KR100504153B1 - A dust collector for disposal of construction waste - Google Patents

Abstract

The present invention relates to a dust collecting apparatus for collecting and collecting fine dust generated when the specific gravity generated by the wind force, that is, the specific gravity separated by the wind in the process of recycling the construction waste to the aggregate, the air inlet is formed on one side of the upper end, A plurality of rotary doors are arranged inside the plurality of rotary doors so as to partition several spaces of a fan shape, and a cylindrical collector having a communication portion formed therein corresponding to the one space portion; It consists of a cylindrical portion communicating with the communication portion and the bottom of the funnel-shaped sedimentation portion, and an air outlet formed in the air outlet formed on one side of the upper end of the cylindrical portion; composed of turbid air is introduced into the air inlet by the blower In the process of passing through the fan-shaped space part, the bottom communication part and the expansion settling body of the cylindrical collector, the fine dust was settled and filtered to discharge the purified air to the air outlet.

Description

A DUST COLLECTOR FOR DISPOSAL OF CONSTRUCTION WASTE}

The present invention relates to a dust collecting device for collecting and collecting fine dust generated when the specific gravity generated by the force of the wind, that is, the wind in the process of recycling the construction waste to the aggregate.

Many structures, such as bridges, roads, and other buildings, which have been created in the process of urbanization and industrialization, are gradually aging over the years, and in recent years, reconstruction and redevelopment has been actively promoted in many regions to improve the living culture. have.

Many construction wastes are generated in the process of dismantling, reconstruction, and redevelopment of old structures. If the construction wastes are reclaimed, landfills are not only difficult to secure, but also have a high cost of landfills and seriously affect the environment.

Accordingly, various measures have been taken in each country to treat construction waste in two aspects, such as protection of the natural environment and recycling of resources. In Korea, many treatment devices for construction waste have been developed.

Construction wastes include earth and sand, construction wastes including waste concrete, waste asphalt, waste bricks, waste tiles, waste stones, waste and waste blocks, waste woods, waste synthetic resins, metals such as rebar, Waste papers, waste glass, sludge waste fibers, incineration residues and the like can be divided into mixed wastes.

As such, construction wastes containing various wastes are separated into landfill, incineration, and recycling through treatment.In recent years, construction wastes, which occupy a considerable portion of waste, are aggregated into various structures or aggregates. There is a plan to increase the recycling of waste by recycling for use.

In general, these construction wastes are firstly crushed to less than 100mm by the jaw crusher and then screened together with various sizes of aggregates in the process of passing through screens with various sizes of sorting holes. In addition, other waste wood or waste resin is subjected to the process of washing at the same time separated from the aggregate and specific gravity by the hydraulic method by the wind power and the tank tank by the blower.

In addition, the aggregates first crushed by the jaw crusher is a crusher having a smaller crushing standard, that is, a second crusher (30-50mm or less) or cone crusher (10-30mm or less) or finally sand mill (10mm or less) It can be crushed to fine aggregate by, and the aggregates shredded in each step as described above will be repeated again the process of specific gravity separation by wind and hydraulic method by the blower and the tank tank as described above.

However, in recent years, due to economic advantages, in particular, the fine-grained shredded by the concrete or sand mill has been considered a wind-screen cleaning method only.

In general, however, in the specific gravity separation method by wind power, the environment is contaminated by dust scattered because it installs several layers of wind screens to trap waste materials that are blown by wind, that is, waste species, waste resin, or fine soil. There is a problem, such as, especially when the fine aggregates crushed by the compactor or sand mill to separate and clean only by the wind, not hydropower, a large amount of fine dust occurs, the situation is serious.

The present invention has a purpose to provide a more comfortable working environment by devising a device that can effectively collect the fine dust generated during separation and cleaning by the force of the wind.

The present invention for achieving the above object is an air inlet is formed on one side of the upper side, the inside of the plurality of rotating doors are arranged so that several space portion of the fan-shaped radially from the central axis is arranged, the bottom of the fan-shaped A cylindrical collector having a communicating portion corresponding to the space portion of the cylindrical collector; The cylindrical portion communicating with the communication portion, the funnel-shaped precipitation portion of the lower portion and the upper end portion of the expansion settled body formed with an air outlet having an opening surface significantly larger than the opening surface of the air inlet.

In addition, the present invention is characterized in that the air inlet formed in the cylindrical collector and the air outlet formed in the expansion settled body connected to a duct interposed with a blower.

In addition, the present invention is characterized in that a plurality of plates in the interior of the expansion settled body.

Hereinafter, with reference to the accompanying drawings will be described in more detail on the basis of a preferred embodiment of the present invention.

1 is a partially cutaway perspective view illustrating the basic configuration of the present invention, Figure 2 is a longitudinal cross-sectional view of Figure 1, Figure 3 is an AA cross-sectional view of Figure 2 is an operating state of the cylindrical collector, Figure 4 is a view of the present invention A partially cutaway perspective view illustrating a configuration in which a bypass plate is provided in the expanding settling body, and FIG. 5 illustrates a cross section of FIG. 4.

In the present invention, as shown in Figure 1, the cylindrical collector 10 is formed on the upper portion, the expansion settled body 20 is formed in the lower portion.

First, the cylindrical collector 10 has an air inlet 11 is formed on one side of the top, the air inlet 11 is a fan-shaped space partitioned by five rotary doors 13 through the expansion portion 12 It is made to communicate with the adjacent fan-shaped space part 14 among the parts 14.

In this embodiment, the rotary door 13 has five, so the fan-shaped space 14 is also divided into five, but the number of these can be added or subtracted by design, the sealing pad at the front end of the rotary door 13 (19) is installed.

The rotary doors 13 are arranged to rotate in a cylindrical collector 10 fixed with a central axis 15 as a hinge, and the upper ceiling 16 of the cylindrical collector 10 is blocked and The lower bottom 17 has a size corresponding to the fan-shaped space 14 at a position opposite to the inlet 11 so that one communication portion 18 is drilled, and the sedimentation settlement is formed at the lower end of the cylindrical collector 10. Communication with the sieve 20 was made.

The extension settled body 20 is composed of the upper cylindrical portion 21 and the lower funnel-shaped precipitate 22, the lower end of the stopper 24 with a dust outlet 23 is installed, On one side of the upper end, an air outlet 29 having an opening surface that is significantly wider than the opening surface of the air inlet 11 is formed at a position as far as possible from the communication portion 18.

The expanded sedimentation body 20 may be a space left as it is, as shown in Figure 1, but may be installed by installing a plurality of plates or porous plates to bypass the flow of air.

4 and 5 illustrate a configuration in which several bypass diaphragms 25 are installed to bypass the flow of air.

That is, five bypass diaphragms 25 are radially arranged at the central point in the cylindrical portion 21 of the expanded sedimentation material 20, as shown in the five spaces (I) (II) (III) (IV). It is divided into (V).

The first space (I) is formed to be in direct communication with the communicating portion 18 of the cylindrical collector 10 at the same position, and the first plate is installed in a state completely isolated from the last fifth space (V). It is.

The second plate has an inner space (27) between the second space (II) and the third space (III) so that the outer space 26 is formed between the first space (I) and the second space (II). Again, the fourth partition has an outer space 26 between the third space (III) and the fourth space (IV), and the fifth partition has an inner gap between the fourth space (IV) and the fifth space (V). 27 is provided so that it may be formed.

In addition, the entire space except for the fifth space (V) is in communication with the funnel-type precipitation portion 22 of the lower portion, but only the fifth space (V) is the funnel-shaped precipitation portion 22 and the blocking floor (28). ), The air outlet 29 is formed at one side of the upper end of the fifth space (V).

The air outlet 29 is connected to the air inlet 11 and the duct 40 through the blower 30.

According to the present invention configured as described above, turbid air supplied from a dust source (not shown) is pushed into the relatively narrow air inlet 11 by the blower 30 and passes through the expanding portion 12 to form a fan in the cylindrical collector 10. As the rotary door rotates due to the wind pressure continuously filled in the space 14 and then continuously introduced from the air inlet 11, clockwise, ie, A-> B-> C-> D-, as shown in FIG. 3. Rotate in the> E direction.

That is, the clouded air passes through the air inlet 11 at a relatively high wind pressure and then passes through the enlarged portion 12, whereby the pressure is first lowered and then pushed back into the wider flat space portion A 14. In the state where the wind pressure is lowered, it is passed through the B and C point spaces in order while being trapped in the fan-shaped space portion 14.

At this time, since the air trapped in the fan-shaped space 14 moves together along the wind pressure, i.e., the flow of air, the trapped air flows in the temporarily closed fan-shaped space 14 to occur.

As such, when the flow of air is stopped, the dust particles mixed in the turbid air show a downward movement to sink downward due to its weight. In such a state, when the fan space portion 14 reaches the point D, By communicating with the expansion settled body 20 which forms a wider space at the bottom by the communication part 18 drilled on the bottom, the dust particles falling as described above are sucked into the larger space of the expanded settled body 20. As it descends, it is settled and settles, and eventually accumulates in the lower funnel-type sedimentation part 22, and when these dusts are accumulated in a certain amount, the stopper 24 of the dust outlet 23 can be opened and collected. The clean air separated from the particles is returned to the blower 30 via the air outlet 29 and the duct 40.

At this time, since the opening surface of the air outlet 29 is significantly larger than that of the air inlet 11, the discharge flow of air is made relatively smooth.

In addition, when the bypass diaphragm 25 as shown in FIG. 4 and FIG. 5 is installed inside the extension settled body 20, air flows into five spaces (I) (II) (III) (IV). Since it bypasses (V) in turn and exits to the air outlet 29, the sedimentation time of the dust particles becomes longer, so that the sedimentation effect can be enhanced.

On the other hand, the fan-shaped space portion 14 that diffuses most of the turbid air in the point D space to the expansion settled body 20 located below it, returns to the original position A through the point E, and then again By repeatedly rotating along the same path, the dust particles continuously mixed in the turbid air are accumulated in the funnel-type precipitate 22 in the expanded sedimentation body 20.

In the above-described embodiment, the communication portion 18 formed in the bottom 17 is formed to have a size corresponding to one fan-shaped space 14, but in some cases, the communication portion 18 may be formed to have two corresponding sizes. Of course, this belongs to the design matter to the last as in the number of sections of the sector space portion 14.

As described above, the present invention collects the fugitive dust generated in the process of gravity separation and selective cleaning of the construction waste by the force of the wind, that is, the air inlet and the air outlet formed in the closed system, that is, the dust collector Since it is processed in the closed space connected to the duct interposed with the blower, the problem that the working environment is contaminated by the scattering dust as in the prior art has an effect that can maintain a more comfortable working environment.

In addition, there is an advantage in that the wind power system, which is conventionally used as an auxiliary separation and sorting means in the treatment of construction waste, can be selected more widely, and as a result, the location can be selected regardless of the water situation.

1 is a partially cutaway perspective view illustrating the basic configuration of the present invention.

2 is a longitudinal cross-sectional view of FIG.

Figure 3 is a cross-sectional view taken along the line A-A of Figure 2 operating state diagram.

4 is a partially cutaway perspective view illustrating a configuration in which a plurality of bypass plates are installed in the expanding settling body of the present invention.

5 is a cross-sectional view of FIG. 4.

* Description of the symbols for the main parts of the drawings *

10 cylindrical collector 11 air inlet

13: revolving door 14: fan-shaped space part

18: communication part 20: expansion settled body

21: cylindrical portion 22: funnel-shaped precipitate

25: bypass plate 29: air outlet

Claims (3)

In the apparatus for collecting the scattering dust generated in the process of separating, sorting, and cleaning construction waste by wind power, An air inlet is formed at one upper end thereof, and a plurality of rotary doors are arranged in the inside thereof so that several spaces of a fan shape are radially formed from a central axis, and a communication part is formed at the bottom corresponding to the space part of the fan shape. Cylindrical collectors; It comprises a expansion settled body consisting of a cylindrical portion in communication with the communication portion of the cylindrical collector and an air outlet having a funnel-shaped precipitation portion at the bottom and an upper end of the cylinder portion has an opening surface that is significantly larger than the opening surface of the air inlet. Dust collecting device for construction waste treatment, characterized in that. The dust collector of claim 1, wherein the air inlet formed in the cylindrical collector and the air outlet formed in the expanding settling body are connected to each other by a duct through an air blower. The dust collector for construction waste treatment according to any one of claims 1 to 3, wherein a plurality of bypass diaphragms are provided in the extension settled body.