for the closing position of the flow control valve 102. Therefore, the signal limiting the closing degree of the flow control valve 102 set by the lower limit value setting module 206 is outputted to the flow control valve 102 through the output terminal OUT1, thereby limiting the closing degree of the flow control valve 102. can do. The lower limit value setting module 206 allows setting the limit value of the closing position to either one of automatic and manual. The lower limit value setting module 206 limits the closing degree of the flow control valve 102, thereby preventing a sudden change in the water supply temperature and minimizing a decrease in power plant efficiency.

4 is a graph illustrating a gain value according to a change in power plant output value. As shown in FIG. 4, the gain adjusting module 204 calculates a gain value Y = F (x) for adjusting an output value between a minimum load and a maximum load capable of frequency following operation. The control signal corresponding to the calculated gain is output. In the load section where the following operation between the minimum load and the maximum load for the frequency following is smooth, the gain adjusting module 204 can adjust the sensitivity of the flow control valve according to the output value of the power plant. By adjusting the gain value, a sudden change in the output is prevented at the boundary between the frequency followable operation and the impossible operation section.

In response to the control signal of the valve control unit 100, the flow control valve 102 performs a valve opening and closing operation. On the other hand, the flow rate control valve 102 can be configured so that no additional pressure loss occurs by installing in place of the conventional bleed-off valve installed in the bleed stage.

On the other hand, apart from the bleeding flow control device for improving the speed regulation rate of the power plant, the power plant load control circuit increases the boiler output according to the frequency error (error due to the frequency drop) through a control algorithm that is already implemented. Produce a flow rate At the time when the increased steam flow rate affects the output of the turbine generator (the frequency improvement is completed), the flow control valve is automatically returned to 100 [%] open state. In addition, even if the opening frequency is not improved, if the boiler load rises above the Maximum Load, the flow control valve returns to 100 [%] Open. The decrease in feed water temperature due to the reduction of heater bleeding is automatically compensated by the fuel control circuit of the boiler, so a separate circuit is not necessary. On the other hand, the flow control valve can be configured so that additional pressure loss does not occur by installing in place of the bleed-off valve installed in the conventional bleed stage.

The bleeding flow rate control device for improving the rate adjustment rate of the power plant of the present invention has been described with reference to the embodiment shown in the drawings for clarity, but this is merely illustrative, and those skilled in the art have various modifications therefrom. And other equivalent embodiments are possible. Accordingly, the true scope of the present invention should be determined by the appended claims.

100: valve control unit
102: flow control valve
200: PID control module
202: output determination module
204: gain adjustment module
206: lower limit value setting module

Claims (6)

Located between the high pressure turbine and the high pressure tower heater, a flow control valve for controlling the flow rate of water vapor supplied from the high pressure turbine to the high pressure tower heater; And
And a valve controller for controlling the opening and closing of the flow regulating valve, in response to the fluctuation value of the frequency error signal of the power grid and the possibility of frequency following operation of the power plant.
The valve control unit,
A PID control module for outputting a control signal in response to a change value of the frequency error signal;
An output determination module for determining whether to output the control signal to the PID control module according to whether the frequency following operation for the power plant is normal; And
And a gain adjustment module for controlling valve opening and closing of the flow control valve by adjusting a gain value of the control signal. delete The method of claim 1, wherein the output determination module
The output flow control device for improving the power plant speed adjustment rate, characterized in that to output the control signal when the frequency following operation of the power plant is possible, and limiting the output of the control signal when the frequency following operation is impossible. The method of claim 1, wherein the gain adjustment module
The additional flow rate control device for improving the speed regulation rate of the power plant, characterized in that for adjusting the gain value of the control signal in accordance with the change in the output value of the power plant. The method of claim 1, wherein the valve control unit
The additional flow control device for improving the power plant speed adjustment rate, characterized in that it further comprises a lower limit value setting module for setting a lower limit value for the closed position of the flow control valve. The method of claim 5, wherein the lower limit value setting module
The additional flow control device for improving the power plant speed adjustment rate, characterized in that for setting the closing position lower limit value of the flow control valve to any one of automatic and manual.

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