JP2020020543A - By-product gas utilization system - Google Patents

Abstract

To provide a boiler system capable of being stably operated and properly consuming a hydrogen gas even when a supply amount of the hydrogen gas is changed.SOLUTION: In a boiler system 1 in which a minimum gas consumption amount as a gas consumption amount in a minimum combustion state is determined in a plurality of boilers 20, and which includes a number control device 50 for controlling a consumption amount of hydrogen gas in a boiler group 2 so that a pressure value inside a secondary-side hydrogen tank 30 is agreed with a target pressure value determined within a predetermined pressure value range, the number control device 50 makes the boiler 20 burn with the minimum gas consumption amount until the pressure value inside the secondary-side hydrogen tank 30 becomes lower than a predetermined lower limit pressure value, even when a necessary gas consumption amount becomes lower than the minimum gas consumption amount.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a by-product gas utilization system. More specifically, for example, the present invention relates to a by-product gas utilization system including a combustion device such as a boiler that uses only by-product gas generated from product by-products such as plant equipment as a fuel gas.

  In a plant or the like in which a boiler system is installed, for example, hydrogen gas (hereinafter, also referred to as “by-product gas”) may be generated as a by-product gas during operation of the plant. Therefore, a boiler system using hydrogen gas (by-product gas) generated in a plant as a part of fuel has been proposed (for example, see Patent Document 1).

JP 2017-40444 A

In Patent Document 1, in a boiler group 2 including a plurality of once-through boilers 20, a first fuel gas supply line L1 for supplying a first fuel gas (for example, a hydrocarbon gas such as 13A or LPG) to each of the once-through boilers 20 is provided. A boiler system 1 provided with a hydrogen gas supply line L2 for supplying a by-product gas (hydrogen gas) to each of the once-through boilers 20 and a number control device 50 is described. Here, the boiler system 1 described in Patent Literature 1 is capable of co-combustion using a mixed gas of a first fuel gas and a by-product gas as a fuel gas, and firing a plurality of fuels using only the first fuel gas as a fuel gas. It consists of a once-through boiler.
Then, based on the steam pressure of the steam header 40, the number control device 50 of the boiler system 1 calculates the required combustion amount of the boiler group 2 according to the required load and the combustion state of the plurality of once-through boilers 20 corresponding to the required combustion amount. By controlling the opening / closing or opening of the first fuel gas supply valve 61 and the hydrogen gas supply valve 62 in accordance with the calculated combustion state of the plurality of once-through boilers 20, The supply amount of the fuel gas (the first fuel gas and the by-product gas) is adjusted, and the combustion state of the plurality of once-through boilers 20 is controlled. For this reason, the amount of consumption of the by-product gas in the boiler system 1 depends on the vapor pressure of the steam header 40, and it is not always possible to consume all the by-product gas generated in the production of products from the plant equipment.
More specifically, in the first embodiment described in Patent Literature 1, the number control device 50 (the hydrogen supply control unit 521) includes, for example, the inside of the hydrogen holder 30 that stores hydrogen gas as a by-product gas. When the pressure is P1 or higher, the number of the once-through boilers 20 for supplying the by-product gas (hydrogen gas) is four, and when the pressure is lower than P1 and higher than P2, the once-through boiler 20 for supplying the by-product gas (hydrogen gas) is used. When the pressure is less than P2 and P3 or more, there are two through-flow boilers 20 that supply hydrogen gas. When the pressure is less than P3 and P4 or more, the once-through boiler 20 that supplies by-product gas (hydrogen gas). Is controlled, and when the pressure is less than P4, the supply of by-product gas (hydrogen gas) is controlled such that the number of once-through boilers 20 for supplying by-product gas (hydrogen gas) is zero.
However, the number of once-through boilers 20 that supply the by-product gas (hydrogen gas) determined by the number control device 50 (the hydrogen supply control unit 521) is larger than the number of once-through boilers 20 for which the combustion instruction is issued. When one state is detected, among the once-through boilers 20 that are determined to supply by-product gas (hydrogen gas), the hydrogen gas supply valve 62 arranged corresponding to the once-through boiler 20 for which the combustion instruction is not issued is closed. Then, the hydrogen gas release valve 63 is opened to release a by-product gas (hydrogen gas) to the atmosphere (hereinafter, also referred to as “gas release”).
In the second embodiment described in Patent Literature 1, the number control device 50A (hydrogen supply control unit 521A) sets a pressure value inside the hydrogen holder 30 that stores the by-product gas (hydrogen gas) in advance. The supply amount (required output hydrogen amount) of hydrogen gas to the boiler group 2 is calculated so as to reach the target pressure value, and the number control device 50A (hydrogen supply control unit 521A) sets the required output hydrogen amount to the boiler group 2. The opening / closing or opening degree of the hydrogen gas supply valve 62 is controlled so as to be supplied.
However, also in this case, the unit number control device 50A (the hydrogen supply control unit 521A) increases the amount of hydrogen output from the hydrogen holder 30 (output hydrogen amount) only by supplying the hydrogen gas to the once-through boiler 20 in the combustion state. When the required output hydrogen amount has not been reached, or when there is no once-through boiler 20 in the combustion state, the opening degree of the hydrogen gas release valve 63A is controlled to discharge the by-product gas (hydrogen gas). It is described that the pressure of the hydrogen gas inside the hydrogen holder 30 is controlled to be a target pressure.

  As described above, the boiler system 1 described in Patent Literature 1 includes a plurality of once-through boilers in which a mixed gas of a first fuel gas and a by-product gas is mixedly burned as a fuel gas, or in which only the first fuel gas is exclusively burned. And only uses hydrogen gas as a by-product gas as an auxiliary to the first fuel gas. For this reason, the number control device of the boiler system 1 controls the supply amount of hydrogen (including the outgassing) under the conditions on the assumption that the generated steam amount is controlled. Regardless of the first embodiment and the second embodiment, when controlling the combustion amount of the boiler system 1, when the hydrogen supply amount is excessive, the number control device 50 </ b> A releases the excessive amount. It is assumed that control is performed. As described above, the boiler system 1 described in Patent Literature 1 cannot necessarily consume all by-product gas generated in product manufacturing from plant equipment. Further, the boiler system does not include a hydrogen-only boiler capable of consuming only by-product gas (hydrogen gas) having a variable generation amount as a fuel gas.

On the other hand, for example, when the amount of steam is generated by the main boiler system and the amount of steam is controlled in the main boiler system, only hydrogen gas generated as a by-product gas in product production from the plant equipment is burned as fuel gas. By installing a new by-product gas utilization system that includes a possible hydrogen-only boiler (through-flow boiler), the by-product gas (hydrogen gas ) Is normally consumed as fuel gas without affecting the plant equipment side, and there is a demand for a by-product gas utilization system that can efficiently use by-product gas with large fluctuations in generation amount as energy. .
In this regard, the boiler system 1 disclosed in Patent Literature 1 has a single-fired combustion in which only a first fuel gas (for example, a hydrocarbon gas such as 13A or LPG) can be burned as a fuel gas, and a first fuel gas and a by-product gas. And a once-through boiler capable of combusting and combusting the mixture gas as a fuel gas to generate a required amount of steam by combining the first fuel gas and the by-product gas. All of them were not consumed without waste as fuel gas, and there was no boiler system that could efficiently use by-product gas (hydrogen gas), whose generation amount fluctuates, as energy.
In addition, the boiler system 1 disclosed in Patent Literature 1 can consume only by-product gas (hydrogen gas) having a variable generation amount as a fuel gas (without controlling the generated steam amount). Neither was a new boiler system including a once-through boiler installed.

  The present invention relates to a by-product gas boiler (through-flow boiler) as a combustion device that can burn only a by-product gas (for example, hydrogen gas) generated in a product manufacturing process in a by-product facility such as a plant facility as a fuel gas. A boiler gas utilization system including a boiler group including at least one boiler group, the boiler group being configured to supply a by-product gas (eg, hydrogen gas) to the boiler group based on a pressure value in a tank storing a by-product gas (hydrogen gas). By controlling the number of units (feedback control), the by-product gas with large fluctuations in the amount of generation can be consumed without waste, and in a by-product gas utilization system that can be efficiently used as energy, if the amount of by-product gas generated is large, Even in the case of fluctuations or abnormalities in the gas consumption of the combustion equipment, use of by-product gas is not affected without affecting by-product equipment such as plant equipment. And to provide a by-product gas utilization system capable of constant control.

(1) The present invention provides a by-product gas tank for storing a by-product gas, a pressure value measuring unit for measuring a pressure value inside the by-product gas tank, and burning only the by-product gas stored in the by-product gas tank. And a combustion device group including a plurality of combustion devices to be consumed by the combustion device group, such that a pressure value inside the by-product gas tank matches a target pressure value set within a predetermined pressure value range. And a control unit for controlling the amount of by-product gas consumed in the combustion apparatus, wherein a minimum gas consumption that is a gas consumption in the smallest combustion state is set in the plurality of combustion devices. A control unit configured to calculate a required gas consumption amount, which is a gas amount to be consumed, based on a pressure value in the by-product gas tank, and a gas consumption amount in the combustion device. Quantity of fruit The actual gas consumption calculation unit that calculates the actual gas consumption that is, and the internal pressure of the by-product gas tank measured by the pressure value measurement unit even when the required gas consumption falls below the minimum gas consumption. A consumption control unit configured to burn the combustion device with the minimum gas consumption until the value falls below a preset lower limit pressure value.

(2) Further, it is preferable that the lower limit pressure value is a value equal to or less than a lower limit value of the pressure value range.

(3) When the pressure value inside the by-product gas tank exceeds an upper limit pressure value set in advance as a pressure value higher than the target pressure value, the control unit may control the inside of the by-product gas tank. May be provided with a valve control unit that controls a pressure value adjustment valve disposed in the by-product gas tank so that the pressure value does not exceed the upper limit pressure value.

(4) Preferably, the upper limit pressure value is equal to an upper limit value of the pressure value range.

(5) The control unit may further include a pressure value arranged in the by-product gas tank such that a pressure value inside the by-product gas tank measured by the pressure value measurement unit maintains an outgassing target pressure value. A valve control unit for controlling the regulating valve may be provided.

(6) Further, it is desirable that the target air release pressure value is equal to or less than an upper limit value of the pressure value range.

(7) In addition, the combustion device may include a local control unit, and the local control unit may control to discharge a gas amount corresponding to a gas consumption amount that the combustion device can no longer consume. preferable.

  According to the present invention, for example, a by-product gas boiler (through-flow boiler) as a combustion device capable of burning only a by-product gas (eg, hydrogen gas) generated in a product manufacturing process in a by-product facility such as a plant facility as a fuel gas. And a pressure value in a tank for storing a by-product gas (hydrogen gas) for supplying a by-product gas (for example, hydrogen gas) to the boiler group. In a by-product gas utilization system that can efficiently use energy as energy by efficiently using by-product gas with large fluctuations in generation amount by performing unit control (feedback control) based on Even if there is a large fluctuation in the gas consumption or if there is an abnormality in the gas consumption of the combustion device, the by-product gas The use can be stably controlled.

It is a figure showing composition of a boiler system in an embodiment of the present invention. It is a figure showing a tank pressure zone in a boiler system in an embodiment of the present invention. It is a functional block diagram showing composition of a number control device in a boiler system in an embodiment of the present invention. It is a figure showing the situation where hunting occurs. It is a diagram showing a correction of a required gas consumption MV _n to prevent or suppress the occurrence of hunting. 5 is a flowchart illustrating a flow of processing of a control unit according to the embodiment of the present invention. 5 is a flowchart illustrating a flow of processing of a control unit according to the embodiment of the present invention. 5 is a flowchart illustrating a flow of processing of a control unit according to the embodiment of the present invention. 5 is a flowchart illustrating a flow of processing of a control unit according to the embodiment of the present invention.

Hereinafter, a preferred embodiment of a boiler system as a by-product gas utilization system of the present invention will be described with reference to the drawings. Note that, as the by-product gas in the present embodiment, a hydrogen gas generated in product production from a by-product facility such as a plant facility (hereinafter, also referred to as “plant facility or the like”) is illustrated, but the present invention is not limited to hydrogen gas. . The present invention can be applied to any by-product gas such as digestion gas and other hydrocarbon gas.
The boiler system as a by-product gas utilization system in the present embodiment is a hydrogen-only boiler (through-flow boiler) as a combustion device capable of consuming, as a fuel gas, only hydrogen gas generated as a by-product gas in product manufacturing from plant equipment or the like. (Boiler).

  As shown in FIG. 1, the boiler system 1 of the present embodiment includes a boiler group 2 including a plurality (for example, four) of once-through boilers 20 (hereinafter, also referred to as “boilers 20”), which are hydrogen-only boilers, and a hydrogen gas supply. The boiler system 1 includes a line L2 and a number control device 50 as a control unit that controls the amount of by-product gas consumed in the boiler group 2. The boiler system 1 is supplied from a secondary hydrogen tank 30 as a by-product gas tank. Consumes hydrogen gas as a by-product gas. In the present embodiment, the boiler group 2 includes four boilers 20, but is not limited thereto. The boiler group 2 may include three or less boilers 20. Further, the boiler group 2 may include five or more boilers 20.

The hydrogen gas supply line L2 supplies hydrogen gas to each of the once-through boilers 20, which are hydrogen-fired boilers. The hydrogen gas supply line L2 includes a main hydrogen gas line L21 and a plurality of hydrogen gas branch lines L22. The upstream side of the hydrogen gas main line L <b> 21 is connected to the secondary side hydrogen tank 30 via the flashback prevention device 23. The upstream side of the plurality of hydrogen gas branch lines L22 is connected to the hydrogen gas main line L21. Downstream sides of the plurality of hydrogen gas branch lines L22 are connected to the once-through boiler 20, respectively.
The hydrogen gas branch line L22 is provided with a hydrogen gas flow control valve 24 and two or more hydrogen gas cutoff valves 25 and 26, respectively.

The hydrogen gas flow control valve 24 is constituted by, for example, an air drive valve, and adjusts the flow rate of the hydrogen gas flowing through the hydrogen gas branch line L22 by opening and closing or adjusting the opening degree of the flow path of the hydrogen gas branch line L22.
The hydrogen gas cutoff valve 25 is disposed upstream of the hydrogen gas flow control valve 24 in the hydrogen gas branch line L22. The hydrogen gas cutoff valve 25 is configured by, for example, an electromagnetic valve, and opens and closes a supply path of hydrogen gas from the hydrogen gas branch line L22 to the boiler 20.
Although not shown, if a failure occurs in the number control device 50 and the control of the consumption of the by-product gas in the boiler group 2 is not performed normally, as a result, the inside of the secondary hydrogen tank 30 By providing a supply gas pressure switch in each of the boilers 20 in case the pressure value becomes too low, the supply gas pressure switch is activated when the supply gas pressure drops, so that the boiler 20 May be set to zero.

<About the secondary hydrogen tank 30>
The secondary hydrogen tank 30 is a by-product gas tank that stores hydrogen gas generated as by-product gas in plant equipment or the like in a state where the hydrogen gas is pressurized as described later. In the secondary hydrogen tank 30, a hydrogen pressure sensor 31 is disposed as a pressure value measuring unit for measuring an internal pressure value. The hydrogen pressure sensor 31 detects the pressure of the hydrogen gas stored in the secondary hydrogen tank 30 as a by-product gas tank, and outputs a signal (hydrogen pressure signal) relating to the detected pressure of the hydrogen gas to a unit control device described later. Send to 50.
Thereby, the number control device 50 controls the consumption of the by-product gas (hydrogen gas) in the boiler group 2 so that the pressure value inside the secondary hydrogen tank 30 falls within a preset pressure value range. . Hereinafter, for the sake of simplicity, the pressure inside the secondary hydrogen tank 30 is also referred to as “tank pressure”, and the pressure value inside the secondary hydrogen tank 30 detected by the hydrogen pressure sensor 31 is referred to as “tank pressure value”. Also called.
More specifically, when the required gas consumption described later becomes larger than the actual gas consumption described later, the number control device 50 causes the boiler group 2 to increase the hydrogen gas consumption so as to increase the hydrogen gas consumption. When the required gas consumption is smaller than the actual gas consumption, the opening degree of the flow control valve 24 is adjusted, and the hydrogen gas flow control valve 24 is instructed to the boiler group 2 so as to reduce the hydrogen gas consumption. Adjust the opening.
At this time, since hydrogen gas is stored in the secondary hydrogen tank 30 at a high pressure, the difference between the gas amount supplied to the secondary hydrogen tank 30 and the gas amount consumed by the boiler group 2 is reduced. Can be absorbed.
In addition, in the boiler system 1, during normal times, that is, when the pressure value of the hydrogen gas inside the secondary hydrogen tank 30 does not exceed the control upper limit pressure value described later, the hydrogen gas generated as a by-product gas is discharged. Without waste, the by-product gas can be used as energy without waste.

  In the secondary hydrogen tank 30, a hydrogen gas release line L3 and a hydrogen gas release valve 33 are arranged. The hydrogen gas discharge valve 33 is configured by, for example, a motor valve or the like. The hydrogen gas discharge valve 33 is normally operated in a closed state, but in an emergency, for example, when the once-through boiler 20 is in a combustion stopped state, it takes several tens of seconds to burn the once-through boiler 20 again. Therefore, when the tank pressure value exceeds the control upper limit pressure value during this time, the hydrogen gas discharge valve 33 is opened and closed or the opening is adjusted so that the tank pressure value does not exceed the control upper limit pressure value. The amount of the hydrogen gas stored in the secondary hydrogen tank 30 released to the atmosphere via the hydrogen gas release line L3 can be adjusted. Accordingly, when an abnormal time occurs in which the tank pressure value exceeds the control upper limit pressure value, the hydrogen gas is released by the hydrogen gas release valve 33 so that the tank pressure value exceeds the control upper limit pressure value. In this way, it is possible to prevent pressure destruction of the secondary hydrogen tank 30 and damage to the hydrogen gas shutoff valves 25 and 26. Details will be described later.

  Further, a safety valve (not shown) may be arranged in the secondary hydrogen tank 30 separately from the hydrogen gas discharge valve 33. The safety valve is for a case where the hydrogen gas release valve 33 has failed, and if the tank pressure value exceeds the control upper limit pressure value and further increases, the tank pressure value increases the pressure resistance of the secondary hydrogen tank 30. The safety valve is opened so as not to exceed the pressure, and the hydrogen gas stored in the secondary hydrogen tank 30 is released to release the pressure of the secondary hydrogen tank 30 and the breakage of the hydrogen gas shutoff valves 25 and 26. Can be prevented.

<About gas supplied from by-product equipment such as plant equipment>
As shown in FIG. 1, a hydrogen gas supplied from a by-product facility (not shown) such as a plant facility is pressurized by a booster 42 to a secondary hydrogen tank 30. Supplied to The opening of the return regulating valve 44 is adjusted by the sensor 41 so that the pressure value on the upstream side of the booster 42 maintains a constant value.

<About boiler group 2>
As described above, the boiler 20 constituting the boiler group 2 is a once-through boiler 20 which is a hydrogen-only boiler, and uses only hydrogen gas generated as a by-product gas in product production from a by-product facility such as a plant facility as a fuel gas. Consumed to produce steam. The boiler group 2 includes a once-through boiler 20, which is a hydrogen-only firing boiler as a combustion device that burns and consumes only by-product gas. The generated steam is supplied to a main boiler or a main boiler system via a steam collecting line L4. Assemble on a steam header (not shown).
As described above, in the present embodiment, a main boiler or a main boiler system (not shown) is provided separately from the boiler system 1, and steam generated in the main boiler or the main boiler system is used as steam-using equipment. To supply. More specifically, the steam generated in the main boiler or the main boiler system and the boiler system 1 is collected and stored in a steam header (not shown). In the steam header, the mutual pressure difference and the pressure fluctuation of the steam generated from the plurality of boilers are adjusted. Then, the steam whose pressure has been adjusted is supplied to a steam use facility (not shown) via a steam supply line (not shown). Here, the main boiler or the main boiler system controls the amount of steam based on the steam header pressure. That is, the main boiler or the main boiler system controls the amount of steam generated by itself, based on the amount of steam generated by the boiler system 1.

The boiler system 1 controls the consumption of by-product gas (hydrogen gas) in the boiler group 2 by the number control device 50 described later so that the tank pressure value falls within a preset pressure value range.
Thus, the boiler system 1 can control the consumption of hydrogen gas as a by-product gas independently of the control of the number of units in the main boiler or the main boiler system. Thereby, in normal times, the hydrogen gas generated as the by-product gas is not released, and the by-product gas can be used as energy without waste.
As described above, the boiler system 1 is configured with the once-through boiler 20 that is a plurality of hydrogen-only boilers, and does not control the amount of steam generated by the boiler group 2. Regardless, the feature is that the consumption of hydrogen gas as a by-product gas is controlled. The details of controlling the consumption of hydrogen gas as a by-product gas will be described later.

<About once-through boiler 20, which is a hydrogen boiler>
Before describing the method of controlling the consumption of hydrogen gas by the number control device 50, the once-through boiler 20, which is a hydrogen-only boiler, will be described. Hereinafter, unless otherwise specified, the once-through boiler 20 means a once-through boiler as a hydrogen-fired boiler. The once-through boiler 20 can be constituted by a step value control boiler having a plurality of stepwise combustion positions or a continuous control boiler. The step value control boiler is selected by controlling the hydrogen gas consumption by selectively turning on / off the combustion, setting the combustion position to high combustion, medium combustion, low combustion, and the like. This is a boiler that can increase or decrease the amount of hydrogen gas consumption stepwise according to the combustion position.
Further, the continuous control boiler means that the gas consumption in the maximum combustion state (for example, 25% of the maximum hydrogen gas consumption) which is the hydrogen gas consumption in the minimum combustion state is reduced. This is a boiler in which the gas consumption (combustion amount) can be continuously controlled within the range of the maximum hydrogen gas consumption. The continuous control boiler adjusts the hydrogen gas consumption by controlling, for example, the output of a valve for supplying hydrogen gas as a fuel gas to a burner or a blower for supplying combustion air. The term “continuously controlling the hydrogen gas consumption” refers to a case where the control is performed in a digital manner and is handled stepwise (for example, a case where the hydrogen gas consumption of the boiler 20 is controlled in steps of 1%). This also includes the case where the hydrogen gas consumption can be controlled substantially continuously.

The once-through boiler 20 in this embodiment is a continuous control boiler unless otherwise specified. The change of the combustion state between the combustion stop state S0 and the minimum combustion state S1 in the boiler 20 in the present embodiment is controlled by turning on / off the combustion of the boiler 20. Then, in the range from the minimum gas consumption amount that is the hydrogen gas consumption amount in the minimum combustion state S1 to the maximum gas consumption amount that is the hydrogen gas consumption amount in the maximum combustion state S2, the hydrogen gas consumption amount (combustion amount) is continuously increased. It can be controlled.
More specifically, a unit gas consumption, which is a unit of variable hydrogen gas consumption, is set for each of the plurality of boilers 20. Thereby, the boiler 20 performs the unit gas consumption unit in a range from the minimum gas consumption amount which is the hydrogen gas consumption amount in the minimum combustion state S1 to the maximum gas consumption amount which is the hydrogen gas consumption amount in the maximum combustion state S2. The gas consumption can be changed.

  The unit gas consumption can be appropriately set according to the maximum gas consumption which is the hydrogen gas consumption in the maximum combustion state S2 of the boiler 20, but the followability of the hydrogen gas consumption in the boiler system 1 to the required hydrogen gas consumption is improved. From the viewpoint of improvement, it is preferably set to, for example, 0.1% to 20% of the maximum hydrogen gas consumption of the boiler 20, and more preferably set to 1% to 10%.

  In addition, priorities are set for the plurality of boilers 20, respectively. The priority is used to select a boiler 20 that issues a combustion instruction or a combustion stop instruction. The priority can be set using, for example, an integer value so that the smaller the numerical value, the higher the priority. When the priority of “1” to “4” is assigned to each of the first to fourth units of the boiler 20 shown in FIG. 1, the first unit has the highest priority and the fourth unit has the lowest priority. . This priority is normally changed at predetermined time intervals (for example, 24 hour intervals) under the control of the control unit 52 described later.

  Each boiler 20 includes a local control unit 201 that controls the amount of hydrogen gas consumed by each boiler 20. The local control unit 201 determines the hydrogen gas consumption (combustion state) of the boiler 20 based on a control signal transmitted from the number control device 50 via the signal line 16B or a control signal input by a manual operation of the driver. Control. In addition, the local control unit 201 transmits a signal used by the number control device 50 to the number control device 50 via the signal line 16B. Examples of the signal used in the number control device 50 include the actual hydrogen gas consumption (combustion state) of the boiler 20 and other data. Thereby, the number control device 50 can manage the combustion state of each boiler 20, the hydrogen gas consumption, and the like.

<About the number control device 50>
Based on the pressure value (tank pressure value) inside the secondary hydrogen tank 30 detected by the hydrogen pressure sensor 31, the number control device 50 determines the hydrogen gas consumption in the once-through boiler 20, which is a plurality of hydrogen-only boilers. Control.
Specifically, if the tank pressure value increases when the amount of by-product gas generated in product production from by-product equipment such as plant equipment increases, the tank pressure value is increased to an appropriate value by increasing the hydrogen gas consumption. When the tank pressure value decreases when the amount of by-product gas supplied to the secondary hydrogen tank 30 is insufficient, the tank pressure value is reduced to an appropriate value by reducing the hydrogen gas consumption. return.
Therefore, the boiler system 1 can monitor the fluctuation of the amount of by-product gas supplied to the secondary hydrogen tank 30 based on the fluctuation of the tank pressure value. Then, the boiler system 1 calculates a required gas consumption amount, which is a hydrogen gas consumption amount required according to the amount of by-product gas generated in product production from by-product equipment such as plant equipment, based on the tank pressure value. Then, based on the calculated required gas consumption, the hydrogen gas consumption state of the plurality of once-through boilers 20 (the number of once-through boilers 20 that consume hydrogen gas and the hydrogen gas consumption of the once-through boiler 20 that consumes hydrogen gas) Can be determined.
In the boiler system 1, the hydrogen gas consumption in the once-through boiler 20, which is a hydrogen-only boiler, is controlled such that the tank pressure value falls within a preset pressure value range. More specifically, the number control device 50 controls the hydrogen gas consumption in the once-through boiler 20, which is a hydrogen-only boiler, so that the tank pressure value matches a preset target pressure value.

  Before describing the control of the hydrogen gas consumption in the boiler system 1 of the present embodiment, the band of the tank pressure will be described. FIG. 2 shows an example of the tank pressure zone.

<Unit control pressure band>
As described above, the number control device 50 controls the hydrogen gas consumption in the boiler group 2 so that the tank pressure value falls within a preset pressure value range. The upper limit pressure value of the pressure value range is called a control upper limit pressure value, and the lower limit pressure value is called a control lower limit pressure value. As described later, when the tank pressure value exceeds the control upper limit pressure value, the number control device 50 controls the tank pressure value so as not to exceed the control upper limit pressure value by adjusting the amount of hydrogen gas released. . When the tank pressure value falls below the control lower limit pressure value, the boiler 20 in the combustion state is immediately put into the combustion stop state, that is, all the units are in the standby state. Hereinafter, a pressure band from the control lower limit pressure value to the control upper limit pressure value is temporarily referred to as a “number control pressure band”. For example, the above-mentioned target pressure value is a value included in the number control pressure band. Note that this target value is also referred to as “unit control target pressure value”.
As will be described later, the number control device 50 basically calculates the current gas consumption in the boiler system 1 by the PI algorithm or the PID algorithm so that the tank pressure value keeps the number control target pressure value, The amount of hydrogen gas consumed in the boiler group 2 (specifically, the number of once-through boilers 20 that consume hydrogen gas and the amount of hydrogen in the once-through boiler 20 that consumes hydrogen gas so that the current required gas consumption Gas consumption). Hereinafter, such control is referred to as “number control”.

<Air release control pressure band>
However, for example, due to an abnormal stop of some of the boilers 20, the tank pressure value may rise rapidly and exceed the control upper limit pressure value. In such a case, the number control device 50 controls the opening / closing or the opening degree of the hydrogen gas discharge valve 33 disposed in the secondary hydrogen tank 30 so that the hydrogen gas stored in the secondary hydrogen tank 30 is controlled. The tank pressure value is controlled so as not to exceed a preset upper limit pressure value by adjusting the amount of air release. Such control is also referred to as “air release control”.
The upper limit pressure value is set higher than the unit control target pressure value, and can be set to, for example, the same value as the control upper limit pressure value.
The number-of-units control device 50 sets the tank pressure value in advance even in the above-described abnormality (that is, when the increase in the tank pressure value cannot be stopped by controlling the hydrogen gas consumption by the unit number control). The opening / closing or opening of the hydrogen gas discharge valve 33 disposed in the secondary hydrogen tank 30 is controlled so as not to exceed the upper limit pressure value.

<Modification of air release control method>
Note that the air release control method is not limited to the method described above. Although not shown in FIG. 2, a target pressure value for air release valve control (hereinafter also referred to as “air discharge target pressure value”) is set in place of the upper limit pressure value, and the air pressure is set to a preset tank pressure value. The opening / closing or opening of the hydrogen gas discharge valve 33 disposed in the secondary hydrogen tank 30 may be controlled so as to maintain the target pressure value. In addition, you may set the discharge target pressure value to the value below the upper limit (control upper limit pressure value) of a pressure value range.

<Bandwidth below the control lower limit pressure value>
As described later, it is preferable to set a boiler interlock stop pressure value in advance as a band equal to or lower than the control lower limit pressure value. For example, when the number control is not performed normally due to a failure of the hydrogen pressure sensor 31, etc., for example, when the number controller 50 cannot set the boiler 20 to the combustion stop state, that is, cannot set all the boilers 20 to the standby state, the boilers 20 are individually set in advance. It is preferable that a supply gas pressure switch is provided, and the supply gas pressure switch is activated by a decrease in the supply gas pressure (to reach the boiler interlock stop pressure value), thereby forcibly stopping the boiler 20 from burning.
Note that these pressure values are set so as to satisfy the following relationship.
Control lower limit pressure value> Boiler interlock stop pressure value.

<Band above the upper limit of the air release control pressure>
It is preferable that a booster stop pressure value be set in advance as a threshold value for forcibly stopping the booster when the tank pressure value exceeds the control upper limit pressure value and further rises.
As described above, in the case where the hydrogen gas discharge valve 33 has failed and the tank pressure value has further increased, the tank pressure value is set so as not to exceed the withstand pressure of the secondary hydrogen tank 30, for example. When the pressure reaches a predetermined pressure value, it is preferable that the safety valve be opened to forcibly discharge the hydrogen gas stored in the secondary hydrogen tank 30. The predetermined pressure value in this case is also referred to as a safety valve opening pressure value.
Note that these pressure values are set so as to satisfy the following relationship.
Safety valve opening pressure value> booster stop pressure value.

  Next, regarding the control of the number control device 50, the number control, the air release control, and the start-up control will be described in order.

<About unit control>
First, details of the number control of the number controller 50 will be described. Here, the number control refers to controlling the hydrogen gas consumption in the boiler group 2 so that the tank pressure value falls within a preset pressure value range.
As illustrated in FIG. 3, the number control device 50 includes a storage unit 51 and a control unit 52 to realize the number control function.
The storage unit 51 stores information on a pressure value set in advance with respect to the tank pressure value (control lower limit pressure value, unit control target pressure value, control upper limit pressure value), and is preset in each of the plurality of once-through boilers 20 and is variable. Information on unit gas consumption, which is a unit of hydrogen gas consumption, information on maximum gas consumption in the largest combustion state, information on minimum gas consumption, which is the gas consumption in the smallest combustion state, and boiler group 2 , The information about the additional line indicating the gas consumption of each boiler 20 as a reference for increasing the number of boilers 20 consuming (burning) hydrogen gas, the boiler consuming (burning) hydrogen gas Information on the increase reference gas consumption as a reference for increasing the number of 20 boilers, and the number of boilers 20 that consume (burn) hydrogen gas Storing information about the reduced base line indicating the gas consumption as a reference to reduce.
In addition, the storage unit 51 stores information such as the content of instructions given to the plurality of once-through boilers 20 under the control of the number control device 50 (the control unit 52) and the hydrogen gas consumption status received from the plurality of once-through boilers 20. , The information on the setting of the priority order of the plurality of once-through boilers 20, the information on the setting regarding the change of the priority order (rotation), the information on the tank pressure value, and the like.

<About gas consumption leveling>
First, a description will be given of the unit control for leveling the gas consumption of the plurality of boilers 20 in the combustion state with respect to the fluctuation of the gas consumption required in the boiler system 1. Here, it is assumed that the plurality of boilers 20 in the combustion state do not satisfy a condition for increasing or decreasing the number of boilers 20 to be burned (conditions relating to an increase line, a decrease line, etc.) described later.
In the boiler system 1, when the hydrogen gas shutoff valves 25 and 26 of the hydrogen gas branch line L22 to the boiler 20 are opened, the number control device 50 determines that the boiler 20 is in a combustion state. .
In order to level the gas consumption of the plurality of boilers 20 in the combustion state with respect to the fluctuation of the gas consumption required in the boiler system 1, the control unit 52, as shown in FIG. An amount calculation unit 520, an actual gas consumption calculation unit 521, a deviation calculation unit 522, a combustion device selection unit 523, a first determination unit 5241, and a consumption control unit 525 are provided.

<Necessary gas consumption calculator 520>
The required gas consumption calculating unit 520 calculates a required gas consumption, which is a gas amount to be consumed by the boiler group 2, based on the tank pressure value and the unit control target pressure value.
More specifically, the required gas consumption calculating unit 520 determines, for example, a known position type PID (or position type PI) algorithm or speed for each control cycle so that the tank pressure value matches the unit control target pressure value. calculating the required gas consumption MV _n at the present time calculated by the form PID (or velocity type PI) algorithm.
Here, when Δt is a control cycle and n is a positive integer value, MV _n is a required gas consumption in the control cycle n (start point t0 + n * Δt) (hereinafter, unless otherwise specified, “the current required gas consumption”). Or, also referred to as “currently required gas consumption”).

<Position type PID algorithm>
Required gas consumption calculation section 520 when using a position type PID algorithm, required gas consumption MV _n This time can be calculated based on known formulas (1).

MV _n = deviation proportional output (P control) −deviation integral output (I control) + deviation differential output (D control)
... (1)

Here, each component constituting MV _n is calculated by, for example, the following equations (2) to (4).
The target steam pressure value is SP, the tank pressure value in the control cycle n (start point t0 + n * Δt) is PV _n (hereinafter, also referred to as “this tank pressure value” unless otherwise specified), and the tank pressure value in the previous control cycle is PV _n−1 (hereinafter, also referred to as “previous tank pressure value” unless otherwise specified), and the proportional gain is K _P ,
Deviation proportional output = K _P × (PV _n −SP) (2)

Deviation integral output = K _P × (Δt / T _I ) × Σ _i (PV _i −SP) (3)
Here, _{T I} denotes the integration time.

Deviation differential output = K _P × (T _D / Δt) × (PV _n −PV _n−1 ) (4)
Here, _{T D} represents the derivative time.

As described above, when using the position type PID algorithm, the required gas consumption calculation unit 520 sums up the respective outputs calculated by, for example, the equations (2) to (4), thereby obtaining the current required gas consumption MV. _n can be calculated.

<Speed PID algorithm>
The required gas consumption calculation unit 520 may use a speed type PID algorithm instead of the position type PID algorithm. The speed type PID algorithm calculates only the required gas consumption change amount ΔMV _{n for} each control cycle, adds the previous required gas consumption MV _n−1 to this, and calculates the current required gas consumption MV _n using the equation (5). ).
MV _n = MV _n−1 + ΔMV _n (5)

The required gas consumption change amount ΔMV _{n for} each control cycle is calculated based on the following equations (6) to (10).
ΔMV _n = ΔP _n + ΔI _n + ΔD _n (6)
Here, ΔP _n is the P control output (variation),
[Delta] I _n the I control output (change amount),
ΔD _n represents the D control output (change).

_{ΔP n = K P × (e} n -e n-1) ··· (7)
Here, K _P represents a proportional gain.
e _n, as shown in equation (8), this installation control target steam pressure value SV _n (however, _SV n = SV now assumptions), the difference between the current tank pressure value PV _n (this deviation ).
_{e n = PV n -SV n ···} (8)

_{ΔI n = K P × (Δt} / T I) × e n ··· (9)
T _I represents the integration time.

_{ΔD n = K P × (T} D / Δt) × (e n -2e n-1 + e n-2)
... (10)
Here, _{T D} represents the derivative time.

When the speed-type PID algorithm is used, the required gas consumption calculating unit 520 sums up the respective outputs (changes) calculated by, for example, Expressions (7), (9), and (10), and thereby obtains a value for each control cycle. calculating the required gas consumption variation .DELTA.MV _n.
Required gas consumption calculating portion 520, as shown in equation (5), by adding the .DELTA.MV _n the last required gas consumption _{MV n-1,} calculates the time required gas consumption MV _n.
The required gas consumption calculating section 520 has been described above.

<Actual gas consumption calculation unit 521>
The actual gas consumption calculation unit 521 determines whether each of the boilers 20 is in the combustion state based on the hydrogen gas consumption state (combustion state, hydrogen gas consumption) of each boiler 20 transmitted from the local control unit 201 of each boiler 20. The actual gas consumption, which is the actual amount of hydrogen gas consumption in the boiler group 2, which is the total amount of gas consumption of each of the boilers 20 in the combustion state, while calculating the actual gas consumption amount, which is the actual result of hydrogen gas consumption. Calculate consumption.

<Deviation calculation unit 522>
The deviation calculator 43 calculates a deviation between the required gas consumption calculated by the required gas consumption calculator 520 and the actual gas consumption of the boiler group 2 calculated by the actual gas consumption calculator 521.

<Combustion device selection unit 523>
When the required gas consumption is larger than the actual gas consumption, the combustion device selection unit 523 selects the boiler 20 that consumes less hydrogen gas (hereinafter, “boiler that consumes less gas”) among the plurality of boilers 20 in the combustion state. "). Conversely, when the required gas consumption is smaller than the actual gas consumption, the combustion device selection unit 523 selects the boiler 20 that consumes the largest amount of hydrogen gas among the plurality of boilers 20 in the combustion state (hereinafter, “gas consumption”). Large boiler ").
The combustion device selection unit 523 determines that the tank pressure value is greater than the unit control target pressure value (that is, the required gas consumption is greater than the actual gas consumption), and that the two or more combustion devices are in the combustion state. When the hydrogen gas consumptions of the boilers with a small gas consumption are equal, for example, the boiler 20 with a high combustion priority may be preferentially selected.
Further, the combustion device selection unit 523 determines that the tank pressure value is smaller than the unit control target pressure value (that is, the required gas consumption is smaller than the actual gas consumption), When the hydrogen gas consumption of the boilers having a large gas consumption is equal, for example, the boiler 20 having a low combustion priority may be preferentially selected.

<First determination unit 5241>
The first determination unit 5241 determines that the deviation between the required gas consumption and the actual gas consumption calculated by the deviation calculation unit 522 is a positive value, that is, the required gas consumption is larger than the actual gas consumption. In this case, it is determined whether the deviation amount is equal to or more than the unit gas consumption set in advance in the “boiler 20 with low gas consumption”.
In addition, the first determination unit 5241 determines that the difference between the required gas consumption and the actual gas consumption calculated by the deviation calculation unit 522 is a negative value, that is, the required gas consumption is smaller than the actual gas consumption. If is also smaller, it is determined whether the absolute value of the deviation is equal to or greater than the unit gas consumption set in advance in the “boiler 20 with a large gas consumption”.

<Consumption control unit 525>
When the deviation between the required gas consumption and the actual gas consumption calculated by the deviation calculating unit 522 is a positive value, the consumption control unit 525 determines that the deviation is “gas consumption” by the first determination unit 5241. If it is determined that the unit gas consumption is equal to or larger than the unit gas consumption set in advance for the “boiler 20 with small gas consumption”, the hydrogen gas consumption of the “boiler 20 with small gas consumption” selected by the combustion device selection unit 523 is converted into the unit gas. Increase by consumption.
Conversely, when the deviation amount between the required gas consumption amount and the actual gas consumption amount calculated by the deviation calculation unit 522 is a negative value, the consumption amount control unit 525 determines the absolute value of the deviation amount by the first determination unit 5241. When it is determined that the value is equal to or greater than the preset unit gas consumption, the hydrogen gas consumption of the “boiler 20 having a large gas consumption” selected by the combustion device selection unit 523 is reduced by the unit gas consumption. Let it.
According to the configuration described above, when the required gas consumption varies, the gas consumption can be adjusted by varying the gas consumption of the boiler 20 having a large or small gas consumption. Gas consumption can be leveled, and the pressure stability of the secondary hydrogen tank 30 can be improved.

<Increase control, Decrease control>
Next, control of the number of boilers 20 to be burned when the number of boilers 20 to be burned is increased or decreased will be described.
For this reason, as described above, the storage unit 51 stores information on an additional line indicating the gas consumption of each boiler 20 as a reference for increasing the number of boilers 20 that consume (burn) hydrogen gas, and hydrogen gas. Information about a reduction line indicating a gas consumption amount serving as a reference for reducing the number of boilers 20 that consume (combust) the gas is set in advance.
The control unit 52 further includes a second determination unit 5242, as shown in FIG.

<Second determination unit 5242>
The second determination unit 5242 determines whether the gas consumption of each of the boilers 20 in the combustion state is equal to or more than the gas consumption specified by the additional line, or exceeds the gas consumption. In addition, the second determination unit 5242 determines whether the gas consumption of each boiler 20 in the combustion state is equal to or less than the gas consumption specified by the reduction line or not.

<Combustion device selection unit 523>
When the second determination unit 5242 determines that the gas consumption of each of the boilers 20 in the combustion state is equal to or greater than the gas consumption specified by the additional line, the combustion device The selection unit 523 selects the boiler 20 whose combustion has been stopped from the boiler group 2 and selects it as a boiler 20 that newly starts combustion (hereinafter, also referred to as a “combustion start boiler”). When there are a plurality of boilers 20 in which combustion has stopped, the combustion device selection unit 523 may select the boiler 20 with the highest priority among the boilers 20 in which combustion has stopped as the combustion start boiler. Good.
In addition, the second determination unit 5242 determines that the plurality of boilers 20 are in the combustion state, and the gas consumption of each of the boilers 20 in the combustion state is equal to or less than the gas consumption specified by the reduction line, or When it is determined that the amount is less than the amount, the combustion device selection unit 523 selects the boiler 20 in the combustion state and selects the boiler 20 to stop the combustion (hereinafter, also referred to as “stop combustion boiler”). When there are a plurality of boilers 20 in the combustion state, the combustion device selection unit 523 may select the boiler 20 with the lowest priority among the boilers 20 in the combustion state as the stopped combustion boiler.

<Consumption control unit 525>
The consumption control unit 525 determines by the second determination unit 5242 that the gas consumption of each of the boilers 20 in the combustion state is equal to or greater than the gas consumption specified by the additional line, or exceeds the gas consumption. In this case, the combustion start boiler selected by the combustion device selection unit 523 is burned in the boiler 20 with a preset minimum gas consumption.
In this way, the newly started combustion start boiler 20 keeps the hydrogen consumption at the start of combustion at the minimum gas consumption.
Conversely, the consumption control unit 525 determines that the plurality of boilers 20 are in the combustion state by the second determination unit 5242, and the gas consumption of each of the boilers 20 in the combustion state is equal to or less than the gas consumption specified by the reduction line. If it is determined that the gas consumption is lower than the gas consumption, the combustion device selection unit 523 controls the selected stopped combustion boiler 20 to change the gas consumption with respect to the change in the tank pressure value. At that time, when the gas consumption of the stopped combustion boiler 20 has decreased to the minimum gas consumption set in advance for the boiler 20, the consumption control unit 525 stops the combustion of the stopped combustion boiler 20.
Accordingly, pressure fluctuations due to fluctuations in gas consumption when increasing or decreasing the number of combustion units can be suppressed, and the pressure stability of the secondary hydrogen tank 30 can be improved.
As described above, the information on the additional line indicating the gas consumption amount serving as a reference for increasing the number of boilers 20 that consume (burn) hydrogen gas, and the reference for decreasing the number of boilers 20 that consume (burn) hydrogen gas are used. A description has been given of the control of the number of boilers 20 to be burned, which is increased or decreased based on the information regarding the reduced line indicating the gas consumption.

<Reserve capacity>
In the boiler system 1, for example, in order to cope with a rapid increase in hydrogen gas generated as a by-product gas in a by-product facility such as a plant facility, the boiler 20 in a combustion state is provided with a certain remaining power. It is preferable to burn hydrogen gas at the pressure. For this reason, as described above, the “increase reference gas consumption” is preset for the boiler group 2 as a reserve for a rapid increase in hydrogen gas consumption, and the hydrogen gas is supplied based on the increase reference gas consumption. The number of boilers 20 to be consumed (burned) may be increased.
For this reason, as shown in FIG. 3, the control unit 52 further includes a remaining capacity calculation unit 526.

<Remaining power calculation unit 526>
The surplus power calculation unit 526 calculates an increased surplus gas consumption, which is the difference between the maximum gas consumption and the current gas consumption for each of the boilers 20 in the combustion state. Then, the remaining capacity calculation unit 526 calculates a total increased remaining gas consumption which is a sum of the increased remaining gas consumptions of the boilers 20 in the combustion state. That is, it can be said that the total surplus gas consumption is the largest increase fluctuation amount of the hydrogen gas consumption of the boiler group 2 that can be immediately followed at the present time.

In this case, the second determination unit 5242 further determines that the total increase reserve gas consumption calculated by the reserve calculation unit 526 is a reference for increasing the number of the boilers 20 that consume (burn) the hydrogen gas. It is determined whether the gas consumption becomes equal to or less than the gas consumption or falls below the increase reference gas consumption.
Then, the combustion device selection unit 523 further performs the boiler group when the second determination unit 5242 determines that the total additional reserve gas consumption is equal to or less than the increase reference gas consumption or less than the increase reference gas consumption. 2, the boiler 20 whose combustion has been stopped is selected, and is selected as a boiler 20 for newly starting combustion (hereinafter, also referred to as a "combustion start boiler"). When there are a plurality of boilers 20 in which combustion has stopped, the combustion device selection unit 523 may select the boiler 20 with the highest priority among the boilers 20 in which combustion has stopped as the combustion start boiler. Good.
Then, the consumption control unit 525, when the second determination unit 5242 determines that the total increase reserve gas consumption is equal to or less than the increase reference gas consumption, or falls below the increase reference gas consumption, the combustion device selection unit. The combustion start boiler selected by 523 is burned in the boiler 20 with a preset minimum gas consumption.
Thereby, in the boiler group 2, the number of the combustion boilers 20 is increased in a state where the reserve capacity capable of immediately following the sudden increase in the preset hydrogen gas consumption (“increase reference gas consumption”) is secured. be able to.

<Pilot holding control>
When newly starting combustion of the boiler 20 whose combustion has been stopped, a pre-purge time or the like is required until the boiler actually starts combustion (that is, consumes hydrogen gas). For this reason, if the required gas consumption increases and the rate of increase in the supply gas amount is high, the tank pressure value rises rapidly due to the delay in the start of the combustion start boiler, and as a result, the control upper limit pressure value is exceeded, and hydrogen gas discharge occurs. Controlling the opening / closing or opening of the gas valve 33 may cause a situation in which the hydrogen gas stored in the secondary hydrogen tank 30 is discharged.
In order to avoid such a situation, for example, the boiler 20 having the highest priority to start combustion next is selected, pre-purge is started for ventilation in the furnace, and the hydrogen supply gas line L22 is connected to the inert gas ( For example, the boiler 20 may be purged with nitrogen gas), then pilot-ignited, and pilot-stabilized to cause the boiler 20 to perform pilot combustion, and then controlled to maintain the pilot-combustion state of the boiler 20 for a predetermined time. By doing so, if the required gas consumption increases abruptly, the boiler in the pilot combustion state is immediately started to burn, so that the increase in the required gas consumption can be followed.
Further, after stopping the combustion, the boiler 20 that burns hydrogen gas as a by-product gas closes the hydrogen gas supply line L22 by the hydrogen gas shutoff valves 25 and 26 during the post-purge for safety, and purges the hydrogen gas supply line with N2 purge ( It is necessary to perform purging with nitrogen gas which is an inert gas. For this reason, it is difficult for the boiler 20 to perform the continuous pilot control in which the pilot burner is burned during the main combustion and the combustion of the pilot burner is continued even after the main combustion is stopped.
After stopping the combustion of the boiler 20 in the combustion state and reducing the number of the combustion boilers, if the required gas consumption increases and the increase rate of the supply gas is fast, the tank pressure value increases due to a delay in the start of the combustion start boiler. As a result, a situation occurs in which the hydrogen gas stored in the secondary hydrogen tank 30 is vented by exceeding the control upper limit pressure value and controlling the opening / closing or opening of the hydrogen gas vent valve 33. there's a possibility that.
In order to avoid such a situation, for example, in the number-reduction control, the number control device 50 (the consumption control unit 525), when the combustion of the boiler 20 is stopped, performs the post-purging of the boiler 20 as described above when the combustion is stopped. After the pilot ignition and pilot stabilization, the boiler 20 may be pilot-burned, and thereafter, the pilot combustion state of the boiler 20 may be controlled to be maintained for a predetermined time.
By doing so, if the required gas consumption increases after the number of vehicles has been reduced, the boiler in the pilot combustion state is started to burn quickly so that the increase in the required gas consumption can be followed. Can be.
Further, as will be described later, when the number of the boilers 20 in the combustion state becomes one and the combustion of all the boilers is stopped when the tank pressure value falls below the control lower limit pressure value, the number control device 50 (consumption control unit) 525) may be controlled so that the post-purge is performed when the boiler 20 stops burning as described above, then the boiler 20 is pilot-burned, and thereafter, the pilot combustion is maintained for a predetermined time.
Alternatively, the number control device 50 (the consumption control unit 525) selects at least one boiler 20 (for example, the highest-priority boiler 20 to start burning next) and sends the selected boiler 20 to the boiler 20 described above. As described above, the pre-purge may be performed, and after the pre-purge is performed, the selected boiler 20 may be pilot-burned, and thereafter, the pilot combustion state may be controlled to be maintained for a predetermined time.
By doing so, if the required gas consumption increases after stopping the combustion of all units, the boiler in the pilot combustion state can be started to burn quickly so that it can follow the increase in the required gas consumption. can do.

  In the pilot holding control method described above, post-purge or pre-purge is performed after or after the boiler is stopped, and the hydrogen supply gas line L22 is purged with an inert gas (for example, nitrogen gas). After stabilization, a transition was made to continuous pilot combustion.

<Another form related to pilot combustion holding control>
On the other hand, there is a system in which pilot combustion is continued during boiler combustion. Specifically, the number controller 50 (consumption controller 525) instructs the local controller 201 to continue the pilot combustion of the boiler 20. Thereby, the local control device 201 supplies the pilot gas to the pilot burner in parallel with the boiler 20 during the combustion (that is, the state in which the main burner is burning the gas) to bring the pilot burner into the pilot combustion state, and stops the boiler 20 from burning. Even when the combustion is stopped (that is, when the combustion is stopped by the main burner), the pilot combustion state is continued.
Thereafter, the local controller 201 starts the post-purge to the extent that the combustion by the pilot burner does not disappear, purges the hydrogen supply gas line L22 with an inert gas (for example, nitrogen gas) during the post-purge, and sets the pilot combustion state. Is controlled to be maintained. In order to maintain the pilot combustion, the air volume of the blower may be set to a medium air volume during the inert gas purge and to a low air volume after the inert gas purge. Note that the number control device 50 and the local control device 201 perform control so that the transition to the main ignition in which the main burner is ignited by the pilot burner during the post-purge of the boiler 20 is performed. Thereafter, the number control device 50 may perform control so as to maintain the pilot combustion state of the boiler 20 for a predetermined time.
By doing so, the number of times of ignition of the pilot burner does not increase as compared with the normal pilot holding control method described above, so that deterioration of the ignition mechanism can be reduced. In addition, compared to the normal pilot holding control method described above, pilot ignition after pre-purge, pilot stabilization, etc. are omitted, and transition to continuous pilot combustion takes place. In this case, the boiler 20 can start burning more quickly.

<Variable setting of the unit control target pressure value>
Next, a description will be given of unit control in which the unit control target pressure value is switched according to the number of boilers 20 in the combustion state of the boiler group 2 or the by-product gas consumption (hydrogen gas consumption).
When newly starting combustion of the boiler 20 whose combustion has been stopped, a pre-purge time or the like is required until the boiler actually starts combustion (that is, consumes hydrogen gas). For this reason, when the number of combustion units is small or when the by-product gas consumption (hydrogen gas consumption) is small, it is preferable to give priority to, for example, the followability to the increase in the gas supply amount over the followability to the decrease in the gas supply amount. Specifically, when the tank pressure value suddenly becomes larger than the unit control target pressure value (that is, when the required gas consumption becomes suddenly larger than the actual gas consumption), a small number of combustion state Preferably, it can be followed by the boiler 20. Therefore, when the number of combustion units is small or when the amount of by-product gas consumed (hydrogen gas consumption) is small, the unit control target pressure value is set low, and the time required to reach the control upper limit pressure value is increased, so that combustion takes place. It is preferable to secure a time during which the small number of boilers 20 in the state can follow the increase in the gas supply amount, during which time the newly selected combustion start boiler 20 can start combustion.
Conversely, when the number of combustion units is large or the by-product gas consumption (hydrogen gas consumption) is large, for example, it is preferable to give priority to the ability to follow the decrease in gas supply rather than the ability to follow the increase in gas supply. Specifically, when the tank pressure value suddenly becomes smaller than the unit control target pressure value (that is, when the required gas consumption becomes suddenly smaller than the actual gas consumption), the boiler in the combustion state is started. It is preferable to be able to follow 20 without stopping combustion. For this reason, when the number of combustion units is large or when the by-product gas consumption (hydrogen gas consumption) is large, the unit control target pressure value is set high, and the time until the control lower limit pressure value is reached is increased to increase the combustion. It is preferable that the boiler 20 in the state can be followed by reducing the gas consumption.
As described above, in order to switch the number control target pressure value according to the number of boilers 20 in the combustion state of the boiler group 2 or the by-product gas consumption (hydrogen gas consumption), the control unit 52 performs the control shown in FIG. It is preferable to further include a target pressure switching unit 527 as shown in FIG.

<Target pressure switching unit 527>
The target pressure switching unit 527 switches the number control target pressure value according to the number of boilers 20 in the combustion state or the by-product gas consumption (hydrogen gas consumption). More specifically, the target pressure switching unit 527 sets the unit control target pressure value high when the number of boilers 20 in the combustion state is large or when the by-product gas consumption (hydrogen gas consumption) is large, When the number of boilers 20 in the combustion state is small or when the by-product gas consumption (hydrogen gas consumption) is small, it is preferable to set the unit control target pressure value low.
By doing so, when the number of boilers 20 in the combustion state is large or when the by-product gas consumption (hydrogen gas consumption) is large, if the tank pressure value becomes smaller than the unit control target pressure value ( When the gas supply amount is suddenly reduced), the unit control target pressure value is set high and the time until the control lower limit pressure value is reached is increased, so that the combustion in the boiler 20 in the combustion state is stopped without stopping the combustion. It is possible to follow up by reducing the gas consumption of the boiler 20 in the state.
Further, when the number of boilers 20 in the combustion state is small or when the by-product gas consumption (hydrogen gas consumption) is small, if the tank pressure value becomes larger than the unit control target pressure value (gas supply amount) Is suddenly increased), the unit control target pressure value is set low, and the time until the control upper limit pressure value is reached is increased, so that the newly selected combustion start boiler 20 can start combustion. This can be followed by increasing the gas consumption of the small number of boilers 20 in the combustion state.
By doing so, overshoot and undershoot hardly occur, and stable control becomes possible.
Note that the number control target pressure value corresponding to the number of the boilers 20 in the boiler group 2 in the combustion state or the by-product gas consumption (hydrogen gas consumption) may be set in the storage unit 51 in advance.

<When a failure occurs in the boiler 20>
The control of the number of units when a failure occurs in the boiler 20 will be described. When the local control unit 201 detects that a predetermined abnormality to stop the boiler 20 controlled by the local control unit 201 has occurred, the local control unit 201 notifies the number control device 50 of the occurrence of the abnormality in the boiler 20. And the combustion of the boiler 20 is stopped.
When receiving the above-described abnormality occurrence signal from the local control unit 201, the number control device 50 transmits a combustion instruction to the boiler 20 in the combustion stop state (standby state). When transmitting the above-described combustion instruction to the boiler 20 in the combustion stopped state (standby state), the number control device 50 has the highest priority among the boilers 20 in the combustion stopped state (standby state). It is preferable to transmit a combustion instruction to the boiler 20. When transmitting the combustion instruction to the boiler 20 in the combustion stopped state (standby state), the number control device 50 uses the same combustion amount (gas consumption amount) as the combustion amount (gas consumption amount) of the boiler 20 stopped in combustion due to the occurrence of the abnormality. It is preferable to burn (consumption) gas consumption.
In this way, when the local control unit 201 detects that a predetermined abnormality has occurred in the boiler 20 controlled by itself, the local control unit 201 stops burning the boiler 20 and sends an abnormality occurrence signal to the number control device 50. The transmission enables the number control device 50 to start the combustion of the boiler 20 in the combustion stopped state (standby state), so that the tank pressure value is not changed.

<Control when tank pressure drops>
Next, control of the number of units when the tank pressure value decreases will be described. If the tank pressure value is too low, the plant equipment upstream of the boiler system 1 will be affected. For example, there is a possibility that the influence (deterioration, malfunction, damage, etc. of the equipment / equipment) may be exerted on the electrolytic equipment provided in the plant equipment.
On the other hand, in the unit control, if the tank pressure value continues to be lower than the unit control target pressure value, the required gas consumption MV _n calculated by the required gas consumption calculating unit 520 becomes smaller and smaller. May be zero or less than zero.
As described above, if the tank pressure value is too low, the upstream plant equipment is affected. Therefore, finally, it is necessary to bring all the boilers 20 into the combustion stop state at a certain timing. However, in the case where the combustion of all the units is stopped, when starting the combustion thereafter, for example, several tens of seconds are required before the combustion stop boiler starts the combustion (that is, before the consumption of the hydrogen gas is started). Become. Then, the tank pressure value continues to increase until the combustion stop boiler starts combustion. If the tank pressure value exceeds the unit control upper limit pressure value, the tank pressure value is arranged in the secondary hydrogen tank 30 as described later. By adjusting the opening degree of the hydrogen gas discharge valve 33, the hydrogen gas has to be released and energy loss may occur.

In this case, the consumption control unit 525 determines that the required gas consumption calculated by the required gas consumption calculation unit 520 falls below the minimum gas consumption when the number of the boilers 20 in the combustion state becomes one. Even so, the boiler 20 in the combustion state is burned with the minimum gas consumption until the tank pressure value falls below the control lower limit pressure value.
By doing so, if the required gas consumption increases and the tank pressure value rises (for example, when it becomes larger than the unit control target pressure value), the boiler in the combustion state with the minimum gas consumption 20 makes it possible to follow up by increasing the gas consumption.
When the tank pressure value falls below the control lower limit pressure value, the consumption control unit 525 causes the boiler 20 in the combustion state to immediately stop combustion, that is, to put all the units in a standby state.
In this case, as described above, the number control device 50 (the consumption control unit 525) performs post-purging of at least one boiler 20 (for example, the highest-priority boiler 20 to start combustion next) and performs pilot purging. It is preferable to control the combustion so as to maintain the pilot combustion state. Then, when the tank pressure value exceeds the pressure value obtained by adding the preset control lower limit pressure differential value to the control lower limit pressure value, the combustion device selecting unit 523 causes the boiler 20 having the highest priority to burn. It is selected as a start boiler, and is controlled by the consumption control unit 525 so as to burn quickly with a preset minimum gas consumption.

  Further, in the case where the above-described other embodiment related to the pilot combustion holding control is applied, when all the units are in the standby state, the pilot combustion of at least one boiler 20 (for example, the highest priority boiler 20 to start combustion next). Preferably, the condition is continued. By doing so, if the tank pressure value exceeds the pressure value obtained by adding the preset control lower limit pressure differential value to the control lower limit pressure value, the boiler 20 is selected as the combustion start boiler by the combustion device selector 523. Is controlled by the consumption control unit 525 so as to burn quickly with the preset minimum gas consumption.

<Boiler interlock stop>
For example, when the number control is not performed normally due to the failure of the hydrogen pressure sensor 31 and the consumption control unit 525 cannot stop the boiler 20 in the combustion stop state, that is, when all the units cannot be in the standby state, the tank pressure value has decreased too much. At this time, as described above, since the plant equipment upstream of the boiler system 1 is affected, a supply gas pressure switch is provided in advance for each of the boilers 20 and the supply gas pressure switch is activated by a decrease in the supply gas pressure. It is preferable to forcibly stop the boiler 20 from burning. Thereby, it is possible to prevent the plant equipment upstream of the boiler system 1 from being affected.
The control lower limit pressure value is preferably set to a pressure value higher than a pressure limit value (also referred to as “interlock”) at which the supply gas pressure switch operates.

<About air release control>
Next, the air discharge control of the number control device 50 will be described.
As described above, if the tank pressure value rises rapidly and exceeds the control upper limit pressure value due to, for example, an abnormal stop of some of the boilers 20, a failure of the hydrogen pressure sensor 31, or the like, the number control device 50 The tank pressure value is set in advance by controlling the opening / closing or opening degree of the hydrogen gas discharge valve 33 disposed in the 30 to adjust the amount of hydrogen gas stored in the secondary hydrogen tank 30. Control so as not to exceed the set upper limit pressure value. For this reason, the control unit 52 further includes a valve control unit 528 as shown in FIG.
More specifically, for example, when setting the upper limit pressure value to a value equal to the control upper limit pressure value, the valve controller 528 determines that the tank pressure value exceeds the preset control upper limit pressure value as described above. In such a case, the opening degree of the hydrogen gas discharge valve 33 as a pressure value adjustment valve disposed in the secondary hydrogen tank 30 is controlled so that the tank pressure value does not exceed the control upper limit pressure value.
As described above, a safety valve (not shown) may be arranged in the secondary hydrogen tank 30 separately from the hydrogen gas discharge valve 33. Even if the hydrogen gas discharge valve 33 fails, the safety valve can discharge the hydrogen gas stored in the secondary hydrogen tank 30 by finally opening the safety valve. Thus, it is possible to prevent the plant equipment upstream of the boiler system 1 from being affected.
During the air release control, for example, when the boiler 20 that has stopped abnormally starts burning, the hydrogen gas release valve 33 is gradually closed, and finally becomes a fully closed state, and the tank pressure value becomes the control upper limit. It becomes less than the pressure value. Then, the number controller 50 controls the hydrogen gas consumption in the boiler group 2 so that the tank pressure value falls within the preset pressure value range again.

<Modification of Valve Control Unit 528>
Note that the valve control unit 528 may be a separate device from the number control device 50. When the valve control unit 528 is a separate device, coordination control between these devices is not performed, and indirect coordination can be performed by the tank pressure value, which is common input information of both devices, and the set pressure value of each device. it can.

<Another embodiment of air release control>
As described above, the air release control method is not limited to the control method described above. In place of the upper limit pressure value, a target pressure value for air release valve control (hereinafter, also referred to as “air discharge target pressure value”) is set. The unit 528 may control the opening and closing or the opening degree of the hydrogen gas discharge valve 33 disposed in the secondary hydrogen tank 30 so that the tank pressure value maintains a preset discharge target pressure value. Good. In addition, you may set the discharge target pressure value to the value below the upper limit (control upper limit pressure value) of a pressure value range.

<About the hunting phenomenon>
As described above, when the tank pressure value falls below the control lower limit pressure value, the number control device 50 (the consumption control unit 525) puts the boiler 20 in the combustion state into an immediate combustion stop state, that is, puts all the units in a standby state, The consumption is zero. On the other hand, even when the gas consumption becomes zero, the hydrogen gas generated as a by-product gas in the plant equipment is supplied to the secondary hydrogen tank 30. For this reason, if the gas supply amount suddenly increases, even if the combustion stop boiler 20 is started to burn, an event that exceeds the control upper limit pressure value occurs because the tank pressure value rises rapidly in a short time. there is a possibility. Then, the number control device 50 is forced to release the hydrogen gas by adjusting the opening of the hydrogen gas discharge valve 33 arranged in the secondary hydrogen tank 30.
Thereafter, when the combustion stop boiler 20, which has been delayed in response, starts burning, the gas consumption increases at a stretch, the tank pressure value drops rapidly in a short time, and the combustion start boiler does not completely reduce the gas consumption. There is a possibility that the tank pressure value falls below the control lower limit pressure value again, and the boiler 20 in the combustion state is immediately put into the combustion stop state, that is, all the units are in the standby state.
As a result, the gas consumption becomes zero, and the hydrogen gas generated as a by-product gas in the plant equipment is supplied to the secondary hydrogen tank 30, so that the tank pressure value rapidly rises again in a short time, and the control upper limit pressure value When the combustion stop boiler 20, which has been delayed in response, starts burning, the gas consumption increases at a stretch, and the tank pressure decreases. There is a possibility that all cars will be on standby without being controlled. This repetition causes a so-called hunting phenomenon in which the tank pressure value fluctuates up and down without converging to the unit control target steam pressure value, and continues.

The hunting occurrence factor will be described with reference to FIG. 4A. As shown in FIG. 4A, in FIG. 4A, after the tank pressure value falls below the control lower limit pressure value and all the units are in a standby state, the gas pressure becomes zero, so that the tank pressure value rises sharply and the boiler burns. Even when the start instruction is given, the control is switched to the gas discharge control by the hydrogen gas discharge valve 33 in FIG. Thereafter, the boiler remain shift occurs due to a delay in the combustion proceeds, lower the tank pressure value (c), the required gas consumption between the gas consumption amount actually consumed needed gas consumption MV _n time Even if the gas pressure decreases, the actual gas consumption does not reach the required gas consumption, and therefore continues to increase. As a result, the tank pressure cannot be suppressed sufficiently and the tank pressure decreases again in (d). Falls below the control lower limit pressure value, and all units are on standby. Thus, it can be explained that hunting occurs.

<Hunting suppression control>
In the present invention, in order to prevent the occurrence of such a hunting phenomenon beforehand, and even if the hunting phenomenon occurs, the required gas consumption calculating unit 520 further includes: The following configuration is provided.
The required gas consumption calculating section 520 uses a speed-type PID algorithm to control the tank pressure value so as to keep the tank pressure value at the unit control target pressure value with respect to the fluctuation of the supply amount of the hydrogen gas to the secondary side hydrogen tank 30. the necessary gas consumption MV _n time in the periodic n, the control period preceding required gas consumption in _n-1 MV _n-1, and the aforementioned equations (6) - (10) required in each control cycle is calculated based on based on gas consumption variation .DELTA.MV _n, it is calculated by the aforementioned equation (5).
Then, the required gas consumption calculation unit 520 determines that the tank pressure value rises to satisfy a predetermined condition while at least one of the boilers 20 is burning (consuming gas), and thereafter the tank pressure value rises. When the tank pressure value changes from rise to decrease in the control cycle n, the value of the current required gas consumption MV _n in the boiler group 2 calculated by the actual gas consumption calculation unit 521 in the control cycle n in which the tank pressure value changes from rise to decrease Calculated by adding the previous required gas consumption MV _n-1 in the control cycle n-1 replaced with the actual gas consumption, which is the actual hydrogen gas consumption, and the required gas consumption change ΔMV _n for each control cycle. (Hereinafter referred to as “configuration A”).
In addition, the required gas consumption calculation unit 520 is configured to increase the pressure value inside the by-product gas tank that satisfies a predetermined condition when at least one of the combustion devices is burning, instead of the above-described configuration. Occurs, and thereafter, when the pressure value inside the by-product gas tank changes from rising to decreasing, the current required gas consumption MV in the control cycle n in which the pressure value inside the by-product gas tank changes from rising to falling _The configuration may be such that the value of _n is calculated by replacing the actual gas consumption amount consumed by the actual combustion device (hereinafter, referred to as “configuration B”).
Here, the rise that satisfies the predetermined condition of the tank pressure value means, for example, that the tank pressure value rises due to the undershoot of the tank pressure value, or that the tank pressure value rises and overshoots. May be included.
Further, the rise that satisfies the predetermined condition of the tank pressure value may include that the tank pressure value falls below the control lower limit pressure value, or that the tank pressure value exceeds the control upper limit pressure value.
In addition, the rise that satisfies the predetermined condition of the tank pressure value may include that all the boilers 20 are on standby when the tank pressure value is lower than the control lower limit pressure value.
The consumption control unit 525 controls the combustion state (consumed gas) of the boiler 20 in the control cycle n so as to generate the current required gas consumption MV _n corrected as described above by the required gas consumption calculation unit 520. I do.
By doing so, the occurrence of the hunting phenomenon can be prevented beforehand, and even if the hunting phenomenon occurs, the hunting phenomenon can be quickly converged.

An operation of preventing the occurrence of the hunting phenomenon and converging the hunting phenomenon promptly even if the hunting phenomenon occurs will be described with reference to FIG. 4B.
As shown in FIG. 4B, the gas control is switched to the gas discharge control by the hydrogen gas discharge valve 33 in (b), and then to the number control again, and the required gas at the time when the tank pressure value changes from rising to falling in (c). By performing the correction for replacing the consumption amount with the actually consumed gas consumption amount, it is possible to suppress the increase in the actually consumed gas consumption amount and suppress the undershoot. Thus, the occurrence of the hunting phenomenon can be prevented beforehand, and even if the hunting phenomenon occurs, the hunting phenomenon can be quickly converged.

<About startup control>
Next, start-up control of the boiler system 1 will be described. As described above, in the boiler system 1, the hydrogen gas supplied from the by-product facility is pressurized, supplied to the secondary hydrogen tank 30, and stored. When the tank pressure value becomes equal to or higher than the lower limit supply pressure value required for supplying hydrogen gas to the boiler group 2, the boiler 20 can consume hydrogen gas.
Then, in the conventional boiler system 1, at the time of startup, after detecting that the tank pressure value becomes equal to or higher than the lower limit supply pressure value, pre-purge is started for ventilation in the furnace, and the hydrogen supply gas line L22 is disconnected during the pre-purge. Purging was performed with an active gas (for example, nitrogen gas), and the combustion of the combustion start boiler 20 was started after pilot ignition and pilot stabilization. For this reason, during pre-purge, pilot ignition, and pilot stabilization (about 30 seconds), hydrogen gas as a by-product gas is supplied to the secondary hydrogen tank 30, but the combustion start boiler 20 does not burn hydrogen gas ( (Not consumed) state, and as a result, the tank pressure value rapidly rises and often exceeds the control upper limit pressure value.
Accordingly, in order to lower the tank pressure value, it is necessary to control the opening / closing or opening degree of the hydrogen gas discharge valve 33 to discharge the hydrogen gas stored in the secondary hydrogen tank 30, and to reduce energy consumption. It was causing waste.
In the present invention, in order to avoid such waste of energy, the control unit 52 further includes a start-up control unit 529 as shown in FIG.

<Startup control unit 529>
When the boiler system 1 is started, for example, by pressing a start button or the like, the start-up control unit 529 selects, for example, a predetermined number of boilers 20 set in advance in descending order of priority and performs ventilation in the furnace. The pre-purge is started, the hydrogen supply gas line L22 is purged with an inert gas (for example, nitrogen gas) during the pre-purge, and after the pilot ignition and the pilot stabilization, the pilot pressure is maintained for a predetermined time. Is detected to be equal to or higher than the lower limit supply pressure value, and then the combustion of the combustion start boiler 20 is controlled to start. Here, the predetermined number is one or more, including the case of all the units. In the pilot combustion, for example, 13A gas is used instead of hydrogen gas as a by-product gas. Therefore, for example, a pilot fuel line (not shown) for supplying 13A gas is provided separately from the main combustion fuel line for supplying hydrogen gas as a by-product gas. By doing so, regardless of the hydrogen supply gas pressure, the pre-purged boiler 20 can be pilot-burned even if the hydrogen supply gas pressure value is low. After that, while maintaining the pilot combustion state, the hydrogen gas supplied from the by-product facility is pressurized, and when the tank pressure value becomes equal to or higher than the lower limit supply pressure value required to supply the hydrogen gas to the boiler group 2, The number control device 50 (the consumption control unit 525) controls the gas consumption in the boiler group 2 so as to burn the boiler 20 in the pilot combustion state so that the tank pressure value falls within a preset pressure value range. Start. The pilot fuel line is not limited to a line that supplies 13A gas. For example, irrespective of the hydrogen supply gas pressure from the secondary hydrogen tank 30, the amount and the amount necessary for pilot combustion are set so that the pre-purged boiler 20 can be pilot-burned even if the hydrogen supply gas pressure value is low. A pilot fuel line that can supply hydrogen gas as a pressure by-product gas may be provided.
By controlling at the time of starting as described above, it becomes possible to cause the boiler 20 to perform main combustion without releasing the hydrogen gas stored in the secondary-side hydrogen tank 30, thereby preventing waste of energy and safety. Can be improved.

<Manual control>
Lastly, for example, when the number control of the boiler group 2 cannot be normally performed due to a failure of the hydrogen pressure sensor 31 for measuring the tank pressure value, a communication failure between the number control device 50 and the boiler 20, or the like, The manual operation will be described.
When the operation is switched to the manual operation for controlling the individual boilers, it is preferable to suppress the boiler combustion amount (that is, the hydrogen gas consumption amount) as much as possible. This is based on the idea that it is safer not to burn the boiler 20 in the event of an abnormality. However, since a sudden change in the boiler combustion amount (gas consumption) immediately after switching to the manual operation greatly affects the secondary-side hydrogen tank 30, the boiler combustion amount (gas consumption) must be suppressed slowly. Is preferred.
Therefore, during the manual operation, the combustion amount (gas consumption) of the entire boiler is reduced from the combustion amount (gas consumption) immediately before switching to the manual operation, and the combustion amount (gas consumption amount) of each combustion boiler 20 is reduced. ) Is not expected to change suddenly.
However, since the boiler control during the manual operation is a constant pressure control of the pressure of the boiler 20 itself, there is a possibility that the combustion amount (gas consumption amount) increases or sudden changes occur. In addition, since the boiler 20 during which combustion is stopped starts combustion (gas consumption) by manual operation, the amount of combustion (gas consumption) in the boiler group 2 may increase.
Furthermore, from the viewpoint of boiler can body protection during manual operation, it is necessary to stop combustion when high pressure is detected.
For this reason, the local control unit 201 included in each boiler 20 determines the combustion state of the boiler 20, for example, when the reception of the control signal transmitted from the number control device 50 is stopped. When it is determined that the boiler 20 is in a combustion state, the local control unit 201 gradually reduces the amount of combustion (gas consumption) by the boiler 20 and then sets the boiler 20 to a predetermined minimum gas consumption. It controls so that it may burn. Further, when it is determined that the boiler 20 is in the combustion stopped state, the local control unit 201 maintains the combustion stopped state of the boiler 20. Further, when the pressure of the boiler 20 exceeds a preset high set pressure value, the local control unit 201 controls so as to stop the combustion of the boiler 20.
By doing so, the combustion amount (gas consumption amount) of the entire boiler is reduced from the combustion amount (gas consumption amount) immediately before switching to the manual operation, and the combustion amount (gas consumption amount) of each combustion boiler 20 is suddenly changed. Without doing so, the boiler group 2 can be operated safely.
The embodiments of the respective functional units of the boiler system 1 of the present invention have been described based on the configuration of the unit control device 50, the once-through boiler 20, which is a hydrogen boiler, and the like.

Next, the flow of the number control and the air discharge control in the boiler system 1 of the present embodiment will be described with reference to FIGS. 5A to 5D. FIG. 5A to FIG. 5D are flowcharts illustrating the flow of processes related to the number control and the air release control of the control unit 52 of the present embodiment.
Here, as preparations for the processing, information on a pressure value preset with respect to the tank pressure value (control lower limit pressure value, unit control target pressure value, control upper limit pressure value, air release control upper limit pressure value), a plurality of once-through boilers 20, information about the unit gas consumption, information about the maximum gas consumption, and information about the minimum gas consumption, which are preset for each of the boiler group 2, and information about the additional line, which is preset for the boiler group 2. It is assumed that information on the reference gas consumption and information on the reduction line are stored. Further, it is assumed that the boiler system 1 is activated and consumes hydrogen gas as a by-product gas generated from the plant equipment.

  Referring to FIG. 5A, in step ST101, the number control device 50 detects whether or not the tank pressure value is within the number control pressure band (that is, within the range from the control lower limit pressure value to the control upper limit pressure value). When the tank pressure value is within the unit control pressure band (that is, within the range from the control lower limit pressure value to the control upper limit pressure value) (YES), the process proceeds to step ST102. If the tank pressure value is not within the number control pressure band, the process proceeds to step ST201 (air release control or minimum combustion control) described later in FIG. 5D.

  In step ST102, the number control device 50 (the required gas consumption calculating unit 520) calculates a required gas consumption amount, which is a gas amount to be consumed by the boiler group 2, based on the tank pressure value and the number control target pressure value. .

  In step ST103, the number control device 50 (actual gas consumption calculation unit 521) uses the hydrogen gas in each of the boilers 20 in the combustion state based on the hydrogen gas consumption state (combustion state, hydrogen gas consumption) of each boiler 20. The actual gas consumption which is the actual gas consumption is calculated, and the actual gas consumption which is the actual hydrogen gas consumption in the boiler group 2 is calculated.

  In step ST104, the number control device 50 (the second determination unit 5242) determines whether the gas consumption of each of the boilers 20 in the combustion state is equal to or greater than the gas consumption specified by the additional line, or Is determined. If the gas consumption of each of the boilers 20 in the combustion state is equal to or greater than the gas consumption specified by the additional line (YES), the processing will be described later with reference to FIG. The process moves to step ST111 (addition control). Otherwise (NO), the process moves to step ST105.

  In step ST105, the number control device 50 (the second determination unit 5242) determines that the plurality of boilers 20 are in the combustion state, and the gas consumption of each of the boilers 20 in the combustion state is equal to or less than the gas consumption defined by the reduction line. , Or less than the gas consumption. If the gas consumption of each of the boilers 20 in the combustion state is equal to or less than the gas consumption specified by the reduction line (YES), the process is described later in FIG. 5C. The process proceeds to ST121 (reduction control). Otherwise (NO), the process moves to step ST106.

  In step ST106, the number control device 50 (deviation calculation unit 522) calculates the deviation between the required gas consumption calculated in step ST102 and the actual gas consumption of the boiler group 2 calculated in step ST103.

  In step ST107, when the tank pressure value is larger than the unit control target pressure value, the number control device 50 (combustion device selection unit 523) selects the boiler 20 (gas consumption When the tank pressure value is smaller than the unit control target pressure value, the boiler 20 that consumes a large amount of hydrogen gas (the boiler that consumes a large amount of gas) is selected from among the boilers 20 in the combustion state. .

  In step ST108, when the deviation amount calculated in step ST106 is a positive value, the number control device 50 (the first determination unit 5241) determines that the deviation amount is a unit preset in the “boiler 20 with small gas consumption”. It is determined whether the gas consumption is equal to or more than the gas consumption. When the deviation amount is a negative value, the absolute value of the deviation amount is equal to or more than the unit gas consumption set in advance in the “boiler 20 having a large gas consumption”, and the unit gas consumption is calculated from the hydrogen gas consumption. It is determined whether the value obtained by subtracting the minute amount is equal to or more than the minimum gas consumption. When the deviation amount is equal to or more than the unit gas consumption amount preset in the “boiler 20 with low gas consumption” (YES), or the absolute value of the deviation amount is preset in the “boiler 20 with large gas consumption”. If it is equal to or greater than the unit gas consumption and the value obtained by subtracting the unit gas consumption from the hydrogen gas consumption is equal to or greater than the minimum gas consumption (YES), the process proceeds to step ST109. Otherwise (NO), the process moves to step ST101.

  In step ST109, when the deviation amount is a positive value, the number controller 50 (consumption controller 525) determines the hydrogen gas consumption of the “boiler 20 with low gas consumption” selected in step ST107 as the unit gas consumption. Increase by the amount. When the deviation is a negative value, the number controller 50 (consumption controller 525) calculates the unit gas consumption from the hydrogen gas consumption of the “boiler 20 with large gas consumption” selected in step ST107. Decrease. After that, the process moves to step ST101.

<Additional control>
Referring to FIG. 5B, in step ST111, the number control device 50 (combustion device selection unit 523) newly starts burning the highest priority boiler 20 among the boilers 20 whose combustion has been stopped from the boiler group 2. Is selected as the boiler 20 (combustion start boiler).

  In step ST112, the number control device 50 (the consumption control unit 525) causes the boiler 20 selected in step ST111 to burn the boiler 20 with a preset minimum gas consumption.

  In step ST113, the number control device 50 (target pressure switching unit 527) switches the number control target pressure value according to the number of boilers 20 in the combustion state. After that, the process moves to step ST101. Step ST113 is applied only when the number control device 50 includes the target pressure switching unit 527 that switches the number control target pressure value according to the number of boilers 20 in the combustion state.

<Regarding additional control based on increased reserve>
5A and 5B, the processing flow for increasing the gas consumption when the gas consumption of the boiler 20 in the combustion state is equal to or more than the gas consumption specified by the additional line has been described, but the present invention is not limited to this. As described above, the system may be increased when it is determined that the total increase reserve gas consumption becomes equal to or less than the increase reference gas consumption or falls below the increase reference gas consumption.
The processing flow in this case is as follows. In step ST104 of FIG. 5A, the number control device 50 (the second determination unit 5242) determines that the total increase reserve gas consumption calculated by the reserve calculation unit 526 consumes hydrogen gas (combustion). It is determined whether the gas consumption is equal to or less than the increased reference gas consumption, which is a reference for increasing the number of boilers 20 to be operated, or less than the increased reference gas consumption. If it is lower than the reference gas consumption (YES), the process proceeds to step ST111; otherwise (NO), the process proceeds to step ST106. "

<Reduction control>
Referring to FIG. 5C, in step ST121, the number control device 50 (the combustion device selection unit 523) newly stops the combustion of the boiler 20 with the lowest priority among the boilers 20 in the combustion state from the boiler group 2. It is selected as the boiler 20 (stop combustion boiler).

  In step ST122, the number controller 50 (consumption controller 525) changes the gas consumption of the stopped combustion boiler 20 selected in step ST121 with respect to the change in the tank pressure value.

  In step ST123, the number control device 50 (the consumption control unit 525) determines whether the gas consumption of the stopped combustion boiler 20 has decreased to the minimum gas consumption preset for the boiler 20. If it has decreased to the minimum gas consumption (YES), the process proceeds to step ST124. If not reduced to the minimum gas consumption (NO), the process proceeds to step ST101.

  In step ST124, the number control device 50 (the consumption control unit 525) stops the combustion of the stopped combustion boiler 20.

  In step ST125, after performing the post-purge of the stopped combustion boiler 20, the number control device 50 (the consumption control unit 525) performs pilot combustion and maintains the pilot combustion state.

  In step ST126, the number control device 50 (the target pressure switching unit 527) switches the number control target pressure value according to the number of the boilers 20 in the combustion state. After that, the process moves to step ST101. Step ST126 is applied only when the number control device 50 includes the target pressure switching unit 527 that switches the number control target pressure value according to the number of boilers 20 in the combustion state.

  Referring to FIG. 5D, when the tank pressure value exceeds the control upper limit pressure value in step ST201, the process proceeds to step ST202. If the tank pressure value is lower than the control lower limit pressure value, the process moves to step ST211.

<Air release control>
In step ST202, the number control device 50 (the valve control unit 528) controls the opening degree of the hydrogen gas discharge valve 33 so that the tank pressure value does not exceed the control upper limit pressure value. After that, the process moves to step ST101.

<Process when tank pressure drops>
In step ST211, the number control device 50 (the consumption control unit 525) sets the boiler 20 in a combustion state to a combustion stop state, that is, a standby state for all units.

  In step ST212, the number control device 50 (the consumption control unit 525) performs post-purging of at least one (for example, the highest priority) stopped combustion boiler 20, performs pilot combustion, and maintains the pilot combustion state. . The process moves to step ST101.

  According to the boiler system 1 of the present embodiment described above, the following effects can be obtained.

(1) In the plurality of boilers 20, the minimum gas consumption which is the gas consumption in the smallest combustion state is set, and the pressure value inside the secondary hydrogen tank 30 is within a predetermined pressure value range. And a control unit for controlling the consumption of hydrogen gas in the boiler group 2 so as to match the target pressure value set in the boiler group 2. Even if it falls below, the boiler 20 is burned with the minimum gas consumption until the pressure value inside the secondary hydrogen tank 30 falls below the preset lower limit pressure value.
Thereby, the gas consumption can be continued as much as possible. Further, if the required gas consumption increases and the tank pressure value increases (for example, when the tank pressure value becomes larger than the unit control target pressure value), the boiler 20 in the combustion state with the minimum gas consumption reduces the gas consumption. It is possible to follow up by increasing the consumption amount.

(2) When the tank pressure value exceeds a preset upper limit pressure value as a pressure value higher than the target pressure value, the valve control unit 528 controls the tank pressure value so that the tank pressure value does not exceed the upper limit pressure value. The opening degree of the hydrogen gas discharge valve 33 as a pressure value adjusting valve disposed in the secondary hydrogen tank 30 is controlled.
Thereby, by controlling the tank pressure value not to exceed the preset upper limit pressure value, when the tank pressure value slightly exceeds the upper limit pressure value, a small amount of air release is started, and the tank pressure value is further increased. When the temperature rises, the amount of air release is controlled to increase, so that the discharge of hydrogen gas (by-product gas) can be minimized, and the pressure stability of the boiler system 1 can be improved.

(3) Further, as a configuration different from (2), the valve control unit 528 is configured to control the hydrogen gas as a pressure value adjusting valve disposed in the secondary-side hydrogen tank 30 so as to maintain the discharge target pressure value. The discharge valve 33 may be controlled.
Thereby, by controlling so as to maintain the discharge target pressure value, a small amount of discharge starts when the tank pressure value approaches the discharge target pressure value, and the discharge amount increases when the tank pressure further increases. Thus, the discharge of hydrogen gas (by-product gas) can be minimized, and the pressure stability of the boiler system 1 can be improved.

(4) Further, the target discharge pressure value may be set to a value equal to or less than the upper limit value (control upper limit pressure value) of the pressure value range.
Thereby, it is possible to prevent the tank pressure value from exceeding the upper limit pressure value and reaching the booster stop pressure value to stop the boiler system, and to stably control (reduce fluctuation) the tank pressure value.

  (5) The local control unit 201 can control the gas discharge amount corresponding to the gas consumption amount that the boiler 20 can no longer consume by the opening degree of the hydrogen gas discharge valve. As a result, even when gas consumption becomes impossible due to the boiler 20 in the combustion state, the gas amount corresponding to the gas consumption amount of the boiler 20 is temporarily discharged, so that the pressure fluctuation of the tank pressure value is achieved. Can be suppressed.

  The preferred embodiments of the boiler system of the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and can be appropriately modified.

<Modification 1>
In the present embodiment, the hydrogen gas is exemplified as the by-product gas, but the present invention is not limited to this. For example, the present invention can be applied to any by-product gas such as digestive gas and other hydrocarbon gas.

<Modification 2>
In the present embodiment, the present invention has exemplified the boiler system 1 including the boiler group 2 including the four once-through boilers 20, but is not limited thereto. That is, the present invention may be applied to a boiler system including a boiler group including five or more once-through boilers, or may be applied to a boiler system including a boiler group including three or less once-through boilers.

<Modification 3>
In the description of the flowchart (FIG. 5A) illustrating the flow of the gas consumption leveling process of the boiler 20 of the boiler system 1, it has been described that the process is shifted to the step ST101 after the step ST109, but the present invention is not limited to this.
For example, in FIG. 5A, after step ST109, the actual gas consumption may be calculated so as to increase or decrease by the unit gas consumption, and then the process may be shifted to step ST106 again. In this case, in step ST108, after it is determined that the deviation between the required gas consumption amount and the actual gas consumption amount is less than the unit gas consumption amount, control is performed so that the process proceeds to step ST101.

<Modification 4>
In the present embodiment, a continuous control boiler is exemplified as the once-through boiler 20, but the present invention is not limited to this. For example, the hydrogen gas consumption is controlled by selectively turning on / off the combustion or setting the combustion position to high combustion, medium combustion, low combustion, etc., and according to the selected combustion position. You may apply to the step value control boiler which can increase and decrease hydrogen gas consumption step by step.

<Modification 5>
In the present embodiment, a case in which the hydrogen gas is discharged by controlling the opening / closing or opening of the hydrogen gas discharge valve 33 disposed in the secondary hydrogen tank 30 by the valve control unit 528 as the discharge control. However, the present invention is not limited to this.
For example, a hydrogen gas discharge valve (not shown) is installed in the hydrogen gas branch line L22 or the hydrogen gas main line L21 in addition to or instead of the hydrogen gas discharge valve 33 arranged in the secondary hydrogen tank 30. You may do so.
By doing so, for example, when the local control unit 201 detects that an abnormality has occurred in the boiler 20 in a combustion state and the boiler 20 has become unable to consume gas, the local control unit 201 supplies hydrogen gas to the boiler 20. By controlling the opening degree of the hydrogen gas discharge valve installed in the gas branch line L22 or the hydrogen gas main line L21, the boiler 20 may be configured to control so as to discharge an unconsumable gas amount. .
As described above, the local control unit 201 can control the gas release amount corresponding to the gas consumption amount that the boiler 20 can no longer consume by the opening degree of the hydrogen gas release valve. Thereby, even if some abnormality occurs in the boiler 20 in the combustion state and gas consumption cannot be performed by the boiler 20, the gas amount corresponding to the gas consumption amount of the boiler 20 is discharged, It is possible to suppress the pressure fluctuation of the tank pressure value.
At this time, the local control unit 201 may be configured to notify the number control device 50 of the abnormal state of the boiler 20 and the amount of gas that cannot be consumed. By doing so, the number control device 50 allocates the unconsumable gas amount of the boiler 20 that can no longer consume the gas to the boiler 20 in another combustion state and discharges the unconsumable gas amount. The hydrogen gas release valve whose opening is controlled can be closed directly or via the local control unit 201. Thereby, even if some abnormality occurs in the boiler 20 in the combustion state and gas consumption becomes impossible by the boiler 20, the pressure fluctuation of the tank pressure value can be suppressed.
More specifically, when the boiler 20 is a continuous control boiler, the local control unit 201 may be configured to control the opening of the hydrogen gas discharge valve so as to discharge the unconsumable gas amount. . Thereafter, after the unconsumable gas amount is allocated to the boiler 20 in another combustion state, the opening of the hydrogen gas discharge valve can be closed.
Further, in the case where the boiler 20 is, for example, a step value control boiler 2 having one or more combustion positions and capable of gradually increasing or decreasing the hydrogen gas consumption according to the selected combustion position, each of the boilers 20 serves as a hydrogen gas discharge valve. By installing a hydrogen gas release valve (for convenience, referred to as a “combustion position-corresponding hydrogen gas release valve”) that releases gas corresponding to the gas supply amount at the combustion position, the boiler 20 can be moved to a predetermined combustion position (for example, high combustion When hydrogen gas is consumed at the position (i.e., the position), an abnormality occurs in the boiler 20, and when the boiler 20 cannot consume gas at a predetermined combustion position (for example, a high combustion position), the predetermined combustion By opening the hydrogen gas discharge valve that releases the gas corresponding to the gas supply amount at the position (for example, the high combustion position), the gas amount corresponding to the gas amount that cannot be consumed by the boiler 20 is discharged. Structure It may be. Then, after the unconsumable gas amount is allocated to the boiler 20 in another combustion state, the hydrogen gas discharge valve for releasing gas corresponding to the gas supply amount at a predetermined combustion position (for example, a high combustion position) is closed. It can be.

DESCRIPTION OF SYMBOLS 1 Boiler system 2 Boiler group 20 Once-through boiler (Hydrogen boiler)
201 Local control unit 24 Hydrogen gas flow control valve 25, 26 Hydrogen gas shutoff valve 30 Secondary hydrogen tank 31 Hydrogen pressure sensor (hydrogen pressure detection unit)
33 Hydrogen gas discharge valve 41 Sensor 42 Booster 44 Return flow regulating valve 50 Number control device 51 Storage unit 52 Control unit 520 Required gas consumption calculation unit 521 Actual gas consumption calculation unit 522 Deviation calculation unit 523 Combustion device selection unit 5241 First determination unit 5242 Second determination unit 525 Consumption control unit 526 Reserve calculation unit 527 Target pressure switching unit 528 Valve control unit 529 Start-up control unit L1 By-product gas supply line L11 Return line L2 Hydrogen gas supply line L21 Hydrogen gas source Line L22 Hydrogen gas branch line L3 Hydrogen gas discharge line L4 Steam collecting line

Claims (7)

A by-product gas tank for storing by-product gas;
A pressure value measurement unit that measures a pressure value inside the by-product gas tank,
A combustion device group consisting of a plurality of combustion devices that burn and consume only the by-product gas stored in the by-product gas tank,
A control unit that controls the consumption of by-product gas in the combustion device group such that the pressure value inside the by-product gas tank matches a target pressure value set within a preset pressure value range. A by-product gas utilization system comprising:
In the plurality of combustion devices, a minimum gas consumption which is a gas consumption in the smallest combustion state is set,
The control unit includes:
Based on the pressure value inside the by-product gas tank, a required gas consumption calculator that calculates a required gas consumption that is a gas amount to be consumed,
An actual gas consumption calculator that calculates an actual gas consumption that is an actual gas consumption in the combustion device;
Even if the required gas consumption is less than the minimum gas consumption, until the pressure value inside the by-product gas tank measured by the pressure value measurement unit falls below a preset lower limit pressure value, the combustion device is A by-product gas utilization system comprising: a consumption control unit configured to burn at the minimum gas consumption.   The by-product gas utilization system according to claim 1, wherein the lower limit pressure value is a value equal to or less than a lower limit value of the pressure value range. The control unit includes:
When the pressure value inside the by-product gas tank exceeds an upper limit pressure value that is set in advance as a pressure value higher than the target pressure value, the pressure value inside the by-product gas tank exceeds the upper limit pressure value. 3. The by-product gas utilization system according to claim 1, further comprising a valve control unit that controls a pressure value adjustment valve disposed in the by-product gas tank so as not to be provided. 4.   The by-product gas utilization system according to claim 3, wherein the upper limit pressure value is equal to an upper limit value of the pressure value range. The control unit includes:
3. The valve according to claim 1, wherein the pressure value inside the by-product gas tank includes a valve control unit that controls a pressure value adjustment valve disposed in the by-product gas tank so as to maintain the discharge target pressure value. 3. The by-product gas utilization system as described.   The by-product gas utilization system according to claim 5, wherein the discharge target pressure value is equal to or less than an upper limit value of the pressure value range. The combustion device includes a local control unit,
The auxiliary device according to any one of claims 1 to 5, wherein the local control unit can control so as to discharge a gas amount corresponding to a gas consumption amount that the combustion device can no longer consume. Raw gas utilization system.

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