KR102202446B1 - Water injection system using real-time measurement data of dispersing dust causing effect factor - Google Patents

Abstract

An embodiment of the present invention, a meteorological measurement device for measuring meteorological information of a raw material yard; A dust measuring device for measuring the concentration of scattered dust generated in the raw material yard; A moisture measuring device for measuring the surface moisture content of fuel or raw materials loaded in the raw material yard; A process management device that provides information on stacking/dispensing operation time of fuel or raw materials that may generate scattering dust in the raw material yard; A sprinkling device for spraying water toward the raw material yard; And meteorological information measured by the meteorological measuring device, the concentration of scattered dust measured by the dust measuring device, the surface moisture content measured by the moisture measuring device, and the loading/dispensing work time information provided by the process management device. Based on, it provides a sprinkling system including a control device for instructing a sprinkling command to the sprinkling device.

Description

Sprinkling system using real-time measurement data of scattering dust influencing factor {WATER INJECTION SYSTEM USING REAL-TIME MEASUREMENT DATA OF DISPERSING DUST CAUSING EFFECT FACTOR}

The present invention relates to a sprinkling system using real-time measurement data of factors influencing generation of fugitive dust, and more particularly, in which raw materials are piled, loaded, and discharged in a raw material yard during a raw material process that handles a large amount of raw materials such as steel, cement, and coal power plants. The generation of dust scattering in raw material yards is detected using data measured in real time, including the wind speed, wind direction, rainfall, moisture content of the raw material pile, and dust concentration at the boundary of the raw material yard that can cause scattered dust in the process. It relates to a sprinkling system for reducing the probability of occurrence of scattered dust by predicting and sprinkling in advance.

In the steel industry, cement industry, power generation industry, etc., a large amount of fuel and raw materials are used due to the nature of the process. These fuels and raw materials go through several processes and are transferred to the final consumer. Among these processes, important processes are the unloading process in which fuel and raw materials are unloaded from transportation means such as ships, the transfer process in which unloaded fuel mill raw materials are to be stored (eg, raw material yard), and transport There are a stacking process in which the equipment is piled into a storage yard, a storage process in which raw materials are stored in a pile form, and a dispensing process for transferring the raw materials stored in a pile form to a factory.

Among them, in the stacking process, the yard process, and the dispensing process performed in the yard, since fuel and raw materials are left outdoors for a long time, scattering dust may be continuously generated by the wind. Therefore, in order to minimize the generation of dust scattered by wind in the stacking process, the stacking process and the dispensing process, first, the wind speed reaching the fuel or raw material surface of the stacked pile must be minimized. Next, it is necessary to increase the bonding force between the fuel or raw material particles placed in the pile. To reduce wind speed, windshields, windshields, windbreaks, etc. are mainly used, and to increase the bonding strength of fuel or raw materials, simply use water or various chemical substances such as surfactants, polymers, and resins.

On the other hand, in relation to the generation of scattered dust from raw material yards, the scattering dust emission coefficient (E) of 10 μm or less suggested by the US Environmental Protection Agency is shown in Equation 1 and Equation 2, respectively.

[Equation 1]

[Equation 2]

Here, M is the moisture content (%) of the raw material, k is a correction factor of 0.5, U _* is the friction flow rate (m/s), and U _* ^t is the dark friction flow rate (m/s).

Equation 1 corresponds to the emission factor of the generation of fugitive dust generated in the process of loading and dispensing raw materials or fuels in the stacking process, and Equation 2 is the emission factor of the generation of fugitive dust generated by wind from piles of fuel or raw materials. Corresponds to the emission factor. In order to minimize the generation of scattered dust in the field process, the amount of moisture contained in the fuel or raw material must be high according to Equation 1, and according to Equation 2, the difference between the friction flow rate and the critical friction flow rate is minimized, or the friction flow rate is the critical friction flow rate. Should be smaller than At this time, the frictional flow velocity represents a flow velocity reduced by the frictional force with the ground surface, and the critical frictional flow velocity is a flow velocity at which a specific raw material can be scattered and varies depending on the type and state of the raw material.

According to the above equations, in order to reduce wind speed, it is necessary to increase the moisture content of the raw material, reduce the frictional flow rate, or increase the critical frictional flow rate.

As described above, in order to increase the moisture content of the raw material, a method such as sprinkling is used, and in order to reduce the frictional flow rate, a method of reducing wind speed by using a windbreak wall, a windbreak net, and a windbreak is used. To increase the flow rate, water, surfactants, polymers, resins, etc. are used to increase the bonding strength between raw materials.

Currently, the most commonly used methods for reducing fugitive dust are windshields, sprinkling, and scattering inhibitors such as chemicals. However, the windshield is effective only for a certain distance in a large raw material yard, and the sprinkling method has the disadvantage of increasing the energy cost in the production facility by increasing the moisture content of the raw material, and the scattering inhibitors such as chemicals can deteriorate the water quality. It causes secondary pollution. Recently, scattering dust is fundamentally blocked using a method of stacking the raw materials in a completely sealed structure, but there is a disadvantage in that an astronomical cost is required.

In the case of raw material yards having a very large area, such as in the steel industry, most of them adopt and use a method of reducing scattered dust using sprinkling water along with a method of reducing the frictional flow velocity of windshields, windshields, and windbreaks. Windshields, windshields, and windbreaks to reduce the frictional flow rate cannot be changed according to weather conditions once they are installed. Therefore, to prevent scattering dust due to weather changes, it is possible to reduce the generation of scattered dust by changing the sprinkling method and sprinkling timing. Efficiency can be improved.

When the wind exceeding the critical friction flow rate blows, dust floats from the surface of the pile at a time and scattered dust is generated. Therefore, the water content of the pile surface is increased through spraying beforehand, thereby increasing the critical friction flow rate. However, since the surface of the pile pile is easily dried, periodic watering is required, which continuously increases the moisture content of the raw material inside the raw material pile, which does not evaporate, causing an increase in energy costs in the production plant using the raw material.

Currently, in order to manage dust scattering from raw material yards using sprinkling, periodic sprinkling is performed regardless of weather, and aperiodic sprinkling is performed only when a phenomenon of deteriorating visibility distance is observed with the naked eye.

Registered Patent No. 10-1247181 (2013.03.19) Unexamined Patent Publication No. 10-2012-0132201 (2012.12.05)

Accordingly, an object of the present invention is to provide a sprinkling system that performs sprinkling based on a factor influencing generation of scattered dust measured in real time in order to solve the above problems.

According to an embodiment of the present invention, a meteorological measurement device for measuring meteorological information of a raw material yard; A dust measuring device for measuring the concentration of scattered dust generated in the raw material yard; A moisture measuring device for measuring the surface moisture content of fuel or raw materials loaded in the raw material yard; A process management device that provides information on stacking/dispensing operation time of fuel or raw materials that may generate scattering dust in the raw material yard; A sprinkling device for spraying water toward the raw material yard; And meteorological information measured by the meteorological measuring device, the concentration of scattered dust measured by the dust measuring device, the surface moisture content measured by the moisture measuring device, and the loading/dispensing work time information provided by the process management device. Based on, it provides a sprinkling system including a control device for instructing a sprinkling command to the sprinkling device.

In one embodiment, the meteorological measurement device may be installed at a location separated by a predetermined distance from the boundary of the raw material yard.

In one embodiment, the sprinkling device may be installed at a position higher than the height of the raw material or fuel loaded in the raw material yard.

In one embodiment, the sprinkler may generate dry fog that is longer than the length of the pile of fuel or raw materials loaded in the raw material yard in a windless state.

In one embodiment, the control device may perform spraying when a signal indicating the start of a stacking or dispensing operation of fuel or raw materials is input to the process management device.

In one embodiment, the control device may perform watering when data indicating that there is no rainfall is input from the meteorological measurement device.

In an embodiment, the control device may perform spraying when the concentration of scattered dust measured by the dust measuring device exceeds a reference value.

In one embodiment, the control device may perform spraying when the wind speed measured by the meteorological measurement device exceeds the critical friction speed of the fuel or the raw material in the raw material yard.

In an embodiment, the control device may perform spraying when the surface moisture content measured by the raw material moisture measurement device is less than a reference value.

In an embodiment, a plurality of sprinkling devices are installed for each direction around the raw material yard, and the control device may perform watering from a sprinkling device corresponding to a wind direction measured by a meteorological measurement device among the plurality of sprinkling devices.

In an embodiment, the control device may perform spraying from two or more of the plurality of sprinkling devices in response to the wind direction measured by the meteorological measurement device.

In addition, the summary of the invention described above does not enumerate all of the features of the invention. In addition, sub-combinations of these feature groups can also be invented.

According to an embodiment of the present invention, in order to reduce dust scattered and discharged in the process of piling, dispensing, and stacking fuel raw materials in a raw material yard, the effect of generating scattered dust such as wind speed, wind direction, rainfall, raw material moisture content, dust concentration, etc. measured in real time By sprinkling in conjunction with a factor, it is possible to improve the efficiency of reducing scattered dust compared to a method of sprinkling irrespective of weather conditions or relying on a worker's visual observation.

1 shows an exemplary schematic diagram of a watering system according to an embodiment of the present invention.
2 shows an exemplary block diagram of a watering system according to an embodiment of the present invention.

Hereinafter, a watering system according to an embodiment of the present invention will be described in detail with reference to the drawings.

1 is an exemplary schematic diagram of a watering system 100 according to an embodiment of the present invention. As shown in the drawing, the sprinkling system 100 according to an embodiment of the present invention includes a vapor phase measuring device 110, a dust measuring device 120, a moisture measuring device 130, and a process management device ( 140), a sprinkling device 150, and a control device 160.

The above-described various devices included in the sprinkling system 100 operate as follows.

First, the meteorological measurement device 110 measures meteorological information of the raw material yard (A). The meteorological information measures weather-related information related to the raw material yard A, such as wind speed, wind direction, rainfall, relative humidity, and insolation. The meteorological measurement device 110 may be installed at a location separated by a predetermined distance from the boundary of the raw material yard (A). For example, the meteorological measurement device 110 may be installed at, for example, 300m or more away from the boundary of the raw material yard (A). In addition, the meteorological measurement device 110 acquires meteorological information at predetermined intervals (eg, 10 seconds) and transmits it to the control device 150. On the other hand, the meteorological measurement device 110 is installed around the raw material yard (A) for each direction, it is possible to measure the meteorological information at the respective installation location.

Next, the dust measuring device 120 measures the concentration of scattered dust generated in the raw material yard (A). The dust measuring device 120 measures the concentration of scattered dust at every preset interval (eg, 1 minute), and transmits it to the control device 150. In addition, a plurality of dust measuring devices 120 are installed for each orientation around the raw material yard A, similar to the meteorological measuring device 110, so that the amount of dust scattered at the corresponding installation location can be measured.

Next, the moisture measurement device 130 measures the surface moisture content of fuel or raw materials loaded in the raw material yard (A). The moisture measurement device 130 measures the surface moisture content at predetermined intervals (eg, 1 minute) and transmits the measured surface moisture content to the control device 150.

On the other hand, the process management device 140 provides the control device 160 with information on the stacking/dispensing operation time of fuel or raw materials that may generate scattering dust in the raw material yard (A). For example, the piling/dispensing work time information may be provided based on an input for the start or end of the piling/dispensing operation by an operator performing the piling/dispensing operation.

In addition, the watering device 150 is installed around the raw material yard (A) to perform watering toward the raw material yard (A). For example, the sprinkling device 150 may generate dry fog toward the raw material yard A. Similar to the meteorological measuring device 110, a plurality of sprinkling devices 150 are installed for each orientation around the raw material yard A, so that water can be sprayed toward the raw material yard A at the corresponding installation position.

On the other hand, it is preferable that the sprinkler 150 is installed at a position higher than the height of the fuel or raw material pile loaded in the raw material yard (A). In addition, the sprinkling device 150 has a sprinkling distance longer than the length of the fuel or raw material piles loaded in the raw material yard A in a windless state. For example, when the length of the fuel or raw material pile is 250M, the sprinkling distance of the sprinkler 150 may have a performance of 250M or more when there is no wind, and when the height of the fuel or raw material pile is 10M, the sprinkling device 150 The height can be 10M or more.

The control device 160 may perform watering so that the sprinkling device 150 sprays the raw material yard A toward the raw material yard A under predetermined conditions. For example, the control device 160 includes meteorological information measured by the meteorological measurement device 110, the concentration of scattered dust measured by the dust measurement device 120, and the moisture measurement device 130 A sprinkling command may be instructed to the sprinkling device 150 based on the obtained surface moisture content and information on the placement/dispensing operation time provided from the process management device 140.

For example, referring to an exemplary block diagram of a sprinkling system according to an embodiment of the present invention shown in FIG. 2, the control device 160 includes wind direction, wind speed, rainfall, relative humidity from the meteorological measurement device 110, Weather information such as solar radiation is provided, scattered dust concentration is provided from the dust measuring device 120, surface moisture content is provided from the moisture measuring device 130, and piled/dispensed operation time information from the process management device 140 After receiving and determining whether to sprinkle based on this information, a sprinkling command may be instructed to the sprinkling device 150.

Examples of specific conditions in which the control device 160 determines whether to spray water are as follows.

First, the control device 160 may perform spraying when a signal indicating the start of a loading or dispensing operation of fuel or raw materials is input from the process management device 120. When the stacking or dispensing of fuel or raw materials is being carried out in the raw material yard (A), since more scattering dust is generated than in other cases, watering can be performed in this case.

On the other hand, in the present specification, sprinkling does not mean that the sprinkling device 150 must sprinkle toward the raw material yard (A), and it is possible to spray water toward the raw material yard (A) in consideration of various factors. It should be interpreted to include being in a state of being. That is, when a signal indicating the start of loading or dispensing of fuel or raw materials is input from the process management device 120, it is not necessarily sprinkling, but even in this state, sprinkling is performed under certain conditions and under any other conditions. This may include the case of not sprinkling.

Next, the control device 160 may perform watering when data indicating that there is no rainfall is input from the meteorological measurement device 110. For example, if there is no rainfall when the fuel or raw material is stacked or dispensed as described above, watering may be performed. In addition, as will be described later, even when the fuel or raw material is not piled up or dispensed, spraying can be performed when there is no rainfall when the concentration of scattering dust exceeds a reference value.

Conversely, the control device 160 may not perform sprinkling when data indicating that there is rainfall is input from the meteorological measurement device 110. In addition, in an embodiment, the control device 160 may perform sprinkling when data indicating that there is a rainfall exceeding a reference value is input from the meteorological measurement device 110. Therefore, when there is sufficient precipitation, the generation of scattering dust can be suppressed by rain, so there is no need for watering, and thus, the watering cost can be reduced.

Next, the control device 160 may perform spraying when the concentration of the scattered dust measured by the dust measuring device 120 exceeds the reference value. For example, when the stacking or dispensing of fuel or raw materials is not performed, if the concentration of scattered dust in the raw material yard is high due to various factors, watering may be performed to suppress this.

Next, the control device 160 may perform spraying when the wind speed measured by the meteorological measurement device 110 exceeds the critical friction speed of the fuel or the raw material in the raw material yard. As mentioned above, the critical friction speed is the speed at which a particular raw material can be scattered. If the wind speed is higher than this critical frictional speed, the possibility of flying dust is high. Thus, for example, even when the fuel or raw material is not stacked or dispensed, when the wind speed is higher than this critical friction speed, sprinkling can be performed to suppress the generation of scattered dust.

In addition, when the surface moisture content measured by the moisture measuring device 140 is less than a reference value, the control device 160 may perform watering. As described above, when the surface moisture content of the fuel or raw material is low, the possibility of scattering is high. Therefore, for example, even when the fuel or raw material is not stacked or dispensed, when the surface moisture content is less than the reference value, sprinkling may be performed to suppress the generation of scattered dust. In addition, in one embodiment, the control device 160, when not performing the stacking or dispensing of fuel or raw material, the wind speed measured by the meteorological measurement device 110 is the critical friction speed of the fuel or raw material in the raw material yard. When it exceeds, when the surface moisture content is less than the reference value, sprinkling may be performed to suppress the generation of scattered dust.

In this way, it is possible to perform spraying by measuring and using weather information, work information, scattered dust concentration information, moisture content information, etc. in real time, so that the generation of scattered dust can be suppressed by adaptively responding to variable conditions. .

Meanwhile, as described above, a plurality of sprinkling devices 150 may be installed for each orientation around the raw material yard, and the control device 160 may include a wind direction measured by the meteorological measurement device 110 among the plurality of sprinkling devices 150. Watering can be performed from the watering device 150 corresponding to. For example, as shown in Fig. 1, if the sprinkling device 150 is installed at four points on the top, bottom, left, and right of the raw material yard (A) (for convenience, it is assumed that the top, bottom, left, and right correspond to the north-southwest direction in the drawing. If the north wind is detected, the sprinkling device 150-#1 disposed above waters toward the raw material yard (A), and when the south wind is detected, the sprinkling device 150-# disposed below 2) Spray it toward the raw material yard (A).

In addition, the control device 160 may spray water from two or more sprinkling devices 160 of the plurality of sprinkling devices 140 in response to the wind direction measured by the meteorological measurement device 110. For example, referring to FIG. 1, when a northeast wind is detected, a sprinkling device 150-#1 disposed above and a sprinkling device 150-#$ disposed on the right sprinkle toward the raw material yard (A). And, when the southwest wind is detected, the watering device 140-#2 disposed below and the watering device 150-#3 disposed on the left spray toward the raw material yard (A).

Accordingly, a suitable sprinkling device 150 among a plurality of suitable sprinkling devices 150 performs sprinkling according to the wind direction so that the sprinkling liquid is directed only to the raw material yard A, thereby reducing sprinkling cost.

As described above, the present invention has been described using examples, but the technical scope of the present invention is not limited to the range described in the above examples. It is clear to those skilled in the art that various changes or improvements can be added to the above embodiments. It is clear from the description of the claims that a form to which such changes or improvements are added may also be included in the technical scope of the present invention.

100: watering system
110: meteorological measurement device
120: dust measuring device
130: moisture measurement device
140: process control device
150: sprinkler
160: control device

Claims (11)

A meteorological measurement device for measuring meteorological information of the raw material yard;
A dust measuring device for measuring the concentration of scattered dust generated in the raw material yard;
A moisture measuring device for measuring the surface moisture content of the fuel or raw materials loaded in the raw material yard;
A process management device that provides information on a stacking/dispensing operation time of fuel or raw materials that may generate scattering dust in the raw material yard;
A sprinkling device for spraying water toward the raw material yard; And
The meteorological information measured by the meteorological measurement device, the generation amount of scattered dust measured by the dust measuring device, the surface moisture content measured by the moisture measuring device, and stacking/dispensing provided by the process management device Control device for instructing a sprinkling command to the sprinkling device based on work time information
Including,
The sprinkling device generates dry fog in which a sprinkling distance in a windless state is longer than a length of a pile of fuel or raw materials loaded in the raw material yard,
The control device, when the wind speed measured by the meteorological measurement device exceeds the critical friction speed of the fuel or the raw material of the raw material yard, to perform watering,
Watering system. The method of claim 1,
The meteorological measurement device is installed at a position separated by a predetermined distance from the boundary of the raw material yard,
Watering system. The method of claim 1,
The sprinkling device is installed at a position higher than the height of the raw material or fuel loaded in the raw material yard,
Watering system. delete The method of claim 1,
The control device performs sprinkling when a signal indicating the start of loading or dispensing of fuel or raw materials is input to the process management device,
Watering system. The method of claim 1,
The control device performs watering when data indicating that there is no rainfall is input from the meteorological measurement device,
Watering system. The method of claim 1,
The control device, when the concentration of the scattered dust measured by the dust measuring device exceeds a reference value, performs watering,
Watering system. delete The method of claim 1,
The control device, when the surface moisture content measured by the moisture measuring device is less than a reference value, to perform watering,
Watering system. The method of claim 1,
The sprinkling device is installed in plurality for each direction around the raw material yard,
The control device is configured to spray water from a sprinkling device corresponding to a wind direction measured by the meteorological measurement device among the plurality of sprinkling devices,
Watering system. The method of claim 10,
The control device is configured to spray water from two or more sprinkling devices among the plurality of sprinkling devices in response to the wind direction measured by the meteorological measurement device,
Watering system.

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