JPH02242011A - Controller of number of operated boilers - Google Patents

Abstract

PURPOSE:To make it possible to push back the steam pressure in a header to a target pressure value in the range of control rapidly and effectively by maintaining to the keep pressure of a value near the steam pressure value in the steam header the pressure of a boiler which is selected to start operation next according to the order of operation which is beforehand decided. CONSTITUTION:A specified number of boilers in combustion operation are controlled intermittently by three-position control, and the steam pressure in a steam header 1 is maintained in the range of control, but during that time keep pressure maintaining command means 4 supplies keep pressure maintaining command signals S4.1-S4.4 respectively for boilers that are selected for starting the operation next according to a beforehand preset order of operation out of boilers other than the boilers in combustion operation, and keep pressure control means C1-C4 which are attached to respective boilers control the combustion of boilers in response to command signals S4.1-S4.4 and keep the steam pressure of the boilers at a value lower than the operation pressure values of check valves V1-V4 and maintain them to the keep pressure that is set as the upper limit value close to the steam pressure in the steam header 1.

Description

[Detailed Description of the Invention] <Industrial Application Field> The present invention provides combustion control for each of a plurality of boilers connected in parallel to a steam header according to a predetermined operating order according to the steam pressure in the steam header. The number of boilers in operation is controlled to increase or decrease the number of the plurality of boilers in operation while maintaining pressure fluctuations in the steam header resulting from fluctuations in the steam load from the steam header within a predetermined control range. It is related to the device.

<Prior Art> FIG. 6 shows the configuration of a conventional example of this type of boiler operation number control device.

The steam header 1 includes a plurality of boilers, for example.

The first boiler B1 to the fourth boiler B4 each output steam pipe 21 to
They are commonly connected via P4 to enable parallel operation, and check valves V1 to V4 are provided in each of the output steam pipes P1 to P4, respectively. For example, a pressure regulator is connected to the steam header 1 as a steam pressure detection means 2, and a combustion number control means 3 is connected to the controller, and from the number control means 3, for example, a combustion command signal is sent. S2・1-92・
Combustion control signal lines for distributing and supplying combustion control signals consisting of 4 and combustion state signals S3.1 to 53-4 to the respective boilers Bl to B4.1 to L4 are connected to the first boiler B1 respectively.
- Connected to the fourth boiler B4. Q is a load steam pipe extending towards the steam load.

The combustion unit number control means 3 includes a circuit configuration as shown in FIG. output terminal 30@
1, 3oa3, 3o*53o*7 are relay drivers 3b, 1.2b, 2.2b, 3.3b-4, respectively.
Combustion command relay 3D・1.3D・2.3D・3,
30-4, while the output terminals 30/23o@4, 3o*e, 3o*8 of the step controller are
Relay driver 3c, 1.3c, 2,3cφ respectively
Combustion status relay 3E/1.3E/2 via 3.3c/4
．． It extends to 3E/3.3E@4.

And each relay 3D@1~3D・4, 3E-1~3E
・The hot side of 4 is commonly connected to power supply E.

The step controller 3a itself is publicly known and its operation is well known.

That is, each output terminal 3o, 1 to 3 is placed near the circuit diagram in FIG.
As is clear from the signal status table arranged corresponding to 0@8, the resistance of the output resistor 2a that moves in equilibrium with the vapor pressure detected in the pressure regulator as the vapor pressure detection means 2. Based on the value, a steam pressure signal St corresponding to the steam pressure is generated and supplied to the step controller 3a, where it is subjected to signal processing by a known multi-stage comparator or the like, and then output to each of the output terminals 30.l to 30. From No. 8, separate combustion command signals 32-1 to S2.4 and separate combustion state signals S3.1 to S3.8 are sent to the first boiler B1 to fourth boiler B4.
For example, as shown by a in the signal state table in FIG. 7, the steam pressure within the control range is 8.0.
When the steam pressure signal S1 corresponding to "Kg/cm" is input, the combustion command signal 52-1 from the output terminal 30.1 toward the first boiler 81 changes to rHJ, and the output terminal 3G.2
The combustion state signal 53φ1 remains at "L" for the first boiler, and the combustion command signals S2.2 to S2.4 and combustion state signals S3.2 to S3.4 for the other boilers B2 to B4.
remain at "L".

Thus, under this operating condition, combustion command relay 30.
Only the first boiler B1 is excited, and only the first boiler B1 starts combustion. At this time, the combustion state signal S3.l of "L" is transmitted to this boiler B1, and the combustion state relay 3
Since E.1 is de-energized, in the end this boiler B
1 performs combustion operation in a low combustion state.

In this way, the combustion command signal S2 for the first boiler B1 is
・Similar to the combustion command relay 3D・1 that responds to the combustion status signal S3・l, the contacts of the combustion status relay 3E-1 for the first boiler B1 that responds to the combustion status signal S3・l are attached to and incorporated in the first boiler B1. The circuit configuration is as shown in FIG.

The power supply E has two circuit interlocking changeover switches SWl and SW2.
Both rotary contacts are commonly connected, and the changeover switch Sw
The I side fixed contact of No. 1 is connected to the combustion command relay Zl via the meter contact 3d.1 of the combustion command relay 3Dφ1. Furthermore, the ■ side fixed contact of the changeover switch Swl is
It is connected to the combustion command relay 21 via an upper limit pressure switch GH that closes when the steam pressure in the first boiler B1 is lower than a preset upper limit pressure. It is also possible to set different upper limit pressures for each.

On the other hand, the 1 side fixed contact of the changeover switch SW2 is connected to the combustion state relay Z2 via the make contact 3e.1 of the combustion state relay 3E.1, and the side fixed contact of the switch SW2 is connected to the first boiler Bl. The combustion state relay 22 is connected to the combustion state relay 22 via a lower limit pressure switch CL that closes when the steam pressure inside the combustion chamber is lower than a preset lower limit pressure.

Currently, in the number control operation mode, selector switch SWI
, Since the movable contact of SW2 is linked and connected to the I side fixed contact, the upper and lower limit internal pressure switches OH and GL are not involved in the operation, and the state shown in a in the signal state table in Figure 7 is reached. Returning to continue the explanation, the excitation of the combustion command relay 30-1 closes the make contact 3d.1, and the first boiler 81
The boiler starts combustion operation by driving the combustion command relay Zl, but at this time, the combustion status relay 3E
Since make contact 3e・1 is closed when 1 is de-energized,
The combustion state relay Z2 of the first boiler B1 is not driven, and the boiler operates in a low combustion state of, for example, 5H.

Next, reflecting the decreasing trend in the steam load, the steam pressure within the control range decreased to 7.8 as shown in the signal status table in Figure 7.
Kg/crn', the combustion command signal S2.1 is sent from the output terminal 3o.1 to the first boiler B1, and the combustion state signal S3.1 is sent from the output terminal 30.2 to the first boiler B1.
1 becomes rHJ, and the same operation corresponding to this causes the combustion command relay 21 and combustion status relay z2 in FIG.
are driven together, so the first boiler B1 is, for example, 1
It operates in a high combustion state of 0.00 kg.

Then, combustion command relay Z in such intermittent three-position control
1. Drive state of combustion state relay 22 (rONJrOFF
FIG. 9 summarizes and shows the correspondence between J) and the boiler operating state.

In the subsequent operation in the number control operation mode, when the steam pressure drops to 7.8 Kg/crn' within the control range as shown in C in the signal status table in Figure 7, the Combustion command signal 52-1 and first boiler Bl
While the combustion state signals S3 and 1 for the second boiler are both kept at rHJ, the combustion command signal 52-2 for the second boiler B2 from the output terminal So and 3 changes to rHJ.
The combustion status signal S3.2 from No. 4 for the second boiler B2 remains at "L", and in response to this, the circuit configuration of the wIJs diagram attached to the second boiler B2 is changed. In the same circuit configuration provided separately and independently, the make contact 3d-2 of the combustion command relay 30.2 is closed, and as a result, while the first boiler B1 continues to operate in a high combustion state, the second
Boiler B2 starts operating in a low combustion state. In other words, even if the first boiler B1 operated at full capacity, it was not possible to push back the drop in steam pressure due to the increase in load, so the second boiler B2, which follows next in the operating order, was operated only half of the time in a low combustion state. A number-of-vehicles control operation was carried out. Hereinafter, there is no need to explain the entire details of the similar number-of-units control operation operation in detail, but it will be clear by referring to the signal status table shown in FIG.

If I may add, in the number control operation operation.

The steam pressure in the steam header 1 increases considerably due to the boiler in combustion operation, whereas the steam pressure in the boiler in non-combustion operation is low. There is a concern about the backflow of steam towards the output steam pipe 21.
~P4 is blocked by check valves V1 to V4 provided in P4.

By the way, in the individual operation mode, returning to Fig. 8, the movable contacts of the two changeover switches swt and sw2 are both closed.
Since it is connected to the side constant contact, this time the make contact 3d/1.3 of combustion command relay 30-1, 30-2...
d.2... and combustion status relay 3E.13E.2...
The make contacts 3e・1, 3e@'2, etc. are not involved in driving the combustion command relay 21 or the combustion status relay 22, and in this case, the one-car relay 2122 is set uniquely to each boiler. It is driven under the control of the upper and lower limit pressure switches GH and GL, which open and close according to the magnitude relationship between the upper and lower limit pressures and the steam pressure.Here, when the steam pressure is between the upper and lower limit pressure values, The boiler operates in a low combustion state, and when the steam pressure is below the lower limit pressure value, the boiler operates in a high combustion state, and the upper and lower limit pressure values of each boiler are set to values that are shifted from each other. This makes it possible to operate multiple boilers in parallel without mutual interference to some extent.

<Problems to be Solved by the Invention> However, in the conventional boiler operation number control device described above, the turndown ratio in the low combustion state of each boiler is not significantly Since it is difficult to reduce the steam load (usually up to 50% load, and it is generally difficult to operate below 30% load), when dealing with the large increase in steam load that occurs at light loads, By controlling the number of operating units, it is necessary to additionally start operation of new boilers, but in this case, with conventional equipment, most of the new boilers that should be additionally started are in a state of failure. Therefore, even if combustion is started by controlling the number of operating units, a considerable period of time (usually about 10 minutes) is required for the steam pressure of the boiler to rise.
There was a problem in that a sudden drop in vapor pressure could not be suppressed.

As a measure to solve this problem, 1. For example, set the number of machines in operation to 4, and set 3 of them to 50 at the same time.
By continuously changing from % load to 100% load, 200! Load (50 oz x 4 units) to 35 oz load (1
It is also known that it is possible to instantaneously deal with a large increase in steam load, but this method does not work when the load is light.

For example, in order to deal with steam load fluctuations from 5oz load to 20oz load, it is necessary to reduce the operation to 50oz.
Since it has to be 2 loads, up to 100% load can be dealt with instantaneously by continuously controlling one of the machines in operation, but in order to deal with fluctuations from 100% load to 20oz load, it is necessary to Since one additional unit has to be put into operation, the steam pressure will suddenly drop at this time.

Means for Solving Problems〉 In view of the problem of the sudden drop in steam pressure when additional boilers are operated in the above-mentioned conventional technology, the present invention is aimed at The above problem is solved by maintaining the boiler or boiler group selected to start operation next according to the operation order at a keep pressure close to the steam pressure value in the steam header. Even when additional boilers are started in response to a significant increase in steam load, the steam in the steam header can be maintained by maintaining the hold pressure and shifting the standby boiler to combustion operation. It is an object of the present invention to provide an excellent device for controlling the number of boilers in operation, which can quickly and effectively push pressure back toward a target pressure value within a control range, and which does not suffer from a sudden drop in load steam pressure.

Function> As shown in FIG.
A combustion control signal S2 is sent from the operation number control means 3 to a plurality of boilers B1 to B4 connected via check valves V1 to V4 so as to be able to operate in parallel to each other, depending on the steam pressure in the header.
, S3 is selectively supplied to shift the required number of boilers to combustion operation according to a predetermined operating order according to an increase or decrease in steam load, and to control the predetermined number of boilers in combustion operation. The steam pressure inside the steam header l is maintained within the control range by intermittently controlling the three positions.
The keep pressure maintenance command means 4 selectively sends a keep pressure maintenance command signal S4.1 to the boiler selected to start operation next according to a predetermined operation order among the boilers other than the boiler in the combustion operation. -94.4 is supplied separately to each boiler, and the keep pressure control means Cl-C4 attached to each boiler controls the combustion of the boiler in response to the command signals S4.l to S4.4, and the steam pressure of the boiler is Steam is maintained at a keep pressure value set as an upper limit pressure value lower than the operating pressure value of the check valves V1 to V4 and close to the steam pressure value in the steam header 1. This function allows the boiler to be put on standby without being connected to the boiler.

<Embodiment> The configuration and operation of an embodiment of the present invention will be described below based on FIGS. 1 to 5.

In FIG. 1, a keep pressure maintenance command means 4 is connected to the combustion unit number control means 3, and its output terminal sends keep pressure maintenance command signals 54-1 to 54-4 to each boiler B1-84. Keep pressure maintenance command signal lines i1 to 114 for distributing and supplying the pressure are respectively connected to the first boiler Bl to the fourth boiler B4.

Each of the boilers B1 to B4 is provided with keep pressure control means 01 to C4 as opposed to the keep pressure maintenance command means 4, and includes a circuit configuration shown in FIG. This circuit configuration consists of the I side fixed contact of selector switch S
Keep pressure maintenance command relay 4D・1 (4
D・2~4 D・0 make contact 4d・1 (4d・2~4
d.4) is inserted, and the other parts are the same as those of the conventional device shown in FIG.

On the other hand, as for the keep pressure maintenance command relay itself,
It is incorporated in the keep pressure maintenance command means 4 connected to the combustion unit number control means 3, and its circuit configuration is as shown in FIG. Output terminals 3o.1, 30.3.30.5 of the step controller 3a in the combustion unit number control means 3;
30.7 extends to the keep pressure maintenance command means 4 and is connected to four ant games) 4a.1 to 4ae4.

That is, regarding the ant game) 4ael, one input terminal is connected to the output terminal 3o.1 via the inverter 4b-1, the other input terminal of the gate is connected to the "H" level power supply, and the gate's other input terminal is connected to the "H" level power supply. The output terminal is connected to the keep pressure maintenance command relay 40-1 for the first boiler B1 via the relay driver 4c@1. Regarding the AND gates 4a and 2, one input terminal is connected to the output via the inverter 4b-2. Connected to terminal 30.3,
The other input terminal of the gate is connected to the output terminal 3o-1, and the output terminal of the gate is connected to the relay driver 4C.
It is connected to the keep pressure maintenance command relay No. 2 for the second boiler B2 via No. 2.

Regarding the AND gate 4a.3, one input terminal is connected to the output terminal 3o*5 via the inverter 4b.3,
The other input terminal is connected to the output terminal 3a.3, and the output terminal of the gate is further connected to the keep pressure maintenance command relay 4D.3 for the third boiler via the relay driver 4c.3.

As for Antogame) 4a*4, one input terminal is connected to the output terminals 30 and 7 via the inverter 4b-4,
The other input terminal is connected to the output terminal 30.5, and the output terminal of the gate is connected to the keep pressure maintenance command relay 4D-4 for the fourth boiler B4 via the relay driver 4ce4.
It is connected to the. The configuration of the combustion unit number control means 3 is the same as that of the conventional device shown in FIG.

In the above configuration, in operation, the combustion unit number control means 3 itself operates in the same manner as in the conventional device shown in FIG.
By controlling boiler B1 to fourth boiler B4 in three positions,
The steam pressure in the steam header 1 is maintained at a value within the control range.

During this time, the keep pressure maintenance command means 4 cooperates with the combustion unit number control means 3 to selectively supply the keep pressure maintenance command signals S4.1 to S4.reef to predetermined boilers.

For example, "H" is sent as a combustion control signal from the combustion unit number control means 3 to the first boiler B1 via the combustion control signal line L1.
Combustion command signal S2.1 and rHJ combustion state signal S3@
1 is supplied (see the signal status table in FIG. 3), the first boiler B1 operates in a high combustion state, but at this time, the output terminal 3o@1 of the step controller 3a
The combustion command signal of "H" appearing in is inverted to "L" via the inverter 4b.1 of the keep pressure maintenance command means 4, and is input to one input terminal of the AND gate 4a.1 corresponding to the first boiler 81. Supplied. However, since the AND gate does not respond to the rLJ input, the first boiler B
The keep pressure maintenance command relay 4D-1 corresponding to No. 1 remains de-energized, and the keep pressure maintenance command signal S4.1 is not transmitted to the keep pressure control means C1 attached to the first boiler at. The rHJ input of 30.1 is
It is also supplied to the other input terminal of the second boiler B2 corresponding to the second boiler B2, but at this time, the "L" combustion command signal S2. is rHJ via inverter 4b.2
is inverted and supplied to one input terminal of the AND gate 4a/2, so the AND gate outputs "1", and in response, the relay driver 4C/2 activates the keep pressure maintenance command relay. 4D.2 is excited and a keep pressure maintenance command signal S4.2 is transmitted to the second boiler B2. Then,
In response to this, the make contact 4d-2 in the keep pressure control means C2 on the second boiler B2 side closes to enable the upper limit pressure switch GH to control the combustion command relay Zl, thereby causing the relay Zl to be controlled by the upper limit pressure switch GH. operates in the same manner as that of the conventional device, and when the steam pressure of the second boiler B2 falls below a preset upper limit pressure value, the switch GM closes and drives the combustion command relay 21. 2 boiler B2 is shifted to the combustion state, but at this time, the boiler itself is originally inactive and the corresponding combustion command signal S2.
2 and the combustion state signal 53-2 are both rLJ (
(See the signal status table in Figure 3), make contacts 3d and 2.3e in the keep pressure maintenance control means C2 attached to the boiler.
・Both relays Z1 and 2 remain open, and both relays Z1 and
It was not involved in the operation of Z2, and in the end, the second boiler B
2 maintains the vapor pressure at the upper limit pressure value by repeating intermittent operation in a low combustion state.

Therefore, by selecting the upper limit pressure value of the upper limit pressure switch GH to be lower than the operating pressure value of the check valve v2 in the output steam pipe P2 of the boiler B2, the steam pressure of the boiler can be maintained at the desired level. The pressure value can be maintained. Thus, the second vapor pressure is maintained at the desired keep pressure value.
Since boiler B2 is not connected to the steam header l in terms of steam, it does not bear any steam load and remains in that state with low fuel consumption due to intermittent operation in a low combustion state. If a steam load that cannot be supported is imposed on the steam header 1 under high combustion conditions, what is the steam pressure within the control range? , 8Kg/rn' (see C in the signal status table in Figure 3), the combustion command signal 3b/2 for the second boiler B2
is output, and the boiler performs low combustion operation (combustion state signal S
3.2 is rLJ).

In this case, since the second boiler B2 is already maintained at the keep pressure, a slight increase in pressure will cause the check valve v2 to open, allowing instantaneous parallel connection to the steam header l, and It works to quickly push back the drop in vapor pressure. In addition, the combustion state signal S in the combustion number control means 3
3.1~S3・Reef.

Since it is not guided by the keep pressure maintenance command means 4, the combustion state (high combustion state or low combustion state) of each boiler is not involved in the keep pressure maintenance command operation.

Similarly, when the first boiler Bl and the second boiler B2 are in combustion operation, the rHJ for the second boiler B2 is
Since the combustion command signal S2.2 is supplied to the other input terminal of the third boiler B3 corresponding to the third boiler B3, the keep pressure maintenance command signal 54-3 is transmitted to the boiler B3. When the first boiler B1 to the third boiler B3 are in combustion operation, the rH for the third boiler B3 is
Since the combustion command signal 52-3 of J is supplied to the other input terminal of the AND gate 4a, 4 corresponding to the fourth boiler B4,
A keep pressure maintenance command signal S4 is transmitted to the boiler B4.

In this way, among the boilers that shift to the combustion state according to the predetermined operation order in the combustion number control means 3,
Keep pressure maintenance command means 4 to keep pressure control means 01 to C4 corresponding to the boilers to be next shifted to the combustion state.
Keep pressure maintenance command signals S4.1 to S4.4 are selectively supplied from the boiler, thereby maintaining a predetermined boiler at the keep pressure.

FIG. 4 is a circuit diagram showing the structure of a modified embodiment of the keep pressure maintenance command means 4. As shown in FIG.

Antgame) Following 4a.2, Orgate 4d.2
One input terminal of the gate 4d.2 is connected to the output terminal of the ant gate 4a.2, and the other input terminal of the gate 4d.2 is connected to the AND gate 4a.1.
is connected to the output terminal of

With exactly the same connection, following AND gates 4a and 3,
OR gate 4d.3 is provided, and gate 4a@4
Following this, or game) 4d-4 is provided. The other components are the same as those labeled with the same reference numerals in FIG.

In operation, if the first boiler Bl is currently in combustion operation, the combustion command signal S2.l for the first boiler is supplied to the other input terminal of the AND gate 4a.2 corresponding to the second boiler B2. Then, "1" from the gate 4a.2 is output as the keep pressure maintenance command signal S4.2 for the second boiler B2 via the gate 4d.2, but the AND gate 4a corresponding to the second boiler B2・“1” from 2 is the third
Since it is also input to the control signal S4d.3 corresponding to the boiler B3, this "1" is also output as the keep pressure maintenance command signal S4.3 for the third boiler.

Thus, in this implementation, the boiler that is next in the operating sequence to enter the combustion state and the boiler that is the next to enter the combustion state are maintained at a keep pressure.

It is obvious that the circuit configuration shown in FIG. 5 can be reached by simply extending a similar similar connection, and in this modified example, all the other boilers B2 to B4 are kept in the Maintained under pressure.

Effects> As described above, according to the present invention, a keep pressure maintenance command signal is selectively supplied to the boiler or boiler group selected to be started in operation first according to a predetermined operation order. Keep pressure maintenance command means 4 and 2 Cooperate with these to maintain the keep pressure of the boiler to which the keep pressure maintenance command signal is supplied.
By having a configuration in which keep pressure control means 01 to C4 for controlling combustion of boilers are attached, operation is started next according to a predetermined operation order in relation to control of the number of operating boilers of a plurality of boilers. Since the boiler or boiler group to be used is maintained at a keep pressure close to the steam pressure value in the steam header 1 before the start of operation, it is possible to cope with a significant increase in steam load during light loads. Even when additionally starting operation of a new boiler, the steam pressure in the steam header can be moved toward the target pressure value within the control range by shifting the boiler that is already maintained at the hold pressure and on standby to combustion operation. The excellent effect of being able to push back quickly and not causing a sudden drop in the load steam pressure is achieved.

By configuring each boiler 81NB4 to be commonly connected to the steam header l via each check valve V1 to V4,
Regarding the boilers that are maintained at keep pressure and are on standby,
Since the keep pressure is set lower than the operating pressure value of each check valve V1 to V4, no steam load is imposed on the standby boiler group, and the keep pressure is maintained with low fuel consumption. The excellent effect of being possible is also achieved.

Moreover, the check valves V1 to V4 are essentially essential components to prevent the steam in the steam header l from flowing back into the boiler group that is not in operation and is not in combustion operation. However, since this structure can be used as is, it has the advantage of being simple and economical.

In addition, in one embodiment of the present invention, the keep pressure control means Cl
NC4 has a configuration including an upper limit switch G)I,
The pressure switch OH itself is an indispensable component for ensuring operation in the side-specific operation mode in the conventional device, and since it is configured to be used as is, it has the practical benefit of being simple and economical. Accompany.

[Brief explanation of drawings]

1 to 5 relate to an embodiment of the present invention, FIG. 1 is a block diagram showing its overall configuration, and FIG. 2 is a configuration of keep pressure control means CI (C2 to C0). 3 is a circuit diagram showing the configuration of the combustion unit number control means 3 and the keep pressure maintenance command means 4. FIG. 4 is a circuit diagram showing a modification of the keep pressure maintenance command means 4. The figure is a circuit diagram showing another modification of the keep pressure maintenance command means 4. Figs. 6 to 9 relate to the conventional example, and Fig. 6 is a block diagram showing the overall configuration. , Fig. 7 is a circuit diagram showing the configuration of the combustion unit number control means 3, Fig. 8 is a circuit diagram showing the configuration of the boiler-side attached part of the combustion unit number control unit 3, and Fig. 9 is a circuit diagram showing the configuration of the boiler side attached part of the combustion unit number control unit 3. 21-P4., Output steam pipes 81-B4., Boilers v1-V4., Check valve 2, Steam pressure detection means 3, Number of combustion units. Control means 4 +++ Keep pressure maintenance command means S4., Keep pressure maintenance command signals C1 to C4, Keep pressure control means 1...Steam header

Claims (1)

[Claims] In response to combustion control signals S2 and S3, a plurality of boilers B1 to B4 whose combustion is individually controlled, and output steam pipes P1 to P4 from each boiler are separately provided. Check valve V
1 to V4, a steam header 1 to which output steam pipes P1 to P4 from each boiler B1 to B4 are commonly connected, and a steam pressure signal in accordance with the steam pressure detected by detecting the steam pressure in the steam header 1. A steam pressure detection means 2 that outputs S1; and selective combustion control for a predetermined boiler or boiler group selected according to a predetermined operating order based on the steam pressure signal S1 from the steam pressure detection means 2. Signal S2, S3
and a combustion unit number control means 3 that supplies steam pressure to maintain the steam pressure in the steam header 1 within a predetermined control range. ~B4, selectively kept for a boiler or boiler group selected to be started next according to a predetermined operation order among boilers other than the boilers to which the combustion control signals S2 and S3 are supplied A keep pressure maintenance command means 4 that supplies a pressure maintenance command signal S4, and a keep pressure control means C1 that controls combustion in each of the boilers B1 to B4 to maintain a predetermined keep pressure based on the keep pressure maintenance command signal S4. A boiler operation number control device characterized in that ~C4 is attached.