JPH0250362B2 - - Google Patents

Description

TECHNICAL FIELD OF THE INVENTION The present invention relates to a water level control device for a deaerator in a thermal power plant, and more particularly to a low pressure clean-up deaerator water level control device during deaerator clean-up.

Technical background of the invention and its problems When starting up a thermal power plant, the deaerator is cleaned in order to improve the water quality of the water supply system. The system that performs this cleaning is called the clean-up system. Incidentally, a deaerator is used to remove gas contained in the water supply, and usually, the gas in the water supply is separated and extracted by heating with bleed air. Therefore, the water level in the deaerator is controlled to be kept constant, and a deaerator water level control device is used to control this.

FIG. 1 is a block diagram of the deaerator water level control device 11. This deaerator water level control device 11 is
The adder 12 obtains the deviation so that the deaerator water level a becomes the preset normal deaerator water level a ₀ , and the deaerator consists of a deaerator water level regulator control gain 13, an integral gain 14, and a differential gain 15. Air water level deviation
It performs PID calculation and outputs the drive signal b to the deaerator water level control valve. Depending on the opening degree of the deaerator water level control valve, the deaerator inlet condensate flow rate Q ₁ flows into the deaerator. Here, block 16 is the time constant of the deaerator water level control valve. Deaerator inlet condensate flow rate Q ₁ and low pressure cleanup flow rate Q ₂ flowing into the deaerator
The integral of the deviation from this becomes the deaerator water level a. That is, a=∫(Q ₁ −Q ₂ )dt. Here, block 17 is the time constant of the deaerator water level.

When there is no low pressure cleanup flow rate _Q2 , that is, before the start of low pressure cleanup, the deaerator water level control device 11 is in the following state.

If the deaerator water level a is below the normal water level _a0 , open the deaerator water level control valve and let water flow into the deaerator so that the deaerator water level a becomes the normal water level _a0 . Increase the deaerator water level a. When the deaerator water level a reaches the normal water level _a0 , an opening/closing command is output from the deaerator water level control device 11 to the deaerator water level control valve. However, normally, when the deaerator water level control valve is closed, it is rare that a=a ₀ , but a>a ₀ . Further, since water does not flow out from the deaerator, the deaerator water level a does not drop even if the deaerator water level control valve is closed. Therefore, the deaerator water level deviation resulting from the deaerator water level height is integrated by the integrator 14 until the integrator is saturated.

When the deaerator water level a is higher than the normal water level _a0 , the deaerator water level control device 11 outputs an opening/closing command to the deaerator water level control valve, but since water does not flow out from the deaerator,
The deaerator water level does not drop even when the deaerator water level control valve is fully closed. Therefore, the deaerator water level deviation resulting from the deaerator water level height is integrated by the integrator 14 until the integrator is saturated.

If the deaerator water level matches the normal water level, the integrator 14 will not become saturated. However, when water flows into the deaerator due to a flow rate leak from the deaerator water level control valve, the deaerator water level becomes high, so the deaerator water level deviation caused by the high water level is corrected by the integrator 14. It is integrated until it reaches saturation.

As described above, at the start of low pressure cleanup, the deaerator water level control device 11 often integrates a positive deviation until the integrator is saturated.

Figure 2 shows the fluctuation characteristics of the deaerator water level and condensate flow rate at the deaerator inlet at the start of low-pressure cleanup.
In order to make the explanation easier to understand, the figure is shown ignoring the differential operation that does not affect the present invention.
Assume that the low-pressure clean-up valve begins to open at time _t1 . The opening degree curve is shown by the low pressure cleanup valve opening degree S1. When the low-pressure clean-up valve is opened, water flows out of the deaerator, so the deaerator water level a begins to drop. At time _t2 , the deaerator water level a reaches the deaerator normal water level _a0 ,
When the water level deviation is about to change from high to low, the deviation signal C12 switches from positive to negative. However, when the integrator 14 is saturated, the integral signal C13 is positive, so the drive signal for the deaerator water level control valve remains in the closing direction, and the deaerator water level control valve does not open. Therefore, water only flows out to the deaerator through low-pressure clean-up flow, and there is no flow into the deaerator.
The deaerator water level a continues to fall. At time _t3 , when the absolute value of the deviation signal C12 and the integral signal C13 match, the deaerator water level control valve starts to open. The condensate flow rate _Q1 begins to be supplied to the deaerator, but since it is lower than the low pressure cleanup flow rate _Q2 , the deaerator water level continues to drop. At time _t4 , when the condensate flow rate _Q1 flowing into the deaerator and the low pressure cleanup flow rate _Q2 flowing out match,
The deaerator water level a begins to rise. At time _t5 , the deaerator water level a tries to switch from low to high, and the deviation signal C12 switches from negative to positive, but the integral signal C1
3 is negative, the deaerator water level control valve drive signal b remains in the open direction, and the deaerator inlet condensate flow rate _Q1 continues to increase. In addition, since the deaerator inlet condensate flow rate _Q1 has already increased beyond the low pressure cleanup flow rate _Q2 after time _t4 , the deaerator water level a
becomes increasingly higher. At time _t6 , when the absolute value of the integral signal C13 matches the deviation signal C12,
The deaerator water level control valve switches from open to closed. In this case, since the deaerator inlet condensate flow rate Q ₁ is higher than the low pressure cleanup flow rate Q ₂ , the deaerator water level a continues to increase. At time _t7 , when the deaerator inlet condensate flow rate _Q1 matches the low pressure cleanup flow rate _Q2 , the deaerator water level a switches from increasing to decreasing.

As described above, when opening the low-pressure clean-up valve during low-pressure clean-up, the integrated deviation of the integrator 14 of the deaerator water level control device 11 changes the deaerator water level a and the deaerator inlet condensate. Flow rate Q ₁
varies. That is, the maximum value of the fluctuation range of the deaerator water level and the maximum value of the fluctuation range of the deaerator inlet condensate flow rate are proportional to the initial setting opening degree of the low pressure clean-up valve. Therefore, if the initial opening degree of the low-pressure clean-up valve is set to the low-pressure clean-up flow rate opening degree as in the prior art, the deaerator water level and the deaerator inlet condensate flow rate vary greatly. Further, if the deaerator inlet condensate flow rate _Q1 fluctuates greatly, the condensate pump may become overloaded and trip, and even if it does not trip, it will give a shock to the condensate pump. On the other hand, when the deaerator water level a decreases, the deaerator internal pressure decreases and a large amount of auxiliary steam to be supplied to the deaerator is sucked in, so that a large amount of auxiliary steam is used. Therefore, it is desirable that the deaerator water level and the condensate flow rate at the deaerator inlet are always stable.

OBJECT OF THE INVENTION An object of the present invention is to provide low-pressure clean-up deaerator water level control that can suppress deaerator water level fluctuations caused by saturation of the integrator of the deaerator water level control device at the start of deaerator clean-up. It's about getting the equipment.

Summary of the Invention The present invention provides an input means for inputting a deaerator water level signal and a low pressure cleanup valve opening signal used to control the deaerator water level in a power generation plant, and a low pressure cleanup valve opening signal from the input means for inputting the deaerator water level signal and the low pressure cleanup valve opening signal. an initial opening setting means for outputting a low-pressure clean-up valve drive signal so that the opening is the initial opening; and a low-pressure clean-up valve driving signal so that the low-pressure clean-up valve opening from the input means becomes the low-pressure clean-up flow rate opening. A clean-up flow rate opening setting means (hereinafter referred to as the opening setting means) outputs a signal, and an initial opening setting means and a flow rate are set based on the deaerator water level signal and low-pressure clean-up opening signal from the input means. A setting control switching means for outputting a low pressure clean-up valve drive signal from the opening setting means, and an output means for outputting a low pressure clean-up valve drive signal from the setting control switching means to the low pressure clean-up valve driving device. Features.

Embodiment of the Invention Hereinafter, an embodiment of the low pressure cleanup deaerator water level control device of the present invention will be described. FIG. 3 is an overall system configuration diagram in which the low pressure cleanup deaerator water level control device 18 of the present invention is applied to a deaerator cleanup system.

The cleanup system of the deaerator 19 is as follows. That is, water is sent from the condenser 20 by a condensate pump 21 to a condensate desalination device 22, where various ions contained in the water are removed. and,
Deaerator water level control valve 2 with condensate booster pump 23
4 and a low-pressure heater 25, the water is sent to a deaerator 19, where gases in the water are separated and extracted. The water from the deaerator 19 is returned to the condenser 20 through the low-pressure clean-up valve 26, and the water quality is improved by repeating the above cycle. The low-pressure clean-up blow valve 27 is a valve for draining water out of the cycle when the water is highly contaminated. Also, the signal S1 is the low pressure clean-up valve 2.
6, the signal S2 is a drive signal for the low-pressure clean-up valve 26, the signal S3 is a drive signal for the low-pressure clean-up blow valve 27, and the signal S4 is an opening signal for the low-pressure clean-up blow valve 27.

Next, an embodiment of the low pressure cleanup deaerator water level control device 18 of the present invention is shown in FIG. This embodiment is for controlling the low pressure clean-up valve 26. Therefore, the signal input to the low pressure cleanup deaerator water level control device 18 is:
This is for the case of the deaerator water level signal a and the low pressure clean-up valve opening signal S1.

The low pressure clean-up valve opening signal S1 is input to the initial opening setting means 29, the flow rate opening setting means 30, and the setting control switching means 31 via the input means 28. The initial opening degree setting means 29 is configured so that the opening degree signal S1 of the low pressure clean-up valve 26 is the initial opening degree setting command S.
The drive signal S2A of the low pressure clean-up valve 26 is outputted so that the current is 1A. On the other hand, the flow rate opening setting means 30 includes the low pressure clean-up valve 26
The drive signal S2 of the low pressure clean-up valve 26 is set so that the opening signal S1 becomes the flow rate opening setting command S1B.
This outputs B.

Further, the setting control switching means 31 selects either one of the drive signal S2A from the initial opening degree setting means 29 and the drive signal S2B from the flow rate opening degree setting means 30, and sends a drive signal to the low pressure clean-up valve 26. This is output as S2. This setting control switching means 31 is constructed as shown in FIG.
That is, based on the deaerator water level signal a obtained from the input means 28, the deaerator water level change rate α is calculated.
The condition that the deaerator water level change rate α is less than the specified value α ₀ and the low pressure cleanup valve opening S1 is the initial opening S1
The AND circuit 33 is configured based on the condition that A is greater than or equal to A.
The output of the AND circuit 33 is input to a timer circuit 34, and an output signal is output after a certain time limit T. When the output of the timer circuit 33 is established, the flow rate opening setting means 3
The drive signal S2B starts from 0. On the other hand, the output of the timer circuit 33 is input to the NOT circuit 35, and when the output of the NOT circuit 35 is established, the initial opening degree setting means 2
9 becomes the drive signal S2A. 36, 37 are
The AND circuit and 38 are an OR circuit.

Let us now begin the low pressure cleanup. In this case, since the low pressure clean-up valve 26 is fully closed, water does not flow out from the deaerator 19.
Further, as described above, the deaerator water level a is higher than the normal water level, and the deaerator water level control valve 24 is fully closed. It is assumed that the integrator 14 of the deaerator water level control device 11 integrates the positive deviation until it reaches saturation.

Assume that low pressure cleanup is started at time _t1 as shown in FIG. Then, the deaerator water level a
and the low pressure clean-up valve opening signal S1 are input to the input means 28. The deaerator water level a and the low pressure cleanup opening signal S1 are transmitted from the input means 28 to the setting control switching means 31, and since the low pressure cleanup valve 26 is fully closed, the low pressure cleanup flow rate opening setting condition is not satisfied. becomes. Therefore, the low-pressure clean-up valve initial opening setting condition is established. Therefore, the low pressure clean-up valve drive signal S2A of the initial opening degree setting means 29 is set to the setting control switching means 3.
1 to the output means 32, and this signal drives the low pressure clean-up valve 26. Further, in this case, the low pressure clean-up valve drive signal S2B of the flow rate opening degree setting means 31 is cut off by the setting control switching means 31.

Next, in Fig. 6, the low pressure clean-up valve 2
6 shows the fluctuations in the deaerator water level a and the deaerator inlet condensate flow rate _Q1 when the initial opening degree S1A is set.
Curve a is the deaerator water level curve, S1 is the low pressure cleanup valve opening curve, and C13 is the deaerator water level control device 1.
1 integral signal, C12 is the deaerator water level a and the reference water level
The deviation signal from a ₀ , Q ₁ is the curve of condensate flow rate at the condenser inlet. These characteristics are changed by the initial opening setting of the low pressure cleanup valve. Since the initial setting opening degree S1A is lower than the flow rate opening degree S1B, fluctuations in the deaerator water level a and the deaerator inlet condensate flow rate _Q1 are reduced.

The deaerator water level control device 11 suppresses the deaerator water level control valve 24 and operates to bring the deaerator water level a to the normal water level _a0 , so that the deaerator water level change rate α is within the specified value _α0 . Thus, after the specified time T has elapsed, the low pressure cleanup flow rate opening setting condition of the setting control switching means 31 is satisfied. Therefore, the low pressure clean-up valve drive signal S2 of the flow rate opening degree setting means 30
B is transmitted by the setting control switching means 31 to the output means 32, and the low pressure clean-up valve 26 is driven by this signal. In this case, the initial opening setting means 29
The low pressure clean-up valve drive signal S2A is cut off by the setting control switching means 31.

Here, the conditions are satisfied that the deaerator water level change rate α of the AND circuit ₃₃ in FIG. This means that the initial opening degree setting of the low-pressure clean-up valve is completed, the deaerator water level a becomes stable, and the integral value of the integrator of the deaerator water level control device 11 almost disappears. When the deaerator water level a switches from an increasing (decreasing) direction to a decreasing (increasing) direction, the deaerator water level change rate α temporarily decreases, so the timer circuit 34 ensures that the deaerator water level a is This is to confirm that it is stable.

The control gain K _1C of the initial opening degree setting means 29 is set in accordance with the time constant of the low pressure clean up valve 26, and is adjusted in advance so as to quickly set the low pressure clean up valve 26 to the initial opening degree. Furthermore, the control gain _K2C of the flow rate opening setting means 30 is adjusted to match the low pressure clean-up valve time constant, and at the same time,
In accordance with the followability of deaerator water level control to fluctuations in the low-pressure cleanup flow rate _Q2 flowing out from the deaerator of the deaerator water level control device 11, fluctuations in the deaerator water level and deaerator condensate flow rate are controlled. It is adjusted in advance so that the fluctuation is within a specified value.

In the above embodiment, the deaerator outlet flow rate is set to the condenser 20.
This is an application example of low-pressure clean-up recirculation, which controls the low-pressure clean-up valve 26. Setting control of the valve 27 can be performed in the same manner. In this case, the opening signal S4 of the low pressure clean up blow valve 27 is inputted. A low pressure clean up blow valve drive signal S3 is outputted from the low pressure clean up deaerator water level control device 18 to the low pressure clean up blow valve 27. Similarly to the low pressure cleanup recirculation described above, at the start of the low pressure cleanup blow, the low pressure cleanup blow valve is initially set according to the present invention to stabilize the deaeration water level and increase the integral of the deaerator water level control device 11. When the integral value of the device decreases, the low pressure clean-up blow valve 2
7 is set as the blow flow rate opening. In this way, the deaerator water level and the deaerator inlet condensate flow rate are stabilized at the start of low-pressure clean-up blowing.

Effects of the Invention As described above, the present invention initializes low pressure cleanup at the start of low pressure cleanup, and when the integral value of the integrator of the deaerator water level control device decreases and the deaerator water level becomes stable. By setting the low-pressure clean-up valve to the clean-up flow rate opening, the deaerator water level can be stabilized, and the deaerator condensate flow rate can be stabilized.

[Brief explanation of drawings]

Figure 1 is a block diagram of the deaerator water level control device, Figure 2 is a characteristic diagram of the deaerator water level in a conventional example, and Figure 3 is a diagram of the deaerator water level control device.
The figure is an overall configuration diagram to which the control device of the present invention is applied, FIG. 4 is a block diagram showing one embodiment of the present invention, and FIG.
The figure is an explanatory diagram of the setting control switching means, and FIG. 6 is a characteristic diagram of the deaerator water level in the present invention. 11... Deaerator water level control device, 18... Low pressure clean up deaerator water level control device, 26... Low pressure clean up valve, 28... Input means, 29...
Initial opening setting means, 30...Flow rate opening setting means,
31... Setting control switching means, 32... Output means.

Claims (1)

[Scope of Claims] 1. The flow rate of water supplied from the condensate booster pump to the deaerator is controlled by opening and closing a deaerator water level control valve so that the water level signal of the deaerator becomes a normal water level. The water circulating from the container to the condenser is controlled by a low-pressure clean-up valve,
an input means for inputting a deaerator water level signal and a low pressure clean-up valve opening signal used to control the deaerator water level; initial opening setting means for outputting a clean-up valve drive signal;
Clean-up flow rate opening setting means for outputting a low-pressure clean-up valve drive signal such that the low-pressure clean-up valve opening from the input means becomes the low-pressure clean-up flow rate opening; and a deaerator water level signal from the input means. If the conditions that the change rate of setting control switching means for selecting the opening degree setting means, and selecting the flow opening degree setting means and outputting a low pressure cleanup valve drive signal when the conditions are met and a prescribed time has elapsed; A low-pressure clean-up deaerator water level control device comprising output means for outputting a low-pressure clean-up valve drive signal from the means to a low-pressure clean-up valve drive device. 2. Control the flow rate of water supplied from the condensate booster pump to the deaerator by opening and closing the deaerator water level control valve so that the water level signal of the deaerator becomes the normal water level, and the deaerator clean-up from the deaerator is controlled. In a system where water blown out of the system is controlled by a low-pressure clean up blow valve, input for inputting the deaerator water level signal and low pressure clean up blow valve opening signal used to control the deaerator water level. means, initial opening degree setting means for outputting a low pressure clean up blow valve drive signal such that the low pressure clean up blow valve opening degree from the input means becomes an initial opening degree; and a low pressure clean up blow valve from the input means. a clean-up flow rate opening setting means for outputting a low-pressure clean-up blow valve drive signal so that the opening becomes a low-pressure clean-up flow rate opening, and a rate of change of the deaerator water level signal from the input means is below a specified value. If the condition that the low pressure clean up blow valve opening signal is equal to or greater than the initial value is not satisfied, or if the specified time has not elapsed even if the condition is satisfied, the initial opening setting means is selected; On the other hand, setting control switching means selects the flow rate opening degree setting means and outputs a low pressure clean up blow valve drive signal when the condition is satisfied and a prescribed time has elapsed;
A low pressure clean up deaerator water level control device comprising output means for outputting a low pressure clean up blow valve driving signal from the setting control switching means to a low pressure clean up blow valve driving device.