JPH1038211A - Corrosion protection coating film formation apparatus for boiler water supply pipe - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a corrosion protection coating film formation apparatus for a boiler water supply pipe capable of rapidly converting dissolved oxygen concentration to specific dissolved oxygen concentration even when a flow rate of boiler water and pressure are changed. SOLUTION: There are used as data to correct the amount of reference value travel determined on the basis of a flow rate of boiler water flowing through a boiler water supply pipe 13 dissolved oxygen concentration in the boiler water, a flow rate of oxygen gas, and pressure in the boiler water supply pipe 13. Hereby, even when pressure of the boiler water supply pipe 13 is high, and oxygen gas is unlikely to be injected in the boiler water pipe 13, the degree of an travel of the control valve 19 is increased, and hence a specific amount of oxygen is rapidly supplied to the boiler water supply pipe 13.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for forming a corrosion prevention film on a boiler water supply pipe for forming a corrosion prevention film of iron oxide on an inner surface of a boiler water supply pipe for supplying boiler water to a boiler, for example, in a steam power plant. It is.

[0002]

2. Description of the Related Art Conventionally, an oxygen cylinder is connected via an oxygen gas supply pipe in the middle of a boiler water supply pipe constituting an apparatus for forming a corrosion prevention film on a boiler water supply pipe. A control valve is provided in the middle of the oxygen gas supply pipe, and oxygen gas is pressure-fed from the oxygen cylinder into the boiler water supply pipe in accordance with the opening of the control valve. This oxygen gas is fed under pressure into the boiler water supply pipe, whereby a corrosion prevention film of iron oxide is formed on the inner surface of the boiler water supply pipe.

The control valve is driven and controlled by a controller. The controller calculates a reference opening amount based on a predetermined condition based on the flow rate of the boiler water flowing through the boiler feed pipe. Then, the calculated reference opening amount is corrected based on the desired correction value, and becomes the final target opening amount. The controller drives and controls the control valve so as to achieve the calculated target opening amount. The correction value used in calculating the target opening amount is calculated based on the flow rate of oxygen gas flowing through the oxygen gas supply pipe (the amount of oxygen gas injected into the boiler water supply pipe) and the dissolved oxygen concentration in the boiler water. Is done.

[0004]

However, the above-described apparatus for forming a corrosion prevention film has the following problems.

When the pressure in the boiler feed pipe increases due to pressure fluctuations in the boiler feed pipe, the pressure becomes a resistance, and it becomes difficult to inject oxygen gas. In this case, since the flow rate of the oxygen gas decreases, the controller increases the opening amount of the control valve to increase the injection amount of the oxygen gas.

For example, as shown in the graph of FIG. 3B, it is assumed that the flow rate of boiler water is 1800 m ³ / h and the concentration of dissolved oxygen is 0.1 ppm (α range in FIG. 3). In this case, the prescribed oxygen injection rate is 2.1 liter / min according to a predetermined calculation formula. Therefore, the controller drives and controls the control valve so that the injection amount of oxygen gas is 2.1 liter / min.

Further, the flow rate of the boiler water detected in the next routine is 1800 m ³ / h, which is the same flow rate as the previous routine.
Assume that Then, it is assumed that the pressure in the boiler feed pipe is increased by 3 kg / cm ² from the time of the previous control (previous routine) due to the pressure fluctuation in the boiler feed pipe (β range in the same figure). At this time, the controller keeps the reference opening amount of the control valve at the same opening amount as in the previous routine because the flow rate of the boiler water does not change even if the pressure fluctuation occurs in the boiler feed pipe. As the pressure in the boiler feed pipe increases, the amount of oxygen gas injected into the boiler feed pipe decreases.

That is, as the pressure in the boiler feed pipe increases, it becomes difficult to inject oxygen gas into the boiler feed pipe. Accordingly, since the values of the oxygen gas flow rate and the dissolved oxygen concentration also decrease accordingly, the controller increases the opening of the control valve so that the dissolved oxygen concentration in the boiler water becomes a predetermined concentration. Also, as the pressure in the boiler feed pipe decreases, oxygen gas is more easily injected into the boiler feed pipe. Accordingly, since the values of the oxygen gas flow rate and the dissolved oxygen concentration also increase accordingly, the controller reduces the opening amount of the control valve so that the dissolved oxygen concentration in the boiler water becomes a predetermined concentration (γ range in the figure).

However, correcting the reference opening amount based on the dissolved oxygen concentration and the flow rate of the oxygen gas requires a long time t1 and t2 to determine the optimum oxygen gas injection amount. That is, since the controller corrects the opening amount of the control valve based on the value of the flow rate of the oxygen gas and the concentration of the dissolved oxygen, the flow rate of the boiler water does not change even if the pressure of the boiler feed pipe changes. If the pressure in the boiler feed pipe changes greatly, the controller takes a long time to inject the specified amount of oxygen into the boiler feed pipe.

[0010] In this case, since the dissolved oxygen concentration in the boiler water varies for a long time, it adversely affects the boiler feed pipe and the boiler, and it is not possible to efficiently form an antioxidant coating on the inner surface of the boiler feed pipe. There was a problem.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to make it possible to quickly bring a dissolved oxygen concentration to a specified dissolved oxygen concentration even when the flow rate and pressure of boiler water change. Another object of the present invention is to provide a boiler feed pipe corrosion prevention film forming apparatus.

[0012]

In order to achieve the above object, according to the first aspect of the present invention, oxygen gas is injected from an oxygen gas supply means into a boiler water supply pipe for supplying boiler water to the boiler. In a corrosion prevention film forming apparatus for forming a corrosion prevention film of iron oxide on the inner surface of a water supply pipe, an oxygen gas flow control valve for adjusting the amount of oxygen gas injected into the boiler water supply pipe from the oxygen gas supply means, Based on the flow rate of the boiler water flowing in the boiler feed pipe, a reference opening amount determining means for determining an opening amount serving as a reference of the oxygen gas flow control valve, and a reference opening amount determined by the reference opening amount determining means, Correction means for correcting the optimal opening amount based on the pressure in the boiler feed pipe and the concentration of oxygen dissolved in the boiler water, and the optimal opening amount corrected by the correcting means, Further comprising a control means for driving and controlling the hydrogen gas flow rate regulating valve as its gist.

(Operation) Therefore, in the first aspect of the invention, first, the reference opening amount is determined by the reference opening amount determining means based on the flow rate of boiler water flowing in the boiler feed pipe. Next, the correction unit corrects the reference opening amount to an optimal opening amount. Then, the control means drives and controls the oxygen gas flow rate adjusting valve so that the corrected optimal opening amount is obtained.

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to the drawings. As shown in FIG. 1, the pump 11 and the boiler 12 are connected by a boiler feed pipe 13. As the pump 11 is driven, boiler water is supplied from the boiler feed pipe 13 to the boiler 12. A boiler water flow meter 14 for measuring a flow rate of boiler water flowing through the boiler water supply pipe 13 is connected to the boiler water supply pipe 13. A pressure gauge 15 for measuring the pressure in the boiler water supply pipe 13 is connected to the boiler water supply pipe 13.

Further, a concentration meter 16 for measuring the concentration of oxygen dissolved in boiler water is connected to the boiler feed pipe 13. An oxygen cylinder 18 is connected via an oxygen supply pipe 17 to a portion of the boiler water supply pipe 13 between the pressure gauge 15 and the concentration meter 16. In addition, oxygen cylinder 1
The pressure of 8 does not change and is kept constant. Oxygen supply pipe 1
7 is connected to a control valve 19 as an oxygen gas flow control valve. Also, the control valve 19
An oxygen flow meter 20 that measures the flow rate of oxygen flowing through the oxygen supply pipe 17 is connected to a portion of the oxygen supply pipe 17 on the more upstream side. Further, an on-off valve 21 and a check valve 22 for preventing backflow of boiler water are provided at a connection portion of the oxygen supply pipe 17 to the boiler water supply pipe 13.

Next, an electrical configuration according to the present embodiment will be described. The controller C as a reference opening amount determining means, a correcting means, and a controlling means includes the boiler water flow meter 1
4, an oxygen flow meter 20, a pressure gauge 15, a concentration meter 16, a control valve 19, and an on-off valve 21 are connected. The controller C individually inputs measurement signals from the respective instruments, and determines the opening amount of the control valve 19 based on the measurement results.

Next, the control executed by the controller C will be described with reference to the flowchart of FIG. Step 1
At 01, a measured value (flow rate of boiler water flowing through the boiler feed pipe 13) is input from the boiler water flow meter 14.
In the next step 102, the reference opening amount of the control valve 19 is calculated from the input flow rate of the boiler water. In step 103, the control valve 19 is opened so that the reference opening amount calculated in step 102 is attained. In the following step 104, the release valve 21
To supply oxygen into the boiler feed pipe 13.

In the next step 105, the measured values (the flow rate of the oxygen gas flowing through the oxygen supply pipe 17 and the concentration of the dissolved oxygen dissolved in the boiler water) are input from the oxygen flow meter 20 and the concentration meter 16, respectively. In the next step 106, the control valve 19 is controlled based on the input measurement value.
A first correction value for correcting the opening amount of the first position is calculated. In the next step 107, a measured value (pressure in the boiler feed pipe 13) is input from the pressure gauge 15.

In step 108, the difference between the pressure value measured in the previous routine and the pressure value measured in the current routine is calculated. In step 109, a second correction value for correcting the opening amount of the control valve 19 is calculated based on the calculated pressure difference. In step 110, the reference opening amount calculated in step 102 is corrected based on the two correction values calculated. In step 111, the corrected opening amount is set as the target opening amount, and the drive of the control valve 19 is controlled so as to become the target opening amount. Then, again at step 10
After returning to 1, the subsequent processing is repeated.

Next, the operation of the present embodiment will be described. When the boiler water flows through the boiler feed pipe 13,
Based on the flow rate of the boiler water flowing through the boiler feed pipe 13, the control valve 19 and the on-off valve 21 are opened by a predetermined amount. Thereby, oxygen gas is supplied from the oxygen cylinder 18 to the boiler water supply pipe 13 via the oxygen supply pipe 17. The oxygen gas supplied to the boiler feed pipe 13 is dissolved in the boiler water. Then, a first correction value used to determine the target opening of the control valve 19 is calculated based on the oxygen concentration value in the boiler water in which the oxygen gas is dissolved and the oxygen flow value flowing through the oxygen supply pipe 17. You.

At the same time, a second correction value used to determine the target opening of the control valve 19 is calculated based on the pressure fluctuation in the boiler feed pipe 13. Based on these two correction values, the opening amount of the control valve 19 is corrected to an appropriate value.

Therefore, for example, when the flow rate of the boiler water is 180
0m^Three/ H, the dissolved oxygen concentration in the boiler water is 0.1pp
m, the injection amount is 2.1 lit.
/ Min. Controller C is the injection amount of oxygen gas
Control bar so that the pressure is 2.1 l / min.
The drive of the lube 19 is controlled. And detected by the next routine
Boiler water flow rate is the same as the previous routine.
800m^Three/ H. On the other hand, boiler feed pipe 1
The pressure in 3 is 3kg / cm more than the previous routine ^TwoHigh 6
kg / cm^TwoAnd

In the present embodiment, the fact that the pressure in boiler feed pipe 13 has risen by 3 kg / cm ² has been detected by pressure gauge 15 even though the flow rate of boiler water has not changed. The controller C detects this and corrects the opening amount of the control valve 19 to increase the opening amount from the previous routine. Thereby, even if the pressure of the boiler feed pipe 13 is high and oxygen gas is difficult to be injected into the boiler feed pipe 13, the opening degree of the control valve 19 is increased. A quantity of oxygen can be supplied.

As described in detail above, in this embodiment,
As the data for correcting the reference opening amount determined based on the flow rate of the boiler water flowing through the boiler feed pipe 13, the dissolved oxygen concentration in the boiler water, the flow rate of the oxygen gas, and the pressure in the boiler feed pipe 13 were used. Thereby, even if the pressure of the boiler feed pipe 13 is high and oxygen gas is difficult to be injected into the boiler feed pipe 13, the control valve 19
The boiler feed pipe 1
3 can be supplied with a specified amount of oxygen.

As a result, as shown in the graph of FIG. 3A, by increasing or decreasing the pressure in the boiler feed pipe 13 as a correction factor, the injection amount of oxygen gas injected into the boiler feed pipe 13 is reduced. It can be corrected to the specified amount quickly, and short time t1 '
(<T1) and t2 ′ (<t2), the correspondence is achieved. Accordingly, it is possible to prevent the concentration of dissolved oxygen in the boiler water from being varied, and thus to efficiently form the corrosion prevention film on the inner surface of the boiler feed pipe 13 and reduce the adverse effect on the boiler 12.

Further, the reference opening amount can be corrected and updated based on the pressure difference between the pressure value in the boiler feed pipe 13 measured in the previous routine and the pressure value in the boiler feed pipe 13 measured in the current routine. I made it. Thereby, the oxygen gas injection amount in consideration of the pressure fluctuation in the boiler feed pipe 13 is accurately determined, and the fluctuation of the dissolved oxygen concentration in the boiler water is determined.
Can be stabilized quickly.

The present invention may be implemented as follows. (1) In the above-described embodiment, the controller C as the control means controls the pressure in the boiler feed pipe 13 measured in the previous routine and the boiler feed pipe 13 measured in the current routine.
A correction value (second correction value) for calculating the target opening amount of the control valve 19 as the oxygen gas amount adjusting means is calculated based on the difference from the internal pressure.

On the other hand, a correction value for the pressure in the boiler water supply pipe 13 is set in advance, and based on the pressure in the boiler water supply pipe 13 measured in the current routine, the correction value as the oxygen gas amount adjusting means is set. The reference opening amount of the control valve 19 may be corrected. In this case, for example, a value obtained by multiplying the measured pressure value by a predetermined coefficient may be used as the correction value.

(2) The data necessary for correcting the reference opening amount may be only the pressure in the boiler feed pipe 13 and the dissolved oxygen concentration in the boiler water. (3) The data required to correct the reference opening amount may be only the pressure in the boiler water supply pipe 13 and the flow rate of the oxygen gas flowing through the oxygen supply pipe 17.

[0030]

According to the first aspect of the present invention, even when the pressure in the boiler feed pipe fluctuates, an appropriate amount of oxygen gas can be quickly and efficiently supplied into the boiler feed pipe. As a result, the corrosion prevention film can be efficiently formed on the inner surface of the boiler feed pipe, and the adverse effect on the boiler can be reduced.

[Brief description of the drawings]

FIG. 1 is a schematic circuit diagram according to an embodiment of the invention.

FIG. 2 is a flowchart showing control contents of a controller.

FIG. 3A shows a boiler water flow rate in the present embodiment,
4 is a graph showing a relationship between a pressure in a boiler feed pipe and an oxygen gas flow rate. (B) is a graph showing the relationship between the boiler water flow rate, the pressure in the boiler feed pipe, and the oxygen gas flow rate in the prior art.

[Explanation of symbols]

12 ... Boiler, 13 ... Boiler feed pipe, 18 ... Oxygen cylinder as oxygen gas supply means, 19 ... Control valve as oxygen gas amount adjustment valve, 15 ... Pressure gauge as pressure measurement means, C ... Reference opening degree determination means , Correction means, and controller as control means.

Claims (1)

[Claims] An apparatus for forming a corrosion-preventing film, wherein oxygen gas is injected from an oxygen gas supply means into a boiler water supply pipe for supplying boiler water to a boiler, and a corrosion prevention film of iron oxide is formed on an inner surface of the boiler water supply pipe. An oxygen gas flow control valve for adjusting the amount of oxygen gas injected into the boiler water supply pipe from the oxygen gas supply means; and a reference for the oxygen gas flow control valve based on a flow rate of the boiler water flowing in the boiler water supply pipe. A reference opening amount determining means for determining the opening amount to be, and the reference opening amount determined by the reference opening amount determining means, to an optimum opening amount based on the pressure in the boiler feed pipe and the concentration of oxygen dissolved in the boiler water. A boiler water supply pipe comprising: a correcting means for correcting; and a control means for driving and controlling the oxygen gas flow rate adjusting valve so as to have the optimal opening amount corrected by the correcting means. Food preventing film formation apparatus.