KR101962769B1 - apparatus for removing dust scattering - Google Patents

Abstract

The present invention relates to an apparatus to remove scattering dust and, more specifically, to an apparatus to remove scattering dust, which removes scattering dust generated when fuel is transferred and loaded from an open-air storage yard of a thermal power plant, and removes heat of the fuel stacked in or transferred from the open-air storage yard. According to the present invention, the apparatus to remove scattering dust comprises: a sensor unit including a first sensor to detect a weather condition of an open-air storage yard, a second sensor to detect a heating state of fuel stacked in the open-air storage yard or transferred from the open-air storage yard by a conveyor belt, a third sensor to detect the amount of scattering duct in the air of the open-air storage yard, and a fourth sensor to detect operation of the conveyor belt; a spray unit to spray high pressure water in the air of the open-air storage yard, spray the high pressure water to one point of the fuel stacked in the open-air storage yard, or spray the high pressure water to one position of the fuel transferred by the conveyor belt; and a control unit to control operation, and a spray direction and intensity of the spray unit in accordance with a detection result of the sensor unit.

Description

[0001] Apparatus for removing dust scattering [

The present invention relates to a fugitive dust removing device, and more particularly, to a fugitive dust removing device that removes fugitive dust generated during a process of transferring and supercharging fuel at a yard of a thermal power plant, and also removes fugitive dust that removes fuel accumulated in the yard, ≪ / RTI >

Generally, fugitive dust is generated in the process of transferring gemstone, coal, and cement from the loading facility to the loading place, or in the process of crushing or blasting to dismantle buildings such as buildings and bridges.

According to the Air Quality Conservation Act of the Ministry of Environment, fugitive dust is a "dust that is directly discharged into the air without a certain outlet", such as dust dome effect, visible distance deterioration, respiratory disease caused by increase of fine dust concentration, In order to cause harm to the environment, environmental regulations are stipulated by the Ministry of Environment (MOE) No. 500, "Provisions on Disposal of Dust Reduction Measures (Sep. 4, 2001)" have.

In the case of thermal power plants that produce electricity using bituminous coal, there is a lot of scattering dust in the process of transporting bituminous coal from the yard using a conveyor belt or in the process of supercharging bituminous coal on a conveyor belt.

Therefore, the operator directly removes the dusts of the fire or bituminous coal generated during transportation using the vacuum cleaner, or the fresh water is sprayed in order to remove dust generated from the bituminous coal stored in the yard.

The scattered dust of bituminous coal (scattered dust) causes the following problems.

First, it can have a detrimental effect on the health of workers who are engaged in dust removal work as well as field workers who perform other work on the yard.

Second, it can adversely affect the health of the residents and the agricultural and marine products in the surrounding area of the yard, and may also affect soil contamination in the surrounding area.

Third, spontaneous ignition occurs in transfer equipment such as yard or conveyor belt, which causes a large fire.

Fourth, scattered dust accumulates and causes idler failure.

Conventionally, fresh water is sprayed in order to remove scattered dust causing the problems listed above. However, there is a problem that a large amount of waste water is generated due to excessive spraying of fresh water in the process of removing dust by fresh water spray.

In addition, when fresh water is sprayed in winter to remove scattered dust, the spray nozzles are frozen and clogged, and the pipe is frozen and frozen.

It is an object of the present invention to provide a device for more effectively removing scattered dust generated during a process of transferring or burying bituminous coal in a yard in a thermal power plant that generates electric power using bituminous coal There is.

Another object of the present invention is to prevent a wide range of water spraying at random and desalinate to the optimum position according to the weather condition (temperature, humidity, wind velocity, wind direction, etc.) of the field (yard) and the heating condition of the bituminous coal Which is capable of spraying the target.

According to another aspect of the present invention, there is provided an apparatus for removing fugitive dust from a yard, the apparatus comprising: a first sensor for sensing the atmospheric state of the yard in the yard; A second sensor for sensing a heating state of the fuel being conveyed from the yard to the conveyor belt, a third sensor for sensing the amount of scattered dust in the yard, and a fourth sensor for sensing whether the conveyor belt is operating. A sensor unit comprising: Pressure water is sprayed to the atmospheric air of the yard, or the high-pressure water is sprayed to one point on the fuel loaded in the yard, or the fuel sprayed to the conveyor belt Quasi; And a control unit for controlling the injection state of the injection unit, the injection direction and the injection intensity according to the detection result of the sensor unit.

Preferably, the control unit may drive the jetting unit as the scattered dust exceeding a predetermined amount is detected by the third sensor.

Preferably, the first sensor includes a temperature sensor for sensing the atmospheric temperature of the yard, a humidity sensor for sensing the atmospheric humidity of the yard, a weather vane for sensing the wind direction of the yard, An anemometer.

More preferably, the control unit drives the injection unit as the temperature sensed by the temperature sensor and the humidity sensed by the humidity sensor exceed a preset reference value, and when the direction of spraying of the injection unit And the jet intensity of the jet unit can be controlled according to the wind speed sensed by the anemometer.

Preferably, the second sensor may include a thermal sensor that senses a point-by-point temperature using infrared rays on the fuel loaded in the yard and the fuel being conveyed to the conveyor belt in the yard.

More preferably, the control unit compares the spraying direction of the spraying unit with the spraying direction of the spraying unit so as to target spray the high-pressure water to a point where the sensed temperature exceeds the reference temperature by comparing the temperature per spot sensed by the heat- The injection intensity can be controlled.

Preferably, the control unit drives the injection unit according to the detection of the operation of the conveyor belt by the fourth sensor, and increases the injection intensity of the injection unit when the operation of the conveyor belt is sensed.

More preferably, the control unit may drive the injection unit to target the high-pressure water to one point on the fuel being conveyed to the conveyor belt as the operation of the conveyor belt is detected by the fourth sensor.

Preferably, the jetting section includes a plurality of nozzles for jetting the high-pressure water mixed with compressed air, a water valve for supplying water to the plurality of nozzles, and an air valve for supplying compressed air to the plurality of nozzles can do.

More preferably, the controller controls the water valve and the air valve according to the spraying distance of the high-pressure water to adjust the supply ratio of the water and the compressed air, wherein the supply amount of the compressed air is proportional to the spray distance .

More preferably, the control unit controls the water valve and the air valve after the injection of the high-pressure water so that only the compressed air is injected through the plurality of nozzles.

More preferably, the jetting unit has a driving motor for adjusting the injection direction of the high-pressure water, and the driving motor is driven under the control of the control unit so that the spraying angles of the plurality of nozzles can be adjusted.

The present invention has the following effects.

This effectively removes fugitive dust from the fuel (bituminous coal) loaded in the yard and from the yard, so it prevents the harmful effects of the workers in the yard or the people in the surrounding area. And it is possible to prevent damage to agricultural and marine products and soil pollution in the surrounding area.

It is also possible to prevent the occurrence of spontaneous ignition in transport equipment such as yard or conveyor belts through spot injection by point.

In addition, by regularly injecting compressed air after the spraying operation, it is possible to prevent the spraying nozzle and the pipe from being frozen in advance, and the use of fresh water can be remarkably reduced because the high-pressure water mixed with compressed air is finely sprayed.

1 is a block diagram showing the overall configuration of a fugitive dust removing device according to an embodiment of the present invention,
2 is a diagram showing a configuration of a jetting unit in a scattering dust removing apparatus according to an embodiment of the present invention.

Other objects, features and advantages of the present invention will become apparent from the detailed description of the embodiments with reference to the accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a configuration and an operation of an embodiment of the present invention will be described with reference to the accompanying drawings, and the configuration and operation of the present invention shown in and described by the drawings will be described as at least one embodiment, The technical idea of the present invention and its essential structure and action are not limited.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the fugitive dust removing apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram illustrating an overall configuration of a fog-free dust removing apparatus according to an embodiment of the present invention. FIG. 2 is a diagram illustrating a configuration of a fogging unit in a fog-free dust removing apparatus according to an embodiment of the present invention.

1 and 2, the fugitive dust removing apparatus according to the present invention removes fugitive dust generated in the process of transferring and coiling fuel (coal) from a yard of a thermal power plant, and discharges the fuel or conveyor belt And is composed of a sensor unit 100, a jetting unit 200, and a control unit 300. The sensor unit 100 includes a control unit 300,

The sensor unit 100 includes a plurality of sensors. In the present invention, the first to fourth sensors 110, 120, 130 and 140 are provided.

The first sensor 110 is a sensor for sensing the atmospheric state of the atmospheric air in the yard. The first sensor 110 may include a temperature sensor 111, a humidity sensor 112, a weather vane 113, and an anemometer 114. The anemometer 114 senses the atmospheric temperature of the yard, the humidity sensor 112 senses the atmospheric humidity of the yard, the weather vane 113 senses the wind direction of the yard, Lt; / RTI >

The second sensor 120 is a thermal sensor that senses the temperature using infrared rays. The second sensor 120 senses the heating state of the fuel loaded in the yard and senses the heating state of the fuel being conveyed to the conveyor belt in the yard. The second sensor 120 may include one heat sensing sensor. However, the second sensor 120 may include a heat sensing sensor for sensing the heat generation state of the fuel loaded in the yard, and a heat sensing sensor for sensing the heat generation state of the fuel being transferred from the yard to the conveyor belt. May be separately provided.

The second sensor 120 senses the temperature of the spot by using infrared rays for the fuel being loaded in the yard and the fuel being conveyed to the conveyor belt in the yard, periodically discharging the infrared rays to different points, Detect temperature.

The third sensor 130 is a dust sensor, and detects the amount of scattered dust in the atmosphere of the yard.

The fourth sensor 140 is a rotation sensor, and detects whether the conveyor belt is operating.

In order to drive the conveyor belt, a driving pulley for driving the rotation of the conveyor belt and a return idler roller (hereinafter referred to as an idler) for supporting the lower portion of the conveyor belt to prevent sagging of the conveyor belt and a support The fourth sensor 140 senses the rotation of the idler and senses whether the conveyor belt is operating.

In order to remove scattered dust, the jetting section 200 injects high-pressure water into the atmosphere of the yard. When a temperature exceeding the reference is detected by the second sensor 120 at a specific point of the fuel, .

Particularly, the jetting section 200 targets the high pressure water to the point where the high temperature is generated on the fuel loaded in the yard, and targets the high pressure water to the point where the high temperature is generated on the fuel being conveyed by the conveyor belt.

The jetting unit 200 includes a plurality of nozzles 210, a water valve 220 for supplying water to the plurality of nozzles, and an air valve 230 for supplying compressed air to the plurality of nozzles. The plurality of nozzles 210 are piped to the water valve 220 and connected to the air valve 230. The water valve 220 regulates the amount of water supplied from a water tank (not shown), and the air valve 230 regulates the supply of compressed air from a compressor (not shown). The plurality of nozzles 210 inject high pressure water mixed with compressed air supplied from the air valve 230 and water supplied from the water valve 220.

Further, the jetting unit 200 may further include a driving motor 240 for moving the plurality of nozzles 210 up, down, left, and right. The driving motor 240 controls the spraying direction of the high-pressure water. The driving motor 240 is driven under the control of the controller 300 to adjust the spraying angle of the plurality of nozzles.

The control unit 300 predicts the spraying point, the spray direction and the spray intensity according to the detection result of the sensor unit 100, and controls the operation of the spraying unit 200 accordingly. The operation control by the control unit 300 includes injection control for controlling on / off of the spray unit 200, and spray direction control and spray intensity control of the spray unit 200.

The control unit 300 controls the opening and closing of the water valve 220 and the air valve 230 and the supply amount of the water valve 220 according to the spraying distance of the high-pressure water to control the supply ratio of water and compressed air. In particular, the water valve 220 and the air valve 230 can be controlled so that the supply amount of the compressed air is increased in proportion to the spraying distance of the high-pressure water. That is, when the distance (injection distance) to the point where the high-pressure water is injected is long, the supply amount of the compressed air is increased through the air valve 230 so that the high-pressure water can be controlled to be injected at a higher pressure.

The control unit 300 controls opening and closing of the water valve 220 and the air valve 230 and control of the supply amount after the injection of the high pressure water in order to solve the problem of freezing the water of the nozzle or the pipe in winter, Only the compressed air can be controlled to be injected through the nozzles 210. Particularly, when the water valve 220 is closed and only the air valve 230 is opened and only the compressed air is controlled to be sprayed, water is completely removed from the nozzle or the pipe.

The conditions for controlling the operation of the control unit 300 by the operation of the sprayer 200 depend on the detection result of the sensor unit 100 and include a control for removing scattered dust and a control for removing the heat of the fuel at a specific point .

Control for removing scattered dust will be described.

The control unit 300 drives the jetting unit 200 when the third sensor 130 senses the amount of scattered dust in the atmospheric air of the yard. For example, the control unit 300 may drive the jetting unit 200 when the third sensor 130 detects scattered dust exceeding a predetermined amount.

As another example, there is a high likelihood that a large amount of fugitive dust will be generated while the conveyor belt is rotating and transporting the fuel. Therefore, the controller 300 does not drive the jetting unit 200 when the conveyor belt is not driven, and only drives the jetting unit 200 when the conveyor belt is driven by the fourth sensor 140 .

In addition, when a conveyor belt is installed at various points in the yard, rotational sensors are mounted on each conveyor belt. Accordingly, the controller 300 can control the jetting direction and jetting intensity of the jetting unit 200 so that high pressure water is jetted toward the point where the conveyor belt is sensed.

The control unit 300 drives the jetting unit 200 when the third sensor 130 senses that a certain level of scattered dust has been generated or controls the movement of the conveyor belt by the fourth sensor 140 When the conveyance belt is driven by the fourth sensor 140, the jetting intensity of the jetting unit 200 is increased so that the high pressure water is jetted at a higher pressure do.

The control unit 300 controls the driving of the jetting unit 200 according to the detection result by the temperature sensor 111, the humidity sensor 112, the weather vane 113 and the anemometer 114 constituting the first sensor 110 And also controls the injection direction and injection intensity. The control unit 300 drives the jetting unit 200 according to the temperature detected by the temperature sensor 111 and the humidity sensed by the humidity sensor 112 exceeding a preset reference value. The controller 300 controls the jetting direction of the jetting unit 200 according to the wind direction sensed by the weather vane 113 and controls the jetting intensity of the jetting unit 200 according to the wind speed sensed by the anemometer 114 . For example, the control unit 300 may inject the high-pressure water in the direction opposite to the detected wind direction and increase the injection pressure of the high-pressure water proportionally to the sensed wind speed. In other words, if the wind direction is a southeast wind, it is the wind blowing from the southeast, so that the high pressure water is sprayed toward the northwest. In addition, if the air velocity is strong, the injection pressure of the high-pressure water is large, so that the injection pressure of the high-pressure water is increased so that the high-pressure water is sufficiently sprayed to the desired point without being influenced by the wind speed.

The following describes control for removing the heat of the fuel at a specific point.

The control unit 300 compares the temperature sensed by the second sensor 120 with the preset reference temperature by using infrared rays on the fuel being loaded in the yard and the fuel being conveyed to the conveyor belt in the yard. At this time, if the temperature of the specific point detected by the second sensor 120 exceeds the reference temperature, the control unit 300 controls the target injection of the high pressure water to the corresponding point. In particular, the control unit 300 controls the injection direction of the jetting unit 200 so as to face a point exceeding the reference temperature, and at the same time, The intensity can be controlled.

The control unit 300 can drive the jetting unit 200 only when it is sensed that the conveyor belt is driven by the fourth sensor 140 without driving the jetting unit 200 when the conveying belt is not driven have. Therefore, the control unit 300 determines the temperature of the specific point from the result of sensing the operation of the conveyor belt by the fourth sensor 140 and sensing the temperature of each point of the fuel being conveyed to the conveyor belt by the second sensor 120 The injection unit 200 can be controlled to target the high-pressure water to the corresponding point on the fuel being conveyed to the conveyor belt.

As a further example, the fugitive dust removal device according to the present invention may further comprise an IR camera for monitoring a yard and a process of transferring or supercharging the fuel in the yard.

In addition, the apparatus of the present invention performs control for removing scattered dust manually at a remote place and control for eliminating the heat of fuel at a specific point based on the image of the IR camera and the detection result of the sensor unit 100 And may further include a communication unit 400 for communicating with a user terminal (such as a smart phone, a tablet PC, or a personal computer) via an optical communication network and an Internet communication network.

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 embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

It is therefore to be understood that the embodiments of the invention described herein are to be considered in all respects as illustrative and not restrictive, and the scope of the invention is indicated by the appended claims rather than by the foregoing description, Should be interpreted as being included in.

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Claims (12)

An apparatus for removing scattered dust from a yard
A second sensor for sensing the state of the fuel being loaded on the yard and the fuel being transferred to the conveyor belt in the yard, and a second sensor for detecting the state of the fuel being transferred to the conveyor belt, A sensor unit including a third sensor for detecting an amount of the toner and a fourth sensor for detecting whether the conveyor belt is operated;
Pressure water is sprayed to the atmospheric air of the yard, or the high-pressure water is sprayed to one point on the fuel loaded in the yard, or the fuel sprayed to the conveyor belt Quasi; And
And a control unit for controlling the injection state of the injection unit, the injection direction, and the injection intensity according to the detection result of the sensor unit,
The first sensor includes a temperature sensor for sensing the atmospheric temperature of the yard, a humidity sensor for sensing the humidity of the yard in the yard, a weather vane for sensing the wind direction of the yard, and an anemometer for sensing the wind speed of the yard Including,
Wherein the second sensor includes a thermal sensor for sensing a point-by-point temperature using infrared rays on the fuel loaded in the yard and the fuel being conveyed to the conveyor belt in the yard,
Wherein the control unit drives the spray unit as the temperature sensed by the temperature sensor and the humidity sensed by the humidity sensor exceed a predetermined reference value and controls the spray direction of the spray unit according to the direction sensed by the vane, Controls the jetting intensity of the jetting section in accordance with the wind speed sensed by the anemometer,
Wherein the control unit controls the injection direction and the injection intensity of the injection unit so as to target the high pressure water to a point where the sensed temperature exceeds the reference temperature by comparing the temperature detected by the temperature sensor with a preset reference temperature and,
Wherein the control unit drives the jetting unit as the scattered dust exceeding a predetermined amount is detected by the third sensor,
Wherein the controller drives the jetting unit as the operation of the conveyor belt is detected by the fourth sensor. delete delete delete delete delete The method according to claim 1,
Wherein,
And increases the jetting intensity of the jetting portion when the operation of the conveyor belt is sensed. The method according to claim 1,
Wherein,
And drives the injector to target inject the high-pressure water to one point with respect to the fuel being conveyed to the conveyor belt as the operation of the conveyor belt is detected by the fourth sensor. The method according to claim 1,
The injection unit
A water valve for supplying water to said plurality of nozzles; and an air valve for supplying compressed air to said plurality of nozzles, characterized by comprising a plurality of nozzles through which said high-pressure water mixed with compressed air is injected, Dust removal device. 10. The method of claim 9,
Wherein,
And controls the water valve and the air valve in accordance with the spraying distance of the high-pressure water to adjust the supply ratio of the water and the compressed air, so that the supply amount of the compressed air is increased in proportion to the spray distance. A scattering dust removing device. 10. The method of claim 9,
Wherein,
And controls the water valve and the air valve to spray only the compressed air through the plurality of nozzles after the injection of the high-pressure water. 10. The method of claim 9,
The injection unit
Wherein the driving motor is driven under the control of the control unit to adjust the spray angle of the plurality of nozzles in the up, down, left, and right directions.

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