KR102626612B1 - Mesh belt for collecting coarse aggregate, hook-type belt for sorting foreign substances, belt for collecting fine aggregate, collection of smart flying aggregate through breathing-exhalation type trash box pores, scattering dust reduction type construction waste foreign matter separation and sorting device and method - Google Patents

Abstract

The present invention relates to a smart device and method for separating and screening construction waste foreign substances, capable of fugitive aggregate recovery and fugitive dust reduction. The device comprises a vibrating screen module, a mesh belt unit for recovering fugitive coarse aggregate, a hook-type belt unit for screening foreign substances, a belt unit for recovering fugitive fine aggregate, an inhalation-exhalation-type waste storage box, and a smart control unit. According to the present invention, fugitive dust can be reduced.

Description

Mesh belt for recovering loose coarse aggregate, hook-type foreign matter sorting belt, belt for recovering loose fine aggregate, inhalation-exhalation waste bin Smart fly aggregate recovery through pores, flying dust reduction type construction waste foreign matter separation device and method {Mesh belt for collecting coarse aggregate, hook-type belt for sorting foreign substances, belt for collecting fine aggregate, collection of smart flying aggregate through breathing-exhalation type trash box pores, scattering dust reduction type construction waste foreign matter separation and sorting device and method}

The present invention is a process of separating and sorting foreign substances in construction waste that fall by particle size in a vibrating screen module from raw aggregates at a strong wind speed of 30 m/s to 70 m/s. Among the flying aggregates blown away as an adverse effect, the flying coarse aggregates are In the process of recovering through the mesh belt for collecting loose coarse aggregate, the flying fine aggregate is separated and sorted and allowed to fall into the flying fine aggregate recovery belt, and the flying fine aggregate and foreign matter that flew farther than the flying coarse aggregate are hooked and placed in an inhalation-exhalation type garbage storage bin. While transporting, the flying fine aggregate is collected in the flying fine aggregate recovery belt, and the heavy part of the flying dust is allowed to settle inside the waste bin and only the light part is passed through the breathing hole on the upper and side walls of the closed waste bin. Mesh belt for recovering loose coarse aggregate that is controlled to be discharged to the outside, hook-type foreign matter sorting belt, belt for recovering loose fine aggregate, and inhalation-exhalation trash bin. Smart collection of loose aggregate and reduction of flying dust through pores. Separation and selection of foreign matter from construction waste. It relates to devices and methods.

In addition to waste concrete, waste asphalt concrete, waste wood, rebar, earth and sand, which are generally generated at construction sites, types of waste that cannot be separated due to working conditions at redevelopment sites, etc., that is, a mixture of construction waste, waste vinyl, household waste, etc. The amount of construction waste and construction waste generated in Korea reaches 40 million tons per year.

In order to increase the recycling rate of these wastes, the wastes are sorted and discharged according to their properties before being discharged as construction wastes. However, because the economic feasibility of this is not high, more than 90% of the wastes are left unseparated with foreign substances, etc. The reality is that the recycling performance in areas with high added value is very low, as it is only used for filling and landfill after intermediate processing.

In order to increase the recycling rate of these wastes, wastes are sorted and discharged according to their properties before being discharged as construction wastes, but since the economic feasibility of this is not high, more than 90% of the wastes are left without foreign substances separated and are sent to construction waste intermediate treatment companies. The reality is that the recycling performance in areas with high added value is very low, as it is only used for fill and landfill after intermediate processing.

In order to solve this problem, as a prior art, a wind-powered separation device for foreign substances in construction waste has been proposed in Domestic Patent Publication No. 10-1830648. However, when foreign substances are sucked in on a vibrating inclined screen, foreign substances are caught in the suction port and the foreign substances are inhaled. It did not work well, and even light fine powder among the flying aggregates was inhaled along with foreign substances, which became a factor in the breakdown of the cyclone dust collector.

Unlike the suction method as described above, when strong blowing is used to increase the efficiency of separating foreign substances in the blowing method, it can cause flying dust, resulting in civil complaints and increased facility investment and maintenance costs for dust management. A problem occurred.

In addition, the strong wind in blowing not only separates foreign substances from the raw aggregate, but also separates light stone dust, soil, etc. from large areas of aggregate or aggregates that are greatly affected by the wind. Aggregates that are separated and sorted by blowing in this way are called flying aggregates, and there is no recovery device for them, so the flying aggregates must be recovered through a separate secondary process from the foreign substances separated after the separation and screening of foreign substances, which reduces economic feasibility and reduces the sorting efficiency. Not only was this low, but a problem arose as the selection time became longer.

Domestic Patent Publication No. 10-1830648

In order to solve the above problems, the present invention uses an inclined blowing module formed at the bottom of the discharge part of the vibrating screen module with strong blowing of 30 m/s to 70 m/s, a process of separating foreign substances such as vinyl or wood chips from construction waste. A mesh belt for recovering loose coarse aggregate for transporting the loose coarse aggregate in a bag while sorting out the flying fine aggregate from the flying aggregate separated together, and foreign substances that have flown farther than the flying coarse aggregate and the flying fine aggregate are selected from the flying fine aggregate and the foreign materials are lifted with a hook. By transporting it to the trash bin, the foreign matter is separated from the flying fine aggregate, and the flying fine aggregate is recovered through the flying fine aggregate recovery belt, which recovers the flying fine aggregate selected from the mesh belt for recovering the flying coarse aggregate and the hook-type foreign material sorting belt, and the inhalation and exhalation type. Through the garbage storage box, flying dust can be reduced, and through the smart control unit, strong wind speed spraying of 30m/s ~ 70m/s, mesh belt for recovering loose coarse aggregate, hook-type foreign matter sorting belt, and belt for recovering loose fine aggregate. Through this, it is possible to collect the flying aggregate and separate and select only foreign substances, and additionally control the reduction of flying dust through the inhalation and exhalation type pores, so that the size of the sorted aggregate on site, the recovery rate of the flying coarse aggregate, the recovery rate of the flying fine aggregate, and the flying dust generation rate are possible. Mesh belt for recovering loose coarse aggregates that can be automatically customized to suit the needs of the user, hook-type foreign matter sorting belt, belt for recovering loose fine aggregates, inhalation-exhalation trash bin, smart fly aggregate recovery through pores, and fugitive dust reduction type construction waste foreign matter The purpose is to provide separation and screening devices and methods.

In order to achieve the above object, according to the present invention, a mesh belt for recovering loose coarse aggregate, a belt for sorting out foreign matter with hooks, a belt for recovering fine aggregate, and a smart flying aggregate recovery and fugitive dust reduction type construction through inhalation-exhalation trash bin pores. Waste foreign matter separation and sorting device

Foreign substances in construction waste that are sorted by particle size and fall from the vibrating screen module are separated from the raw aggregate at a strong wind speed of 30 m/s to 70 m/s. Among the flying aggregates that are blown away as an adverse effect during the sorting process, the flying coarse aggregate is the flying coarse aggregate. In the process of recovery through the mesh belt for recovery, the flying fine aggregate is separated and sorted to fall into the flying fine aggregate recovery belt, and the flying fine aggregate and foreign matter that flew farther than the flying coarse aggregate are transferred to the inhalation-exhalation type waste storage bin by hook, Flying fine aggregates are collected in the belt for collecting flying fine aggregates, and through breathing holes on the top and side walls of the enclosed waste storage bin, the heavy part of the flying dust settles inside the waste bin and only the light part is discharged to the outside. This is achieved by being configured to control it to do so.

In more detail, the smart flying aggregate recovery and flying dust reduction type construction waste foreign matter separation and sorting device is,

A vibrating screen module (100) that sorts construction waste containing foreign substances such as vinyl or wood chips by particle size through the force of vibration and an inclined structure,

Based on the raw aggregate falling at the bottom of the discharge part of the vibrating screen module, a strong wind of 30 m/s to 70 m/s is sprayed in an inclined direction from the bottom to the top, and the aggregate that is not blown away by the wind is transferred directly to the aggregate transport conveyor belt. An inclined blowing module (200) that causes foreign substances and loose aggregates to fall toward the trash bin and blows them to the mesh belt for collecting loose coarse aggregate and the hook-type foreign material sorting belt section installed inside the waste bin,

The aggregate transport conveyor belt unit (located in the Y-axis direction based on the inclined blowing module) receives and transports the aggregate that has not been blown by the wind and the loose coarse aggregate that has been transported back by the mesh belt unit for recovering the loose coarse aggregate. 300) and,

It is formed along the longitudinal direction of the A mesh belt unit (400) for recovering loose coarse aggregate that collects and delivers it to the aggregate transfer conveyor belt section, separates and selects loose fine aggregate from the flying aggregate blown away with the wind, and discharges it toward the loose fine aggregate recovery belt section,

It is located at an incline on the same line as the mesh belt for recovering loose coarse aggregate, and is inhaled and exhaled through a rolling spinning movement that rolls foreign matter in the downward direction among loose fine aggregate and foreign matter that flies farther than coarse aggregate through an inclined blowing module. A hook-type foreign material sorting belt unit 500 that separates and sorts the soil contained in the loose fine aggregate and foreign materials and discharges them toward the inclined soil guide plate while transporting them to the garbage storage bin;

It is located at the bottom of the mesh belt for collecting loose coarse aggregate, and is formed on one side of the inclined soil guide plate along the longitudinal direction of the A flying fine aggregate recovery belt unit (600) that receives the flying fine aggregate and soil selected from the guide plate and joins them to the adjacent conveyor belt section for transporting soil and sand,

Formed in the shape of a box with only one side open, foreign matter transferred from the hook-type foreign matter sorting belt section is stored, and the heavy part of the flying dust is discharged into the bin through inhalation-exhalation pores on the top and side walls of the bin, which is closed on all sides. An inhalation-exhalation type garbage storage box (700) that sinks in and discharges only the light parts to the outside,

An inclined soil guide plate (800) formed at an angle at the lower end of the hook-type foreign material sorting belt section and guiding the loose fine aggregate and soil selected through the hook-type foreign material sorting belt section toward the loose fine aggregate recovery belt section;

A soil discharge conveyor belt unit 900 located on one side of the loose fine aggregate recovery belt via the bottom of the vibrating screen module and collects and discharges loose fine aggregate and soil,

Vibrating screen module, inclined blowing module, aggregate transfer conveyor belt section, mesh belt section for recovering loose coarse aggregates, hook-type foreign matter sorting belt section, belt section for recovering loose fine aggregates, breathing-out garbage storage box, conveyor belt for sediment discharge It is connected to the unit and controls the overall operation of each device, while spraying strong wind speeds of 30m/s to 70m/s, double back transfer and recovery of flying aggregates, soil recovery, soil selection, and inhalation-exhalation type pores. It is characterized by being composed of a smart control unit (900a) that controls the reduction of flying dust and the selective storage of foreign substances.

As described above, in the present invention

First, by using a strong blowing speed of 30 m/s ~ 70 m/s from the inclined blowing module formed at the bottom of the discharge part of the vibrating screen module, the separation efficiency of foreign substances such as vinyl and wood chips from construction waste can be improved by more than 90% compared to the existing method. In addition, the separation efficiency of soil attached to aggregate that is not sorted by the vibration of a simple screen device can be improved by 80% compared to the existing method.

Second, through the mesh belt for collecting loose coarse aggregate, the loose coarse aggregate among the loose aggregates blown away with the wind is recovered and delivered to the aggregate transport conveyor belt, and the loose fine aggregates are separated and selected from the flying aggregates blown away with the wind. As a result, the loose fine aggregate can be discharged to the belt for recovery, and the loose aggregate recovery rate can be increased by 1.5 to 2 times compared to the existing method.

Third, the configuration of the loose fine aggregate recovery belt section that receives the loose fine aggregate and soil selected from the mesh belt section for loose coarse aggregate recovery and the inclined soil guide plate and joins them to the adjacent conveyor belt section for soil transfer, and the inhalation and exhalation type. Through inhalation and exhalation holes on the top and side walls of the garbage storage box, the heavy part of the flying dust settles inside the trash box and only the light part is discharged to the outside, reducing the flying dust to less than 80% and removing foreign substances from inside the trash box. The secondary process occurrence rate, which requires separate soil and sand, can be reduced to less than 70% compared to the existing process.

Fourth, through the smart control unit, strong wind speed spraying of 30m/s to 70m/s, back transport and recovery of flying aggregates, soil recovery, foreign matter selection, reduction of flying dust through inhalation and exhalation type pores, and selective storage of foreign substances at the same time. It can be controlled automatically to suit the size of the selected aggregate on site, the amount of flying aggregate recovered, the soil sorting rate, and the flying dust generation rate. As a result, it is eco-friendly and improves automation, so it is in the construction waste foreign material separation and sorting market. Competitiveness can be increased.

Figure 1 shows a mesh belt for recovering loose coarse aggregate, a hook-type foreign matter sorting belt, a belt for recovering loose fine aggregate, and smart flying aggregate recovery and fugitive dust reduction type construction waste foreign matter separation and screening through inhalation-exhalation bin pores according to the present invention. A block diagram showing the components of the device,
Figure 2 shows a mesh belt for recovering loose coarse aggregate, a hook-type foreign matter sorting belt, a belt for recovering loose fine aggregate, and smart flying aggregate recovery and fugitive dust reduction type separation and screening of foreign matter from construction waste through inhalation-exhalation bin pores according to the present invention. a perspective view showing the components of the device;
Figure 3 is a block diagram showing the components of the vibrating screen module according to the present invention;
Figure 4 is a perspective view showing the components of the vibrating screen module according to the present invention;
Figure 5 is a block diagram showing the components of the vibration generator according to the present invention;
Figure 6 is a block diagram showing the components of the inclined blowing module according to the present invention;
Figure 7 is a perspective view showing the components of the inclined blowing module according to the present invention;
Figure 8 is a block diagram showing the components of the aggregate transport conveyor belt according to the present invention;
Figure 9 is a perspective view showing the components of the aggregate transport conveyor belt according to the present invention;
Figure 10 is a block diagram showing the components of the mesh belt section for recovering loose coarse aggregate according to the present invention;
Figure 11 is a perspective view showing the components of the mesh belt portion for recovering loose coarse aggregate according to the present invention;
Figure 12 shows a mesh belt for recovering loose coarse aggregate, a hook-type foreign matter sorting belt, a belt for recovering loose fine aggregate, and smart fly aggregate recovery and fugitive dust reduction type separation and screening of foreign matter from construction waste through inhalation-exhalation bin pores according to the present invention. a cross-sectional view showing the components of the device;
13 is a block diagram showing the components of the hook-type belt for separating foreign substances according to the present invention;
Figure 14 is a perspective view showing the components of the hook-type belt for separating foreign substances according to the present invention;
Figure 15 is a perspective view showing the components of the hook-type rolling spinning drum cell portion according to the present invention;
Figure 16 shows a 1a hook-type rolling spinning drum cell (630a), a 1b hook-type rolling spinning drum cell (630b), a 1c hook-type rolling spinning drum cell (630c), and a 1d hook-type rolling spinning drum according to the present invention. Cell (630d), 1e hook-type rolling spinning drum cell (630e), 1f hook-type rolling spinning drum cell (630f), 1g hook-type rolling spinning drum cell (630g), 1h hook-type rolling spinning drum cell ( 630h), an exploded perspective view showing the components of the 1i hook-type rolling spinning drum cell (630i) and the 1j hook-type rolling spinning drum cell (630j),
Figure 17 is a block diagram showing the components of the belt section for recovering loose fine aggregate according to the present invention;
Figure 18 is a perspective view showing the components of the belt portion for recovering loose fine aggregate according to the present invention;
Figure 19 is a block diagram showing the components of the inhalation-exhalation type garbage storage box according to the present invention;
Figure 20 is a perspective view showing the components of the inhalation-exhalation type garbage storage box according to the present invention;
Figure 21 is a perspective view showing the components of the ceiling-type inhalation breathing hole according to the present invention;
Figure 22 is a perspective view showing the components of the side wall type exhalation breathing hole according to the present invention;
Figure 23 is a circuit diagram showing the components of the smart control unit according to the present invention;
Figure 24 is a block diagram showing the components of the conveyor belt for soil discharge according to the present invention;
Figure 25 is a perspective view showing the components of the conveyor belt for soil discharge according to the present invention;
Figure 26 shows a mesh belt for recovering loose coarse aggregate, a hook-type foreign matter sorting belt, a belt for recovering loose fine aggregate, and smart flying aggregate recovery and fugitive dust reduction type construction waste foreign matter separation through inhalation-exhalation bin pores according to the present invention. An embodiment showing the operation process of the sorting device,
Figure 27 shows a mesh belt for recovering loose coarse aggregate, a hook-type foreign matter sorting belt, a belt for recovering loose fine aggregate, and smart flying aggregate recovery and fugitive dust reduction type construction waste foreign matter separation and screening through inhalation-exhalation waste bin pores according to the present invention. A flowchart showing the specific process of the method,
Figure 28 shows that the hook-type foreign matter sorting belt buoy is driven in accordance with the control signal of the smart control unit according to the present invention, and through the inclined blowing module, the blowing foreign matter is transmitted and inhaled and exhaled through the rolling spinning movement of rolling downward. A flowchart showing the specific process of selecting the soil covered in foreign substances and discharging it through the inclined soil guide plate formed at an angle at the bottom while transporting it to the waste storage bin.

First, the flying aggregate described in the present invention is the sorted aggregate that is selected and dropped by the force of vibration, and is divided into a mesh belt part for recovering loose coarse aggregate and a hook-type belt part for separating foreign substances by a strong wind speed of 30 m/s to 70 m/s. This refers to aggregate that flies toward the installed inhalation type waste storage bin. In other words, it is the same concept as sorted aggregate, but if it is separated along with foreign substances in the field, it is an aggregate that must be sorted again in a secondary process. In this patent, it is a new term for recovery by back transport, and is called "blown aggregate." Here, those with a size of 5 mm or more are called “blowing coarse aggregate” and those with a size of less than 5 mm are called “blowing fine aggregates.”

Hereinafter, a preferred embodiment according to the present invention will be described with accompanying drawings.

Figure 1 shows a mesh belt for recovering loose coarse aggregate, a hook-type foreign matter sorting belt, a belt for recovering loose fine aggregate, and smart flying aggregate recovery and fugitive dust reduction type construction waste foreign matter separation and screening through inhalation-exhalation bin pores according to the present invention. It is a block diagram showing the components of the device, and Figure 2 shows a mesh belt for recovering loose coarse aggregate, a hook-type foreign matter sorting belt, a belt for recovering loose fine aggregate, and a smart waste bin through breathing holes according to the present invention. This is a perspective view showing the components of a flying aggregate recovery and flying dust reduction type construction waste foreign matter separation and sorting device, which is sorted by particle size on a vibrating screen module and filters out foreign matter in the falling construction waste at a speed of 30 m/s to 70 m/s. Among the flying aggregates that are blown away as an adverse effect in the process of separating and sorting from the raw aggregate by strong wind speed, the flying coarse aggregate is separated and sorted during the recovery process through the mesh belt for collecting flying coarse aggregate and falls into the belt for collecting flying fine aggregate. , Flying fine aggregates and foreign matter that have flown farther than the flying coarse aggregate are transported to the breathing-out waste storage bin using hooks, and the flying fine aggregates are collected in the belt for collecting flying fine aggregates, and the upper and side walls of the breathing-out waste storage box are closed on all sides. Through the inhalation and exhalation type pores, the heavy part of the flying dust settles inside the garbage bin and is controlled so that only the light part is discharged to the outside.

More specifically, the smart flying aggregate recovery and flying dust reduction type construction waste foreign matter separation and sorting device (1) includes a vibrating screen module (100), an inclined blowing module (200), an aggregate transfer conveyor belt unit (300), and a loose coarse Mesh belt unit for aggregate recovery (400), hook-type belt unit for sorting out foreign substances (500), belt unit for recovering loose fine aggregate (600), inhalation type garbage storage box (700), inclined soil guide plate (800), soil It consists of a discharge conveyor belt unit (900) and a smart control unit (900a).

First, the vibrating screen module 100 according to the present invention will be described.

The vibrating screen module 100 serves to sort construction waste containing foreign substances such as vinyl or wood chips by particle size through the force of vibration and an inclined structure.

As shown in FIG. 3, it is composed of a screen module main body 110, a construction waste/soil input unit 120, a screen unit 130, a discharge unit 140, and a vibration generator 150.

First, the screen module main body 110 according to the present invention will be described.

The screen module body 110 is formed in a longitudinal box shape with one side open, and serves to support each device and protect it from external pressure.

As shown in Figure 4, a construction waste and soil input part is formed on one side of the front end of the upper surface, an discharge part is formed on one side of the lower part of the upper surface, a screen part is formed through the upper front end, the middle part of the upper surface, and the lower part of the upper surface. It is composed of a discharge part formed on one side of the lower part.

Here, the front end of the upper surface refers to the place where the aggregate to be sorted falls, the middle part of the upper surface refers to the place where the aggregate spreads and is sorted, and the lower part of the upper surface refers to the place where the sorted aggregate is generated.

Second, the construction waste and soil input unit 120 according to the present invention will be described.

The construction waste and soil input unit 120 is located on one side of the upper front end of the screen module main body and serves to receive construction waste or soil containing foreign substances such as vinyl or wood chips and deliver it to the screen unit.

It is formed in a hopper structure, and construction waste or earth and sand containing foreign substances such as vinyl or wood chips are injected.

Third, the screen unit 130 according to the present invention will be described.

The screen portion 130 is formed at the upper front end, upper middle portion, and upper lower portion of the screen module main body, and receives the force of vibration generated from the vibration generator, and receives the force of vibration and the input vinyl or material through the inclined structure. It spreads out construction waste or soil containing foreign materials such as wood chips and selects only the foreign materials and aggregates separated from the soil.

This is configured by selecting one of a single network screen, a double network screen, and a triple screen.

In addition, one of a flat screen with a tilt angle of 5 degrees or less and an inclined screen with a tilt angle of 16 to 40 degrees is selected.

The screen portion has a plurality of screen nets formed on the surface, and the screen net size is formed in various sizes ranging from 40 mm to 80 mm.

Fourth, the discharge unit 140 according to the present invention will be described.

The discharge part 140 is located on one side of the lower part of the upper surface and serves to discharge selected foreign substances and aggregates.

It falls freely and is discharged through the force of gravity and vibration.

Fifth, the vibration generator 150 according to the present invention will be described.

The vibration generator 150 is formed on one side of the screen module body and serves to generate a vibration force in the screen module body.

As shown in Figure 5, it consists of a vibration weight 151 and a vibration motor 152.

The vibrating weight 151 rotates by receiving the force of vibration generated by the vibration motor, and an inertial force is generated along the weight of the weight, thereby generating a vibration force in the screen module body.

The vibration motor 152 generates vibration force and transmits it to the vibration weight.

Next, the inclined blowing module 200 according to the present invention will be described.

The inclined blowing module 200 sprays a strong wind of 30 m/s to 70 m/s in an inclined direction from the bottom to the top, based on the raw aggregate falling at the bottom of the discharge part of the vibrating screen module, so that it does not blow away in the wind. The unused aggregate falls directly toward the aggregate transfer conveyor belt, and foreign matter and loose aggregate are blown toward the mesh belt for recovering loose coarse aggregate and the hook-type foreign material sorting belt installed inside the trash bin.

As shown in FIG. 6, it is composed of a blowing module main body 210, a blower 220, a plate fan 230, a blowing distributor 240, and a spray duct portion 250.

First, the blowing module main body 210 according to the present invention will be described.

The blowing module main body 210 is formed as an upright box-shaped structure in the longitudinal direction, and serves to protect and support each device from external pressure.

As shown in FIG. 7, a blower is formed on one side of the floor, a plate fan is formed on one side of the blower, a blower distributor is formed on one side of the top of the plate fan, and a spray duct is formed toward the top of the blower distributor. Wealth is formed and constituted.

Second, the blower 220 according to the present invention will be described.

The blower 220 is located on one side of the bottom of the glide jump type vibrating screen module, and serves to suck in external air and form a blower towards the blower distributor.

It consists of a blower blade and a blower motor.

Here, the blower motor is generated at 1500rpm to 4000rpm.

And, the wind speed according to the size of the aggregate is set in various ways depending on the purpose and type of use.

In addition, one side of the intake port of the blower is connected to the upper duct of the foreign matter storage box, forming an air circulation blowing module.

Third, the plate pan 230 according to the present invention will be described.

The plate fan 230 is formed in a cover-type structure on one side of the blower, and serves to prevent foreign substances from flowing into the blower and to dissipate heat generated in the blower.

It is formed by protruding a plurality of wing-shaped heat dissipation fins from a circular plate.

Fourth, the blower distributor 240 according to the present invention will be described.

The blowing distributor 240 is located on the output side of the blower, and serves to receive the blowing air generated by the blower through one input port and then distribute it toward the spray duct through two or four outlets.

As shown in FIG. 7, it is formed in a distributed structure.

In addition, the diameter of one input port and the diameter of the two outlets are formed to be the same size, and the length and diameter of each blowing pipe located at the one input port and the two outlets are also formed to have the same length and diameter.

Fifth, the injection duct portion 250 according to the present invention will be described.

The spray duct portion 250 receives wind through a blower distributor and serves to spray wind in an inclined direction from the bottom to the top, based on foreign substances and aggregates that fall at the bottom of the discharge portion of the vibrating screen module.

This is configured to spray wind speed to the left, center, and right sides of foreign substances and aggregates that fall at the bottom of the discharge section of the vibrating screen module.

At this time, strong winds are generated with wind speeds of 30m/s to 70m/s.

Next, the aggregate transport conveyor belt unit 300 according to the present invention will be described.

The aggregate transport conveyor belt unit 300 is located in the Y-axis direction based on the inclined blowing module, and transports aggregate that is not blown by the wind and loose coarse aggregate transported back by the mesh belt unit for recovering loose coarse aggregate. It plays a role in receiving and transporting goods.

It is formed and configured as a belt conveyor structure.

And, as shown in Figures 8 and 9, it is composed of an aggregate transport rotation motor 310, an aggregate transport driving roller 320, an aggregate transport driven roller 330, and an aggregate transport conveyor belt 340.

The aggregate transport rotation motor 310 serves to generate rotational force and transmit it to the aggregate transport drive roller.

It is connected to a smart control unit on one side and is driven according to control signals from the smart control unit.

The aggregate transport drive roller 320 receives rotational force from the aggregate transport rotation motor and serves to rotate the aggregate transport conveyor belt in one direction.

The aggregate transport driven roller 330 is located on the driven shaft and serves to support the aggregate transport conveyor belt to rotate in one direction.

The aggregate transport conveyor belt 340 serves to receive and transport selected aggregates that have not been blown by the wind and loose coarse aggregates that have been transported back by the mesh belt unit for recovering the loose coarse aggregates.

Next, the mesh belt unit 400 for recovering loose coarse aggregate according to the present invention will be described.

The mesh belt portion 400 for recovering loose coarse aggregate is formed along the longitudinal direction of the Among the flying aggregates blown away with the wind, the loose coarse aggregates are recovered by back transfer and delivered to the aggregate transport conveyor belt, and the loose fine aggregates are separated and selected from the flying aggregates blown away with the wind and discharged to the flying fine aggregate recovery belt section. .

It is formed and configured as a mesh-type conveyor structure. And, as shown in Figure 12, in order to recover the loose coarse aggregate among the loose aggregates blown with the wind through the inclined blowing module and transfer it to the aggregate transfer conveyor belt part, an upper part of the loose fine aggregate recovery belt part is installed on one side. It is located and is connected to the aggregate transport conveyor belt.

In addition, it is formed along the longitudinal direction of the

It is installed by moving it to the left or right depending on the falling point of the flying aggregate and the degree to which foreign substances are flying.

The reason is that all particles are different depending on the size of the particles selected in the vibrating screen module. To solve this problem, the mesh belt for collecting loose coarse aggregate must be able to move left and right, and at this time, the separated fine aggregate is discharged to the belt for collecting loose fine aggregate.

In determining the size of the mesh net of the mesh belt part for recovering loose coarse aggregate, that is, the eye size to be able to sort out soil and stone dust, it is configured to be smaller than the eye size of the net selected in the vibrating screen module. For example, if the screen mesh size of the vibrating screen module is 40mm, it should be made to be smaller than this by about 20mm.

This is because foreign substances passing through here may be included in the soil and stone dust if they are selected through the mesh net.

As shown in FIGS. 10 and 11, the mesh belt unit 400 for recovering loose coarse aggregate includes a mesh-type transfer rotation motor 410, a mesh-type transfer driving roller 420, and a mesh-type transfer driven roller 430. ), and a mesh-type transfer conveyor belt (440).

The mesh-type transfer rotation motor 410 serves to generate rotational force and transmit it to the mesh-type transfer drive roller.

It is connected to a smart control unit on one side and is driven according to control signals from the smart control unit.

The mesh-type transfer drive roller 420 receives rotational force from the mesh-type transfer rotation motor and serves to rotate the mesh-type transfer conveyor belt in one direction.

The mesh-type transfer driven roller 430 is located on the driven shaft and serves to support the mesh-type transfer conveyor belt to rotate in one direction.

The mesh-type transfer conveyor belt 440 recovers loose coarse aggregate from the flying aggregate blown with the wind through an inclined blowing module and transfers it to the aggregate transport conveyor belt part, and blows out the flying aggregate from the flying aggregate blown with the wind. It serves to separate and select fine aggregates and discharge them to the belt for collecting loose fine aggregates.

It is composed of a plurality of mesh networks with a diameter of 2cm to 5cm formed on the surface.

In this way, the mesh belt unit (400) for recovering loose coarse aggregate consists of a mesh-type transfer rotation motor (410), a mesh-type transfer driving roller (420), a mesh-type transfer driven roller (430), and a mesh-type transfer conveyor belt (440). ) is configured to collect the loose coarse aggregate among the flying aggregates blown with the wind by back transfer and deliver it to the aggregate transport conveyor belt, and separate and select the flying fine aggregates from the flying aggregates blown with the wind to collect the flying fine aggregates. Since it can be discharged to the side, the recovery rate of flying aggregate can be increased by 1.5 to 2 times compared to the existing one.

Next, the hook-type foreign material sorting belt unit 500 according to the present invention will be described.

The hook-type foreign matter sorting belt unit 500 is located inclined on the same line as the mesh belt unit for recovering loose coarse aggregate, and blows foreign matter out of the loose fine aggregate and foreign matter that flies farther than the loose coarse aggregate through an inclined blowing module in the vertical direction. It serves to separate and select the soil contained in loose fine aggregates and foreign substances and discharge them toward the inclined soil guide plate while transporting them to the inhalation-exhalation type garbage storage bin through the rolling spinning movement.

It has a hooked disc drum type foreign matter screening function.

Even if foreign matter is blown away, it does not necessarily mean that it flies farther than the flying fine aggregate. Therefore, some of the loose fine aggregate must be blown up to the mesh belt part for recovering loose coarse aggregate or the hook-type foreign matter sorting belt part, and the foreign matter is configured to be blown up to the hook-type foreign matter sorting belt part.

Most of these blown foreign substances are lighter than the flying fine aggregate, but the reason why they are different in size is because the flying fine aggregate has a high specific gravity, so being in a similar position to the flying fine aggregate means that the weight is similar, and if you think of this in reverse, it is bound to be large. Therefore, if a hook is placed on the rotating part, the foreign matter can be picked up.

As shown in FIG. 13, the hook-type foreign matter sorting belt unit 500 includes a hook-type module body 510, a rotating shaft rod 520, a hook-type rolling spinning drum cell unit 530, and a foreign matter separation rotation gear 540. ), and a foreign matter selection rotation motor (550).

First, the hook-type module body 510 according to the present invention will be described.

The hook-shaped module body 510 is formed in a regular inclined structure that gradually becomes higher from the front end to the rear end, and a hook protruding bar is formed on the surface, which serves to protect and support each device from external pressure.

As shown in FIG. 14, it is shaped like a box, has a space at the top and is open at the front and rear ends, and a plurality of rotating shaft rods are formed on the surface of the bottom along the longitudinal direction of the Y-axis, and hook-shaped rolling is formed on the rotating shaft rods. The spinning drum cell part is formed, a foreign matter separation rotation gear is formed on one side of the end of the rotating shaft, and a foreign matter separation rotation motor is formed on one side of the foreign matter separation rotation gear.

Here, the regular inclined structure refers to a structure that is inclined at an angle of 10 to 15 degrees toward the top with respect to the horizontal reference line.

Second, the rotating shaft rod 520 according to the present invention will be described.

The rotation axis rod 520 is formed along the Y-axis longitudinal direction on the surface of the hook-shaped module body, serves as a framework to support the hook-type rolling spinning drum cell unit, and transmits rotational force.

Here, being formed along the Y-axis longitudinal direction on the surface of the hook-shaped module body means that it is formed in a plurality of row structures.

Fourth, the hook-type rolling spinning drum cell unit 530 according to the present invention will be described.

The hook-type rolling spinning drum cell unit 530 is supported on the rotating shaft rod and scrapes foreign substances blown by the wind like a hook through a rolling spinning movement in the vertical direction generated by the rotational force transmitted to the rotating shaft rod. It serves to separate and select soil with foreign substances while transporting it to the type waste storage box and discharges it to the inclined soil guide plate.

As shown in FIG. 15, the 1st hook-type rolling spinning drum cell 530a, the 1b hook-type rolling spinning drum cell 530b, the 1c hook-type rolling spinning drum cell 530c, and the 1d hook-type rolling Spinning drum cell (530d), 1st hook type rolling spinning drum cell (530e), 1f hook type rolling spinning drum cell (530f), 1g hook type rolling spinning drum cell (530g), 1h hook type rolling spinning drum It consists of a cell 530h, a 1i hook-type rolling spinning drum cell 530i, and a 1j hook-type rolling spinning drum cell 530j.

[1st hook type rolling spinning drum cell (530a)]

The first hook-type rolling spinning drum cell 530a is located on the rightmost side of the rotating shaft when viewed from the front view, and is linked with another neighboring hook-type rolling spinning drum cell, and moves in the vertical direction generated by the rotational force. Through the rolling motion of rolling, foreign matter carried by the wind is scraped like a hook and transferred to the inhalation-exhalation type garbage storage box, while the soil on the foreign matter is separated and sorted and discharged to the inclined soil guide plate.

As shown in FIG. 16, it is composed of a 1st fixed twin ring 530a-1, a 1st hook-type rolling spinning drum 530a-2, and a 1st snail wing 530a-3.

The 1a fixed twin ring 530a-1 is formed in a twin ring structure on the rotating shaft rod, and serves to position and support the 1a hook-type rolling spinning drum so that it is fixed in place.

At this time, the 1st fixed twin ring and the 1st hook type rolling spinning drum are formed as an integrated structure through bolting or welding.

The first a hook-type rolling spinning drum (530a-2) has a plurality of hook protruding bars formed on the surface, has a hexagonal drum structure and a weight of 1 kg, and generates the transmitted rotational force into a rolling spinning movement rolling in the up and down directions. 1a is delivered to the snail wing, and through a rolling spinning motion rolling in the up and down direction, it scrapes foreign substances blown by the wind like a hook and transfers them to another neighboring hook protruding bar.

Here, generating the rotational force through a rolling spinning movement that rolls up and down means that when the rotational force is transmitted, due to the non-circular hexagonal structure and its own weight of 1Kg, it rolls in the up and down direction like an elliptical rotational movement when viewed from the front. It refers to the creation of a rolling spinning movement in which a spinning movement is performed while (=shaking).

It consists of a hexagonal drum structure and a weight of 1kg.

And, depending on the purpose and form of use, it is formed in various angular structures and with various weights.

The hook protruding bars are formed in plural numbers on the surface of the drum, and serve to scrape foreign substances blown by the wind like hooks and transfer them to another neighboring hook protruding bar through a rolling spinning motion rolling in the up and down direction.

It is made of silicon or rubber, and allows foreign matter blown by the wind to come into contact with the surface and deliver it to the final destination, the foreign matter storage box.

The 1a cochlear wing (530a-3) is located on one side of the 1a hook-type rolling spinning drum, is formed in a cochlear structure, and is positioned between the 1a hook-type rolling spinning drum and another adjacent hook-type rolling spinning drum. When a foreign substance is stuck in the machine, the force of the rolling spinning movement is transmitted and the rolling spinning movement rolls in the up and down direction, which serves to loosen and dislodge the trapped foreign matter.

In other words, when the 1a hook-type rolling spinning drum is formed in a circular shape and only moves in a circle at a constant speed, foreign matter often occurs between the 1a hook-type rolling spinning drum and another neighboring hook-type rolling spinning drum. However, the hook-type rolling spinning drum 1a has a hexagonal structure and a weight of 1Kg, and the transmitted rotational force can generate a rolling spinning movement that rolls in the up and down directions, loosening and dislodging the trapped foreign matter.

[1b hook type rolling spinning drum cell (530b)]

The 1b hook-type rolling spinning drum cell 530b is located on one side of the 1a hook-type rolling spinning drum cell and is interlocked with another neighboring hook-type rolling spinning drum cell, rolling in the vertical direction generated by rotational force. Through the rolling spinning movement, foreign matter carried by the wind is scraped like a hook and transported to the inhalation-exhalation type garbage storage bin, while the soil on the foreign matter is separated and sorted and discharged to the inclined soil guide plate.

As shown in Figure 16, it is composed of a 1b fixed twin ring (530b-1), a 1b hook-type rolling spinning drum (530b-2), and a 1b snail wing (530b-3).

The 1b fixed twin ring 530b-1 is formed in a twin ring structure on the rotating shaft rod, and serves to position and support the 1b hook-type rolling spinning drum so that it is fixed in place.

At this time, the b fixed twin ring and the first b hook type rolling spinning drum are formed as an integrated structure through bolting or welding.

The 1b hook-type rolling spinning drum (530b-2) has a plurality of hook protruding bars formed on the surface, has a hexagonal drum structure and a weight of 1 kg, and generates the transmitted rotational force into a rolling spinning movement rolling in the up and down directions. It is delivered to the 1b snail wing, and through a rolling spinning motion rolling in the up and down direction, it scrapes foreign substances blown by the wind like a hook and transfers them to another neighboring hook protruding bar.

Here, generating the rotational force through a rolling spinning movement that rolls up and down means that when the rotational force is transmitted, due to the non-circular hexagonal structure and its own weight of 1Kg, it rolls in the up and down direction like an elliptical rotational movement when viewed from the front. It refers to the creation of a rolling spinning movement in which a spinning movement is performed while (=shaking).

It consists of a hexagonal drum structure and a weight of 1kg.

And, depending on the purpose and form of use, it is formed in various angular structures and with various weights.

The hook protruding bars are formed in plural numbers on the surface of the drum, and serve to scrape foreign substances blown by the wind like hooks and transfer them to another neighboring hook protruding bar through a rolling spinning motion rolling in the up and down direction.

It is made of silicon or rubber, and allows foreign matter blown by the wind to come into contact with the surface and deliver it to the final destination, the foreign matter storage box.

The 1b cochlear wing (530b-3) is located on one side of the 1b hook-type rolling spinning drum, is formed in a cochlear structure, and is positioned between the 1b hook-type rolling spinning drum and another adjacent hook-type rolling spinning drum. When a foreign substance is stuck in the machine, the force of the rolling spinning movement is transmitted and the rolling spinning movement rolls in the up and down direction, which serves to loosen and dislodge the trapped foreign matter.

In other words, if the 1b hook-type rolling spinning drum is formed in a circular shape and only moves in a circle at a constant speed, foreign matter often occurs between the 1b hook-type rolling spinning drum and another neighboring hook-type rolling spinning drum. However, the 1b hook-type rolling spinning drum has a hexagonal structure and a weight of 1Kg, and the transmitted rotational force can generate a rolling spinning movement that rolls up and down, loosening and dislodging trapped foreign substances.

[1c hook type rolling spinning drum cell (530c)]

The 1c hook-type rolling spinning drum cell 530c is located on one side of the 1b hook-type rolling spinning drum cell and is interlocked with another neighboring hook-type rolling spinning drum cell, rolling in the vertical direction generated by rotational force. Through the rolling spinning movement, foreign matter carried by the wind is scraped like a hook and transported to the inhalation-exhalation type garbage storage bin, while the soil on the foreign matter is separated and sorted and discharged to the inclined soil guide plate.

As shown in Figure 16, it is composed of a 1c fixed twin ring (530c-1), a 1c hook-type rolling spinning drum (530c-2), and a 1c snail wing (530c-3).

The 1c fixed twin ring 530c-1 is formed in a twin ring structure on the rotating shaft rod, and serves to position and support the 1c hook-type rolling spinning drum so that it is fixed in place.

At this time, the c fixed twin ring and the first c hook type rolling spinning drum are formed as an integrated structure through bolting or welding.

The 1c hook-type rolling spinning drum (530c-2) has a plurality of hook protruding bars formed on the surface, has a hexagonal drum structure and a weight of 1 kg, and generates the transmitted rotational force into a rolling spinning movement rolling in the up and down directions. It is delivered to the 1c snail wing, and through a rolling spinning movement that rolls in the up and down direction, it scrapes foreign substances blown by the wind like a hook and transfers them to another neighboring hook protruding bar.

Here, generating the rotational force through a rolling spinning movement that rolls up and down means that when the rotational force is transmitted, due to the non-circular hexagonal structure and its own weight of 1Kg, it rolls in the up and down direction like an elliptical rotational movement when viewed from the front. It refers to the creation of a rolling spinning movement in which a spinning movement is performed while (=shaking).

It consists of a hexagonal drum structure and a weight of 1kg.

And, depending on the purpose and form of use, it is formed in various angular structures and with various weights.

The hook protruding bars are formed in plural numbers on the surface of the drum, and serve to scrape foreign substances blown by the wind like hooks and transfer them to another neighboring hook protruding bar through a rolling spinning motion rolling in the up and down direction.

It is made of silicon or rubber, and allows foreign matter blown by the wind to come into contact with the surface and deliver it to the final destination, the foreign matter storage box.

The 1c cochlear wing (530c-3) is located on one side of the 1c hook-type rolling spinning drum and is formed in a cochlear structure, between the 1c hook-type rolling spinning drum and another hook-type rolling spinning drum adjacent to it. When a foreign substance is stuck in the machine, the force of the rolling spinning movement is transmitted and the rolling spinning movement rolls in the up and down direction, which serves to loosen and dislodge the trapped foreign matter.

In other words, if the 1c hook-type rolling spinning drum is formed in a circular shape and only moves in a circle at a constant speed, foreign matter often occurs between the 1c hook-type rolling spinning drum and another neighboring hook-type rolling spinning drum. However, the 1c hook-type rolling spinning drum has a hexagonal structure and a weight of 1Kg, and the transmitted rotational force can generate a rolling spinning movement that rolls up and down, loosening and dislodging trapped foreign substances.

[1d hook type rolling spinning drum cell (530d)]

The 1d hook-type rolling spinning drum cell 530d is located on one side of the 1c hook-type rolling spinning drum cell, and is interlocked with another neighboring hook-type rolling spinning drum cell, rolling in the vertical direction generated by rotational force. Through the rolling spinning movement, foreign matter carried by the wind is scraped like a hook and transported to the inhalation-exhalation type garbage storage bin, while the soil on the foreign matter is separated and sorted and discharged to the inclined soil guide plate.

As shown in FIG. 16, it is composed of a 1d fixed twin ring (530d-1), a 1d hook-type rolling spinning drum (530d-2), and a 1d snail wing (530d-3).

The 1d fixed twin ring 530d-1 is formed in a twin ring structure on the rotating shaft rod, and serves to position and support the 1d hook-type rolling spinning drum so that it is fixed in place.

At this time, the d fixed twin ring and the 1d hook type rolling spinning drum are formed as an integrated structure through bolting or welding.

The 1d hook-type rolling spinning drum (530d-2) has a plurality of hook protruding bars formed on the surface, has a hexagonal drum structure and a weight of 1 kg, and generates the transmitted rotational force into a rolling spinning movement that rolls in the up and down directions. It is delivered to the 1d snail wing, and through a rolling spinning movement that rolls in the up and down direction, it scrapes foreign substances blown by the wind like a hook and transfers them to another neighboring hook protruding bar.

Here, generating the rotational force through a rolling spinning movement that rolls up and down means that when the rotational force is transmitted, due to the non-circular hexagonal structure and its own weight of 1Kg, it rolls in the up and down direction like an elliptical rotational movement when viewed from the front. It refers to the creation of a rolling spinning movement in which a spinning movement is performed while (=shaking).

It consists of a hexagonal drum structure and a weight of 1kg.

And, depending on the purpose and form of use, it is formed in various angular structures and with various weights.

The hook protruding bars are formed in plural numbers on the surface of the drum, and serve to scrape foreign substances blown by the wind like hooks and transfer them to another neighboring hook protruding bar through a rolling spinning motion rolling in the up and down direction.

It is made of silicon or rubber, and allows foreign matter blown by the wind to come into contact with the surface and deliver it to the final destination, the foreign matter storage box.

The 1d cochlear wing (530d-3) is located on one side of the 1d hook-type rolling spinning drum, is formed in a cochlear structure, and is positioned between the 1d hook-type rolling spinning drum and another adjacent hook-type rolling spinning drum. When a foreign substance is stuck in the machine, the force of the rolling spinning movement is transmitted and the rolling spinning movement rolls in the up and down direction, which serves to loosen and dislodge the trapped foreign matter.

In other words, if the 1d hook-type rolling spinning drum is formed in a circular shape and only moves circularly at a constant speed, foreign matter often occurs between the 1d hook-type rolling spinning drum and another neighboring hook-type rolling spinning drum. However, the 1d hook-type rolling spinning drum has a hexagonal structure and a weight of 1Kg, and the transmitted rotational force can generate a rolling spinning movement that rolls in the up and down directions, loosening and dislodging the trapped foreign matter.

[1st hook type rolling spinning drum cell (530e)]

The 1e hook-type rolling spinning drum cell 530e is located on one side of the 1d hook-type rolling spinning drum cell and is interlocked with another neighboring hook-type rolling spinning drum cell, rolling in the vertical direction generated by rotational force. Through the rolling spinning movement, foreign matter carried by the wind is scraped like a hook and transported to the inhalation-exhalation type garbage storage bin, while the soil on the foreign matter is separated and sorted and discharged to the inclined soil guide plate.

As shown in FIG. 16, it is composed of a 1st fixed twin ring (530e-1), a 1st hook-type rolling spinning drum (530e-2), and a 1st snail wing (530e-3).

The 1e fixed twin ring 530e-1 is formed in a twin ring structure on the rotating shaft rod, and serves to position and support the 1e hook-type rolling spinning drum so that it is fixed in place.

At this time, the 1e fixed twin ring and the 1e hook type rolling spinning drum are formed as an integrated structure through bolting or welding.

The 1e hook-type rolling spinning drum (530e-2) has a plurality of hook protruding bars formed on the surface, has a hexagonal drum structure and a weight of 1 kg, and generates the transmitted rotational force into a rolling spinning movement rolling in the up and down directions. It is delivered to the 1e snail wing, and through a rolling spinning movement that rolls in the up and down directions, it scrapes foreign substances blown by the wind like a hook and transfers them to another neighboring hook protruding bar.

Here, generating the rotational force through a rolling spinning movement that rolls up and down means that when the rotational force is transmitted, due to the non-circular hexagonal structure and its own weight of 1Kg, it rolls in the up and down direction like an elliptical rotational movement when viewed from the front. It refers to the creation of a rolling spinning movement in which a spinning movement is performed while (=shaking).

It consists of a hexagonal drum structure and a weight of 1kg.

And, depending on the purpose and form of use, it is formed in various angular structures and with various weights.

The hook protruding bars are formed in plural numbers on the surface of the drum, and serve to scrape foreign substances blown by the wind like hooks and transfer them to another neighboring hook protruding bar through a rolling spinning motion rolling in the up and down direction.

It is made of silicon or rubber, and allows foreign matter blown by the wind to come into contact with the surface and deliver it to the final destination, the foreign matter storage box.

The 1e cochlear wing (530e-3) is located on one side of the 1e hook-type rolling spinning drum and is formed in a cochlear structure, between the 1e hook-type rolling spinning drum and another adjacent hook-type rolling spinning drum. When a foreign substance is stuck in the machine, the force of the rolling spinning movement is transmitted and the rolling spinning movement rolls in the up and down direction, which serves to loosen and dislodge the trapped foreign matter.

In other words, if the 1e hook-type rolling spinning drum is formed in a circular shape and only moves in a circle at a constant speed, foreign matter often occurs between the 1e hook-type rolling spinning drum and another neighboring hook-type rolling spinning drum. However, the 1e hook-type rolling spinning drum has a hexagonal structure and a weight of 1Kg, and the transmitted rotational force can generate a rolling spinning movement that rolls up and down, loosening and dislodging trapped foreign substances.

[1st hook type rolling spinning drum cell (530f)]

The 1f hook-type rolling spinning drum cell 530f is located on one side of the 1e hook-type rolling spinning drum cell and is linked with another neighboring hook-type rolling spinning drum cell, rolling in the vertical direction generated by rotational force. Through the rolling spinning movement, foreign matter carried by the wind is scraped like a hook and transported to the inhalation-exhalation type garbage storage bin, while the soil on the foreign matter is separated and sorted and discharged to the inclined soil guide plate.

As shown in Figure 16, it is composed of a 1f fixed twin ring (530f-1), a 1f hook-type rolling spinning drum (530f-2), and a 1f snail wing (530f-3).

The 1f fixed twin ring 530f-1 is formed in a twin ring structure on the rotating shaft rod, and serves to position and support the 1f hook-type rolling spinning drum so that it is fixed in place.

At this time, the 1f fixed twin ring and the 1f hook-type rolling spinning drum are formed as an integrated structure through bolting or welding.

The 1f hook-type rolling spinning drum (530f-2) has a plurality of hook protruding bars formed on the surface, has a hexagonal drum structure and a weight of 1 kg, and generates the transmitted rotational force into a rolling spinning movement rolling in the up and down directions. It is delivered to the 1f snail wing, and through a rolling spinning motion rolling in the up and down direction, it scrapes foreign substances blown by the wind like a hook and transfers them to another neighboring hook protruding bar.

Here, generating the rotational force through a rolling spinning movement that rolls up and down means that when the rotational force is transmitted, due to the non-circular hexagonal structure and its own weight of 1Kg, it rolls in the up and down direction like an elliptical rotational movement when viewed from the front. It refers to the creation of a rolling spinning movement in which a spinning movement is performed while (=shaking).

It consists of a hexagonal drum structure and a weight of 1kg.

And, depending on the purpose and form of use, it is formed in various angular structures and with various weights.

The hook protruding bars are formed in plural numbers on the surface of the drum, and serve to scrape foreign substances blown by the wind like hooks and transfer them to another neighboring hook protruding bar through a rolling spinning motion rolling in the up and down direction.

It is made of silicon or rubber, and allows foreign matter blown by the wind to come into contact with the surface and deliver it to the final destination, the foreign matter storage box.

The 1f snail wing (530f-3) is located on one side of the 1f hook-type rolling spinning drum, is formed in a cochlear structure, and is positioned between the 1f hook-type rolling spinning drum and another adjacent hook-type rolling spinning drum. When a foreign substance is stuck in the machine, the force of the rolling spinning movement is transmitted and the rolling spinning movement rolls in the up and down direction, which serves to loosen and dislodge the trapped foreign matter.

In other words, if the 1f hook-type rolling spinning drum is formed in a circular shape and only moves in a circle at a constant speed, foreign matter often occurs between the 1f hook-type rolling spinning drum and another neighboring hook-type rolling spinning drum. However, the 1f hook-type rolling spinning drum has a hexagonal structure and a weight of 1Kg, and the transmitted rotational force can generate a rolling spinning movement that rolls up and down, loosening and dislodging trapped foreign substances.

[1g hook type rolling spinning drum cell (530g)]

The 1g hook-type rolling spinning drum cell (530g) is located on one side of the 1f hook-type rolling spinning drum cell and is interlocked with another neighboring hook-type rolling spinning drum cell, rolling in the vertical direction generated by rotational force. Through the rolling spinning movement, foreign matter carried by the wind is scraped like a hook and transported to the inhalation-exhalation type garbage storage bin, while the soil on the foreign matter is selected and discharged to the bottom.

As shown in FIG. 16, it is composed of a 1g fixed twin ring (530g-1), a 1g hook-type rolling spinning drum (530g-2), and a 1g snail wing (530g-3).

The 1g fixed twin ring (530g-1) is formed in a twin ring structure on the rotating shaft rod, and serves to position and support the 1g hook-type rolling spinning drum so that it is fixed in place.

At this time, the 1g fixed twin ring and the 1g hook type rolling spinning drum are formed as an integrated structure through bolting or welding.

The 1g hook-type rolling spinning drum (530g-2) has a plurality of hook protruding bars formed on the surface, has a hexagonal drum structure and a weight of 1Kg, and generates the transmitted rotational force into a rolling spinning movement rolling in the up and down directions. It is delivered to the 1g snail wing, and through a rolling spinning movement that rolls in the up and down directions, it scrapes foreign substances blown by the wind like a hook and transfers them to another neighboring hook protruding bar.

Here, generating the rotational force through a rolling spinning movement that rolls up and down means that when the rotational force is transmitted, due to the non-circular hexagonal structure and its own weight of 1Kg, it rolls in the up and down direction like an elliptical rotational movement when viewed from the front. It refers to the creation of a rolling spinning movement in which a spinning movement is performed while (=shaking).

It consists of a hexagonal drum structure and a weight of 1kg.

And, depending on the purpose and form of use, it is formed in various angular structures and with various weights.

The hook protruding bars are formed in plural numbers on the surface of the drum, and serve to scrape foreign substances blown by the wind like hooks and transfer them to another neighboring hook protruding bar through a rolling spinning motion rolling in the up and down direction.

It is made of silicon or rubber, and allows foreign matter blown by the wind to come into contact with the surface and deliver it to the final destination, the foreign matter storage box.

The 1g snail wing (530g-3) is located on one side of the 1g hook-type rolling spinning drum, is formed in a cochlear structure, and is positioned between the 1g hook-type rolling spinning drum and another adjacent hook-type rolling spinning drum. When a foreign substance is stuck in the machine, the force of the rolling spinning movement is transmitted and the rolling spinning movement rolls in the up and down direction, which serves to loosen and dislodge the trapped foreign matter.

In other words, when the 1g hook-type rolling spinning drum is formed in a circular shape and only moves in a circle at a constant speed, foreign matter often occurs between the 1g hook-type rolling spinning drum and another neighboring hook-type rolling spinning drum. However, the 1g hook-type rolling spinning drum has a hexagonal structure and a weight of 1Kg, and the transmitted rotational force can generate a rolling spinning movement that rolls up and down, loosening and dislodging trapped foreign substances.

[1st hook type rolling spinning drum cell (530h)]

The 1h hook-type rolling spinning drum cell (530h) is located on one side of the 1g hook-type rolling spinning drum cell and is interlocked with another neighboring hook-type rolling spinning drum cell, rolling in the vertical direction generated by rotational force. Through the rolling spinning movement, foreign matter carried by the wind is scraped like a hook and transported to the inhalation-exhalation type garbage storage bin, while the soil on the foreign matter is separated and sorted and discharged to the inclined soil guide plate.

As shown in FIG. 16, it consists of a 1h fixed twin ring (530h-1), a 1h hook-type rolling spinning drum (530h-2), and a 1h snail wing (530h-3).

The 1h fixed twin ring (530h-1) is formed in a twin ring structure on the rotating shaft rod, and serves to position and support the 1h hook-type rolling spinning drum so that it is fixed in place.

At this time, the 1h fixed twin ring and the 1h hook-type rolling spinning drum are formed as an integrated structure through bolting or welding.

The 1h hook-type rolling spinning drum (530h-2) has a plurality of hook protruding bars formed on the surface, has a hexagonal drum structure and a weight of 1Kg, and generates the transmitted rotational force into a rolling spinning movement rolling in the up and down directions. It is delivered to the 1h snail wing, and through a rolling spinning movement that rolls in the up and down directions, it scrapes foreign substances blown by the wind like a hook and transfers them to another neighboring hook protruding bar.

Here, generating the rotational force through a rolling spinning movement that rolls up and down means that when the rotational force is transmitted, due to the non-circular hexagonal structure and its own weight of 1Kg, it rolls in the up and down direction like an elliptical rotational movement when viewed from the front. It refers to the creation of a rolling spinning movement in which a spinning movement is performed while (=shaking).

It consists of a hexagonal drum structure and a weight of 1kg.

And, depending on the purpose and form of use, it is formed in various angular structures and with various weights.

The hook protruding bars are formed in plural numbers on the surface of the drum, and serve to scrape foreign substances blown by the wind like hooks and transfer them to another neighboring hook protruding bar through a rolling spinning motion rolling in the up and down direction.

It is made of silicon or rubber, and allows foreign matter blown by the wind to come into contact with the surface and deliver it to the final destination, the foreign matter storage box.

The 1h snail wing (530h-3) is located on one side of the 1h hook-type rolling spinning drum and is formed in a cochlear structure, between the 1h hook-type rolling spinning drum and another hook-type rolling spinning drum adjacent to it. When a foreign substance is caught in the machine, the force of the rolling spinning movement is transmitted and the rolling spinning movement rolls in the up and down direction, which serves to loosen and dislodge the trapped foreign matter.

In other words, if the 1h hook-type rolling spinning drum is formed in a circular shape and only moves in a circle at a constant speed, the phenomenon of foreign matter being caught between the 1h hook-type rolling spinning drum and another neighboring hook-type rolling spinning drum often occurs. However, the 1h hook-type rolling spinning drum has a hexagonal structure and a weight of 1Kg, and the transmitted rotational force can generate a rolling spinning movement that rolls in the up and down directions, loosening and dislodging the trapped foreign matter.

[1st hook type rolling spinning drum cell (530i)]

The 1i hook-type rolling spinning drum cell 530i is located on one side of the 1h hook-type rolling spinning drum cell and is interlocked with another neighboring hook-type rolling spinning drum cell, rolling in the vertical direction generated by rotational force. Through the rolling spinning movement, foreign matter carried by the wind is scraped like a hook and transported to the inhalation-exhalation type garbage storage bin, while the soil on the foreign matter is separated and sorted and discharged to the inclined soil guide plate.

As shown in FIG. 16, it is composed of a 1i fixed twin ring (530i-1), a 1i hook-type rolling spinning drum (530i-2), and a 1i snail wing (530i-3).

The 1i fixed twin ring 530i-1 is formed in a twin ring structure on the rotating shaft rod, and serves to position and support the 1i hook-type rolling spinning drum so that it is fixed in place.

At this time, the 1i fixed twin ring and the 1i hook-type rolling spinning drum are formed as an integrated structure through bolting or welding.

The 1i hook-type rolling spinning drum (530i-2) has a plurality of hook protruding bars formed on the surface, has a hexagonal drum structure and a weight of 1 kg, and generates the transmitted rotational force into a rolling spinning movement rolling in the up and down directions. 1a is delivered to the snail wing, and through a rolling spinning motion rolling in the up and down directions, it scrapes foreign substances blown by the wind like a hook and transfers them to another neighboring hook protruding bar.

Here, generating the rotational force through a rolling spinning movement that rolls up and down means that when the rotational force is transmitted, due to the non-circular hexagonal structure and its own weight of 1Kg, it rolls in the up and down direction like an elliptical rotational movement when viewed from the front. It refers to the creation of a rolling spinning movement in which a spinning movement is performed while (=shaking).

It consists of a hexagonal drum structure and a weight of 1kg.

And, depending on the purpose and form of use, it is formed in various angular structures and with various weights.

The hook protruding bars are formed in plural numbers on the surface of the drum, and serve to scrape foreign substances blown by the wind like hooks and transfer them to another neighboring hook protruding bar through a rolling spinning motion rolling in the up and down direction.

It is made of silicon or rubber, and allows foreign matter blown by the wind to come into contact with the surface and deliver it to the final destination, the foreign matter storage box.

The 1i cochlear wing (530i-3) is located on one side of the 1i hook-type rolling spinning drum, is formed in a cochlear structure, and is positioned between the 1i hook-type rolling spinning drum and another adjacent hook-type rolling spinning drum. When a foreign substance is stuck in the machine, the force of the rolling spinning movement is transmitted and the rolling spinning movement rolls in the up and down direction, which serves to loosen and dislodge the trapped foreign matter.

In other words, if the 1i hook-type rolling spinning drum is formed in a circular shape and only moves in a circle at a constant speed, foreign matter often occurs between the 1i hook-type rolling spinning drum and another neighboring hook-type rolling spinning drum. However, the 1i hook-type rolling spinning drum has a hexagonal structure and a weight of 1Kg, and the transmitted rotational force can generate a rolling spinning movement that rolls up and down, loosening and dislodging the trapped foreign matter.

[1j hook type rolling spinning drum cell (530j)]

The 1j hook-type rolling spinning drum cell 530j is located on one side of the 1i hook-type rolling spinning drum cell and is interlocked with another neighboring hook-type rolling spinning drum cell, rolling in the vertical direction generated by rotational force. Through the rolling spinning movement, foreign matter carried by the wind is scraped like a hook and transported to the inhalation-exhalation type garbage storage bin, while the soil on the foreign matter is separated and sorted and discharged to the inclined soil guide plate.

As shown in FIG. 16, it consists of a 1j fixed twin ring (530j-1), a 1j hook-type rolling spinning drum (530j-2), and a 1j snail wing (530j-3).

The 1j fixed twin ring 530j-1 is formed in a twin ring structure on the rotating shaft rod, and serves to position and support the 1j hook-type rolling spinning drum so that it is fixed in place.

At this time, the 1j fixed twin ring and the 1j hook-type rolling spinning drum are formed as an integrated structure through bolting or welding.

The 1j hook-type rolling spinning drum (530j-2) has a plurality of hook protruding bars formed on the surface, has a hexagonal drum structure and a weight of 1Kg, and generates the transmitted rotational force into a rolling spinning movement rolling in the up and down directions. 1a is delivered to the snail wing, and through a rolling spinning motion rolling in the up and down direction, it scrapes foreign substances blown by the wind like a hook and transfers them to another neighboring hook protruding bar.

Here, generating the rotational force through a rolling spinning movement that rolls up and down means that when the rotational force is transmitted, due to the non-circular hexagonal structure and its own weight of 1Kg, it rolls in the up and down direction like an elliptical rotational movement when viewed from the front. It refers to the creation of a rolling spinning movement in which a spinning movement is performed while (=shaking).

It consists of a hexagonal drum structure and a weight of 1kg.

And, depending on the purpose and form of use, it is formed in various angular structures and with various weights.

The hook protruding bars are formed in plural numbers on the surface of the drum, and serve to scrape foreign substances blown by the wind like hooks and transfer them to another neighboring hook protruding bar through a rolling spinning motion rolling in the up and down direction.

It is made of silicon or rubber, and allows foreign matter blown by the wind to come into contact with the surface and deliver it to the final destination, the foreign matter storage box.

The 1j cochlear wing (530j-3) is located on one side of the 1j hook-type rolling spinning drum and is formed in a cochlear structure, between the 1j hook-type rolling spinning drum and another adjacent hook-type rolling spinning drum. When a foreign substance is stuck in the machine, the force of the rolling spinning movement is transmitted and the rolling spinning movement rolls in the up and down direction, which serves to loosen and dislodge the trapped foreign matter.

In other words, if the 1j hook-type rolling spinning drum is formed in a circular shape and only moves in a circle at a constant speed, the phenomenon of foreign matter being caught between the 1j hook-type rolling spinning drum and another neighboring hook-type rolling spinning drum often occurs. However, the 1j hook-type rolling spinning drum has a hexagonal structure and a weight of 1Kg, and the transmitted rotational force can generate a rolling spinning movement that rolls in the up and down directions, loosening and dislodging trapped foreign substances.

Fifth, the foreign matter separation rotating gear 540 according to the present invention will be described.

The foreign matter separation rotary gear 540 is located at the end of the rotating shaft and serves to rotate the rotating shaft by receiving the rotational force generated by the foreign matter separating rotary motor from the chain.

It consists of a roller chain sprocket.

Sixth, the foreign matter selection rotary motor 550 according to the present invention will be described.

The foreign matter separation rotary motor 550 generates rotational force and transmits the rotational force to the foreign matter separation rotation gear through the chain.

This generates a clockwise rotational force to transport the foreign matter toward the inhalation type waste storage bin.

Due to this, clockwise rotational force is transmitted toward the rotating shaft.

Next, the belt unit 600 for recovering loose fine aggregate according to the present invention will be described.

The belt part 600 for recovering loose fine aggregate is located at the bottom of the mesh belt part for recovering loose coarse aggregate, and is formed on one side of the inclined soil guide plate along the longitudinal direction of the It receives the loose fine aggregate and soil selected from the mesh belt section for coarse aggregate recovery and the inclined soil guide plate and joins them to the adjacent conveyor belt section for soil transfer.

As shown in Figures 17 and 18, a rotating motor 610 for collecting loose fine aggregate, a driving roller 620 for recovering flying fine aggregate, a driven roller 630 for recovering flying fine aggregate, and a conveyor belt 640 for recovering flying fine aggregate. ) is composed of.

The rotation motor 610 for collecting loose fine aggregate generates rotational force and transmits it to the driving roller for recovering loose fine aggregate.

It is connected to a smart control unit on one side and is driven according to control signals from the smart control unit.

The driving roller 620 for collecting loose fine aggregate receives rotational force from the rotation motor for recovering loose fine aggregate and serves to rotate the conveyor belt for recovering loose fine aggregate in one direction.

The driven roller 630 for recovering loose fine aggregate is located on the driven shaft and serves to support the conveyor belt for recovering loose fine aggregate to rotate in one direction.

The conveyor belt 640 for recovering loose fine aggregate receives the loose fine aggregate and soil selected from the mesh belt section for recovering loose coarse aggregate and the inclined soil guide plate, and serves to merge them toward the conveyor belt section for transporting neighboring soil. .

It is fixed and consists of a regular rubber belt.

In this way, the flying fine aggregate recovery belt unit ( 600) receives the loose fine aggregate and soil selected from the mesh belt section for recovering loose coarse aggregate and the inclined soil guide plate, and can join them to the conveyor belt section for conveying neighboring soil, eliminating the need to separate the soil from the foreign matter. The secondary process occurrence rate can be reduced to less than 70% compared to before.

Next, the inhalation-exhalation type garbage storage box 700 according to the present invention will be described.

The inhalation-exhalation type garbage storage box 700 is formed in the shape of a box with only one side open, and stores foreign substances transferred from the hook-type foreign material sorting belt portion through inhalation-exhalation type pores on the upper and side walls of the trash box, which is closed on all sides. , the heavy part of the flying dust settles inside the trash bin and only the light part is discharged to the outside.

As shown in FIG. 19, it is composed of a garbage storage box main body 710, an inclined air flow guide plate 720, a ceiling-type inhalation breathing hole portion 730, and a side wall-type exhalation breathing hole portion 740.

First, the garbage storage box main body 710 according to the present invention will be described.

The waste storage box main body 710 is formed in a box shape, has an open front portion, and has a sealed interior space, thereby serving to protect and support each device.

As shown in FIG. 20, the front part is formed in an open structure, and along the open structure, a belt part for recovering loose fine aggregate, a mesh belt part for recovering loose coarse aggregate, and a hook-type foreign matter sorting belt part are located in the inner space. It is formed along the longitudinal direction of the

In addition, an inclined air flow guide plate is formed toward the interior space along the top of the front open structure, a ceiling-type inhalation breathing hole is formed on one side of the ceiling of the interior space, and a side wall-type exhalation breathing hole is formed on one side of the side wall of the interior space. It is composed.

In addition, in order to discharge only foreign substances after all work processes are completed, a double door opening and closing part is formed on one side of the rear.

Second, the inclined air flow guide plate 720 according to the present invention will be described.

As shown in FIG. 12, the inclined air flow guide plate 720 is formed along the top of the open structure at the front of the waste storage box main body, and blows air at a strong wind speed of 30 m/s to 70 m/s of the inclined blowing module. It serves as a guide so that the flying aggregate, earth, sand, and foreign matter separated from the raw aggregate flies and settles in the belt section for collecting loose fine aggregate, the mesh belt section for recovering loose coarse aggregate, and the hook-type foreign material sorting belt section.

It is formed by tilting downward by 5° to 20° based on the horizontal reference line.

Here, the reason why it is formed by tilting downward at 5° to 20° based on the horizontal reference line is that below 5°, the blown aggregate is separated and selected from the raw aggregate by the strong wind speed of 30 m/s to 70 m/s of the inclined blowing module, As earth, sand, and foreign matter fly, they expand, causing problems of not being seated in the correct position on the belt section for recovering loose fine aggregate, the mesh belt section for recovering loose coarse aggregate, and the belt section for sorting out hook-type foreign matter, and more than 20°. Since the problem occurs that it cannot fly far and only flies short distances, it is most desirable to be formed inclined downward at 5° to 20°.

Third, the ceiling-type inhalation breathing hole portion 730 according to the present invention will be described.

The ceiling-type breathing hole 730 is located on one side of the ceiling of the waste storage box main body, and breathes out the flying dust scattered in the air, which is generated by the strong wind speed of 30 m/s to 70 m/s of the inclined blowing module. It acts as an inhalation structure, sucking in air from the ceiling and expelling it to the outside.

As shown in Figure 21, it is composed of a suction motor 731 for inhalation, a suction fan 732 for inhalation, an external discharge pipe 733, and a water spray type flying dust removal unit 734.

The suction motor 731 for inhalation generates rotational force and transmits it to the suction fan for inhalation.

It is connected to a smart control unit on one side and is driven according to control signals from the smart control unit.

The suction fan 732 for inhalation is rotated by the rotational force of the suction motor for inhalation, and breathes out the flying dust scattered in the air, which is generated by the strong wind speed of 30 m/s to 70 m/s of the inclined blowing module. It has an inhalation structure as if breathing in, sucking in air from the ceiling and delivering it to the pipe for external discharge.

It is composed of a plurality of rotary blades.

The external discharge pipe 733 is formed in the longitudinal direction along the exterior direction from the ceiling of the waste storage box main body, and serves to transport flying dust sucked in by the inhalation fan.

The water spray type flying dust removal unit 734 is located on the external discharge pipe, and serves to store flying dust transported through the external discharge pipe in the filtering net 734a and then discharge it to the outside by spraying water. .

Fourth, the side wall type exhalation breathing hole portion 740 according to the present invention will be described.

The side wall-type exhalation breathing hole portion 740 is located on one side of the side wall of the garbage storage box main body, so that the heavy part of the flying dust generated by the strong wind speed of 30 m/s to 70 m/s of the inclined blowing module goes inside the garbage container. Only the light parts that have passed through the mesh belt for recovering loose coarse aggregates and the hook-type foreign matter sorting belt are exhaled from the side wall as if exhaling, and are discharged to the outside.

As shown in Figure 22, it is composed of a side wall type exhalation suction part 741, an exhalation pipe part 742, a flying dust storage tank part 743, and an air compressor part 744.

The side wall type exhalation intake unit 741 is located on one side of the side wall of the garbage storage box main body, so that the heavy part of the flying dust generated by the strong wind speed of 30 m/s to 70 m/s of the inclined blowing module goes inside the garbage container. It serves to inhale only the light part of the flying dust that has passed through the mesh belt section for collecting loose coarse aggregates and the hook-type foreign matter sorting belt section.

Here, exhalation refers to expelling one's breath, and the strong air suction power of the air compressor unit causes the flying dust in the garbage storage box body to create an exhalation effect similar to exhaling one's breath.

The exhalation pipe portion 742 serves to transfer the light part of the flying dust inhaled from the side wall-type exhaling breath intake toward the flying dust storage tank.

This suction force is generated within the pipe by the strong air suction force of the air compressor unit.

The flying dust storage tank 743 serves to store the light portion of flying dust transmitted from the exhaled breath five part.

The air compressor unit 744 serves to form an exhalation structure with strong air suction force in the flying dust storage tank portion, exhalation pipe portion, and side wall type exhalation suction portion.

In this way, the inhalation-exhalation type garbage storage box 700 is composed of the garbage storage box main body 710, the inclined air flow guide plate 720, the ceiling-type inhalation breathing hole portion 730, and the side wall-type exhalation breathing hole portion 740, The upper part of the internal space of the storage box main body has an inhalation structure through the ceiling-type inhalation breathing hole, and the lower middle part of the inner space of the garbage storage box main body has an exhalation structure through the side wall-type exhalation breathing hole, using the convection phenomenon in the air to remove flying dust. The heavy part can be sunk inside the trash bin and only the light part can be discharged to the outside, reducing flying dust to less than 80% and reducing the occurrence rate of the secondary process, which requires separate separation of soil and sand from foreign substances, to less than 70% compared to before. It can be lowered.

Next, the inclined soil guide plate 800 according to the present invention will be described.

The inclined soil guide plate 800 is formed at an angle at the lower end of the hook-type foreign matter sorting belt portion, and serves to guide the loose fine aggregate and soil selected through the hook-type foreign material sorting belt portion toward the flying fine aggregate recovery belt portion. .

It consists of a guide plate with a regular inclined panel structure.

In other words, it is composed of a regular inclined panel structure that is the same as the inclined direction of the hook-type foreign matter sorting belt part.

Next, the conveyor belt unit 900 for soil discharge according to the present invention will be described.

The conveyor belt unit 900 for discharging soil and sand is located on one side of the belt for recovering loose fine aggregate through the bottom of the vibrating screen module, and serves to collect and discharge loose fine aggregate and soil.

As shown in Figures 24 and 25, it consists of a rotation motor 910 for soil discharge, a driving roller 920 for soil discharge, a driven roller 930 for soil discharge, and a conveyor belt 940 for soil discharge. .

The rotation motor 910 for soil discharge serves to generate rotational force and transmit it to the soil transfer drive roller.

It is connected to a smart control unit on one side and is driven according to control signals from the smart control unit.

The transport drive roller 920 for soil discharge receives rotational force from the rotation motor for soil discharge and serves to rotate the conveyor belt for soil discharge in one direction.

The driven roller 930 for soil discharge is located on the driven shaft and serves to support the aggregate/soil transport conveyor belt to rotate in one direction.

The soil transfer conveyor belt 940 is located on one side of the loose fine aggregate recovery belt via the bottom of the vibrating screen module, and serves to collect and transport loose fine aggregate and soil.

Next, the smart control unit 900a according to the present invention will be described.

The smart control unit (900a) includes a vibrating screen module, an inclined blowing module, an aggregate transport conveyor belt unit, a mesh belt unit for recovering loose coarse aggregate, a belt unit for sorting out hook-type foreign substances, a belt unit for recovering loose fine aggregate, and an exhaled waste type. It is connected to the storage box and the conveyor belt for sediment discharge, controlling the overall operation of each device, while spraying strong wind speeds of 30 m/s to 70 m/s, double back transport of flying aggregates, soil recovery, and soil sorting. , It serves to reduce flying dust through inhalation and exhalation pores and at the same time control the selective storage of foreign substances.

It is configured by selecting one of the PIC one-chip microcomputer, microcomputer, and microprocessor.

In the present invention, it consists of a microprocessor.

That is, as shown in FIG. 23, the keypad unit 900a-1 is input to one side of the input terminal, the signal input through the keypad unit is input, and the vibration motor 152 of the vibrating screen module is connected to one side of the output terminal. An output signal is output to generate a vibration force in the screen module main body, and the blower 220 of the inclined blowing module is connected to one side of another output terminal, sucks in external air, and blows the air toward the blowing distributor. An output signal is output to form an output terminal, and the aggregate transport rotation motor 310 of the aggregate transport conveyor belt is connected to one side of another output terminal to generate a rotational force and output an output signal to transmit it to the aggregate transport drive roller. The mesh-type transfer rotation motor 410 of the mesh belt part 400 for recovering loose coarse aggregate is connected to one side of the other output terminal, generates rotational force and outputs an output signal to transmit it to the mesh-type transfer drive roller, and another output terminal is connected to the other output terminal. A foreign material sorting rotary motor 550 of the hook-type foreign material sorting belt part is connected to one side of the output terminal, generates rotational force and outputs an output signal to transmit the rotational force to the foreign material sorting rotary gear through the chain, and is connected to another output terminal on one side. A rotation motor 610 for collecting loose fine aggregate is connected to the belt part for recovering loose fine aggregate, generates rotational force and outputs an output signal to be transmitted to the drive roller for transporting the back of loose aggregate and soil, and is connected to another output terminal. A suction motor 731 for inhalation of the ceiling-type inhalation breathing hole is connected to one side, generates rotational force and outputs an output signal to be transmitted to the suction fan for inhalation, and an air compressor unit of the side wall-type exhalation breathing hole is on one side of another output terminal. (744) is connected and configured to output an output signal to form an exhalation structure with strong air suction force in the fugitive dust storage tank portion, exhalation pipe portion, and side wall type exhalation suction portion.

In addition, in order to increase the amount of flying aggregate recovery and soil separation rate depending on the purpose and type of use, in the case of wind speed control of the blower 220 of the inclined blowing module, a wind speed of 70 m/s is generated for aggregates of 40 mm or more, and for aggregates of 30 mm or more. A wind speed of 50 m/s is generated in the aggregate, and a wind speed of 40 m/s is generated in the aggregate less than 25 mm.

In order to increase the rate of fugitive dust generation depending on the purpose and type of use, the rpm of the inhalation motor is set and controlled to 1500 rpm to 4000 rpm, and the air pressure of the air compressor is set and controlled to 6 to 20 bar.

Hereinafter, a mesh belt for recovering loose coarse aggregate, a hook-type foreign matter sorting belt, a belt for recovering loose fine aggregate, and a smart fly aggregate recovery and fugitive dust reduction type construction waste foreign matter separation and selection method through inhalation-exhalation waste bin pores according to the present invention. Explains the specific process.

Figure 27 is a flowchart showing the specific process of the smart flying dust reduction type construction waste foreign matter separation and selection method through double-structure flying aggregate bag transfer recovery, hook-type foreign matter selection, and inhalation-exhalation type waste bin pores according to the present invention. .

First, as shown in Figure 26, the vibrating screen module is driven according to the control signal from the smart control unit, and through the force of vibration and the inclined structure, construction waste containing foreign substances such as vinyl or wood chips are separated by particle size. Select (S10).

Next, as shown in FIG. 26, the inclined blowing module is driven according to the control signal from the smart control unit, and moves from the bottom direction to the top inclined direction based on the raw aggregate falling at the bottom of the discharge part of the vibrating screen module. By spraying a strong wind of 30m/s to 70m/s, aggregates that are not blown by the wind fall directly toward the aggregate transfer conveyor belt, and foreign substances and flying aggregates are removed from the mesh belt and hook for recovering loose coarse aggregate installed inside the waste bin. It blows all the way to the belt section for sorting foreign substances (S20).

Next, the aggregate transport conveyor belt unit is driven according to the control signal from the smart control unit, and is positioned in the Y-axis direction based on the inclined blowing module, and the bag ( Back) The transported loose coarse aggregate is received and transported (S30).

Next, as shown in FIG. 26, the mesh belt unit for recovering loose coarse aggregate is driven according to the control signal from the smart control unit, and back transfers and recovers the loose coarse aggregate among the flying aggregate blown with the wind through the inclined blowing module. It is delivered to the aggregate transfer conveyor belt section, and the flying fine aggregate is separated and selected from the flying aggregate blown away with the wind and discharged to the flying fine aggregate recovery belt section (S40).

At this time, the aggregate transport conveyor belt unit receives and transports the aggregate that has not been blown by the wind and the loose coarse aggregate that has been transported back by the mesh belt unit for recovering the loose coarse aggregate.

Next, as shown in FIG. 26, the hook-type foreign matter sorting belt part is driven according to the control signal from the smart control unit, and is inclinedly positioned on the same line as the mesh belt part for recovering loose coarse aggregate, through the inclined blowing module. Among the loose fine aggregates and foreign materials that fly farther than the loose coarse aggregates, foreign materials are transported to the inhalation-exhalation type garbage storage bin through a downward rolling motion of rolling spinning, and the soil contained in the loose fine aggregates and foreign materials is separated and selected to provide an inclined soil guide. Discharge toward the plate (S50).

That is, as shown in FIG. 28, a rotational force is generated in the foreign material selection rotation motor and the rotational force is transmitted through the chain to the foreign material selection rotation gear (S51).

Next, in the foreign matter sorting rotary gear, the rotational force generated from the foreign matter sorting rotary motor is transmitted from the chain to rotate the rotary shaft rod (S52).

Next, the rotational force is transmitted through the rotation axis rod while serving as a framework to support the hook-type rolling spinning drum cell unit (S53).

Next, through the motion of rolling spinning, which rolls in the vertical direction generated by the rotational force transmitted from the hook-type rolling spinning drum cell to the rotating shaft, foreign matter blown by the wind is scraped like a hook and transferred to the inhalation-exhalation type garbage storage bin, blowing away. The soil contained in the fine aggregate and foreign matter is separated and discharged toward the inclined soil guide plate (S54).

Next, the flying fine aggregate recovery belt unit is driven according to the control signal from the smart control unit, and the loose fine aggregate and soil selected from the mesh belt unit for loose coarse aggregate recovery and the inclined soil guide plate are delivered to the conveyor for transferring neighboring soil. Join towards the belt part (S60).

Next, the inhalation-exhalation type waste storage bin is driven according to the control signal from the smart control unit, storing the foreign substances transferred from the hook-type foreign matter sorting belt unit, through the inhalation-exhalation type pores on the upper and side walls of the trash bin, which is closed on all sides. The heavy part of the flying dust settles inside the trash bin and only the light part is discharged to the outside (S70).

At this time, the inclined soil guide plate is formed at an angle at the lower end of the hook-type foreign material sorting belt section, and guides the loose fine aggregate and soil selected through the hook-type foreign material sorting belt section toward the loose fine aggregate recovery belt section.

Finally, as shown in Figure 27, the conveyor belt for soil discharge is driven in accordance with the control signal from the smart control unit to collect and transport the fallen or delivered loose fine aggregate and soil through the vibrating screen module and the loose fine aggregate recovery belt. Discharge (S80).

1: Smart flying aggregate recovery and flying dust reduction type construction waste foreign matter separation and sorting device
100: Vibrating screen module
110: Screen module body
120: Construction waste and soil input department
130: screen unit
140: discharge unit
150: Vibration generator
200: Inclined blowing module
300: Aggregate transfer conveyor belt section
400: Mesh belt part for recovering loose coarse aggregate
410: Mesh type transfer rotation motor
420: Mesh type transfer drive roller
430: Mesh type transfer follower roller
440: Mesh type transfer conveyor belt
500: Hook-type foreign matter sorting belt part
510: Hook-type module body
520: Rotation shaft rod
530: Hook-type rolling spinning drum cell part
540: Rotating gear for separating foreign substances
550: Foreign matter selection rotation motor
600: Belt part for recovering loose fine aggregate
700: Inhalation-exhalation type trash storage box
710: Garbage storage box body
720: Inclined air flow guide plate
730: Ceiling type inhalation breathing hole
740: Side wall type exhalation breathing hole
800: Inclined soil guide plate
900: Conveyor belt part for soil discharge
900a: Smart control unit

Claims (12)

Foreign substances and aggregates in the construction waste that are selected and dropped by the force of vibration are separated by strong wind speeds of 30 m/s to 70 m/s, and then the loose coarse aggregates among the blown aggregates carried by the wind are transported back and recovered. After sorting out the loose fine aggregates and soil with foreign substances, collecting them into one piece and discharging them, the heavy part of the flying dust settles inside the waste bin through the inhalation-exhalation type pores formed on the top and side walls of the waste bin, which is closed on all sides, and only the light part is discharged to the outside. In the smart flying aggregate recovery and flying dust reduction type construction waste foreign matter separation and screening device that controls discharge to,
The smart flying aggregate recovery and flying dust reduction type construction waste foreign matter separation and screening device is
A vibrating screen module (100) that sorts construction waste containing foreign substances such as vinyl or wood chips by particle size through the force of vibration and an inclined structure,
Based on the raw aggregate falling at the bottom of the discharge part of the vibrating screen module, a strong wind of 30 m/s to 70 m/s is sprayed in an inclined direction from the bottom to the top, and the aggregate that is not blown away by the wind is transferred directly to the aggregate transport conveyor belt. An inclined blowing module (200) that causes foreign substances and loose aggregates to fall toward the trash bin and blows them to the mesh belt for collecting loose coarse aggregate and the hook-type foreign material sorting belt section installed inside the waste bin,
The aggregate transport conveyor belt unit (located in the Y-axis direction based on the inclined blowing module) receives and transports the aggregate that has not been blown by the wind and the loose coarse aggregate that has been transported back by the mesh belt unit for recovering the loose coarse aggregate. 300) and,
It is formed along the longitudinal direction of the A mesh belt unit (400) for recovering loose coarse aggregate that collects and delivers it to the aggregate transfer conveyor belt section, separates and selects loose fine aggregate from the flying aggregate blown away with the wind, and discharges it toward the loose fine aggregate recovery belt section,
It is located at an incline on the same line as the mesh belt for recovering loose coarse aggregate, and is inhaled and exhaled through a rolling spinning movement that rolls foreign matter in the downward direction among loose fine aggregate and foreign matter that flies farther than coarse aggregate through an inclined blowing module. A hook-type foreign material sorting belt unit 500 that separates and sorts the soil contained in the loose fine aggregate and foreign materials and discharges them toward the inclined soil guide plate while transporting them to the garbage storage bin;
It is located at the bottom of the mesh belt for collecting loose coarse aggregate, and is formed on one side of the inclined soil guide plate along the longitudinal direction of the A flying fine aggregate recovery belt unit (600) that receives the flying fine aggregate and soil selected from the guide plate and joins them to the adjacent conveyor belt section for transporting soil and sand,
Formed in the shape of a box with only one side open, foreign matter transferred from the hook-type foreign matter sorting belt section is stored, and the heavy part of the flying dust is discharged into the bin through inhalation-exhalation pores on the top and side walls of the bin, which is closed on all sides. An inhalation-exhalation type garbage storage box (700) that sinks in and discharges only the light parts to the outside,
An inclined soil guide plate (800) formed at an angle at the lower end of the hook-type foreign material sorting belt section and guiding the loose fine aggregate and soil selected through the hook-type foreign material sorting belt section toward the loose fine aggregate recovery belt section;
A soil discharge conveyor belt unit 900 located on one side of the loose fine aggregate recovery belt via the bottom of the vibrating screen module and collects and discharges loose fine aggregate and soil,
Vibrating screen module, inclined blowing module, aggregate transfer conveyor belt section, mesh belt section for recovering loose coarse aggregates, hook-type foreign matter sorting belt section, belt section for recovering loose fine aggregates, breathing-out garbage storage box, conveyor belt for sediment discharge It is connected to the unit and controls the overall operation of each device, while spraying strong wind speeds of 30m/s to 70m/s, double back transfer and recovery of flying aggregates, soil recovery, soil selection, and inhalation-exhalation type pores. A mesh belt for collecting loose coarse aggregates, a hook-type foreign material sorting belt, a belt for recovering flying fine aggregates, and a breathing hole in an inhalation-exhalation type garbage bin, which is composed of a smart control unit (900a) that controls the removal of flying dust and the selection and storage of foreign substances at the same time. Smart loose aggregate recovery and fugitive dust reduction type construction waste foreign matter separation and sorting device through .
delete The method of claim 1, wherein the mesh belt portion 400 for recovering loose coarse aggregate is
A mesh-type transfer rotation motor (410) that generates rotational force and transmits it to the mesh-type transfer drive roller,
A mesh-type transfer drive roller 420 that receives rotational force from the mesh-type transfer rotation motor and rotates the mesh-type transfer conveyor belt in one direction,
A mesh-type transfer driven roller 430 located on the driven shaft and supporting the mesh-type transfer conveyor belt to rotate in one direction,
Through the inclined blowing module, the loose coarse aggregate is recovered by back transfer and delivered to the aggregate transport conveyor belt, and the flying fine aggregate is separated and selected from the flying aggregate blown with the wind, and the flying fine aggregate recovery belt is used. A mesh belt for recovering loose coarse aggregates, a hook-type foreign matter sorting belt, a belt for recovering fine aggregates, and a smart blowing through an inhalation-exhalation trash bin pore, which is composed of a mesh-type transfer conveyor belt (440) that discharges to the side. Aggregate recovery and fugitive dust reduction type construction waste foreign matter separation and screening device.
The method of claim 1, wherein the hook-type foreign matter sorting belt unit 500 is
A hook-shaped module body 510 that is formed in a regular inclination structure that gradually increases from the front end to the rear end, and has a hook protruding bar formed on the surface to protect and support each device from external pressure,
A rotating shaft rod 520 is formed along the Y-axis longitudinal direction on the surface of the hook-type module body and serves as a framework to support the hook-type rolling spinning drum cell unit and transmits rotational force,
Supported on the rotating shaft rod, through the rolling spinning movement that rolls in the vertical direction generated by the rotational force transmitted to the rotating shaft rod, foreign matter blown by the wind is scraped like a hook and transferred to the inhalation-exhalation type garbage storage bin, removing the foreign matter. A hook-type rolling spinning drum cell unit 530 that separates and selects soil and discharges it toward the inclined soil guide plate,
A foreign matter separation rotation gear 540 located at the end of the rotating shaft, which rotates the rotating shaft by receiving the rotational force generated by the foreign material separating rotation motor from the chain, and
A mesh belt for collecting loose coarse aggregates, a hook-type foreign material sorting belt, and a belt for collecting loose fine aggregates, characterized in that it consists of a foreign material sorting rotary motor (550) that generates a rotating force and transmits the rotating force to the foreign material sorting rotating gear through a chain. ·Smart flying aggregate recovery and fugitive dust reduction type construction waste foreign matter separation and sorting device through inhalation-exhalation trash bin pores.
The method of claim 4, wherein the hook-type rolling spinning drum cell unit 530
When viewed from the front, it is located on the far right side of the rotating shaft, and is linked with another neighboring hook-type rolling spinning drum cell, and through the movement of rolling spinning in the up and down direction generated by rotational force, the drum cell is carried with the wind. A 1a hook-type rolling spinning drum cell (530a) that scrapes foreign substances like a hook and transports them to an inhalation-exhalation type waste storage bin, while separating and sorting soil on foreign substances and discharging them toward an inclined soil guide plate;
1a is located on one side of the hook-type rolling spinning drum cell and is interlocked with another neighboring hook-type rolling spinning drum cell, and removes foreign substances carried by the wind through the rolling spinning movement generated by the rotational force in the upward and downward direction. It scrapes like a hook and transports it to the inhalation-exhalation type waste storage bin, while separating and sorting out the soil covered in foreign substances and discharging it to the inclined soil guide plate.
A 1b hook-type rolling spinning drum cell (530b),
It is located on one side of the 1b hook-type rolling spinning drum cell and is linked with another neighboring hook-type rolling spinning drum cell, and removes foreign substances blown by the wind through the rolling spinning movement generated by the rotational force in the upward and downward direction. A 1c hook-type rolling spinning drum cell (530c) that scrapes like a hook and transports it to an inhalation-exhalation type waste storage bin, while separating and sorting soil covered with foreign substances and discharging it toward an inclined soil guide plate;
It is located on one side of the 1c hook-type rolling spinning drum cell and is linked with another neighboring hook-type rolling spinning drum cell to remove foreign substances blown by the wind through the rolling spinning movement generated by the rotational force in the upward and downward direction. A 1d hook-type rolling spinning drum cell (530d) that scrapes like a hook and transports it to an inhalation-exhalation type waste storage bin, while separating and sorting soil covered with foreign substances and discharging it toward an inclined soil guide plate;
It is located on one side of the 1d hook-type rolling spinning drum cell, and is linked with another neighboring hook-type rolling spinning drum cell, and removes foreign substances blown by the wind through the rolling spinning movement generated by the rotational force in the upward and downward direction. A 1e hook-type rolling spinning drum cell (530e) that scrapes like a hook and transports it to an inhalation-exhalation type waste storage bin, while separating and sorting soil covered with foreign substances and discharging it toward an inclined soil guide plate;
It is located on one side of the 1e hook-type rolling spinning drum cell and is linked with another neighboring hook-type rolling spinning drum cell to remove foreign substances blown by the wind through the rolling spinning movement generated by the rotational force in the upward and downward direction. It scrapes like a hook and transports it to the inhalation-exhalation type waste storage bin, while separating and sorting out the soil covered in foreign substances and discharging it to the inclined soil guide plate.
A 1f hook-type rolling spinning drum cell (530f),
It is located on one side of the 1f hook-type rolling spinning drum cell, and is linked with another neighboring hook-type rolling spinning drum cell, and removes foreign substances carried by the wind through the rolling spinning movement generated by the rotational force in the upward and downward direction. A 1g hook-type rolling spinning drum cell (530g) that scrapes like a hook and transports it to an inhalation-exhalation type waste storage bin, while selecting soil and soil with foreign substances and discharging it toward the bottom;
It is located on one side of the 1g hook-type rolling spinning drum cell and is linked with another neighboring hook-type rolling spinning drum cell, and through the rolling spinning movement generated by the rotational force in the upward and downward direction, foreign substances carried by the wind are removed. A 1h hook-type rolling spinning drum cell (530h) that scrapes like a hook and transports it to an inhalation-exhalation type garbage storage bin, while separating and sorting soil covered with foreign substances and discharging it toward an inclined soil guide plate;
It is located on one side of the 1h hook-type rolling spinning drum cell and is linked with another neighboring hook-type rolling spinning drum cell, and through the rolling spinning movement generated by the rotational force in the upward and downward direction, foreign substances carried by the wind are removed. A 1i hook-type rolling spinning drum cell (530i) that scrapes like a hook and transports it to an inhalation-exhalation type waste storage bin, while separating and sorting soil covered with foreign substances and discharging it toward an inclined soil guide plate;
It is located on one side of the 1i hook-type rolling spinning drum cell and is interlocked with another neighboring hook-type rolling spinning drum cell to remove foreign substances carried by the wind through the rolling spinning movement generated by the rotational force in the upward and downward direction. A flying coarse aggregate characterized by being composed of a 1j hook-type rolling spinning drum cell (530j) that scrapes like a hook and transports it to an inhalation-exhalation type waste storage bin, while separating and sorting soil covered with foreign substances and discharging it toward an inclined soil guide plate. Mesh belt for recovery, hook-type foreign matter sorting belt, belt for recovering loose fine aggregates, smart loose aggregate recovery and fugitive dust reduction type construction waste foreign matter separation and sorting device through inhalation-exhalation trash bin pores.
The method of claim 1, wherein the belt unit 600 for recovering loose fine aggregate is
A rotary motor 610 for collecting loose fine aggregate that generates rotational force and transmits it to a driving roller for recovering loose fine aggregate,
A driving roller for collecting loose fine aggregate (620) that receives rotational force from a rotating motor for recovering flying fine aggregate and rotates the conveyor belt for recovering flying fine aggregate in one direction;
A driven roller 630 for collecting loose fine aggregates, which is located on the driven shaft and supports the conveyor belt for recovering loose fine aggregates to rotate in one direction,
It is characterized by being composed of a conveyor belt (640) for collecting loose fine aggregate that receives the loose fine aggregate and soil selected from the mesh belt section for recovering loose coarse aggregate and the inclined soil guide plate and joins them toward the conveyor belt section for transferring neighboring soil and sand. A mesh belt for recovering loose coarse aggregate, a hook-type foreign matter sorting belt, a belt for recovering loose fine aggregate, and a smart flying aggregate recovery and fugitive dust reduction type construction waste foreign matter separation and sorting device through inhalation-exhalation trash bin pores.
The method of claim 1, wherein the inhalation-exhalation type waste storage box (700) is
A waste storage box main body 710 that is formed in a box shape, has an open front portion, and has a sealed interior space to protect and support each device;
It is formed along the top of the open structure at the front of the waste storage box main body, and the blown aggregate, soil, sand, and foreign matter separated from the raw aggregate are blown away by the strong wind speed of 30 m/s to 70 m/s of the inclined blowing module. An inclined air flow guide plate (720) that serves as a guide to be seated toward the belt portion for recovering loose fine aggregate, the mesh belt portion for recovering loose coarse aggregate, and the belt portion for sorting out hook-type foreign substances,
It is located on one side of the ceiling of the main body of the garbage storage box, and sucks the flying dust scattered in the air, which is generated by the strong wind speed of 30m/s to 70m/s of the inclined blowing module, from the ceiling with an inhalation structure as if breathing in. A ceiling-type inhalation breathing hole (730) that lifts and discharges to the outside,
Located on one side of the side wall of the waste storage box main body, the heavy part of the flying dust generated by the strong wind speed of 30m/s to 70m/s of the inclined blowing module settles inside the waste box, and the mesh belt part for recovering loose coarse aggregate , A mesh belt for recovering loose coarse aggregate, characterized in that it is composed of a side wall-type exhalation breathing hole section 740 that allows only the light portion that has passed through the hook-type foreign matter sorting belt section to be exhaled from the side wall in an exhalation structure as if exhaling and discharged to the outside. ·Hook-type foreign matter sorting belt, flying fine aggregate recovery belt, smart flying aggregate recovery through breathing holes in the breathing-out waste bin, and flying dust reduction type construction waste foreign matter separation and sorting device.
The method of claim 7, wherein the ceiling-type inhalation hole portion 730 is
An inhalation motor 731 that generates rotational force and transmits it to the inhalation fan,
As it is rotated by the rotational force of the suction motor for inhalation, the flying dust scattered in the air, which is generated by the strong wind speed of 30m/s to 70m/s of the inclined blowing module, is blown from the ceiling as if breathing in. A suction fan (732) for inhalation that sucks in and delivers it to the pipe for external discharge,
An external discharge pipe 733 is formed in the longitudinal direction along the exterior direction from the ceiling of the waste storage box main body and transports the flying dust sucked in by the inhalation fan,
It is located on the external discharge pipe and is characterized by being composed of a water spray type flying dust removal unit 734 that stores the flying dust transported through the external discharge pipe in the filtering net 734a and then discharges it to the outside by spraying water. A mesh belt for recovering loose coarse aggregate, a hook-type foreign matter sorting belt, a belt for recovering loose fine aggregate, and a smart flying aggregate recovery and fugitive dust reduction type construction waste foreign matter separation and sorting device through inhalation-exhalation trash bin pores.
The method of claim 7, wherein the side wall type exhalation breathing hole portion 740 is
Located on one side of the side wall of the waste storage box main body, the heavy part of the flying dust generated by the strong wind speed of 30m/s to 70m/s of the inclined blowing module settles inside the waste box, and the mesh belt part for recovering loose coarse aggregate , a side wall-type exhalation suction part 741 that inhales only the light part of the flying dust that has passed through the hook-type foreign matter sorting belt part,
An exhalation pipe portion 742 that transfers the light part of the flying dust sucked in from the side wall type exhaling breath intake portion to the flying dust storage tank portion,
A flying dust storage tank 743 that stores the light part of the flying dust transmitted from the exhaled breath five part,
Mesh belt and hook-type foreign matter separation for recovering loose coarse aggregate, characterized in that it consists of a flying dust storage tank, an exhalation pipe, and an air compressor unit (744) that forms an exhalation structure with a strong air suction force in the side wall-type exhalation suction section. Smart flying aggregate recovery/flying dust reduction type construction waste foreign matter separation and sorting device through belt/flying fine aggregate recovery belt/breathing bin pores.
The method of claim 1, wherein the smart control unit (900a)
The keypad unit 900a-1 is input to one side of the input terminal, the signal input through the keypad unit is input, and the vibration motor 152 of the vibrating screen module is connected to one side of the output terminal to apply the force of vibration to the screen module body. An output signal is output to generate a blower, and a blower 220 of an inclined blowing module is connected to one side of another output terminal, sucks in external air, and outputs an output signal to generate blowing toward the blower distributor. The aggregate transport rotation motor 310 of the aggregate transport conveyor belt is connected to one side of the other output terminal, generates a rotational force and outputs an output signal to transmit it to the aggregate transport drive roller, and is used to collect loose coarse aggregate on one side of another output terminal. The mesh-type transfer rotation motor 410 of the mesh belt unit 400 is connected to generate a rotational force and output an output signal to be transmitted to the mesh-type transfer drive roller, and a hook-type foreign matter sorting belt is installed on one side of another output terminal. The secondary foreign matter separation rotary motor 550 is connected, generates rotational force, and outputs an output signal to transmit the rotational force to the foreign matter separation rotation gear through the chain. The fine aggregate collection belt section for collecting loose fine aggregate is output to one side of another output terminal. The receiving rotation motor 610 is connected, generates rotational force, and outputs an output signal to be transmitted to the driving roller for transporting the flying aggregate and soil back, and suction for inhalation of the ceiling-type inhalation hole on one side of another output terminal. The motor 731 is connected to generate a rotational force and output an output signal to be transmitted to the suction fan for inhalation, and the air compressor unit 744 of the side wall type exhalation breathing hole is connected to one side of another output terminal to store flying dust. A mesh belt for recovering loose coarse aggregate, a hook-type foreign matter sorting belt, and configured to output an output signal to form an exhalation structure with strong air suction force in the tank portion, exhalation pipe portion, and side wall type exhalation suction portion. Smart flying aggregate recovery and flying dust reduction type construction waste foreign matter separation and sorting device through flying fine aggregate recovery belt and breathable waste bin pores.
A step (S10) in which the vibrating screen module is driven according to a control signal from the smart control unit, and construction waste containing foreign substances such as vinyl or wood chips is selected by particle size through the force of vibration and an inclined structure,
The inclined blowing module is driven according to the control signal from the smart control unit, blowing strong wind of 30m/s to 70m/s in an inclined direction from the bottom to the top, based on the raw aggregate falling at the bottom of the discharge part of the vibrating screen module. By spraying, the aggregate that is not blown away by the wind falls directly toward the aggregate transport conveyor belt, and the foreign matter and flying aggregate are blown toward the mesh belt section for recovering loose coarse aggregate and the hook-type foreign material sorting belt section installed inside the trash bin (S20) )and,
The aggregate transport conveyor belt unit is driven according to the control signal from the smart control unit, and is located in the Y-axis direction based on the inclined blowing module, and back transport is carried out by the mesh belt unit for collecting aggregates that are not blown by the wind and loose coarse aggregates. A step (S30) of receiving and transporting the loose coarse aggregate,
According to the control signal from the smart control unit, the mesh belt unit for recovering loose coarse aggregate is driven, and the loose coarse aggregate blown away with the wind through the inclined blowing module is back transferred and recovered and delivered to the aggregate transport conveyor belt part, and the wind A step (S40) of separating and selecting flying fine aggregates from the flying aggregates and discharging them to the belt for collecting flying fine aggregates;
According to the control signal from the smart control unit, the hook-type foreign matter sorting belt part is driven, and is positioned at an angle on the same line as the mesh belt part for collecting loose coarse aggregate, and through the inclined blowing module, loose fine aggregate and foreign matter fly farther than the loose coarse aggregate. A step (S50) of transporting foreign substances to an inhalation-exhalation waste storage bin through a downward rolling motion of rolling spinning, while separating and sorting out the loose fine aggregate and soil contained in the foreign substances and discharging them toward the inclined soil guide plate;
According to the control signal from the smart control unit, the flying fine aggregate recovery belt unit is driven, and the loose fine aggregate and soil selected from the mesh belt unit for loose coarse aggregate recovery and the inclined soil guide plate are delivered to the neighboring conveyor belt unit for soil transfer. A joining step (S60),
In accordance with the control signal from the smart control unit, the inhalation-exhalation waste storage bin is driven, storing foreign substances transferred from the hook-type foreign matter sorting belt part, and removing fugitive dust through inhalation-exhalation type pores on the top and side walls of the trash bin, which is closed on all sides. A step (S70) of sinking the heavy parts inside the trash bin and discharging only the light parts to the outside,
The conveyor belt for soil discharge is driven according to the control signal from the smart control unit, and the falling or delivered loose fine aggregate and soil are collected and transported and discharged through the vibrating screen module and the loose fine aggregate recovery belt (S80). A mesh belt for recovering loose coarse aggregate, a hook-type foreign matter sorting belt, a belt for recovering loose fine aggregate, and a method for separating and sorting out foreign matter from construction waste using a smart waste aggregate recovery and fugitive dust reduction type through the pores of an inhalation-exhalation waste bin.
The method of claim 11, wherein step (S50) is
A step (S51) of generating rotational force in the foreign matter selection rotary motor and transmitting the rotational force to the foreign matter selection rotary gear through the chain;
A step (S52) of rotating the rotary shaft rod by receiving the rotational force generated from the foreign material selection rotary motor from the chain in the foreign material selection rotary gear,
A step (S53) of transmitting rotational force through the rotation axis rod, while serving as a framework to support the hook-type rolling spinning drum cell unit,
Through the motion of rolling spinning in the vertical direction generated by the rotational force transmitted from the hook-type rolling spinning drum cell to the rotating shaft, foreign substances blown by the wind are scraped like hooks and transferred to the inhalation-exhalation type garbage storage bin, and the flying fine aggregate and A mesh belt for recovering loose coarse aggregates, a hook-type foreign material sorting belt, a belt for recovering fine aggregates, and an inhalation exhalation process, characterized in that it consists of the step (S54) of separating and sorting the soil contained in the foreign matter and discharging it toward the inclined soil guide plate. Smart flying aggregate recovery and fugitive dust reduction method for separating and sorting foreign substances from construction waste through waste bin pores.