JPH07109289B2 - Boiler system controller - Google Patents

Description

TECHNICAL FIELD The present invention relates to a control device for a boiler system having a plurality of boiler units, and particularly to a plurality of boiler units that are sequentially activated in accordance with the activation sequence. On the other hand, pre-purge (ventilation or scavenging) is sequentially performed prior to the startup, minimizing the operation time delay due to the pre-purge at each startup, and the system responsiveness to load fluctuations and starting the entire system. The present invention relates to an improvement that enhances the quickness of the operation.

<Prior art> A boiler system that has multiple boiler units with a relatively small capacity that are commonly connected to a steam header has a stopped state for each boiler unit compared to a boiler system that has a single boiler unit with a large capacity. It is easy to shift between the operating state and the operating state, which allows the system to follow the fluctuation of the load, and it is also possible to operate each boiler unit at maximum output, so it can be used widely over a wide range. Has been done.

By the way, the boiler unit is usually prepurged when it is started, regardless of its capacity.
Inevitably needed.

Therefore, even in a boiler system having a plurality of boiler units, each time each boiler unit is started, pre-purge as a preparatory step is performed, and pre-purge requires a considerable amount of time.
There is a delay in the activation time of the operation. as a result,
Even in this type of system, which is said to easily follow a load change, there is still a problem that the system cannot be made to follow the load change smoothly and promptly. On the other hand, recently, in the control of a boiler system composed of a plurality of boiler units, the combustion state of each boiler unit is alternately switched between a high output state and a low output state, so that load fluctuations occur. A combustion state control method has been proposed in which the system is made to follow and the number of times of starting and stopping the boiler unit is reduced.

The configuration and operation will be described below with reference to parts of FIGS. 1 and 2.

The numbers # 1, # 2, # 3, and # according to the boot order
The output tubes of the four boiler units 10 marked with 4,
It is commonly connected to the steam header 11, and steam is supplied to a load device (not shown) through the steam header 11. The steam header 11 is provided with a pressure regulator 12, the output terminal of the pressure regulator 12 is connected to a control device 13, and a vapor pressure signal representing the vapor pressure in the header 11 is supplied to the control device 13. The output terminal of the control device 13 is connected to each of the four boiler units 10, and has a combustion start signal BI, a combustion stop signal BD, and a high combustion state selection signal BH, or a low combustion state selection signal BL.
Are supplied to the individual boiler units 10.

In the control device 13, the resistance-voltage conversion circuit 14 connected to the output terminal of the variable resistor incorporated in the pressure regulator 12 of the steam header 11 and the comparison input terminal connected to the output terminal of the resistance-voltage conversion circuit 14. However, the first to fourth four comparators 15a, 15b, 15c and 15d, which connect the separately set reference voltage values to the respective reference input terminals, and the first and fourth comparators 15a and 1
The combustion number setting unit 17 connected to the output terminal of 5d via the buffers 16a and 16d, and the second and third comparators 15
A combustion state selection unit 18 connected to the output terminals of b and 15c via respective buffers 16b and 16c is provided.

The first comparator 15a is supplied with a reference voltage value corresponding to a first critical value as a lower critical value, for example, 7.2 Kg / cm ^2, and the vapor pressure represented by the vapor pressure signal of the pressure regulator 12 is , When it is smaller than this lower critical value, the first comparator
The combustion number increase request signal Bi is supplied from 15a to the combustion number setting unit 17. Similarly, the fourth comparator 15d is supplied with a voltage value corresponding to a fourth critical value as the upper critical value, for example, 8.0 Kg / cm ² , and the vapor pressure is higher than the upper critical value. Sometimes, from the fourth comparator 15d to the combustion number setting unit 1
A request signal Bd for reducing the number of burning units is supplied to 7.

The second comparator 15b is supplied with a second threshold value larger than the first threshold value, for example, a reference voltage value corresponding to 7.4 Kg / cm ² , and the vapor pressure is equal to the second threshold value. When it becomes smaller, the high combustion state request signal Bh is supplied from the second comparator 15b to the combustion state selection unit 18. Similarly, the third comparator
15c is supplied with a reference voltage value corresponding to a third critical value greater than the second critical value, eg, 7.8 Kg / cm ² , and when the vapor pressure is greater than the third critical value, The low combustion state request signal Bl is sent from the third comparator 15c to the combustion state selecting section 18.
Is supplied.

When the combustion number increase signal Bi is supplied, the combustion number setting unit 17 sequentially supplies each of the boiler units 10 with a combustion start signal BI in accordance with the starting order, and a combustion start signal BI to supply each unit 10. On the other hand, when the combustion number decrease signal Bd is supplied, the combustion stop signal BD is sequentially generated every time a predetermined time elapses in the reverse order of the starting order.
Is supplied to sequentially stop each unit 10 in the reverse order of the starting order, and start and stop control of the plurality of boiler units 10 is performed.

The combustion state setting unit 18 is the last boiler unit that is sequentially activated by the combustion number setting unit 17 according to the activation order (hereinafter,
For the adjustment boiler), when the high combustion state request signal Bh is supplied to the combustion state setting unit 18, in the operating state of the adjustment boiler, the high combustion state selection signal BH for selecting the combustion state to the high combustion state. On the other hand, when the low combustion state request signal Bl is supplied, the low combustion state selection signal BL for selecting the combustion state to the low combustion state is supplied,
Controls the combustion state of the adjusting boiler.

Hereinafter, the operation of the control device of this type of boiler system based on the prior art will be described in more detail. The output signals Bi, Bd, Bh, and Bl from the first to fourth comparators 15a to 15d are all active high signals, and the input voltage of the comparators 15a to 15d is less than or equal to the reference voltage. When the input voltage is equal to or higher than the reference voltage of each of the comparators 15c and 15d, the signal is active at a high level.

The combustion number setting unit 17 is activated when the start switch 20 is turned on, and outputs a high level combustion start signal BI or a low level combustion stop signal BD, respectively, according to the input signal Bi or Bd. # 1, # 2, # 3, # 4
Selectively output to.

The combustion number setting unit 17 outputs the high-level combustion start signal BI to the boiler unit at predetermined time intervals while the combustion number increase request signal Bi appears at its input. Are sequentially output, that is, in the order of # 1 → # 2 → # 3 → # 4.

On the other hand, while the combustion number reduction request signal Bd is appearing, the low level combustion stop signal BD is started to the boiler unit at a predetermined time interval, for example, at a time interval of 4 seconds to start the boiler unit. The sequence is reversed, that is, in the order of # 4 → # 3 → # 2 → # 1. It should be noted that the time interval at which the combustion start signal BI is sequentially supplied to each boiler unit is 5 seconds in consideration of a slight time margin until each boiler unit 10 is activated from the stopped state to the high combustion state. It is good to set the degree. Further, when each boiler unit transitions from the stopped state to the combustion state by the combustion start signal BI from the combustion number setting unit 17, it is unconditionally set to the high combustion state, provided that the boiler unit 10 is Prior to going from a stopped state to a high combustion state, there is some time delay, followed by some low combustion state time.

In the combustion state selection unit 18, its set input terminal S is connected to the output terminal of the second comparator 15b via the buffer 16b, and its reset terminal R is connected to the third comparator 15c via the buffer 16c. A set-reset type flip-flop 21 connected to the output terminal of
The output terminal Q of 21 is commonly connected to one input terminal of each of the OR gates 22, 23 and 24. Also, OR Gate 2
The other input terminals of 2, 23, and 24 are connected to the output terminals of the boiler units # 1 to # 4 of the combustion number setting unit 17, respectively. The output terminals of the OR gates 22, 23, 24 and the output terminals of the flip-flop 21 are connected to the boiler units # 1 to # 4, respectively. 1 to # 4
The high combustion state selection signal BH or the low combustion state selection signal
BL is available.

Then, the combustion state selection unit 18 outputs a high combustion state selection signal BH at a high level or a low combustion state selection signal BL at a low level in accordance with the high combustion state request signal Bh from the second comparator 15b. Boiler units # 1, # 2, # 3, #
4 is output selectively.

As a result, for example, during combustion of all the boiler units # 1 to # 4 of the boiler system in this example, one boiler unit # whose start sequence is later among those boiler units #
4 and the one boiler unit # 3 whose starting sequence is later among these boiler units during the combustion of the boiler units # 1 to # 3 respectively becomes the adjustment boiler, but for this adjustment boiler, When the steam pressure is rising, the low combustion state request signal Bl is input to the reset input terminal of the flip-flop 21, the flip-flop stores "0" in response to this, and the low combustion state selection signal BL For example, the output is sequentially output to the adjustment boiler in (1) in the order opposite to the starting order. Further, when the steam pressure is decreasing, the high combustion state request signal Bh is input to the set input terminal of the flip-flop 21, and accordingly the flip-flop 21
Stores "1" and sequentially outputs the high combustion state selection signal BH to the adjustment boiler at the time point, for example, according to the starting order thereof.

Therefore, according to the above-mentioned conventional technique, the burner number setting unit 17
Is a start-up control for a plurality of boiler units 10 according to the start-up order, or the reverse order, for each boiler sequentially, the combustion state selection unit 18, the combustion number setting unit 17
Combustion state control is performed for the adjustment boiler set in 1., and these operate together so that the system follows the fluctuation of the load.

<Problems to be Solved by the Invention> However, according to the above-mentioned conventional technique, the adjustment boiler is set, and the control is performed such that the combustion state is switched between the high combustion state and the low combustion state. If the change in the vapor pressure due to the load change remains within the predetermined range, it is possible to make the system follow the load change to some extent even by the above combustion state control. In the event of such load fluctuations, or when starting the boiler system as a whole, after all, each boiler unit must be started and stopped, and when starting the boiler, Each time, a pre-purge is required for each boiler, so the time delay associated therewith cannot be avoided. As a result, the system still cannot follow the load variation smoothly and promptly, so that there is a problem that the system lacks responsiveness and that the system is not swiftly started.

<Means for Solving Problems> Therefore, the present invention has a problem in that the response of the system to the load variation in the controller of the boiler system based on the above-mentioned conventional technique is poor, and the promptness at the time of starting is lacking. In view of the above, when supplying the combustion start signal BI to the boiler which is most recently switched to the operating state in accordance with a predetermined starting order among the plurality of boiler units, the boiler which should be moved to the next operating state in accordance with the starting order. By providing a pre-purge standby signal generation means for supplying a pre-purge standby signal to each of the boiler units, the start order of each boiler unit is preceded (the time slot assigned to the heating operation of the boiler unit preceding by one in the start order is Pre-purge is performed in advance to eliminate the time delay associated with pre-purge, and thus the above problem It is intended to resolve cents.

<Operation> The configuration of the present invention is based on the combustion start signal BI which is sequentially supplied to the plurality of boiler units by the combustion number setting means 17 in accordance with the startup order thereof, and the pre-purge standby is performed. The signal generation means 30 is, for the boiler unit that will be activated next according to the activation sequence,
The pre-purge standby signal BP is supplied so that the pre-purge in the boiler unit is performed within the time slot assigned to the boiler unit which is currently operating prior to the start of the boiler unit, whereby each of the boiler units is started according to the starting order. When the boiler unit is started, each boiler unit starts the combustion start signal following the prepurge standby signal BP.
It immediately responds to BI and acts to start the heating operation.

<Example> The following will describe an example of the present invention with reference to the drawings.

The boiler system to which the control device according to the present invention can be applied may be of any type, and may be composed of any number of boiler units, but in the embodiments described below, the description will be made. For the sake of convenience, the boiler system is configured by connecting four steam boilers.

In FIG. 1, the control device 13 is connected to the pressure adjuster 12 of the steam header 11 that commonly connects the four boiler units # 1 to # 4, and the control device 13 has a pre-purge standby signal generating means 30 inside. It is provided. The output terminal of the control device 13 is connected to each of the boiler units 10, and the combustion start signal BI, the combustion stop signal BD, the high combustion state selection signal BH, the low combustion state selection signal BL, and the prepurge standby signal BP are supplied to each boiler unit 10. Can be supplied to.

FIG. 2 conceptually shows a hardware configuration for executing the algorithm as a specific configuration example of the control device 13. The control device 13 is realized by a microcomputer or the like, and is numbered according to the starting order. The four boiler units # 1 to # 4 attached are appropriately and selectively controlled.

The output terminal of the variable resistor which is incorporated in the pressure regulator 12 and whose resistance value changes in response to the fluctuation of the steam pressure in the steam header 11 is a resistor for converting the change of the resistance value into the change of the voltage value. Four comparators 15a, 15b, 15c and 15d are connected to the output terminal of the resistance-voltage converter 14, which are connected to the voltage converter 14. The output terminals of the comparators 15a and 15d are connected to the combustion number setting unit 17 via the buffers 16a and 16d, and the output terminals of the comparators 15b and 15c are connected to the combustion state selection unit 18 via the buffers 16b and 16c. There is.

The output terminal of the burner number setting unit 17 is for each boiler unit.
Pre-purge standby signal generation means connected to 10 and branching midway
It is also connected to 30, and the combustion start signal BI and the combustion stop signal BD can be supplied to each. Further, among the output terminals of the combustion number setting unit 17, those connected to the boiler units # 2, # 3, # 4 are also connected to the combustion state selection unit 18.

Next, the prepurge standby signal generating means 30 will be described in detail.

One input terminal of the prepurge standby signal generating means 30 is connected to the start switch 20 via the first inverter 31,
The other input terminal is connected to the output terminal to the boiler unit # 1 of the combustion number setting section 17 via the second inverter 32, and one input terminal is the boiler unit # 1. Is connected to the output terminal of the combustion number setting unit 17 via the third inverter 34
Second AND gate 35 connected to the output terminal to the boiler unit # 2, and one input terminal connected to the output terminal to the boiler unit # 2, and the other input terminal to the fourth inverter 36. A third AND gate 37 connected to the output terminal of the combustion number setting unit 17 to the boiler unit # 3 via one of the input terminals and one input terminal of the boiler unit # 3.
A fourth AND gate connected to the output terminal of the burner unit # 4 connected to the output terminal of the burner unit number setting section 17 of the combustion number setting unit 17 via the fifth inverter 38.
39, and these first to fourth AND gates 3
The output terminals of 3, 35, 37 and 39 are connected to the boiler units # 1 to # 4, respectively, so that the pre-purge standby signal BP can be supplied to each boiler unit 10.

As a result, for example, the boiler system #
When the combustion start signal BI is supplied from the combustion number setting unit 17 to the first boiler unit, the low level signal due to the closing of the start switch 20 is first supplied to one input terminal of the first AND gate 33. Is inverted by the inverter 31 and input as a high level signal, and the other input terminal of the AND gate 33 receives the high level signal of the output terminal to the boiler unit # 1 of the combustion number setting unit 17 by the second inverter 32. Since it is inverted and input as a low level signal,
Since the output of AND gate 33 is a low level signal,
In this case, the pre-purge standby signal BP is not supplied to the boiler unit # 1.

On the other hand, one input terminal of the second AND gate 35 connected to the boiler unit # 2, which is the next boiler unit in the startup order, outputs the output to the boiler unit # 1 of the combustion number setting unit 17 to one input terminal. Since the high level signal of the terminal is input and the low level signal of the output terminal to the boiler unit # 2 is inverted by the third inverter 34 and input as a high level signal, the second AND gate 35
Becomes a high level signal, and in this case, the pre-purge standby signal BP is supplied to the boiler unit # 2.

However, the third and fourth AND gates 37 and 39 connected to the boiler units # 3 and # 4, respectively, have a low level signal from the output terminals of the burner number setting unit 17 to the boiler units # 2 and # 3. , The outputs of the AND gates 37 and 39 are low level signals, and even in this case, the pre-purge standby signal BP is not supplied to the boiler units # 3 and # 4.

If the combustion start signal BI is supplied from the combustion number setting unit 17 to the boiler unit # 2 in addition to the boiler unit # 1 in accordance with the starting sequence,
A low-level signal is input to the first and second AND gates 33 and 35 via the first and second inverters 32 and 34, and the fourth AND gate 39 has a combustion number setting unit 17 of Since a low level signal is input from the output line to the boiler unit # 3, the outputs of the AND gates 3, 35 and 39 become low level signals, and the boiler units # 1, # 2 and # 4 have a pre-purge standby signal. BP is not supplied.

However, in this case, a high level signal is input to one input terminal of the third AND gate 37 from the output terminal of the combustion number setting unit 17 to the boiler unit # 2, and the other input terminal thereof. , The low level signal of the output terminal to the output to the boiler unit # 3 is inverted by the fourth inverter 36 and inputted as a high level signal, so that the output of the third AND gate 37 becomes a high level signal, Boiler unit # 3 that will be activated next according to the activation sequence
In response, the prepurge standby signal BP is supplied.

At that time, at the time when the output of the third AND gate 37 shifts to a high level signal, the combustion start output from the combustion unit setting unit 17 is output to the boiler unit # 2 to start the heating operation. Since it is controlled by the signal BI (at the time of transition of the signal to the high level), the pre-purge standby signal BP output from the third AND gate 37 to the boiler unit # 3 and the boiler unit # 2 are output. And the combustion start signal BI that is output as a result are simultaneously supplied. That is, in this case, boiler unit # 1
Among the # 4, when the combustion start signal BI is supplied to the boiler unit # 2 which is most recently switched to the operating state according to the predetermined starting sequence, the operating state should be changed to the next according to the same starting sequence. The prepurge standby signal BP is supplied to the boiler unit # 3. After all, prior to the start-up (heating operation) of the boiler unit # 3, the start-up sequence thereof is overlapped with the time slot assigned to the heating operation of the boiler unit # 2, which is the first, in the boiler unit # 3.
Is supplied with the prepurge standby signal BP.

Thus, the prepurge standby signal generating means 30 is activated in response to the combustion start signal BI sequentially supplied from the combustion number setting unit 17 to each of the plurality of boiler units according to the activation order thereof, and is then activated according to the activation order. The pre-purge standby signal BP is supplied to the boiler unit, which will probably be installed, prior to its activation, and the pre-purge is performed prior to its activation. Then, when the combustion start signal BI is supplied from the combustion number setting unit 17 to the boiler unit, prepurge has already been performed or has been completed, so the time delay associated with prepurge is eliminated, and it is smooth and prompt. The boiler unit will be started.

The overall operation of the control device 13 including the prepurge standby signal generating means 30 that operates as described above will be described below.

First, the boiler system (FIG. 1) is controlled on the basis of a control protocol relating to the following five-step control areas.

Control area A (operation number increasing mode) If the steam pressure in the steam header 11 (Fig. 1) is less than the first critical value 7.2 Kg / cm ² , this is regarded as the pressure control area A, and this control area A In (1), the number of burning boiler units is sequentially started at a high combustion state one by one at intervals of 5 seconds. In this case, the starting order of the boiler units that shift from the stopped state to the high combustion state is # 1 → # 2 → # 3 → # 4. Then, at this time, prior to the activation of each boiler unit, the pre-purge is sequentially performed for each boiler unit in the order of → # 2 → # 3 → # 4.

Control Region B (High Combustion State Transition Mode) When the vapor pressure is the first critical value 7.2 Kg / cm ² or more and the second critical value 7.4 Kg / cm ² or less, this is defined as the pressure control region B, In the control region B, the adjustment boiler is shifted from the low combustion state to the high combustion state. However, when the steam pressure is rising, the adjustment boiler is already in the high combustion state, so this mode is executed when the steam pressure is decreasing and the adjustment boiler is in the low combustion state. Only.

Control region C (state holding mode) When the vapor pressure is the second critical value of 7.4 kg / cm ² or more and the third critical value of 7.8 kg / cm ² or less, this is defined as the pressure control region C, and this control is performed. In region C, the vapor pressure rises and the second
All the boiler units maintain the state at the time when it exceeds the critical value of, or the steam pressure drops to the third critical value or less.

Control region D (low combustion state transition mode) When the vapor pressure is the third critical value 7.8 kg / cm ² or more and the fourth critical value 8.0 kg / cm ² or less, this is defined as the pressure control region D, In this control area D, the adjustment boiler is shifted from the high combustion state to the low combustion state. However, when the steam pressure is decreasing, the adjustment boiler is already in the low combustion state, so this mode is executed when the steam pressure is increasing and the adjustment boiler is in the high combustion state. Only.

Control area E (combustion number reduction mode) When the steam pressure is the fourth critical value of 8.0 kg / cm ² or more, this is set as the pressure control area E. In this control area E,
At the same time, the number of burning boiler units is reduced by one every 4 seconds, and at the same time, the adjustment boiler is shifted from the high combustion state to the low combustion state. The stop order in this case is also the reverse of the start order of the boiler unit, that is, # 4 → # 3 → # 2 →
The order is # 1.

Hereinafter, based on the control protocol as described above, the first
The operation of controlling the boiler system having the configuration shown in the figure will be described with reference to FIG. In FIG. 3, BH and BL respectively represent the high combustion selection signal and the low combustion selection signal from the combustion state selection unit 18 of FIG. 2 in that order, and BP represents the pre-purge standby signal generation means 30 of FIG. The prepurge standby signal BP represents H, L and P, which represent the actual combustion state and prepurge state of the boiler unit during the period in which the high combustion selection signal BH, the low combustion selection signal BL and the prepurge standby signal BP are output. Here, H represents a high combustion state, L represents a low combustion state, and P represents a prepurge state. Therefore, the short-time low combustion state L preceding the rise of the high combustion state H of each boiler unit indicates a low combustion period inevitably following the pre-purge. Then, in the following explanation,
For the time being, the description will proceed assuming that the heat load on the boiler system is substantially constant, and thereafter, the control operation when the load changes will be described.

(1) First, at the time when the start switch 20 shown in FIG. 2 is turned on at the time t0 shown in FIG. 3, the steam pressure is within the control region A. In the control area A, as described above, the number of burning boiler units is increased by one every 5 seconds,
At that time, it is a control region in which pre-purge is performed prior to the activation of each boiler unit, and the output signals from the comparators 15a and 15b are held at a high level.Therefore, the combustion number increase request signal Bi and the high combustion state request signal are provided. Bh is output, therefore, the combustion start signal BI is output from the combustion number setting unit 17, and the high combustion state selection signal BH is output from the combustion state selection unit 18.
Are output to the boiler unit # 1 respectively, and accompanying this, the pre-purge standby signal generating means 30 is simultaneously generated.
Outputs a prepurge standby signal BP to the boiler unit # 2. As a result, the boiler unit # 1 starts combustion in the high combustion state H after a slight amount of pre-purge P and the subsequent low combustion state L has passed, and the steam pressure in the header 11 (Fig. 1) of the boiler system is increased. However, the pre-purge of the boiler # 2 is performed in response to the pre-purge standby signal BP supplied so as to overlap the time slot assigned to the combustion operation of the boiler # 1. If the state of the control region A is still maintained at time t1 5 seconds after the boiler unit # 1 is switched to the operating state, the combustion unit number setting unit 17 and the combustion unit are set for the boiler unit # 2. The combustion start signal BI and the high combustion state selection signal BH are output from the state selection unit 18, and the pre-purge standby signal generation unit 30 simultaneously outputs the pre-purge standby signal BP to the boiler unit # 3 in association with this. It During this period, the boiler unit # 2 has already been pre-purged before it is started, so in response to the combustion start signal BI and the high combustion state selection signal BH, after a slight low combustion state L period, the high combustion state is reached. Combustion starts promptly with H. As long as the state of the control area A continues after that, each boiler unit after the boiler unit # 3 also starts combustion at 5 second intervals in sequence according to the starting order and becomes the high combustion state H. At that time, Pre-purge is sequentially performed prior to startup. Thus, each of the plurality of boiler units promptly starts combustion in the high combustion state H without allowing the delay time due to its own pre-purge to enter the time slot assigned to its own combustion operation. In the following description, suppose time t2,
At t3, boiler units # 3 and # 4 are activated,
It is assumed that all boiler units # 1 to # 4 in the boiler system are in a high combustion state. As described above, when all of these boiler units # 1 to # 4 are in the combustion state, the boiler unit #
4 operates as an adjustment boiler.

(2) All boiler units # 1 to # 4 as described above
Start burning in the high combustion state H, the steam pressure in the header rises promptly, and for example, at time t4 shown in the figure.
Then, the first critical value of 7.2 kg / cm ² is reached, and the pressure control region shifts from the region A to the region B, that is, the high combustion state transition mode. This control area B is a mode for shifting the adjustment boiler from the low combustion state to the high combustion state. In the case of this operation example, the boiler unit # 4 is designated as the adjustment boiler as described above, and this boiler unit is Is a control region where the low combustion state L should be shifted to the high combustion state H.
However, at this time, since the output signal from the comparator 15b is at a high level, the high combustion state request signal Bh
Since the boiler unit # 4 is already in the high combustion state H and the steam pressure is rising, all the boiler units # 1 to # 4 are in the same state, that is, the high combustion state. Held at H.

(3) When the steam pressure further rises and reaches the second critical value of 7.4 kg / cm ² at time t5, for example, the steam pressure shifts from the control region B to the control region C, that is, the state holding mode. In this control region C, the output signals from the comparators 15a to 15d are all at a low level, so that the vapor pressure is equal to the second critical value 7.4 Kg / cm ² and the third critical value.
As long as it is in the range between 7.8 Kg / cm ² , all boiler units maintain the state as it is, that is, the high combustion state H.

(4) Then, when the steam pressure reaches the third critical value of 7.8 kg / cm ² at time t6 shown in the figure, for example, the steam pressure shifts from the control region C to the control region D, that is, the low combustion state transition mode. . This control area D is an area for shifting the adjustment boiler from the high combustion state to the low combustion state. In the case of this operation example, first, the output signal from the comparator 15c becomes high level, and the low combustion state request signal is generated. Bl is emitted. Then, the combustion state selection unit 18 outputs the low combustion state selection signal BL to the boiler unit # 4, and the boiler unit # 4 shifts from the high combustion state H to the low combustion state L. After that, however, the steam pressure continued to rise, and
If the critical value is 7.8 Kg / cm ² or more, the boiler unit # 4 at this time is already in the low combustion state L, so that the boiler units # 1 to # 4 are maintained in the current state.

(5) Then, when the vapor pressure further increases and reaches the fourth critical value 8.0 kg / cm ² at time t7 shown in the figure, for example, the pressure control region shifts from the region D to the region E.
In this control area E, the number of units of combustion is reduced by one at intervals of 4 seconds, and at the same time, the adjustment boilers are sequentially redesignated in the order opposite to the starting order, and the newly designated adjustment boilers are changed from the high combustion state. This is a control region for shifting to a low combustion state. In the case of this operation example, first, at time t7, the combustion number setting unit 17 outputs the combustion stop signal BD to the boiler unit # 4 and the comparator 15d. , 15c output signal becomes high level and the number of combustion reduction request signal
Bd and the low combustion state request signal Bl are issued, and the combustion state selection unit 18 outputs the low combustion state selection signal BL to the boiler unit # 3. Thus, the boiler unit # 4, which is burning in the low combustion state L, stops burning, and along with this, the adjustment boiler is moved from the previous boiler unit # 4 to the boiler unit # 3, and this boiler unit # 3 is in the high combustion state. H
To the low combustion state L. If the steam pressure is still above the fourth critical value of 8.0 kg / cm ² at time t8 which is 4 seconds after the time t7, at this time t8, the combustion unit number setting unit 17 is set to the boiler unit # 3. Combustion stop signal
BD is output and the boiler unit # 3 stops burning. At this time, since the output signal from the comparator 15c becomes high level and the low combustion state request signal Bl is issued, the low combustion state selection signal BL from the combustion state selection unit 18 to the boiler unit # 2. Is output, and the boiler unit # 2 shifts from the high combustion state H to the low combustion state L. In this case, the combustion stop signal BD for the boiler unit # 3 and the low combustion state selection signal BL for the boiler unit # 2 are also issued at the same time.

(6) Boiler units # 4 and # as described above
3 is stopped and the adjusting boiler # 2 is in the low combustion state L, the steam pressure is reduced. Nevertheless, when the steam pressure is above the fourth critical value of 8.0 kg / cm ² at the time t9 shown in the drawing, the steam pressure is in the control area E, and therefore the number of combustion units is set for the boiler unit # 2 as well. A combustion stop signal BD is output from the section 17, and the boiler unit # 2 stops combustion. At the same time, the adjustment boiler is moved from the boiler unit # 2 until now to the boiler unit # 1, and the boiler unit # 1 is simultaneously changed from the high combustion state H to the low combustion state L. At this time, since the boiler unit # 2 is the boiler unit to be activated next in accordance with the activation sequence, the prepurge standby signal generator 30 sends the prepurge standby signal to the unit # 2.
BP is supplied, where prepurge is continuously performed prior to the start of combustion.

(7) The steam pressure further decreases, and
When the second critical value of 7.4 kg / cm ² is reached at t10, the steam pressure shifts from the control area C to the control area B, and in this case, the steam pressure is decreasing, so that the boiler unit # 1 is in the low combustion state. Transition from L to high combustion state H. As a result, the evaporation capacity of the boiler unit # 1 increases, and the steam pressure turns to the rising tendency again at about time t10. Thus,
For example, when the steam pressure again reaches the third critical value of 7.8 kg / cm ² at time t11 shown in the figure, the steam pressure shifts from the control region C to the control region D, and the boiler unit # 1 in the high combustion state H is Transition to the low combustion state L. As a result, the evaporation capacity of the boiler unit # 1 is reduced, and the steam pressure is almost constant.
It will start to decline again at t11. As described above, as long as the heat load is substantially constant, the burning boiler unit # 1 alternately reciprocates between the low combustion state L and the high combustion state H, so that the steam pressure is the second critical state. Value 7.4K
Illustration between g / cm ² and the third critical value of 7.8 kg / cm ² (t10-
As shown in t11-t12-t13), the vapor pressure converges in the state holding region C by going up and down.

As described above, even after the control region D to the control region E, that is, the transition from the low combustion state transition mode to the combustion number reduction mode, the steam pressure reverses from the increasing tendency to the decreasing tendency as at the time t8. If the steam pressure reaches a predetermined maximum critical value, for example, 8.5 Kg / cm ² , if the steam pressure continues to rise, the combustion unit setting unit 17 sets the burning boiler unit # 1 to the burning boiler unit # 1. It is also possible to output the combustion stop signal BD so that all the boiler units stop combustion. Such a function can be easily realized by slightly modifying the configuration shown in FIG.

The above-described control operation is based on the assumption that the heat load on the boiler system is substantially constant, but the control operation when the heat load fluctuates abruptly continues to FIGS. 2 and 3. Will be described with reference to. That is, when the heat load applied to the boiler system changes abruptly, the steam pressure increases abruptly or drops rapidly. Now, for example, at the time t13, while the boiler unit # 1 is transitioning from the high combustion state H to the low combustion state L and the steam pressure is decreasing, the heat load on the boiler system is rapidly increased and the steam header 11 (first (Figure)
Suppose that the steam pressure in the inside suddenly drops.

(8) Then, when the steam pressure is, for example, time t14,
When the critical value of 7.4 kg / cm ² of
To the control region B, and since the steam pressure is decreasing, the boiler unit # 1 shifts from the low combustion state L to the high combustion state H. As a result, the evaporation capacity of the boiler unit # 1 increases, but the steam pressure is still decreasing. Therefore, at time t15, the steam pressure shifts from the control area B to the control area A, and the combustion unit number setting unit is set. Since the combustion start signal BI is output from 17 to the boiler unit # 2, the boiler unit # 2 is activated. At this time, since the boiler unit # 2 has already been prepurged, the boiler unit # 2 immediately shifts to the high combustion state H. During this period, the prepurge standby signal BP is simultaneously supplied from the prepurge standby signal generating means 30 to the boiler unit # 3.
Thus, even though both the boiler units # 1 and # 2 are in the high combustion state H, the steam pressure continues to decrease, and for example, when the steam pressure is in the control area A at the time t16 shown in the drawing, At this time point, the combustion start signal BI is output from the combustion number setting unit 17 to the boiler unit # 3 that is in the inoperative state, and the boiler unit # 3 is promptly started in the high combustion state H. Become. As a result, the steam pressure changes to a rising tendency and rises from the control area A to the control area B (time t17), from the control area B to the control area C (time t18), and further to the control area D (time t19). Then, the process is almost the same as in the above case (time t10 to t13) and converges in the control region C.

<Effects of the Invention> As described above, in the boiler system control device according to the present invention, in the boiler system including a plurality of boiler units, the output steam pressure of the entire system is detected and the detected value is determined according to the detected value. By selectively starting or stopping the plurality of boiler units, in controlling the output steam pressure of the boiler system, based on the combustion start signal BI, for each boiler unit to be started according to the starting order, By configuring to perform prepurge prior to its startup, when each boiler is started according to the startup order, the prepurge has already been started for the boiler unit, and the preparatory stage for startup in the boiler is Since there is no time delay due to the prepurge period entering the time slot for The system can follow the movement smoothly and promptly, enhances the responsiveness, and quickly starts each boiler unit at the time of starting the entire system, so the start time can be shortened. The effect is played.

[Brief description of drawings]

FIG. 1 is a schematic diagram schematically showing a boiler system to which a boiler control device according to the present invention is applicable, and FIG. 2 is a control system of the present invention as a concrete configuration example of the control device in the system shown in FIG. FIG. 3 is a block diagram conceptually showing an example of a hardware configuration for executing the algorithm of the apparatus, FIG. 3 is a steam pressure curve when the boiler control apparatus according to the present invention is applied to the boiler system shown in FIG. It is a time chart which shows the logic state of the control signal selectively supplied to the system at each time on a curve, and the output state of each boiler unit. 10 …… Boiler unit 11 …… Steam header 12 …… Pressure regulator 13 …… Control device 14 …… Resistance-voltage conversion circuit 15 …… Voltage comparison circuit 17 …… Combustion number setting unit 18 …… Combustion state setting unit 30 ...... Pre-purge standby signal generating means # 1, # 2, # 3, # 4 …… Boiler unit.

Claims (2)

[Claims] 1. A steam header 11 is commonly connected and can be switched between a stopped state and an operating state in response to each of a combustion start signal BI and a combustion stop signal BD. A plurality of boiler units 10 capable of pre-purging in response to BP, a pressure controller 12 connected to a steam header 11 and outputting a steam pressure signal representing the steam pressure in the header, and a steam pressure from the pressure controller 12. In response to the signal, a combustion start signal BI and a combustion stop signal BD are separately supplied to the plurality of boiler units 10, and the plurality of boiler units 10 are individually controlled to the stopped state and the operating state. The control device 13 includes a plurality of boiler units 10.
Among these, when supplying the combustion start signal BI to the boiler that most recently shifts to the operating state in accordance with the predetermined starting sequence, the pre-purge standby is performed for the boiler that should shift to the next operating state in accordance with the starting sequence. A control device for a boiler system, comprising a prepurge standby signal generating means 30 for supplying a signal BP. 2. The control device 13 includes a combustion number increase request signal generation means 15a for detecting that the steam pressure represented by the steam pressure signal is below a lower limit critical value and outputting a combustion number increase request signal Bi. Combustion number reduction request signal generation means 15 which outputs a combustion number reduction request signal Bd by detecting that the vapor pressure represented by the vapor pressure signal is greater than or equal to the upper limit critical value greater than the lower limit critical value.
d and the combustion start signal BI in response to the combustion number increase request signal Bi,
It is sequentially supplied to each of the plurality of boiler units 10 in accordance with a predetermined starting sequence at each elapse of a predetermined time, and in response to the combustion number reduction request signal Bd, a combustion stop signal BD.
The combustion number setting means 17 for sequentially supplying each of the plurality of boiler units 10 in sequence in the reverse order of the starting order every time a predetermined time elapses. Boiler system controller.