JPH01102213A - Automatic control device for burner - Google Patents

Abstract

PURPOSE:To make it possible to promptly and easily cope with the requirements of a change in a burner pattern by setting ignition order and extinguishment order for each of burner groups and transmitting the ignition order and the extinguishment order to be fetched into a computing program. CONSTITUTION:Ignition order and extinguishment order specified in advance for each of burner groups are set by means 3 and 8 for setting the ignition order and the extinguishment order for each of the burner groups. With respect to an ignition command signal, an extinguishment command signal and a by-pass signal on the computing program of an automatic control device 30 for burners, a data address is set in advance for each of the burners and stored in a data area. A means 6 by which the ignition and extinguishment orders are fetched into the computing program in accordance with information on the ignition and extinguishment orders set for each of the burner groups, automatically allocates these data on the computing program in correspondence to the ignition and extinguishment order for each of the burner groups. The automatic control device 30 for the burners controls the ignition and the extinguishment for each of the burner groups according to the computing program allocated with the ignition and extinguishment order for each of the burner groups.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an automatic burner control device, and more particularly to an automatic burner control device that allows easy changes in the ignition order and extinguishing order of burners.

[Conventional technology]

- For example, in a boiler for steam generation equipped with multiple burners, the number of burners used is changed as the load fluctuates. ) burner used has a great influence on main steam temperature control, denitrification control, etc. Operating a combustion device with an inadequate burner pattern causes temperature differences between the superheater and reheater, as well as temperature differences between the front and back of the furnace, and the main steam temperature fluctuates, reducing boiler efficiency. In addition, if the burner ignition state in the vertical direction is inappropriate, the NOx reduction effect due to in-furnace denitrification control will be reduced, and N
This causes problems such as the inability to suppress the OX value.

Figure 8 shows loads of 25%, 50%, 75%, and 100%.
%, and the NOX values corresponding to this burner pattern are shown in Figure 9.
Similarly, the main steam temperature is shown in FIG. In this case, when the load is around 50%, there is an imbalance in the number of burner ignitions between the front and rear of the furnace, and between the left and right sides, which induces temperature differences between the front and rear of the furnace, and between the left and right sides, and the main steam temperature as shown in Figure 10. fluctuates, reducing boiler efficiency. In addition, due to the difference in the burner ignition state in the vertical direction between the first stage and the third stage, the NOx reduction effect by in-furnace denitrification control decreases, and as shown in Figure 9, it becomes impossible to suppress the NOx value. The situation is as follows.

On the other hand, in the burner pattern shown in Fig. 5,
The burner ignition number is balanced in the morning, afternoon, can left, and cap stone in the full load range, making it an appropriate burner pattern, and the behavior of the NOX value and main steam temperature at this time is the 6th and 7th. As shown in the figure, the values are appropriate.

The burner pattern is determined across the entire load range, and in conventional burner automatic control devices, changes in the burner ignition/extinguishing pattern, including number control to optimize the burner pattern, are fixed. The contents of the control program,
The method used was to directly rewrite programs using a maintenance tool, which is hardware for modifying programs.

In the conventional technology shown in FIG. 2, a system controller 14 is provided in the burner automatic control device 11, and subloop controllers 21a to 21 that perform distributed control of 1 to 4 burners.
The system controller 14 and the subloop controllers 21a to 21n are connected by a system transmission line 25. The program area 15 in the system controller includes a program common to the entire burner system, and the burner automatic ignition/extinguishing sequence program 17 built therein is fixed. The devices 23a to 23n are devices that are controlled by each of the subloop controllers 21a to 21n, and operate according to command signals from the system controller 14 and the subloop controllers 21a to 21n. In the case of this example of the prior art, the only way to change the burner ignition/extinguishing order is to connect the maintenance tool 26 to the system transmission line 25 and directly rewrite the fixed burner automatic ignition/extinguishing order program 17. Changing the order requires changing the firing order, extinguishing order, and bypass signal; the more burners there are, the more work the change will require, and the more time and money it will take to make the change. Boiler operation must be stopped.

[Problem that the invention seeks to solve]

In the above conventional technology, the only way to change the burner pattern is to directly rewrite the burner automatic ignition and extinguishing order program using a maintenance tool. Therefore, it is difficult to change the burner pattern unless you understand the details of the program. I couldn't do that. In addition, since it takes a lot of time to make changes, the combustion equipment must be stopped, and if the burner pattern is operated with an incorrect burner pattern until it is time to stop, there is a problem that the boiler efficiency and NOx reduction rate are adversely affected. .

An object of the present invention is to enable quick and easy response to burner pattern change requests.

[Means for solving problems]

The above-mentioned problem is to provide a means for setting the ignition order and extinguishing order for each burner group consisting of one or more burners in a burner automatic control device that sequentially ignites and extinguishes a plurality of burners according to a computer program, and and means for transmitting the ignition order and extinguishing order for each burner group.

This is achieved by an automatic burner control device comprising means for incorporating the transmitted ignition order and extinguishing order for each burner group into the computer program.

[Effect]

The means for setting the ignition order and extinguishing order for each burner group sets a predetermined ignition order and extinguishing order for each burner group. A data address is set in advance for each burner in the ignition, extinguishing command signal, and bypass signal on the computer program of the burner automatic control device and stored in the data area, and this data is used to control the ignition, extinguishing, and bypass signals for each burner group. According to the extinguishing order information, means for incorporating the ignition/extinguishing order into the computer program automatically assigns the ignition/extinguishing order to the computer program in correspondence with the ignition/extinguishing order of each burner group.

The burner automatic control device controls ignition and extinguishing of each burner group according to a computer program to which the ignition and extinguishing order of each burner group is assigned.

〔Example〕

An embodiment of the present invention will be described below with reference to FIG.

The burner automatic control device 30 consists of a CRT operation system 1 and a burner control device 11 connected thereto. The CRT operation system 1 includes a burner pattern display/setting means and a burner/boiler operating state monitoring means, a CRT 2 as a display means, an operation keyboard 3 as a burner pattern setting means. and a CRT operation controller 4. A program area 5 built into the CRT operation controller 4 is composed of an automatic data allocation program 6, an automatic burner ignition/extinguishing pattern program 7, and a signal data area 8. In the data area 8, data necessary for the program, such as burner ignition commands and extinguishing commands, are stored in one-to-one correspondence for each burner. The automatic data allocation program 6 extracts the signal data on the automatic burner ignition/extinguishing program 7 from the data area 8 in accordance with the burner ignition/extinguishing order set on the keyboard 3 and allocates it in the order set for each burner. The burner control device 11, which is connected to the CRT operation system 1 by a system transmission path 24, includes a system controller 14 that centrally controls the entire control device, and subloop controllers 21a to 21n that perform distributed control of the water wheel levels of burners 1 to 4. Built-in system controller 14 and subloop controllers 21a to 21
n are connected by a system own transmission line 25.

A system controller internal program area 15 built in the system controller 14 has a program common to the entire burner system, and a burner automatic ignition/extinguishing pattern program 17 built therein is connected to the system transmission line 24.
It is connected to the burner automatic ignition/extinguishing pattern program in the CRT operation controller 4 and has the same contents. The device group 22 consists of devices 23a to 23n that are controlled by each subloop controller 21a to 21n, and operates according to command signals from the system controller 14 and the subloop controllers 21a to 21n, and its operating state is determined by the subloop controller 21a. ~21n, systematic transmission line 25. System controller 14. System transmission line 24. The image is then displayed on the CRT 2 via the CRT operation controller 4.

FIG. 3 shows an example of the settings and display screen on the CRT2. Burner pattern display/setting screen 32a,
32b indicates a burner arranged in the same way as the burner arrangement on the actual boiler wall surface with a burner Nα 33 attached thereto. A sign 34 indicates the ignition/extinguishing status of each individual burner,
A number 35 displayed within the indicator 34 indicates the burner ignition order, which can be set and changed individually for each burner using the operation keyboard 3. The burner ignition number displays 36a and 36b display the number of ignitions in compartment units such as 2 cans in the morning, 2 cans left, 9 cans right, etc. Burner ignition number imbalance display 37a.

37b compares the number of burners ignited for the canned stone and canned water in the morning and afternoon and displays the difference, and the imbalance check display 38
a and 38b check in advance whether imbalance will occur when the boiler is operated according to the ignition/extinguishing order displayed on the burner pattern display/setting screen of 32a32b,
In addition to displaying the information, even during actual boiler operation, if the burner becomes abnormal and cannot be ignited, and as a result the burner pattern shifts and the number of ignitions becomes unbalanced, the condition is checked and displayed. The boiler process amount displays 39a and 39b can switch and display the boiler process amount that you want to display on the screen, and for example, they show the boiler load amount % and NOX value corresponding to the number of burners ignited (1). .

FIG. 4 shows details of the automatic data allocation program 6, automatic burner ignition/extinguishing pattern program 7, and data area 8 shown in FIG. In the burner automatic ignition/extinguishing program 7 in the burner number control, the number control on/off command signal 71a, b and the flip-flop 77 constitute the number control on/off command signal 79.
9 and the burner increase command 72a are calculated by the AND calculator 78, and a first wood burner ignition command signal 73a is output. The first wood burner ignition bypass signal 74a is a signal that is established when the first burner is in an abnormal state and cannot be ignited, or when the ignition has already been completed, and the first wood burner ignition bypass signal 74a and the first burner ignition are When the command signal 73a is output together, the AND operator 78 outputs the second wood burner ignition command signal 73b. The burner ignition command signals from the third wood onward are also sequentially output by the same logical operation.

Further, the extinguishing command signals 75a to 75n for each burner are also sequentially outputted by the same calculation as the ignition command signal. Burner ignition command signal data 83 corresponding to each burner
a to 83n, burner ignition command bypass signal data 84a
~84n, burner extinguishing command signal data 85a~85n,
and burner extinguishing command bypass signal data 86a to 86
n is stored in the data area 8, and predetermined data is extracted and allocated to the signal for each burner on the burner automatic ignition/extinguishing pattern program 7 by the automatic data allocation program 6.

As shown in the burner ignition/extinguishing pattern display setting screen in Figure 3, if the burner ignition order is set to F-1 burner as the first wood and F-4 burner as the second wood, the first wood burner will be ignited. Burner ignition command signal data 83a for the F-1 burner is assigned to the command signal 73a, and burner ignition command signal data 83b for the F-4 burner is assigned to the second wood burner ignition command signal 73b.

When the first wood burner ignition command 73a is output in this state, the F-1 burner is ignited because the burner ignition command signal data 83a of the F-1 burner is assigned to this signal, and the second wood burner ignition command is issued. When the signal 73b is output, the F-4 burner is ignited because the burner ignition command signal data for the F-4 burner is assigned to this signal.

The same applies to extinguishing fires.

The CRT operation controller 4 containing the burner automatic ignition/extinguishing pattern program 7 is connected to the system controller 14 via the system transmission line 24, and the burner automatic ignition/extinguishing pattern program 17 built in the system controller 14 is connected to the system controller 14 by the system transmission line 24. , has the same contents as the burner automatic ignition/extinguishing program 7 in the CRT operation controller 4. When the burner automatic ignition/extinguishing pattern program 17 is started and the first wood burner ignition command 73a is output as described above, the subloop controller outputs a device operation signal for igniting the assigned burner in accordance with this, and the device Ignition and extinguishing are performed by operating 23a to 23n.

According to this embodiment, the burner ignition order and extinguishing order can be set and changed using the keyboard and the CRT setting display screen, so it is possible to easily and quickly optimize the burner pattern without knowing the details of the computer program. . Furthermore, in this embodiment, when the burner ignition and extinguishing order is set using the keyboard, the burner ignition and extinguishing order is simultaneously assigned to the computer program that controls the subloop controller. It is also possible to connect the system controller offline and prepare a burner automatic ignition and extinguishing pattern program in which the burner pattern is changed using the keyboard and CRT setting/display screen even when the system controller is in operation. .

Boiler process amount display includes main steam temperature, NOX value, etc.
Main steam pressure, fuel flow rate, fuel pressure, water supply flow rate, water supply pressure, air flow rate, air blow pressure, etc. may be displayed.

〔Effect of the invention〕

According to the present invention, means for setting the firing order and extinguishing order of the burners, and means for transmitting the set order;
Since the burner automatic control device is provided with means for importing the set order into a computer program that controls ignition and extinguishing of the burner via the transmission means, it is possible to operate the burner automatically even without detailed knowledge of the computer program. , changing the ignition/extinguishing order15) makes it possible to easily and quickly correct the burner pattern, achieve combustion with the appropriate burner pattern, maintain an appropriate main steam temperature, and properly control NOx. It has the effect of holding the

[Brief explanation of the drawing]

FIG. 1 is a system diagram of an embodiment of the present invention, FIG. 2 is a system diagram showing an example of the prior art, and FIG. FIG. 4 is a diagram illustrating some details of the embodiment of the present invention, FIG. 5 is a graph showing examples of burner patterns corresponding to loads, and FIG. 6 is a graph showing the behavior of the NOX value corresponding to the burner pattern shown in FIG. 5,
FIG. 7 is a graph showing the behavior of the main steam temperature corresponding to the burner pattern shown in FIG. 5, FIG. 8 is a graph showing examples of other burner patterns corresponding to the load, and FIG. Burner pattern L shown in FIG. 8; corresponding N
10 is a graph showing the behavior of the OX value, and FIG. 10 is a graph showing the behavior of the main steam temperature corresponding to the burner pattern shown in FIG. 8. 3.8... Means for setting the ignition and extinguishing order (operation keyboard, data area), 6... Means for incorporating the set order into the computer program (data automatic allocation program), 24... Setting Means (system transmission path) for transmitting the order in which the data has been determined, 30... Burner automatic control device.

Claims (1)

[Claims] 1. In an automatic burner control device that sequentially ignites and extinguishes a plurality of burners according to a computer program, means for setting the ignition order and extinguishing order for each burner group consisting of one or more burners. and means for transmitting the set ignition order and extinguishing order for each burner group, and means for incorporating the transmitted ignition order and extinguishing order for each burner group into the computer program. A burner automatic control device featuring: 2. The burner automatic control device according to claim 1, wherein the means for setting the ignition order and the extinguishing order includes means for displaying the set order. 3. The burner automatic control device according to claim 2, wherein the means for displaying the set order includes means for displaying the operating state of each burner. 4. The means for displaying the set order includes means for displaying an imbalance in the number of burner ignitions during operation in the burner pattern according to the set ignition and extinguishing order, and a boiler process amount display means. An automatic burner control device according to claims 2 and 3. 5. The burner according to any one of claims 1 to 4, wherein the means for setting the ignition and extinguishing order and the computer program for controlling the burner are connected offline. Automatic control device.