KR102264422B1 - Double-spraying dust reduction apparatus of scattered dust location tracking type and reducing method for scattered dust using the same - Google Patents

Abstract

The present invention provides a double-spraying dust reduction apparatus that is located spaced apart from a scattering dust generating source and removes scattering dust, and a method of reducing scattering dust using the same. A double-spraying dust reduction apparatus of a scattering dust location tracking type includes a dual injection module that independently sprays water in the form of mist and water in the form of a high-pressure jet, and removes scattering dust including fine dust; and a control module for recognizing information on wind direction, wind speed, and location of a place where the scattering dust reduction device is located, wherein the control module controls the motion and water injection state of the dual injection module according to the recognized information.

Description

Double-spraying dust reduction apparatus of scattered dust location tracking type and reducing method for scattered dust using the same}

The present invention relates to a scattering dust reduction device and a method for reducing scattering dust using the same, and it is possible to minimize the influence of external wind and efficiently reduce scattering dust generated from a scattering dust generating source at a construction site. It relates to a scattering dust reduction device and a method for reducing scattering dust using the same.

Fugitive dust is generated in various industrial sites such as construction sites, plants, cement mines, and road scattering. Domestic treatment technology for scattering dust at construction sites is very rudimentary, such as manpower sprinkling, dustproofing, and wheel washing facilities.

On the other hand, recently, construction works are being carried out due to large-scale, life-saving, and high-tech, etc., and construction works by manpower in the past are being replaced by construction equipment. In particular, almost 100% of construction equipment is used for construction dismantling and demolition sites, earthworks, etc., which generate a lot of scattering dust. When working with such construction equipment, scattering dust is intensively generated in the end area (attachment) of the equipment, which is the work part of the construction equipment, and this part is called a scattering dust generator.

As is known, fine dust contained in scattering dust is fatal to human health, and in order to solve this problem, we developed a dust suppression system that implements slip stream effect avoidance technology in the US, Europe, and Japan. Therefore, it is applied to treat fine dust such as PM10 together with scattering dust in various industrial sites where scattering dust is generated. The above technique is to install a plurality of nozzles capable of fine jetting in an independent jetting device and spray water to suppress not only scattering dust but also fine dust in scattering dust.

1 is a perspective view showing a site to which a conventional scattering dust reduction water spray system is applied, and a scattering dust generating source (A) of a structure (1) and construction equipment (20) performing crushing and a scattering dust reduction water spray device (30) ) is shown. As shown in FIG. 1, when the water spray system for reducing scattering dust is applied to a construction site, the water (B) sprayed by the water spray device 30 according to the direction of the wind (W) and the source (A) from which scattering dust is generated Locations may not match in real time. Therefore, there may be a problem that the removal of scattering dust becomes inefficient and the reduction effect may be greatly reduced.

Korean Patent Registration No. 10-2193458 (Registration Date: December 15, 2020) Korean Patent Publication No. 10-2020-0089388 (published on July 27, 2020)

A technical problem to be achieved by the present invention is a scattering dust reduction device of the scattering dust location tracking type double injection method that can efficiently remove scattering dust generated at a construction site by minimizing the influence of external wind, and a scattering dust reduction method using the same The purpose is to provide

The object of the present invention is not limited to the object mentioned above, and other objects not mentioned will be clearly understood by those of ordinary skill in the art to which the present invention belongs from the following description.

In order to solve the above problem, the present invention is a scattering dust reduction device that is located apart from a scattering dust generating source and removes scattering dust, spraying water in the form of mist and water in the form of a high-pressure jet independently, respectively, and including fine dust Dual injection module to remove scattered dust; and a control module for recognizing information on the wind direction, wind speed, and location of the place where the scattering dust reduction device is located, wherein the control module controls the motion and water injection state of the dual injection module according to the recognized information. It is possible to provide a scattering dust reduction device of the scattering dust location tracking type double injection method, characterized in that it is set by controlling.

The control module may be provided with the location of the scattering dust generating source and the wind direction or wind speed, and correct the setting of the dual injection module according to a preset threshold value of the wind speed.

When the measured wind speed is less than the threshold value, the control module may be to correct the injection angle of the double injection module by vector calculating the position of the scattering dust generating source and the position of the scattering dust reducing device.

If the measured wind speed is greater than or equal to the threshold value, the control module analyzes the location of the scattering dust generating source, the separation distance from the scattering dust reduction device, the wind direction and the wind speed, and the injection angle and the injection speed of the dual injection module. may be correcting.

The dual injection module may include a first injection unit that sprays water in the form of mist, and a second injection unit that operates independently of the first injection unit and sprays water in the form of a high-pressure jet.

The dual injection module may further include a first positioning unit including a first linear gear for adjusting the vertical injection angle of the first injection unit, and a first horizontal rotation member for adjusting the horizontal rotation angle of the first injection unit. .

The double injection module may further include a second positioning unit including a second linear gear for adjusting the vertical injection angle of the second injection unit, and a second horizontal rotation member for adjusting the horizontal rotation angle of the second injection unit. .

The first injection part may include a first body-shaped rotating body having a diameter of one end smaller than the diameter of the other end and having a flow path therein, and a plurality of mist nozzles positioned along the circumference of the one end and spraying mist. have.

The second injection unit may include a second body coupled to an outer circumferential surface of the body of the first injection unit, and a plurality of jet nozzles provided at one end of the second body.

In addition, in order to solve the above problem, the present invention provides a method for reducing scattering dust that is separated from a scattering dust generating source and removes scattering dust. Information on the wind direction, wind speed, and location of the control module where the scattering dust reduction device is located recognizing; controlling and setting the motion and water injection state of the dual injection module according to the recognized information; Reducing scattering dust of the scattering dust location tracking type double injection method, comprising: independently spraying water in the form of mist and water in the form of a high-pressure jet according to the set state, respectively, and removing scattering dust including fine dust method can be provided.

The setting by controlling the motion and water injection state of the dual injection module is that the control module receives the location, wind direction or wind speed of the scattering dust generating source, and corrects the water injection state according to a preset threshold value of wind speed. can

The scattering dust reduction device of the scattering dust location tracking type double injection method and the scattering dust reduction method using the same according to an embodiment of the present invention recognize and recognize information on the wind direction, wind speed, and location of the place where the scattering dust reduction device is located By controlling the motion of the dual injection module and the water injection state according to the obtained information, there is an advantage in that it is possible to efficiently remove the scattered dust generated at the construction site by minimizing the influence of the external wind.

1 is a perspective view showing a site to which a conventional scattering dust reduction water spray system is applied;
Figure 2 is a perspective view showing the operation of the scattering dust generating source of the scattering dust location tracking type double injection type scattering dust reduction device according to the embodiment of the present invention;
Figure 3 is a perspective view showing the scattered dust location tracking type double spraying method for reducing scattered dust according to an embodiment of the present invention;
4 is a process flow diagram showing a method for reducing scattered dust of a location tracking type double injection method according to an embodiment of the present invention;
5 is a side view showing a method for controlling scattered dust reduction of a location tracking type double injection method according to an embodiment of the present invention;
6 is a perspective view showing a site to which the scattered dust reduction method of the scattered dust location tracking type double injection method according to an embodiment of the present invention is applied.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments introduced below are provided as examples so that the spirit of the present invention can be sufficiently conveyed to those skilled in the art. Accordingly, the present invention is not limited to the embodiments described below and may be embodied in other forms. In addition, in the drawings, the length, thickness, etc. of layers and regions may be exaggerated for convenience. Like reference numerals refer to like elements throughout.

1 is a perspective view showing a site to which a conventional scattering dust reduction water injection system is applied, and FIG. 2 is an operation for the scattering dust generating source of the scattering dust location tracking type double injection type scattering dust reduction device according to the embodiment of the present invention. 3 is a perspective view showing a scattering dust reduction device of a scattering dust location tracking type dual injection method according to an embodiment of the present invention, and FIG. 4 is a scattering dust location tracking type double injection method according to an embodiment of the present invention. is a process flow chart showing a method for reducing scattering dust, and FIG. 5 is a side view illustrating a method for controlling scattering dust reduction of a scattering dust location tracking type double injection method according to an embodiment of the present invention, and FIG. 6 is an embodiment of the present invention It is a perspective view showing the site where the scattered dust reduction method of the scattered dust location tracking type double injection method is applied.

2 to 6 , in the scattering dust reduction device that is located spaced apart from the scattering dust generating source (A) and removes scattering dust, the scattering dust location tracking type double injection type scattering dust according to an embodiment of the present invention The reduction device 10 independently sprays water in the form of mist and water in the form of a high-pressure jet, and a double injection module 100 for removing scattered dust including fine dust; and a control module 200 for recognizing information on the wind direction, wind speed, and location of the place where the scattering dust reduction device 10 is located, wherein the control module 200 includes, according to the recognized information, the double It may be set by controlling the motion of the spraying module 100 and the water spraying state.

In detail, the dual spray module 100 for removing scattering dust including fine dust is not reduced from mist-type water and mist-type water to reduce not only scattering dust but also fine dust in scattering dust. Water in the form of a high-pressure jet that removes scattering dust scattered in the air can be sprayed independently.

For example, the dual injection module 100 includes a first injection unit 110 that sprays water in the form of mist, and a second injection unit 110 that operates independently of the first injection unit 110 and sprays water in the form of a high-pressure jet. It may include the injection unit 120 . In this case, the scattered dust reduction device 10 may include a storage tank 300 , and the first spray unit 110 and the second spray unit 120 may receive water from the storage tank 300 .

In the case of installing the dust film 3 before construction in the construction site as shown in FIG. 6 , the scattering dust (A') that is separated from the scattering dust measuring device 7 located on the upper part of the dust film 3 to the outside of the construction site is removed. can be measured At this time, there may be a problem of contamination of the surrounding environment due to the scattering dust (A') that scatters to the upper surface of the dust film and escapes outside the construction site. Therefore, scattering dust (A) generated inside the dust film (3) at the construction site _{is treated by the mist spray (B M} ) of the first spray unit 110, and outside the upper surface of the dust film (3) The scattering dust (A ') separated to the outside of the construction site may be reduced by _{the high-pressure jet injection (B J ) of the second injection unit 120 .} Therefore, the scattering dust reduction device 10 of the scattering dust location tracking type double injection type according to an embodiment of the present invention is water (B _M ) in the form of mist through the first injection unit 110 and the second injection unit 120 . _{By independently spraying water (B J} ) in the form of a high-pressure jet and scattering dust, it is possible to remove not only scattering dust but also fine dust generated at the construction site, and it is also possible to reduce scattering dust from the construction site.

The first injection unit 100 has a first body 114 of a rotating body type having a diameter of one end smaller than the diameter of the other end and having a flow path formed therein, and a plurality of mist sprayed portions located along the circumference of the one end. It may include a mist nozzle 112 . That is, the flow path formed inside the first body 114 may be connected to the storage tank 300 to supply water to the mist nozzle 112 so that water in the form of mist may be sprayed. For example, the water particles sprayed from the mist nozzle 112 preferably have a size of 30 to 80 μm in order to remove fine dust of PM10 or less. The first spraying unit 100 may have a mist-type spraying water particle size as described above in consideration of a technology for avoiding slip stream effects for reducing fine dust in scattered dust. Slip Stream Effects refers to a phenomenon in which the sprayed water particles are blown into the atmosphere without colliding with the scattered dust particles scattered in the atmosphere when the size (diameter) of the sprayed water particles is larger than the PM10 fine dust particles. For efficient reduction of and fine dust, the water sprayed from the mist nozzle 112 may have the above size.

The second injection unit 120 includes a second body 124 coupled to the outer circumferential surface of the body 114 of the first injection unit, and a plurality of jet nozzles 122 provided at one end of the second body 124 . ) may be included. When the wind speed is strong at the construction site, it may be difficult to reach the target scattering dust generating source (A) under the influence of the strong wind speed because the first spraying unit 100 is sprayed in the form of mist. Therefore, high-pressure jet water is sprayed by the jet nozzle 122 of the second injection unit 120 to be less affected by the wind, so that scattering dust can be effectively reduced, and the scattering dust in the air is blown away by the wind to the respiratory system. penetration and damage can be minimized.

The double injection module 100 includes a first linear gear 133 for adjusting the vertical injection angle of the first injection unit 110 and a first horizontal rotation for adjusting the horizontal rotation angle of the first injection unit 110 . The first position adjusting unit 130 including the member 135 may be further included.

In addition, the double injection module 100, the second linear gear 143 for adjusting the vertical injection angle of the second injection unit 120, and a second for adjusting the horizontal rotation angle of the second injection unit (120) A second position adjusting unit 140 including a horizontal rotating member 145 may be further included.

The double injection module 100 must be freely rotated vertically and horizontally to efficiently and accurately spray water. Accordingly, the first injection unit 110 and the second injection unit 120 may include a first linear gear 133 and a second linear gear 143 for separate vertical and vertical rotation, respectively, and separate horizontal and vertical rotations, respectively. It may include a first horizontal rotation member 135 and a second horizontal rotation member 145 to adjust the rotation angle. In addition, the scattered dust reduction device 10 of the scattered dust location tracking type dual injection method according to the embodiment of the present invention may further include a transport module 400 for mounting and moving the dual injection module 100, The control module 200 may also be located on the transfer module 400 .

The control module 200 may include a weather vane 210 , a GPS 220 , and a control box 230 , and a place where the dust scattering reduction device 10 is located from the weather vane 210 and the GPS 220 . Recognizes information on the wind direction, wind speed, and location of the , and the control box 230 controls the motion and the water injection state of the dual injection module 100 according to the recognized information to be set. That is, by installing a wind vane 210 that can measure the direction and strength of the wind, data on wind obtained from the wind vane 210 can be transmitted to the control box 230, and The motion behavior of the double injection module 100 can be adjusted.

For example, the particle size of water sprayed from the first spraying unit 110 and the second spraying unit 120 may be determined in consideration of the wind condition of the construction site on the day, and the water particle size to be sprayed is determined according to the wind condition. In order to do this, the diameter of the mist nozzle 112 or the jet nozzle 122, the water outlet pressure of the pump equipped with the storage tank 300, the mist according to the operation of the first linear gear 133 and the second linear gear 143 The angle of the nozzle 112 or the jet nozzle 122, the number of sprays of the mist nozzle 112 or the jet nozzle 122, etc. can be controlled. In this case, the mist nozzle 112 or the jet nozzle 122 may be provided to enable separation and coupling, and the diameter and number of the mist nozzle 112 or the jet nozzle 122 can be easily replaced according to the conditions required at the construction site. can do.

Furthermore, the control module 200 receives the location and wind direction or wind speed of the scattering dust generating source (A), and corrects the setting of the dual injection module 100 according to a preset threshold value of the wind speed. . In this case, as shown in Figure 2, the scattering dust generating source (A) may be the end region 26 of the construction equipment 20, for example, the construction equipment 20 can measure the wind direction or wind speed of the corresponding location. A weather vane 22 and a GPS 24 for detecting a location may be provided to provide the control module 200 with the location and wind direction or speed of the scattering dust generating source A.

That is, when adjusting the motion behavior of the dual injection module 100 according to the scattering dust pushed by the wind or the sprayed water, the location of the scattering dust generating source (A) from the GPS 24 of the construction equipment 20 is determined. By reflecting the wind direction or wind speed from the wind vane 22 of the construction equipment 20, the water sprayed from the dual injection module 100 and the scattering dust generator A are corrected to match in real time to minimize the influence of the wind. can It is preferable to install the wind vane directly on the construction equipment 20 as shown in FIG. 2, but it can be installed anywhere on the site where scattering dust can be efficiently controlled according to site characteristics.

When the measured wind speed is less than the threshold value, the control module 200 calculates a vector of the position of the scattering dust generating source (A) and the position of the scattering dust reduction device 10, and the injection angle of the double injection module 100 may be to correct For example, the threshold value may be a pongsok in which the spraying radius of the mist-type water sprayed from the first spraying unit 110 is maintained even when the wind blows, and the scattering degree of scattered dust is included in the mist spraying range. That is, when the wind speed is less than the threshold value, the control member 200 is provided with the location of the scattering dust source (A) from the GPS 24 of the construction equipment 20, and the GPS 120 of the scattering dust reduction device 10 ), after recognizing the position of the dual injection module 100 from the vector calculation for the position, correcting the injection angle of the dual injection module 100, and spraying water in the form of mist and water in the form of a jet to reduce scattering dust. can

Furthermore, if the measured wind speed is greater than or equal to the threshold value, the control module 200 analyzes the location of the scattering dust generating source (A), the separation distance d1 from the scattering dust reduction device 10, and the wind direction and wind speed and correcting the injection angle and the injection speed of the dual injection module 100 . That is, if the wind speed is strong and the spraying radius of the mist-type water sprayed from the first spraying unit 110 cannot be maintained, or the scattering degree of scattered dust is out of the mist spraying range, it can be said that the wind speed is higher than the threshold value.

Referring to FIG. 5 , the control module 200 can measure the distance d1 between the scattering dust reduction device 10 and the scattering dust generator A, that is, the end region 26 of the construction equipment 20. , the distance d1 may be calculated from the GPS 24 of the construction equipment 20 and the GPS 120 of the scattering dust reduction device 10 . When the distance d1 between the scattering dust reduction device 10 and the scattering dust generating source A is determined, the wind direction obtained from the wind vane 22 of the construction equipment 20 and the wind vane 210 of the scattering dust reduction device 10 is determined. (W) Data can be comparatively analyzed. For example, data of the construction equipment 20 may be transmitted by wireless transmission to the control module 200 of the scattering dust reduction device 10 .

In the above process, the separation distance (d1), the time to reach the scattering dust generating source (A) when the double spray module 100 sprays water, and the wind direction (W) speed and direction are reflected, so it must be adjusted when spraying. A correction distance d2 and a correction angle θ to be calculated may be calculated. That is, if the location of the scattered dust A2 that is changed by the wind W is calculated based on the initially sprayed water B1 and the analyzed data with respect to the location of the scattered dust generating source A1, the location is changed. Since the end point of the water B2 to be sprayed for one scattering dust A2 can be predicted, the correction distance d2 and the correction angle θ can be calculated. In a process different from the above, when the sprayed water is more affected by the wind than the dispersion of the scattered dust, the location (B2) of the water to be sprayed by the wind is predicted, and the location of the scattered dust source (A1) is A correction distance d2 and a correction angle θ may be calculated.

Since the water injection direction can be adjusted by motion-controlling the behavior of the dual injection module 100 by the first position adjusting unit 130 and the second position adjusting unit 140 by the correction values (d2, θ), the dual injection module ( 100) and the actual location of the scattered dust (A2) can be matched in real time to minimize the influence on the wind. In addition, as shown in FIG. 6, data is acquired from the scattering dust measuring device 7 for scattering dust (or fine dust) leaving the construction site, and the acquired data is transmitted to the scattering dust reduction device 10 to be sprayed at high pressure. 2 The spraying unit 120 can block and reduce scattering dust and fine dust leaving the construction site by locating and spraying it.

In addition, in order to solve the above problem, the present invention provides a method for reducing scattering dust that is separated from a scattering dust generating source and removes scattering dust. Recognizing information on wind speed and location (S110); Controlling and setting the motion and water injection state of the dual injection module 100 according to the recognized information (S120); According to the set state, spraying water in the form of mist and water in the form of a high-pressure jet independently, respectively, and removing scattered dust including fine dust (S130); It is possible to provide a method for reducing scattering dust.

In detail, first, the control module 200 may recognize information on the wind direction, wind speed, and location of the place where the scattered dust reduction device 10 is located (S110). The control module 200 including the weather vane 210 and the GPS 220 and the control box 230 provides the wind direction and speed of the location where the scattering dust reduction device 10 is located from the weather vane 210 and the GPS 220 . , can recognize information about the location. Furthermore, the control module 200 may be provided with the location and wind direction or speed of the scattering dust generating source (A). As an example, as shown in FIG. 2 , the scattering dust generating source A may be the end region 26 of the construction equipment 20 , and the construction equipment 20 has a wind vane 22 capable of measuring the wind direction or speed of the corresponding location. ) and a GPS 24 for detecting the position, the control module 200 may provide the location and wind direction or speed of the scattering dust generating source (A) through wireless communication.

Next, according to the recognized information, the motion of the dual injection module 100 and the water injection state may be controlled and set (S120). The control box 230 may be set by controlling the motion and water injection state of the dual injection module 100 according to the recognized wind direction, wind speed, and location information. That is, by installing a wind vane 210 that can measure the direction and strength of the wind, data on wind obtained from the wind vane 210 can be transmitted to the control box 230, and The motion behavior of the double injection module 100 can be adjusted. For example, the particle size of water sprayed from the first spraying unit 110 and the second spraying unit 120 may be determined in consideration of the wind condition of the construction site on the day, and the water particle size sprayed according to the wind condition is determined In order to do this, the diameter of the mist nozzle 112 or the jet nozzle 122, the water outlet pressure of the pump equipped with the storage tank 300, the mist according to the operation of the first linear gear 133 and the second linear gear 143 The angle of the nozzle 112 or the jet nozzle 122, the number of sprays of the mist nozzle 112 or the jet nozzle 122, etc. can be controlled. In this case, the mist nozzle 112 or the jet nozzle 122 may be provided to enable separation and coupling, and the diameter and number of the mist nozzle 112 or the jet nozzle 122 can be easily replaced according to the conditions required at the construction site. can do.

Controlling and setting the motion and water injection state of the double injection module 100 (S120) is that the control module 200 receives the location, wind direction or wind speed of the scattering dust generating source, and a preset threshold of the wind speed. It may be to correct the water injection state according to the value. That is, when adjusting the motion behavior of the double injection module 100 according to the scattered dust pushed by the wind, the location of the scattered dust generating source (A) is provided from the GPS 24 of the construction equipment 20 and the construction By reflecting the wind direction or wind speed from the wind vane 22 of the equipment 20, the water sprayed from the dual injection module 100 and the scattering dust generating source A are corrected to match in real time, thereby minimizing the influence of the wind.

By comparing the wind speed and the threshold value (S121), when the wind speed is less than the threshold value, the control module 200 may calculate a vector operation using the position information and a correction angle (S123). For example, the threshold value may be a pongsok in which the spraying radius of the mist-type water sprayed from the first spraying unit 110 is maintained even when the wind blows, and the scattering degree of scattered dust is included in the mist spraying range. That is, when the wind speed is less than the threshold value, the control member 200 is provided with the location of the scattering dust source (A) from the GPS 24 of the construction equipment 20, and the GPS 120 of the scattering dust reduction device 10 ), after recognizing the position of the dual injection module 100 from the vector calculation for the position, correcting the injection angle of the dual injection module 100, and spraying water in the form of mist and water in the form of a jet to reduce scattering dust. can

If the wind speed and the threshold value are compared (S121), and if the wind speed is greater than or equal to the threshold value, the control module 200 analyzes the wind direction, wind speed, and separation distance (S125), and can calculate a vector operation and a compound correction angle (S127). ). That is, if the wind speed is strong and the spraying radius of the mist-type water sprayed from the first spraying unit 110 cannot be maintained, or the scattering degree of scattered dust is out of the mist spraying range, it can be said that the wind speed is higher than the threshold value. The control module 200 may measure the distance d1 between the scattering dust reduction device 10 and the scattering dust generating source A, that is, the end region 26 of the construction equipment 20, wherein the distance d1 is It can be calculated from the GPS 24 of the equipment 20 and the GPS 120 of the scattering dust reduction device 10 . When the distance d1 between the scattering dust reduction device 10 and the scattering dust generating source A is determined, the wind direction obtained from the wind vane 22 of the construction equipment 20 and the wind vane 210 of the scattering dust reduction device 10 is determined. (W) Data can be comparatively analyzed. For example, the data of the construction equipment 20 may be transmitted by wireless transmission to the control module 200 of the scattering dust reduction device 10 .

With the above process, the separation distance (d1), the time to reach the scattering dust generating source (A) when the double injection module 100 sprays water, and the wind direction (W) speed and direction are reflected when spraying. The correction distance d2 and the correction angle θ may be calculated. That is, if the location of the scattered dust A2 that is changed by the wind W is calculated based on the initially sprayed water B1 and the analyzed data with respect to the location of the scattered dust generating source A1, the location is changed. Since the end point of the water B2 to be sprayed for one scattering dust A2 can be predicted, the correction distance d2 and the correction angle θ can be calculated. In a process different from the above, when the sprayed water is more affected by the wind than the dispersion of the scattered dust, the location (B2) of the water to be sprayed by the wind is predicted, and the location of the scattered dust source (A1) is A correction distance d2 and a correction angle θ may be calculated.

Thereafter, the motion of the dual injection module can be controlled (S129). That is, the motion of the dual injection module 100 may be controlled by the first position adjusting unit 130 and the second position adjusting unit 140 by the correction values d2 and θ.

Next, water in the form of mist and water in the form of a high-pressure jet are each independently sprayed according to the set state, and scattered dust including fine dust can be removed (S130). Since the water injection direction can be adjusted according to the motion control step (S129), the injection direction of the dual injection module 100 and the actual location of the scattered dust (A2 or A1) are matched in real time to form mist-type water and high-pressure jet form The influence of wind can be minimized by spraying each of the water independently. In addition, as shown in FIG. 6, data is acquired from the scattering dust measuring device 7 for scattering dust (or fine dust) leaving the construction site, and the acquired data is transmitted to the scattering dust reduction device 10 to be sprayed at high pressure. 2 The spraying unit 120 can block and reduce scattering dust and fine dust leaving the construction site by locating and spraying it.

The scattering dust reduction device of the scattering dust location tracking type double injection method and the scattering dust reduction method using the same according to an embodiment of the present invention recognize and recognize information on the wind direction, wind speed, and location of the place where the scattering dust reduction device is located By controlling the motion of the dual injection module and the water injection state according to the obtained information, there is an advantage in that it is possible to efficiently remove the scattered dust generated at the construction site by minimizing the influence of the external wind.

Although the above has been described with reference to the preferred embodiment of the present invention, those skilled in the art can variously modify and change the present invention within the scope without departing from the spirit and scope of the present invention described in the claims below. You will understand that it can be done.

One; structure
3; dust film
7; Fugitive dust measuring device
10; Fugitive dust location tracking type double-spraying dust reduction device
20; construction equipment
30; Conventional scattering dust reduction water spray device
100; double injection module
110; first injection unit
112; mist nozzle
114; first body
120; second injection unit
122; jet nozzle
124; second body
130; first positioning unit
133; first linear gear
135; first horizontal rotating member
140; second positioning unit
143; 2nd linear gear
145; second horizontal rotation member
200; control module
210; wind vane
220; GPS
230; Control box
300; storage tank
400; transfer module
A; Fugitive dust generator
B; water spray

Claims (11)

In the scattering dust reduction device that is located apart from the scattering dust generating source and removes scattering dust,
a dual injection module that independently jets water in the form of mist and water in the form of a high-pressure jet, and removes scattering dust including fine dust; and
Including; a control module for recognizing information on the wind direction, wind speed, and location of the place where the scattering dust reduction device is located;
The control module sets by controlling the motion and the water injection state of the dual injection module according to the recognized information,
The double injection module includes a first injection unit for spraying water in the form of mist, and a second injection unit that operates independently of the first injection unit and sprays water in the form of a high-pressure jet,
The first spraying part includes a first body of a rotating body having a diameter of one end smaller than the diameter of the other end and having a flow path therein, and a plurality of mist nozzles positioned along the circumference of the one end and spraying mist,
The second spraying unit includes a second body coupled to the outer circumferential surface of the body of the first spraying unit, and a plurality of jet nozzles provided at one end of the second body. of scattering dust reduction device.
The method of claim 1,
The control module is provided with the location and wind direction or wind speed of the source of scattered dust, and corrects the setting of the dual injection module according to a preset threshold value of the wind speed. dust reduction device.
3. The method of claim 2,
The control module, if the measured wind speed is less than the threshold value,
Fugitive dust location tracking type dual injection type scattering dust reduction device, characterized in that the position of the scattering dust generating source and the position of the scattering dust reduction device are vector calculated to correct the injection angle of the dual injection module.
3. The method of claim 2,
The control module, if the measured wind speed is above the threshold value,
The location of the scattering dust generation source, the separation distance from the scattering dust reduction device, the wind direction and the wind speed are analyzed, and the injection angle and the injection speed of the dual injection module are corrected. Fugitive dust reduction device.
delete The method of claim 1,
The double injection module further comprises a first position adjustment unit including a first linear gear for adjusting the vertical injection angle of the first injection unit, and a first horizontal rotation member for adjusting the horizontal rotation angle of the first injection unit Fugitive dust location tracking type double-spraying dust reduction device.
The method of claim 1,
The double injection module further comprises a second positioning unit comprising a second linear gear for adjusting the vertical injection angle of the second injection unit, and a second horizontal rotation member for adjusting the horizontal rotation angle of the second injection unit Fugitive dust location tracking type double-spraying dust reduction device.
delete delete In the scattering dust reduction method of removing scattering dust away from the scattering dust generating source,
Recognizing, by the control module, information on the wind direction, wind speed, and location of the place where the scattering dust reduction device is located;
Controlling and setting the motion and water injection state of the dual injection module according to the recognized information;
Including; spraying water in the form of mist and water in the form of a high-pressure jet according to the set state independently, and removing scattered dust including fine dust;
The double injection module includes a first injection unit for spraying water in the form of mist, and a second injection unit that operates independently of the first injection unit and sprays water in the form of a high-pressure jet,
The first spraying part includes a first body of a rotating body having a diameter of one end smaller than the diameter of the other end and having a flow path therein, and a plurality of mist nozzles positioned along the circumference of the one end and spraying mist,
The second spraying unit includes a second body coupled to the outer circumferential surface of the body of the first spraying unit, and a plurality of jet nozzles provided at one end of the second body. of scattering dust reduction method.
11. The method of claim 10,
The setting by controlling the motion and water injection state of the dual injection module is that the control module receives the location, wind direction or wind speed of the scattering dust generating source, and corrects the water injection state according to a preset threshold value of wind speed. A method for reducing scattered dust of a location tracking type double spraying method characterized by its features.

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