JP2996519B2 - Control method of chemical solution injection amount in boiler water supply system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for controlling the amount of chemical solution injected into a boiler water supply system, and more particularly, to maintain the water to be treated supplied to a boiler and discharged from a condensate desalination apparatus at a constant water quality. The present invention relates to a method for controlling a chemical solution injection amount of a boiler water supply system which can be used.

[0002]

2. Description of the Related Art Generally, in a power generating plant, a condensate desalination apparatus is installed upstream of a chemical injection point, and an NH ₄ type ion exchange resin is used as an ion exchange resin in the apparatus. ing.

This NH ₄ type ion exchange resin has the following characteristics. (1) In the early stage of operation, the pH of the outlet water of the condensate desalination apparatus is 7 because it acts as an H-type ion exchange resin that absorbs all ammonia together with impurities. (2) The H-type ion exchange resin is converted into an NH ₄ type ion exchange resin by absorbing ammonia. (3) After the conversion to the NH ₄ type ion exchange resin, impurities are absorbed, but the ammonia passes through in its entirety.
The outlet water of the H condensate desalination unit flows out. (4) The NH ₄ type ion exchange resin that has reached the break point due to the absorption of impurities is regenerated and acts again as an H type ion exchange resin.

A condensate demineralizer has an NH having the above characteristics.
A plurality of resin cylinders filled with type ₄ ion exchange resin are provided side by side, and each resin cylinder is appropriately regenerated and used,
The pH value of the outlet water of the condensate desalination unit is a synthetic value obtained by operating each resin cylinder. However, when the resin cylinder is converted from NH ₄ type to H type after regeneration, the water to be treated is upstream of the chemical solution injection point. The pH of the outlet water of a condensate desalination unit changes suddenly. On the other hand, the pH of the water supply to the boiler must be kept constant,
It is necessary to control the amount of injected chemical solution for sudden changes in

FIG. 7 is a flow sheet diagram of a conventional ammonia injection control device. This apparatus is a condensate desalination apparatus 1 for desalinating condensate obtained by a condenser (not shown).
A low-pressure heater 4 for superheating the water to be treated discharged from the condensate desalination device by the condensate pump 2, a deaerator 7 for degassing the superheated water to be treated, Ammonia tank 9 for storing ammonia for adjusting the pH to a constant value, conductivity detector 2 for detecting the conductivity of the water to be treated before the injection of ammonia, and detecting the conductivity of the water to be treated after the injection of ammonia. A conductivity detector 6, a flow meter 5 for measuring the flow rate of the water to be treated, a ratio setting device 14 and a PID to which conductivity signals upstream and downstream of the ammonia injection point are input.
A drive unit 16 connected to a stroke length controller 12 connected to a controller 13; and a speed change drive motor 15 connected to a rotation speed controller 11 to which a flow rate signal of the water to be treated is input.
And the ammonia injection pump 10 for controlling the injection amount of ammonia.

In such a configuration, the condensate desalination apparatus 1
The water to be treated, which has been desalted in the above step, is supplied to the low-pressure heater 4 by the condensate pump 3, is superheated, is further deaerated by the deaerator 7, and is then supplied to a boiler (not shown). Ammonia is injected into the water downstream of the condensate pump 3 so as to cope with a pH change caused by the operation of the condensate desalination apparatus 1 and is maintained at a constant pH. The control of the injection amount of ammonia for maintaining the pH constant is performed as follows.

First, the pH of the water to be treated before injecting ammonia is measured as a conductivity by a conductivity detector 2 at the outlet of the condensate desalination apparatus 1, and the conductivity is input to a ratio setting device 14 to input a stroke length. Ammonia injection pump 10 via controller 12
Is controlled in advance to determine the ammonia discharge amount.

Next, the conductivity of the water to be treated after the injection of ammonia is measured by the conductivity detector 6 at the inlet of the deaerator 7, and this signal is input to the PID controller 13 to determine the integration time based on the flow signal. The drive unit 16 is adjusted via the stroke length controller 12 by a deviation signal obtained by adjusting the time delay between the injection point and the measurement point and comparing the correction signal with a signal of a predetermined pH value. Work.

With respect to the fluctuation of the feed water flow rate due to the change in the load of the boiler, the flow rate of the water to be treated is measured by the flow meter 5 and the rotation of the shift drive motor 15 of the ammonia injection pump 10 is controlled via the rotation speed controller 11. Adjust to control the amount of ammonia discharged.

As described above, in the prior art, a change in the feed water flow rate due to a load change is handled by controlling the rotation speed of the speed change drive motor 15, and a change in the pH value and correction of the time delay are corrected by the stroke. It was supported by length control.

The flow fluctuation of the feed water corresponding to the adjustment of the rotation speed is about 1: 4 due to the restriction on the operation of the boiler. Since the range of fluctuation is large, it is necessary to perform rapid control with a large range.

However, the control range (rangeability) of the rotational speed is 1:10, while the control range of the stroke length is about 1: 4. However, the effective use of the control range is not performed, and there is a problem that the operation must be performed in a severe range as controllability.

In the conventional control method, feedback control is performed by measuring the conductivity at the inlet of the deaerator where the ammonia injected into the outlet of the condensate pump is sufficiently mixed and the ammonia concentration in the feedwater becomes uniform. However, there is a distance between the ammonia injection point and the measurement point, and a large time lag occurs due to a sudden change in pH due to a time delay.To prevent this, the conductivity signal at the condensate desalination device outlet is used to prevent this. There was a need for complicated control in which feedforward control was also performed. In addition, to adjust the integration time with the flow signal of the feedback signal that corrects the time delay between the injection point and the measurement point, it is necessary to repeat the adjustment by trial run to match the plant characteristics to optimize the set value. was there.

On the other hand, in a once-through power plant,
At the time of starting the plant, a cleanup operation is performed before the normal operation to improve the quality of water supplied to the boiler. This cleanup operation is performed in order to strictly maintain the quality of the water supplied to the boiler.The clean range is expanded while discharging and removing impurities from the pre-boiler sequentially for each system, and the target value of the water quality is adjusted. It is an operation to satisfy.

In this cleanup operation, since the water quality is lower than during the normal operation and dissolved oxygen is contained, a larger amount of hydrazine must be injected than during the normal operation. For this reason, in controlling the injection amount of hydrazine, a control range that satisfies the injection of a large amount of hydrazine during the cleanup operation and the injection of a small amount of hydrazine during the normal operation is required.

FIG. 8 is a flow sheet diagram of a conventional hydrazine injection control device. 8, the same parts as those in FIG. 7 are denoted by the same reference numerals, and the description will be omitted. In FIG. 8, FIG.
The difference is that instead of providing the ammonia tank 9 and the means for controlling the inflow of ammonia, a hydrazine tank 21 for storing hydrazine and a hydrazine concentration meter 20 for measuring the hydrazine concentration of the water to be treated after hydrazine injection are provided. And a drive unit 16 connected to a PID controller 13 and a stroke length controller 12 to which a hydrazine concentration signal is input, and a variable speed drive motor 15 to be connected to a rotation speed controller 11 to which a flow rate signal is input. And a hydrazine infusion pump 23 for controlling the pressure.

In this apparatus, the control of the hydrazine injection amount is performed as follows. First, in the wake of the hydrazine injection point (the downstream of the low-pressure heater 4), the hydrazine concentration of the water to be treated is electrically detected by the hydrazine concentration meter 20, and this signal is input to the PID controller 13 to be supplied to the predetermined position. Compared with the hydrazine concentration signal, the hydrazine infusion pump 2
3, the drive unit 10 is controlled, and the flow rate of the water to be treated is detected by the flow meter 5 and input to the rotation speed controller 11,
The rotational speed of the speed change drive motor 11 of the hydrazine infusion pump 23 is adjusted in proportion to the flow rate.

As described above, in the prior art, the variable speed drive motor 11 is not affected by a change in the feed water flow rate due to a load change.
The change in the hydrazine injection amount and the correction of the time delay during the cleanup operation and the normal operation were corrected by the stroke length control.

The flow fluctuation of the feed water corresponding to the adjustment of the rotation speed is about 1: 4 due to the limitation on the operation of the boiler, but the amount of hydrazine injection during the clean-up operation and the normal operation corresponding to the adjustment of the stroke length is controlled. Since the change has a large fluctuation range, it is necessary to perform rapid control in a large range.

However, the control range (rangeability) of the rotational speed is 1:10, whereas the control range of the stroke length is about 1: 4. However, the effective use of the control range is not performed, and there is a problem that the operation must be performed in a severe range as controllability.

In the conventional control method, the injected hydrazine is sufficiently mixed, and the concentration of hydrazine in the feed water is measured at the inlet of the deaerator 7 where the concentration of hydrazine becomes uniform. Adjustment of the integration time by the flow signal to correct the time lag from the measurement point required repeated adjustment by trial run to match the characteristics of the plant in order to optimize the set value.

[0022]

SUMMARY OF THE INVENTION A first object of the present invention is to eliminate the above-mentioned problems of the prior art and to make optimal use of the controllability of the chemical liquid injection pump even when the quality of the water to be treated changes rapidly. It is another object of the present invention to provide a method for controlling a chemical injection amount of a boiler water supply system, which can more reliably and stably control a chemical injection amount.

A second object of the present invention is to provide a boiler water supply system which eliminates the above-mentioned problems of the prior art and simplifies the complicated control of the chemical solution injection amount for maintaining the quality of the water to be treated constant. It is an object of the present invention to provide a method for controlling a chemical solution injection amount.

[0024]

Means for Solving the Problems The inventors of the present invention have conducted intensive studies in view of the above problems, and as a result, control of the water quality change such as pH which fluctuates greatly by controlling the rotational speed of the speed change drive motor having a large control range. It is found that the above problem can be solved by controlling the stroke length with a small control range for a flow rate change with little fluctuation, and a chemical solution for maintaining a constant boiler feed water quality is supplied to the inlet of a condensate pump. Since the concentration of the chemical solution becomes uniform at the outlet of the condensate pump when the water is injected into the condensate pump, it has been found that a signal without a time delay can be fed back by measuring the quality of the water to be treated at the outlet of the condensate pump.

A first aspect of the present invention is to provide a water treatment system for adjusting pH by injecting ammonia into the water to be treated, measuring the conductivity of the water to be treated upstream and downstream of the injection point of ammonia, and measuring the conductivity of the water. Based on the deviation signal obtained by comparing with the conductivity at the pH value, the rotation speed of the ammonia injection pump is adjusted, the flow rate of the water to be treated is detected, and the stroke length of the ammonia injection pump is proportional to this flow rate. The present invention relates to a method for controlling a chemical liquid injection amount in a boiler water supply system, which is characterized by adjusting.

A second aspect of the present invention is to provide a water treatment system for adjusting pH by injecting ammonia into water to be treated discharged from a condensate desalination apparatus by a condensate pump. The stroke length or rotation speed of the ammonia injection pump is adjusted by a deviation signal obtained by comparing the measured value of the conductivity of the water to be treated downstream of the condensate pump with the conductivity at a predetermined pH value. In addition, the present invention relates to a method for controlling a chemical liquid injection amount in a boiler water supply system, wherein a flow rate of water to be treated is detected, and a rotation speed or a stroke length of an ammonia injection pump is adjusted in proportion to the detected flow rate.

A third aspect of the present invention is to provide a water treatment system in which hydrazine is injected into the water to be treated to remove dissolved oxygen, the measured value of the hydrazine concentration of the water to be treated downstream of the hydrazine injection point and a predetermined hydrazine concentration. Using the deviation signal obtained by comparing with the concentration, adjust the rotation speed of the hydrazine injection pump, detect the flow rate of the water to be treated, and adjust the stroke length of the hydrazine injection pump in proportion to this flow rate. The present invention relates to a method for controlling a chemical liquid injection amount in a boiler water supply system, which is a characteristic method.

A fourth aspect of the present invention is to provide a water treatment system for removing dissolved oxygen by injecting hydrazine into water to be treated discharged from a condensate desalination apparatus by a condensate pump. Inject hydrazine, adjust the stroke length or rotation speed of the hydrazine injection pump by a deviation signal obtained by comparing the measured value of the hydrazine concentration of the water to be treated downstream of the condensate pump with a predetermined hydrazine concentration, In addition, the present invention relates to a method for controlling a chemical solution injection amount of a boiler water supply system, wherein a flow rate of water to be treated is detected, and a rotation speed or a stroke length of a hydrazine injection pump is adjusted in proportion to the flow amount.

[0029]

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

FIG. 1 is a flow sheet diagram of an ammonia injection control device showing a first embodiment of the present invention. In FIG. 1, the same parts as those in FIG. FIG. 1 is different from FIG. 7 in that a ratio setting unit 1 to which the conductivity signals upstream and downstream of the ammonia injection point are input.
4 and the PID controller 13 are connected to the rotation speed controller 11 and the flow rate signal of the water to be treated is transmitted to the stroke length controller 1.
2 is input.

According to such an apparatus, the control for the pH change having a large fluctuation range can be performed by the rotation speed of the fluctuation drive motor 15 having a large control range, and the control for the flow rate change of the water to be treated having a small fluctuation range. Can be performed through the stroke length controller 12 having a small control range.
Each control range can be used effectively and the pH of the water to be treated
Can be more reliably and stably controlled even when the temperature changes suddenly.

In FIG. 1, it is possible to switch the control system for the rotation speed and the stroke length of the pump so that the control system can be operated according to the fluctuation width of the control signal which differs for each plant.

FIG. 2 is a flow sheet diagram of an ammonia injection control device showing a second embodiment of the present invention. 2 differs from FIG. 7 in that the ammonia condensate desalination apparatus 1
At the outlet of the condensate pump 3, and at the downstream of the condensate pump 3, the conductivity detector 2 is installed. The conductivity signal detected by this detector is input to the PID controller 13. The drive unit 16 of the ammonia injection pump 10 is controlled via the stroke length controller 12 by the obtained deviation signal by comparing with the conductivity at the predetermined target pH value,
Further, a flow rate signal of the water to be treated is input to the flow rate controller 11 to control the speed change drive motor 15 of the ammonia injection pump 10.

According to such a device, it is possible to detect the conductivity with almost no time delay in a state where the ammonia injected into the inlet of the condensate pump 3 is uniformly mixed. By performing the control, it is not necessary to perform the feedforward control based on the conductivity signal at the outlet of the condensate desalination apparatus and the correction control of the time delay between the injection point and the measurement point. Therefore, the method for controlling the amount of injected ammonia can be made very simple, and labor for adjusting the set value of the correction of the time delay due to the trial operation is unnecessary.

In FIG. 2, it is also possible to control the rotation speed by a feedback signal based on the conductivity deviation signal and control the stroke length by the flow rate signal. In such a device, not only the control device is simplified, but also the control range of each device can be effectively used, so that the ammonia injection amount can be more reliably and stably controlled.

FIG. 3 is a flow sheet diagram of an ammonia injection control device showing a second other embodiment of the present invention. This apparatus further includes a conductivity detector 6 for measuring the conductivity of the downstream of the boiler feed pump 25 (the inlet of the boiler 26) in addition to the apparatus of FIG. 2, and a PID controller 13A for inputting this signal. And pH by operation of the condensate desalination unit 1
Can be dealt with by the measurement signal of the conductivity detector 2 inputted to the PID controller 13 at the time of sudden change, and can be dealt with by the measurement signal of the conductivity detector 6 inputted to the PID controller 13A at the time of normal operation. That is, the switching operation is performed according to the change rate of the measurement signal of the conductivity detector 2.

According to such an apparatus, it is possible to quickly respond to the sudden change of the pH by the conductivity of the outlet of the condensate pump. In the normal operation, even if the ammonia concentration changes due to disturbance, the final Accurate control is possible by controlling the conductivity at the inlet of the boiler (conserving unit) 26, which is the target concentration monitoring position.

FIG. 4 is a flow sheet diagram of a hydrazine injection control device showing a third embodiment of the present invention. In FIG. 4, the same portions as those in FIG. 4 differs from FIG. 8 in that the PID controller 1 to which the hydrazine concentration signal downstream of the hydrazine injection point is input.
3 is connected to the rotation speed controller 11 and the flow rate signal of the water to be treated is input to the stroke length controller 12.

According to such an apparatus, the stroke length controller having a rangeability of about 1: 4 can cope with a change in the amount of hydrazine injection due to the feed water flow rate having a relatively small fluctuation width (about 1: 4). More effective use of each range ability by responding to changes in the amount of hydrazine injection due to switching from clean-up operation to normal operation by a rotation speed controller with a wider range ability (1:10) than the long controller can do. Therefore, the operation in a severe range can be improved as the controllability of the conventional technique, and the injection amount of hydrazine can be more reliably and stably controlled even when the hydrazine injection concentration changes abruptly within a large range.

In FIG. 4, it is also possible to switch the control system for the number of revolutions and the stroke length of the pump so that the control system can be operated in accordance with the fluctuation width of the control signal which differs for each plant.

FIG. 5 is a flow sheet diagram of a hydrazine injection control device showing a fourth embodiment of the present invention. The difference between FIG. 5 and FIG. 4 is that
The hydrazine densitometer 20 is installed at the outlet of the condensate pump 3, i.e., upstream of the condensate pump 3, and the hydrazine densitometer 20 is installed. The drive unit 16 of the ammonia injection pump 23 is controlled via the stroke length controller 12 by using the obtained deviation signal, and the flow rate signal of the water to be treated is input to the rotation speed controller 11 by the obtained deviation signal. That is, the speed change drive motor 15 of the ammonia injection pump 23 is controlled.

According to such a device, the hydrazine injected into the inlet of the condensate pump 3 can be detected at a concentration with almost no time delay in a state of being uniformly mixed. , It is not necessary to perform feedforward control based on the concentration signal at the outlet of the condensate desalination apparatus and control for correcting the time delay between the injection point and the measurement point. Therefore, the method for controlling the injection amount of hydrazine can be made very simple, and the labor for adjusting the set value of the time delay correction by the trial operation is not required.

In FIG. 5, it is also possible to control the rotation speed by a feedback signal based on a deviation signal of the hydrazine concentration and to control the stroke length by a flow rate signal. In such a device, not only the control device is simplified, but also the control range of each device can be effectively used, so that the hydrazine injection amount can be more reliably and stably controlled.

FIG. 6 is a flow sheet diagram of a hydrazine injection control device showing a fourth other embodiment of the present invention. In this apparatus, a hydrazine concentration meter 24 for measuring the hydrazine concentration in the downstream side of the boiler feed pump 25 (the inlet of the boiler 26) is installed in the apparatus shown in FIG. 5, and a PID controller 13A for inputting this signal is installed. The hydrazine densitometer 2 is adapted to respond to the sudden change in the hydrazine concentration with the measurement signal of the hydrazine densitometer 24 and to respond to the measurement signal of the hydrazine densitometer 20 during normal operation.
That is, the switching operation is performed according to the change rate of the measurement signal of 0.

According to such an apparatus, when the hydrazine concentration changes suddenly, the hydrazine concentration at the outlet of the condensate pump is quickly responded. During normal operation, even if the hydrazine concentration changes due to disturbance, the final concentration of the hydrazine changes. More accurate control is possible by controlling the hydrazine concentration at the inlet of the boiler (coal saving device) 26 which is the monitoring position.

[0046]

According to the first and third aspects of the present invention, a change in water quality such as pH having a large fluctuation range can be dealt with by controlling the rotation speed with a large control range, and a flow rate change with a small fluctuation range can be achieved. Since the control is performed by controlling the stroke length, which has a small control range, even if the quality of the water to be treated changes rapidly, the controllability of the chemical liquid injection pump is optimally used to ensure more stable and stable chemical liquid control. Can be controlled.

According to the second and fourth aspects of the present invention, the concentration of the chemical at the outlet of the condensate pump is adjusted by injecting a chemical for maintaining the quality of the feedwater supplied to the boiler at a constant level. By measuring the quality of the water to be treated at the outlet of the chemical liquid pump, it is possible to feed back a signal without time delay, and to perform feedforward control and correction control of the time delay between the injection point and the measurement point. There is no need for this, and the method of controlling the amount of injected chemical solution can be simplified.

[Brief description of the drawings]

FIG. 1 is a flow sheet diagram of an ammonia injection control device showing a first embodiment of the present invention.

FIG. 2 is a flow sheet diagram of an ammonia injection control device showing a second embodiment of the present invention.

FIG. 3 is a flow sheet diagram of an ammonia injection control device showing a second other embodiment of the present invention.

FIG. 4 is a flow sheet diagram of a hydrazine injection control device showing a third embodiment of the present invention.

FIG. 5 is a flow sheet diagram of a hydrazine injection control device showing a fourth embodiment of the present invention.

FIG. 6 is a flow sheet diagram of a hydrazine injection control device showing a fourth other embodiment of the present invention.

FIG. 7 is a flow sheet diagram of a conventional ammonia injection control device.

FIG. 8 is a flow sheet diagram of a conventional hydrazine injection control device.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Condensate desalination apparatus, 2, 6 ... Conductivity detector, 3 ... Condensate pump, 4 ... Low pressure heater, 5 ... Flow meter, 7 ... Deaerator, 8,
Reference numeral 22: valve, 9: ammonia tank, 10: ammonia injection pump, 11: rotation speed controller, 12: stroke length controller, 13, 13A: PID controller, 14: ratio setting device, 15: variable speed drive motor, 16 … Drive unit,
20, 24: hydrazine concentration meter, 21: hydrazine tank, 23: hydrazine injection pump, 25: boiler feed pump, 26: boiler.

──────────────────────────────────────────────────続 き Continuation of the front page (72) Inventor Yasuyuki Yamamoto 6-9 Takara-cho, Kure-shi, Hiroshima Pref. Inside the Kure factory of Babcock Hitachi Ltd. (56) References JP-A-50-94303 (JP, A) 48-9791 (JP, A) JP-A-58-131193 (JP, A) JP-A 60-238603 (JP, A) JP-A 50-94304 (JP, A) (58) Fields investigated (Int) .Cl. ⁷ , DB name) F22B 37/56 F22D 11/00

Claims (8)

(57) [Claims] In a water treatment system for adjusting pH by injecting ammonia into water to be treated, the measured value of the conductivity of the water to be treated upstream and downstream of the injection point of ammonia and the conductivity at a predetermined pH value The rate of deviation of the ammonia injection pump is adjusted by the deviation signal obtained by comparing with the rate, the flow rate of the water to be treated is detected, and the stroke length of the ammonia injection pump is adjusted in proportion to this flow rate. The method for controlling the amount of chemical solution injected into the boiler water supply system. 2. In a water treatment system for adjusting pH by injecting ammonia into water to be treated discharged from a condensate desalination device by a condensate pump, ammonia is injected into a stream upstream of the condensate pump. Based on the deviation signal obtained by comparing the measured value of the conductivity of the water to be treated downstream of the water pump with the conductivity at a predetermined pH value, the stroke length of the ammonia injection pump is adjusted, and the flow rate of the water to be treated is also adjusted. And controlling the number of revolutions of an ammonia injection pump in proportion to the flow rate. 3. In a water treatment system for adjusting pH by injecting ammonia into water to be treated discharged from a condensate desalination apparatus by a condensate pump, ammonia is injected into a stream upstream of the condensate pump. By using a deviation signal obtained by comparing the measured value of the conductivity of the water to be treated downstream of the water pump with the conductivity at a predetermined pH value, the rotation speed of the ammonia injection pump is adjusted, and the flow rate of the water to be treated is adjusted. A method for controlling a chemical solution injection amount of a boiler water supply system, comprising detecting and adjusting a stroke length of an ammonia injection pump in proportion to the flow rate. 4. A control method according to claim 2, further comprising means for measuring the conductivity of the water to be treated at the inlet of the boiler, wherein the conductivity measured by the means during operation with small fluctuations in the pH of the water to be treated. Wherein the stroke length or the number of revolutions of the ammonia injection pump is controlled by using the method. 5. In a water treatment system for removing dissolved oxygen by injecting hydrazine into the water to be treated, a measured value of the hydrazine concentration of the water to be treated downstream of the hydrazine injection point is compared with a predetermined hydrazine concentration. Boiler feed water, wherein the rotational speed of the hydrazine injection pump is adjusted based on the obtained deviation signal, the flow rate of the water to be treated is detected, and the stroke length of the hydrazine injection pump is adjusted in proportion to this flow rate. How to control the amount of chemical solution injected into the system. 6. In a water treatment system for removing dissolved oxygen by injecting hydrazine into the water to be treated discharged by a condensate pump from a condensate desalination apparatus, hydrazine is injected before the condensate pump, The stroke length of the hydrazine injection pump is adjusted by a deviation signal obtained by comparing the measured value of the hydrazine concentration of the water to be treated downstream of the condensate pump with a predetermined hydrazine concentration, and the flow rate of the water to be treated is also adjusted. A method for controlling a chemical solution injection amount in a boiler water supply system, comprising detecting and adjusting the number of revolutions of a hydrazine injection pump in proportion to the flow rate. 7. In a water treatment system for removing dissolved oxygen by injecting hydrazine into water to be treated discharged by a condensate pump from a condensate desalination apparatus, hydrazine is injected in front of the condensate pump, hydrazine of water to be treated該復water pump slipstream
Based on a deviation signal obtained by comparing the measured value of the hydrazine concentration with a predetermined hydrazine concentration , the rotation speed of the hydrazine injection pump is adjusted, the flow rate of the water to be treated is detected, and hydrazine injection is performed in proportion to the flow rate. A method for controlling a chemical liquid injection amount in a boiler water supply system, comprising adjusting a stroke length of a pump. 8. A control method according to claim 6 or 7, wherein the means for measuring the hydrazine concentration of the treatment water to the boiler inlet is provided, during operation less hydrazine concentration variation of the water to be treated, hydrazine measured by the means A method for controlling a chemical liquid injection amount in a boiler water supply system, wherein a stroke length or a rotation speed of a hydrazine injection pump is controlled using the concentration .