KR102647151B1 - Control system of soot blower - Google Patents

Abstract

It suppresses changes in steam temperature in the heat pipe and increases the operating efficiency of the soot blower. A soot blower 30 that sprays steam on the surface of the heat transfer tube 6, an inlet temperature sensor 20d that detects the steam inlet temperature (T _in ) of the heat transfer tube, and a steam outlet temperature (T _out ) of the heat transfer tube. In the control system of a soot blower including an outlet temperature sensor 20e and a controller 100, the controller determines the first temperature, which is the difference between the steam inlet temperature and the steam outlet temperature at a first point in time during operation of the soot blower. The temperature change value (dT), which is the difference between the temperature difference (ΔT1) and the second temperature difference (ΔT2), which is the difference between the steam inlet temperature and the steam outlet temperature at the second time point during operation of the soot blower, is obtained, and the temperature change value is obtained. The operation interval of the soot blower is determined to be within the range of this target value.

Description

Control system of soot blower

The present invention relates to a control system for a soot blower.

A boiler that burns solid fuel such as pulverized coal injects powdered solid fuel into a furnace from a fuel burner and combusts it within the furnace. A number of heat transfer tubes constituting a superheater or reheater are installed in the boiler, and ash burned during boiler operation is attached to the heat transfer tubes as clinker. If the boiler continues to be operated with clinker attached to the heat transfer pipe, the heat exchange efficiency of the heat transfer pipe decreases. Therefore, a soot blower is regularly operated to remove clinker adhering to the heat transfer pipe.

As a control method for a soot blower, for example, in Patent Document 1, the steam temperature at the boiler outlet is measured when the soot blower is operated, the maximum variation range of the deviation from the measured value and the predetermined control value is determined, and It is described that the injection fluid pressure when the soot blower is next operated is changed by increasing or decreasing it from the previous injection fluid pressure according to the range of the maximum fluctuation range.

According to the control method described in this patent document 1, the spraying fluid pressure of the soot blower can be adjusted, and therefore fluctuations in the steam temperature and steam pressure at the boiler outlet due to the operation of the soot blower can be suppressed.

Japanese Patent Publication No. 3615776

However, since the operation interval of the soot blower is fixed in Patent Document 1, there is room for improvement in order to operate the soot blower efficiently.

The present invention was made in consideration of such circumstances, and its purpose is to provide a soot blower control system that can increase the operation efficiency of the soot blower while suppressing changes in the steam temperature of the heat transfer pipe due to the operation of the soot blower. .

In order to achieve the above object, the present invention typically includes a soot blower that sprays steam on the surface of a heat transfer tube installed in a boiler, an inlet temperature sensor that detects the steam inlet temperature of the heat transfer tube, and an outlet that detects the steam outlet temperature of the heat transfer tube. In the soot blower control system including a temperature sensor and a controller that controls operation of the soot blower based on each detection signal input from the inlet temperature sensor and the outlet temperature sensor, the controller controls the operation of the soot blower. A first temperature difference, which is the difference between the steam inlet temperature and the steam outlet temperature at a first point in time, and a difference between the steam inlet temperature and the steam outlet temperature at a second time point during operation of the soot blower. The temperature change value that is the difference from the second temperature difference is obtained, and the operation interval of the soot blower is determined so that the temperature change value is within the range of the target value.

According to the soot blower control system according to the present invention, the operating efficiency of the soot blower can be increased while suppressing changes in the steam temperature of the heat transfer pipe due to the operation of the soot blower. In addition, problems, configurations, and effects other than those described above will become clear from the description of the embodiments below.

1 is a side view showing the overall configuration of a boiler to which the present invention is applied.
Figure 2 is a water vapor system diagram of a boiler.
Figure 3 is a diagram schematically showing the structure of a soot blower.
Figure 4 is a block diagram showing the electrical configuration of the controller.
Fig. 5 is a flow chart showing the procedure for determining the operation schedule of the soot blower in the first embodiment.
Figure 6a is a diagram showing a conventional soot blower operation schedule.
FIG. 6B is a diagram showing the operation schedule of the soot blower in the first embodiment.
Fig. 7 is a diagram showing a display example of a monitor.
Fig. 8 is a diagram showing a display example of the next page on the monitor.
Fig. 9 is a flow chart showing the procedure for determining the operation schedule of the soot blower in the second embodiment.
Fig. 10 is a diagram showing the correspondence between operation modes and target values.
Fig. 11 is a flow chart showing the procedure for determining the operation schedule of the soot blower in the third embodiment.
Fig. 12 is a diagram showing the correspondence between operation mode and spray vapor pressure.
Fig. 13 is a flow chart showing the procedure for determining the operation schedule of the soot blower in the fourth embodiment.
Fig. 14 is a diagram showing the correspondence between operation mode and rotation speed.

(First Embodiment)

Hereinafter, embodiments of the soot blower control system according to the present invention will be described with reference to the drawings. 1 is a side view showing the overall configuration of a boiler to which the present invention is applied. As shown in FIG. 1, the boiler 1 includes a furnace 2, a cage portion 3, and a secondary side wall 4 that connects the furnace 2 and the cage portion 3. The furnace 2 is provided with a wind box 5 for blowing air into the furnace 2, and inside the wind box 5, pulverized coal, which is a solid fuel, is blown into the furnace 2 for combustion. A burner (not shown) is provided for this purpose. In addition, inside the furnace 2, the auxiliary side wall 4, and the cage portion 3, a plurality of heat exchangers composed of a plurality of heat transfer tubes (group of heat transfer tubes) 6 are installed. Additionally, these heat exchangers include a primary superheater (13), a secondary superheater (14), a tertiary superheater (15), a primary reheater (16), a secondary reheater (17), and a fuel saver (10). (see Figure 2).

When air is introduced into the furnace 2 from the wind pipe 5 and fuel is injected from the burner to combust the pulverized coal within the furnace 2, high-temperature combustion gas is generated. Combustion gas generated within the furnace 2 flows in that order through the furnace 2, the subside wall 4, and the cage portion 3, and is finally discharged to the outside through a chimney (not shown). The high-temperature combustion gas exchanges heat with the fluid in the heat transfer tube (6) while flowing through the furnace (2), the subside wall (4), and the cage portion (3). As a result, high-temperature heating steam is generated.

Next, the water vapor system of the boiler 1 will be explained. FIG. 2 is a water vapor system diagram of the boiler 1 shown in FIG. 1. As shown in Figure 2, the water supplied by the water supply line is a fuel saver 10, a furnace wall (water wall) 11, a vapor separator 12, a primary superheater 13, and a secondary superheater ( 14), while flowing through the 3rd superheater 15, heat is exchanged with the combustion gas to form high-temperature and high-pressure heated steam, which is supplied to the high-pressure turbine 18. In addition, the steam taken out from the high pressure turbine 18 exchanges heat with the combustion gas while flowing in the order of the first reheater 16 and the second reheater 17, becomes reheated steam, and is supplied to the low pressure turbine 19. After that, it returns to the condenser. Additionally, temperature sensors 20a to 20i for detecting the steam temperature are installed at the steam inlet and outlet of each heat exchanger.

Returning to FIG. 1, a plurality of soot blowers 30A, B, C..., 40A, B, C... are installed in the boiler 1. In addition, in the following description, when there is no need to distinguish between the soot blowers 30A, B, C..., they may be simply referred to as the soot blower 30. The same goes for soot blowers (40A, B, C...).

The soot blower (30) is for removing clinker attached to the surface of each heat pipe (6) constituting each heat exchanger (10, 13, 14, 15, 16, 17), and the soot blower (40) is used to remove clinker from the furnace wall. This is to remove clinker attached to the inner wall of (11).

Next, the structure of the soot blower 30 will be described. FIG. 3 is a diagram schematically showing the structure of the soot blower 30 shown in FIG. 1. In addition, since the soot blower 40 has the same structure as the soot blower 30, description is omitted.

As shown in FIG. 3, the soot blower 30 includes a nozzle block 32 having spray holes 33 and 34, and a soot blower tube whose tip is connected to the nozzle block 32 (inside which steam for the soot blower flows). It is provided with a tube (31) and a motor (38). In addition, the motor 38 and the soot blower tube 31 are connected through a power transmission mechanism such as a gear not shown, and rotation of the motor 38 causes the soot blower tube 31 to rotate around the central axis. Movement in the insertion/extraction direction (axial direction) is possible.

The motor 38 is driven through the inverter 39 based on commands from the controller 100. The rear end of the soot blower tube 31 is connected to the spray steam supply line 35, and steam whose pressure is adjusted by the steam pressure control valve 37 flows through the soot blower tube 31, and the spray hole 33 , 34) is sprayed into the furnace 2. By spraying steam onto the heat transfer pipe 6 from the spray holes 33 and 34, the clinker adhering to the heat transfer pipe 6 is removed. The detection signal from the pressure sensor 36 is input to the controller 100, and the controller 100 controls the steam pressure control valve 37 to a desired opening degree. Thereby, the pressure and flow rate of the steam sprayed from the soot blower 30 are adjusted.

Figure 4 is a block diagram showing the electrical configuration of the controller 100. As shown in FIG. 4, the controller 100 includes a CPU 100a that performs calculations for determining the operation schedules of the soot blowers 30 and 40, which will be described later, and a program for executing calculations by the CPU 100a. A storage device (100b) such as ROM or HDD, a RAM (100c) that serves as a work area when the CPU (100a) executes a program, and a communication interface (communication I/ F) It is composed of hardware including (100d) and software stored in the memory device (100b) and executed by the CPU (100a). Each function of the controller 100 is realized by the CPU 100a loading various programs stored in the memory device 100b into the RAM 100c and executing them.

The controller 100 includes a temperature sensor 20a that detects the water inlet temperature of the fuel saver 10, a temperature sensor 20b that detects the coolant inlet temperature of the furnace wall 11, and a temperature sensor 20b that detects the temperature of the coolant inlet of the furnace wall 11, and the steam of the primary superheater 13. A temperature sensor 20c detecting the inlet temperature, a temperature sensor 20d detecting the steam outlet temperature of the primary superheater 13 (steam inlet temperature of the secondary superheater 14), the steam of the secondary superheater 14 A temperature sensor 20e that detects the outlet temperature (steam inlet temperature of the 3rd superheater 15), a temperature sensor 20f that detects the steam outlet temperature of the 3rd superheater 15, and a temperature sensor 20f of the 1st reheater 16. A temperature sensor (20g) for detecting the vapor inlet temperature, a temperature sensor (20h) for detecting the vapor outlet temperature of the primary reheater (16) (the vapor inlet temperature of the secondary reheater (17)), and a secondary reheater. A detection signal from the temperature sensor 20i that detects the steam outlet temperature at (17) is input. Additionally, information on the type of coal input into the boiler 1 and information on the operation mode are also input to the controller 100.

And the controller 100 controls the motor 38 to rotate by driving the inverter 39 of the desired soot blower 30 or 40 according to the operation schedule of the soot blower 30 or 40 described below. That is, the controller 100 individually controls the operation of each soot blower 30 and 40.

Additionally, a detection signal from the pressure sensor 36 is input to the controller 100, and the controller 100 controls the opening degree of the steam pressure control valve 37 based on the detection signal. Additionally, the controller 100 is connected to the monitor 50, and the calculation results by the controller 100 are configured to be appropriately displayed on the monitor 50 (see FIGS. 7 and 8).

Next, the procedure for determining the operation schedule of the soot blowers 30 and 40 will be described. FIG. 5 is a flow chart showing the procedure for determining the operation schedule of the soot blowers 30 and 40. The controller 100 executes the processing shown in FIG. 5 for each operation of the soot blowers 30 and 40, and continues for a predetermined period (in this embodiment) from the first operation of the soot blower 30 in the current operation schedule. After 3 days), an operation schedule for the soot blowers 30 and 40 for the next 3 days is created. In addition, the operation schedule of the soot blowers 30, 40 for the first three days when starting the boiler 1 is set in advance, and for example, in this embodiment, all soot blowers 30, 40 are 9. A driving schedule for each hour of operation is preset. Therefore, in this embodiment, all soot blowers 30, 40 are operated every 9 hours for the first 3 days from the start of the boiler 1, and from the 4th day onwards, according to an operation schedule based on the temperature change of the heat transfer tube 6. The soot blowers 30 and 40 are operated individually.

When the operation of the soot blowers 30 and 40 starts, the controller 100 starts the process of FIG. 5. Here, the order of the operation schedule determination process will be explained taking the soot blower 30 installed for the secondary superheater 14 as an example, but the soot blower 30 can be determined in the same order for other soot blowers 30 and 40. , 40), the driving schedule is determined.

First, the controller 100 detects the steam inlet temperature (T _in ) of the secondary superheater 14 (heat pipe 6) at the start of operation (first operation) of the soot blower 30 from the temperature sensor 20d. and the steam outlet temperature (T _out ) of the secondary superheater 14 is acquired from the temperature sensor 20e. Then, the controller 100 calculates the temperature difference ΔT1 (first temperature difference) between the steam inlet temperature T _in and the steam outlet temperature T _out , and stores this temperature difference ΔT1 in the RAM 100c (step S1).

Next, the controller 100 measures the steam inlet temperature (T _in ) of the secondary superheater 14 (heat pipe 6) when the soot blower 30 is stopped (during the second operation) by using the temperature sensor 20d. ), and the steam outlet temperature (T _out ) of the secondary superheater 14 is acquired from the temperature sensor 20e. Then, the controller 100 calculates the temperature difference ΔT2 (second temperature difference) between the steam inlet temperature T _in and the steam outlet temperature T _out , and stores this temperature difference ΔT2 in the RAM 100c (step S2). Additionally, the processing of steps S1 and S2 is not limited to when operation of the soot blower 30 is started or when operation is stopped.

Next, the controller 100 calculates the difference between the temperature difference ΔT2 and the temperature difference ΔT1, that is, the temperature change value dT (=ΔT2-ΔT1), and stores this temperature change value dT in the RAM 100c. Remember (step S3). When 3 days have elapsed since the first operation of the soot blower 30 in the current operation schedule (Step S4/Example), the controller 100 stores the 3 days (integrated time (H)) stored in the RAM 100c. ) The temperature change value (dT) is read, and the integrated value (ΣdT) of the temperature change value (dT) over 3 days is calculated (step S5).

Next, the controller 100 calculates the interval time (operation interval) T _int2 of the soot blower 30 based on the integrated value ΣdT of the temperature change value dT (step S6), and the next time 3 The daily operation schedule of the soot blower 30 is determined (step S7). According to this operation schedule, the controller 100 controls the operation of the soot blower 30 for the next three days. That is, the soot blower 30 is operated every interval time (T _int2 ) calculated in step S6. In addition, if 3 days have not elapsed in step S4 (step S4/No), the controller 100 ends the process and waits until the next operation of the soot blower 30 starts.

Next, a method for calculating the interval time T _int2 in step S6 will be described. The integration time is H, the integration value is ΣdT, the target value of the temperature change of the heat transfer tube 6 is T*, the number of heat transfer tubes 6 is N, the current soot blower operation interval (current interval time) is T _int1 , If the meeting interval time is T _int2 and the expected value is E _x , the next meeting interval time (T _int2 ) is calculated by equations (1) and (2).

E _x =T*/N×H/T _int1 ···(Equation 1)

T _int2 =T _int1 /(ΣdT/E _x )···(Equation 2)

For example, target value T* = 2℃, integration time H = 72 hours (3 days), integration value (ΣdT) = 0.77℃, number of heat pipes N = 12 (6 pairs), current interval time T _int1 In the case of =9 hours (initial value), from (Equation 1), the expected value _E By substituting this _expected value, _E

The controller 100 performs this calculation for all soot blowers 30A, B, C, D, E... to determine the operation schedule of each soot blower. For example, assuming that for soot blowers (30A, B, C, D, E), the integrated values (ΣdT) for the current three days were 0.77 (described above), 0.33, 1.13, 0.54, and 1.92, respectively, the controller (100) calculates the interval times (T _int2 ) of the next session as 15.2 hours (described above), 35.5 hours, 10.4 hours, 21.7 hours, and 6.1 hours, respectively. Accordingly, the soot blowers 30A, B, C, D, and E are each individually operated for the next three days at the calculated next interval time (T _int2 ).

The operation schedule of the soot blower in this embodiment will be explained by comparing it with the conventional one. FIG. 6A is a diagram showing a conventional soot blower operation schedule, and FIG. 6B is a diagram showing the soot blower operation schedule in this embodiment. Additionally, Figures 6a and 6b show the operation schedule for five soot blowers (SB).

As shown in Fig. 6A, conventionally, soot blowers A to E were all operated sequentially at intervals of 9 hours. Therefore, conventionally, the operation schedule was such that the soot blower was operated in the order of A → B → C → D → E every 9 hours.

Meanwhile, in the present embodiment, as described above, the interval times of the soot blowers 30A, B, C, D, E (hereinafter abbreviated as A, B, C, D, E) are determined individually, so 3 The daily operation schedule of soot blowers A to E is as shown in FIG. 6B. That is, the soot blower (A) is operated every 15.2 hours, the soot blower (B) is operated every 35.5 hours, the soot blower (C) is operated every 10.4 hours, and the soot blower (D) is operated every 21.7 hours. The soot blower (E) runs every 6.1 hours. Therefore, the driving order for 3 days is E → A → E → D → C → E...

Next, a display example of the monitor 50 will be described. The controller 100 displays the integrated value ΣdT of each soot blower 30 and 40 in a predetermined display area of the monitor 50. FIG. 7 is a diagram showing a display example of the monitor 50. As shown in FIG. 7, a side schematic diagram of the boiler 1 is displayed on the monitor 50, and a display area for displaying temperature information of the heat transfer tube 6 at the position where the soot blowers 30 and 40 are arranged. (60) is formed. The controller 100 calculates the integrated value ΣdT as described above, and controls the integrated value ΣdT to be displayed on the predetermined display area 60 corresponding to the arrangement of the soot blowers 30 and 40. . Since the integration value ΣdT is calculated once every three days, the integration value ΣdT displayed in the display area 60 is also updated every 3 days. Additionally, the display area 60 is divided according to the integrated value ΣdT, making it easy to visually determine the temperature distribution.

Additionally, a display area 65 is provided in the lower right part of the monitor 50, and the text “Next Page” is displayed in this display area 65. When this display area 65 is operated by, for example, a touch, the screen display is switched. Fig. 8 is a diagram showing a display example of the next page on the monitor 50. As shown in FIG. 8, when the screen of the monitor 50 changes, the integrated value ΣdT for each type of coal, which is fuel information for the boiler 1, is displayed. In the example of FIG. 8, the value of the integrated value (ΣdT) of the temperature change value (dT) of the heat transfer tube 6 corresponding to each of the soot blowers (A, B, C, D, E) is determined by the type of coal (coal type). It is indicated for each No.1 to No.4. Additionally, although not shown, the display is divided depending on the temperature value.

According to this embodiment configured as described above, the following effects can be achieved.

When the clinker adhering to the heat transfer tube 6 is removed, the heat transfer efficiency of the heat transfer tube 6 is improved, so the steam outlet temperature of the heat transfer tube 6 is lowered before operating the soot blowers 30 and 40 (i.e., ) rises compared to before removing the clinker attached to it. And the change in the temperature of the steam outlet of the heat transfer pipe (6) increases as the amount of clinker removed from the heat transfer pipe (6) increases. Considering the stable operation of the boiler 1, it is preferable that the temperature change at the steam inlet and outlet of the heat transfer pipe 6 is smaller. However, if the operation interval of the soot blower is fixed as in the past, the temperature of the steam for each heat transfer pipe 6 is small. Management is difficult.

Therefore, in this embodiment, the operation interval of each soot blower 30, 40 (30A, B, C..., 40A, B, C...) is obtained by the above calculation method, and each soot blower 30, 40 is calculated according to the operation schedule. The soot blowers 30 and 40 are controlled to operate.

As a result, by frequently operating the soot blowers 30 and 40 to remove clinker from the heat transfer tube 6 to which clinker easily adheres, the temperature rise of the heat transfer tube 6 can be suppressed. In addition, for the heat transfer pipe 6 to which clinker is difficult to adhere, unnecessary operation of the soot blowers 30 and 40 can be suppressed by slightly lengthening the operation interval of the soot blowers 30 and 40. In this way, in this embodiment, the operating efficiency of the soot blowers 30 and 40 can be improved while suppressing the change in the steam outlet temperature of the heat transfer tube 6 before and after the operation of the soot blowers 30 and 40. .

In addition, a schematic diagram of the boiler 1 is displayed on the monitor 50, and the integrated value ΣdT is displayed in correspondence with the positions of the soot blowers 30 and 40 installed in the boiler 1, so any surrounding It is easy to visually check whether the temperature change in the heat pipe 6 is large. In addition, since the temperature is displayed separately according to the integrated value (ΣdT), it is easy to visually understand the distribution of temperature changes, making it easy to manage the operation of the boiler 1. Additionally, when the screen of the monitor 50 is switched, the integrated value ΣdT is displayed in a list according to the type of coal, so the soot blowers 30 and 40 can be optimally operated depending on the type of coal.

(Second Embodiment)

Next, the control system of the soot blower according to the second embodiment of the present invention will be described. The soot blower control system according to the second embodiment is characterized in that the controller 100 changes the target value T* according to the operation mode. Hereinafter, explanation will be given focusing on this feature.

Fig. 9 is a flow chart showing the procedure for determining the operation schedule of the soot blower in the second embodiment. As shown in Fig. 9, the second embodiment differs from the first embodiment in that the target value T* is changed according to the operation mode of the boiler 1 (step S6-1).

Fig. 10 is a diagram showing the correspondence between the operation mode and the target value (T*). As shown in Figure 10, target value (T*) = 2°C for operation mode (a), target value (T*) = 3°C for operation mode (b), and target value for operation mode (c). A table to which (T*)=4°C is associated is stored in advance in the storage device 100b. When executing the process of step S6-1, the controller 100 reads the target value T* corresponding to the input operation mode from the storage device 100b, and T* of the above (Equation 1). By substituting into , the expected value (E _x ) is calculated, and finally the next interval time (T _int2 ) is calculated.

According to this second embodiment, the soot blowers 30 and 40 can be operated at a more appropriate interval time T _int2 depending on the operation mode, so the operating efficiency of the soot blowers 30 and 40 is further increased.

(Third Embodiment)

Next, a control system for a soot blower according to a third embodiment of the present invention will be described. The soot blower control system according to the third embodiment is characterized in that the controller 100 changes the spray vapor pressure P of the soot blowers 30 and 40 depending on the operation mode. Hereinafter, explanation will be given focusing on this feature.

Fig. 11 is a flow chart showing the procedure for determining the operation schedule of the soot blower in the third embodiment. As shown in FIG. 11, in the third embodiment, after calculating the next interval time T _int2 , the spray vapor pressure P of the soot blowers 30 and 40 is determined according to the operation mode (configuration) Step S6-2) has a feature.

Figure 12 is a diagram showing the correspondence between the operating mode and the spray vapor pressure (P). As shown in Figure 12, for the operation mode (a), the spray steam pressure (P) = Pa, for the operation mode (b), the spray steam pressure (P) = Pb, and for the operation mode (c), the spray steam pressure ( A table corresponding to P) = Pc is stored in advance in the storage device 100b. The controller 100 selects the spray vapor pressure P of the soot blowers 30 and 40 according to the operation mode in step S6-2, and the pressure of the spray vapor supply line 35 is set to the selected spray vapor pressure. Adjust the opening degree of the steam pressure control valve 37 so that it becomes (P).

According to this third embodiment, since the pressure of the steam sprayed from the soot blowers 30 and 40 can be adjusted, changes in the temperature of the steam in the heat transfer tube 6 can be precisely suppressed depending on the operation mode.

(Fourth Embodiment)

Next, the control system of the soot blower according to the fourth embodiment of the present invention will be described. The soot blower control system according to the fourth embodiment is characterized in that the controller 100 changes the rotational speed N of the soot blowers 30 and 40 according to the operation mode. Hereinafter, explanation will be given focusing on this feature.

Fig. 13 is a flow chart showing the procedure for determining the operation schedule of the soot blower in the fourth embodiment. As shown in Fig. 13, in the fourth embodiment, the rotational speed N of the soot blowers 30 and 40 is determined according to the operation mode after calculating the next interval time T _int2 (step S6). There is a characteristic in -3).

Fig. 14 is a diagram showing the correspondence between the operation mode and the rotation speed (N). As shown in Fig. 14, rotational speed (N) = Na for operation mode (a), rotational speed (N) = Nb for operation mode (b), and rotational speed (N) = Nb for operation mode (c). The table corresponding to Nc is stored in advance in the storage device 100b. In step S6-3, the controller 100 selects the rotational speed N of the soot blowers 30 and 40 according to the operation mode and controls the rotational speed of the motor 38.

According to this fourth embodiment, since the rotational speed of the soot blowers 30 and 40 can be adjusted, changes in the steam temperature of the heat transfer tube 6 can be precisely suppressed depending on the operation mode.

In addition, the present invention is not limited to the above-described embodiments, and various modifications are possible without departing from the gist of the present invention, and all technical matters included in the technical idea described in the claims are the subject matter of the present invention. It becomes. Although the above embodiments are presented as preferred examples, those skilled in the art can realize various alternatives, modifications, variations or improvements based on the contents disclosed in this specification, which are within the technical scope described in the appended claims. included in

In the above-described embodiment, the difference between the steam inlet temperature and the steam outlet temperature of the heat transfer pipe 6 was integrated to calculate the interval time T _int2 of the soot blowers 30 and 40. This is because the steam inlet temperature and the steam outlet temperature of the heat transfer tube 6 are always changing during operation of the boiler 1, but in an operating state in which both the steam inlet temperature and the steam outlet temperature of the heat transfer tube 6 are relatively stable. In this case, the interval time T _int2 may be calculated by integrating only the difference in the temperature of the steam outlet of the heat transfer tube 6.

In addition, in the above-described embodiment, the interval time (T _int2 ) was calculated using the integration value (ΣdT), but the interval time (T _int2 ) was calculated each time the temperature change value (dT) was calculated, and the soot blower 30 , 40) operation may be controlled.

Furthermore, in the above-described embodiment, after the process of determining the interval time T _int2 (step S6), the process of selecting the spray vapor pressure P of the soot blower (step S6-2) and the rotation speed of the soot blower Both of the processes for determining (N) (step S6-3) may be performed.

In addition, in the above embodiment, the method of calculating the interval time (T _int2 ) of the soot blower (30) installed in the heat exchanger was explained, but the interval time (T _int2 ) of the soot blower (40) installed in the furnace wall (11) was explained. When calculating , it is sufficient to integrate the temperature difference between the coolant inlet and outlet of the furnace wall 11.

1: Boiler
2: Brazier
3: Cage part
4: Secondary side wall
6: Heat pipe
10: Fuel Saver
13: Primary superheater
14: Secondary superheater
15: Tertiary superheater
16: Primary reheat
17: Secondary reheating
20a∼20i: Temperature sensor (inlet temperature sensor, outlet temperature sensor)
30, 40: Soot blower
31: Soot blower tube
32: nozzle block
33, 34: Spray hole
35: Atomizing vapor supply line
36: pressure sensor
37: Steam pressure regulating valve
38: motor
39: inverter
50: monitor
100: Controller

Claims (8)

A soot blower that sprays steam onto the surface of a heat transfer tube installed in a boiler, an inlet temperature sensor that detects the steam inlet temperature of the heat transfer tube, an outlet temperature sensor that detects the steam outlet temperature of the heat transfer tube, the inlet temperature sensor, and the outlet. In the soot blower control system including a controller that controls the operation of the soot blower based on each detection signal input from the temperature sensor,
The controller is,
A first temperature difference, which is the difference between the steam inlet temperature and the steam outlet temperature at a first time point during operation of the soot blower, and the steam inlet temperature and the steam outlet temperature at a second time point during operation of the soot blower. A control system for a soot blower, characterized in that the temperature change value that is the difference between the temperature and the second temperature difference is determined, and the operation interval of the soot blower is determined so that the temperature change value is within the range of the target value. According to paragraph 1,
The control system of the soot blower, wherein the controller calculates the temperature change value over a predetermined period to obtain an integrated value, and determines the operation interval of the soot blower so that the integrated value is within the range of the target value. . According to paragraph 2,
A plurality of the soot blowers are installed,
The controller determines an operation interval of the soot blower for each soot blower, and independently controls a plurality of soot blowers according to the operation interval. According to any one of claims 1 to 3,
A plurality of target values are set in advance in correspondence with the operation mode of the boiler,
The control system of the soot blower, characterized in that the controller determines the operation interval of the soot blower based on the target value corresponding to the operation mode input from the outside. According to any one of claims 1 to 3,
A plurality of spray vapor pressures of the soot blower are set in advance in correspondence with the operation mode of the boiler,
The control system of the soot blower, characterized in that the controller determines the spray vapor pressure of the soot blower according to the operation mode input from the outside. According to any one of claims 1 to 3,
A plurality of rotational speeds of the soot blower are set in advance in correspondence with the operation mode of the boiler,
The control system for a soot blower, wherein the controller determines the rotation speed of the soot blower according to the operation mode input from the outside. According to paragraph 2 or 3,
Additionally provided with a monitor connected to the controller and displaying temperature information of the heat pipe,
The control system for a soot blower, characterized in that the controller displays the integrated value on the monitor to correspond to the arrangement of the soot blower. In clause 7,
The soot blower is characterized in that the controller internally stores the temperature information in correspondence with the fuel information of the boiler input from the outside, and simultaneously displays the integrated value on the monitor for each type of fuel input to the boiler. control system.