KR102515210B1 - Scattering Dust Automatic Removal System - Google Patents

Abstract

The present invention relates to an automatic scattering dust removal system. The automatic scattering dust removal system comprises: a raw water tank part; a pump part; a high pressure gas supply part; a spray drain discharge part; an automatic control part; and a terminal part. Therefore, the present invention effectively removes scattering dust while using less water and has high efficiency against scattering dust.

Description

Scattering Dust Automatic Removal System}

The present invention relates to a watering facility capable of effectively suppressing or reducing and removing scattering dust.

Stone crushing facilities are installed at road construction sites, stone mines, aggregate yard, and building waste yard. Stone crushing equipment generates a lot of dust when producing aggregates or sand. The generated dust is scattered and deteriorates the health of workers and nearby residents.

Accordingly, in many workplaces, as shown in FIG. 1 , facilities capable of suppressing, reducing or removing scattering dust are installed. At this time, many dust reduction facilities having a structure in which water flows through a hole in a pipe are installed in a stone mine, a waste treatment workplace, and the like. However, such a dust reduction facility has a problem in that the area where water meets dust is small and the amount of dust removed is small compared to the amount of water used, resulting in poor effectiveness. In addition, the dust reduction facility has a problem in that the hose (piping) freezes due to the temperature drop in winter and cannot spray water. Therefore, in order to prevent freezing in the winter, it is designed with a structure to prevent freezing by installing a heating wire through which electricity flows throughout the hose (piping). there is a problem.

Republic of Korea Patent No. 10-2041945 (Announcement date: 2019.11.07)

The present invention solves the problem of the existing scattering dust removal device, that is, the amount of dust removal is small compared to the amount of water used, and the efficiency is poor. We want to solve the problem of unknown whether or not, the problem of freezing of pipes in winter, and the complicated construction of structural changes to solve these problems.

The problem to be solved by the present invention is not limited to the problem to be solved mentioned above, and other problems not mentioned above will be clearly understood by those skilled in the art from the description below.

The automatic scattering dust removal system of one embodiment of the present invention for achieving the above object to be solved includes a container module for storing water therein and a water tank valve connected to the container module to control the discharge of the water stored in the container module. A raw water tank unit including a water tank unit, a pump unit that is connected to the water tank valve on one side and sucks water in the container module and discharges it to the other side, a compressor module that compresses and discharges gas, and gas control that controls the output of the gas output from the compressor module. A high-pressure gas supply unit including a valve, a distribution pipe module receiving either gas from the high-pressure gas supply unit or water supplied from the pump unit, a drain valve module disposed at one end of the distribution pipe module, and a distribution pipe module at regular intervals A water spray drain discharge unit including a plurality of water spray valve modules spaced apart from each other, a gas control valve, one drain valve module, and data communication with a plurality of water spray valve modules, and sending an open or closed signal to the gas control valve and one drain valve When an open signal is generated that is applied to the module and a communication module transmitted to a plurality of water spray valve modules, a gas control valve, a drain valve module, and a plurality of water spray valve modules, and an open signal is applied to the gas control valve and drain valve module , A control signal capable of generating a closing signal applied to a plurality of water spray valve modules, and capable of generating a closing signal applied to the drain valve module when an open signal is applied to the gas control valve and any one water spray valve module It includes an automatic control unit including an output module and a terminal unit that communicates with the communication module, transmits and receives data, and manages the generation and output of an open signal or a closed signal output from the control signal output module.

In addition, the automatic scattering dust removal system may further include a filter unit that is located between the pump unit and the water spray drain discharge unit to filter water discharged from the pump unit and then supplies the water to the water spray drain discharge unit. Here, the drain valve module includes a drain valve that is opened when an open signal is applied and closed when a close signal is applied, and a sensor for measuring at least one of state information of the valve, pressure or flow rate or flow rate of the fluid,

The plurality of water spray valve modules may include a water spray valve that is opened when an open signal is applied and closed when a close signal is applied, and a sensor that measures at least one of state information of the valve and pressure or flow rate or flow rate of the fluid.

The control signal output module may be connected to the pump unit and the high-pressure gas supply unit to apply an operation signal to the pump unit and the high-pressure gas supply unit.

The control signal output module may apply an open signal or a close signal to the plurality of water spray valve modules.

The control signal output module opens the drain valve for a second set time when the pump stops after operating for a first set time, operates the compressor module, closes the drain valve when the second set time has elapsed, and then closes the drain valve. The water spray valve may be sequentially opened for a third set time and then closed.

The plurality of sprinkling valve modules include first to seventh sprinkling valves, and the first to seventh sprinkling valves include a circular nozzle having a spray hole having a diameter of 0.1 mm to 3.0 mm and a plurality of nozzles It can be connected to the nozzle module. In addition, the automatic control unit may further include an input and display panel module connected to the control signal output module to generate an open signal and a close signal in a touch manner, and a communication module for transmitting and receiving data to and from a remote server.

In addition, the meter is from the drain sensor for measuring at least one of the valve state information of the drain valve, the pressure or flow rate or flow rate of the fluid, and the valve state information of the water spray valve, the water spray sensor for measuring at least one of the pressure or flow rate or flow rate of the fluid It includes an integrated module in which a sensor data receiving module receiving data, a data collector, and a gateway are integrated.

The present invention effectively removes scattering dust while using less water, and has high efficiency against scattering dust. In addition, compressed air is sprayed on the pipeline through which the water is discharged to accurately remove the water remaining in the pipeline to prevent the pipeline from freezing in winter. Moreover, since no electric wire is disposed near the discharge of water, no leakage accident occurs during thawing, so the safety of use is high. Further, in the present invention, when the water sprinkling operation and the residual water discharging operation cannot be performed on site, the sprinkling operation and the residual water discharging operation can be performed through a remote control.

1 is a view showing an automatic scattering dust removal facility installed in a workplace where scattering dust is generated.
2 is a schematic diagram of an automatic scattering dust removal system according to an embodiment of the present invention.
Figure 3 is an actual picture of the automatic scattering dust removal system according to an embodiment of the present invention.
4 is an actual picture of an automatic control unit according to an embodiment of the present invention.
5 is a view showing a water spray drain discharge unit according to an embodiment of the present invention.
6 is a view showing the structure of a drain valve module and a first water spray valve module to a sixth water spray valve module according to an embodiment of the present invention.
7 to 9 are views showing nozzles connected to the first to sixth spray valves according to an embodiment of the present invention.
10 is a diagram showing an automatic control unit according to an embodiment of the present invention.
11 is a view showing a structure in which a measurement unit for sensor signal measurement and communication of an automatic control panel, a data collector, and a gateway are separated, and an integral structure in which a measurement unit, a data collector, and a gateway are configured as one.
12 is a diagram showing a structure in which a measurement unit for measuring an output signal of whether an automatic valve is opened or closed, a data collector, and a gateway are separated, and an integral structure in which a measurement unit, a data collector, and a gateway are configured as one.
13 is a view showing a structure in which a measurement unit for measuring a signal of a sensor installed at a rear end of a valve, a data collector, and a gateway are separated, and an integral structure in which a measurement unit, a data collector, and a gateway are configured as one.
14 is a diagram showing a state in which the automatic scattering dust removal system according to an embodiment of the present invention is operated in a watering mode.
15 and 16 are diagrams showing a process in which components constituting the automatic scattering dust removal system according to an embodiment of the present invention are operated in a watering mode.
17 is a view showing a state in which the automatic scattering dust removal system according to an embodiment of the present invention is operated in the residual water removal mode.
18 is a diagram showing a sequence in which components constituting the automatic scattering dust removal system according to an embodiment of the present invention are operated in a residual water removal mode.
19 to 23 are diagrams showing states in which the automatic scattering dust removal system according to an embodiment of the present invention is operated in a sprinkling mode and a residual water removal mode.

Advantages and features of the present invention and a system for achieving them will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various forms and structures. The embodiments disclosed below are only provided to complete the disclosure of the present invention and to completely inform those skilled in the art of the scope of the invention to which the present invention belongs.

The contents and drawings described in this specification are only provided to help those skilled in the art to fully understand the scope of the present invention, and the scope of the present invention is not defined in the described contents and drawings. The scope of the present invention can only be defined by the claims.

Hereinafter, an automatic scattering dust removal system according to an embodiment of the present invention will be described in detail with reference to FIGS. 2 to 23 of the following embodiment of the present invention.

However, in order to make the description of the present invention concise and clear, the automatic scattering dust removal system according to an embodiment of the present invention is first briefly described with reference to FIG. 2, and then the present invention with reference to the description and the remaining drawings The components and operation of are described in detail.

2 is a schematic diagram of an automatic scattering dust removal system according to an embodiment of the present invention.

The automatic scattering dust removal system 1 of the present invention effectively removes scattering dust while using less water. Accordingly, the present invention exhibits high efficiency in removing scattering dust. In particular, the automatic scattering dust removal system 1 of the present invention can remove scattered dust by operating the sprinkling operation and discharging residual water through a remote control even when the operation of spraying and discharging residual water cannot be performed on site. At this time, the present invention injects compressed air into the pipe through which the water is discharged to quickly and accurately remove the water remaining in the pipe and prevent the pipe from freezing in winter.

As such, the automatic scattering dust removal system 1 removes water remaining in the conduit by wind without arranging a hot wire in the conduit, thereby preventing a leakage accident caused by leakage current generated from the conduit.

The automatic scattering dust removal system 1 having such characteristics includes a raw water tank unit 10, a pump unit 20, a high-pressure gas supply unit 30, a sprinkling drain discharge unit 40, an automatic control unit 50, and a terminal unit ( 60) as a component.

Hereinafter, components constituting the automatic scattering dust removal system 1 will be described in detail with reference to FIGS. 2 to 13 .

2 is a schematic diagram of an automatic scattering dust removal system according to an embodiment of the present invention, and FIG. 3 is an actual picture of the automatic scattering dust removal system according to an embodiment of the present invention. 4 is an actual picture of an automatic control unit according to an embodiment of the present invention, and FIG. 5 is a view showing a water spray drain discharge unit according to an embodiment of the present invention. 6 is a view showing the structure of a drain valve module and a first water spray valve module to a sixth water spray valve module according to an embodiment of the present invention. 7 to 9 are views showing nozzles connected to the first to sixth spray valves according to an embodiment of the present invention, and FIG. 10 is a view showing an automatic control unit according to an embodiment of the present invention. 11 is a view showing a structure in which a measurement unit for sensor signal measurement and communication of an automatic control panel, a data collector, and a gateway are separated, and an integral structure in which a measurement unit, a data collector, and a gateway are configured as one. 12 is a view showing a structure in which a measurement unit, a data collector, and a gateway are separated for measuring an output signal of whether an automatic valve is opened or closed, and an integral structure in which the measurement unit, the data collector, and the gateway are configured as one unit, and FIG. 13 is installed at the rear end of the valve This is a diagram showing a structure in which the measurement unit, data collector and gateway for measuring the signal of the sensor are separated, and an integrated structure consisting of the measurement unit, data collector and gateway as one.

The raw water tank unit 10 includes the container module 110 and the water tank valve 120, selectively controls the water stored in the container module 110 through the water tank valve 120, and supplies it to the pump unit 20. . Here, the container module 110 becomes a container for storing water therein. The container module 110 stores water sprayed to remove dust scattered in various workplaces, such as a quarry stone crushing workplace and a waste treatment workplace.

The container module 110 may be formed in a cylindrical shape as shown in FIG. 3 . However, the container module 110 is not limited to a cylindrical shape and may be formed in various shapes having an accommodation space therein.

The water tank valve 120 is connected to one side of the container module 110 . The water tank valve 120 is a valve that controls the discharge of water stored in the container module 110 . The water tank valve 120 is connected to the automatic control unit 50 and operates according to an operation signal transmitted from the automatic control unit 50, that is, an open signal or a close signal, and controls the flow of water stored in the container module 110. can do. The water tank valve 120 having these characteristics may be formed as a solenoid valve or an electronic (electric) valve that opens and closes according to an applied signal.

The pump unit 20 has one side connected to the water tank valve 120 through a pipe, sucks water in the container module 110, that is, water discharged through the water tank valve 120, and discharges it to the other side. At this time, the pump unit 20 supplies the sucked water to the water spray drain discharge unit 40 at high pressure.

The pump unit 20 pressurizes and discharges water through the water spray drain discharge unit 40 so that water can be sprayed like mist. The pump unit 20 may be a pump for pressurization such that the water pressure (water pressure) is 5 kg/cm ² or more.

The water spray drain discharge unit 40 is connected to the pump unit 20 and the high-pressure gas supply unit 30 to receive and spray water and air. The water spray drain discharge unit 40 will be described in detail after the high-pressure gas supply unit 30 is described.

The high-pressure gas supply unit 30 includes a compressor module 310 and a gas control valve 320. Here, the compressor module 310 compresses the gas and discharges it as a high-pressure gas. The gas control valve 320 is connected to the compressor module 310 and becomes a valve that controls the flow of high-pressure gas discharged from the compressor module 310 . Such a gas control valve 320 may be connected to the automatic control unit 50 and operated according to an operation signal transmitted from the automatic control unit 50, that is, an open signal or a close signal. The gas control valve 320 having these characteristics may be formed as a solenoid valve or an electronic (electric) valve that opens and closes according to an applied signal.

The water spray drain discharge unit 40 receives water from the pump unit 20, divides the water into several places, receives high-pressure gas from the high-pressure gas supply unit 30, and removes the water remaining in the various pipes that have been sprayed. As shown in FIG. 5, the water spray drain discharge unit 40 includes a distribution pipe module 410, a liquid delivery pipe 411 extending from the distribution pipe module 410, and a gas delivery pipe extending from the distribution pipe module 410. 412, and a drain discharge pipe 413 formed on one side of the distribution pipe module 410, and a first watering pipe 414, a second watering pipe 415, a third watering pipe 416, and a fourth watering pipe 417, a fifth water supply pipe 418 and a sixth water supply pipe 419. Here, the liquid transfer pipe 411 is connected to a pump that supplies water, that is, the pump unit 20 or the filter unit 70, and becomes a conduit for water transferred from the pump unit 20 or the filter unit 70. Also, the gas transfer pipe 412 is connected to the compressor module 310 and becomes a conduit through which the high-pressure gas discharged from the compressor module 310 is transported.

The distribution pipe module 410 communicates with the liquid conveying pipe 411 and the gas conveying pipe 412, so that the fluid transferred from the liquid conveying pipe 411 and the gas conveying pipe 412 branches into a plurality of water spray pipes and drain ejection pipes 413. It becomes a pipe that allows you to go out. In addition, the drain valve module 4200 installed on the drain discharge pipe 413, the first spray valve module 4201 installed on the first spray pipe 414, and the second spray valve module installed on the second spray pipe 415 ( 4202), the third spray valve module 4203 installed on the third spray pipe 416, the fourth spray valve module 4204 installed on the fourth spray pipe 417, and the fifth spray valve module 4204 installed on the fifth spray pipe 418 A water spray valve module 4205 and a sixth water spray valve module 4206 installed in the sixth water spray pipe 419 are included. And it includes a nozzle connected to each water spray valve module. Here, the drain valve module 4200 and the first water spray valve module 4201 to the sixth water spray valve module 4206, as shown in FIG. 5, are valves that control fluid flow and valve state information, fluid pressure, fluid It includes a sensor that measures the speed and flow rate of As an example, the drain valve module 4200 includes a drain valve 42010 that opens when an open signal is applied and closes when a close signal is applied, and a drain sensor for measuring at least one of valve status information, pressure or flow rate or flow rate of a fluid ( 42020). And the plurality of water spray valve modules 4201 to 4206, that is, the first water spray valve module 4201 to the sixth water spray valve module 4206 are water spray valves 42021 that open when an open signal is applied and close when a close signal is applied. ~ 42026) and valve state information including water spray sensors (42021 to 42026) that measure at least one of the pressure, flow rate, or flow rate of the fluid. Here, the water spray sensors 42021 to 42026 are connected to a measuring instrument 501 and a data collector and gateway 502 to be described later, and transmit operational state data. In addition, the spray nozzle 430 is a circular nozzle 430a having a hole having a diameter of 0.1 mm to 3.0 mm as shown in FIG. 5 or a nozzle module including a plurality of nozzles as shown in FIGS. 6 and 7 (430b). Such a nozzle and nozzle module enable water particles to be removed from scattered dust without being blown away by external wind. In addition, the water spray drain discharge unit 40 can remove residual water from several pipes that have been sprayed with water supplied from the high-pressure gas supply unit 30 . A filter unit 70 is installed between the water spray drain discharge unit 40 and the pump unit 40 to filter foreign substances in the water discharged from the pump unit 20, and then to the water spray drain discharge unit 40 to clean water. make this supply. Through this, the sprinkler drain discharge unit 40 divides the water supplied from the pump unit 20 through the second sprinkler pipe 414 to the seventh sprinkler pipe 417 so that water can be sprayed.

The automatic control unit 50 transmits an operation signal to the pump unit 20, the high-pressure gas supply unit 30, and the water spray drain discharge unit 40, and communicates data with the terminal unit 60. Such an automatic control unit 50 may be formed as shown in FIG. 4 . The automatic control unit 50 may have a case and a plurality of devices installed inside the case. At this time, the case may include a door and the door may be opened and closed. The closing of the door prevents dust and foreign matter from contaminating a plurality of devices installed inside the case.

As shown in FIG. 10 , such an automatic controller 50 may be a computer including a communication module 510, a control signal output module 520, and a display panel module 530. In addition, the automatic control unit 50 or the automatic control unit 50 may be formed in a structure including the aforementioned meter 501, data collector, and gateway 502 therein. That is, the automatic control unit 50 may be formed of a computer in which various modules are installed. In addition, the above-described integrated module 503 includes a drain sensor for measuring at least one of valve state information of the drain valve, pressure or flow rate or flow rate of the fluid, valve state information of the water spray valve, and at least one of the pressure or flow rate or flow rate of the fluid. It may be a module in which a sensor data receiving module for receiving data from a water spray sensor measuring one, a data collector, and a gateway are integrated.

The automatic control unit 50 can monitor the operating state of each watering facility to prevent a problem in which the watering facility for each discharge facility is not operated due to carelessness or operation error of some users. Here, the communication module 510 communicates data with the gas control valve 320, one drain valve module 4200, and a plurality of water spray valve modules 4201 to 4206, and controls the gas by an operation signal, that is, an open signal or a closed signal. It is transmitted to the valve 320, one drain valve module 4200, and a plurality of water spray valve modules 4201 to 4206. The control signal output module 520 is connected to the pump unit 20 and the high-pressure gas supply unit 30 and applies an operation signal to the pump unit 20 and the high-pressure gas supply unit 30 . Then, an open signal applied to the gas control valve 320, the drain valve module 4200, and the plurality of water spray valve modules 4201 to 4206 is generated. At this time, when an opening signal is applied to the gas control valve 320 and the drain valve module 4200, a closing signal applied to the plurality of water spray valve modules 4201 to 4206 may be generated. In addition, when an open signal is applied to the gas control valve 320 and any one of the water spray valve modules 4201 to 4206, a close signal applied to the drain valve module 4200 may be generated.

The display panel module 530 may be connected to the control signal output module 520 to generate an open signal and a close signal in a touch manner. As shown in FIG. 10, such a display panel module 530 outputs a screen related to a watering operation and a residual water removal operation.

The automatic control unit 50 is connected to the measuring instrument 501, data collector and gateway 502 through a communication module and a 4 to 20 mA signal, digital communication (RS-232, RS-485, ethernet, etc.) Data may be received through the Collector and Gateway 502 . At this time, the state information of the plurality of water spray valves (40211 to 42016) and the drain valve may be a contact point, voltage, 4-20mA signal, and the like. By measuring the data output from the plurality of sprinkling sensors (42021 to 42026) and the drain sensor (42020), the operating state of the sprinkling system corresponding to each discharge facility can be confirmed. The state information of the plurality of water spray sensors 42021 to 42026 and the drain sensor 42020 includes contacts, voltages, and 4 to 20 mA signals.

The terminal unit 60 communicates with the communication module 510, transmits and receives data, and manages the generation and output of an open signal or a closed signal output from the control signal output module 520. For example, the terminal unit 60 is formed of a desktop, a control system, or a smart phone to transmit and receive data with the automatic control unit 50 and to control a signal output from the automatic control unit 50. In particular, the terminal unit 60 outputs information output from the display panel module 530 and enables the control signal output module 520 to generate an open signal and a closed signal through screen settings.

Hereinafter, with reference to FIGS. 14 to 23, the operation of the automatic scattering dust removal system according to an embodiment of the present invention will be described in detail.

14 is a view showing a state in which the automatic scattering dust removal system according to an embodiment of the present invention is operated in a watering mode, and FIGS. 15 and 16 are diagrams constituting the automatic scattering dust removal system according to an embodiment of the present invention. It is a diagram showing the process of the components operating in the watering mode. 17 is a view showing a state in which the automatic scattering dust removal system according to an embodiment of the present invention is operated in the residual water removal mode, and FIG. 18 is a configuration constituting the automatic scattering dust removal system according to an embodiment of the present invention. It is a diagram showing the order in which the elements operate in residual water removal mode. And FIGS. 19 to 23 are diagrams showing states in which the automatic scattering dust removal system according to an embodiment of the present invention is operated in a sprinkling mode and a residual water removal mode.

The automatic scattering dust removal system 1 of the present invention is a sprinkling operation of sprinkling water on dust scattered through a sprinkling drain discharge unit, and residual water for removing water remaining in a piping and a sprinkling drain discharge unit after the sprinkling operation after the sprinkling operation. You can proceed with the removal operation.

First, the automatic scattering dust removal system 1 may perform a watering operation as shown in FIGS. 14 to 17 . At this time, the automatic controller 50 applies an open signal to the water tank valve 120 so that the water stored in the container module 110 is discharged from the container module 110 (S110). Then, by applying an operation signal to the pump unit 20 (S120), the water discharged from the container module 110 through the pump unit 20 is discharged to the filter unit 70 and filtered, and then the water spray drain discharge unit 40 ) to be transported. In addition, the automatic control unit 50 applies a closing signal to the gas control valve 320 to prevent gas from flowing into the water spray drain discharge unit 40 . In addition, a closing signal is sent to the drain valve 42010 so that the inflowing water is not discharged meaninglessly without removing scattered dust.

In addition, the automatic control unit 50 applies an opening signal to the first spray valve 42011 to the sixth spray valve 42016 to open the first spray valve 42011 to the sixth spray valve 42016, thereby dispensing the first water spray. Water can be discharged through the circular nozzle 430a or the nozzle module 430b connected to the valve 42011 to the sixth water spray valve 42016. For example, as shown in FIG. 14, the automatic control unit 50 applies an open signal to the fourth water spray valve 42014 and the sixth water spray valve 42016 to open them, and opens the first water spray valve 42011 and the second water spray valve 42011. A closing signal is applied to the spray valve 42012, the third spray valve 42013, and the fifth spray valve 42015 to close them. Through this, water is discharged through the fourth and sixth injection nozzles. In other words, as shown in FIG. 14, the automatic control unit 50 drives the discharge facilities, that is, the raw water tank unit 10, the pump unit 20, and the sprinkling drain discharge unit 40 to spray the first to sixth spray nozzles. It allows the water to be selectively discharged through the nozzle. In addition, the automatic control unit 50 applies a closing signal to the water tank valve 120 when it is necessary to stop the water sprayed from the nozzle, that is, when the watering operation is stopped, so that the water stored in the container module 110 is removed from the container module 110. ) from being released. And stop the operation signal to the pump unit 20 so that the pump unit 20 does not operate.

Through this, water is not transferred to the water spray drain discharge unit 40 . Then, a closing signal is applied to the first sprinkling valve 42011 to the sixth sprinkling valve 42016 so that the first sprinkling valve 42011 to the sixth sprinkling valve 42016 are closed (S140), and the first sprinkling valve 42011 ) through the circular nozzle 430a or the nozzle module 430b connected to the sixth water spray valve 42016 so that water is not discharged.

The automatic control unit 50 applies an open signal to the gas control valve 320 so that gas flows into the water spray drain discharge unit 40 . Then, an open signal is sent to the drain valve 42010 so that water remaining in the distribution pipe module 410 and the liquid transfer pipe 411 is discharged through the drain valve 42010.

More specifically, the automatic controller 50 controls the pump unit 20 to operate for a first set time through the control signal output module 520 and supplies water to the distribution pipe module 410 for the first set time. do. After the first set time, the operation of the pump unit 20 is stopped. Thereafter, the gas control valve 320 and the drain valve 42010 are opened for a second set time and the compressor module 310 is operated so that high-pressure gas flows into the distribution pipe module 410 and flows into the drain outlet pipe 413. to let it out At this time, the high-pressure gas primarily discharges water remaining in the distribution pipe module 410 to the drain outlet pipe 413.

The automatic controller 50 closes the drain valve 42010 when the second set time elapses, and then sequentially opens and closes the plurality of water spray valves 42021 to 42026 for a third set time. For example, the automatic control unit 50 closes the drain valve 42010 when the second set time elapses, and then opens the first spray valve for 20 seconds to discharge residual water through the first spray pipe 414. . After 20 seconds have elapsed, the first water spray valve 42011 is closed again and the second water spray valve 42012 is opened for 20 seconds so that residual water is discharged through the second water spray pipe 415. When 20 seconds have elapsed, the second water spray valve 42012 is closed again and the third water spray valve 42013 is opened for 20 seconds so that residual water is discharged through the third water spray pipe 416. When 20 seconds have elapsed, the third water spray valve 42013 is closed again and the fourth water spray valve 42014 is opened for 20 seconds so that residual water is discharged through the fourth water spray pipe 417. When 20 seconds have elapsed, the fourth water spray valve 42014 is closed again and the fifth water spray valve 42015 is opened for 20 seconds so that residual water is discharged through the fifth water spray pipe 418. When 20 seconds have elapsed, the fifth water spray valve 42015 is closed again and the sixth water spray valve 42016 is opened for 20 seconds so that residual water is discharged through the sixth water spray pipe 419.

The automatic scattering dust removal system 1 of the present invention sequentially sprays compressed air to the first water spray pipe 414 to the sixth water spray pipe 419 that discharge water. Accordingly, the automatic scattering dust removal system 1 allows the compressed air to be concentrated in one water spray tube without being dispersed to several water spray tubes, and quickly and reliably removes water from one water spray tube where water remains.

As such, the automatic scattering dust removal system 1 removes residual water with compressed air and prevents piping from freezing in winter. Moreover, the automatic scattering dust removal system 1 can prevent electric leakage accidents due to leakage of electricity from electric wires because electric wires are not installed in a plurality of water spray pipes through which water is discharged.

Although the embodiments of the present invention have been described with reference to the accompanying drawings, those skilled in the art to which the present invention pertains can be implemented in other specific forms without changing the technical spirit or essential features of the present invention. you will be able to understand Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

1: Scattering dust automatic removal system
10: enemy grandfather
110: container module 120: water tank valve
20: pump part
30: high pressure gas supply unit
310: compressor module 320: gas control valve
40: watering drain discharge unit
410: distribution pipe module 411: liquid transfer pipe
412: gas transfer pipe
413: drain outlet pipe 414: first watering pipe
415: second watering pipe 416: third watering pipe
417: 4th watering pipe 418: 5th watering pipe
419: 6th watering pipe
4200: drain valve module
42010: drain valve 42020: drain sensor
4201: first watering valve module
42011: 1st watering valve 42021: 1st watering sensor
4202: second watering valve module
42012: second watering valve 42022: second watering sensor
4203: third watering valve module
42013: 3rd watering valve 42023: 3rd watering sensor
4204: fourth watering valve module
42014: 4th watering valve 42024: 4th watering sensor
42015: 5th watering valve
4205: 5th watering valve module 42025: 5th watering sensor
4206: 6th watering valve module
42016: 6th watering valve 42026: 6th watering sensor
430: injection nozzle
430a: circular nozzle 430b: nose module
50: automatic control unit
501: instrument
502: data collector and gateway
503: integrated module
510: communication module 520: control signal output module
530: input and display panel module
60: terminal unit 70: filter unit

Claims (9)

A raw water tank unit 10 including a container module 110 for storing water therein and a water tank valve 120 connected to the container module 110 to control discharge of water stored in the container module 110;
A pump unit 20 having one side connected to the water tank valve 120 to suck water in the container module 110 and discharge it to the other side;
A high-pressure gas supply unit 30 including a compressor module 310 that compresses and discharges gas and a gas control valve 320 that controls the output of gas output from the compressor module 310;
A distribution pipe module 410 receiving either gas from the high-pressure gas supply unit 30 or water supplied from the pump unit 20 and one drain valve module 4200 disposed at one end of the distribution pipe module 410 and a water spray drain discharge unit 40 including a plurality of water spray valve modules 4201 to 4206 spaced apart from each other at regular intervals in the distribution pipe module 410;
Data is communicated with the gas control valve 320, one drain valve module 4200, and a plurality of water spray valve modules 4201 to 4206, and an open or closed signal is transmitted to the gas control valve 320 and one drain valve module 4200. ) and open applied to the communication module 510 transmitted to the plurality of watering valve modules 4201 to 4206, the gas control valve 320, the drain valve module 4200, and the plurality of watering valve modules 4201 to 4206 When a signal is generated and an open signal is applied to the gas control valve 320 and the drain valve module 4200, a closing signal applied to the plurality of water spray valve modules 4201 to 4206 can be generated, and the gas control valve 320 and an automatic control signal output module 520 capable of generating a closing signal applied to the drain valve module 4200 when an open signal is applied to any one of the water spray valve modules 4201 to 4206. control unit 50 and
It communicates with the communication module 510, transmits and receives data, and includes a terminal unit 60 that manages the generation and output of an open signal or a closed signal output from the control signal output module 520,
The drain valve module 4200,
A drain valve 42010 that opens when an open signal is applied and closes when a close signal is applied, and a drain sensor 42020 that measures at least one of valve state information, pressure, flow rate, or flow rate of a fluid,
A plurality of water spray valve modules (4201 to 4206),
Water spray valves (42021 to 42026) that open when an open signal is applied and close when a close signal is applied, and water spray sensors (42021 to 42026) that measure at least one of valve status information, pressure or flow rate, or flow rate of a fluid. , fugitive dust automatic removal system. According to claim 1,
A filter unit 70 located between the pump unit 20 and the water spray drain discharge unit 40 filters the water discharged from the pump unit 20 and then supplies it to the water spray drain discharge unit 40. which, fugitive dust automatic removal system. delete The method of claim 1, wherein the control signal output module 520,
An automatic scattering dust removal system that is connected to the pump unit 20 and the high-pressure gas supply unit 30 and applies an operation signal to the pump unit 20 and the high-pressure gas supply unit 30. The method of claim 4, wherein the control signal output module 520,
An automatic scattering dust removal system that applies an open signal or a close signal to a plurality of water spray valve modules (4201 to 4206). The method of claim 5, wherein the control signal output module 520,
When the pump unit 20 stops after operating for the first set time, the drain valve 42010 is opened for the second set time, the compressor module 310 is operated, and when the second set time elapses, the drain valve 42010 ( 42010), a plurality of water spray valves (42021 to 42026) are sequentially opened for a third set time and then closed. According to claim 5,
The plurality of water spray valve modules 4201 to 4206 include a first water spray valve 42021 to a sixth water spray valve 42026,
The first spray valve 42021 to the sixth spray valve 42026 are connected to a nozzle module 430b including a circular nozzle 430a having a spray hole with a diameter of 0.1 mm to 3.0 mm and a plurality of nozzles, scattering Automatic dust removal system. The method of claim 1, wherein the automatic control unit 50,
An automatic scattering dust removal system comprising an input and display panel module 530 connected to the control signal output module 520 to generate an open signal and a close signal in a touch manner. The method of claim 1, wherein the instrument (501) comprises:
The drain sensor 42020 for measuring at least one of the valve state information of the drain valve 42010, the pressure, flow rate, or flow rate of the fluid, and the valve state information of the water spray valves 42021 to 42026, the pressure, flow rate, or flow rate of the fluid An automatic scattering dust removal system comprising a sensor data receiving module for receiving data from water spray sensors (42021 to 42026) measuring at least one of them, and an integrated module (503) in which a data collector and a gateway (502) are integrated.

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