JP6277683B2 - Boiler system - Google Patents

Description

  The present invention relates to a boiler system having a feed water heater for heating feed water supplied to a boiler.

  Conventionally, in boiler systems, boiler efficiency is improved by preheating water supplied before being supplied to the boiler with a water heater (also referred to as “economizer”) (see Patent Document 1). ). An economizer is a device that heats feed water by exchanging heat between exhaust gas (waste heat) discharged from a boiler or the like and feed water supplied to the boiler.

JP 2012-002385 A

  In general, in a boiler system, when the water level of the boiler body (can body) falls to the lower limit water level (target water level control start water level), the supply of water supply starts, and when the water level of the boiler body rises to the upper limit water level (target water level) In other words, so-called on-off control is performed to stop the supply of water. In such on-off control, the feed water is not supplied unless the water level of the boiler body is lowered to the lower limit water level, so the water staying in the economizer is heated by the exhaust gas to a high temperature until the feed water is supplied. Become.

  In particular, the target water level becomes lower than the current water level, such as when the water level of the boiler body is shifted from a high state to a high load state due to a low load state, or when steaming from a low steam pressure state. In this case, the state where there is no water supply request continues. In that case, the time during which water stays in the economizer becomes longer.

  When the time during which hot water stays in the economizer becomes longer, the water tends to boil due to the heat of the exhaust gas. Further, when high-temperature water exceeding 100 ° C. is supplied as water supply, and high-temperature water stays in the economizer, the water staying in the economizer may reach the saturation temperature and boil. If water staying in the economizer boils, there is a possibility that the supply efficiency of the water supply will be reduced due to pressure loss (water supply will be delayed), or that the economizer piping will be damaged due to the effects of vibration and pressure fluctuations. is there.

  An object of the present invention is to provide a boiler system capable of suppressing boiling of high-temperature water staying in a feed water heater during combustion of the boiler.

The present invention includes a boiler having a feed water heater that heats feed water to the boiler by exhaust gas, a feed water line that feeds feed water to the boiler via the feed water heater, and upstream of the feed water heater in the feed water line A feed water flow rate adjusting unit that adjusts the flow rate of feed water supplied to the feed water heater, and is arranged downstream of the feed water heater in the feed water line, and is supplied from the feed water heater to the boiler A feed water temperature detector that detects the temperature of the feed water that flows outside the feed water heater, and a controller that controls the feed water flow rate adjuster, the controller from the boiler When there is no water supply request and the state where the temperature of the water supply detected by the water supply temperature detection unit is equal to or higher than a reference temperature continues for a set time or longer, the water supply is supplied to the water heater. To control the water supply flow rate adjusting unit, to the boiler system.

  Further, it is preferable that the reference temperature is a temperature lower than a saturation temperature calculated from a set target pressure of the boiler by a predetermined temperature.

  In addition, a water level detection unit that detects a water level inside the boiler is provided, and the control unit has no water supply request from the boiler, and the temperature of the feed water detected by the feed water temperature detection unit is equal to or higher than the reference temperature. When the water level detected by the water level detection unit is lower than or equal to a target water level control start water level, the water supply flow rate adjustment unit is controlled to supply water to the water heater. It is preferable.

  Moreover, it is preferable to collect | recover the drain discharged | emitted from the load apparatus which uses the generated steam of the said boiler by a closed system, and to utilize again the collected drain as water supply to the said boiler.

  ADVANTAGE OF THE INVENTION According to this invention, the boiler system which can suppress that the high temperature water which retains in a feed water heater boils during combustion of a boiler can be provided.

1 is an overall configuration diagram of a boiler system 1 according to an embodiment. It is a flowchart which shows operation | movement of the boiler system 1 of 1st Embodiment. It is a time chart which shows operation | movement of the boiler system 1 of 1st Embodiment. It is a flowchart which shows operation | movement of the boiler system 1 of 2nd Embodiment. It is a time chart which shows operation | movement of the boiler system 1 of 2nd Embodiment.

[Configuration of First Embodiment]
Hereinafter, a boiler system according to a first embodiment of the present invention will be described with reference to the drawings. FIG. 1 is an overall configuration diagram of a boiler system 1 according to the first embodiment. FIG. 2 is a flowchart showing the operation of the boiler system 1 of the first embodiment. FIG. 3 is a time chart showing the operation of the boiler system 1 of the first embodiment.

  As shown in FIG. 1, the boiler system 1 according to the first embodiment includes a boiler 2, a steam header 4, a load device 5, a drain tank 6, and a makeup water tank 7. The boiler 2 includes an economizer 3 as a feed water heater. The economizer 3 is provided in a water supply line L <b> 1 described later, and is a facility that preheats the water supply W <b> 1 before being supplied to the boiler 2 by waste heat of exhaust gas generated when fuel is burned in the boiler 2.

  Moreover, the boiler system 1 is provided with the feed water pump 8, the control part 10, the feed water flow rate adjustment valve 11 as a feed water flow rate adjustment part, and the feed water temperature sensor 12 as a feed water temperature detection part. In FIG. 1, a path of electrical connection is indicated by a broken line.

  Further, the boiler system 1 includes a water supply line L1, a fuel supply line L2, a steam supply line L3, a drain line L4, a makeup water line L5, a flash steam discharge line L6, a makeup water introduction line L7, and a water supply A reflux line L8. The “line” in the present specification is a general term for lines capable of flowing a fluid such as a flow path, a radial path, and a pipeline.

  Each line is provided with devices such as various valves, various sensors, check valves, orifices, strainers and the like as necessary, but the illustration is omitted as appropriate in FIG.

  The water supply line L <b> 1 is a line that supplies the water supply W <b> 1 stored in the drain tank 6 toward the boiler 2 via the economizer 3. The upstream end of the water supply line L <b> 1 is connected to the water supply / discharge port of the drain tank 6. The downstream end of the water supply line L <b> 1 is connected to the water supply inlet of the boiler 2. The water supply line L1 is provided with a water supply pump 8, a water supply flow rate adjustment valve 11, and a water supply temperature sensor 12.

  The feed water pump 8 is a device that sucks in the feed water W <b> 1 and discharges it toward the boiler 2. A motor (not shown) provided in the water supply pump 8 is electrically connected to the control unit 10 and is controlled and driven based on a control signal from the control unit 10.

  The water supply flow rate adjustment valve 11 is a valve that is arranged downstream of the water supply pump 8 and upstream of the economizer 3 in the water supply line L1 and can adjust the flow rate of the water supply W1 supplied to the economizer 3. The feed water flow rate adjustment valve 11 is electrically connected to the control unit 10. The valve opening degree of the feed water flow rate adjustment valve 11 (the opening degree of the valve element) is controlled by a drive signal from the control unit 10.

  The boiler 2 is equipment for heating the feed water W1 supplied from the drain tank 6 to generate steam W2. The boiler 2 includes a boiler body 21 which is a can body, a water level sensor 25 as a water level detection unit, and an economizer 3 as a feed water heater.

The boiler body 21 includes a lower header, a water tube, an upper header, a burner, and the like (all not shown).
The upper header is a hollow container formed in an annular shape. The upper end of each water pipe communicates with the upper header. The upstream end of the steam supply line L3 is connected to the upper end of the upper header. The steam W2 generated in the plurality of water pipes is sent to the steam supply line L3 through the upper header. The steam supply line L3 is a line for supplying the load W 5 with the steam W2 generated in the water pipe. The downstream end of the steam supply line L <b> 3 is connected to the load device 5.

  A burner part is a combustion apparatus which burns fuel (liquid or gas etc.). A fuel supply line L2 is connected to the burner portion. The fuel supply line L2 is a line for supplying fuel delivered from a fuel supply source (not shown) to the burner unit.

  The water level sensor 25 is a device that detects the water level inside the boiler body 21. The water level sensor 25 is electrically connected to the control unit 10. The water level inside the boiler body 21 detected by the water level sensor 25 (hereinafter also referred to as “water level Hd”) is transmitted to the control unit 10 as a detection signal.

  The economizer 3 is a facility that is provided in the feed water line L1 and preheats the feed water W1 before being supplied to the boiler 2 by waste heat of exhaust gas generated when fuel is burned in the boiler 2. The water supply W1 heated by the economizer 3 is supplied into the boiler body 21 of the boiler 2 through the water supply line L1.

  The feed water temperature sensor 12 is disposed on the downstream side of the economizer 3 in the feed water line L1, and the temperature of the feed water W1 (the feed water W1 supplied from the economizer 3 to the boiler 2) that circulates downstream from the economizer 3 in the feed water line L1. Is a device that detects In other words, the feed water temperature sensor 12 is a device that detects the temperature of the feed water W1 flowing between the economizer 3 and the boiler body 21 in the feed water line L1. The feed water temperature sensor 12 is connected to the feed water line L1 at the connection portion J2. The connecting portion J2 is disposed between the economizer 3 and the boiler body 21. The feed water temperature sensor 12 is electrically connected to the control unit 10. The temperature of the feed water W1 detected by the feed water temperature sensor 12 (hereinafter also referred to as “feed water temperature Td”) is transmitted to the control unit 10 as a detection signal.

  The steam header 4 is a device that temporarily accumulates the steam W2 supplied from the boiler 2 via the steam supply line L3 and supplies the steam W2 to the load device 5 that uses the steam W2. The steam header 4 is provided between the boiler 2 and the load device 5 in the steam supply line L3.

  The load device 5 is a device (for example, a heat exchanger) that is operated by the steam W2 supplied from the boiler 2. The steam W2 used in the load device 5 is deprived of heat and condensed to be discharged as drain W3. The drain W3 discharged from the load device 5 is collected in the drain tank 6 through the drain line L4.

  The drain line L4 is a line for sending the drain W3 discharged from the load device 5 to the drain tank 6. The upstream end of the drain line L4 is connected to the drain discharge port of the load device 5. The downstream end of the drain line L4 is connected to the drain inlet of the drain tank 6. The drain line L4 is provided with a steam trap (not shown) that removes steam contained in the drain W3.

  The drain tank 6 is a sealed tank that stores water supply W <b> 1 supplied to the boiler 2. The drain tank 6 stores high-temperature and high-pressure drain W3 discharged from the load device 5. The lower end (water supply discharge port) of the drain tank 6 is connected to the upstream end of the water supply line L1. The drain tank 6 is a supply source of the feed water W1 to the boiler 2.

  That is, in the boiler system 1 according to the first embodiment, the high-temperature and high-pressure drain W3 discharged from the load device 5 and collected in the sealed drain tank 6 is supplied (utilized) again to the boiler 2 as the feed water W1. A drain recovery system of the type.

  The makeup water tank 7 is a facility for replenishing the drain tank 6 with water supply W1. The drain tank 6 and the makeup water tank 7 are connected by a makeup water line L5. The makeup water line L5 is a line for replenishing the drain water 6 with the feed water W1 when the flow rate of the feed water W1 supplied from the drain tank 6 to the boiler 2 is large. The upstream end of the makeup water line L5 is connected to the water supply supply port of the makeup water tank 7. The downstream end of the makeup water line L5 is connected to the water supply inlet of the drain tank 6.

  The makeup water line L5 is provided with a pressurizing pump or the like (not shown). The pressurizing pump provided in the makeup water line L5 is electrically connected to the control unit 10. When the water level of the drain tank 6 decreases to the lower limit water level, the pressurizing pump is driven by the control unit 10, and the supply water W <b> 1 is supplied from the makeup water tank 7 to the drain tank 6.

  The drain tank 6 (gas phase section) and the makeup water tank 7 are connected by a flash steam discharge line L6. The flash steam discharge line L6 is a line for discharging the flash steam generated inside the drain tank 6. The upstream end of the flash steam discharge line L6 is connected to the flash steam discharge port of the drain tank 6. The downstream end of the flash steam discharge line L <b> 6 is connected to the flash steam inlet of the makeup water tank 7.

  A makeup water introduction line L 7 for introducing (supplying) the feed water W 1 to the makeup water tank 7 is connected to the lower portion of the makeup water tank 7. The upstream end of the makeup water introduction line L7 is connected to a supply source (not shown) of the feed water W1. The downstream end of the make-up water introduction line L7 is connected to the water supply / supply port of the make-up water tank 7.

  A water supply recirculation line L8 is connected to the water supply line L1. The feed water recirculation line L8 is a line for returning a part of the feed water W1 flowing through the feed water line L1 to the drain tank 6 when supply of the feed water W1 to the boiler 2 is unnecessary. The upstream end of the feed water recirculation line L8 is connected to the feed water line L1 at the connection portion J1. The connecting portion J1 is disposed between the feed water pump 8 and the feed water flow rate adjustment valve 11 in the feed water line L1. The downstream end of the feed water reflux line L8 is connected to the feed water reflux port of the drain tank 6.

  The control unit 10 is configured by a microprocessor (not shown) including a CPU and a memory. The microprocessor incorporates an integrated timer unit (hereinafter also referred to as “ITU”) that manages time measurement and the like. Further, a control program and various data necessary for controlling the boiler system 1 are stored in the memory of the microprocessor. For example, a water supply request status to be described later is stored as rewritable data in the memory of the microprocessor.

  When the supply of the water supply W1 to the boiler 2 is necessary (for example, when there is a water supply request from the boiler 2), the control unit 10 supplies the boiler 2 with a predetermined amount of water supply W1. The flow rate of the feed water flow rate adjustment valve 11 is controlled. By this control, the boiler 2 is supplied with a predetermined amount of water supply W1.

  The control unit 10 determines the combustion state of the fuel in the boiler 2 based on the amount of steam consumed by the load device 5, the pressure of the steam inside the steam header 4, and the like (for example, 1 to 3 stages). (Or stepless) and combustion stop state.

  In the control unit 10, the status related to the water supply request (hereinafter also referred to as “water supply request status”) is changed based on the detection signal related to the water level Hd inside the boiler body 21 transmitted from the water level sensor 25. Specifically, when the water level Hd inside the boiler body 21 falls below the target water level control start water level HL that is the lower limit water level, the control unit 10 changes the water supply request status to the water supply request ON. In addition, when the water level Hd inside the boiler body 21 rises to the target water level Hh that is the upper limit water level, the water supply request status is changed to the water supply request OFF in the control unit 10.

  As shown in FIGS. 2 and 3, the control unit 10 uses the temperature of the feed water detected by the feed water temperature sensor 12 (also referred to as “feed water temperature Td”) as a reference even when there is no feed water request from the boiler 2. When the temperature Tk or higher continues for the set time Xs or longer, the water supply flow rate adjustment valve 11 is controlled so as to supply the water supply W1 to the economizer 3. The reference temperature Tk is a temperature that is a predetermined temperature Ts lower than the saturation temperature Th calculated from the control target pressure setting value (set target pressure) of the boiler, and is appropriately set. The control target pressure set value is appropriately set according to the required pressure. The predetermined temperature Ts is, for example, 5 to 20 ° C.

  The set time Xs is set as appropriate. The set time Xs is converted when the burner part of the boiler 2 burns 100%. For example, when the set time Xs is 25 seconds at 100% combustion, if the 100% combustion is performed for 10 seconds and 50% combustion is performed for 30 seconds, the set time Xs is also 25 seconds (25 seconds = 10 seconds + 30 seconds) X (50% / 100%)).

  The controller 10 determines whether or not the temperature of the water supply W1 (water supply temperature Td) detected by the water supply temperature sensor 12 is equal to or higher than the reference temperature Tk (also referred to as “reference temperature higher than state”). When the control unit 10 determines that the state is equal to or higher than the reference temperature, the ITU incorporated in the microprocessor of the control unit 10 measures the duration of the state that is equal to or higher than the reference temperature as “continuous time higher than the reference temperature”. To start. In addition, the control unit 10 determines whether or not the continuation time above the reference temperature continues for a predetermined set time Xs. When it is determined that the continuation time above the reference temperature has continued for the predetermined set time Xs or more, the control unit 10 changes the water supply request status to the water supply request ON. By this control, the boiler 2 is supplied with a predetermined amount of water supply W1.

The control unit 10 can perform constant flow control as normal water supply control. In the constant flow control, the water level Hd detected by the water level sensor 25 is calculated based on the combustion state of the burner portion of the boiler 2, the feed water temperature Td, the electrical conductivity of the feed water W1, the pressure of the steam inside the boiler 2, and the like. Control to turn on / off the feed water by setting the feed water flow rate adjustment valve 11 to a constant flow rate opening degree or a fully closed state that is appropriately changed by the pressure of the boiler 2 so as to approach the target water level Hh. Control to be performed).
In addition, continuous water supply control is also employable as normal water supply control. In the continuous water supply control, the feed water W1 is continuously supplied to the boiler 2 by adjusting the valve opening of the water supply flow rate adjustment valve 11 and the drive of the water supply pump 8 so that the water level Hd approaches the target water level Hh. Control.

[Operation of First Embodiment]
Next, in the boiler system 1 which concerns on this embodiment, the operation | movement which controls the feed water W1 according to the temperature (feed water temperature Td) of the feed water W1 is demonstrated, referring drawings.

  First, the normal water supply operation by the normal water supply control will be described. When the water level Hd inside the boiler body 21 falls to the target water level control start water level HL that is the lower limit water level, the water supply request status is changed to the water supply request ON in the control unit 10. In this state, the control unit 10 controls the valve opening degree of the feed water flow rate adjustment valve 11 so that the boiler 2 is supplied with the feed water W1 having a predetermined feed water amount. In this embodiment, the valve opening degree of the feed water flow rate adjustment valve 11 is controlled to be a constant flow rate opening degree that is appropriately changed according to the pressure of the boiler 2. By this control, the boiler 2 is supplied with a predetermined amount of water supply W1.

  On the other hand, when the water level inside the boiler main body 21 rises to the target water level Hh, which is the upper limit water level, the control unit 10 changes the water supply request status to the water supply request OFF. When the water supply request status is changed to water supply request OFF, the valve opening degree of the water supply flow rate adjustment valve 11 is controlled so that the water supply W1 is not supplied to the boiler 2. At this time, the valve opening degree of the feed water flow rate adjustment valve 11 is controlled to be fully closed.

  Next, an operation of controlling the feed water W1 according to the temperature of the feed water W1 (feed water temperature Td), which is a characteristic operation of the boiler system 1 of the first embodiment, will be described.

  As shown in FIG. 2, in step ST101, the control unit 10 determines whether or not there is a water supply request. If there is a water supply request (NO), the process proceeds to step ST121. If there is no water supply request (YES), the process proceeds to step ST102.

  If there is a water supply request (NO), in step ST121, the control unit 10 starts normal water supply control. By this control, the supply operation of the water supply W1 to the boiler 2 shifts to the normal water supply operation. The process returns to step ST101.

  As shown in FIG.2 and FIG.3, when there is no water supply request | requirement (YES), in step ST102, the control part 10 WHEREIN: The temperature (water supply temperature Td) of the water supply W1 detected by the water supply temperature sensor 12 is reference | standard. It is determined whether or not the temperature is higher than Tk. If the feed water temperature Td is equal to or higher than the reference temperature Tk (YES), the process proceeds to step ST103. If the feed water temperature Td is lower than the reference temperature Tk (NO), the process returns to step ST102.

  In step ST <b> 103, the control unit 10 starts measuring time by setting the duration of the state above the reference temperature (the state where the feed water temperature Td is above the reference temperature Tk) as “the duration above the reference temperature”. The process proceeds to step ST104. In FIG. 3, the time when the feed water temperature Td becomes the reference temperature Tk is indicated by “Xk”.

  In step ST104, the control part 10 determines again whether there exists any water supply request | requirement. If there is no water supply request (YES), the process proceeds to step ST105. If there is a water supply request (NO), the process proceeds to step ST121.

  Next, in step ST105, the control unit 10 determines whether or not a continuation time above the reference temperature continues for a predetermined set time Xs or more. If the continuation time above the reference temperature continues for a predetermined set time Xs (YES), the process proceeds to step ST111. If the continuation time above the reference temperature does not continue for the predetermined set time Xs (NO), the process returns to step ST104. In FIG. 3, “Xp” indicates the time at which the set time Xs has elapsed for the duration above the reference temperature.

  In step ST111, the control unit 10 changes the water supply request status to the water supply request ON. By this control, the boiler 2 is supplied with a predetermined amount of water supply W1 (ON operation).

  Next, in step ST112, after the water supply request status is changed to water supply request ON and a predetermined ON operation time Xd has elapsed, the control unit 10 starts normal water supply control. In FIG. 3, the ON operation time is indicated by “Xd”. By this control, the supply operation of the water supply W1 to the boiler 2 shifts to the normal water supply operation. The process returns to step ST101.

  According to the boiler system 1 which concerns on 1st Embodiment mentioned above, the following effects are acquired, for example.

  In the boiler system 1 according to the first embodiment, the control unit 10 is in a state where there is no water supply request from the boiler 2 and the temperature Td of the feed water W1 detected by the feed water temperature sensor 12 is equal to or higher than the reference temperature Tk. When continuing, the water supply flow rate adjustment valve 11 is controlled so as to supply the water supply W1 to the economizer 3. Therefore, the state where the temperature Td of the water supply W1 inside the economizer 3 is equal to or higher than the reference temperature Tk, that is, the water supply W1 inside the economizer 3 is prevented from staying in the economizer 3 for a long time in a state where it is likely to boil. The As a result, it is possible to suppress boiling of high-temperature water staying inside the economizer 3 during the combustion of the boiler 2. In particular, when the water level Hd exceeds the target water level Hh, it takes a long time for the water level Hd to become equal to or lower than the target water level control start water level HL, so this control according to the first embodiment is effective.

  Further, in the closed boiler system 1 as in the first embodiment, the drain W3 is very hot, so the water supply W1 to the economizer 3 is also likely to be hot. That is, the feed water W1 staying inside the economizer 3 is likely to boil. Therefore, the control according to the first embodiment is particularly effective for a closed boiler system.

[Second Embodiment]
Next, a second embodiment of the present invention will be described focusing on differences from the first embodiment. For this reason, the same code | symbol is attached | subjected about the same (or equivalent) structure as 1st Embodiment, and detailed description is abbreviate | omitted. The description of the first embodiment is appropriately applied to points that are not particularly described in the second embodiment. The second embodiment is mainly different from the first embodiment in the configuration of the control unit 10.

As described above, the control unit 10 according to the first embodiment has a set time Xs in which there is no water supply request from the boiler 2 and the temperature of the water supply (water supply temperature Td) detected by the water supply temperature sensor 12 is equal to or higher than the reference temperature Tk. When continuing, the water supply flow rate adjustment valve 11 is controlled so as to supply water to the economizer 3.
In contrast, the control unit 10 according to the second embodiment is configured to supply water to the economizer 3 only when the state where the water supply temperature Td is equal to or higher than the reference temperature Tk continues for the set time Xs or longer. When the water level Hd detected by the water level sensor 25 is equal to or lower than the target water level control start water level HL, the water supply flow rate adjustment valve 11 is controlled to supply water to the economizer 3.

  The control part 10 in 2nd Embodiment determines whether the water level Hd detected by the water level sensor 25 is below the target water level control start water level HL. In the control unit 10 according to the second embodiment, the water level Hd detected by the water level sensor 25 is the target water level control start water level HL even when the state where the feed water temperature Td is equal to or higher than the reference temperature Tk continues for the set time Xs or longer. Only when it is the following, the water supply request status is changed to water supply request ON. By this control, the boiler 2 is supplied with a predetermined amount of water supply W1.

[Operation of Second Embodiment]
Next, in the boiler system 1 according to the second embodiment, an operation for controlling the feed water W1 according to the temperature of the feed water W1 (feed water temperature Td) and the water level Hd will be described with reference to the drawings. FIG. 4 is a flowchart showing the operation of the boiler system of the second embodiment. FIG. 5 is a time chart showing the operation of the boiler system of the second embodiment.

Step ST201 to step ST205, step ST211, step ST212, and step ST221 in the operation of the second embodiment are the same as step ST101 to step ST105, step ST111, step ST112, and step ST221 in the operation of the first embodiment, respectively. Therefore, the operation of the second embodiment will be described focusing on step ST206.
As shown in FIGS. 4 and 5, in step ST205, when the continuation time above the reference temperature has continued for a predetermined set time Xs (YES), the process proceeds to step ST206.

  In step ST206, the control unit 10 determines whether or not the water level Hd detected by the water level sensor 25 is equal to or lower than the target water level control start water level HL. If the water level Hd is equal to or lower than the target water level control start water level HL (YES), the process proceeds to step ST211. When the water level Hd exceeds the target water level control start water level HL (NO), the process returns to step ST206. In FIG. 5, the time when the water level Hd becomes the target water level control start water level HL is indicated by “XL”.

  In step ST211, the control unit 10 changes the water supply request status to the water supply request ON. By this control, the boiler 2 is supplied with a predetermined amount of water supply W1 (ON operation).

  Next, in step ST212, after the water supply request status is changed to water supply request ON and a predetermined ON operation time Xd has elapsed, the control unit 10 starts normal water supply control. In FIG. 5, the ON operation time is indicated by “Xd”. By this control, the supply operation of the water supply W1 to the boiler 2 shifts to the normal water supply operation. The process returns to step ST201.

  According to the boiler system 1 according to the second embodiment described above, the following effects are obtained in addition to the same effects as the effects of the first embodiment.

  In the boiler system 1 according to the second embodiment, the control unit 10 is in a state where there is no water supply request from the boiler 2 and the temperature Td of the feed water W1 detected by the feed water temperature sensor 12 is equal to or higher than the reference temperature Tk. Further, when the water level Hd detected by the water level sensor 25 is equal to or lower than the target water level control start water level HL, the water supply flow rate adjustment valve 11 is controlled so as to supply water to the economizer 3. Therefore, in the second embodiment, there is no water supply request from the boiler 2 and the state where the temperature Td of the water supply W1 detected by the water supply temperature sensor 12 is equal to or higher than the reference temperature Tk continues for the set time Xs or more, and the water level sensor 25 When the water level Hd detected by the above is equal to or lower than the target water level control start water level HL, control different from normal water supply control, for example, whether the normal water supply control is constant flow rate water supply control or continuous water supply control. The constant flow rate water supply control can be performed forcibly.

The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and can be implemented in various forms.
In the said embodiment, although the one control part 10 is controlling the feed water pump 8 and the feed water flow regulating valve 11, it is not restrict | limited to this. For example, a combustion control unit that controls combustion of the boiler and a water supply control unit that controls water supply to the boiler (including drain recovery) are provided separately, and the combustion control unit controls the water supply flow rate adjustment valve 11 to supply water. The control unit can also control the water supply pump 8.

The exhaust gas that heats the economizer 3 is not limited to the exhaust gas from the boiler 2, and may be, for example, exhaust gas from an engine of another facility.
The feed water flow rate adjustment unit is not limited to a valve (valve), and may be a pump capable of adjusting the flow rate, for example.
Although the said embodiment was a closed boiler system, it is not restricted to this, An open boiler system may be sufficient.

1 Boiler system 2 Boiler 3 Economizer (feed water heater)
6 Drain tank 8 Water supply pump 10 Control unit 11 Water supply flow rate adjustment valve (Water supply flow rate adjustment unit)
12 Water temperature sensor (Water temperature detector)
L1 Water supply line W1 Water supply W2 Steam W3 Drain

Claims (4)

A boiler having a feed water heater that heats feed water to the boiler by exhaust gas;
A water supply line for supplying water to the boiler via the water heater;
A water supply flow rate adjusting unit that is arranged upstream of the water supply heater in the water supply line and adjusts the flow rate of water supplied to the water supply heater,
A feed water temperature detector that is disposed downstream of the feed water heater in the feed water line and detects feed water temperature supplied from the feed water heater to the boiler and flowing outside the feed water heater. When,
A control unit for controlling the feed water flow rate adjustment unit,
The control unit supplies water to the feed water heater when there is no feed water request from the boiler and the temperature of the feed water detected by the feed water temperature detecting unit is higher than a reference temperature for a set time or longer. A boiler system that controls the feed water flow rate adjustment unit.   The boiler system according to claim 1, wherein the reference temperature is a temperature lower than a saturation temperature calculated from a set target pressure of the boiler by a predetermined temperature. A water level detector for detecting the water level inside the boiler,
In the control unit, a state where there is no water supply request from the boiler and the temperature of the water supply detected by the water supply temperature detection unit is equal to or higher than the reference temperature continues for the set time or more, and is further detected by the water level detection unit. The boiler system according to claim 1 or 2, wherein when the water level is equal to or lower than a target water level control start water level, the feed water flow rate adjusting unit is controlled so as to supply feed water to the feed water heater.   The boiler in any one of Claims 1-3 which collect | recovers the drain discharged | emitted from the load apparatus which uses the generated steam of the said boiler by a closed system, and uses again the collect | recovered drain as water supply to the said boiler. system.

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