KR101178257B1 - Clinker monitoring system of bolier in power plant - Google Patents

Abstract

PURPOSE: A clinker monitor system of the powerhouse boiler is provided to supply stable power by preventing a drop of a clinker. CONSTITUTION: A first site facility(100) transmits a clinker image generated in a tube and water wall according to a boiler operation to a central device. A second site facility(200) transmits the pH variation and temperature of cooling water stored in a SDCC(Submerged Drag Chain Conveyor) reservoir, clinker images, and fly ashes to the central device(300) displaying and storing clinker images and information provided to the second site facility and controlling the operation of the first and second site facilities. The power device(600) always maintains a constant reserve rate by calculating the power consumption.

Description

CLINKER MONITORING SYSTEM OF BOLIER IN POWER PLANT}

The present invention relates to a monitoring system of a power plant boiler, and more particularly, to a clinker monitoring system of a power plant boiler that enables to monitor the clinker generated in the water cooling wall and the tube of the boiler according to the combustion of coal. .

In order to meet the demand for electricity due to the acceleration of industrial development, various types of power plants, including hydroelectric power plants, thermal power plants, nuclear power plants, wind power plants, solar thermal power plants, and tidal power plants, are constructed to produce electric power. Thermal power plants play a pivotal role in power generation.

The coal-fired power plant uses coal as its main fuel, and finely pulverizes the coal, supplies it with air to the boiler for combustion, and heats the boiler tube with combustion heat to generate steam to rotate the turbine to produce power. .

Ash from the combustion of coal in the boiler is transported through a wet submerged drag chain conveyor (SDCC), discharged, and solidified in the process.

However, the coal ash produced by the combustion of coal is not completely discharged to the boiler outlet together with the combustion gas, and part of it is melted by the high temperature inside the boiler and solidifies attached to the water cooling wall and the tube.

And, as time passes, the ash solidified on the water cooling wall and the tube in the boiler grows large and is produced as clinker such as (a) and (b) of FIG. 1. As shown in (c) of Figure 1 by the hopper (Hopper) of the lower portion of the boiler or as shown in (d) of Figure 1 to SDCC.

Clinker can be caused by problems with boiler type, problems with operation and blending technology, and problems with coal supplied. Specific causes are as follows.

When the boiler furnace is narrow and the separation distance between burner zone and superheater tube is short, adsorption of coal ash is easy and clinker may be generated.

If the heat transfer area of the boiler is small, the heat load in the burner zone is increased, thereby increasing the temperature in the furnace. Accordingly, coal ash may be easily melted to generate clinker.

When the soot blower installed in the boiler has a small capacity, the clinker attached to the water cooling wall and the tube may not be completely removed at first, and thus the shape of the clinker may be increased.

If an error occurs in the furnace's furnace temperature measurement, the boiler's operation is overheated unnecessarily, increasing the furnace's temperature, so the coal ash can be easily melted and proceed to the clinker.

If the sootblower installed in the boiler is not operated properly, the clinker attached to the water cooling wall and the tube may not be removed at an early stage, and thus the shape of the clinker may be increased.

In addition, it may be generated by the introduction of low-melting viscous coals due to the diversification of imports of coal and the reduction of fuel costs, and by the inadequate ratio of the multiple coal species.

When the clinker is generated in the water cooling wall and the tube of the power plant boiler as described above, the clinker may seriously inhibit heat transfer to reduce power generation efficiency.

In addition, the clinker generated on the heat transfer surface of the boiler lowers the heat absorption of the heat transfer surface and thus increases the temperature of the exhaust gas, which may cause emission deterioration.

In addition, the hopper on the lower side of the boiler may be damaged due to the falling of the clinker adsorbed to the water cooling wall and the upper tube, and the large clinker may accidentally fall into the hopper or the SDCC, causing damage and failure of the hopper or the SDCC system. It can cause serious problems that lead to unplanned power outages.

In addition, it can cause a long-term power generation stop for the removal of large clinker dropped and repair of the broken equipment can cause a serious emergency in the power supply.

The present invention has been proposed in view of the above-described problems, and an object thereof is to detect the clinker generated in the boiler water cooling wall and the tube early according to the operation of the power plant, resulting in the inhibition of heat conduction and the large clinker drop due to the clinker generation. It is intended to prevent unplanned power outages due to damage to the boiler bottom and the SDCC system.

In addition, the monitoring of the clinker generated in the boiler water cooling wall and the tube in real time, so that the planned maintenance schedule according to the generation of the clinker can be established.

In addition, it is possible to analyze and monitor the change in the clinker generation according to the change in the type of coal and fuel mixture supplied to the boiler to provide the selection and mixing of the type of coal to minimize the generation of clinker.

In addition, by continuously monitoring the changes in coal ash and clinker generation that have fallen to the SDCC, the SDCC will be prevented from being stopped and a scheduled maintenance schedule will be established to provide safety and reliability to the operation of the power plant.

Features according to an embodiment of the present invention is a first field device for detecting the clinker image generated in the water-cooled wall and tube in accordance with the boiler operation to transmit to the central unit; A second field device installed at a predetermined position of the SDCC to detect an image of coal ash and clinker loaded on the conveyor, a change in the water temperature of the coolant stored in the SDCC tank, and a change in basicity (pH) of the coolant stored in the SDCC tank; Controls the operation of the first and second site devices, stores and displays the clinker image provided from the first and second site devices, and provides information of the first and second site devices. A central device that analyzes and determines whether the thermal conductivity is inhibited and dropped according to the clinker generation trend and outputs the result; A manager terminal connected to the central device to execute operation and management and clinker analysis with an HMI function; Clinker monitoring system of a power plant boiler is provided, comprising a power supply for supplying power to the first field device, the second field device, the central device, and calculating the power consumption to maintain a constant reserve ratio at all times.

Connected via the central unit and the fan server may further include a remote monitoring terminal for monitoring changes in the water cooling wall of the boiler, clinker generated in the tube and the clinker dropped on the SDCC, coal ash.

The first field apparatus comprises a plurality of image collecting apparatuses including a camera and a field control panel, each installed at a predetermined position of a boiler, and collecting and transmitting images of the clinker generated and grown in a surveillance region of a set viewing angle to a central apparatus. Can be.

The second field device includes a camera for collecting coal ash, clinker, and conveyor operation state which are loaded on the conveyor and discharged from the SDCC as an image; A temperature detector detecting a temperature change of the coolant stored in the SDCC tank; It may include a pH detector for detecting a change in the basic (pH) of the cooling water stored in the SDCC tank.

The second field apparatus may further include a level detector for detecting a change in the level of the coolant stored in the SDCC tank according to the change in the coal ash and the drop in the clinker.

The central apparatus may check an operation state of the cameras configured in the first field apparatus and the second field apparatus, and control the entry and withdrawal, rotation, coal ash purge, focal length, exposure, and shutter speed of the camera.

The central unit analyzes the information collected from the first and second field devices, extracts the trend of clinker generation according to coal type change and mixing, and determines the type of coal and mixing that minimizes clinker generation and outputs the result. have.

The central apparatus may analyze the image of the SDCC provided by the second field apparatus, the temperature change of the cooling water, and the basic (pH) change of the cooling water to estimate the amount of change in coal ash and the amount of clinker precipitated and dropped in the SDCC, and output the result. .

The central unit collects the image of the water cooling wall and tube provided from the first field device and the coal ash image provided from the second field device, the temperature change of the coolant, the basic (pH) change of the coolant to generate the clinker and analyze the growth trend. A data collection unit provided to the control unit for establishing a maintenance schedule and provided and stored in the image recording unit; Analyzes the image of water cooling wall and tube, the change of cooling water temperature, basic pH (pH), change of discharged coal ash, and clinker of SDCC, and results of clinker growth according to each location, inhibition of thermal conduction and dropping, and generation of clinker according to coal species and mixed matters. The control unit to determine the maintenance schedule and determine the type of coal and mixed fire; A first driving unit configured to draw out and draw in a camera configured in a first field apparatus, rotate to collect an image of a surveillance region other than a main surveillance region, and purge coal ash attached to a lens under the control of the controller; A second driver adjusting a focal length, exposure, and shutter speed of a camera configured in a first field device under control of the controller; An image recording unit storing the boiler water cooling wall and the tube provided by the data collecting unit and the surveillance image of the SDCC in a designated area by matching the installation position of the camera; A display unit configured to display a surveillance image of the boiler water cooling wall and the tube detected by the data collection unit, a surveillance image of the SDCC, a change in the water temperature of the SDCC cooling water, and a change in the basic temperature (pH) of the cooling water of the SDCC; A database for storing clinker generation and growth trends for each position of the boiler water cooling wall and tube analyzed by the control unit, and a result of the generation of clinker according to the change of coal species and mixed matters; It may include a hub for supporting a communication connection with the terminal configured externally.

The power supply includes a transformer for stepping down a voltage of three-phase AC480V / 60Hz to a voltage of AC220V / 60Hz; A distributor for supplying the voltage stepped down by the transformer to the first and second field devices as an operating voltage; It may include a UPS for converting the AC voltage supplied from the transformer to a direct current and stored in the storage battery, and supplying power to the first and second field devices when the main power is cut off due to power failure or repair or replacement of the transformer. .

The viewing angle of the camera may be set differently according to the installed position, and 90 ° H × 60 ° V × 100 ° D, 72 ° H × 52 ° V × 90 ° D, 60 ° H × 45 ° V × 75 It may be set to any one or more of ° D.

The field control panel may draw the camera into and out of the boiler under the control of the central apparatus, rotate the camera to collect images around the main surveillance area, and purge the coal ash adsorbed around the camera lens. .

The field control panel may circulate a cooling medium in the camera unit to protect the camera from the high temperature of the boiler.

The field control panel may adjust the focal length, exposure, shutter speed of the camera under the control of the central unit.

The field control panel may supply any one of cooling water, hydrogen, and compressed air as a cooling medium for protecting the camera.

The first field device includes a field control panel; The camera unit is configured to combine the lens, the camera unit installed in the enclosure of stainless steel to protect the camera from the high temperature of the boiler; A transfer device configured under the camera unit to draw the camera unit from the inside of the boiler or to the inside of the boiler; Guide member for guiding the movement of the camera unit to be drawn in and drawn out by the operation of the transfer device; Rotating device to rotate the camera unit at a predetermined angle to collect the image for the surveillance region other than the main surveillance region; It may include a purge device for injecting air to the coal ash accumulated in the lens unit of the camera unit to purge.

The field control panel includes an AC / DC converter for converting the voltage of AC220V supplied from the power supply device into a DC voltage and then stepping down and supplying power to the power supply; A servo controller controlling the driving of the rotating device; A lamp indicating an operating state; Communication unit for performing communication with the central device; An amplifier for amplifying the image collected by the camera unit; It may include a cooling unit for protecting the device configured in the field control panel from the high temperature around the boiler.

The on-site control panel has a pressure control unit for adjusting the pressure of the air supplied from the first compressor and the second compressor; A solenoid valve for intermittent supply of air; It may include a filter for removing moisture and impurities contained in the air supplied from the second compressor.

The cooling unit may supply the air supplied from the first compressor to the inside of the field control panel to maintain the temperature of the field control panel below the set temperature.

Air to which the moisture and impurities have been removed may be supplied to the inside of the camera unit to provide a cooling function with respect to the high temperature in the boiler furnace, and to purify the coal ash contaminated on the lens.

The field control panel may draw out the camera unit from the inside of the boiler when the power is cut off when the cooling air supplied to the camera unit is cut off or the pressure of the cooling air falls below the set pressure.

When the soot blower driving signal is input in the area where the camera unit is installed, the field control panel may draw out the camera unit from the inside of the boiler in order to prevent lens contamination by steam jetting.

The field control panel may automatically return to the main monitoring area when a predetermined time elapses while the camera unit is rotated to an area other than the main monitoring area by the operation of the rotating device.

In addition, a feature according to another embodiment of the present invention is a camera installed to collect the image inside the boiler; An on-site control panel for controlling an image collection operation of the camera; A camera for collecting images of coal ash and clinker discharged from the SDCC to the conveyor; A temperature detector for detecting a change in the temperature of the coolant water stored in the SDCC tank; A pH detector for detecting basic changes in the cooling water stored in the SDCC bath; A data collection unit for collecting and distributing images of the inside of the boiler, images of coal ash and clinker discharged, temperature changes of the cooling water, and basic changes of the cooling water; A control unit for analyzing the information provided from the data collection unit to determine the clinker growth trend, thermal conduction inhibition and fall, and clinker generation results according to carbon species and mixed matters for each location; A first driving unit configured to carry out drawing and drawing of a camera collecting a boiler image, rotation for expanding a surveillance area, and purging coal ash under control of the controller; A second driver adjusting a focal length, exposure, and shutter speed of a camera collecting a boiler image under control of the controller; An image recording unit for storing the general information provided from the data collecting unit and storing the matching information with the installation position of the camera; A display unit displaying information provided from the data collector and an analysis result of the controller; A database storing clinker generation and growth trends analyzed by the control unit, and a clinker generation result according to changes in coal species and mixed matters; Clinker monitoring system of a power plant boiler is provided, comprising a hub for supporting a communication connection with a terminal configured to the outside.

As described above, the present invention can establish a planned maintenance by monitoring the clinker generated in the water cooling wall and the tube of the power plant boiler in real time, and improve the thermal efficiency of the boiler.

In addition, the occurrence of clinker falling objects can be prevented in advance, so that stable power supply and damage to power plant equipment can be prevented in advance.

In addition, the present invention by analyzing and monitoring the change in the clinker generation according to the change of carbon type and mixing, it is possible to determine the type of coal and mixed to minimize the generation of clinker can provide stability and optimal efficiency in operation of the thermal power plant.

1 illustrates a clinker generated in a power plant boiler and a clinker dropped on an SDCC.
2 is a view schematically showing a clinker monitoring system of a power plant boiler according to an embodiment of the present invention.
3 is a view showing a detailed configuration for the clinker monitoring system of a power plant boiler according to an embodiment of the present invention.
4 is a view showing the installation position of the first field device in the clinker monitoring system of a power plant boiler according to an embodiment of the present invention.
5 is a view showing the detailed configuration of the first site in the clinker monitoring system of a power plant boiler according to an embodiment of the present invention.
6 is a view showing a state of the monitoring screen in the clinker monitoring system of a power plant boiler according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

The present invention can be embodied in various different forms, and thus the present invention is not limited to the embodiments described herein.

2 is a view schematically showing a clinker monitoring system of a power plant boiler according to an embodiment of the present invention, Figure 3 is a view showing a detailed configuration for the clinker monitoring system of a power plant boiler according to an embodiment of the present invention.

2 and 3, an embodiment of the present invention includes a first field apparatus 100, a second field apparatus 200, a central apparatus 300, an administrator terminal 400, a remote monitoring terminal 500 and And a power supply 600.

The first field apparatus 100 is expected to generate clinker in the boiler, and is installed in a zone that does not interfere with the operation of the boiler, and detects the clinker generated in the water cooling wall and the tube according to the operation of the boiler as a central device ( 300).

The first field device 100 is composed of a plurality of image acquisition device 110 consisting of a camera 111 and the field control panel 112 are respectively installed at a predetermined position of the boiler, the clinker in the monitoring area of the set viewing angle It collects and generates an image, such as a growth trend, a drop or not, and provides the image to the central apparatus 300.

The camera 111 is composed of a CCD (Charged Coupled Device) camera that provides clear image quality, fine expression, and fine color separation, and is capable of light weight reduction, and collects and corrects an image in a surveillance area having a set viewing angle to display a video signal. Will output

The viewing angle of the camera 111 is set differently according to the installation position. For example, 90 ° H × 60 ° V × 100 ° D, 72 ° H × 52 ° V × 90 ° D, 60 ° H × 45 It can be adjusted to ° V × 75 ° D.

The field control panel 112 is connected to the central unit 300, controls all operations for collecting the image of the camera 111 under the control of the central unit 300, and controls the video signal provided from the camera 111. Amplified to a predetermined predetermined level and transmitted to the central device (300).

The field control panel 112 draws in and out the camera 111 into the boiler according to the control of the central unit 300, rotates the camera 111 to collect the image around the outside of the main monitoring area, Coal ash adsorbed around the lens of the camera 111 is purged to ensure a stable surveillance image.

The field control panel 112 circulates the cooling medium in the camera 111 to protect the camera 111 from the high temperature of the boiler.

The cooling medium circulated in the camera 111 may be provided with cooling water, hydrogen, air, or the like, and preferably supplies cooling air.

The field control panel 112 controls the focal length, exposure, shutter speed, etc. of the camera 111 to collect an image for the surveillance region of the viewing angle set under the control of the central apparatus 300.

The second field apparatus 200 is installed at a predetermined position of the SDCC and detects images of coal ash and clinker loaded on a conveyor, changes in the water temperature of the coolant stored in the SDCC tank, and changes in basicity (pH) of the coolant stored in the SDCC tank. To provide the central device (300).

The second field apparatus 200 includes a camera 210, a temperature detector 220, a pH detector 230, and an on-site control panel 350.

The camera 210 is installed at a predetermined position of the conveyor area connected to the upper side in the horizontal conveyor of the SDCC is collected on the fly ash and the clinker and the conveyor operating state discharged on the upper side of the conveyor in the image control panel 350 It provides the central unit 300 as a video signal through.

The temperature detector 220 is installed at a predetermined position of the SDCC tank, detects a change in the water temperature of the coolant, and provides the information to the central apparatus 300 through the field control panel 350.

The pH detector 230 is installed at a predetermined position of the SDCC tank, and detects the basic (pH) change of the coolant according to the effects of coal ash change, clinker change, and coal type change according to the operation, and provides information about the on-site control panel 350. Provided to the central unit 300 through.

The second field apparatus 200 may further include a level detector 240, and the level detector 240 detects a change in the level of the coolant stored in the SDCC tank according to the amount of coal ash change and the amount of clinker change, and displays information on the spot. Provided to the central unit 300 through the control panel 350.

The central apparatus 300 controls all operations of the first field apparatus 100 and the second field apparatus 200 by connecting the first field apparatus 100 and the second field apparatus 200 through a network. 1 Collect and store the surveillance image of the clinker generated from the boiler water cooling wall and the tube provided in the field device 100, and analyze the collected surveillance image to determine whether to inhibit the heat conduction and fall according to the trend of the clinker is planned maintenance Set a schedule.

The central unit 300 checks the operation state of the camera configured in the first field device 100 and the second field device 200, the camera's incoming and outgoing, rotation, coal ash purge, focal length, exposure, shutter Control speed and more.

The central unit 300 displays an image of the surveillance region of the set viewing angle provided by the first field apparatus 100 and the second field apparatus 200 on the screen, analyzes the image, and is generated on the water cooling wall and the tube. Provide the deposit shape of the clinker.

The central unit 300 extracts the trend of clinker generation according to the change of coal type and blending through the analysis of the collected images so that the type of coal and blend is minimized.

The central unit 300 analyzes the image of the SDCC provided from the second field device 200, the temperature change of the cooling water, the basic (pH) change of the cooling water, and estimates the amount of change in coal ash and the amount of clinker precipitated by dropping in the SDCC. can do.

The central unit 300 analyzes the image of the SDCC provided by the second field device 200 and the temperature change of the coolant, the basic (pH) change of the coolant, and the level change of the coolant stored in the SDCC tank to change the amount of coal ash and fall. The amount of clinker change can be estimated.

The central device 300 is connected to the manager terminal 400 to display the image of the surveillance area provided by the first field device 100 and the second field device 200 on the screen, the image analysis is provided by the HMI function To be possible.

The central device 300 is connected to the remote monitoring terminal 500 through a web server to remotely monitor an image of a surveillance area provided from the first field device 100 and the second field device 200 at a remote location. To be monitored.

The central device 300 includes a controller 310, a first driver 320, a second driver 330, a data collector 340, an image recorder 350, a display 360, a database 370, and a hub. 380.

The controller 310 controls the overall operation of the first field apparatus 100 and the second field apparatus 200, the image of the water cooling wall and the tube collected by the first field apparatus 100, and the second field apparatus 200. ) Analyzes the amount of change in coal ash collected from cinder, change in clinker, change in temperature of coolant, change in basic (pH) of coolant, etc., and store the result in database 370 and at the same time as set in display 360 Display.

The controller 310 executes image analysis using a video capture function, and searches for video data stored in the video recording unit 350 by camera, time-by-time search, image magnification, and the like through the request of the HMI through the display unit 360. Provides reduction, printer of search results, playback of recordings, etc.

The first driving unit 320 rotates to drive the first field apparatus 100 according to the control signal of the controller 310 to collect images of the surveillance region other than the withdrawal, withdrawal, and main surveillance region of the camera 111. And purging the ash of the ash which is attached to the lens.

The second driving unit 330 drives the first field device 100 according to the control signal of the control unit 310 and the focal lengths of the cameras 210 formed in the camera 111 and the second field device 200. Perform general operations for collecting images such as exposure and shutter speed.

The data collection unit 340 collects an image of the water cooling wall and the tube provided from the first field device 100, the change amount of coal ash provided by the second field device 200, the change amount of the clinker, the temperature change of the cooling water, By collecting the change in the basic (pH) of the cooling water and the like to the control unit 310, it is possible to provide the generation and growth trend analysis of the clinker and the establishment of the maintenance schedule accordingly.

The data collector 340 is an image recording unit 350 of the image of the boiler water cooling wall and tube collected by the first field device 100 and the coal ash of the SDCC collected by the second field device 200 and the dropped clinker image. To be stored in real time.

The image recording unit 350 matches the surveillance image of the boiler water cooling wall, the tube, and the SDCC provided by the data collecting unit 340 with the DVR, and stores it as a moving image in a designated area.

The display unit 360 may monitor video information of the boiler water cooling wall and the tube provided by the first field device 100 and the second field device 200, and the video image information of the SDCC provided by the second field device 200. The change in the water temperature of the cooling water stored in the SDCC tank and the change in the basicity (pH) of the cooling water are displayed in a predetermined manner.

When the second field apparatus 200 includes a level detector, the level change of the coolant stored in the SDCC tank is displayed.

The display unit 360 includes an input function consisting of, for example, a touch screen or a button of a mouse click to provide the control unit 310 and a human machine interface (HMI), and generates a clinker and grows a clinker according to a request of the HMI. Analysis results such as trends are displayed in a predetermined format.

The display unit 360 is to provide a HMI, the recording time, recording mode and the selection of the monitoring mode, the remaining capacity and recording method of the hard disk display, camera selection, division by division, image quality control for the surveillance image and recorded image, alarm, Event log and screen change are provided.

The database 370 is a clinker according to the location of the clinker generation and growth for each location such as the boiler water cooling wall, the tube, and the SDCC analyzed by the controller 310 according to the request of the HMI configured in the display unit 360, and the change of the carbon species and the mixed matter. The result of generation of the data is stored in a predetermined format.

The hub 380 supports the communication connection between the manager terminal 400 and the remote monitoring terminal 500 that is configured externally, so that the video surveillance of the clinker generated in the boiler can be provided.

The manager terminal 400 is installed outside the central unit 300 and is connected to the heavy-duty unit 300 through the hub 380 to execute the operation and management of the central unit 400 and analyze the information collected through the HMI. do.

Remote monitoring terminal 400 is a terminal connected through a web server can monitor the water cooling wall of the boiler, a clinker generated in the tube and a drop in the SDCC clinker, coal ash, etc. at a remote location.

The power supply unit 600 supplies stable power to the first field apparatus 100, the second field apparatus 200, and the central apparatus 300 configured according to the embodiment of the present invention, and calculates a power consumption to maintain a predetermined reserve ratio. This should always be maintained.

The power supply 600 includes a transformer 610, a distributor 620, and a UPS 6300.

For example, the transformer 610 steps down the voltage of the three-phase AC480V / 60Hz to a voltage of AC220V / 60Hz and supplies it to the distributor 620.

The distributor 620 supplies the voltage of the step-down voltage of the transformer 610, for example, AC220V / 60Hz, to the first field device 100 and the second field device 200 as operating voltages.

The UPS 630 converts an AC voltage supplied from the transformer 610, for example, a voltage of AC220V / 60Hz into a direct current through a rectifier configured therein, and stores the same in a storage battery, and performs a power failure or repair or replacement of the transformer 610. When the main power is cut off, it is automatically converted to convert the DC voltage stored in the battery into an inverter to maintain a normal power supply to each device so that stable operation can be provided.

4 is a view showing the installation position of the image collecting device in the clinker monitoring system of a power plant boiler according to an embodiment of the present invention.

Referring to FIG. 4, the plurality of image acquisition apparatuses 110 constituting the first field apparatus 100 may include a first position A1, a second position A2, and a superheater position of the hopper in a power plant boiler. A3), a superheater nose position A4, and a reheater nose position A5, respectively.

The position at which the image collecting device 110 is installed is not limited, but various positional changes and numbers can be changed according to design.

The image collecting device 110 installed at the first position A1 and the second position A2 of the hopper has a viewing angle and a monitoring area set to the lower side to monitor the clinker dropped on the hopper.

The image collecting device 110 installed at the superheater position A3 has a viewing angle and a monitoring area set to monitor the clinker generated and grown in the superheater according to the operation of the boiler.

The image collecting device 110 installed at the superheater nose position A4 has a viewing angle and a monitoring area set to monitor the clinker generated and grown in the nose area of the superheater according to the operation of the boiler.

 The image collecting device 110 installed at the reheater nose position A5 has a viewing angle and a monitoring area set to monitor the clinker generated and grown in the reheater according to the operation of the boiler.

5 is a view showing the detailed configuration of the first site in the clinker monitoring system of a power plant boiler according to an embodiment of the present invention.

Referring to FIG. 5, the embodiment of the first field device includes the field control panel 101, the first compressor 102A, the second compressor 102B, the camera unit 103, the transfer device 104, and the guide member 105. ), A lens protector 106, a rotating device 107, and a purge device 108.

The on-site control panel 101 converts the voltage of AC220V supplied from the power supply device into DC voltage and then step-downs the AC / DC converter for supplying power to the camera, and a servo controller controlling the driving of the rotating device 107. ), A lamp indicating the operation state, a communication unit for communicating with the central unit, an amplifier for amplifying the image collected from the camera for long-distance transmission to the central unit, a device configured in the field control panel 101 from the high temperature around the boiler It includes a cooling unit for protecting the.

The cooling unit is supplied from the first compressor (102A) to maintain the temperature inside the on-site control panel 101 to the set temperature, for example, less than 40 ℃ by the pressure-adjusted air of the devices configured in the on-site control panel 101 Prevents malfunctions and damage from occurring.

On the lower part of the field control panel 101, a pressure regulating unit for adjusting the pressure of the air supplied from the first compressor 102A and the second compressor 102B, a solenoid valve for regulating the supply of air, and a second compressor 102B. A filter is configured to remove moisture and impurities contained in the supplied air.

The camera unit 103 has a structure in which the camera and the lens are coupled to each other, and installed in an enclosure made of stainless steel to protect the camera from the high temperature of the boiler so that the camera unit 103 may be protected from the harsh environment.

The camera unit 103 is supplied from the second compressor (102B) in order to be able to safely capture the image from the high temperature in the boiler furnace is supplied with air to remove moisture and impurities through a filter to provide a cooling function, inside the boiler A purge function is provided to prevent the lens from being contaminated from coal ash.

The conveying device 104 is configured on the lower side of the camera unit 103, the cooling air supplied to the camera unit 103 is cut off or the pressure of the cooling air is lowered below the set pressure or the power is cut off If the camera unit 103 is withdrawn from the boiler to prevent damage from high temperatures.

The transfer device 104 is a camera unit 103 when a soot blower driving signal is input in the region where the camera unit 103 is installed in order to prevent the lens from being contaminated from steam jets due to sootblowing. Is drawn from inside the boiler.

When the risk factor that affects the stability of the camera unit 103 is released, the transfer device 104 allows the camera unit 103 to be introduced into the boiler so that image collection can be performed.

The transfer device 104 is operated by air supplied from the second compressor 102B to remove moisture and impurities by a filter, and the introduction and withdrawal of the camera unit 103 by the operation of the transfer device 104 is performed. It moves along the guide member 105.

The rotating device 107 may be installed at a predetermined position of the lens protection unit 106 and may be configured as a server motor and a reduction device, and set the camera unit 103 at a predetermined angle according to a control signal applied from the central device. For example, it rotates 90 ° to the left and right to collect images for surveillance areas other than the main surveillance area.

The rotating device 107 automatically returns to the main monitoring area when the set time elapses from the rotated position.

The purge device 108 purges the coal ash accumulated around the camera lens with the air supplied from the first compressor 102A.

6 is a view showing a state of the monitoring screen in the clinker monitoring system of a power plant boiler according to an embodiment of the present invention.

Referring to FIG. 6, the monitoring screen provided to the display unit 360 or the manager terminal 400 includes a function of an HMI, rotation control of a camera, control of input / output signals, video surveillance and analysis, generation of clinker, analysis of growth trend, and the like. Provide information.

As can be seen in the figure, the name of each installation location of the camera, as shown in item 1, and outputs the surveillance image of each installation location of the camera as shown in item 2, the surveillance image can support 30 frames per second video. .

By selecting the surveillance image output as shown in item 2, it is possible to analyze the clinker generation and growth trend, and to capture and store the image.

Then, as shown in item 3, information such as whether the camera control is executed by local or remote control, whether the camera is drawn into or taken out of the boiler, or whether the air purge control is performed to prevent foreign matter from adhering to the camera lens is output. .

In addition, as in item 4, the HMI function allows manual or automatic selection of camera in / out and air purge control, and the camera can be rotated left and right to an observation area other than the main monitoring area. Display information.

Analyze the clinker dropped on the SDCC as in item 5 and output it as stereoscopic information, and change the water temperature and basicity of the coolant stored in the tank due to the effects of changes in coal ash, clinker, coal species and mixed matters in the SDCC as shown in item 6. pH) change information is outputted, and cleaning status information of the pH detector is output as shown in item 7.

The operation according to the embodiment of the present invention including the function as described above is executed as follows.

When the power supply device 600 configured in the present invention steps down the voltage of the three-phase AC480V / 60Hz to a voltage of AC220V / 60Hz to supply power to each component of the monitoring system, the operation of the clinker monitoring starts in the boiler. The first field apparatus 100 installed in a predetermined number in a region where clinker is expected to be generated, detects the clinker generated in the water cooling wall and the tube according to the operation of the boiler, and provides the image to the central apparatus 300.

In addition, the second field apparatus 200 installed at a predetermined position of the SDCC includes images of coal ash and clinker discharged and loaded on the conveyor according to the operation of the boiler, changes in the water temperature of the coolant stored in the SDCC tank, and basicity of the coolant stored in the SDCC tank. pH change is detected and provided to the central device 300.

The second field apparatus 200 may further include a level change of the coolant stored in the SDCC tank with respect to the information provided to the central apparatus 300.

The central unit 300 collects and stores the surveillance image of the clinker generated from the boiler water cooling wall and the tube provided by the first site apparatus 100, and analyzes the collected surveillance image to inhibit the thermal conduction and drop according to the generation of the clinker. Determine whether there is a planned maintenance schedule.

In addition, the central unit 300 analyzes the surveillance image of the SDCC provided from the second field device 200, the temperature change of the coolant, the basic (pH) change of the coolant, the amount of change in the coal ash, and the amount of clinker changes dropped and precipitated in the SDCC. And the like can be estimated.

The central unit 300 displays image information on the screen of the surveillance region of the set viewing angle provided by the first field apparatus 100 and the second field apparatus 200 on the screen, and analyzes the image to generate the water cooling wall and the tube. To provide the deposited shape of the clinker.

The central device 300 extracts the change in the clinker generation according to the change of the type of coal and the mixing by the analysis of the collected surveillance images, and determines the type of coal selection and the mixing of the generation of the clinker is minimized.

The central device 300 is connected to the manager terminal 400 to display an image of the surveillance area provided by the first field device 100 and the second field device 200 on a screen, and provide an HMI screen to analyze the image. To be provided.

In addition, the central device 300 is connected to the remote monitoring terminal 500 through a web server to monitor the image of the surveillance area provided from the first field device 100 and the second field device 200 in real time from a remote location. Do it.

The above operation will be described in detail.

The data collection unit 340 configured in the central apparatus 300 collects the images of the water cooling wall and the tube provided from the first field apparatus 100, and changes the amount of coal ash of the SDCC provided from the second field apparatus 200, After collecting the amount of clinker changes, changes in the temperature of the coolant, changes in the basicity (pH) of the coolant, and the like, the image recorder 350 is provided to the controller 310 for analysis of the formation and growth of the clinker and the establishment of a maintenance schedule accordingly. Provided to and stored.

In addition, the monitoring image of the boiler water cooling wall and the tube provided by the first field apparatus 100 and the second field apparatus 200 and the monitoring temperature of the SDCC provided by the second field apparatus 200 and the water temperature change of the coolant, The basic pH change of the cooling water is displayed in a predetermined manner set through the display unit 360.

The control unit 310 is an image of the water cooling wall and the tube collected by the first field apparatus 100, the change amount of coal ash collected from the second field apparatus 200, the change amount of the clinker, the temperature change of the coolant, the basic change of the coolant And the like, and the result is stored in the database 370 and displayed in a predetermined manner through the display unit 360.

In addition, the control unit 310 provides a camera-by-time, time-by-time search, enlargement and reduction of an image, a printer of a search result, recording and playback, etc. of the image data stored in the image recording unit 350 at the request of the HMI through the display unit 360. do.

In addition, the control unit 310 operates the cooling unit of the field control panel 101 configured in the first field apparatus 100 through the first driving unit 320 to set the temperature inside the field control panel 101, eg For example, by maintaining below 40 ℃ to prevent the malfunction and damage of the devices configured in the field control panel 101 occurs.

In addition, the control unit 310 supplies cooling air to the camera unit 103 through the first driving unit 320 to protect the camera from the high temperature of the boiler, and to supply the purge air to prevent contamination of the lens from the coal ash. do.

In addition, the controller 310 rotates the camera unit 103 at a predetermined predetermined angle through the first driving unit 320 so that an image of a region other than the main monitoring region is collected.

In addition, when the cooling air supplied to the camera unit 103 is cut off, or when the pressure of the cooling air falls below a set pressure or the power is cut off, the controller 310 may be contaminated by the lens by steam jet. When the camera unit 103 is pulled out from the inside of the boiler through the first driving unit 320 to prevent damage from high temperature, and when the risk factor is released, the camera unit 103 may be drawn into the boiler to collect images. Make sure

The image collection is preferably performed at intervals of a predetermined period set to protect the camera unit 103 from high temperatures.

In addition, the control unit 310 is a focal length and exposure of the camera 111 configured in the first field device 100 and the camera 210 formed in the second field device 200 through the second driving unit 330. In addition, the shutter speed may be adjusted to optimize the collection of images.

Clinker generation and growth trend for each location such as boiler water cooling wall, tube, and SDCC collected and analyzed in the first and second site apparatuses 100 and 200 as described above, and generation of clinker according to changes in coal species and mixed matters. And the like are stored in the database 370 and output through the display unit 360.

As described above, when the main power is cut off while the clinker monitoring is in progress according to the boiler operation, the UPS 630 in the power supply unit 600 converts the DC voltage stored in the battery into an inverter and supplies it to the respective devices. Allows operation to be maintained.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be understood that various modifications and changes may be made without departing from the scope of the appended claims.

100: first field device 200: second field device
300: central unit 400: manager terminal
500: remote monitoring terminal 600: power supply

Claims (25)

A first field apparatus comprising a plurality of image collecting apparatuses including a camera and a field control panel, each installed at a predetermined position of a boiler, and detecting and transmitting a clinker image generated from a water cooling wall and a tube according to a boiler operation to a central apparatus;
The image of coal ash and clinker loaded on the conveyor and installed at a certain position of the submerged drag chain conveyor (SDCC), the change in the water temperature of the coolant stored in the submerged drag chain conveyor (SDCC) tank, and the coolant stored in the submerged drag chain conveyor (SDCC) tank. A second field apparatus for detecting basic (pH) changes and transmitting the same to the central apparatus;
A central apparatus for controlling the operation of the first and second field apparatuses and storing and displaying the clinker image provided from the first and second field apparatuses;
An administrator terminal connected to the central device to execute operation and management and clinker analysis with a Human Machine Interface (HMI) function;
A power supply device for supplying power to the first field device, the second field device, and the central device, and calculating a power consumption to maintain a constant reserve ratio at all times;
Including,
The central device analyzes the information of the first and second field devices to determine whether the thermal conduction is inhibited and dropped according to the clinker generation trend, and the operation state of the camera configured in the first and second field devices is checked. Clinker monitoring system of the power plant boiler, characterized in that the camera to control the incoming and outgoing, rotation, coal ash purge, focal length, exposure, shutter speed. delete delete The method of claim 1,
The second field apparatus includes a temperature detector for detecting a change in water temperature of cooling water stored in a submerged drag chain conveyor (SDCC) tank;
A level detector which detects a change in the level of cooling water stored in a submerged drag chain conveyor (SDCC) tank according to a change in coal ash and a drop in clinker;
Including,
A camera for collecting images of coal ash, clinker, and conveyor operation in a submerged drag chain conveyor (SDCC) tank;
A pH detector for detecting a basic (pH) change of cooling water stored in a submerged drag chain conveyor (SDCC) tank;
Clinker monitoring system of a power plant boiler comprising a. delete delete The method of claim 1,
The central unit analyzes the information collected from the first and second field devices, extracts the trend of clinker generation according to coal type change and mixing, and determines the type of coal and mixing that minimizes clinker generation and outputs the result. Clinker monitoring system for power plant boilers. The method of claim 1,
The central unit analyzes the image of the submerged drag chain conveyor (SDCC) provided by the second field device, the temperature change of the coolant, and the basic (pH) change of the coolant to fall to the coal ash change and the submerged drag chain conveyor (SDCC) to settle. Clinker monitoring system of a power plant boiler, characterized in that for estimating the amount of change in the clinker output. The method of claim 1,
The central unit collects the image of the water cooling wall and tube provided from the first field device and the coal ash image provided from the second field device, the temperature change of the coolant, the basic (pH) change of the coolant to generate the clinker and analyze the growth trend. A data collection unit provided to the control unit for establishing a maintenance schedule and provided and stored in the image recording unit;
Analyze the image of water cooling wall and tube, the change of cooling water temperature, basic (pH), discharge of coal ash, and clinker of cooling water of submerged drag chain conveyor (SDCC), and analysis of clinker growth, thermal conduction inhibition and drop, coal type and A control unit for determining a clinker generation result according to the mixing point, establishing a maintenance schedule, and determining a type of coal and mixing rate;
A first driving unit configured to draw out and draw in a camera configured in a first field apparatus, rotate to collect an image of a surveillance region other than a main surveillance region, and purge coal ash attached to a lens under the control of the controller;
A second driver adjusting a focal length, exposure, and shutter speed of a camera configured in a first field device under control of the controller;
An image recording unit for matching the surveillance image of the boiler water cooling wall and the tube provided from the data collection unit and the submerged drag chain conveyor (SDCC) with the installation position of the camera and storing the image in the designated area;
Surveillance image of the boiler water cooling wall and tube detected through the data collection unit and surveillance image of SDCC (Submerged Drag Chain Conveyor), water temperature change of SDCC (Submerged Drag Chain Conveyor), and cooling water basicity of Submerged Drag Chain Conveyor (SDCC) a display unit for displaying the pH) change in a set manner;
A database for storing clinker generation and growth trends for each position of the boiler water cooling wall and tube analyzed by the control unit, and a result of the generation of clinker according to the change of coal species and mixed matters;
A hub supporting a communication connection with an externally configured terminal;
Clinker monitoring system of a power plant boiler comprising a. delete delete delete The method of claim 1,
The field control panel draws and draws the camera into the boiler under the control of the central unit, rotates the camera to collect images around the main surveillance area, and purges the coal ash adsorbed around the camera lens. Clinker monitoring system for power plant boilers. The method of claim 1,
The field control panel is a clinker monitoring system of a power plant boiler, characterized in that for circulating the cooling medium in the camera unit to protect the camera from the high temperature of the boiler. The method of claim 1,
The field control panel is a clinker monitoring system of a power plant boiler, characterized in that for adjusting the focal length, exposure, shutter speed of the camera according to the control of the central unit. The method of claim 1,
The field control panel is a clinker monitoring system of a power plant boiler, characterized in that for supplying any one of cooling water, hydrogen, compressed air as a cooling medium for protecting the camera. The method of claim 1,
The first field device includes a field control panel;
The camera unit is configured to combine the lens, the camera unit installed in the enclosure of stainless steel to protect the camera from the high temperature of the boiler;
A transfer device configured under the camera unit to draw the camera unit from the inside of the boiler or to the inside of the boiler;
Guide member for guiding the movement of the camera unit to be drawn in and drawn out by the operation of the transfer device;
Rotating device to rotate the camera unit at a predetermined angle to collect the image for the surveillance region other than the main surveillance region;
A purge device that injects and purges air to the coal ash accumulated in the lens unit of the camera unit;
Clinker monitoring system of a power plant boiler comprising a. 18. The method of claim 17,
The field control panel includes an AC / DC converter for converting the voltage of AC220V supplied from the power supply device into a DC voltage and then stepping down and supplying power to the power supply;
A servo controller controlling the driving of the rotating device;
A lamp indicating an operating state;
Communication unit for performing communication with the central device;
An amplifier for amplifying the image collected by the camera unit;
Cooling unit for protecting the device configured in the field control panel from the high temperature around the boiler;
Clinker monitoring system of a power plant boiler comprising a. 18. The method of claim 17,
The on-site control panel has a pressure control unit for adjusting the pressure of the air supplied from the first compressor and the second compressor;
A solenoid valve for intermittent supply of air;
A filter for removing moisture and impurities contained in the air supplied from the second compressor;
Clinker monitoring system of a power plant boiler comprising a. 19. The method of claim 18,
The cooling unit is a clinker monitoring system of a power plant boiler, characterized in that to supply the air supplied from the first compressor into the field control panel to maintain the temperature of the field control panel below the set temperature. 19. The method of claim 18,
Clinker monitoring system of a power plant boiler characterized in that the air is removed from the moisture and impurities is supplied to the camera unit to provide a cooling function against the high temperature in the boiler furnace, and to purge the contaminated coal ash in the lens. 19. The method of claim 18,
The site control panel is a clinker of a power plant boiler, characterized in that when the cooling air supplied to the camera unit is cut off or the pressure of the cooling air is lowered below the set pressure, the power is cut off the camera unit from the inside of the boiler Surveillance system. 19. The method of claim 18,
The field control panel is a clinker monitoring system of a power plant boiler, characterized in that when the soot blower operation signal is input in the area where the camera unit is installed, draw out the camera unit from the inside of the boiler to prevent lens contamination by steam jet. 19. The method of claim 18,
The site control panel is a clinker monitoring system of a power plant boiler, characterized in that the camera unit is automatically returned to the main monitoring area when the set time elapses while the camera unit is rotated to an area other than the main monitoring area by the operation of the rotating device. delete

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