JP7400934B2 - Water supply control device - Google Patents

Description

The present invention relates to a water supply control device.

A boiler system is used in which steam is generated by a boiler and supplied to load equipment, and drain produced by condensation of the steam in the load equipment is collected in a drain tank and resupplied to the boiler. In order to improve thermal efficiency in such a boiler system, a boiler system has been proposed, for example, as described in Patent Document 1, in which a drain tank is pressurized, high-temperature, high-pressure drain is recovered, and the drain is re-supplied to the boiler device. has been done.

The boiler system described in Patent Document 1 includes a drain supply pump and a drain flow rate control valve, and includes a drain supply line that supplies drain contained in a drain tank to a boiler device having a plurality of boilers, and a drain supply line that supplies fresh water to the boiler device. and a new water supply line that supplies water. The boiler system described in Patent Document 1 preferentially supplies condensate from a condensate supply line, and when the condensate supply from the condensate supply line is insufficient, fresh water is supplied from a new water supply line. The control device is provided with two operation modes: a first water supply mode and a second water supply mode in which water is supplied only from the new water supply line.

JP 2017-146074 Publication

In a boiler that performs water level control as described in Patent Document 1, the combustion amount is set depending on the steam consumption of load equipment, etc., and the flow rate of feed water may be adjusted depending on the combustion amount. In this case, a flow rate sensor is provided in the drain supply line, and the opening degree of the drain flow rate control valve is feedback-controlled so that the detected value of the flow rate sensor becomes a target value determined according to the combustion amount.

In a boiler system having such a configuration, when the second water supply mode is switched to the first water supply mode, the target value of the flow rate of drain supplied to the boiler increases in a stepwise manner. In this case, the drain flow rate may overshoot and become temporarily excessive. If you switch from the second water supply mode to the first water supply mode when the required condensate flow rate is relatively large, such as when the steam consumption of load equipment is large, the condensate supply pump may cause cavitation. Once cavitation occurs in the drain supply pump, the flow rate of the drain decreases, so the opening degree of the drain flow rate control valve is further increased by feedback control, and cavitation may not be eliminated.

Therefore, an object of the present invention is to provide a water supply control device that can suppress the occurrence of cavitation in a drain supply pump.

The water supply control device according to the present invention includes a boiler that generates steam and supplies it to load equipment, a drain tank that collects drain produced by condensing steam in the load equipment without releasing it to the atmosphere, and the drain tank. a drain supply line that supplies the drain recovered to the boiler; a makeup water supply line that supplies make-up water to the boiler; and a drain supply line that is disposed on the drain supply line and that sends out the drain from the drain tank. Controls the water supply of a boiler system that includes a pump, a flow rate adjustment mechanism that is arranged in the drain supply line and can set a state quantity that determines the ease with which the drain flows, and a flow rate detection section that detects the flow rate of the drain. The water supply control device includes a flow rate control unit that performs feedback control on a state quantity of the flow rate adjustment mechanism so that the flow rate detected by the flow rate detection unit approaches a set flow rate target value, the flow rate control unit , from a state in which the drain is not supplied to the boiler from the drain supply line and makeup water is supplied from the makeup water supply line, the drain is supplied from the drain supply line and makeup water is supplied from the makeup water supply line. When the state is switched to a non-supply state, the feedback control is started after the state quantity of the flow rate adjustment mechanism is adjusted to the set initial value.

In the water supply control device according to the present invention, the flow rate target value is set to zero or the minimum flow rate when the water level in the boiler is equal to or higher than a predetermined upper limit, and when the water level in the boiler is equal to or lower than a predetermined lower limit. If this happens, it may be set to a predetermined value.

In the water supply control device according to the present invention, the target value may change continuously so as to keep the water level of the boiler constant.

According to the present invention, it is possible to provide a water supply control device that can suppress the occurrence of cavitation in a drain supply pump.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the structure of the boiler system provided with the water supply control apparatus of 1st Embodiment of this invention. It is a figure showing the composition of the boiler system provided with the water supply control device of a 2nd embodiment of the present invention.

Hereinafter, preferred embodiments of the water supply control device of the present invention will be described with reference to the drawings. FIG. 1 is a diagram showing the configuration of a boiler system 1 including a water supply control device 200 according to a first embodiment of the present invention.

The boiler system 1 includes a boiler device 10, a drain tank 20, an open tank 30, a number control device 100, and a water supply control device 200 according to an embodiment of the present invention. The boiler system 1 generates steam using the boiler device 10 and supplies the steam to a load device 40 that consumes the steam (condenses the steam using thermal energy).

The boiler system 1 also includes a plurality of lines connecting these devices and through which steam or water flows. Specifically, the boiler system 1 includes a steam supply line L1, a drain recovery line L2, a drain supply line L3, a pressurized steam line L4, a flash steam line L5, a tank makeup water supply line L6, and a boiler makeup water supply line L7. Equipped with

Furthermore, the boiler system 1 includes a steam trap 21 and a check valve 22 provided in the drain recovery line L2, a drain supply pump 31, a drain flow rate control valve 32, and a drain flow rate sensor 33 provided in the drain supply line L3. A supply pressure regulation valve 41 provided in the pressurized steam line L4, a discharge pressure regulation valve 51 provided in the flash steam line L5, a tank water supply pump 61 and a tank water supply amount regulation valve 62 provided in the tank makeup water supply line L6. , and a makeup water supply pump 71 provided in the boiler makeup water supply line L7.

The boiler device 10 includes a plurality of boilers 11, a steam header 12 in which steam generated by the plurality of boilers 11 is collected, and a connecting pipe 13 that connects the boilers 11 and the steam header 12.

The plurality of boilers 11 generate steam by heating drain supplied from the drain supply line L3 or makeup water supplied from the boiler makeup water supply line L7. Each boiler 11 can be configured by, for example, a once-through boiler. The plurality of boilers 11 operate in cooperation and generate an amount of steam that is approximately equal to the amount of steam consumed by the load equipment 40.

The boilers 11 each have a local control section 15 that controls the combustion state according to instructions from the number control device 100. The local control unit 15 instructs the water supply control device 200 to specify a target flow rate value, which is the amount of water supplied to each boiler 11 . Specifically, the local control unit 15 instructs the water supply control device 200 to set the flow rate target value to zero and stop water supply when the water level in the boiler 11 exceeds a predetermined upper limit, and When the water level in 11 becomes below a predetermined lower limit, on/off control can be performed to instruct the water supply control device 200 to set the flow rate target value to a predetermined value. In this case, it is preferable that the target flow rate value that the local control unit 15 instructs when the water level in the boiler 11 becomes below a predetermined lower limit be set to a larger value as the combustion amount becomes larger. For example, when the drain supply line L3 is provided with an economizer that heats the water supply using the combustion exhaust gas of the boiler 11, the local control unit 15 may instruct the flow rate when the water level in the boiler 11 reaches a predetermined upper limit or higher. The target value may not be completely zero, but may be the minimum value that can prevent the feed water from boiling within the economizer. Thereby, when the water level in the boiler 11 becomes equal to or higher than a predetermined upper limit, water supply at the minimum flow rate can be continued, and boiling of the supply water in the economizer can be prevented.

The steam header 12 stores steam generated by the boiler 11 and supplies it to the load equipment 40, thereby suppressing pressure fluctuations in the steam. Connecting pipe 13 collects steam generated in boiler 11 to steam header 12 . The steam header 12 has a pressure sensor 16 that detects the pressure of internal steam.

The drain tank 20 is constituted by a pressure vessel having pressure resistance. This drain tank 20 collects drain, which is generated by condensation of steam generated by the boiler 11 and used by the load equipment 40, in a high temperature and high pressure state.

A drain water level gauge 25 is provided in the drain tank 20 to detect the water level of the internal drain. The drain water level gauge 25 can be configured to include a cylindrical main body and a plurality of electrode rods arranged inside the main body to detect the water level inside the main body.

The open tank 30 is open to the atmosphere. This open tank 30 stores make-up water to be supplied to the boiler 11. Furthermore, flash steam generated from drain in the drain tank 20 is supplied to the open tank 30 .

The steam supply line L1 connects the steam header 12 and the load device 40, and supplies steam generated by the plurality of boilers 11 to the load device 40.

The drain recovery line L2 recovers drain generated by condensing steam in the load equipment 40 into the drain tank 20 without releasing it to the atmosphere. In the drain recovery line L2, the steam trap 21 allows only the drain to pass through and prevents steam from flowing into the drain tank 20. The check valve 22 prevents drain from flowing backward.

The drain supply line L3 supplies the drain collected in the drain tank 20 to the boiler device 10. The upstream end of the drain supply line L3 is connected to the lower part of the drain tank 20. The downstream side of the drain supply line L3 is branched into a plurality of lines so that the ends thereof are connected to the plurality of boilers 11, respectively.

The drain supply pump 31 is arranged upstream of the branched portion of the drain supply line L3, and boosts the pressure of the drain supplied from the drain tank 20 and sends it to the plurality of boilers 11. The drain supply pump 31 is started and stopped by a water supply control device 200, which will be described later.

The drain flow rate control valve 32 is a flow rate control mechanism that can set the opening degree, which is a state quantity that determines the ease with which drain is supplied to the corresponding boiler 11. Each drain flow rate control valve 32 can be configured by, for example, a motor valve or the like. Each drain flow rate control valve 32 is individually controlled by the water supply control device 200 so as to supply an appropriate amount of drain depending on the operating state of the corresponding boiler 11, as will be described in detail later.

The drain flow rate sensor 33 is a flow rate detection section that detects the flow rate of drain supplied to the corresponding boiler 11. Each drain flow rate sensor 33 can be constituted by any flowmeter, such as a mass flow rate sensor or an orifice flow rate sensor.

The pressurized steam line L4 supplies steam directly from the boiler device 10 to the drain tank 20. A supply pressure regulating valve 41 disposed in the pressurized steam line L4 maintains the pressure of steam supplied to the drain tank 20 at a set pressure. This prevents the pressure in the drain tank 20 from becoming lower than the set pressure.

The flash steam line L5 connects the upper space of the drain tank 20 and the open tank 30. In the flash steam line L5, when the pressure in the drain tank 20 becomes higher than the set pressure, the discharge pressure regulating valve 51 opens and discharges the steam in the drain tank 20 to the open tank 30. This prevents the pressure in the drain tank 20 from becoming higher than the set pressure.

Tank makeup water supply line L6 connects open tank 30 and drain tank 20 and supplies water stored in open tank 30 to drain tank 20. The tank water supply pump 61 disposed in the tank makeup water supply line L6 boosts the pressure of water stored in the open tank 30 and sends it out to the plurality of drain tanks 20. This tank water supply pump 61 is started and stopped by the water supply control device 200 so that the water level of the drain tank 20 detected by the drain water level gauge 25 can be maintained within a certain range. Further, the tank water supply amount regulating valve 62 disposed in the tank makeup water supply line L6 restricts the flow rate of makeup water according to the pressure of the drain tank 20, and applies back pressure to the tank water supply pump 61. Specifically, when the pressure of the drain tank 20 is lower than the set pressure, cavitation in the tank water supply pump 61 is prevented by reducing the opening degree so that the flow rate of makeup water is small.

The boiler make-up water supply line L7 supplies make-up water stored in the open tank 30 to the boiler device 10. The upstream end of the boiler make-up water supply line L7 is connected to the lower part of the open tank 30. The downstream side of the boiler make-up water supply line L7 is branched into a plurality of lines so that the ends thereof are connected to the plurality of boilers 11, respectively. When water supply from the drain supply line L3 is insufficient, makeup water is supplied to the boiler device 10 through the boiler makeup water supply line L7.

A plurality of make-up water supply pumps 71 are provided on the downstream side of the boiler make-up water supply line L<b>7 so as to correspond to each boiler 11 .

The make-up water supply pump 71 boosts the pressure of make-up water supplied from the open tank 30 and sends it to the corresponding boiler 11 . The make-up water supply pump 71 is speed-adjustable, and can be configured by, for example, an electric pump driven by an inverter (frequency converter) 72. The output frequency of inverter 72 is controlled by water supply control device 200.

The number control device 100 determines the combustion state of each boiler 11 (including operation/stop and combustion amount during operation) according to the amount of steam used by the load equipment 40. Specifically, the number control device 100 calculates the amount of steam generation required to keep the detected value of the pressure sensor 16 of the steam header 12 substantially constant, and determines the number of operating boilers 11 and the combustion amount. do.

The number control device 100 can be realized by installing an appropriate program into the number control device 100, for example, a computer device having a CPU, memory, and the like.

The water supply control device 200 can be realized, for example, by introducing an appropriate program into a computer device having a CPU, memory, and the like. Further, the water supply control device 200 may be configured integrally with the number control device 100 and the local control unit 15.

Water supply control device 200 controls water supply from drain tank 20 and open tank 30 to boiler device 10 . This water supply control device 200 includes a water supply selection unit 210 that selects either or both of the water supply by the drain supply line L3 and the water supply by the boiler make-up water supply line L7, and the drain supply to the boiler device 10 using the drain supply line L3. and a makeup water flow rate control unit 230 that controls the supply flow rate of makeup water to the boiler apparatus 10 using the boiler makeup water supply line L7. In the water supply control device 200, the water supply selection section 210, the drain flow rate control section 220, and the makeup water flow rate control section 230 are functionally distinct, and even if they cannot be clearly distinguished in their physical configuration and program configuration, good.

The water supply selection unit 210 supplies water to the boiler 11 by selecting water supply from the drain supply line L3 and water supply from the boiler make-up water supply line L7.

When the water supply selection unit 210 selects water supply from the drain supply line L3, the drain flow rate control unit 220 adjusts the corresponding drain flow rate so that the flow rate detected by the drain flow rate sensor 33 approaches the set flow rate target value. The opening degree of the valve 32 is feedback-controlled. In addition, the drain flow rate control unit 220 presets the opening degree of each drain flow rate control valve 32 when the water supply amount instructed by the local control unit 15 and, by extension, the drain flow rate target value determined thereby is changed. Feedback control is started after adjusting to the initial value.

When the drain flow rate target value is changed, the drain flow rate control unit 220 starts feedback control after setting the opening degree of the drain flow rate control valve 32 to an opening degree that matches the initial value set according to the operating conditions. , it is possible to reduce the deviation of the detected value of the drain flow rate sensor 33 from the target drain flow rate value at the time when feedback control is started. The drain flow rate control unit 220 checks the feedback of the opening degree information from the drain flow rate control valve 32 to confirm that the degree of opening of the drain flow rate control valve 32 has become equal to the initial value, and then starts feedback control. Alternatively, the feedback control may be started when the time required for the drain flow rate control valve 32 to operate has elapsed after outputting a signal instructing the initial value to the drain flow rate control valve 32.

That is, in the boiler system 1, once cavitation occurs in the drain supply pump 31, the flow rate of drain becomes very small, so the opening degree of the drain flow rate control valve 32 becomes even larger, and there is a possibility that cavitation cannot be eliminated. However, since the drain flow rate control unit 220 starts feedback control after adjusting the opening degree of the drain flow rate control valve 32 to a preset initial value, the flow rate of the drain supply pump 31 may overshoot at the start of the feedback control. It is possible to prevent cavitation from occurring due to temporary excessive pressure. Thereby, the boiler system 1 can prevent cavitation of the drain supply pump 31 and operate each boiler 11 appropriately.

The initial value of the opening degree of each drain flow rate control valve 32 may always be a constant value, but may be a value set according to the operating pressure (steam pressure) of the corresponding boiler 11 by a predetermined method. It is preferable to do so. Specifically, it is preferable to increase the opening degree of the drain flow rate control valve 32 as the operating pressure of the boiler 11 increases. By setting the initial value of the opening degree of the drain flow rate control valve 32 according to the operating pressure of the boiler 11, which acts as a back pressure to the drain supply pump 31, overshoot of the flow rate can be suppressed more reliably. , cavitation of the drain supply pump 31 can be more reliably prevented. The initial value of the opening degree of each drain flow rate control valve 32 may be set as a function of the operating pressure of the boiler 11, and may be set with reference to a correspondence table that defines values corresponding to the operating pressure categories of the boiler 11. You can.

Further, the initial value of the opening degree of each drain flow rate control valve 32 may be a value that is preset according to the set combustion amount of the corresponding boiler 11. Specifically, it is preferable to increase the opening degree of the drain flow rate control valve 32 as the combustion amount of the boiler 11 increases. By setting the initial value of the opening degree of the drain flow rate control valve 32 according to the set combustion amount of the boiler 11, it is possible to supply drain to the boiler 11 at a flow rate close to the state where the control is stable from the start of the feedback control. . For this reason, even if the local control unit 15 changes the flow rate target value by normal control immediately after starting the feedback control, the flow rate due to an excessive deviation of the actual drain flow rate from the changed drain flow rate target value. By suppressing the overshoot of the drain supply pump 31, cavitation of the drain supply pump 31 can be prevented.

The initial value of the opening degree of each drain flow rate control valve 32 may be set according to only one of the operating pressure and the set combustion amount of the boiler 11, but it may be set according to both the operating pressure and the set combustion amount of the boiler 11. It is preferable to set In this case, the initial value of the opening degree of each drain flow rate control valve 32 may be set as a function (two-variable function) of the operating pressure and set combustion amount of the boiler 11; It may be set with reference to a two-dimensional correspondence table that defines values corresponding to combustion amounts.

The drain flow rate control unit 220 changes from a state in which drain is not supplied to the boiler 11 from the drain supply line L3 and makeup water is supplied to the boiler 11 from the boiler make-up water supply line L7, to supplying drain from the drain supply line L3 to restart the boiler. When switching to a state in which makeup water is not supplied from the makeup water supply line L7, it is preferable to start feedback control after setting the opening degree of the drain flow rate control valve 32 to an initial value. Cavitation of the drain supply pump 31 is particularly likely to occur when the drain flow rate target value of the drain supply line L3 changes in steps with relatively large steps. By setting it to the initial value, cavitation of the drain supply pump 31 can be effectively prevented.

The makeup water flow rate control unit 230 controls the supply of makeup water from the boiler makeup water supply line L7 to each boiler 11 when the water supply selection unit 210 selects the water supply from the boiler makeup water supply line L7.

As described above, in the boiler system 1, the drain flow rate control unit 220 of the water supply control device 200 adjusts the opening degree of the drain flow rate control valve 32 to a preset initial value when the drain flow rate target value is changed. Since the feedback control is started from , the deviation of the detected value of the drain flow rate sensor 33 from the drain flow rate target value at the time of starting the feedback control is reduced, overshoot in the feedback control is suppressed, and cavitation of the drain supply pump 31 is suppressed. can be prevented.

Next, FIG. 2 shows the configuration of a boiler system 1A including a water supply control device 200A according to a second embodiment of the present invention. The boiler system 1 includes a boiler device 10, a drain tank 20, an open tank 30, a number control device 100, and a water supply control device 200A according to an embodiment of the present invention. Boiler system 1A generates steam using boiler device 10 and supplies the steam to load equipment 40 that consumes the steam. The boiler system 1A also includes a steam supply line L1, a drain recovery line L2, a drain supply line L3A, a pressurized steam line L4, a flash steam line L5, a tank makeup water supply line L6, and a boiler makeup water supply line L7. Furthermore, the boiler system 1A includes a steam trap 21 and a check valve 22 provided in the drain recovery line L2, a plurality of drain supply pumps 31A and a drain flow rate sensor 33 provided in the drain supply line L3A, and a pressurized steam line L4. a supply pressure regulating valve 41 provided in the flash steam line L5, a discharge pressure regulating valve 51 provided in the flash steam line L5, a tank water supply pump 61 and a tank water supply amount regulating valve 62 provided in the tank makeup water supply line L6, and a boiler makeup water supply A plurality of make-up water supply pumps 71 are provided in the line L7. In the boiler system 1A of FIG. 2, the same components as those of the boiler system of FIG.

The drain supply line L3A supplies the drain collected in the drain tank 20 to the boiler device 10. The upstream end of the drain supply line L3A is connected to the lower part of the drain tank 20. The downstream side of the drain supply line L3 is branched into a plurality of lines so that the ends thereof are connected to the plurality of boilers 11, respectively. The drain supply pump 31A and the drain flow rate sensor 33 are arranged in correspondence with the respective boilers 11 on the downstream side of the branch part in the drain supply line L3.

The drain supply pump 31A can be speed-adjusted, and can be configured by, for example, an electric pump driven by an inverter (frequency converter) 36. The output frequency of the inverter 34 in the drain supply pump 31A is a state quantity that determines the ease with which drain flows. That is, the inverter 34 is a flow rate adjustment mechanism that is arranged in the drain supply line L3A and can set an output frequency, which is a state quantity that determines the ease with which drain flows.

The drain flow rate control unit 220A performs feedback control on the speed of the corresponding drain supply pump 31A (output frequency of the inverter 34) so that the flow rate detected by the drain flow rate sensor 33 approaches the set flow rate target value. Furthermore, when the drain flow rate target value determined by the water supply amount instructed by the local control unit 15 is changed, the drain flow rate control unit 220 adjusts the speed of each drain supply pump 31A to a preset initial value. Start feedback control from . In other words, the drain flow rate control section 220A of the feed water control device 200A in the boiler system 1A of FIG. The opening degree is changed to the speed of the drain supply pump 31A, and the control contents can be the same.

In the boiler system 1A of FIG. 2, when the drain flow rate target value is changed, the drain flow rate control unit 220A of the water supply control device 200A adjusts the speed of the drain supply pump 31A to a preset initial value and then performs feedback control. Therefore, the deviation of the detected value of the drain flow rate sensor 33 from the target drain flow rate value at the time of starting the feedback control is reduced to suppress overshoot in the feedback control and prevent cavitation of the drain supply pump 31A. I can do it.

Although preferred embodiments of the water supply control device of the present invention have been described above, the present invention is not limited to the embodiments described above, and can be modified as appropriate.

For example, in the first embodiment and the second embodiment, the boiler systems 1 and 1A were configured to include the boiler device 10 having three boilers 11, but the water supply control device of the present invention has one or two boilers. Alternatively, the present invention can also be applied to a boiler system equipped with a boiler device having four or more boilers.

Moreover, the pressurized steam line L4, the flash steam line L5, and the tank makeup water supply line L6 in the first embodiment each have an arbitrary configuration and can be omitted.

In the above-described embodiment, the flow rate target value has two values: zero or minimum flow rate when the water level of the boiler 11 is above a predetermined upper limit, and a predetermined value when the water level of the boiler 11 is below a predetermined lower limit. However, the flow rate target value may be continuously changed by, for example, feedback control based on the deviation between the set water level and the actual water level so as to keep the water level of the boiler 11 constant.

In the embodiment described above, the water supply selection unit 210 selects either the drain water supply from the drain supply line L3 or the makeup water supply from the boiler makeup water supply line L7; The drain water supply from the supply line L3 and the makeup water supply from the boiler makeup water supply line L7 may be performed simultaneously. In this case, the water supply selection unit 210 selects the amount of water to be supplied to each boiler 11 instructed by the local control unit 15 based on the target value of the drain flow rate of the drain supply line L3 (drain flow rate target value) and the boiler make-up water supply line L7. The target value of the make-up water flow rate (make-up water flow rate target value) can be configured to be distributed to the make-up water flow rate target value.

In the above-described embodiment, the boiler make-up water supply line L7 is provided with the speed-adjustable make-up water supply pump 71, but similarly to the drain supply line L3, the boiler make-up water supply line L7 is connected to the branch part of the boiler make-up water supply line L7. Alternatively, a make-up water supply pump may be arranged on the upstream side and the flow rate may be controlled by a flow rate control valve.

1, 1A boiler system 10 boiler device 11 boiler 20 drain tank 30 open tank 31, 31A drain supply pump 32 drain flow rate control valve (flow rate control mechanism)
33 Drain flow rate sensor (flow rate detection part)
34 Inverter (flow rate adjustment mechanism)
40 Load equipment 200, 200A Water supply control device 210 Water supply selection section 220, 220A Drain flow rate control section 230 Makeup water flow rate control section L1 Steam supply line L2 Drain recovery line L3, L3A Drain supply line L7 Boiler makeup water supply line

Claims (1)

A boiler that generates steam and supplies it to load equipment;
a drain tank that collects drain generated by condensing steam in the load equipment without releasing it to the atmosphere;
a drain supply line that supplies the drain collected in the drain tank to the boiler;
a makeup water supply line that supplies makeup water to the boiler;
a drain supply pump disposed in the drain supply line and configured to send out the drain from the drain tank;
a flow rate adjustment mechanism disposed in the drain supply line and capable of setting a state quantity that determines the ease with which the drain flows;
a flow rate detection unit that detects the flow rate of the drain;
A water supply control device for controlling water supply of a boiler system comprising:
a flow rate control unit that feedback-controls the state quantity of the flow rate adjustment mechanism so that the flow rate detected by the flow rate detection unit approaches a set flow rate target value;
The flow rate control unit supplies the drain from the drain supply line to supply the makeup water from a state in which the drain is not supplied to the boiler from the drain supply line and makeup water is supplied from the makeup water supply line. When the state is switched to not supply makeup water from the line, the state quantity of the flow rate adjustment mechanism is set to a constant value, or to an initial value set to a value that allows the drain to flow more easily as the operating pressure or set combustion amount increases. A water supply control device that starts the feedback control after matching.

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