JPH09159103A - Boiler control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To minimize the number of boilers to be in service and simplify the control of their operation. SOLUTION: A combustion control unit 51 and a package control unit 52 are provided in a number of unit-control area 5. The former is designed to output commands to an individual control area of each boiler so as to operate in conformity with the increase and decrease in loads in the order of the operation states of the boilers, for example, stop → low combustion → high combustion or to change the operation state of the boilers in the opposite direction while the latter is designed to output similar commands so as to start the purge of a boiler in the next order when a boiler in a preceding order is changed to low combustion or high combustion. This construction makes it possible to eliminate the need for the presence of a low combustion boiler since there stands by a boiler which has finished the purge when a new boiler is to be ignited. As a result, the number of boilers to be operated is minimized, which makes it possible to simplify control and maximize the operation efficiency of boilers during operation time.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an individual control part provided in each of a plurality of boilers and capable of controlling each of the boilers in a stopped state or in a low combustion state or a high combustion state and operating states of the plurality of boilers. The present invention relates to a boiler control device that includes a unit number control unit that determines the above, and that can integrate the plurality of boilers and use the same for a common load.

[0002]

2. Description of the Related Art Some boiler plants that supply steam on the basis of demand in factories or the like supply steam generated by a large number of boilers in an integrated manner. As a control device for such a boiler plant, in general, in addition to the control parts of the individual boilers, a unit control part for controlling the number of operating boilers corresponding to the demand for steam is provided. Then, the individual boilers in such a device are usually controlled in three positions by operating in one of three states of stop, low combustion, and high combustion.

As a control method combining such three-position control and unit number control, conventionally, the boiler is started in response to the load so that it can be operated at low combustion so as to cope with a rapid increase in the boiler load. When the load further increases or decreases, a method of switching the operating state between low combustion and high combustion has been generally adopted. According to this method, although the ability to follow load fluctuations is good, the number of low-combustion boilers increases, so the number of operating boilers increases and the boiler efficiency of the entire plant also decreases. As a control method for improving this point, there is proposed a control method in which the number of low-combustion boilers is reduced by providing a backup means for coping with a sudden increase in load (Japanese Patent Laid-Open No. 3-186102). reference).

[0004]

However, in any of the above control methods, a low-combustion boiler must always be prepared in any case, so that the number of operating boilers cannot be avoided. In addition, control is complicated because a low combustion boiler is always present. Therefore, the present invention is to solve the above problems in the prior art, to provide a boiler control device in which the number of operating boilers is minimized, the boiler efficiency in the operating state is improved, and the control is simplified. And

[0005]

In order to solve the above-mentioned problems, the present invention provides an individual control which is provided in each of a plurality of boilers and is capable of controlling each of the boilers in a stopped state or in a low combustion state or a high combustion state. In a boiler control device comprising a part and a unit number control part for determining the operating state of the plurality of boilers, the plurality of boilers can be integrated and used for a common load, the respective individual control parts are Equipped with a function that can control the completion of purge after putting each boiler into a standby state after purging for a certain period of time.
The unit control unit is configured to individually stop the plurality of boilers in a predetermined order in response to an increase or decrease in the common load, and sequentially change the boilers to low combustion, high combustion, or vice versa. A combustion control unit that issues a command to
The individual control to put at least one of the stopped boilers in a purge standby state when the stopped boilers have low combustion or when all the operating boilers have high combustion And a purge control unit for issuing a command to the portion.

[0006]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows a schematic configuration of a boiler plant in which four boilers are integrated and used for a common load as an example of a plurality of boilers. The boiler control device is provided in each of the boilers 1, 2, 3, and 4, and an individual control unit 11 capable of controlling each of the boilers to stop, to wait for completion of purge, to a low combustion state or a high combustion state,
It has 21, 31, 41 and a unit number control part 5 for controlling the number of these boilers used. The steam evaporated from each boiler is collected in the steam header 6 and sent to a supply destination such as a factory.

The boiler is, for example, a small once-through boiler, which has two burners (12, 13), (22, 23),
(32, 33) and (42, 43). In addition, in order to simplify the explanation, in the figure, it is shown that two burners are provided, but the number of burners is one, and the fuel system for gas, oil, etc. sent to this burner has two systems. In many boilers, the amount of combustion is changed by providing a solenoid valve or the like in each system and opening or closing it. The present invention can be applied to any type of boiler as long as it can control three positions. In addition, each of the boilers has a push blower 14, 24, 3 respectively.
4 and 44 are provided for supplying combustion air and purging air into the furnace. Reference numeral 7 is a pressure sensor that detects the pressure of the steam header 6 that changes in response to an increase or decrease in the boiler load.

Each individual control part 11, 21, 3
Nos. 1 and 41 can control each of the boilers 1 to 4 in three stages of a normal control, a 2 burner OFF stop state, a 1 burner ON low combustion state, and a 2 burner ON high combustion state, and purge completion It can also be controlled in the standby state. The purge completion standby state is to put the boiler in a standby state after purging for a certain period of time.Under this control, unlike the normal pre-purge control, the ignition is automatically switched to ignition-low combustion when the purge is completed. There is nothing to do. Therefore,
After the purging, the burner register (not shown) is set to the minimum opening degree to continue the operation of the forced draft blower or to stop it. A boiler in such a purge completion standby state can instantly ignite and achieve low combustion.

The unit number control section 5 has a combustion control section 51 and a purge control section 52. The combustion control unit 51 sequentially stops a plurality of boilers in a predetermined order corresponding to the increase or decrease of the common load, low combustion (hereinafter referred to as “L”), high combustion (hereinafter referred to as “H”), or The individual control section 52 is instructed to change the order in the opposite order. For example, if the order is boiler 1, 2, 3, 4,
When the boiler load increases, 1L, 1H, 2L, 2H, 3L, 3H, 4L, 4H
In the case where the number of boilers operating in this order is increased and the boiler load decreases, the unit number control unit 5 issues an operation command to each individual control unit so as to decrease the boilers operating in the opposite order.

Individual control parts 11 to 4 of each boiler
1 turns on / off the burner according to the command, and turns the boiler from stop to L, from L to H, and in the opposite direction. For example, when the boiler 1 is operating at H and the boiler 2 is operating at L, if the boiler load increases, the combustion control unit 51 issues a command to the individual control unit 21 to operate the boiler 2 at H, whereby The individual control unit 21 controls the burner 23 to be turned on in addition to the burner 22 which is already turned on. According to this control, when a plurality of boilers are in operation, only the last-ranked boiler is the low-combustion or high-burning boiler, and all the boilers in the preceding ranks are high-burning boilers.

The purge controller 52 controls the boiler stopped when the boiler stopped by the command of the combustion controller 51 becomes low combustion or when all the operated boilers become high combustion. A command is issued to the individual control units 11 to 41 so that at least one of them is placed in the purge completion standby state.

Here, "when the stopped boiler has become low in combustion" means when the boiler of the previous rank which has been stopped but has already completed the purge is ignited and the L operation is started. Say. Also, "when all of the operating boilers have become highly burned" means that the last-ranked boiler that has been operated at low combustion has been switched from low combustion to high combustion, or has been operated. This is the case when the last-ranked boiler is stopped from low-combustion, and as a result, the low-combustion boiler disappears.

Further, "at least one of the stopped boilers" usually means one boiler which is first in the operating order. For example, the boiler group is composed of gas-fired boilers. , When there is a so-called afterglow in which a slight combustion state of the boiler continues due to the residual gas in the pipe when the operation is stopped, it is the first rank boiler, which is the next rank of the stopped boiler. Become a boiler. or,
In a boiler plant with a particularly large load change, two or more boilers are controlled to a purge completion standby state so that they can be quickly followed.

When a command is issued from the purge controller 52,
The corresponding individual control part activates the forced draft blower of the boiler to purge the combustion gas in the furnace for a certain period of time, and maintains the boiler in the above-described purge completion standby state.

According to the method of controlling the purge to start when the low combustion boiler is exhausted, for example, when the boiler 1 is operating at H and the boiler 2 is operating at L, the boiler load increases. When the boiler 2 is switched to H, the purging of the boiler 3 of the next rank or the boiler 4 of the next rank is started. As a result, when the boiler 2 becomes H, the boiler 3 or 4 has not been purged yet. However, when the load further increases after the boiler 2 is switched to H, there is a certain time until the next boiler 3 or 4 is started and the L operation should be performed. Therefore, the boiler 3 or 4 is purged. Even if it waits until the completion of the above, the start time of the normal boiler 3 or 4 will not be delayed. Therefore, the problem that the boiler evaporation amount becomes insufficient due to the increase in load and the pressure drops sharply does not occur.

Further, the unit number control section 5 has a combustion control section 51 and a purge control section 52 having the above-mentioned functions, but these sections need not necessarily be physically separated. There is no. For example, in a computer-controlled device, a control mechanism having such a function is
It is incorporated as an inseparable thing.

FIG. 2 shows a combustion controller 51 and a purge controller 5.
An example of control by 2 is shown. The pressure of the steam header 6 which fluctuates according to the fluctuation of the boiler load is, for example, 5 kgf / cm ²
The lower limit pressure P ₁ and the upper limit pressure P ₂ of 7 kgf / cm ² are set in advance, P ₁ or less is an increasing range, P ₁ and P ₂ is a stable range, and P ₂ or more is a decreasing range. The combustion control unit 51 compares the detected pressure of the pressure sensor 7 with the set value, and when the detected value enters the increase range or the decrease range, stops the boiler with an appropriate time difference according to the priority order, L, H or the opposite. Signal to switch to. The purge control unit 52 outputs a signal for waiting the purge completion of the boiler having the highest priority among the boilers that are currently stopped and are ready to start up. In this example, the operating boiler is switched from L to H. Start purging when required.

In the illustrated example, the boiler 1 is operating at H and the boiler 2 is operating at L at the pressure state at point A, and this state is represented as "A: 1H, 2L". In this state,
Since there is an L boiler, the boiler 3 has not been purged.
When the boiler load increases from this state and the pressure detected by the pressure sensor 7 reaches the point B where the pressure has dropped to P ₁ , the combustion control unit 51
Outputs a signal to the individual control section 21, which controls the burner 23 to ignite the burner 23 to switch the operating state of the boiler 2 from L to H. Combustion control unit 5
The signal 1 is also transmitted to the purge control unit 52 at the same time.
As a result, the purge control unit 52 selects the boiler 3 which is, for example, the boiler in the next operation order, and outputs a signal to the individual control unit 31 so that this boiler waits for completion of purging. As a result, the boiler 2 becomes H, and the purging of the boiler 3 is also started. In the figure, this state is represented by "B: 1H, 2H, 3P".

If the fluctuation of the boiler load is within a certain range, the boiler 2 is switched to H and the evaporation amount increases, so that the pressure of the steam header 6 enters the stable range again. However, when the boiler load is significantly increased, the pressure of the steam header 6 is not recovered even when the boiler 2 changes from L to H. After switching the boiler 2 from L to H, when the pressure detected by the pressure sensor 7 is in the increase region for T ₁ hours or more, the combustion control unit 51 individually controls the combustion unit 51 so that the boiler 3 in the next order is changed from stop to L. Send a signal to 31. This T ₁ time is, for example, about 30 seconds. Purge controller 5
The purging of the boiler 3 started by the instruction of 2 is completed within this time. As a result, the L burner 32 is safely ignited by the individual control part 31, and the overall boiler evaporation amount is increased. This state is represented by "C: 1H, 2H, 3L". As a result, when the pressure enters the stable region as shown by the chain double-dashed line in the figure, the boiler is maintained in the operating state of 1H, 2H, 3L.

When the load of the boiler is increased so much that the pressure further decreases or the state where the pressure does not recover from the increased region to the stable region elapses T ₂ hours, the combustion control unit 51 causes the individual control unit 31 to move the boiler 3 from L to H. Send a signal to switch to. This signal is also sent to the purge control unit 52 at the same time, and the purge control unit 52 issues a signal to the individual control unit 41 so that the boiler 4 waits for the completion of the purge. As a result, the boiler 3 is all operated at H, and the boiler 4 is made operable. This state is represented by "D: 1H, 2H, 3H, 4P".

The combustion control unit 51 and the purge control unit 52 are
Similar control is performed when the boiler load decreases. For example, when the boiler load is reduced and the pressure of the steam header 6 reaches P ₂ when the boilers 1, 2, 3 are all operated at H at point E, the boiler 3 is switched from H to L and The standby state of the purge completion of the boiler 4 is released. This state is represented by "F: 1H, 2H, 3L". When the pressure decreases due to the decrease in the evaporation amount of the boiler 3 and enters the stable region, the combustion state is maintained.

When the load is greatly reduced and the pressure further increases, and the pressure in the reduced region continues for T ₃ hours, the boiler 3 is stopped and the boiler is maintained in the purge completion standby state.
This state is represented by "G: 1H, 2H, 3P". . As a result, when the pressure drops and enters the stable region, that state is maintained.
When the pressure still does not enter the stable region even after the boiler 3 is stopped for T ₄ hours, the boiler 2 is switched from H to L and the purge completion standby state of the boiler 3 is released. This state is represented by "J: 1H, 2L".

According to the above-described operation control, the boiler that needs to be started next time is always in the purge completion standby state, so there is no need to prepurge the boiler after the start command is issued, and it is possible to instantaneously It is possible to start the L operation and prevent a large decrease in steam pressure. According to such control, the L operation of the boiler can be minimized, the boiler can be operated in a highly efficient state as a whole, and energy saving due to low fuel consumption can be achieved. In addition, since the total number of boilers operated is reduced, the burner is less contaminated and the parts are consumed less, and the labor for operating, monitoring and maintaining the boiler is also reduced. Furthermore, the boiler group is sequentially stopped by the balance between the load and the boiler evaporation amount-L-H
On the contrary, since the control is performed only by the switching operation, the control is simplified, and the reliability of the boiler plant is improved accordingly. Also, since it is not necessary to secure the L boiler,
There is no need to perform complicated control with four-point set pressure as in the past, and control with two upper and lower limit set pressures can be performed, and control is further simplified. However, it is also possible to control four-point set pressure. Further, by preparing the purge completion standby boiler only when there is no boiler in the L state, it is possible to reduce the cooling loss of the boiler due to the purge and the operating time of the blower.

FIG. 3 shows a combustion controller 51 and a purge controller 5.
2 shows another control example. This control differs from the control shown in FIG. 2 in that even if an L operation boiler is present, purging of the boiler in the next operation order is started. That is, A
At the point, as indicated by "A: 1H, 2L, 3P", boiler 1 is H and 2 is L, but at this time, boiler 3 has been completely purged and burner ignition is instantaneously performed. Is ready for use. Therefore, when the load increases, the pressure enters the increasing range, both boilers 1 and 2 become H (point B), and when the pressure does not recover to the stable range, the boiler 3 is set to L at time T ₁ ′ (point C). ). Further, when the boiler 3 becomes L, the purging of the boiler 4 is immediately started. The same applies to the case where the boiler load decreases, and even if the boiler 3 or the boiler 2 goes to L, the purge completion standby state of these boilers in the next rank is maintained.

According to this control, there is a boiler that can always be ignited instantly after the purge is completed. Therefore, in this control, the boiler load often changes rapidly and greatly.
It is suitable for a boiler plant that often requires continuous switching between -H and L operation of the next boiler.

FIG. 4 shows an example of the operating state when the load is constant and stable. In the figure, the solid circle indicates the ON burner, and the broken circle indicates the OFF burner. The double circle with a solid line and a broken line shows a burner that turns ON / OFF.
In order to simplify the explanation, the evaporation amount of each of the boilers 1 to 4 is set to 2 t / h, the evaporation amount of each burner is set to 1 t / h, and the boiler plant is set to 4.5 t / h.
It is assumed that the vehicle is operating under a constant load. According to the control of the present invention, all the burners of the boilers 1 and 2 are ignited, so that both the boilers 1 and 2 are operated at H and the burner 32 of the boiler 3 is turned on / off as shown in FIG. , Boiler 3
Repeats L operation and stop each time the set pressures P ₁ and P ₂ are reached from the stable region shown in FIG. When stopped, the purge is immediately started to prepare for the next ignition.
According to this control, both the boilers 1 and 2 are operated with the highest efficiency. Also, the boiler pressure is well maintained between P ₁ and P ₂ .

FIG. 2B shows conventional control in the same boiler plant. In this case, in order to always secure the low combustion boiler, the burner 32 of the boiler 3 is always turned on to perform the L operation, and the burner 23 of the boiler 2 is turned on / off. Therefore, there are always three burning boilers, and the low combustion state of the boiler also increases.

FIG. 5 shows a case where the load is 5.5 t / h in the above boiler plant. Control of the present invention is performed (a)
Then, the boilers 1 and 2 are operated at H, the burner 32 of the boiler 3 is always on, and the burner 33 is on or off. Then, when the burner 33 is turned on, the boiler 4 is placed in a purge completion standby state. Therefore, although the number of boilers in H operation increases, the next boiler 4 is maintained in a state in which it can be instantly started, and therefore measures against an increase in load are also taken. On the other hand, in (b) showing the conventional control,
In order to ensure a low combustion boiler, the boiler 1 must be H, the boilers 3 and 4 must be L, and the boiler 2 must be switched between L and H. As a result, the number of low-combustion boilers is increased more than in the case of FIG. 4, and the number of operating boilers is always four. Also, depending on the size of the load,
Since the operating state becomes as shown in FIG. 5B or FIG. 5B, the control becomes complicated.

[0029]

As described above, according to the present invention, the combustion control unit is provided in the unit number control unit, whereby a plurality of boilers are sequentially stopped in a predetermined order corresponding to the increase or decrease of the common load. , A low combustion, a high combustion, or the opposite order, a command is issued to the individual control parts provided in each of the plurality of boilers, so that the individual control parts control each boiler according to the order by this command. . As a result, the number of boilers operated in the low combustion state is one or zero. Therefore, the number of low-combustion boilers can be reduced to a minimum number as compared with the conventional one. Also, the number of operating boilers as a whole is reduced. Furthermore, according to this control, the evaporation amount of the boiler is increased or decreased by simply repeating stop, low combustion, and high combustion according to the load, so compared to complicated control that requires a low combustion boiler. Therefore, the control can be simplified and the reliability of the boiler plant can be improved.

On the other hand, each individual control section has a function capable of performing a purge completion standby control in which, in addition to the above configuration, each boiler is purged for a certain period of time and then placed in a standby state. Further, the unit number control section includes a combustion control section and a purge control section, and the purge control section is stopped when the stopped boilers have low combustion or when all the operated boilers have high combustion. The individual control unit is instructed to put at least one of the boilers in the purge standby state. As a result, the individual control portion of the boiler for which the command has been issued activates the blower and starts purging. After the purging is completed, the blower may be continuously operated or stopped. As a result, when the next boiler is started from a stopped state due to load fluctuation and low combustion is performed,
Since the purging has been completed, the boiler can be made to burn low with no time delay. As a result, it is not necessary to prepare a boiler that is always in a low combustion state, and the combustion control section can perform the above-mentioned simple control.

If the low combustion boiler is minimized in this way,
The boiler efficiency as a whole of the operated boiler is maximized, the fuel consumption is reduced, and the energy saving of the plant can be achieved. In addition, since the number of high-burning boilers increases, the number of boilers that are in operation is smaller than before, burner contamination and parts consumption are reduced, and labor for operating, monitoring, and maintaining the boiler is also reduced. To be done.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram of a boiler plant including an example of a control device of the present invention.

FIG. 2 is an explanatory diagram showing an example of a control state by the control device.

FIG. 3 is an explanatory diagram showing another example of a control state by the control device.

FIG. 4 Burner ON / OF when the boiler load is constant
The F state is shown, (a) is the case of the control of the present invention, and (b) is the case of the prior art.

FIG. 5: Burner ON / OF when the boiler load is constant
The F state is shown, (a) is the case of the control of the present invention, and (b) is the case of the prior art.

[Explanation of Codes] 1, 2, 3, 4 Boiler (plural boilers) 5 Unit control part 11, 21, 31, 41 Individual control part 51 Combustion control part 52 Purge control part L Low combustion H High combustion

Claims (1)

[Claims] 1. An individual control unit provided in each of the plurality of boilers and capable of controlling each of the boilers in a stopped state or in a low combustion state or a high combustion state, and a unit number control section for determining an operating state of the plurality of boilers. In a boiler control device comprising a plurality of boilers that can be used for a common load by integrating them, each of the individual control units is configured to purge each of the boilers for a certain period of time and then put them into a standby state. A standby controllable function is provided, and the unit number control part sequentially stops the plurality of boilers in a predetermined order corresponding to the increase or decrease of the common load, low combustion, high combustion or vice versa. A combustion control unit for issuing a command to the individual control unit to change,
The individual control to put at least one of the stopped boilers in a purge standby state when the stopped boilers have low combustion or when all the operating boilers have high combustion And a purge control unit for issuing a command to a portion.